TW202021257A - 3-phase dc/ac converter with sequential energy extraction - Google Patents

Abstract

A sequential extraction control device for use in a 3-phase DC/AC converter. The 3-phase converter has three single-phase DC/AC converter each controlled by a respective PWM extractor. Duty factor adjustments are made depending on a current portion of an AC power cycle. A sequential regulator causes the PWM extractors to have non-overlapping duty cycles such that extractions of each of the single-phase DC/AC converters is performed in sequence, rather than concurrently. This improves the efficiency in extracting power from the DC power.

Description

Three-phase DC/AC modulator with sequential power extraction

This case is about a modulator, and particularly about a modulator that can track and optimize power usage.

Single-phase "DC to AC" (DC/AC) modulators can convert "DC" (DC) power (energy) sources into "AC" (AC) power that meets grid specifications. Under the grid specifications, the AC power ripple carried on the grid must be a sine (/cosine) waveform with a specific fixed peak voltage and a specific fixed frequency.

A traditional 3-phase DC/AC inverter can provide AC power to three pairs of power lines, and each pair of power lines must have a phase difference of 120° (called “A-phase, B-phase, and C-phase”). The core architecture of a three-phase DC/AC inverter is composed of three single-phase DC/AC inverters. Each single-phase inverter performs the extraction and conversion of DC power, and then transmits the AC power with the same root mean square power to the corresponding power line. One of the single-phase DC/AC inverters supplies AC power with A-phase to the first pair of power lines. The second single-phase DC/AC inverter supplies AC power with B-phase to the second pair of power lines. The third single-phase DC/AC inverter supplies AC power having the C phase to the third pair of power lines. In other words, each of these three single-phase DC/AC inverters extracts approximately the same amount of DC power; and then extracts The received DC power is converted into AC power. The three AC power supplies must be 120° in phase with each other; then 3 inverters will send 3 sets of AC power into the grid with 3 or 4 power lines. Therefore, each pair of power lines carries a single-phase AC power of the same frequency and has approximately the same rms power as the AC power of the other two pairs of power lines; and the phase difference between each other must be 120°. The professional terms described in the professional field of this article: "inverter", "converter" and "modulator" (and in terms of "inverter", "conversion" and "modulation") are interchangeable , So they are used interchangeably in this article.

The scope of the claims of this patent is not limited to solving the shortcomings of the aforementioned actual cases or their use environment. More precisely, the background description of this patent is only provided to illustrate one technical field in the applied example.

The embodiment described herein relates to a sequential controller; it is applied to a 3-phase DC/AC modulator, which enables three single-phase inverters to extract power in chronological order. In the three-phase inverter; the first single-phase DC/AC modulator, which contains the first group of PWM power extractors, can extract DC power from the DC power source and convert to have the first phase, also The first set of AC power that meets the grid specifications. The second single-phase DC/AC modulator contains a second group of PWM power extractors that extracts DC power from the DC power source and converts it into a second group of AC power with a second phase that also meets the grid specifications. The third group of PWM power extractors of the third single-phase DC/AC modulator extracts DC power from the DC power source and converts it into a third group of AC power with a third phase that meets the grid specifications. Among the three groups of single-phase inverters The duty cycle of the PWM power extractor is adjusted according to the current AC power cycle level.

When the sequential controller is used to guide the first group of PWM power extractors to perform power extraction, the first group of PWM duty cycles will be generated. Then guide the second group of PWM power extractors to generate a second group of PWM duty cycles when performing power extraction. Then guide the third PWM power extractor to generate a third group of PWM duty cycles when performing power extraction. This power extraction design method is different from the traditional 3-phase DC/AC inverter. This sequential controller can ensure that the PWM duty cycles of the first, second, and third groups will not overlap. The second and third sets of PWM power extractors extract power sequentially, rather than at the same time; this approach can improve the efficiency of extracting DC power from a DC power source.

This summary is provided in a simplified form to introduce some of the concepts used. These concepts will be described in detail later. The purpose of this review is not to define the key features or basic features of the scope of this patent claim, nor to assist in determining the scope of the claimed patent claim.

In order to make the above and other purposes, features, advantages and embodiments of this case more obvious and understandable, the attached symbols are explained as follows:

