WO2025014409A1 - A multi power generating device and a method. - Google Patents

Abstract

The invention relates to a power generating apparatus, comprising at least one tubular structure (202) adhering to a spiral path, a configuration designed to ionize, move and accelerate a fluid flow in the tubular structure and to generate electricity along the path of the tubular structure, and an egg-shaped reactor (504) in fluidic communication with the downstream end terminus of the at least one tubular structure, where the reactor comprises an anode and a cathode and is intended for electrochemical and fusion reactions instigated by the ionized and accelerated fluid flow.

Description

Description

Title of Invention: A multi power generating device and a method.

Technical Field

[0001] The present invention introduces a groundbreaking unit for multi-power generation or quantum charging, incorporating an advanced system for selectively accelerating and ionizing a fluid within a closed loop. The fluid, when subjected to acceleration and ionization, can exist in a normal gaseous state or form mixtures with light and heavy gases while retaining its gaseous properties. It has the capability to generate energy through various mechanisms, including the movement of electrons and ions in a winding's magnetic field, electrochemical reactions, and the production and acceleration of small particles resulting from ionization processes and collisions.

[0002] In conventional practices, electricity generation involves creating an electric current by establishing a potential difference in a circuit, resulting in the movement of electrons within a conductor. This is achieved by generating a negative potential on one side and a positive potential on the other, with the combination of voltage and current being essential for electricity flow. This can be accomplished through various means, including mechanical electromagnetic fields generated by turbines in waterpower, wind power, and sea wave generators, as well as electrochemical reactions in solar panels or quantum electrochemical reactions like hot and cold fusion. These methods can withstand elevated temperatures, making them suitable for long- duration operation.

[0003] While there may be similarities in technical terminology related to electricity and quantum physics with prior arts, it is crucial to discern subtle differences to avoid confusion or misinterpretation. Classic physics and quantum physics concepts are not the same and have complex effects. On the other hand, integrating components such as ionization, Tesla coils, coils, transformers, or simpler items like ICs, electrodes, capacitors, resistors, and transistors can lead to innovative products. These innovations span various domains, including telecommunication towers, smartphones, dialysis machines, or skimmer card readers, each contributing innovation, and advancements in their fields.

[0004] It is important to note that my innovation has undergone refinements to enhance its functionality and ensure long-term safe operation, particularly within power generator units. To avoid further delays and more potential damage to this technology, I urge skilled persons to exercise caution and provide a comprehensive explanation of the fundamental knowledge and methodology, involving up-to-date experts. Emphasizing the tangible components and underlying theories is vital to safeguard the device and its technology through patent protection. Reviewers should be familiar with recent scientific advancements, such as quantum phenomena, unconventional gas behaviors, and practical and operational challenges in this field.

[0005] The disclosure in the next chapter should not be regarded as any admittance of prior art, in this filed.

Background Art

[0006] Since 2008, this method and device have been continuously refined through the development of various prototypes and rigorous bench tests aimed at enhancing ion control. The primary objective has been to design a device that is simple, lightweight, and less complex, utilizing readily available materials and gases. Extensive simulations involving different shapes and materials have tackled numerous challenges, leading to the current device design. Over the past decade, advancements in quantum physics have broadened the understanding of atomic interactions, paving the way for innovative approaches to material creation and device construction. Increased research and publications in the field of quantum physics have drawn more attention and support from the scientific community, aiding in the creation of this device. As a result, the limitations on its development have diminished over time. Modem technologies, such as 3D printing (including metal 3D printing) and advanced molding techniques for critical components, have played a significant role in the development and industrial feasibility of these types of devices. These technological advancements have enabled the creation of more complex objects with greater detail and dimensions. As a result, the device has become more space-efficient, economical, and safer. These improvements align with the common goal of all developers and systems to enhance the functionality and practicality of the device in future applications.

[0007] (W02010093981A2), by Helion, Method and apparatus for heating and/or compressing plasmas to thermonuclear temperatures and densities are provided. In one aspect, at least one of at least two plasmoids separated by a distance is accelerated towards the other. The plasmoids interact, for instance to form a resultant plasmoid, to convert a kinetic energy into a thermal energy. The resultant plasmoid is confined in a high energy density state using a magnetic field.

[0008] (WO2018/211309), by the same inventor, describes an ozone generation method using air through an electric arc ionization technique. This method involves machining opposite helical grooves along two-thirds of the path within ionization chamber for the treatment and sanitization of water, wastewater, and air. Developed independently over the past fifteen years, this device and method have had a significant impact on related industries.

[0009] Ion acceleration technologies have evolved significantly, employing various methods to accelerate charged particles. Traditional methods include linear accelerators (Linacs), synchrotrons, synchrocyclotrons, cyclotrons, SANCTRON (Space Acceleration New Concept TRON), betatrons, drift tube linacs (DTLs), radiofrequency quadrupoles (RFQs), electron cyclotron resonance (ECR) ion sources, and induction accelerators. These methods primarily utilize magnetic and electric fields within a tube structure and coli to achieve ion acceleration in a linear or circular trajectory.

[0010] Linear accelerators (Linacs) utilize oscillating electric fields to accelerate particles in a straight line. This process is governed by Maxwell's equations, particularly Gauss's law for electricity and Faraday's law of induction, which describe the behavior of electric fields and charges. Given these principles, acceleration by the Lorentz force law in a tube with a coil is both feasible and well- supported by established physics.

[0011] Synchrotrons employ powerful magnetic fields to guide particles in a circular path, synchronizing acceleration with particle speed. A prime example is the Large Hadron Collider (LHC). The Lorentz force law describes the force on a charged particle moving through electric and magnetic fields.

[0012] Synchrocyclotrons are similar to synchrotrons but adjust the frequency of the accelerating electric field to account for relativistic effects as particle speeds increase. Relativistic corrections to the Lorentz force law account for the increase in mass at relativistic speeds, as described by Einstein’s theory of relativity.

[0013] Synchrocyclotrons are similar to synchrotrons but adjust the frequency of the accelerating electric field to account for relativistic effects as particle speeds increase. Relativistic corrections to the Lorentz force law account for the increase in mass at relativistic speeds, as described by Einstein’s theory of relativity. This utilizes the Lorentz force law to optimize acceleration in confined spaces with enhanced field configurations.

[0014] Betatrons accelerate electrons using a changing magnetic field in a circular orbit. Faraday’s law of induction and the Lorentz force law describe how the changing magnetic field induces an electric field that accelerates the electrons. Drift tube linacs (DTLs) use a series of drift tubes within an electric field to accelerate ions. The concept of drift velocity and the behaviour of ions in electric fields describe how ions gain energy while “drifting” through the electric fields in the tubes.

[0015] Radio-Frequency Quadrupoles (RFQs) utilize electric fields within quadrupole structures to focus and accelerate ions in a linear path. The principles of electric quadrupole fields focus and accelerate the ions along the desired path. Electron cyclotron resonance (ECR) ion sources generate and accelerate ions using a combination of magnetic fields and microwave radiation. The cyclotron resonance condition and Maxwell’s equations describe how the frequency of the applied microwave radiation matches the natural frequency of the ions in the magnetic field. [0016] Induction accelerators use magnetic induction to accelerate particles in a circular or linear path. Faraday’s law of induction describes how a changing magnetic field induces an electric field that accelerates the particles.

[0017] The present invention introduces a novel approach to ion acceleration, integrating a spiral- shaped module and a unique design for recycling and cooling the accelerated particles. This system enhances sustainability, efficiency, and continuous operation, distinguishing it from existing technologies. The invention also operates under the same fundamental physical laws as the prior arts, ensuring ions can be accelerated in the axial direction of the tube.

[0018] The faster recycling, ionization, and movement acceleration occurs continuities and frequently in a spiral tube pathway within one and/or both modules, optimizing space and improving acceleration efficiency unlike existing technologies. This design leverages the principles of electromagnetic induction and the Lorentz force, like synchrotrons and cyclotrons. At least one winding layer generates a magnetic field to accelerate the fluid, while another layer acts as self-inducted windings to generate voltage by plasmid flow. Additional winding layers function as transformer windings to control high and low voltage, facilitating the acceleration and energy transformation processes as the ionized fluid flows through the primary tubular structure. The system incorporates a mechanism to return the fluid to the beginning of the process, cooling it to prevent abnormal behaviours of atoms, such as uncontrolled fission, and to ionize atoms that have lost electrons again. This recycling process ensures that unstable ions with lower mass are reaccelerated, achieving higher speeds, and improving the probability of fusion by increasing proton numbers ratio to the atom’s electrons, the method optimizing required space and improving acceleration efficiency by further explanation. This design leverages the principles of electromagnetic acceleration similar to synchrotrons and cyclotrons. The system incorporates a mechanism to return the fluid to the beginning of the process, cooling it to prevent abnormal behaviours of atoms, such as uncontrolled fission, and to ionize atoms that have lost electrons. This recycling process ensures that unstable ions with lower mass are reaccelerated, achieving higher speeds (F: m.a) and improving the chance of fusion by increasing proton numbers ratio to electrons by daring them to an external circuit.

[0019] The cooling system adheres to the laws of thermodynamics and the conservation of energy, similar to cooling systems in synchrotrons and linear accelerators, but operates within the same embodiment axially. This design eliminates the need for additional energy consumption for separate condensers, cooling, and heat exchanger systems, thereby preventing overheating and melting of parts of the embodiment. This makes the device more space and weight efficient compared to prior technologies. [0020] The invention features a cooling system at the axial center to cool the device's body and a specific fuel cell tank designed to attract free electrons to the ground-negative pole of the control circuit. This mitigates the risk of overheating, maintaining efficient operation and operational stability according to Joule’s law of heating, unlike thermal management systems in existing accelerators. Unlike prior arts where ionization occurs at the beginning, the present invention allows ionization along the entire path of the tube. This continuous process prevents energy loss, ensuring sustained acceleration and higher efficiency. This feature is supported by the continuous application of electric fields and the principles of charge conservation.

[0021] The system is designed to optimize pressure by further explanation in recycling part, enhancing the stability and speed of the accelerated ions in a cycle. This feature differentiates the current application from existing methods, offering a more sustainable and energy-efficient solution. This design consideration follows the ideal gas law and principles of fluid dynamics. The optimized design reduces energy consumption for creating magnetic fields and accelerations. Additionally, the system can generate electricity through other magnetic fields in different modules, contributing to overall energy efficiency. This aspect is based on Faraday’s law of electromagnetic induction.

[0022] In the acceleration of ionized particles, it is crucial to consider the role of frequency adjustment in physical short-circuit electrodes and the control circuit's function in adjusting the voltage type for each winding layer. This device and its established principles effectively address and clarify misconceptions regarding the magnetic field and the directions of Lorentz and solenoid forces within the embodiment. One such misconception is the belief that in a magnetic field, the energy of a charged particle remains constant. While a static magnetic field cannot change the speed of charged particles, only their direction, Anderson's work demonstrates that a time-dependent magnetic field (frequency in the magnet wires) introduces an associated electric field, which changes both the energy and speed of the particle. This is analogous to frequency regulation in wire voltage: as the magnetic field varies with time, it induces an electric field that can accelerate particles by increasing their kinetic energy. Practical systems often employ varying magnetic fields to create these conditions, which are essential for real- world applications. This understanding contradicts the erroneous notion that electrical bells, valves, or electrical solenoid valves would not function as intended, thereby negating any practical counterexamples from prior arts. The integration of these advanced principles ensures that the acceleration mechanisms within the device are robust, scientifically sound, and highly efficient for various practical applications. [0023] In practical scenarios, wires are rarely perfectly aligned or isolated from external influences. According to Herbert Goldstein’s "Classical Mechanics," system dynamics often involve multiple interacting forces, resulting in a net force along the wire that causes acceleration. Similarly, David J. Griffiths in "Introduction to Electrodynamics" explains that small deviations in alignment or field uniformity can result in nonperpendicular components of the Lorentz force. In this innovation, the winding layers are located in tube-shaped modules with curves and angles in three directions (X, Y, and Z); therefore, the wrapped wires are not aligned in a vertical direction to create an ideal solid and permanent magnetic field. This configuration means that the magnetic fields and induced electric fields interact in complex ways, causing acceleration along the wire according to the Lorentz force law. The curvature and angular placement of the windings leverage the principles of electromagnetic induction to enhance the acceleration process, accommodating practical imperfections and ensuring efficient particle acceleration. This approach underscores the importance of considering frequency adjustments, the control circuit's role, and the practical aspects of system dynamics in achieving optimal performance.

[0024] When a solenoid is energized with electrical current, it generates a magnetic field along its axis. The magnetic field inside a long solenoid is uniform and parallel to its length. Although the solenoid itself does not inherently produce an electric field to accelerate ions, its magnetic field can be effectively utilized in conjunction with an electric field to achieve this. To accelerate ions — increasing their speed rather than merely altering their direction — an electric field is essential. This electric field can be established independently from the solenoid by applying a voltage difference across a region where the ions are present. Additionally, by applying a pulsating current to at least one of the solenoid's winding layers, a pulsating magnetic field can be generated. This pulsating magnetic field interacts with the electric field to push the ions forward in the direction of the electric field. As the ions traverse each segment of the tubular modules, their velocity follows an algebraic linear summation, resulting in continuous acceleration.

[0025] A practical setup involves using at least one electrode and/or the polarity of electrodes to establish an electric discharge field along the ion trajectory, aligned with the solenoid's magnetic field axis and direction. By emitting electrons and positrons from each electrode, an ionic wind is generated within a confined path, akin to the effect of ionic wind thrusters. Unlike conventional thruster devices, this approach uses environmental plasmid fluid as the negative pole that conducts the current at the end of the spiral tubes. These tubes are connected to the negative pole in the central circuit of the fuel cell, creating a differential potential voltage. This setup allows for controlling the fluid speed by adjusting the input voltage of each electrode's transformer/winding layer, providing an alternative method to control the acceleration speed.

[0026] As ions enter this region, they are subjected to the electric discharge field of each electrode, and lamp radiation electrodes, which increases their kinetic energy by ionizing them and causing them to lose more electrons, thereby accelerating them further along the ion fluid direction lines. The solenoid's magnetic field in one of the winding layers is primarily used to confine or steer the ions, guiding them and keeping them focused along the desired path, thus enhancing the efficiency of the acceleration process.

[0027] In particle accelerators (like cyclotrons and synchrotrons), both electric and magnetic fields are used. These devices often use solenoids or other magnetic field sources to manipulate the path of charged particles effectively while using separate mechanisms to accelerate these particles.

[0028] This invention enhances both space efficiency and safety by implementing a specially designed reactor chamber, an optimized self-cooling system for the flow of ions and the device's body, and a customized variable voltage for each self/transformer windings with a spiral shape. This technological breakthrough significantly reduces the input energy demands of power generators, achieving a remarkable milestone in energy efficiency compared to prior technologies.

[0029] This technology can be used in small-scale applications, providing sufficient power generation for individual buildings by itself without needing the external electrical supplier. The low power consumption of both internal and external components is crucial for achieving this being independent to external electricity resources like municipal power supplier compared to prior technologies.

[0030] The invention also encompasses a method that reveals the potential of using more common and noble gases for electricity generation in a highly cost-effective manner compared to prior technologies that rely on expensive and scarce materials like helium-4 and thorium. By utilizing more readily available gases, the method reduces production costs and supply chain constraints, making it a more sustainable and environmentally friendly solution. The device's smaller size compared to prior technologies further lowers production costs and reduces CO2 emissions by minimizing the need for large-scale transportation and heavy machinery. This adherence to carbon footprint guidelines is maintained both during the production of the device and its daily use, reducing reliance on fossil and nuclear power plants. By leveraging these normal and/or noble gas-based energy sources, this innovation significantly contributes to the generation of green energy, promoting a cleaner and more sustainable future. This approach not only enhances energy efficiency but also supports environmental conservation by decreasing greenhouse gas emissions and promoting the use of renewable energy sources compared to prior technologies.

[0031] Furthermore, accelerating the ionized gas may be used in downstream applications for power generation. It is important to acknowledge that the device and method described in this innovation require the proper arrangement and integration of all components and parts to achieve the desired effects. Without proper optimization, the process can experience issues such as flow rate disruptions, blockages, overheating, and potential melting of sensitive components.

[0032] Through the optimization of recycling, cooling design and the rest of arrangement and optimizations, the device can function as an independent power supply at least for itself, and space-efficient power generator or quantum charger. While all of components have to work together harmoniously, there may be exceptions, such as draining free electron before collision point or the need to mix heavy gases and modify the shape of the reactor chamber. These aspects can be adapted or modified to enhance the range of possible reactions and potentially be applied to other existing technologies.

[0033] The invention also encompasses a method that reveals the potential of using more common and noble gases for electricity generation in a highly cost-effective manner compared to prior technologies that rely on expensive and scarce materials like helium-4 and thorium. By utilizing gases such as argon, hydrogen isotopes, and helium, the method reduces production costs and supply chain constraints, making it a more sustainable and environmentally friendly solution. The electrochemical reactions involved include ionization, where electrons are stripped away to create plasma, governed by Coulomb's law and ionization energy principles. Recombination occurs when free electrons, weak atomic cores, and free protons touch and recombine with ions, releasing energy in the form of photons, adhering to the conservation of energy and quantum mechanics. The ionized plasma phase, as seen in tokamak reactors and other prior technologies, is maintained by continuously sustaining ions and plasma, requiring high heating processes to keep the ions/plasma ionized for future electrochemical reactions, such as in cold-fusion or hot-fusion reactors. With the optimization in this technology, the demand for such heating and cost is reduced with it the optimization provided by applying this technology, such as spiral tubes and continuous ionization, reactors can achieve faster output energy generation that surpasses the input energy demand. Additionally, the need for high-speed acceleration, such as those required by Helion or CERN to reach near-light speeds, will decrease using this method, meeting the requirements for cold-fusion devices more efficiently. This is achieved through spiral- shaped tube paths and a unique and gentle process for recycling at the beginning of the process in a shorter loop, with several circulations and repeated ionizations of the fluid/plasma. Simultaneously, the method allows more time for free electrons released in the ionization process to be absorbed and added to another circuit. This was not possible or optimized in prior art, but this technology, with its circulation and longer spiral path, can manage this and improve the conditions for the fusion reaction. This represents a significant optimization over previous technologies. An axial central cooling capsule is added to protect components from melting during long-term device operation. This current method and technology can optimize existing devices or technologies by integrating its components, leading to significant improvements in performance and energy efficiency.