10‧‧‧sequence

101‧‧‧Photovoltaic solar panel string

201‧‧‧DC/DC Boost converter

223‧‧‧DC/AC modulation module

224‧‧‧Polar synchronization and exchange controller

225‧‧‧Transformer

300,6500B,6600B‧‧‧Grid

310‧‧‧simultaneous guide

510‧‧‧sequential regulator

4110‧‧‧Photovoltaic generator

4210, 4220 ‧‧‧ 3-phase DC/AC modulator

6000A‧‧‧Photovoltaic power plant

6111A, 6111B, 6112A, 6112B, 6221A, 6222A

6100A, 6100B, 6200A, 6200B

6130A, 6130B, 6130S, 6230A, 6230B ‧‧‧ 3-phase DC/AC modulator

6311B, 6312B, 6313B, D, DD‧‧‧ diode

6320B‧‧‧MEUPT controller

6351A, 6351B, 6352A, 6352B ‧‧‧ 3-phase AC wattmeter

6361A,6361B,6362A,6362B‧‧‧Energy meter

6410B‧‧‧Energy storage

6500A, 6600A‧‧‧Transformer

DFA‧‧‧Load working factor regulator

L,LL‧‧‧Inductor

Q,QQ,QA-QC,S1-S4‧‧‧switch

C‧‧‧Capacitor

In order to make the above and other objects, features, advantages and embodiments of the disclosure more comprehensible, the drawings are described as follows: Figure 1A shows the modules of the solar power generation sequence, used to explain and explain the professional terms mentioned in this article, such as power extraction, adjustment, regulation, DC/AC modulation, and the transmission of AC power; Figure 1B symbolizes Shows that the DC/AC modulator delivers a sine and cosine time-varying AC voltage representative of the AC message to oscillate the specific power supplied to the grid Figure 2A shows the single-phase power extraction/adjustment (or regulation) components described in the typical circuit of the Boost DC/DC modulator; Figure 2B shows the typical circuit of the Buck DC/DC converter The described single-phase power extraction/conversion component; FIG. 2C shows an interactive bridge structure composed of switching elements to control the polarity of the power output by the DC/DC Buck modulator; it can generate the output AC as shown in FIG. 1B Voltage oscillation; Fig. 2D symbolically shows the sine-cosine AC power ripple delivered by a DC/AC modulator to the interactive bridge structure switch; Fig. 2E symbolically shows that during a PWM duty cycle, it is adjusted by Booster The output DC power regulated by the converter includes three areas: Area-I represents the extracted energy, Area-II and Area-III represent the remaining energy area; Figure 3A shows the phase of the conventional 3-phase DC/AC modulator. Corresponding to the circuit of the power extractor; FIG. 3B symbolically shows the input DC power ripple in one PWM duty cycle; FIG. 3C symbolically shows the three power extractors in FIG. 3 in one PWM duty cycle Simultaneously captured power; Figure 4 symbolically shows the structure of a DC power supply DC power Pmx. This structure is provided to the two power supplies with the rated power Pmx declared by the DC power supply manufacturer without MEUPT components. Three identical 3-phase DC/AC modulators; FIG. 5A shows three circuits of A-phase power extraction, B-phase power extraction and C-phase power extraction using MEUPT modulator; FIG. 5B symbolically shows the adjustment by the sequential controller of FIG. 5A The time sequence of power extraction of phase A, phase B, and phase C; Figure 6A shows the power plant architecture diagram in the experiment of the implementation case. There are two sets of AC power production units in the architecture diagram, and each group of power production units is set A power meter and a kilowatt-hour meter are configured in it to measure the AC power and electrical energy output by each power production unit; and FIG. 6B shows that the power station in FIG. 6A is equipped with components including decoupling components and energy storage components. The revised architecture diagram, and the modified power plant was used to verify that it can improve the efficiency of power output to the grid.

All words used in this article have their usual meanings. The definitions of the above vocabulary in commonly used dictionaries. The use of any of the vocabulary examples discussed here in the content of this specification is only an example and should not be limited to the scope and meaning of this disclosure. Likewise, the disclosure is not limited to the various embodiments shown in this specification.

In this article, the terms first, second, third, etc. are used to describe various elements, components, regions, layers, and/or blocks that can be understood. But these elements, components, regions, layers and/or blocks should not be limited by these terms. These terms are only used to identify a single element, component, region, layer, and/or block. Therefore, in the following, a first element, component, region, layer, and/or block may also be referred to as a second element, component, region, layer, and/or Or block, without departing from the original intention of this case. As used herein, "and/or" includes any and all combinations of one or more related items.

With regard to "coupled" or "connected" as used in this article, it can mean that two or more elements directly make physical or electrical contact with each other, or indirectly make physical or electrical contact with each other, or two or more Components interoperate or act.

In this article, the term "circuitry" refers to a single system formed by one or more circuits. The term "circuit" generally refers to an object in which one or more transistors and/or one or more active and passive components are connected in a certain way to process signals.

Fundamentally, the 3-phase DC/AC modulator is composed of 3 single-phase DC/AC modulators. Each single-phase DC/AC modulator is used to perform the functions of power extraction, adjustment, and conversion of DC power into AC power; and then provide approximately equal AC root mean square power to three pairs of AC power lines; these 3 groups The phase difference of the AC power must be 120°. Therefore, if you want to understand the operation mechanism of the three-phase DC/AC modulator, you must have a clear understanding of the single-phase DC/AC modulator; especially for the "power (energy) extraction" function mentioned in this article . In addition, the meanings of power lines and cables mentioned in this article are interchangeable in this article and related professional fields.