Summary of Invention

[0034] We have named this comprehensive methodology package "Magnetic field generation - Electricity production - Tesla coil by several winding layers to produce a magnetic field and self-induction by flow of ions in each path and self / high voltage transformer windings in in parallel and series connection simultaneously in one embodiment please requirements- Acceleration by magnetic field - Circulation/ recycling by spiral circulation tubes in an axial capsule heat exchanger - Ionized with electric discharges at all the path tubes - Orbitals of each atom lose more electrons in each circulation - Plasmid maintains active with lower temperature demand," abbreviated as "M.E.T.A.C.I.R.O.P." This name encapsulates the essential elements and physical laws integrated into this technology, each playing a significant role in this application. Further descriptions elaborate on each component's role and importance. For simplicity and ease of reference in current documents, we call it METACIROP.

[0035] For extra clarity of some terms used in this application, the prefix "semi" is adapted from the term "semiconductors." In this context, it signifies that the subject possesses a complex definition that is not entirely one thing or another, much like how semiconductors exhibit properties between conductors and insulators. For example, the terms "semi arc," "semi fusion,” indicate that these processes are not complete fission or fusion reactions. Similarly, a "new half-arc/discharge" described as a semi arc is not a complete arc or corona discharge but rather involves additional principles or mechanisms. These phenomena are fundamentally different from their fully realized counterparts. They share common characteristics in understanding or visibility but involve an intermediate or interstitial process. For simplicity and ease of reference in current documents, the inventor refers to these as "semi-fusion" or "semi arcs" to emphasize the nuanced differences and the potential for varied outcomes in these processes. This approach highlights the innovative aspects and the possibilities inherent in the subject, distinguishing it from traditional definitions. [0036] In this method and embodiment, the importance of a spiral shape, rather than a straight design where the collision point is uncertain and controlled by a magnetic field with high energy consumption in the middle of two opposite straight tubes in most prior arts, or possible edges and acute-angled tubes, is to avoid the collection of ions at high speeds at the edges, this accumulating can cause overheating or accumulate high energy, posing a danger of tube explosion. Additionally, tubes designed with round spiral shapes can manage gas or material expansions in a closed loop by providing the necessary flexibility. This flexibility, along with the benefits of the spiral design, is further explained in the following sections.

[0037] The continuous ionization within a spiral-shaped tube ensures that ions remain sufficiently active to undergo the desired reactions without needing elevated temperatures to maintain their ionized state. The necessary kinetic energy is achieved through various ionization methods in the tube, such as electrode discharge and wave radiation, including UV rays or other types of radiation like alpha, beta, or gamma rays possible released from the reactor chamber. This ionization process causes each atom to increase its kinetic energy and lose more electrons, according to ionization energy principles. The efficiency of this process depends on the number of circulations and the significant volume of ionized gas moving through the tube. As the ionized atoms or plasma continue to circulate, they gradually gain higher speed because the electrons, having less mass, are more easily accelerated by the same magnetic force. This process is in accordance with Newton's Second Law of Motion (F=ma) and is further enhanced by additional forms of energy such as kinetic energy and heating, which increase motion and velocity of atoms, thereby helping to achieve more acceleration speed.

[0038] A continuous and varied level of ionization process plays a crucial role in each atom losing electrons from its orbitals. This ionization process must be controlled by a control circuit and physically designed at specific points along the tube path by determining the number and placement of each winding layer. For example, at the beginning of the tube, lower ionization energy is required, whereas near the reaction chamber, higher ionization energy is needed. According to quantum mechanics, removing electrons from lower energy orbitals requires more ionization energy. This principle aligns with the concepts outlined by the Schrodinger equation and the quantum mechanical model of the atom.

[0039] For example, radon's electrons in the first upper orbital are lost more easily due to lower ionization energy requirements, while ionizing a lower orbital requires more input energy, as indicated in the ionization table. By losing more electrons, the atom becomes unstable and larger, which is necessary for fusion reactions. This instability allows the atom to accept more protons from external ionized atoms, changing its content to other atomic specifications in a shorter time. Since this reaction is weak and unnatural, with lower acceleration speed, controlling the process increases the chances of achieving more sustainable chemical reactions. In the reactor chamber, a considerable number of electrons (exact number depending on the ionization conditions) and protons are involved. The electrons are absorbed or drained by electrochemical electrodes, leaving the radon atom with an increased number of protons as it continues to circulate. This process enhances the efficiency of the reaction by maintaining a higher proton count within the radon atom throughout the cycle of circulation — an aspect often ignored in prior research.

[0040] For another example, consider two 10-gram balls moving towards each other in a tube at 10 m/s. When they collide, their relative speed is 20 m/s. According to the conservation of momentum, if they have equal mass and a perfectly elastic collision, they will rebound with their velocities reversed. For inelastic collisions, they might stick together, moving with zero velocity due to the initial momentum cancellation.

[0041] In another scenario, two 100-gram balls follow the 10-gram balls with the same or lower speed. When these larger balls collide with the smaller ones, they exert additional force on them. The pressure exerted by the larger balls on the smaller balls can be calculated using the formula P=F/A, where F is the force and A is the area of contact. Given the larger mass of the 100-gram balls, the force F=m.a (with a being the deceleration upon and magnetic field collision) will be significantly higher.

[0042] To quantify the pressure difference, assume the deceleration (a) is the same for both cases. The force exerted by a 10-gram ball would be F10g=10gxa. For a 100-gram ball, the force would be F100g=100gxa Therefore, the pressure exerted by the 100- gram ball is 10 times greater than that of the 10-gram ball. If the contact area (A) is constant, the pressure increase can be expressed as follows: Pressure by 10-gram ball: P10g=F10g/A, Pressure by 100-gram ball: P100g=F100g/A=10xP10g

[0043] This represents a 900% increase in pressure exerted by the larger balls compared to the smaller ones. If the smaller balls are made of soft material, this additional pressure (referred to as "pressure lever") will compress and flatten them, potentially merging them due to the plastic deformation.

[0044] another example, Now considering the small balls as hydrogen ions (mass of approximately 1.67 x 10^A-27 kg) and the larger balls as radon ions (mass of approximately 3.65 x 10^A-25 kg), the mass difference is substantial. A radon ion is roughly 218 times more massive than a hydrogen ion. This mass difference means the pressure exerted by the radon ions on the hydrogen ions will be much greater than the previously calculated 900% increase. Specifically, the radon ions would exert pressure that is approximately 21,800% greater (218 times the pressure) than the pressure exerted by hydrogen ions on each other. [0045] Given this immense pressure difference, the probability of fusion increases significantly. If the initial chance of fusion is 1 per 10 billion collisions (l x 10^A-10) per frequent circulation, the increased pressure by radon ions enhances the collision force and energy, thereby increasing the fusion probability. If we estimate the enhancement factor due to pressure increase, we could consider it proportional to the pressure ratio. Thus, the fusion probability could be increased by a factor of approximately 21,800, making the new probability roughly 2.18x10-62.18x10-6, or about 1 in 460,000 collisions. This translates to an approximate increase of 2,180,000% in the probability of fusion.

[0046] The spiral shape of the tube circulates the ions, ionizing those multiple times, ensuring they remain sufficiently active to undergo the desired reactions without needing elevated temperatures to keep them ionized or in a plasma state. Achieving the necessary kinetic ionization energy for each ionized atom depends on the number of radiations or discharges in the tube, several circulations, and the significant volume of ionized fluid gases in motion. This motion is achieved by two methods and has several effects on the system, as explained in the description section. This process can generate electricity in one of the winding layers and increase the gas volume's speed. This high-speed motion and electron drainage may not be possible in a short linear tube, but it can definitely be achieved in a curved tube (X, Y, or Z direction) within several consecutive magnetic fields generated by at least one of the winding layers. The spiral shape allows for better multiple and frequent circulations and ionizations, ensuring the ions remain active and increasing the efficiency of the system.

[0047] Regarding the acceleration part, in classical physics, this acceleration by a solenoid magnetic field is visibly evidenced in controlled circuit boards on each coil with one winding layer in a certain and sealed moving path, such as with metal bullet ball that can be polarized. In the industry, it is known that the ball gains momentum and added velocity in each tube. Similarly, in this method, the smart control circuit can create the magnetic field in each winding wire layer by sending control signals at different frequencies. This setup allows for precise control and acceleration of the ionized gas, enhancing the overall efficiency and effectiveness of the system.

[0048] According to quantum physics, neutral gases are not affected by a magnetic field. However, when a gas is ionized, it can be effectively manipulated and accelerated within a magnetic field generated by a winding layer. This principle is utilized in existing technologies, where ionized gases are accelerated using magnetic fields. By ionizing the gas, it becomes responsive to the magnetic field, allowing it to be polarized and accelerated efficiently. This process is crucial for applications such as fusion reactors and particle accelerators, where ionized gases need to be controlled and manipulated to achieve the desired actions and reactions. [0049] In this device and method, the circuit control (e.g., frequency regulator/pulsing) can create the magnetic field in each winding wire layer by sending control signals at different frequencies and voltage in each winding to be pulsed or permanent in different scenarios in each tube segment or winding layer. This setup allows for precise control and acceleration of the ionized gas, enhancing the overall efficiency and effectiveness of the system. The control circuit can be a smart control circuit that generates signals to create different magnetic fields in each tube with varying power and frequency to accelerate the speed of the plasmid or stop them by reverse current and frequency in high-risk situations. It can also increase or decrease the speed in different winding layers, ensuring optimal performance and safety. Additionally, the control circuit can apply stronger signals to create stronger magnetic fields in the environment of tube parts near the reaction chamber, creating narrower paths for the plasmid flow. This achieves higher velocity and a sharp, narrow flow for the next part of the reaction chamber, like a waterjet cutter, to increase the chances of possible fusion/ semi-fusion reactions or atomic collisions. These concepts are explained in more detail in the following sections.

[0050] This method offers significant advantages due to its use of multiple winding layers and the liquid flow recycling frequently, with some windings in series and others in parallel, as illustrated in the drawings and figures. This setup allows the creation of electrical voltage through induction and self-induction processes. The compact design, featuring a smaller pipe or tube compared to prior arts, facilitates a significant flow of ionized fluid or particles through the tube and its winding layers. This movement generates a magnetic field, and according to Faraday's law, these polarized particles create a magnetic field in certain winding layers, inducing the movement of electrons and generating electricity. As the flow of particles increases, so does the movement of electrons in the winding layer.

[0051] Meanwhile, the solenoid magnetic field effect creates a path that guides the plasma flow, preventing it from hitting the tube walls and losing its content. This controlled movement ensures the ions remain active and directed, enhancing the efficiency of the fusion reaction.

[0052] The device can use this self-generated voltage for long-term operation, such as batteries, powering pumps, LEDs, or feeding transformer winding layers in series with longer wires to create high voltage for ionization discharges. As the ionized fluid passes through each tube segment and magnetic field, each segment adds momentum and increases velocity within the magnetic field around the tube. This process allows the ionized fluid to keep moving through the cycle of tube paths frequently, creating thrust and an atomic wind, as explained further in the description. Additionally, this movement generates low voltage electricity independently of whether a fusion reaction is happening, which is why the device can function as a quantum battery by itself, without the apparatus over heating in a safe operation.

[0053] A potential difference is generated by the control circuit and external circuit, resulting in the production of electrical current in the winding's wire. This simultaneous process of flow movement, ion acceleration, and current generation significantly impacts the functioning of various energy conversion and power generation devices, enabling multi-power generation capabilities even if fusion does not occur at the beginning of the device's circulation. Additionally, the potential difference created between the reactor and external consumers is essential to keep the device up and running in the desired operation. This connection with the external circuit and the drainage of electrons from ionized atoms enhances the system's efficiency and effectiveness, preventing the ions from returning to a stable atomic state and keeping them active. This approach ensures that the device can achieve its desired results and, at the very least, provide energy for itself without needing a permanent external power supply from numerous large capacitors or municipal electricity sources or individual power plant supplier, unlike prior arts in this field.

[0054] By transitioning from a linear path to a closed-loop and spiral tube path, or curved tubes in the shape of an infinity symbol, it becomes possible to maintain the long linear distance for the fluid flow while significantly reducing the spatial length requirements. From a physics and geometry perspective, this design modification allows for a continuous and extended path within a confined space, enhancing ion movement and acceleration efficiency. The curved geometry minimizes the risk of ion collisions with the tube walls and provides a controlled environment for the magnetic fields to optimize ion acceleration. This innovative approach ensures efficient ion dynamics and energy transfer within a more spatially compact and safe design for the process.

[0055] To mitigate the risk of undesired reactions over time, it is important to address the instability that arises as atoms or molecules acquire positive or negative charges through electron gain or loss. The core of such electron-deficient or electron-rich molecules becomes increasingly unstable, often leading to uncontrolled chemical changes and rapid collisions that result in undesirable reactions. This poses challenges for common applications and smaller devices, such as those used in homes or small factories that attempt to improve and optimize them in current designs. To address these challenges, a control unit is required to manage the reaction and the entire process. Additionally, a heat exchange unit is necessary to control temperature, and a reactor chamber is employed to prevent electrochemical reactions that can lead to core disintegration or nuclear fission, both of which are types of uncontrolled electrochemical reactions. [0056] However, by introducing an opposing flow of loosen atoms and/or identical ions, collisions can occur, allowing for the repair or merging of electron clouds or cores with a relatively low probability. Achieving the required speed for such interactions is demanding. The specialized shape of the reactor chamber aids in concentrating the volume of ions and molecules, exerting pressure, or guiding them towards better connections, thus facilitating the desired interactions at slightly lower speeds. This embodiment allows for the management of various forms of energy acquired within the reactor, transforming them into kinetic energy and ionization during the acceleration process to generate electricity and voltage in wires or direct them towards a boiler and turbine.

[0057] The inherent nature of gases makes achieving linear acceleration in their natural state challenging. Therefore, the process of ionization becomes crucial to facilitate acceleration. However, in recent years, the size of the device body and its components and gases costs, and initial power consumption of the device has posed a significant challenge, resulting in increased costs and reduced interest from potential consumers.

[0058] By transitioning from a linear path to a closed-loop and spiral tube path, or curved tubes in the shape of an infinity symbol, it becomes possible to maintain the long linear distance for the fluid flow while significantly reducing the spatial length requirements. From a physics and geometry perspective, this design modification allows for a continuous and extended path within a confined space, enhancing the ion movement and acceleration efficiency. The curved geometry minimizes the risk of ion collisions with the tube walls and provides a controlled environment for the magnetic fields to optimize ion acceleration. This innovative approach ensures efficient ion dynamics and energy transfer within a more compact and spatially efficient design.

[0059] Continuous ionization in a linear or looped path is essential for maintaining control over ionization and discharge. A smart control circuit that determines the location and amount of electric discharge required is crucial for controlling subsequent reactions, as evidenced by prior art and other innovative devices. The size and weight of a variable high voltage, High-Frequency transformer presents challenges in achieving the desired voltage and frequency for each level of ion reaction while maintaining continuous flow. If the ion flow is low and the ionization guns release the same amount of energy as before, it can lead to excessive heat and uncontrolled, risky reactions within the gases and device body. Conversely, if the ion flow is too fast, ionization efficiency decreases, acceleration reduces, and the flow rate drops suddenly, resulting in variable released voltages from the windings.

[0060] Continuous ionization along the entire length of the tube is crucial, with the ability to control the voltage of each ignition and/or discharge electrode. The size and weight of the device and its components pose significant challenges. It is essential to develop a compact and space-efficient design that can accommodate the required number of windings for ionization and acceleration. By integrating multiple separated winding layers within the body of the gas tube, it is possible to use the same body as a low/ high voltage transformer and an acceleration unit simultaneously. This approach helps reduce the size and weight of the power generator device in the quantum technology model and allows for the utilization of transformer spaces for other electrical components such as batteries or electronic components. The interconnected nature of the device's components, with the magnetic fields of the puzzle-shaped container’ s winding layers charging and resonating with each other, contributes to its functionality.

[0061] Moreover, by transitioning from a linear path to a closed- loop and spiral tube path, or curved tubes in the shape of an infinity symbol, it becomes possible to maintain the long linear distance for the fluid flow while significantly reducing the spatial length requirements. This design modification allows for a continuous and extended path within a confined space, enhancing the ion movement and acceleration efficiency. The curved geometry minimizes the risk of ion collisions with the tube walls and provides a controlled environment for the magnetic fields to optimize ion acceleration. This innovative approach ensures efficient ion dynamics and energy transfer within a more compact and spatially efficient design.

[0062] By using more than one winding layer, as explained before, the transformer winding can efficiently generate and manage the required high voltage and frequency, ensuring continuous and effective ionization and acceleration. The smart control circuit's ability to adjust electric discharge based on ion flow maintains the necessary balance to prevent excessive heat and uncontrolled reactions. This integrated and compact design enhances the device's overall efficiency and effectiveness, making it suitable for various energy conversion and power generation applications.