U.S. published patents US2016/0036232 and US2017/0149250A1 disclose a discovery; that is, the traditional single-phase modulator can only capture, adjust, and convert, and the output is less than half from the direct current (DC) power input to the single-phase modulator DC power. From the teachings of these published patents: In order to effectively capture the DC power supply produced and convert it into electrical energy used on the grid, the characteristics of the designed power extraction components must match the power production unit to be effective (effective) and efficient (efficient) extraction of the generated DC power.

In addition, these published patents also teach that other components related to the power extractor must also be well matched to regulate and/or transmit the extracted power, so that the use of electrical energy is more efficient. Proposed according to the reference announcement document; the "maximum use energy tracker" should be used as the optimizer of the solar power plant. This optimizer is called "MEUPT optimizer" in this article and can be used to replace the optimizer used in existing commercially available photovoltaic (PV) power plants. This commercially available optimizer is often referred to as a "maximum power point tracking (MPPT) device". However, the more appropriate name for this commercially available optimizer should be called the "voltage point tracking (MPPPVT)" for maximum power production.

According to the published patent reference, the MEUPT optimizer is designed to capture "surplus energy" or "surplus power", while the "surplus power" defined in the reference patent is "the electrical energy (or power) produced, which is not captured. Extract and/or input electricity to the grid for use". The definition of surplus power (or surplus power) used in this text is also the same as the referenced published patent. Since the phase difference between the surplus power and the power grid is about 90°, the surplus power cannot be directly sold to the same power grid. However, in the reference patent, the MEUPT optimizer is also designed to temporarily store all captured surplus power in the energy storage; then the optimizer adjusts the stored electrical energy and sends it to the grid for use. Therefore, when the photovoltaic power plant is combined with the MEUPT optimizer, the income from power generation sales can increase.

In related professional fields, there are many technologies that can be applied to perform the so-called DC power extraction, power regulation, power regulation, and power transmission herein. In the principles described in this patented technology, these technologies are not necessarily related to production The type of DC power supply is related. However, in the case of this article, only the solar panel string is used as a DC power supply. And the actual situation of the solar power station is explained and explained in the professional terms mentioned in this article, such as power extraction, adjustment, regulation and transmission. In other words, the technical principles described in this article are not limited to the professional field of solar power generation. These technologies and principles can be used in a fairly broad power industry. Also, although "electrical energy", "electricity" and "power" have different meanings in physics, unless otherwise specified, they are usually used interchangeably in the professional field of electric power. In addition, although "AC power pulsation" and "AC voltage oscillation" also have different physical meanings physically, unless otherwise specified, they are also used interchangeably in this article.

Sequence 10 in FIG. 1A is used to illustrate the arrangement of photovoltaic power plant components. Sequence 10 starts with a photoelectric conversion component (photovoltaic solar panel string) 101, which can convert light energy (eg, solar energy) as initial energy into DC power, but the voltage of this power is often affected by various factors rather than stable. These factors include the shadow of the sun shaded by clouds, the angle of incidence of the sun, the uneven efficiency of different photovoltaic cells, and many other influencing factors. The produced DC power of a non-fixed voltage is adjusted and regulated to a constant voltage DC power (source) by the DC/DC Boost converter 201 connected subsequently. Then, through the DC/AC modulation module 223 connected to 201, the constant voltage DC power is converted into sine wave time-varying pulsating DC power. Then, through a polarity synchronization and exchange controller 224 installed behind the DC/AC modulation module 223, the sine wave time-varying pulsating DC power is converted into the positive (/cosine) time-varying voltage shown in FIG. 1B Oscillating AC power.

For example; the DC/AC modulation module 223 may be a Buck module operated by a pulse (wave) width (degree) modulation module (PWM); this Buck module It can also be regarded as a DC/AC inverter module; it converts a fixed voltage DC power into a sine wave time-varying pulsating DC power. FIG. 2C shows an example of using a bridge structure to form the polarity synchronization and switching controller 224. The component names of this structure are referred to as Integrated Bridge Gate Transistor in this article and related professional fields; This article is short for IBGT). As shown in FIG. 2C, the polarity synchronization and exchange controller (bridge structure) 224 includes 4 sets of switches (S1, S2, S3, and S4) to control the synchronization of the output AC power ripple of the DC/AC modulation module 223 And polarity. The "LOAD" shown in the figure represents the transformer 225 connected to the polarity synchronization and switching controller 224 and all electrical loads connected to it. The combination of the DC/DC Boost converter 201 and the DC/AC modulation module 223 may also be referred to as a "PWM power extractor" herein.