[0063] Another approach to generate low voltage current involves addressing the heat variation among the reactor tubes' bodies. By utilizing transformers/tubes as primarily hot and axial-middle heat exchanger capsules as primarily cold, and with the assistance of Thermoelectric cooling components, it is possible to obtain low voltage output. This low voltage output can be produced by one of the windings and magnetic fields or by the Thermoelectric cooling electronic component, which charges certain batteries or other high voltage windings in series or parallel.

[0064] For another instance, consider a small apparatus that operates with a 12V, 10A input, equivalent to a 120W power supply. This device is capable of charging batteries or providing an output of 12V at 100A, which equals 1200W. This results in an output power that is 1080W greater than the input power. Consequently, this discrepancy allows for the generation of additional electricity, effectively providing an extra 1080 watt-hours of energy. To understand the difference between watt-hours (Wh) used in batteries and regular municipal power measured in watts (W), it is essential to grasp that watt-hours measure the total amount of energy consumed over time. One watt- hour is equivalent to using one watt of power for one hour. For instance, a battery with a capacity of 1200Wh can theoretically provide 1200W of power for one hour or 600W for two hours, and so on. The duration for which a battery can provide power depends on its capacity (measured in watt-hours) and the power consumption of the connected devices (measured in watts). For example, if a battery has a capacity of 1200Wh and is used to power a device that consumes 100W, it can theoretically provide power for 12 hours (1200Wh / 100W = 12 hours). This surplus energy generated ensures that downstream batteries or connected consumers remain sufficiently charged, enhancing the overall efficiency and reliability of the power management system. By leveraging such efficient energy management, systems can maintain consistent power supply and potentially reduce dependency on municipal or extra power sources.

[0065] The invention relates to a multi-power generating or quantum charger method unit comprising an arrangement for a selective continuous acceleration and ionization process of a fluid in a closed loop with a high circulation rate along the entire spiral transit route. The fluid may be in a gaseous state when subjected to acceleration and ionization, making it space-efficient and safe due to the specific reactor chamber shape and cooling system. As a result of this technology, input energy demand on power generators is significantly reduced, reaching a milestone point in energy efficiency.

[0066] In one possible process gases feed example, the fluid used can consist of a single gas or a mixture of gases, which may include light and/or heavy molecules, depending on the desired composition. The gas could be a Noble gas such as Argon or a combination of Noble gases with hydrogen isotopes or helium in their normal phase or isotopic forms.

[0067] In another example, the process feed can involve a combination of three inlet gases: H2O (g) water vapor, H2 (g) hydrogen, and 02 (g) oxygen, or their isotopes. Alternatively, a different combination of gases can be used, such as He (g) helium, Ar (g) argon, and Rn (g) radon, as the three inlet gases.

[0068] These examples illustrate the flexibility in choosing the composition of the fluid used in the process, allowing for different gas combinations to achieve specific objectives.

[0069] Radon, or other heavy gases, offer distinctive advantages within the power generation process. Firstly, heavy gases such as Radon possess two remarkable characteristics that enhance their effectiveness. Their innate heaviness makes them function as potent pressure levers when they collide with lighter ionized atoms, exerting force and compressing them. This compression generates countercurrents and effectively reduces the required acceleration rate for fusion reactions. [0070] Heavy gases like Radon offer distinct advantages in power generation. Their inherent heaviness allows them to function as potent pressure levers, compressing lighter ionized atoms and reducing the required acceleration rate for fusion reactions. Additionally, these gases efficiently acquire free electrons, enhancing ionization efficiency and minimizing energy demand. Leveraging these unique attributes, heavy gases optimize the fusion reaction process, improving overall effectiveness and efficiency in power generation. Another notable advantage of heavy gases is their ability to efficiently acquire and release more free electrons during the ionization process. Due to their high electron content, these gases facilitate electron acquisition with remarkable ease, thereby enhancing ionization efficiency and reducing the energy demand for ionization. This advantage enables smoother and more efficient power generation.

[0071] It is worth noting that radon is a toxic gas commonly found in the open air and in older homes, posing a significant health risk and being costly to remove. However, by harnessing radon as a raw material in the energy industry, we can turn this hazardous waste into a valuable asset. Using radon for energy generation not only consumes and transforms it but also makes it more beneficial for advanced treatment and filtration devices with unique filters, or for large-scale industrial applications. By leveraging radon, we address environmental concerns head-on and provide a sustainable solution. This green earth approach highlights an innovative and eco-friendly way to repurpose a dangerous pollutant, demonstrating how we can turn a problem into an opportunity within the energy sector.

[0072] In the described process, the presence of helium, as a noble gas, within the reactor chambers along the spiral route plays a specific role in the heating of matter. When electric discharges, semi-arcs, or arcs occur inside these chamber tubes, thermal energy is generated, causing the temperature to increase. However, the presence of a small amount of helium within the reactor chambers helps to moderate the heating of the matter, specifically affecting the electrons and cores of the atoms. This targeted heating occurs in such a way that the ions and electrons in the gas mixture are more impacted by the generated heat, while the atoms themselves experience minimal temperature increase. As a result, the overall temperature of the core or nucleus of the gaseous mixture does not significantly rise. However, the excitation level of the electrons increases, leading to a targeted ionization and acceleration process. By maintaining a specific concentration of helium within the chambers, the heat generated primarily affects the ions and electrons, promoting the desired ionization reactions while minimizing temperature increases in the atomic nuclei. This targeted heating mechanism ensures that the ionization process occurs in a controlled and efficient manner. [0073] In another example of an ionization and acceleration unit, the primary objective of the invention is to develop a power-generating unit that operates based on the ionization and acceleration of a fluid flow. This is achieved through the utilization of the solenoid magnetic field phenomenon. When molecules are ionized, they become polarized and susceptible to the forces exerted by the coil windings within the magnetic field, resulting in the acceleration of the ions. It is important to note that in its normal phase, a gas atom does not experience the effects of the magnetic field force and therefore does not undergo acceleration. However, through the process of ionization, the gas molecules transform into ions and become responsive to the forces within the magnetic field, enabling their acceleration. The objective is achieved through the implementation of a quantum power generating unit or a self-contained charger unit. The power generating unit comprises seven key components: a first tube- shaped structure designed to facilitate the flow of fluid, which can be a gas or a liquid, through the unit; an arrangement for acceleration and ionization responsible for accelerating and ionizing the fluid as it passes through the first tube-shaped structure, achieved through various means such as electromagnetic fields or other suitable methods; a reactor with a first inlet connected to the downstream end of the first tubeshaped structure that receives the ionized fluid flow, where electrochemical reactions take place in a reactor chamber created by the ionized fluid flow; two electrochemical electrodes positioned in a spaced relationship within the reactor chamber, where the first electrode functions as an anode, releasing electrons to an external circuit, and the second electrode serves as a cathode, acquiring electrons from the external circuit during the electrochemical reaction. Additionally, a control circuit is employed to create, control, and regulate the electric potential difference, provided by total electric structure and control circuit unit such as electric current (AC or DC) in each wire of a winding layer, and electricity/ electron in wires movement path direction within the system, simultaneously affecting the winding layers with different signals and frequencies that influence the magnetic fields of each tube path. As shown in the figures, the AC current can also be created by Tesla coil part-short circuit electrodes mechanically, without needing to use numerous sensitive electronic components in the control circuit package. Overall, this power generating unit allows for the controlled generation of electricity through the utilization of accelerated and ionized fluid flow, along with the facilitation of electrochemical reactions in the reactor chamber. The control circuit ensures precise control and regulation of the electrical parameters within the system.

[0074] In another example of a Self / low voltage transformer tube, the traditional external High-voltage, High-Frequency transformer winding layers typically used in the ionization process are replaced by the curved shape of the tubes. The tubes are equipped with at least two layers of windings, resembling a Tesla coil setup, which generates magnetic fields around the tubes and creates high voltage in the wire windings, as shown in the figures. Instead of using short-circuit electrodes to discharge as a capacitor’s component, these electrodes can be replaced with transistors or other suitable components in the control circuit. This design modification and the replacement of components with onboard elements in the tube’s embodiment structure reduce the weight and increase the space efficiency of the device.

[0075] In this power generator device, the various components are interconnected and influence each other's magnetic fields. The arrangement of the tube-shaped windings, resembling puzzle pieces, creates magnetic fields that charge, resonate, and influence the adjacent coils or windings. Each individual component alone may produce a voltage that is too low for the device's requirements, but in series connection, the windings can collectively achieve the necessary voltage.

[0076] To fulfill this requirement, the winding can be extended across multiple tube-shaped puzzle parts, facilitating an increase in voltage with more wrapped winding numbers or by reducing them in some tube puzzles. This extended winding can be connected to the low-voltage output line of the control circuit, typically ranging from 1 to 24 volts and suitable for powering internal consumers or standard batteries. Alternatively, the extended winding can be linked to a high-voltage electrode situated within one of the tube holes. By employing multiple windings in series, the self-induction effect generated by the ionized particles passing through each winding layer can contribute to further voltage enhancement, as shown in the figures.

[0077] This configuration provides enhanced control and manipulation of the voltage levels within the device. This design approach improves the voltage output and ensures that the device receives the necessary input voltage for optimal operation. It also promotes a lighter and more space-efficient device compared to traditional external transformers. In another example, a winding can be extended along multiple tube- shaped puzzle parts within each tube, connecting them to one another. This extension of the winding allows for an increase in voltage. The increased voltage can then be connected to the low-voltage output line of the control circuit or linked to a high-voltage electrode within one of the tube holes. This arrangement ensures that the required voltage is supplied to the device for its operation.

[0078] In a further example, each winding layer of the tubes or coils induces another winding layer with a different or similar resonance frequency. This arrangement ensures that the magnetic fields are supplied to each required slot continuously and efficiently. Additionally, the spiral shape of the tubes replaces the need for a normal external low voltage, Low-Frequency transformer. The accelerated polarized ions within the tubes simultaneously create kinetic energy within at least one of the windings' magnetic fields, following Faraday's law of electromagnetic induction.

[0079] These examples highlight the use of extended windings, resonance frequencies, and the spiral shape of the tubes to optimize the voltage output, magnetic field generation, and overall efficiency of the power generation device. In another example, achieving the necessary kinetic energy by ionization of ions requires a significant volume of ionized gases moving at high speeds within a magnetic field generated by at least one coil or winding layer. As the ions move within the magnetic field, a potential difference is created, resulting in the generation of electrical current in the winding and simultaneous ion acceleration. This process is facilitated by the circulation of ions in a closed-loop path.

[0080] In a further example, two Self / transformers windings, which are tube-shaped puzzle parts equipped with multiple windings and separated magnetic fields, are designed to have the same natural frequency and be identical. By placing these self-transformers adjacent to each other in close proximity, their frequency cycles become synchronized over time during operation. This synchronization occurs spontaneously as the transformers are turned on and influenced by each other based on Hertz and frequency laws. Alternatively, means can be provided to actively control the synchronization, such as incorporating one-way diodes in the path of each exit terminal to ensure the current flows in the same direction, aligning the sinus or cosine wave in the control circuit. This synchronization enables the creation of individual electric discharge / semi-arcs at one of the electrodes, optimizing the performance of the power generation device. It is worth noting that the device incorporates tube-shaped self-transformers, eliminating the need for additional external transformers. These self-transformers have the capability to increase the voltage and frequency on their own.

[0081] For another example, through the employment of an array of forty cylindrical self-transformer windings with several layers connected in a series configuration, it becomes possible to escalate both the voltage and frequency to substantial levels — up to 300 kV and 100 kHz, respectively. Such elevations can be further amplified as needed, particularly when dealing with lighter atoms like Hydrogen (H) or Helium (He). These atoms require substantial ionization energy to achieve atomic ionization, enabling them to release one or two electrons situated in their singular spin orbital. Additionally, this apparatus can cater to the secondary or tertiary ionization energy requirements inherent in denser gases. This process exemplifies the concept of selective or programmed ionization at the requisite level.

[0082] In another configuration, the device includes at least four separate winding layers, with two of them dedicated to generating lower voltage (around 4 to 7 kV) and a frequency of 22 kHz, specifically for selective ionization purposes. The remaining winding layers can be utilized to generate higher voltages. This means that, for example, with the use of ten tube-shaped self/ transformers winding layers, there are 65,536 possible arrangements of winding wires in series and parallel, providing greater flexibility in voltage and frequency output.

[0083] This configuration enables the device to generate alternating current (AC) or direct current (DC) high voltage for each electrode while concurrently producing a stable or pulsating magnetic field. This magnetic field can have varying effects on the exterior of the spiral tube structure, influencing other modules or objects. Internally, within the inner tube, it can accelerate ions using different principles such as Maxwell's equations and the Lorentz force, as previously described. Furthermore, some of the winding layers can become inductively charged through Lenz's law and the operation of a Tesla coil device in other winding layers within parallel tubular containers. A Tesla coil operates on the principles of electromagnetic induction and resonance, producing high-voltage, low-current, High-Frequency alternating current. This High- Frequency AC can induce currents in nearby conductive objects, illustrating wireless energy transfer and the potential for efficient power distribution. By leveraging these principles, the Tesla coil can generate high voltages that create strong electromagnetic fields. These fields can inductively charge winding layers, providing low voltage power for internal electrical components. This process reduces the overall power demand on its batteries and control circuit. This sophisticated design enhances the efficiency of the device by harnessing electromagnetic principles to optimize energy use. The ability to create high voltage and manage magnetic fields effectively allows for versatile applications, including influencing adjacent modules or accelerating ions within the device. Additionally, the inductive charging of winding layers contributes to lower power consumption from the primary power sources, ensuring a more sustainable and efficient energy management system. In summary, the integration of Tesla coil phenomena and its underlying physical principles — such as electromagnetic induction, resonance, and Maxwell's equations — enables the device to achieve superior performance. This results in efficient high-voltage generation, effective magnetic field management, and reduced dependency on primary power sources, promoting a more sustainable and reliable energy solution.

[0084] In a possible scenario utilizing DC high voltage mode, the smart control circuit organizes all the Self tubes container shaped /transformer windings. A special condition occurs where, without the acceleration of ions or a pulsating magnetic field with high frequency, the frequency becomes zero, resulting in DC voltage and a stable magnetic field. The ionized gases become polarized by the magnetic field in the tubes, and from each discharge electrode in the system (comprising numerous electrodes in the spiral embodiment), all electrodes emit electrons (acting as positive discharges) but do not accept them. With a negative pole (a permanent electrochemical electrode to drain electrons to other circuits) in the reactor chamber (e.g., egg-shaped), a current is generated. The potential difference between these numerous discharge electrodes and the negative pole in the embodiment helps the ions start to move in this closed and sealed loop. This condition creates an ionic wind with a mechanism similar to a plasma thruster device, following similar principles and physical laws. In this scenario, the device and embodiment can function without needing high acceleration to create electrochemical reactions in the reactor chamber, such as fusion. The permanent motion of the ionized flow in the axial direction of the tubes toward the middle part of the embodiment (egg-shaped) generates a magnetic field. According to Faraday's law, this creates electricity in one of the winding layers.

[0085] In a possible scenario, Even the shown gas pump in this embodiment can assist in creating this flow movement, demonstrating hybrid functionality for multiple tasks. This condition creates an ionic wind with a mechanism similar to a plasma thruster device, following similar principles and physical laws. In this scenario, the device and embodiment can function without needing high acceleration to create electrochemical reactions in the reactor chamber, such as fusion. The permanent motion of the ionized flow in the axial direction of the tubes toward the middle part of the embodiment (egg- shaped) generates a magnetic field. According to Faraday's law, this creates electricity in one of the winding layers. This is another example and reason this device can work as quantum batteries, whether or not fusion occurs.

[0086] This flexibility in voltage and frequency output that create by physical components or electrical components in control circuit box enables precise control over the ionization and create movement motion in flow liquid also acceleration of them in described processes, enhancing the efficiency and effectiveness of the device. The ability to manipulate the magnetic field and voltage outputs allows for a variety of applications, ensuring optimal performance in different operational scenarios.

[0087] In one embodiment example puzzled parts (Tubes-shaped containers), the first tubeshaped structure of the power generation device is designed in a spiral shape, forming a continuous curve with a constant diameter around a central axis. This configuration allows for the efficient extraction of loosely bound electrons from the core due to the inertia force and the high-speed fluid flow at the outlet end of the structure, aided by the centrifugal force in tube- shaped structures. The diameter of the first tube- shaped structure typically falls within the range of 200-1000 mm.

[0088] Furthermore, the first tube-shaped structure extends for at least 360° (one complete turn), preferably at least 720° (two complete turns), and can include multiple turns. This extended length enhances the interaction between the fluid and the magnetic fields generated by the winding, leading to increased ionization and acceleration. [0089] In a particular embodiment example, the first tube-shaped structure consists of a series of containers arranged in sequence. Each container has a curved extension forming an arc of a circle when viewed in the direction of the central axis. The angle of curvature for each container typically falls within the range of 10°-90°, preferably 20°-60°. This design ensures a smooth flow path for the fluid and enhances the efficiency of ionization and acceleration.

[0090] It is further advantageous for the containers in the spiral structure to have a similar general shape and dimension. This uniformity facilitates a consistent fluid flow and magnetic field interaction throughout the entire structure, optimizing the power generation process.

[0091] To ensure structural integrity and withstand the stresses caused by long-term operation, the spiral-shaped structure is designed with a circular cross-section and a flexible longitudinal shape. This flexibility allows the structure to accommodate expansion and contraction of gases without bursting, even at elevated temperatures and pressures.

[0092] Between two adjacent containers, a fluid conveying connection element is included. This connection element comprises a fluid conveying channel that facilitates fluid communication between the containers, ensuring a smooth and continuous flow throughout the spiral structure.

[0093] In one example, the ionized fluid conveying connection element within the power generation unit is designed to guide a portion of the incoming fluid flow in a circumferential direction to one of the containers located downstream in the fluid flow direction. This arrangement ensures a smooth and continuous flow of the fluid throughout the spiral structure.

[0094] The fluid conveying connection element includes flanges at both ends in the axial direction, allowing for mechanical connections to be established with the adjacent containers. These flanges provide stability and secure attachment between the components.

[0095] Each container in the spiral structure has an elongated shape, with an inlet for fluid entry located near the first end in the longitudinal direction and an outlet for fluid exit located near the second end in the longitudinal direction. This design facilitates the efficient flow of the fluid through each container.

[0096] In another embodiment example, at least one of the elongated containers may have a shape where the central axis extending along its longitudinal direction follows an arc. The diameter of this arc matches the diameter of the spiral shape formed by the series of containers. This alignment ensures a seamless flow transition within the structure.

[0097] Furthermore, at least one of the elongated containers may have a circular crosssection, perpendicular to its longitudinal direction. This circular shape aids in maintaining a consistent fluid flow and supports efficient ionization and acceleration processes.

[0098] The outer surface of the elongated container typically has a diameter ranging from 10-50 mm, with dimensions of 10-30 mm or preferably 15-25 mm. These dimensions have been determined to offer high ionization efficiency while maintaining costeffectiveness and a long lifespan of the ionization device.

[0099] The length of each elongated container falls within the range of 50-200 mm in the longitudinal direction. These dimensions facilitate easy manufacturing using methods such as metal casting, metal 3D printing, or precise molding, while also allowing for convenient maintenance.

[0100] Additionally, the power generation unit may include a second tube-shaped structure designed to convey a second fluid in a fluid flow. The reactor in this configuration is equipped with a second inlet, connected to the downstream end of the second tubeshaped structure, to receive the ionized fluid flow.

[0101] The first and second inlets are positioned in opposite directions to each other within the power generation unit. This arrangement causes the first and second ionized fluid flows to meet each other from a counter-current direction with homogenous acceleration.

[0102] The first and second tube-shaped structures are arranged parallel to each other, with their central axes aligned. In another embodiment example, they are located on opposite sides of the reactor, ensuring symmetrical placement and efficient operation.

[0103] Furthermore, the second tube-shaped structure shares the same shape and dimensions as the first tube-shaped structure, maintaining consistency and coherence in the overall design.

[0104] In a further embodiment example, a spiral return line, the reactor within the power generation unit is equipped with at least one outlet to release the fluid after the electrochemical reactions. The power generating unit includes at least a first return line that connects the outlet at one end and the upstream end of the first tube- shaped structure at the other end, establishing fluid communication between them.

[0105] Preferably, the reactor is equipped with two outlets, and the power generating unit comprises a first return line connected to the first outlet and a second return line connected to the second outlet. Both return lines extend from their respective outlets to the upstream ends of the tube- shaped structures.

[0106] The first return line forms a spiral shape with a smaller diameter compared to the spiral formed by the first tube-shaped structure. It is positioned radially inside the first tube-shaped structure. This configuration allows the fluid to circulate in a controlled manner, driven by hydraulic and thermodynamic pressure from the top to the bottom of the reactor. The acceleration of the fluid in the return pipe also creates a negative pressure that aids in the fluid circulation.

[0107] Overall, these arrangements facilitate the continuous flow and recirculation of the fluid within the power generation unit, optimizing the efficiency of the ionization and electrochemical reactions processes.

[0108] In a further embodiment example, a Reactor chamber, the wall of the reactor is designed with a rounded extension. This rounded shape can enhance the functionality of the reactor by promoting the reflection of ionized gases, such as electrons, positrons, plasma, photons, and other high-energy particles, towards the electrochemical electrodes. The rounded extension of the reactor wall redirects the movement of these particles towards the center of the fuel cell, following the principles of Newton's Law of Universal Gravitation.

[0109] In another embodiment example, the wall of the reactor has an oval shape in crosssection. The specific egg shape is suggested as being particularly advantageous for the reactor's functionality. Due to the ovality and curvature of the reactor wall, ionized gases and particles with high kinetic energy that come into contact with the wall are reflected towards the electrochemical electrodes. The heavier nuclei, on the other hand, may gain different directions upon hitting the wall, ultimately converging towards the center point of the fuel cell under the influence of gravity.

[0110] In the first module of this spiral embodiment, the interaction between inflated electron clouds is increased, leading to more releases and interactions. In the context of unstable cold fusion, atoms naturally seek to return to their normal orbital electron numbers and stable conditions. This process involves losing excess energy and electrons from their orbitals, which leads to permanent ionization. As electrons are shed, the core of the atom (comprising protons and neutrons) becomes disproportionately large and unstable, which can result in the division of the atom due to the loss of mass balance and intrinsic gravitational forces. A notable example of this phenomenon is uranium, where rapid electron loss leads to a larger core, triggering fission. However, this method focuses on smaller or lighter atoms to avoid reaching a fission level.

[0111] At this critical juncture, the atom with fewer electron layers is highly vulnerable. If another atom with a similar condition from the second module of the spiral embodiment collides with it, a unique interaction occurs. This collision is analogous to methodologies employed by Helion Energy and CERN, where the core of one atom can penetrate and merge with the core of another atom. This momentary fusion creates a new atom with a higher number of protons and neutrons, essentially a brief period of fission/ semi-fission and a possible fusion. [0112] Unlike traditional methods, where interactions and collisions are localized and static, the current embodiment and method employs a dynamic and continuous process. This design facilitates more frequent collisions without reaching the terminal phase of each reaction. The system is engineered to prevent the complete stabilization of atoms, thereby maintaining a high potential for energy release through repeated interactions. This innovative design reduces the need for high-temperature environments and excessive energy consumption typically required to sustain ionized or plasmid states in conventional systems.

[0113] The current embodiment and method reactions leverage these principles to maximize energy extraction from nuclear interactions. By controlling the conditions under which atoms lose electrons and become unstable, the system ensures a continuous supply of atoms at optimal states for fusion. When these atoms collide, they release various forms of energy and smaller particles, such as quarks. The high-pressure reactor is designed to promote interactions between nuclei along the central axis of the fuel cell. This configuration ensures that nuclei entering from opposite sides face residual nuclei from previous cycles, increasing the likelihood of successful collisions and energy release.

[0114] This process can be broken down into several critical stages. Initially, atoms are ionized and enter a state of high instability, characterized by an inflated core due to electron loss. These atoms are then directed into the reactor module where they collide with similarly unstable atoms. The spiral embodiment ensures that these collisions occur with high frequency and precision, maximizing the interaction time and potential for energy release.

[0115] As the collisions occur, the unstable atoms merge briefly, creating new, larger atoms. This fusion/ semi-fusion process releases substantial amounts of energy and smaller subatomic particles. The design of the reactor ensures that these particles are captured and utilized effectively, contributing to the overall efficiency of the system. The innovative aspect of the current embodiment and method lies in its ability to maintain a continuous cycle of ionization, collision, and energy extraction without reaching a state of complete stabilization for the atoms involved.

[0116] For an example in this embodiment, in examining the energy dynamics involved in atomic collisions and fusion processes, a detailed calculation reveals stark contrasts. The kinetic energy released during the collision of two hydrogen atoms, assuming typical thermal velocities, is approximately 2.82xlO^A-21 joules. In the scenario where a hydrogen atom collides with a radon atom, the total kinetic energy is slightly higher, at approximately 8.09xl0^A-21 joules, due to the significantly greater mass of the radon atom. However, when considering the fusion of two hydrogen atoms, the energy released is vastly greater. The fusion process, particularly in deuterium nuclei, releases approximately 5.23xlO^A-13 joules per fusion event. This comparison underscores the immense energy potential of nuclear fusion, with the fusion energy being roughly 1.85xlO^A8 times greater than the kinetic energy from hydrogenhydrogen collisions and about 6.47xlO^A7 times greater than that from hydrogenradon collisions. These calculations highlight the significant energy yield from fusion reactions, which far surpasses the energy involved in non-fusion atomic collisions, illustrating the transformative potential of fusion energy in practical applications. Once again, it is emphasized that all seven components of the device are crucial and must function together in unison and within the same location. Failure to do so will result in the system overheating or losing control and functionality immediately. The immense amount of energy generated must be carefully controlled and reused within the winding layers, reactor chamber, axial cooling system, and other critical parts. Without this precise coordination, the system's integrity and operational stability cannot be maintained.

[0117] To further understand the impact of this energy release of possible fusion or waves rays in process, we can consider a specific example involving a pipe with a diameter of 20 mm and an initial hydrogen ion velocity of 10 m/s. Given the energy released per fusion event (approximately 5.23xlO^A13 joules), we calculate the effect on the velocity of ionized hydrogen. Initially, the kinetic energy of a hydrogen ion moving at 10 m/s is 8.35xl0^A-26 joules. After imparting the fusion energy to a single hydrogen ion, the new kinetic energy becomes approximately 5.23xlO^A-13 joules, given that the fusion energy is several orders of magnitude larger than the initial kinetic energy. Using this new kinetic energy, we calculate the new velocity of the hydrogen ion. The resulting velocity, determined through the kinetic energy formula, is approximately 7.91xlO^A7 meters per second, which is significantly higher than the initial velocity of 10 m/s. To put this into perspective, the velocity of light is approximately 3xl0^A8 meters per second. While the new velocity of the hydrogen ion is about a quarter of the speed of light, this comparison demonstrates the immense impact of fusion energy on the velocity of ionized particles, highlighting how fusion can dramatically increase the kinetic energy and subsequent speed of particles involved. This immense increase in velocity illustrates the powerful effect that fusion energy can have on atomic and subatomic particles, further emphasizing the potential applications of fusion energy in various technological and scientific fields.

[0118] When these high-velocity hydrogen ions pass through a magnetic field, the interaction is governed by the Lorentz force, which states that a charged particle moving through a magnetic field experiences a force perpendicular to both its velocity and the magnetic field. This can result in circular or helical motion of the ions. According to Faraday's law of electromagnetic induction, a changing magnetic field within a closed loop induces an electromotive force (EMF) or voltage. If we consider a solenoid or a loop of wire with the high-velocity hydrogen ions passing through, the induced EMF /E can be calculated using Faraday's law: E=-N*dOB/dt, where OB is the magnetic flux. For simplicity, assuming the ion's motion creates a uniform change in magnetic flux: E=-N*dOB /dt, here, N is the number of turns in the coil, B is the magnetic field strength, and A is the area of the coil. Given the high velocity of the ions, the rate of change of the magnetic flux would be significant, leading to a substantial induced EMF.

[0119] For a coil with N=100 turns, a magnetic field strength B=1 Tesla, and an effective coil area A=l*10^A-4 square meters, and assuming the ion velocity induces a flux change at a rate d(B.A)/dt=B.A.v : E«-N.B.A.v, E«- 100* 1 T* 1 * 10^A-4m2*7.91 * 10^A7 m/s, E«-7.91V

[0120] In another scenario, if we consider a coil with N=2500 turns and a magnetic field strength B=850 Tesla: E«-N.B.A.v, E«-2500*850T* 1 * 10^A-4m2*7.91 * 10^A7 m/s, E«- 1.68* 10^A9 V. To convert this voltage into power (in watts), we need to consider the current generated by this voltage (using the control circuit, inner Batteries and induct winding layers with more thickness etc.). However, assuming an ideal scenario where the system can convert this voltage into electrical power efficiently, the power in megawatts (MW) can be approximated. If we assume the current generated is proportional and the system is perfectly efficient: P=E*I, Assuming a practical current I of 1 ampere for simplicity: P=1.68*10^A9V*l A,P =1.68*10^A9, P=1.68*10^A3MW [0121] This indicates that theoretically, a power output of approximately 1680 megawatts could be generated by the high-velocity hydrogen ions passing through the magnetic field in this more intense scenario. Additionally, if we consider that container tubes with at least two winding layers can further accelerate the passing fluid, the total velocity increases due to the algebraic linear summation of the velocities contributed by each winding layer. This would result in an even higher induced EMF and, consequently, more electricity generated than the above calculations indicate. This concept can be applied in a small system where proper circulation and soft control of parameters such as temperature are crucial. Controlling the temperature is important to maintain the system's stability and efficiency. The application must work together seamlessly to ensure long-term operation, even without fusion occurring continuously. This highlights the potential for creating highly efficient energy generation systems that leverage the principles of fusion and electromagnetic induction, potentially transforming energy production and usage. If we consider that with this method, the input power of the device is at most 2400 watt-hours by internal suppliers such as batteries, the output can be significantly greater. In one case scenario, the output power is many folds more than the input power, demonstrating the high efficiency and transformative potential of this technology.

[0122] Further elaboration on the role of the smart control circuit and inner battery in the system highlights its importance in managing the device's multiple winding layers and other components, as shown in the figures. Several methods can be used to convert the induced voltage into usable power, depending on the specific application and system configuration. One method is direct connection to a load, where the voltage is connected directly to an electrical load (such as a resistor, light bulb, or appliance), allowing current to flow and converting the electrical energy into heat, light, or other forms of energy. Another method involves the use of a power converter, such as DC- DC converters or inverters, to regulate and convert the voltage to a desired level, ensuring compatibility with the connected load or system. Inductive loads, such as electric motors or transformers, can convert the induced voltage into mechanical energy or transfer it to another circuit with a different voltage level. Capacitive loads, such as capacitors, can temporarily store the electrical energy and release it as needed, smoothing out voltage spikes and supplying power intermittently. For systems generating AC voltage, rectification and filtering using diodes, rectifiers, capacitors, and inductors can convert the AC voltage to DC voltage and smooth it for DC loads or further power conversion. Battery charging is another method, where the induced voltage charges batteries, providing a stable and reliable power source. In scenarios where high current is generated, a current transformer can step down the current to a manageable level while stepping up the voltage, facilitating easier measurement and utilization of the power. Additionally, using thicker wires in the inductive winding layers or incorporating turbine engines can enhance the system's efficiency and power output. The integration of these methods, along with the smart control circuit, ensures efficient and effective power conversion and management within the system.

[0123] Further elaboration reveals the intricacies of this method. The spiral design of the reactor module is crucial in maintaining the dynamic environment needed for sustained reactions. The curvature and angles of the spiral ensure that atoms are constantly in motion, preventing them from settling into a stable state. This motion is critical for maintaining the high potential energy required for effective collisions.

[0124] Additionally, the reactor's ability to manage varying pressures and temperatures is vital. By optimizing these parameters, the system ensures that atoms are at the ideal energy state for collisions, further enhancing the efficiency of the reactions. The use of lighter atoms, which are less likely to undergo traditional fission, allows for more controlled and sustainable reactions, reducing the risk of unwanted high-energy events.

[0125] The energy released from these reactions is harnessed in several ways. Firstly, the kinetic energy of the colliding atoms is converted into usable energy. Secondly, the smaller particles and quarks released during the collisions are captured and utilized as explained before, such as wave rays (alpha) that increase the kinetic energy of ions or are drained as heat energy. This multi-faceted approach ensures that the system is highly efficient, with minimal energy loss.

[0126] Another critical aspect of the current embodiment and method is the handling of residual particles. The system is designed to recycle these particles, re-ionizing them and directing them back into the reactor module. This recycling process not only maximizes the use of available particles but also ensures a continuous supply of atoms in the optimal state for collisions.

[0127] Moreover, the design addresses the issue of overheating and energy accumulation at the edges of the reactor. By employing a spiral shape rather than edges or closed angles, the system avoids the collection of high-energy ions at specific points, which could lead to overheating or explosive events. The round, spiral shapes of the tubes allow for better handling of gas and material expansions, providing a flexible and safer environment for the reactions to occur.

[0128] In the current embodiments and method, several key electrochemical and energy conversion reactions occur. Firstly, ionization and recombination reactions are fundamental. Atoms are ionized by releasing electrons, creating plasma through external electric discharges and electric fields, as governed by Coulomb's law and ionization energy principles. Recombination then occurs when free electrons recombine with ions, releasing energy in the form of photons and rays that increase the kinetic energy of ionized atoms in a recycling process, adhering to the conservation of energy and quantum mechanics. Additionally, nuclear fusion reactions play a critical role, where lighter atomic nuclei, such as hydrogen isotopes, collide and fuse to form heavier nuclei. This fusion process releases substantial energy according to Einstein's mass-energy equivalence principle (E=mc^A2) and is akin to the reactions powering the sun, relying on the strong nuclear force to overcome electrostatic repulsion at high energy levels.

[0129] In another embodiment, energy conversion in the current embodiments and method of the system involves electromagnetic induction and thermoelectric conversion. The kinetic energy of moving charged particles within magnetic fields induces electric currents in surrounding coils, as described by Faraday's law of electromagnetic induction. This process effectively converts kinetic energy into electrical energy in the wire of the winding layer. Furthermore, the thermal energy generated by high- energy particle collisions is harnessed using thermoelectric materials, which convert heat into electricity based on the Seebeck effect. These processes are underpinned by fundamental physics laws such as Maxwell's equations, the Lorentz force law, the principles of thermodynamics, and quantum mechanics, ensuring efficient and sustainable energy extraction and conversion within the current embodiments and method framework.