The AC voltage oscillation output by the polarity synchronization and exchange controller 224 must conform to the specifications of the power grid. The AC power ripple is adjusted by the transformer 225, and then AC power is transmitted to the connected power grid 300 (electric load). FIG. 2A shows a typical circuit of a DC/DC Boost converter 201. The DC/DC Boost converter 201 adjusts the varying DC power supply voltage to a constant voltage DC power supply. The circuit in FIG. 2B is a Buck module circuit operated by PWM in the single-phase DC/AC modulation module 223. This circuit converts the constant voltage DC power generated by the DC/DC Boost converter 201 into a time-varying sine/cosine DC Power pulsation. The interactive bridge structure (Switch bridge structure) 224 shown in FIG. 2C is used to adjust the time-varying DC power ripple output by the single-phase DC/AC modulation module 223 to meet the polarity required by the power grid, and AC power delivered by the grid is synchronized. Single-phase DC/AC modulation module 223 (or a combination of DC/DC boost converter 201 and single-phase DC/AC modulation module 223 is a module, called "PWM power extraction "Fetcher") is applied to a traditional single-phase modulation module (three single-phase modulators that constitute a traditional three-phase DC/AC modulator) as a module that performs power extraction/conversion.

Section 1: Discussing traditional DC/AC power conversion

Generally speaking, under actual conditions, the voltage of the maximum power generation point (MPPPV) of a photovoltaic solar panel string is an unfixed voltage value, and this DC voltage is usually less than the peak voltage specified by the AC grid. Therefore, photovoltaic solar panel strings require a voltage-boost power extractor to perform power extraction and adjustment; this power extractor can adjust an unfixed low-voltage DC power supply into a fixed high-voltage DC power supply.

Figure 2A shows the Booster circuit of the DC/DC Boost module 201. This circuit consists of the following components: an inductor L; a feedback adjustable load work factor regulator (FCDFA; not shown in the figure). Control switch Q; and diode D. In this circuit; switch Q can operate at high frequency (usually about 18kHz in commercial products), and it uses an adjustable duty factor (ADF) to perform on/off switching. FCDFA is used to adjust the load working factor, so that the DC/DC Boost module 201 generates a substantially constant DC output voltage (V ₀ ). In other words, the DC/DC Boost module 201 adjusts a DC power supply with a fixed voltage to a DC power supply with a fixed voltage v ₀ (typically, V ₀ =V _pk , where V _pk is the peak voltage of the AC power grid), so that the DC power supply The subsequent components connected in the circuit (that is, the DC/AC modulation module 223 in the case of FIG. 1A) can be matched. The DC/AC modulation module 223 then converts the DC power of a specific peak voltage into a sine/cosine time-varying power ripple that conforms to the grid specifications.

During the period when the switch Q maintains the path, the designed inductor L extracts power from the power input unit (in the case of FIG. 1A, this power input unit refers to the photovoltaic solar panel string 101). Specifically, the inductor L is charged by inputting electric power within a path period set by a PWM switch that feedback-controls the load operating factor. When charging occurs, the voltage V _SW on the switch Q increases and tends to the input voltage V _in until the voltage V _SW across the _switch reaches an appropriate balance value. During the period when the switch Q is open, the current from the inductor through the diode D will charge the designed capacitor C, generating a stable voltage equal to the output voltage demand (in the case of a grid connection, V=V ₀ =V _pk ). By using feedback control to adjust the load working factor, this load working factor at a properly designed fixed PWM frequency, adjusting the on/off period of the switch Q, can increase the output voltage from V _in to the peak voltage specified by the AC grid V ₀ =V _pk . Therefore, the voltage-Boost circuit can generate an appropriate peak voltage output to the DC/AC modulation module connected subsequently. The above circuit is called "Boost DC/DC converter" or "Boost converter" in the professional field of this article.

As mentioned earlier, Booster converters are designed to be able to adjust a DC power supply with a fixed voltage (such as a photovoltaic solar panel string) to a DC power supply with a substantially constant voltage. The voltage of the DC power supply can be equal to that specified in AC grid Peak voltage value. Note that in order to prevent the voltage decay of the peak voltage of the DC power supply during an AC power cycle of normal operation, the capacitor C in the Boost circuit shown in FIG. 2A needs to design an appropriate capacitance value. In other words, when designing the capacitor C, it is necessary to maintain a substantially constant voltage during the period of an AC power cycle. The capacitor used to maintain this constant DC voltage is called a "DC Link" capacitor in the professional field. In the grid code, the voltage variation that can be tolerated through the DC link must be very small, so The capacitors required for DC links are not designed to store large amounts of surplus energy. If it is used to store a large amount of surplus electrical energy, a huge (and expensive) capacitor with a very high capacity will be required to store the surplus electrical energy and maintain the output of the AC power after conversion to be stable at the maximum voltage regulated by the AC grid Allowable voltage fluctuation range.

A typical DC/AC modulation module 223 shown in FIG. 2B; which includes an inductor LL, a set of controllable switches QQ adjusted by a load duty factor regulator (DFA), a set of diodes DD and a set of DC link capacitors CC. The switch QQ is controlled by an adjustable load duty factor (ADF) at high frequencies (usually about 18 kHz in commercial products) to control on/off switching. Therefore, the switch QQ (usually regarded as a "PWM switch") is controlled by the PWM output signal. The load working factor of the PWM switch is adjusted by the DFA, so that the AC power ripple generated by the modulation module 223 conforms to the grid specifications. The proper name of the DC/AC modulation module 223 shown in FIG. 2B in the professional field of this article is called "Buck converter". The Buck converter 223 related to the DFA can convert DC power that meets the peak voltage specification into sine/cosine time-varying pulsating AC power. This time-varying pulsating AC power will be sent through the interactive bridge structure shown in FIG. 2C (FIG. 2C may be used as an example of the polarity/synchronization controller 224 of FIG. 1A); and then through the transformer (transformer 225 in FIG. 1A ) Transmit AC power to the grid (such as grid 300 in FIG. 1A). As mentioned above, the interactive bridge structure is a controller used to adjust the polarity and synchronization of the sine/cosine time-varying power ripple output.

As shown in FIG. 2C, when switches S1 and S2 are both turned on, and switches S3 and S4 are opened, a positive voltage is applied across the load. Conversely, when switches S3 and S4 are on and switches S1 and S2 are off, a negative voltage is applied across the load. when When these switches are controlled by a "synchronization director" (not shown in Figure 2C) or called a "synchronization director", the synchronous director will sense that the positive/negative voltage on the grid (or when zero voltage passes) is accurately converted Time, and use it to guide and execute the on/off switching function, the component of the polarity synchronization and the switch 224 and DFA can effectively control the sine/cosine time-varying power pulse output by the single-phase DC/AC modulator It can match the polarity of AC grid and synchronize with AC grid.

The synchronous regulator can adjust the time-varying PWM load working factor in time; generate a pure positive (/cos) sine pulse, which is the waveform of cos ² (ω t+θ), and ω is the output sine/cosine The angular frequency required for the time-varying power pulse, V _pk is the peak voltage of the required sine/cosine time-varying power pulse, and θ is the phase angle of the pulse, all synchronized with the corresponding power line on the power grid. When the synchronous guide combines the input DC pulse power with a fixed voltage and coexists with the parasitic inductance and parasitic capacitance on the power grid, the inductor LL and the capacitor CC can be reduced or even omitted in practical applications. The professional terms described in the professional field of this article: "inverter", "converter" and "modulator" (and in terms of "inverter", "conversion" and "modulation") are interchangeable , So they are used interchangeably in this article.

DFA adjusts the load working factor according to the design of the power ripple as a function of time to control the switch QQ of the Buck inverter module to perform the path/open circuit work. Therefore, with properly designed circuits and adjusted peak voltage, the Buck Modulation Module can generate the output voltage, power form, frequency and phase AC power required to meet the design requirements to meet the requirements of the AC grid specifications and The phase of power ripple existing on the corresponding power line of the grid. In the case of connection to the grid equipment, the AC synchronous pilot will be used (usually built in DC/AC In the modulator), the pilot can adjust the AC power to be output according to the drift of the peak voltage of the power grid or the frequency of the power grid, and then output it to the power grid. The resulting AC power (not voltage) output signal is shown in Figure 2E. In other words, using the above-mentioned PWM power extractor, a single-phase DC/AC modulator can extract a fixed voltage DC power from a DC power source and convert it into output AC power that conforms to grid specifications.

It is very important that the output power P(t) of the single-phase modulator changes with time in a pulsating form of cos ² (ω t+θ). Therefore, within a certain period of time, the energy delivered through the power line of the power grid is equal to the time integral value of the power pulsation output according to time during this period. The resulting transmission energy (integral value) is only equal to the energy supplied by the initial energy source, and half the energy integrated by the constant voltage DC power over time in the same period. In other words, the above-mentioned conventional single-phase modulator can only capture, convert, and then deliver half of the energy provided by the DC power supply. Therefore, the remaining and unused energy is more than half of the available input energy. That is to say, this untransmitted residual energy occupies most of the residual energy described in the above-mentioned reference publication patent.

For the convenience of intuitively explaining the purpose of the following analysis; let us assume that the DC power supply has a constant power P _mx during a period of several AC ripple cycles. Figure 2E shows the DC power pulses captured during one PWM duty cycle (with period D). As it will be proved; the extracted DC power P _{x is} less than or equal to the DC power P _{mx of the} power supply. The load duty factor “d(t)/D” of this PWM duty cycle is adjusted to be equal to the calculated value of d(t)/D=cos ² (ω t+θ), so that the generated power is equal to P _x * cos ² (ω t+θ), to make the power pulsation essentially conform to the grid specifications, where θ is the power pulsation phase corresponding to the power line of the grid. FIG. 2E (specifically, the lower half of FIG. 2E) also shows the coordinate system (called the energy coordinate system) of the power corresponding to time, where D represents a PWM duty cycle length; the input DC power is P _mx ; The DC power is P _x .