[0130] In conclusion, the current embodiments and method represent a significant advancement in the field of cold fusion and nuclear energy. By leveraging the principles of ionization, collision, and energy extraction in a continuous and controlled environment, this method maximizes energy output while minimizing risks and energy consumption. The innovative design of the reactor, with its spiral embodiment and dynamic operation, ensures a high frequency of successful collisions and efficient use of released energy. This approach not only enhances the sustainability and safety of nuclear energy production but also opens new possibilities for its application in various fields, from power generation to advanced research in particle physics.

[0131] Overall, the oval shape and curvature of the reactor wall play a role in optimizing the interactions and movements of particles within the fuel cell, potentially leading to improved performance and efficiency.

[0132] In the described embodiment, particularly in small-scale applications such as cars or buildings, the bottom part of the reactor/fuel cell, which includes a section with weak acids, plays a role in the device's functionality. It is designed to generate a certain amount of amperage hour (A.h) to initiate the device or enable it to turn on automatically.

[0133] When the device is turned off, the bottom part of the fuel cell remains charged. However, due to the absence of an electric potential difference, no current flows in the circuit. Once the device is turned on and connected to a consumer through a control circuit, a potential difference is created, leading to the flow of current in the circuit.

[0134] This feature of the system ensures safety and control, distinguishing it from nuclear devices. Similar to a safety match, which poses no danger when turned off or deactivated, this method provides a controlled and safe means of power generation. The activation of the device and the flow of current occur only when the necessary conditions are met, reducing risks, and ensuring the system operates in a controlled manner. In a larger system or application, such as a power plant, a liquid chamber can be used instead of weak acids to transfer the elevated temperatures generated by the fusion reactions or wave temperatures to water. This heated water can then be evaporated and connected to a turbine or any other device to utilize the released heat energy.

[0135] The continuous and controlled ionization process in the spiral structure ensures a considerable number of available electrons and positrons, which can support a current flowing to an external battery. The generated current in the winding can charge the external battery over time, depending on its capacity and the charging rate. [0136] In smaller devices, as the temperature of the gases increases, it may be necessary to change or refill the gas tank or alter the direction of the electric current through the control circuit periodically. In larger devices, the increased temperature can be utilized for turbine operation, similar to a boiler.

[0137] In emergency situations where the reactions become unbalanced and the temperature rises excessively, potentially leading to nuclear fission or uncontrolled fusion, the control circuit can quickly reverse the flow direction and inject electrons from the external batteries into the reactor. This helps stabilize the ionized molecules' core by absorbing the free electrons, leading to a cooldown and subsequent reboot of the system.

[0138] The tube's body serves multiple purposes simultaneously, including providing structural support, containing the ionized gases, and facilitating sednoid, magnetic field and acceleration magnetic fields that accelerate the ions within the tube.

[0139] The external surface of the tube's body is wrapped with 2 to 7 separated windings, each separated by an insulator layer. This arrangement creates a magnetic field for accelerating the ionized gases inside the tube, enabling efficient ionization and energy generation.

[0140] According to the embodiment example, an axial-middle heat exchange unit, the power generating unit includes at least one heat exchange unit that facilitates the exchange of heat between a secondary fluid and the fluid flowing in the first return line. This heat exchange serves to cool down the fluid in the first return line and is positioned in the axial-middle of the device.

[0141] The heat exchange unit consists of a chamber that contains the secondary fluid, and the first return line extends through this chamber. The chamber is designed to have direct contact with the external body of the reactor, as well as the bodies of the high voltage and low voltage self/ transformers winding layers and magnet blocks. This arrangement helps prevent the temperature from rising excessively in these components, as exposure to high heat can cause magnets to lose their magnetism.

[0142] It is a well-known phenomenon that magnets can lose their magnetism or magnetic field when exposed to elevated temperatures. Therefore, by implementing the heat exchange unit and maintaining appropriate cooling, the device ensures that the magnets or electromagnets used in the system retain their desired magnetic properties and functionality.

[0143] According to the embodiment example, the chamber of the heat exchange unit is divided by at least one internal wall into at least two compartments. Each compartment is filled with secondary fluid, and the return line extends through each of these compartments. This design allows for efficient heat exchange between the fluid in the first return line and the secondary fluid in each compartment. [0144] In this embodiment, the heat exchange unit utilizes a cooling gas in its liquid phase. The cooling gas is present within the chamber and undergoes a phase change from liquid to gas during the heat exchange process.

[0145] The arrangement of the heat exchange unit promotes effective cooling. As the chamber absorbs heat from the reactor chamber side, the cooling gas undergoes a phase change to the gas phase more quickly on that side compared to the other side of the chamber. This temperature difference between the colder and hotter sides of the chamber creates a natural circulation of gas through convection, leading to the spontaneous movement of gas at the top of the chamber and / or between one or two axial-middle heat exchange units in small devices.

[0146] It is a known phenomenon that the rapid movement or agitation of a gas inside a chamber can result in cooling and freezing of the gas itself. Therefore, in this embodiment, the movement and circulation of the vaporized cooling gas within the chamber contribute to the cooling process. The two chambers of the heat exchanger are positioned opposite each other in the axial direction and are connected by at least two pipelines. This arrangement facilitates increased movement and frequent circulation of the vaporized cooling gas between the chambers, enhancing the cooling rate of the components. Importantly, there is no need for a separate condenser or motor to move and rotate the cooling gas, as the natural circulation mechanism serves this purpose effectively.

[0147] In a further embodiment example, a magnet component, the device does not incorporate permanent magnets. However, if the tube-shaped bodies are constructed using graffiti and superconductive materials, a notable phenomenon occurs during the cooling process when the device is in standby or shutdown mode. Through the implementation of an axial-middle heat exchanger device, the tube- shaped bodies are cooled to temperatures below three hundred degrees Celsius. This cooling process induces a transformation in the graffiti and superconductive materials, causing them to exhibit magnet-like characteristics.

[0148] The magnetization effect resulting from the cooling process in the tube-shaped bodies made of graffiti and superconductive materials contributes to the acceleration of ionized gases at the start of the process. This acceleration is particularly significant in reaching the milestone or breakeven point represented by T2=eV total. Enhancing acceleration occurs right from the beginning of the process.

[0149] It is important to emphasize that the magnet-like characteristics observed in the cooled tube-shaped bodies made of graffito and superconductive materials are a natural consequence of the cooling process facilitated by the axial-middle heat exchanger device. This characteristic magnetization feature further promotes the efficient initiation and progress of the process. [0150] In the provided embodiment example, the device incorporates the generation of distinct magnetic fields around individual wires and multiple windings. Furthermore, each tube- shaped component within the device generates its own magnetic field, which can possess similar or different specifications. Additionally, magnetic fields are formed around the right and left sides of the egg-shaped reactor.

[0151] These magnetic fields exhibit specific characteristics, including tesla strength, frequency, and direction, which collectively contribute to the device's overall functionality. The magnetic fields serve various purposes within the embodiment. At least two windings are responsible for generating high voltage, while others produce low voltage. Certain magnetic fields facilitate acceleration, while others function to redirect ions away from the left and right sides of the reactor or the inner section of the tube bodies, redirecting them towards the desired acceleration direction or the center of the reactor chamber. Additionally, individual magnetic fields can function as virtual walls and separators, allowing for the segregation of ions based on their weight or speed within the top-to-bottom region of the reactor chamber. Each magnetic field fulfills a unique role and plays a vital part in ensuring the efficient operation of the device.

[0152] According to the embodiment example, direct gases ionization is achieved within tube- shaped containers by utilizing various ionization methods such as electric discharge and UV LED lamps. The device incorporates pairs of electrode holes and/or lamps that are positioned at regular intervals along the structure of the tube. These electrodes, when supplied with voltage from self/ transformers winding layers (exploiting Tesla coil phenomena), create an electric arc or electric discharge between themselves and the gases present in the tube. Furthermore, UV lamps or LEDs may be combined with electrodes to emit radiation through the holes.

[0153] The distinction between arcs and electric discharge lies in the structural characteristics and arrangement of windings within high voltage and High-Frequency transformers, as well as the variations in amperage and power consumption. These differences ultimately affect the heating generated during the ignition/ionization process. In the case of small power generator devices, minimizing power consumption and amperage becomes crucial as it enables the self/ transformers winding layers to deliver power for long-term continuous operation. This, in turn, ensures low heating with standard components and facilitates a stable and laminar voltage supply, leading to a consistent and stable power output from the generator. The positive charge of the high voltage electrodes creates a configuration that promotes ionization of the fluid by electric discharge. The fluid flow / environment passing between the electrodes forms a negatively charged region, interacting with the emitted electrons. The resulting electric discharge structure covers a sizeable portion of the container, making it difficult for ordinary atoms to pass through without being ionized.

[0154] Different configurations of electrodes and lamps may be used in upstream and downstream containers, and different type of types of electric discharge or arc structures, such as glow discharge, corona, and electric spark, can be created. The electric discharge structure may have a half zigzag shape resembling saw teeth, where ionization is more readily achieved at the tips due to increased electron excitement.

[0155] The optimization of ionization and magnetic field efficiency in the device involves adjusting the distance between the electrodes or pair of short circuit electrodes, as well as the applied voltages to each electrode. By carefully controlling these parameters, electric discharges with different frequencies can be created, leading to enhanced ionization and magnetic field effects. Additionally, chemical coatings can be applied to the electrodes to increase their corrosion resistance.

[0156] The electrodes used in the device are typically rod-shaped with pointed ends, and they can be arranged either in-line or in parallel, depending on the specific configuration required. The voltage supplied to each electrode falls within the range of 5V to 300kV, which is specifically adjusted to achieve selective ionization at the desired energy level, based on the particular gas being utilized. The preferred voltage value for selective ionization is around 6-7kV. It is worth noting that the device incorporates tube-shaped Self/ transformers winding layers, eliminating the need for additional external transformers. These Self/ transformers winding layers have the capability to increase the voltage and frequency on their own. For instance, with the presence of forty tube-shaped Self/ transformers winding layers connected in series, the high voltage and high frequency can be raised to 300 kV and 10kHz, or even higher if necessary.

[0157] In another configuration, the device includes at least four separate winding layers, with two of them dedicated to generating lower voltage with varia frequency 0 to 22 kHz, specifically for selective ionization purposes. The remaining winding layers can be utilized to generate higher voltages. This means that, for example, with the use of ten tube-shaped self/ transformers winding layers, there are 65,536 possible arrangements of winding wires in series and parallel, providing greater flexibility in voltage and frequency output.

[0158] The frequency of the supplied voltage can vary from null to 60 Hz or even up to 100 kHz, depending on the desired ionization energy level and magnetic field pulsation. This frequency is achieved by adjusting the winding's wire wrapping number, diameter, and extension. These adjustments are made to meet the specific ionization energy level demands for a particular gas or the desired step in hot, cold, or current embodiments and method fusion electrochemical reactions. [0159] The device may also include a light source for radiating the fluid flow. At least a portion of the tube-shaped structure allows light transmission, and the light source can be located outside the structure. The light-matter interaction enhances ionization efficiency and can lead to the emission of waves with different wavelengths. Lightemitting diodes (LEDs) emitting ultraviolet (UV) light or light bulbs and lamps can be used as light sources, with light intensities ranging from low to high lumens or varying color temperatures (Kelvin).

[0160] As per the above description, the electric discharge to ionization setup in the first embodiment is designed to charge the electrodes in a pair with the same electric charge (positive), enabling both electrodes to emit electrodes. An alternative could involve providing the electrodes in a pair with opposite charges (positive and negative). Additionally, several types of arc structures, such as glow discharge corona and electric spark, can be created. Consequently, different arrangements and designs of the electrodes may also be feasible.

[0161] As per the above description, all containers in the spiral possess identical shape and size. An alternative configuration could have some containers longer than others. For instance, the containers of the second type may be longer than those of the first type.

[0162] As per the above description, all containers in the spiral feature two pairs of electrodes. An alternative setup could equip some containers with a different number of electrodes or without any electrodes. Thus, some containers may not include radial openings in the container wall to accommodate electrodes. For example, a second type of container may be designed without openings for electrodes. Additionally, one container may be specifically designed for ionization, while another container may be designed for the acceleration of the fluid. Consequently, the series of containers may comprise additional types of containers beyond the first and second types. As an alternative, the ionization device could include a magnetic field generating arrangement capable of creating a magnetic field in the vicinity of at least one of the pairs of electrodes in the second container. This magnetic field would influence the arc structures to support the ionization of the gas. The magnetic field generating arrangement could be located outside of the second container, further enhancing the ionization process, and supporting the overall efficiency of the power generation device.

[0163] Overall, the combination of electrode-based electric discharges, light radiation, and different radiation wavelengths contributes to the ionization and increases the kinetic energy of electrons and the release of electrons. As described in the application, this enhances the movement and motion of electrons within the specified path of the tube containers. This, in turn, helps create a complex combination of forces for the magnetic field-driven acceleration of the fluid. By implementing the described embodiment and technology, the overall efficiency of the power generation device is significantly improved.

[0164] It should be understood that the present invention is not confined to the embodiments described and illustrated in the drawings; instead, individuals skilled in the field will recognize numerous alterations and modifications that can be made within the scope of the attached claims.

[0165] Further advantages and advantageous features of the invention are disclosed in the following description and in the dependent claims.

[0166] With reference to the appended drawings, below follows a more detailed description of embodiments of the invention cited as examples.

BRIEF DESCRIPTION OF THE DRAWINGS

[0167] [Fig.12] provides a perspective view of a power generation and/or quantum charger or batteries unit, representing a second embodiment. The figure highlights various components, including 408, 410, 344, 202, 2, 402, 504, and 502. These components play integral roles in the functioning of the unit, contributing to its power generation and/or quantum charging capabilities.

[0168] [Fig.17] is a cross section view of the power generation unit according to [Fig.12],

[0169] [Fig.5] is a perspective view of a power generation unit according to a first embodiment comprising a device for ionization of a fluid according to a third embodiment comprising a plurality of containers of a first type as in [Fig. lb] and a plurality of containers of a second type as in [Fig.9] arranged in series in a spiral configuration,

[0170] [Fig.9] is a perspective view of an internal support structure of the power generation unit according to [Fig.5].

[0171] [Fig.10] is a cross-section view of the power generation unit according to [Fig.9].

[0172] [Fig.10a] shows interconnected axial-middle heat exchange units 344 with spiral return lines 317b, gas cooler nozzle, one-way valve 1011, and reactor chamber 504, 304. It illustrates the trajectory of vaporized gases from liquified cooling agents, highlighting thermal gradients, and enabling gas-liquid mixing and movement within interconnected conduits 1010.

[0173] [Fig.2] provides an enlarged and partially cut perspective view of a fluid conveying connection element, as depicted in [Fig. lb]. It also displays a partial perspective view of a device for fluid ionization, representing a second embodiment. The device includes a container of a second type, which may or may not have windings wire or cover shelters.

[0174] [Fig.lh] illustrates the creation of electric discharge structures within a container through different configurations of electrodes and charges, depicted in diagrams A, B, and C. In Figure A, the electrode 34 is bent at a about 90-degree angle to interact more with the fluid for ionization as it passes through the tubular container 2 from the tip and surface of the electrode. This bending enhances the thruster ionic wind mode by facilitating easier installation inside the tube with minimal leakage and aiding the movement of ions towards the electrochemical negative pole (electrode 316j) inside the reactor chamber, creating a thruster effect and increasing fluid disruption. Figure B shows multiple angled forces converging towards the center, with electrodes 34 and 36 positioned to create significant disruption and ionization within the fluid, enhancing electric discharge effects. Figure C depicts electrodes 34 and 36 interacting with circular or spherical objects (72 and 74), indicating junctions or contact points, emphasizing the creation of specific discharge points to form electric discharges within the container. [Fig.lh] also provides a schematic top view illustrating the creation of a first electric discharge or arc structure within the container using positive or positive and negative charged electrodes and various electric discharges. Additionally, it offers a front view of the first pair of electrode holes, highlighting their specific shape as described in [Fig.le], and C includes short electric sphere-shaped instead of capacitors, designed to generate High-Frequency mechanical effects. This combination leads to the formation of electric arc structures within the container, utilizing different configurations of positive and negative charges and electrode discharges.

[0175] [Fig. lb] provides a detailed schematic representation of a pair of identical devices 2 positioned in different rings. The figure includes a partially cut view of the device, displaying its internal components. It also presents a perspective view of a device specifically designed for the ionization and acceleration of a fluid. This embodiment features a container of the first type, which plays a crucial role in the functioning of the device. The schematic view in [Fig. lb] emphasizes the intricate interaction between the two devices 2 within their respective rings. The magnetic fields generated by each device mutually influence and affect one another. This mutual interaction results in an increase in charge, resonance, and frequency for both devices. The depiction highlights the precise arrangement and configuration of the devices, as well as the role of their magnetic fields in enhancing their functionality. This detailed illustration offers a comprehensive understanding of the device's design and operation, particularly in terms of fluid ionization and acceleration.

[0176] [Fig.le] is a longitudinal cross section view of the device as in [Fig.lb], [0177] [Fig. Id] is a transversal cross section view of the device as in [Fig.lb],

[0178] [Fig.le] is a partially cut side view of device 2, resembling [Fig.lb]. The figure illustrates the schematic perspective of the magnetic field generated by each winding wire. It emphasizes the application of the magnetic field, Lorentz's law, and solenoid schematics, governing the behaviour of the magnetic field when a polarized subject, such as an ionized atom or metal bullet, enters the tubular structure 2. The resulting force (F) hits and imparts momentum to the subject, with more detailed descriptions available in references on solenoid phenomena. According to the Lorentz force law in a pulsed magnetic field, the charged particles experience a force perpendicular to both the magnetic field and their velocity, which accelerates them within the tubes. The solenoid's magnetic field is also influenced by the shape and configuration of the winding layers, enhancing the precision of ion acceleration. The symbols S and N in the figure denote the south and north poles of the solenoid, respectively, indicating the direction of the magnetic field lines. The arrows around these symbols show the flow of the magnetic field, moving from the north (N) to the south (S) outside the solenoid and from south to north inside the solenoid, creating a closed loop. This magnetic field configuration generates a force (F) on the charged particles according to the right-hand rule, where the thumb points in the direction of the current, and the curled fingers show the magnetic field direction, resulting in a force perpendicular to both. In a linear wire, the magnetic field forms concentric circles around the wire, with the strength of the field decreasing as the distance from the wire increases. This field is typically weak and diffused, resulting in a relatively small Lorentz force that acts perpendicularly to both the magnetic field and the velocity of charged particles, thereby providing minimal acceleration. In contrast, when the wire is wrapped into a coil or solenoid, the individual magnetic fields of each loop combine to create a much stronger and uniform magnetic field inside the coil. This field runs parallel to the axis of the coil and is concentrated, providing a robust and directed force that can significantly accelerate charged particles along the tube's axis. The configuration of the coil means that the magnetic and induced electric fields interact in complex ways, producing a substantial Lorentz force that pushes ionized particles effectively. The force exerted by the solenoid is much greater and more controlled compared to a linear wire, making it ideal for applications like particle acceleration and electromagnetic devices. This strong and directed force is essential in practical scenarios where ionized particles need to be precisely controlled and accelerated, as seen in various electromagnetic and particle acceleration devices. Each winding in the solenoid serves specific functions, such as acting as high voltage ionization electrodes or supplying low voltage to internal or external power consumers like batteries. This versatility is further highlighted by the potential for winding layers to be optimized for different tasks, such as energy conversion, signal modulation, and control applications. For instance, varying the winding configuration can adjust the strength and direction of the magnetic field, thereby optimizing the device's performance for specific operational needs. The magnetic field generated by the solenoid can induce electric fields that drive currents in nearby conductive materials, leveraging Faraday's law of induction to enhance overall device efficiency. In a linear wire, the magnetic field forms concentric circles around the wire, with the strength of the field decreasing as the distance from the wire increases. This field is typically weak and diffused, resulting in a relatively small Lorentz force that acts perpendicularly to both the magnetic field and the velocity of charged particles, thereby providing minimal acceleration and this not the case in this embodiment.

[0179] [Fig.14] presents a perspective view of oval-shaped reactor in the power generation unit depicted in [Fig.12]. The reactor features at least one inlet 506 or 306 and at least one outlet 312 or 805, allowing for the controlled flow of materials and fluid within the system.

[0180] [Fig.15] provides the first cross-sectional view of the reactor depicted in [Fig.14].

It illustrates the direction of movement for electrons and protons within the reactor, as well as a schematic representation of the geometric arrangement of the electrodes and the locations of the inlet and outlet pipes and tubes. This detailed view allows for a clear understanding of the electron and proton dynamics within the reactor, as well as the positioning and geometry of the various components.

[0181] [Fig.23] displays an egg-shaped reactor with a symmetrical and geometrically optimized design. It features two chemical electrodes 316, 318 arranged in a spaced relationship inside the reactor chamber. The first electrode 316 acts as an anode, facilitating the controlled release of electrons to an external circuit.

[0182] [Fig.16a] is a top view is presented, like [Fig.23], illustrating the movement of ions and electrons around electrodes 316 and 318. Additionally, it depicts the schematic estimation of magnetic fields generated by the component embodiments 202 and 502 on the left and right sides of the reactor chamber. Notably, the side parts of the reactor chamber depicted in the image do not exhibit magnetic fields. To facilitate the separation of ions based on their size and weight, virtual magnetic walls 831 and 832 are strategically positioned, along with pathways. This controlled separation allows for precise atomic-level mixing, guiding the ions towards outlet holes 312 and 5125 located in the z801 zone. These design elements contribute to a comprehensive understanding of the system's functionality, as explained in the previous description of [Fig.23],

[0183] [Fig.16] is a represents a cross-section of [Fig.14], revealing a holed perforated sphere 800 and the presence of zones z800 and z801 within the reactor. The figure also provides a schematic view depicting the movement of ions in the top, middle, and bottom regions of reactor 304, 504. Additionally, it highlights the collision of loose electrons within the ion clouds, as well as the interaction with photons. This collision and interaction result in the release of wave rays, such as alpha rays, which contribute to the increase in kinetic energy and aid in the acceleration process. [0184] [Fig- 8] illustrates a schematic view of a power control system and a power generator reactor unit. It displays the process of electron suction and the controlled movement direction of ions, electrons, and positrons within the top, middle, and bottom regions of an Egg/rectangular- shaped reactor chamber. Additionally, it provides an example of the wiring configuration for the windings of a device, such as 2/1 in embodiment 202 or 5 to 40 devices in embodiment 502, demonstrating their contribution and interconnectedness in the 330 zone. This setup involves internal consumers like self-sufficient power supply unit 330, 70/1, 70/3, as well as external batteries and users 327,328,333. The smart control circuit 326 plays a vital role in coordinating and regulating the various components, forming an integrated schematic drawing. The internal electrical circuit overview (330) of the power generating apparatus involves the strategic arrangement, synchronization, and frequency adjustment of winding layers and internal power consumers in both embodiments 502 and 202. Winding layers can be connected in series to increase the total voltage (V = V_A + V_B + V_C) or in parallel to increase the total current capacity (I = I_A + I_B + I_C), with each winding wire's frequency adjusted, synchronized, and harmonized when identical windings are used together for optimal performance. Similarly, internal power consumers, such as resistors and LEDs, can be arranged in series to share the voltage drop or in parallel to distribute the current load evenly. In embodiment 502, the winding layers are optimized for High-Frequency induction to facilitate rapid ion acceleration, with series and parallel configurations balancing high voltage and current requirements, and the frequency of each winding wire synchronized and harmonized. In embodiment 202, the winding layers and power consumers are arranged to ensure stable voltage levels and redundancy, maintaining consistent power supply even if one path fails, with frequency adjustments and synchronization to enhance efficiency. This integrated approach leverages the principles of electromagnetic induction, precise frequency tuning, and efficient power management to enhance the device's performance under various operational conditions.

[0185] [Fig. If] presents a tube-shaped container 2 with various winding arrangements and options for filling electrode holes 26, 28, 32, 38. The design includes a Tesla coil setup and demonstrates the versatility of windings and wiring functioning as ionization electrodes or short-circuit electrodes. The control circuit 326 coordinates these components and provides an example of filling the electrode holes with sphere electrodes or needle electrodes for High-Frequency short-circuiting or ionization discharge with UV LED mixture.

[0186] [Fig.11] is a graph illustrating a method B and C or A of control and operation of the quantum power generation unit, [0187] [Fig.20] shows the casing 404 of the power generation unit from [Fig.12], The casing is coated internally and externally with a nano chemical material to offer protection and function as a shield against emitted waves. It features a metal capsule- shaped design to enhance containment and prevent emission leakage. Additionally, the casing includes check valves for monitoring gas quality, controlling high pressure, and an inlet/outlet power junction 404 for coordination with external circuits and small to medium power consumers. It should be noted by examiners and readers that this embodiment and device are not limited to the mentioned sizes, and they can be scaled up or down to suit different industrial applications. Additionally, smaller-scale versions can be beneficial for consumers facing limitations in geographical location or climate conditions, or those unable to connect their machines or buildings to regular power suppliers. The versatility of the device allows for adaptability to various industry fields and specific consumer needs.

Description of Embodiments

[0188] [Fig.12] illustrates a perspective view of a power generation apparatus, designated as unit 402, in accordance with a second design configuration. This is also accompanied by a perspective view of axial-middle heat exchanger capsules, labelled as 344 a or b, which represent two variants of the model 202 designated in [Fig.10]. The apparatus highlights longitudinally extended tubular transformers that are arranged in a helical orientation, positioned around a centrally located reactor chamber, marked as 504, between two components, 202 and 502. In the provided example, specifically model 2,502, the apparatus design includes the induction of unique magnetic fields that envelop individual conductors and incorporate multiple windings. Each tubular component, designated as 2,2/1 within the device, engenders its respective magnetic field. These fields can display similar or divergent characteristics depending on the device's specifications. Moreover, magnetic fields are generated around the right 202, and left, designated as 502, flanks of the ovate reactor. These fields resonate at high frequencies and are in harmonic sync with each other. This resonance culminates in a larger magnetic field, resulting from the collective action of identical modules 202 and 502. This combined action leads to the induction of charges on the windings of each module separately, thereby reducing the energy required to produce electrical voltages of varying magnitudes on the windings and wires, a phenomenon reminiscent of Tesla coils. Furthermore, these specific magnetic fields on both sides of the ovate reactor, 304 and 504, give rise to multiple virtual walls. These serve to guide, collide, and separate ions based on their mass on top of reactor z800, and towards the bottom z801 of reactors 304 and 504. These separated ions are maintained near the electrodes 316 and 318, within the reactor core. The 304 reactor facilitates the draining of electrons and minimally ionized atoms that gravitate towards the reactor wall, redirecting them through return lines 316, 317a, and 317b, back to the primary tubular container 2. Here, the atoms are re-ionized and accelerated, perpetuating the cycle of ionization and return. These magnetic fields exhibit specific characteristics, including tesla strength, frequency, and direction, which collectively contribute to the device's overall functionality. The magnetic fields serve various purposes within the embodiment. At least two windings are responsible for generating high voltage, while others produce low voltage. Certain magnetic fields facilitate acceleration, while others function to redirect ions away from the left and right sides of the reactor or the inner section of the tube bodies, redirecting them towards the desired acceleration direction or the center of the reactor chamber. Additionally, individual magnetic fields can function as virtual walls and separators, allowing for the segregation of ions based on their weight or speed within the top-to-bottom region of the reactor chamber. Each magnetic field fulfills a unique role and plays a vital part in ensuring the efficient operation of the device.

[0189] [Fig.9] is a perspective view of an internal support structure of the power generation unit 402 according to [Fig.12]. The power generating unit 402 comprises a first tubeshaped structure in the form of the ionization device 202 adapted for conveying a first fluid in a fluid flow as described above and a second tube-shaped structure 502 adapted for conveying a second fluid in a fluid flow, wherein a reactor 504 is provided with a first inlet 306 in fluid communication with a downstream end of the first tubeshaped structure 202 for receiving a first ionized fluid flow and a second inlet 506 in fluid communication with a downstream end of the second tube- shaped structure for receiving a second ionized fluid flow. The first inlet 306 and the second inlet 506 are directed opposite each other in a way that the first ionized fluid flow and the second ionized fluid flow are directed towards each other during operation, wherein there is a high likelihood of collisions of the mentioned electrically charged species. The power generation unit 402 comprises an air pump 408 and a pressure regulator 410 arranged downstream of the air pump 408 and associated to the spiral shape of containers 4, 104. The air pump 408 and a pressure regulator 410 form bypass components in the beginning of the spiral of containers 4, 104. Further, the first tube-shaped structure 202 and the second tube-shaped structure 502 are arranged so that a central axis of the spiral shape of the first tube- shaped structure 202 is in parallel with a central axis of the spiral shape of the second tube-shaped structure 502. Further, the first tube-shaped structure 202 and the second tube-shaped structure 502 are arranged on opposite sides of the reactor. Further, the second tube-shaped structure 502 generally has the same shape and dimension as the first tube- shaped structure 202. For ease of presentation, only the main differences of the power generation unit 402 according to the second embodiment and the power generation unit 302 according to the first embodiment will be described. The power generation unit 402 according to the second embodiment is provided with a similar support structure for the transformers as the power generation unit 302 according to the first embodiment. Reactor 504 is shown in more detail in [Fig.14], 15 and 16. Reactor 504 comprises a second outlet 512 opposite the first outlet 312. Gases return line 317 is also present in the figure.

[0190] [Fig.17] depicts a cross-sectional view of the power generation unit, based on the configuration shown in [Fig.12]. The power generation unit 402 in the second embodiment features a similar return line and heat exchange structure as the power generation unit 302 in the first embodiment. Additionally, it includes two axial-middle heat exchange units 344 that are interconnected. These spiral return line right side 317b and left side 317b, heat exchange heat exchange units 344a, 344b are composed of two identical- baffled namely 348 and 346-axial-middle heat exchange units, which are connected to each other as shown in [Fig.10a]. The setup may also involve a gas cooler nozzle and a one-way valve 1011. Reactor chambers 504 or 304 are also present in the figure.

[0191] [Fig.5] is a perspective view of device 202 for ionization of a fluid according to a third embodiment comprising a plurality of containers 4 of the first type as in [Fig. lb] and a plurality of containers 104 of a second type as in [Fig.9], arranged in series in a spiral configuration. The spiral configuration comprises a plurality of complete turns. More specifically, [Fig.5] discloses a power generating unit 302 comprising the ionization device 202 forming a first tube-shaped structure and a reactor 304 provided with an inlet 306, see in fluid communication with a downstream end of the tubeshaped structure 202 for receiving an ionized fluid flow. This is a perspective view of a device 102 for ionization of a fluid according to a second embodiment comprising the container 4 of the first type as in [Fig. lb] and the container 104 of the second type as in [Fig.9] and 3a, wherein the containers 4, 104 are arranged in series forming a continuous arc. The fluid conveying connection element 84 is arranged between containers 4, 104 and mechanically connected to each one of the containers via a flanged connection [Fig.2]. More specifically, the reactor 304 comprises a tube-shaped portion 308 defining the inlet 306, wherein the tube-shaped portion 308 is provided with a flange 310 at a free end adapted for a mechanical connection with the tubeshaped structure 202 for providing a fluid communication. Further, reactor 304 is provided with at least one outlet 312 for the fluid. The power generating unit 302 may further comprise a first return line (not shown) that is in fluid communication at the first end with the outlet 312 and at a second end with an upstream end of the tubeshaped structure 202. [0192] [Fig-9] is a perspective view of an internal Heat exchanger capsule body 344 of the power generation unit 302 according to [Fig.5]. The Heat exchanger capsule body 344 is provided radially inside of the spiral of containers 202. The Heat exchanger capsule body 344 has an axial-cylindrical shape. Further, a plurality of the containers 4, 104 in the plurality of containers forming the spiral shape are provided with at least one pair of electrodes 34, 36; 38,40, wherein an individual power supply in the form of a high voltage transformer 68, 14, 48,50 is associated to each electrode or pair, wherein the plurality of low voltage and high voltage frequency power supplies and /or other inner batteries or electrical cooling unit, control circuit 70,70/1,70/2, 70/3, 68 are mechanically connected to the Heat exchanger capsule body 344. The plurality of tubeshaped low and high transformers 2,4,10470 are mechanically connected to the Heat exchanger capsule body 344 and/or on row or two rows of 70,70/1,70/2, 70/3, 68 in a way projecting radially from the Heat exchanger capsule body 344. More specifically, the transformers are provided in sets of electrical component unit 70, wherein the electrical components in each set are arranged on top of each other. Further, a plurality of electrical component sets is optional and provided in a row next to each other in an axial direction of the Heat exchanger capsule body 344. Further, a plurality of such rows of sets of transformers are arranged in a spaced relationship in a circumferential direction of the Heat exchanger capsule body 344.

[0193] [Fig.10] is a cross-section view of the power generation unit 302 according to [Fig.9]. The power generation unit 302 comprises a return line 342 for conveying fluid exiting from the outlet 312 of the reactor 304 to the first end of the spiral, wherein the return line 342 is provided radially inside of the spiral of containers 4, 104. More specifically, the return line 342 forms a spiral shape with a smaller diameter than a diameter of the spiral formed by the plurality of containers 4, 104. More specifically, the plurality of containers 4, 104 arranged in series, the reactor 304 and the return line 342,317 forms a closed circuit. Two Link pipes 1010 of 344 a, 344 b or 304 and 304 b and a one-way valve 1011. Further, the power generation unit 302 comprises at least one heat exchange unit 344 for heat exchange of a secondary fluid with the fluid in the return line 342 for cooling the fluid in the return line. The heat exchange unit 344 comprises a chamber provided with the secondary fluid and wherein the return line 342 extends through the chamber. More specifically, the heat exchange unit 344 has the shape of a cylinder. According to the embodiment of [Fig.10], the heat exchange unit 344 forms the support structure for the transformers 68, 70. Further, the chamber of the heat exchange unit 344 comprises two axially spaced internal walls 346, 348 dividing the chamber in three compartments, wherein each compartment is provided with the secondary fluid, wherein the return line 342 extends through each one of the three compartments. [Fig.10a] displays the arrangement of interconnected axial-middle heat exchange units 344 in the form of spiral return lines 317b. The units comprise identical baffles 348, 346 and are connected to each other. The figure also includes a gas cooler nozzle, a one-way valve 1011, and a reactor chamber 504, 304. The illustration emphasizes the trajectory of vaporized gases derived from liquified cooling agents, highlighting varying thermal gradients, and promoting convection processes. The interconnected conduits 1010 facilitate the mixing of gases and liquids, facilitating automatic gas movement indicated by directional arrows.

[0194] [Fig.10a] illustrates the trajectory of vaporized gases, derived from liquified cooling agents such as Freon or nitrogen, at liquid phase level 874. This representation underscores the existence of zones with varying thermal gradients, where certain areas are notably warmer or cooler relative to others. These differences in temperature instigate convection processes that potentially induce automatic gas movement, specifically for gases labelled as 863. This circulation is expedited by the potential intermingling of gases and liquids within the interconnected conduits, designated as 1010, as suggested by the directional arrows. This arrangement significantly amplifies the cooling effect in areas experiencing higher thermal loads, while also assisting in maintaining the balance of the magnetic field, as evidenced by the depicted arrow directions. A notable feature of this cooling system is its operational autonomy, meaning it can function without the need for a condenser engine. This independence relies on the varying pressure levels of the cooling gas in its two states - liquid and gaseous. During periods when the device is either in standby or shutdown mode, the cooling gas predominantly transitions back to its liquid state, consequently causing a reduction in pressure within the 344 capsules. Additionally, the configuration might incorporate a gas cooler nozzle and a one-way valve, labelled 1011, which facilitate additional cooling of the gases during their circulation within the 1010 conduits.