As shown in FIG. 2E, the energy coordinate can be divided into 3 regions. Region-I represents the DC power pulse captured by the captured power P _x ; when the pulse duration is D * cos ² (ω t+θ), at any time t corresponding to the PWM capture period, The DC power pulse is converted into a single-phase AC power ripple P(t)=P _x * cos ² (ω t+θ). Area-I is also called "electric energy extraction area" or "electric energy extraction area". The area between the DC power source P _mx and the extracted power P _x is the region III. Region-II is the area after the power extraction region of the PWM duty cycle D. The combination of Area-II and Area-III shows the remaining electrical energy area in the energy coordinate system. The energy in the remaining electrical energy area (area) will not be extracted and converted into AC power, so it cannot be used in grid codes. On the contrary, this surplus electrical energy is eventually transformed into heat energy in the system.

To reiterate, the traditional DC/AC single-phase modulator uses a Boost module to adjust a DC power supply with an unfixed voltage to a DC power supply with a substantially fixed set voltage (such as the peak voltage of the power grid), which is supplied to the PWM power extraction The power of this constant voltage DC power source is extracted by the PWM power extractor and converted into a DC power pulse signal. At this time, the load working factor is adjusted within a PWM working cycle according to the time function corresponding to cos ² (ω t+θ) (phase θ is the corresponding power oscillation phase existing on the power line of the grid), and then the output is output to the grid AC power can meet the grid specifications. When the input power is above a certain high level, the input power in each PWM duty cycle is composed of two areas on the energy coordinate system; divided into the captured energy area (for example, area I in FIG. 2E) and the remaining energy Region (for example, a combination of Region II and Region III in FIG. 2E). The extracted energy will be converted into AC power and provided to the corresponding power line on the grid; but the remaining energy can only be converted into heat energy unless it is captured and stored in the MEUPT optimizer... and other equipment.

As mentioned above, the cited published patent teaches that when the extracted power is integrated over a period of several AC power cycles, the remaining power is at least as large as the extracted power. In other words, the traditional single-phase DC/AC modulator can only extract at most half of the input DC energy. In other words, when using a traditional single-phase DC/AC modulator, at least half of the input DC energy will become residual energy; it is not captured, converted, transmitted to the grid, or used by the load; and eventually converted into Thermal energy.

The referenced patent also emphasizes that the root cause of the low power extraction efficiency of single-phase DC/AC modulators will continue to exist in traditional 3-phase DC/AC modulators. This is because a three-phase DC/AC modulator is essentially composed of three single-phase DC/AC modulator architectures, which individually perform power extraction and conversion functions, and then provide an approximate time average to the three pairs of power lines in the grid For square root AC power, the phase difference between the three output AC power pulses must be 120°.

Section 2: Energy Extraction of Traditional 3-Phase Modulator

Three single-phase DC/AC modulators are built into the traditional 3-phase DC/AC modulator. Each single-phase DC/AC modulator is equipped with a PWM power extractor. The three power harvesters are adjusted by a synchronous pilot so that they operate at the same frequency (called "PWM frequency"). Figure 3A shows; three circuits 301, 302 and 303 are equivalent to three PWM power extractors. Circuits 301, 302 and 303 use the same single-phase power extractor and use the same operating principle as described above. Single-phase power extractor 301 outputs A-phase AC power and has switch QA; single-phase power extractor 302 outputs B-phase AC power and has switch QB; single-phase power extractor 303 outputs C-phase AC power and has switch QC. The synchronous pilot 310 is designed to simultaneously activate the paths of the three switches QA, QB, and QC in the three power extractors, and extract power at the same frequency but different load working factors.

It is assumed that the DC power supply has a constant input DC power P _mx in one AC power cycle. And a PWM duty cycle is indeed a small part of the entire AC power cycle. FIG. 3B shows the input DC power in a PWM duty cycle, which is presented symbolically in FIG. 3C. In a PWM duty cycle, three power extractors extract DC power. The height value of the extracted power in FIG. 3C is P _x , and in FIG. 3B P _{x is} lower than 1/3 of the input DC power P _mx . The load duty factor of the PWM duty cycle of the A-phase power extractor is adjusted to be equal to cos ² (ω t) (or sin ² (ω t)), so that the output AC power is equal to P _x * cos ² (ω t)( Or P _x * sin ² (ω t)), which can meet the specifications of single-phase output AC power. Similarly, the load duty factor of the PWM duty cycle of the B-phase power extractor is adjusted to be equal to cos ² (ω t+120°) (or sin ² (ω t+120°)), so that the output power is equal to P _x * cos ² (ω t+120°) (or P _x * sin ² (ω t+120°)). In addition, the load duty factor of the C-phase power extractor during this PWM duty cycle is adjusted to be equal to cos ² (ω t-120°) (or sin ² (ω t-120°)), so that the output power is equal to P _x * cos ² (ω t)-120°) (or P _x * sin ² (ω t-120°)). In addition, in order to meet the three-phase power grid specifications, the phase difference between the single-phase output power of the three-phase AC power must be 120°.