[0195] [Fig. lb] provides an exemplar of two identical devices, designated as 2, situated on distinct rings in the schematic illustration. One of these devices is depicted with a protective cap, while the other is displayed without this cap to expose the internal components for examination. The cap's presence signifies that the device's interior framework can be safeguarded or enclosed. Central to the functioning and efficacy of the devices is the intricate interaction and resonance between the magnetic fields of the tubular containers and their winding and wires. The magnetic field created by one device interacts with the coils of the second device, echoing the phenomena associated with Tesla coil devices. Such an interaction holds considerable influence over the intensity of the electrical current and the energy transfer between the two units. Interestingly, this synergistic relationship can diminish the input power requirement and power consumption of the internal components, which is pivotal for achieving a stable and consistent output power level. This power conservation is more effectively realized if the tube has a spiral one rather than a straight configuration, as it optimizes the magnetic field interactions and energy transfers. Subsequently, [Fig. lb] presents a perspective view of a device, marked as 2, designed for ionizing a fluid, as per a primary embodiment. This view features a container, labelled as 4 of a specific type and a partially cut view of device 2, akin to that in [Fig. lb].

[0196] [Fig.lc] portrays a longitudinal cross-section view in alignment with cut A-A of device 2, as shown in [Fig. lb]. Similarly.

[0197] [Fig. Id] exhibits a transversal cross-section view in line with cut B-B of the same device.

[0198] [Fig. If] presents a schematic representation of a tube-shaped container, as depicted in [Fig. lb]. It highlights one possible configuration of device 2 (numerus pieces), illustrating 40st up to 4-2 arrangements for the windings 14, 46, 48, and 50. These windings can be combined or connected in series and parallel configurations. The image also highlights one of the 2 up to 4 potential arrangements for filling the electrode holes 26, 30, 28, and 32 with lamps 366, 466, 566, and 666, electric discharge 38, 39, and 48x, or arcs 36, 34, and 36/5. Additionally, it demonstrates the schematic setup of a Tesla coil device created by two windings of 14, 46, 48, 50n. These windings can function as ionization high-voltage electrodes and/or short- circuit low-voltage electrodes to create high frequency such as 36a, 36b, 36/4, and 48X. Additionally, this design incorporates a transistor or capacitor to generate high frequency, and a control circuit 326 which is sufficient for creating low voltage across all internal components of the power generator. This configuration can charge all standard batteries such as those found in electric cars 327 or buildings, offering an alternative to solar panel systems. A further option depicted in the multi power generator setup involves connecting the control circuit 326 and reactor 504 to external systems or devices. The control circuit 326 can also be connected to the electrodes or chemical electrodes of reactor 316,318. This design can power potential external consumers 328, such as pumps and turbine 328 ,1000, zlOOO electromotors. It facilitates algebraic summation of output power generation through series connections or individual power from external batteries 327, 328 or any end-user power consumer 333. This embodiment is versatile and can be used with containers situated close to or far from the reactor, such as downstream of a halfway container in a series of containers that form a spiral shape 1,12 or with straight tube-shaped containers.

[0199] [Fig.le] is a partly cut view from the side of the device as in [Fig. lb]. Schematic drawing of the magnetic field of each coil in each layer, the amount of magnetic charge and showing the possible output electricity of each windings wire, showing the direction of polarity and the direction of the flow of ions inside the tube. Coils close to the windings field are stronger 4 and if they are further away, the field is larger and their Tesla is lower, but it is compensated by changing the diameter of the coil and / or Functionality of each winding in general way. Referring now to [Fig. lb]. The first container 4 is adapted for conveying the fluid. The first container 4 has an elongated shape with an inlet 6 for fluid entry adjacent a first end 8 in a longitudinal direction of the elongated first container 4 and an outlet 10 for fluid exit adjacent a second end 12 in a longitudinal direction of the elongated first container 4. The device 2 comprises at least a first wire 14 of an electrically conductive material extending in a spiral shape around the first container 4, wherein the first wire 14 is adapted to receive a current for generating a magnetic field for acceleration of the fluid through the first container 4. The first wire 14 extends in a spiral shape that forms a continuous curve of constant diameter about a central axis 16 that is commensurate with a central longitudinal axis 24 of the first container 4. Device 2 further comprises a core 20 of a metallic material arranged radially inside of the first wire 14 and adapted for increasing the strength of the magnetic field. The metallic material of core 20 is a superconductor and preferably a ferromagnetic material or ferrimagnetic material such as iron. The magnetic core concentrates the magnetic flux and makes a more powerful magnet, complete first container wall 22 is formed by the core 20 of metallic material. The first container 4 has a rounded cross section shape and more specifically a circular cross section shape. Further, the cross section of the first container 4 is constant along the complete length of the first container 4. The first container wall 22 defines an inner chamber. The inner surface of the first container wall 22 has a diameter of about 20 mm. Further, the first container 4 has a shape such that the central longitudinal axis 24 extends along an arc. The first container 4 comprises two pairs of transverse openings 26, 28, 30, 32 extending through the first container wall 22. The two openings in each pair of openings are arranged opposite each other and in-line with each other. Each one of the transverse openings 26, 28; 30, 32 is adapted to receive an electrode 34, 36; 38, 40, see [Fig.le]. More specifically, the first container 4 comprises two pairs of pipeshaped portions extending in a transverse direction relative to the longitudinal direction of the first container 4 that define the openings 26, 28; 30, 32. More specifically, the pipe- shaped portion extends perpendicularly relative to the longitudinal direction of the first container 4. More specifically, the pipe-shaped portions are formed in one-piece with the first container 4. More specifically, the electrodes 34, 36; 38, 40 are arranged in the pipe-shaped portions in a gas tight manner for avoiding leakage. Further, the first container 4 comprises a connection flange 42, 44 at either end 8, 12 in its longitudinal direction. Device 2 comprises a second wire/windings 46 of an electrically conductive material extending in a spiral shape around the first container 4, wherein the first and second wires 14, 46 are provided at a radial distance from each other. Further, the second wire 46 is arranged to be inducted by the magnetic field generated by the first wire 14 for generating an electrical current for powering an electrically powered component. Thus, the first wire 14 and the second wire 46 forms a first pair of magnetically coupled coils. Device 2 further comprises a third wire/ windings 48 of an electrically conductive material extending in a spiral shape around the first container 4. The third wire 48 is adapted to receive a current for generating a magnetic field. The device 2 further comprises a fourth wire 50 of an electrically conductive material extending in a spiral shape around the first container 4. The third and fourth wires 48, 50 are provided at a radial distance from each other. Further, the fourth wire 50 is arranged to be inducted by the magnetic field generated by the third wire 48 for generating an electrical current for powering an electrically powered component. Thus, the third wire 48 and the fourth wire 50 forms a second pair of magnetically coupled coils. The four spiral- shaped wires are arranged in order from the first container wall 22 so that the first wire 14 is innermost and then followed by the third wire 48, the second wire 46 and the fourth wire 50. Device 2 further comprises a body 52, 54, 56 in the form of a pipe of a thermally insulating material provided radially between two adjacent wires. The first pair of such magnetically coupled wires 14, 46 may be designed for creating a sufficiently high voltage for supplying a pair 64 of electrodes for generating an electric arc for the ionization during operation of the device. The pair 64 of electrodes may be arranged in a downstream container, see further description in the following. The second pair of such magnetically coupled wires 48, 50 may be designed for creating a relatively lower voltage for supplying a light source 66 for the ionization during operation of the device. The light source 66 may be associated to a downstream container, see further description in the following. Device 2 further comprises a case 58 of a thermally insulating material arranged so that it encapsulates the first container 4. Case 58 of a thermally insulating material is arranged so that it encapsulates all wires 14, 46, 48, 50 wound around the first container 4. More specifically, case 58 is made of two case halves 60, 65, wherein each case half comprises a recess for receipt of a portion of the first container 4. The recess may be cylindrical. Case 58 may have a rectangular outer shape in a transverse cross section. The first electrodes 34 or 36 are arranged in the first container 4 opposite or beside each other and at a distance from each other. The electrodes 34, 36 may be arranged perpendicularly relative to the longitudinal direction of the first container 4. More specifically, the electrodes 20, 22 are arranged so that they extend in a horizontal plane. The electrodes 34, 36 are shown in an enlarged view in [Fig.lh]. The electrodes 34, 36 are arranged at a distance from each other in a range of 2-4 mm. Further, each one of the electrodes 34, 36 in the first pair has an elongated shape with a circular cross section and a pointy end 72, 74. The electrodes are arranged so that the pointy ends 72, 74 face each other. More specifically, each one of the electrodes 34, 36 in the first pair has an elongated shape with a pointy end 72, 74 defining an angle in a range of 20-35°. In other words, each one of the electrodes 34, 36 has a sharp or round tip. More specifically, the electrodes 34, 36 in the first hole’s pair are straight and arranged in-line with each other. More specifically, the electrodes 34, 36 in the first pair are in the form of rods. The electrodes 34, 36 in the first pair may be termed needle electrodes. The electrodes 34, 36 in the first pair are formed in a metallic material and more precisely in the material tungsten (also called wolfram coated with nano materials) as an example. The design of the electrodes 34, 36 with sharp tips 72, 74 creates good conditions for creating different type of discharges from the surface of the tip having an inclination relative to the longitudinal direction of the elongate electrode when affected by a fluid flow. More specifically, a first set of arcs may be created extending from the electrode tip in a downstream direction. Further, a second set of all types of arcs may be created extending from the electrode tip in an upstream direction. It will be described in more detail below in association with [Fig.lh]. Device 2 further comprises a power supply 68 adapted to supply such a voltage to the first pair of electrodes 34, 36 that both electrodes are positively charged and therefore emit electrons. It is schematically shown in a schematic top view in [Fig.lh], wherein the arrows 76, 78 indicate paths of electrons emitted from the tips of the electrodes 34, 36. Further, the first container 4 is adapted for conveying the gas in a flow past the first pair of electrodes 34, 36, wherein the gas flow may form a negatively charged region 80 between the electrodes 34, 36 for interaction with the emitted electrons from the electrodes so that a first arc structure 82 may be created between the electrodes 34, 36 for ionization of the gas. [Fig.lh] is a schematic front view of the first discharge’s structure 82 created in the container according to [Fig.lh]. It may be noted that the first arc structure 82 comprises a plurality of electric discharges between the electrodes 34, 36. Further, each half-arc/discharges has a zigzag shape in the form of saw teeth. It should be noted that the zigzag arc shapes shown in [Fig.lh] and [Fig.lh], are magnified and much bigger than the actual size in relation to the size of the electrodes 20, 22. The zigzags are in microscopic scales. Also, their plurality is much higher than the number of arcs shown in the figures. Device 2 may include an additional set of low voltage or high voltage power supplies, represented by the number 70, which can encompass multiple components positioned within the same place and holder. These power supplies are specifically designed to deliver the required high voltage high frequency to both electrodes or DC high voltage at their respective holes if needed, or This enables the generation of complete arcs-arc. Moreover, the power supplies 70 can serve the purpose of consolidating space, potentially replacing, or combining as holders for batteries 70/2 or cooling electronic components 70/3 that They facilitate the production of low voltage electricity by utilizing tolerance and variable heating in the surrounding environment. Additionally, smaller control circuit units can be situated together with the power supplies or separately, within at least one or two ring levels positioned between the heat exchanger units and tube-shaped units. The device 2 further comprises a fluid conveying connection element 84 adapted to be arranged between two adjacent containers 4, wherein the fluid conveying connection element 84 comprises a fluid conveying channel 86 providing a fluid communication between the containers. More specifically, the fluid conveying connection element 84 is adapted for conveying a first part of an incoming fluid flow in a circumferential direction to one of the containers 4 arranged downstream of the fluid conveying connection element 84 in a fluid flow direction. Additionally, or alternatively, the fluid conveying connection element 84 can be equipped with an extra winding layer with additional wrapping and increased thickness, connected to the control circuit to apply an individually stronger pulsating magnetic field if needed. The fluid conveying connection element 84 comprises a flange 88 [Fig.2], 90 at either end in an axial direction of the fluid conveying connection element for providing a mechanical connection to each one of the adjacent containers 4. In addition to [Fig.le], two schematic magnetic fields of two windings are also shown as an example 14,46 along with the input current of a winding IW 1 or 2 to 14 or 46 and the output current of a winding OW 1 or 2 to 14 or 46. A schematic view of two lines of magnetic flux, Outer winding flux OWF #1,2, 14,46 or Inner winding flux IWF#1 and 2 around each of the windings 14 or 46 or 48 or 50, etc. is also depicted, indicating the direction of S and N polarities of each winding through solenoid magnetic fluxes. The direction of the force (F) described by the solenoid and Lorentz force law in a tube structure for ion acceleration is illustrated in [Fig.le]. This type of figure aims to provide clarity for general readers who may not have fully understood or correctly analysed the Lorentz force law and the solenoid effect within a winding layer tube structure. Given the complexity of visualizing these phenomena in a 2D view, additional references on magnetic fields in solenoids are recommended for more comprehensive information. The intention is that [Fig.le] will help individuals visualize the fundamental phenomena involved in the physics of solenoids and magnetic fields, thereby rectifying common misconceptions. By providing a clear and detailed illustration, [Fig.le] aims to bridge the gap between theoretical understanding and practical application, ensuring that the underlying principles are accurately conveyed and comprehended. This approach helps demystify the interaction of magnetic fields and forces within a solenoid structure, highlighting how these forces can be utilized for ion acceleration and other applications. For more information, readers are encouraged to explore detailed texts and research papers on the topics of solenoid magnetic fields, the Lorentz force, and their applications in modern physics and engineering. Understanding the intricacies of these principles is crucial for advancing knowledge in electromagnetic theory and its practical implementations in various technological fields.

[0200] [Fig.14] provides a perspective view of a reactor within the power generation unit as depicted in [Fig.12]. A similar perspective is provided in [Fig.14] ,6, where the reactor 304 is shown within the power generation unit outlined in [Fig.5]. The reactor, numbered 304 or 504, features a generally egg-shaped design. This shape extends considerably longer in one direction than in the second direction, which is perpendicular to the first. To clarify, the reactor possesses an elongated, continuously rounded form, appearing oval in longitudinal cross-sections across two perpendicular planes. The rounded shape of reactor 304 creates conditions conducive to withstanding relatively high internal pressures. Additionally, the reactor wall is made from high- strength and high heat-resistant materials. A potential location for the return line 312 connection is also indicated, which is situated roughly at the middle of the reactor's body surface. The possible connection of reactor 805-806 at the bottom part of the reactor body is also demonstrated. This connection serves as a boiler; the inlet water 999 to pipe 806 and regular water999 pass through zone z900, subsequently producing steam water at junction 805 for a turbine zlOOO in larger reactor systems or quantum power generator devices. In contrast, smaller reactors exhibit a unique design where connections 805 and 806 are closed off with a plug or fitting junction. These smaller reactors use a weak acid and operate as internal batteries, as previously described in the summary paragraphs.

[0201] [Fig.15] illustrates a first cross-sectional view of the ovel/egg-formed reactor from [Fig.14],

[0202] [Fig.23] the reasoning behind the positioning and design of each element is demonstrated. This is evident in the symmetric design for elements such as liquid junctions 805,836, inlet gas junctions 306,506, outlet or return lines 312,512, and electrodes 316,318 along with their junctions 316j, 318j. The symmetric counteraction and availability of each node and point on the egg-oval shape enhances concentration and guides each part of the ion movement. This freedom allows ions to strike the walls and be automatically directed to the desired hole. The spatial hydrolytic of zone 801 and the automatic mixing of ionized gases with high concentration result in ions adhering to the cathode or anode 316,318. The ions are then absorbed and supply the necessary electrons until a second circuit is required. At this point, the circuit is closed, and the remaining ionized or unionized molecules and atoms are directed to the 312 or 512 return line pipe, or spiral return pipes. These elements circulate in a closed loop until the considered reaction occurs. This cycle continues automatically due to the pressure and negative pressure created by acceleration in tube-shaped containers. [0203] [Fig.16] offers a second cross-sectional view of the reactor from [Fig.14], emphasizing the directional movement of electrons 891,871, 873 and protons 892. The operation of the system significantly depends on the schematic geometric placement of the cathode and anode electrodes 316,318, along with the inlet and outlet pipes. Accurate positioning of the electrodes and holes within the device is critical to ensure an ideal flow of electrons and protons. The reactor's unique egg-shaped design enables strategic placement, fostering efficient interaction between fluid ions and electrodes. This factor enhances the efficiency of such reactors for quantum power generators, particularly for cold fusion electrochemical reactions. Moreover, this design helps prevent the ionization process from leading to nuclear fission during continuous and long-term operation, as previously described. The placement of the inlet and outlet pipes also promotes smooth and controlled fluid flow throughout the system, optimizing its overall performance. In an alternative embodiment, the reactor includes an extra central holed sphere 800, contributing to zone z800. This configuration improves the collision of incoming ionized flows. Gas enters the central holed sphere z800 from either side. Regardless of whether the gas entry is from right 506 or left 306, gases within the holed sphere collide and react in this zone. The remaining atomic bodies support this process, passing through the holes and getting deflected upwards, downwards, or sideways. They may strike the reactor body or be guided within magnetic fields. They are then directed towards the center of the reactor body under high pressure and are led to two closed return loops. This design bolsters the interaction between the incoming ionized flows and the reactor, enhancing the reactor's overall performance. The metallic body of the holed sphere can be connected to a cathode or anode via a wire rod, facilitating the direct extraction of electrons or temporary retention of positive ions. This arrangement increases the mobility of negative ions, positive ions, electrons, or positrons, improving their interaction with the ion's electron cloud or electrostatic field of suspended electrons. As these particles collide, mix, and interact with photons and electrons, they generate waveforms such as alpha rays. This process produces energy either as heat or by increasing the kinetic energy of the molecules. Additionally, this process amplifies ionization, leading to a heightened potential for acceleration within the tube-shaped reactors' magnetic fields. This action contributes to producing more low-voltage electricity through the induction of some magnetic fields within the windings. Furthermore, this setup aids in the process of electron drainage or absorption, thereby optimizing the energy production and efficiency of the reactor 506,306.