Note that a typical traditional 3-phase DC/AC modulator has overlapping periods during power extraction (a symbolic representation is shown in Figure 3C). Three pickers are overlapping The power extraction during the period is referred to herein as "simultaneous (sexual) power extraction"; and the guide used to extract power during this period (as shown in FIG. 3A) is referred to as the "simultaneous regulator" .

The combination of the conservation of energy and the extremely short-lived electrical energy characteristics forces the sum of the three single-phase power extractions in the simultaneous power extraction to be no greater than the input DC power supply P _mx (or P _mx >P _x +P _x +P _x ; or P _x <(1/3)P _mx ). The total power output of traditional three-phase AC power output: P(t)=P _x (sin ² (ω t)+sin ² (ω t+120°)+sin ² (ω t-120°)); or P(t )=P _x (cos ² (ω t)+cos ² (ω t+120°)+cos ² (ω t-120°)). Since (sin ² (ω t)+sin ² (ω t+120°)+sin ² (ω t-120°))=(cos ² (ω t)+cos ² (ω t+120°)+cos ² (ω t-120°))=3/2. Therefore, P(t)=(3/2)P _x <(3/2)*(1/3)P _mx =1/2P _mx . In colloquial terms, since the three single-phase power extractors extract power simultaneously, the total output power of the traditional DC/AC modulator cannot be greater than (1/2)P _mx , only the input DC power half.

In other words, the total output AC power of a conventional 3-phase DC/AC modulator cannot be greater than half of the input DC power. In other words, when photovoltaic power plants use this traditional modulator, the traditional 3-phase DC/AC modulator can only capture and convert less than half of the DC power produced by photovoltaic (PV) solar panel strings. Therefore, at least half of the DC power generated by photovoltaic power plants becomes surplus power. Unless the surplus power is captured and stored in the equipment using MEUPT, the surplus power will be converted into heat energy.

To reiterate, traditional three-phase DC/AC modulators basically operate three single-phase DC/AC modulators to perform the functions of capturing and converting power. Phase DC/AC modulators provide similar time rms AC power to a 3-phase grid consisting of 3 or 4 power lines; the phase difference between the output single-phase AC power must be 120°. In other words, the conventional 3-phase DC/AC modulator is a DC/AC modulator that operates three single-phase DC/AC modulators. The DC power input to each single-phase DC/AC modulator is 1/3 of the DC power input to the 3-phase modulator, and 1/3 of the power input to the unidirectional modulator is only half of the DC The power is captured and converted into single-phase AC power, and the phase difference between the three output single-phase power must be 120°; and three single-phase AC power is output to three of three or four power lines Phase grid. Each pair of power lines carries a single-phase AC power of the same frequency (AC power frequency) and has the same time rms power; but the phase difference between the unidirectional AC power must be 120°. The meanings of "power line" and "cable" are interchanged in this article and in the professional field.

According to the derivative results stated in the reference announcement patent; and confirmed again in the above theoretical derivation; each input to the single-phase modulator (in the 3-phase DC/AC modulator) DC power (this DC power is less than Or equal to 1/3 of the DC power input to the three-phase modulator), less than half of this DC power is captured and converted into single-phase AC power output. Therefore, the maximum three-phase AC power output (retrieved and converted) by any conventional three-phase DC/AC modulator at any time can only be half of the DC power produced; that is, P(t)=3*( 1/2)*(1/3)P _mx =(1/2)P _mx .

What needs to be emphasized here is that the above theoretical derivation reveals the serious consequences of the "simultaneous power extraction" design method used in the traditional three-phase DC/AC modulator industry. This design method has been followed in the three-phase DC/AC modulator industry for a long time; the inverter industry does not even know how to design like this Serious consequences. This paper theoretically concludes that the serious consequences of this type of energy extraction are the first to be revealed. The serious consequences of this design lead to "the sum of the three AC power outputs of the traditional three-phase DC/AC modulator is less than half of the input DC power." The conventional (common) simultaneous power extraction design method disclosed in this article is indeed used in this way in the green power industry; especially in the photovoltaic power industry.