[0204] [Fig.16a] presents a schematic drawing of the top view of the reactor 506,306. It illustrates the locations of the chemical electrodes (cathode and anode) 316,318, the holed sphere body 800, and the central collision zone z800. It also shows various movements, including potential movement directions 871, 891, 873, 314, of lighter ions and heavier ions or atoms. After these particles collide with each other or hit the wall, they follow different paths at varying angles and speeds, in accordance with Newton's first and second laws, the law of gravity, and thermodynamic laws.

[0205] [Fig.16] provides a detailed representation of the reactor's design and its operational mechanisms. The positioning of the cathode and anode electrodes 316,318, along with the inlet and outlet pipes, greatly affects the system's functionality. Correct placement of these components is essential for maximizing electron and proton flow within the reactor. The unique egg-shaped design of the reactor allows for the strategic placement of these components, promoting efficient interaction between the fluid ions and the electrodes. This enhanced interaction leads to increased. Efficiency of this type of reactor, particularly beneficial for quantum power generators. In the context of cold fusion electrochemical reactions, this design becomes even more critical. The proper flow of electrons and protons, combined with efficient ion-electrode interactions, can significantly boost reaction efficiency, thereby maximizing the power output of the generator. A detailed understanding of these movement dynamics and component placements is therefore central to the optimal operation of the reactor and its potential applications in quantum power generation. These movements abide by various principles, such as the internal energy of a monoatomic ideal gas, the first and second laws of thermodynamics, the law of center of mass, linear momentum, one-dimensional inelastic and elastic collisions, chain reactions of elastic collisions, devices with variable mass, motion of the center of mass, and stability of linear momentum during a collision. The impact of the motion of the center of mass of three particles also influences these movements. All these factors govern the movements of ions and atoms within the reactor. The movements of ions, atoms, and electrons within the virtually separated layers 832,833, created by the magnetic field of the body of the second tube-shaped structure 502, play a crucial role in the reactor's operation. This second tube-shaped structure generally mirrors the shape and dimensions of the first tube- shaped structure 202. The separation of light and heavy particles through these layers aids in controlling the reaction and enhances the efficiency of electron drainage. This design leverages the loosely bound electron atoms to facilitate unstablemerging fusion/ semi-fusion, yielding more quarks, muons, or alpha rays from the core and nuclear body. By separating and compressing these particles and increasing their concentration in certain parts of the reactor, the device can maintain efficient operation over extended periods. While illustrating and explaining these movements in a 2D format or on paper can be challenging due to their complexity, the primary phenomena have been described here. Many aspects of these processes remain unknown to scientists, but this device aims to enhance efficiency by further exploring these phenomena. A more detailed explanation of the reasons, mechanisms, and methods will be provided in the future, following the patent process. This will further elucidate the operations of the device and contribute to the scientific understanding of these complex phenomena.

[0206] [Fig.8] provides a schematic representation of a power control system and a power generator reactor unit. It illustrates the movement of ions, electrons, and positrons in different sections of an egg/rectangular shaped reactor chamber. The diagram also shows an example of how windings 14, 46, 48, and 50, as well as tube-shaped containers 2, 2/1, 2/2, and 2/40 from module 202 and 502, are interconnected. These components play a crucial role in the functioning of the system by contributing to both the control circuit 326 and the external circuits 327, 328, and 330. [Fig.8] presents a schematic of the power control system, also known as control circuit 326, along with the power generator reactor unit 304 in the power generation unit. The diagram demonstrates the direction of current flow in wires 320 and 322, the external circuit, and consumers 327, 328, and 330. Moreover, it illustrates the trajectory of ions, electrons, or positrons in the top, middle, and bottom sections of an egg or rectangularshaped reactor chamber. It also indicates the movement direction of electrons and positrons in water or weak acid medium, which function as a boiler and a battery, respectively. Reactor unit 304 is designed to facilitate electrochemical reactions within its chamber 314, guided by the flow of ionized fluid. The reactor chamber houses two electrodes, an anode 316 and a cathode 318arranged in a spaced relationship. The anode 316 is responsible for releasing electrons, as represented by arrow 320, into the external circuit 324, while the cathode 318 acquires electrons, indicated by arrow 322, from the external circuit during the electrochemical reaction. The external circuit 324 is interconnected with a control unit 326, which is devised to regulate power flows. This control unit is operationally linked to potential external power storage mechanisms, such as battery 327, and to external power consumers, like an electric motor 328. It delivers power, generated by reactor 304, to these components. Additionally, the control unit 326 is operationally connected to internal power consumers 330 like a pump, light source, transformers, and so forth within the ionization device 202, providing them with power from the reactor. Furthermore, it is capable of drawing power from external storage units like the battery 327 to supply to internal power consumers and windings layer functionality and their arrangements in series and parallel connection schematically 330. As mentioned in [Fig.14], reactor 304 consists of an electrolyte 332 and an insulation plate 334. The electrodes 316 and 318 extend inside the reactor chamber, partially submerged in electrolyte 332. Fluid portions exiting the end of the ionization spiral are directed to the space between the electrodes 316 and 318, above the insulation plate 334. The composition of this arriving fluid, which may be a plasma mixture of free electrons, quarks, and other positively charged ions resulting from ionization, relies on the input fluid and the acceleration acquired in the spiral. The movement direction of these electrically charged species is indicated with arrows at the top of the reactor. In the bottom section of the reactor, inside the electrolyte, the charged species can move towards the anode 316 and cathode 318. The movement of these charged species in both areas, namely above and below the insulation plate 334, can generate an electrical current to power external devices, akin to a car battery or a regular fuel cell. However, the collision of positively charged ions in the top section of the reactor can produce a substantial amount of energy within a confined space. Even if some collisions do not induce cold fusion, they can still liberate substantial energy during thermal and electrochemical reactions. The harvested electrochemical energy is used to generate power via an electrical current, while thermal energy facilitates these electrochemical reactions. The amalgamation of pair production and arc ionization can enhance the probability of generating alpha rays, muons, and quarks. These interactions augment the kinetic and potential energies of atoms, accelerating the release rate of electrons from their cores. Consequently, the cores become unstable and prepared to release quarks and other types of subatomic particles during high-pressure collisions within the reactor.

[0207] [Fig.11] portrays a graph delineating the operational method of the power generation unit. The time span from t = 0 to t = t2 illustrates the start-up phase of the power generation unit 302. The period where t > t2 signifies the operational phase of the power generation unit 302. During the start-up phase of the power generation unit 302, an internal and/or external power source, such as a battery, may provide the ionization and acceleration devices 202 with power to operate the transformers, a fluid pump, light sources, and magnetic coils. The external power source input eV may range from 12v or 24 v to 220 v or 240 v or even higher. The period from t = O to t = tl denotes a time lag wherein the power generation unit does not produce power until the device process attains the requisite level of ionization and acceleration to induce one of the windings and reconcile the potential difference with the secondary external circuit or control circuit. When the power generation unit 302 begins to generate power at t = tl, a lesser power input is required from the external power supply, if necessary. The power generated by the power generation unit 302 can be represented by any one of the lines A, B, or C. At time t = t2', the power produced by the power generation unit 302 is adequate to power all internal components. Furthermore, during the period t > t2, the power generation unit 302 may supply power to the battery for storage. Point d/D signifies the breakeven point for total internal or external consumption. Point E represents energy storage, battery usage, power consumption, or capacitor discharge. When the device's workload decreases, it shifts to standby mode until point G or until it supplies additional external consumers or adds more power output, such as a boiler or turbine connected to the reactor. This can be done through the device's control circuit to generate more electricity for municipal demand. The presented graph is an example for smaller devices, and for larger ones, the eV/watt level total will be doubled or duplicated on an extended graph with the algebraic sum of all voltages produced by the multi-power generator. Point G symbolizes the device's reboot to recharge or regenerate energy. This process will repeat until external demand appears in the control circuit or consumers. It continues until the gases deplete their power and need replacement or refilling with new gas feeds or electrons with the reverse direction of the control circuit. Line A represents a rapid hot fusion reaction that reaches thermal equilibrium t2=eV more quickly with the help of a boiler and turbine unit z 1000, 1000. Line C, in contrast, depicts a slower cold fission reaction that takes more time to reach t2=eV. On the other hand, Line B signifies the metaphase, an intermediate stage of electrochemical reaction occurring prior to nuclear fission and fusion. In the metaphase, the ionized molecule retains some of its electrons, and the nuclear shell is yet to disintegrate. High-speed impulses and impacts on the electron clouds and weak atomic nucleus may potentially lead to the release of quarks or microparticles from the nucleus, resulting in the emission of alpha microwaves equivalent to at least 2 mega electron volts of energy per alpha ray. This energy surge, in the form of kinetic energy for ion acceleration, is enhanced by the inductive magnetic field generated by the corresponding windings. According to Faraday's law, this process also aids in electricity /power generation from wave energies. The swift and unstable fusion/ semifusion occurring during this intermediate state merges aspects of nuclear fission and fusion. In an ideal METACIROP/current embodiment and method power generation device, this process can be safely controlled and implemented.

[0208] [Fig.20] is a perspective view of the power generation unit in [Fig.12] enclosed in a casing, [Fig.20] illustrates a perspective view of the power generation casing 404 for unit 402, as shown in [Fig.12]. The casing is coated with a nano chemical material, both internally and externally, acting as a protective barrier. This coating serves as a shield against any waves emitted from the quantum power generator, ensuring that they do not escape outside. The casing is designed in the form of a metal capsuleshaped body to enhance containment and prevent any potential leakage of emissions from the generator. Conclusion, it is to be understood that the present invention is not limited to the embodiments described above and illustrated in the drawings; rather, the skilled person will recognize that many changes and modifications may be made within the scope of the appended claims. According to the description above, the electric arc ionization arrangement according to the first embodiment is adapted for supplying the electrodes in one pair with the same electric charge (positive) for emitting electrodes from both electrodes. According to one alternative, the electrodes in one pair may be provided with opposite charges (positive and negative). Further, various kinds of arc structures may be created, such as glow discharge corona and electric spark. Accordingly, other arrangements and designs of the electrodes may also be applicable. According to the description above, all containers in the spiral have the same shape and dimension. According to an alternative, some containers may be longer than others. For example, the containers of the second type may be longer than the containers of the first type. According to the description above, all containers in the spiral have two pairs of electrodes. According to an alternative, some containers may be provided with a different number of electrodes or without electrodes. Accordingly, some containers may not be provided with radial openings through the container wall for receipt of electrodes. For example, the container of the second type may be designed without openings for electrodes. According to a further example, one container may be specifically designed for the ionization and another container may be specifically designed for acceleration of the fluid. Thus, the plurality of containers in the series of containers may comprise containers of further types, in addition to the first type and the second type. According to one alternative, the ionization device comprises a magnetic field generating arrangement, which is adapted for generating a magnetic field in the vicinity of at least one of the pair of electrodes in the second container for affecting the arc structures for supporting the ionization of the gas. The magnetic field generating arrangement may be arranged outside of the second container.

Claims

Claims

[Claim 1] A power generating apparatus comprising,

- at least one curved tubular structure 2, 502, 317 designed fo r fluid conveyance and recycling, shaped in X, Y, and Z dir ections around central axis.

- the tubular structure 2, 202 adheres to a spiralling path 502, maintaining a consistent diameter curve around a central ax is, and further comprises a sequential series of containers 4,

104 with an axial heat exchanger unit 344.

- at least one a configuration 2, 102 designed to create a simu Itaneously magnetic field, ionize, move and accelerate the i onized fluid, generate electricity along the entire path of mo vement by ionized flow inside the tubular structure 2.

- an egg-shaped reactor 304, 504 equipped with a primary in let 306 in fluidic communication with the downstream term inus of all tubular structures 202 for accommodating an ion ized fluid stream, wherein the reactor 304, 504 facilitates el ectrochemical reactions within its chamber 314 instigated b y the ionized fluid stream, two chemically active electrodes 316, 318 positioned at a distance within the reactor chamb er 314, wherein the first electrode 316 serves as an anode, c ontributing electrons to an external circuit 326, 330, 328, 3 27.

[Claim 2] The power generating apparatus as per any preceding claim, wherein the primary tubular structure 202 is designed to transport a first fluid and the apparatus includes a secondary tubular structure 502 designed for the conveyance of a second fluid, the reactor then includes a second inlet 506 in fluidic communication with the downstream end of the second tubular structure for receiving a second ionized fluid stream.

[Claim 3] The power generating apparatus according to any preceding claim, wherein the first 306 and second inlets 506 are oppositely directed, causing the first and second ionized fluid streams to converge during operation.

[Claim 4] The power generating apparatus according to any preceding claim, wherein the primary and secondary tubular structures 202, 502 are aligned such that their spiral central axes run parallel to each other.

[Claim 5] The power generating apparatus according to any preceding claim, wherein the primary and secondary tubular structures 202, 502 are symmetrically positioned on either side of reactor 504.

[Claim 6] The power generating apparatus according to any preceding claim, wherein the secondary tubular structure 502 approximates the shape and dimensions of the primary tubular structure 202.

[Claim 7] The power generating apparatus according to any preceding claim, wherein the reactor 304, 504 incorporates at least one outlet 312, 512, and the apparatus features at least one return line 342 in fluidic communication at one end with the outlet 312 and at the other end with the upstream end of the primary tubular structure 202.

[Claim 8] The power generating apparatus according to any preceding claim, wherein the return line 342 forms a spiral shape with a smaller diameter than the spiral formed by the primary tubular structure 202. The return line 342 is positioned radially within the primary tubular structure 202. The primary tubular structure's 202 exterior surface diameter lies within the range of 10-50 mm, particularly within the 10-30 mm range, and preferably within the 15-25 mm range.

[Claim 9] The power generating apparatus according to any preceding claim, wherein the apparatus includes at least one heat exchange unit 344 for the purpose of exchanging heat between a secondary fluid and the fluid in the return line, thereby cooling the fluid in the return line.

[Claim 10] The power generating apparatus according to any preceding claim, wherein the reactor's 304, 504 wall features a rounded extension, and the reactor's 304, 504 wall cross-section assumes an oval shape.

[Claim 11] The power generating apparatus according to any preceding claim, wherein the apparatus includes multiple winding layers functioning as a transformer’s windings /coil 2, capable of generating a voltage level with different frequencies independently at the same time 330. Voltage regulation and flexibility can be implemented at the start or middle of each winding 14, 46; 48, 50, by a smart control circuit or fixed points physically.

[Claim 12] The power generating apparatus according to any preceding claim, wherein the apparatus incorporates a pressure regulator 410 that forms a bypass component in the primary tubular structure and includes means for connecting and disconnecting the pressure regulator 410 to and from the fluid stream.

[Claim 13] The power generating apparatus according to any preceding claim, wherein the apparatus comprises an arrangement of at least two winding layers, simultaneously One winding layer generates a magnetic field to accelerate the fluid, while another layer acts as self-inducted windings magnetic filed to generate a voltage in the winding in series and parallel connections.

[Claim 14] The power generating apparatus according to any preceding claim, wherein the fluid acceleration arrangement includes a conductive wire 14 extending in a spiral around the primary tubular structure's wall. The wire is designed to receive current to generate a magnetic field. A metallic core 22 is positioned radially within the first winding wire to enhance the magnetic field strength, inducing other winding wires.

[Claim 15] The power generating apparatus according to any preceding claim, wherein the apparatus incorporates more than two conductive wires 14, 46, 48, 50 extending in spiral shapes around the primary container. The wires are placed at a radial distance from each other, with one winding wire 46; 50 arranged to be induced by the magnetic field generated by the other wire 14; 48 to generate an electrical current to power an electrically driven component.

[Claim 16] The power generating apparatus according to any preceding claim, wherein the apparatus includes a starter pump 408 that forms a bypass component in the primary tubular structure and includes means for connecting and disconnecting the starter pump 408 to and from the fluid stream.

[Claim 17] The power generating apparatus according to any preceding claim, wherein the apparatus includes at least one axial-middle heat exchanger unit 344 and baffles 348,346 serving to cooling. This heat exchanger connected axially to prevent melting and cools the other parts such as 2, 102, 304, 302, 312, 504,202,70, without need for an external condenser. Additionally, internal spiral tube 317 effectively cools the secondary ionized gases.

[Claim 18] The power generation unit facilitates mix of normal gases and/ or heavy gases, such as Radon, to enhance the overall chance of quantum batteries, power generation and/or fusion rection by inherent ability to release a considerable number of free electrons. These gases can play a role as a pressure lever for additional pressure on lighter ions collision within collision zones 800 or holed perforated sphere 800, simultaneously.