In other words; the traditional photovoltaic power industry does indeed adopt the design method of simultaneously extracting electrical energy. Conversely, the law of conservation of energy combined with extremely short-lived power characteristics will force the sum of the maximum power (P _x ) extracted by each single-phase DC/AC modulator designed in this way to be less than the maximum power (P _mx ) of the photovoltaic power supply ) (Ie, P _x <(1/3)P _mx ). So at any time, the sum of traditional three-phase AC AC power transmission is P(t)=(3/2)P _x ; that is, P(t)<(3/2) * (1/3) * P _mx <(1/2)P _mx , or in colloquial terms: less than half of the maximum DC power generated by PV. Therefore, with a traditional three-phase DC/AC modulator, at least half of the DC power generated by the PV string becomes surplus energy. This remaining electrical energy can only be converted into thermal energy unless it is captured and stored in MEUPT optimizer...etc.

As mentioned above, with a conventional 3-phase DC/AC modulator, at least half of the input DC power will become surplus power. According to the information disclosed in this article, the next question may be: "Can we use more than one traditional three-phase DC/AC modulator to capture, convert and deliver DC residual energy to provide an alternating current (power) source?" To understand from the description below, its answer is no.

As shown in FIG. 4, after two sets of the same 3-phase DC/AC modulators 4210 and 4220 (each with the manufacturer’s declared rated power P _mx ) are connected to the PV generator 4110, the PV generator 4110 has no connection to capture And storage of surplus electrical energy equipment (for example, MEUPT optimizer) can provide the maximum DC power P _mx . The law of conservation of energy only allows one of two parallel DC/AC modulators 4210 and 4220 to extract half of the total input DC power P _mx (i.e. each modulator extracts only 1/2 P _mx As input power). In other words, the input DC power of individual modulators in two identical 3-phase DC/AC modulators can only be 1/2 P _mx .

The three power extractors described above (in the traditional 3-phase DC/AC modulator) follow the design method of simultaneous power extract. Each three-phase DC/AC modulator can only convert half of the input DC power to produce output AC power; equivalent to (1/2) * (1/2) * P _mx , or 1/4 of P _mx . The total AC power output from the two modulators is 2 * (1/4) * P _mx ; still equal to (1/2)P _mx . The above inference can also be used in the case analysis of a case where a higher rated power or a larger number of DC/AC modulators are used, and the same conclusion can be obtained. Again, "simultaneous extraction of electrical energy" is the root cause of more than half of the DC power produced as surplus electrical energy.

The next question may be: "Can we design an experiment to clearly prove that when power is extracted through a traditional three-phase DC/AC modulator, half of the electrical energy generated by the photovoltaic solar panel string will become residual energy?" An experimental design is described. It is used to prove that if the traditional three-phase DC/AC modulator is used to extract the DC power generated by the PV string, at least more than half of the generated DC power becomes residual energy.

Section 3: Definitive experimental evidence

The MEUPT optimizer is designed to capture/use the above surplus power-surplus power. In the experiment setup and experiment execution steps described below Combined with the MEUPT optimizer, the purpose of this experiment is to clearly prove that when power is extracted through a traditional three-phase DC/AC modulator, at least half of the photovoltaic power becomes surplus energy.

FIG. 6A illustrates a power generation device of a photovoltaic (PV) power station 6000A combined by 2 AC power production units 6100A and 6200A. The AC power production units 6100A and 6200A each use the MPPT design method; convert the extracted DC power into three-phase AC power and provide it to the grid 6600A. The AC power production unit 6100A includes a (30 kW) DC generator 6110A and a (30 kW) 3-phase DC/AC modulator 6130A. The AC power production unit 6200A includes (30kW) DC power generator 6220A and (30kW) 3-phase DC/AC modulator 6230A. The generator 6110A uses two parallel PV strings 6111A and 6112A to produce DC power. The generator 6220A uses another two parallel PV strings 6221A and 6222A to produce DC power. Each of the 4 PV strings is composed of 25 solar panels connected in series; each solar panel can generate 300W of DC power under a clear and cloudless sky at noon.

The DC generator 6110A supplies DC power to the 3-phase DC/AC modulator 6130A; the DC generator 6220A supplies DC power to the 3-phase DC/AC modulator 6230A. Then, the two modulators 6130A and 6230A convert the supplied DC power into 3-phase AC power. In this experiment, the output AC power of the power production units 6100A and 6200A was measured by two 3-phase AC wattmeters (in kilowatts) 6351A and 6352A, respectively. The AC power (in kilowatts * hours) produced by these two power generating units 6100A and 6200A is also measured by two electric meters 6361A and 6362A respectively. The generated three-phase AC power is then supplied to the grid 6600A through the transformer 6500A. then Conduct a photovoltaic power plant experiment and measure the cumulative electrical energy generated by the two AC power production units 6100A and 6200A.

All components based on the two power production units 6100A and 6200A (including two sets of instruments for measuring power and energy) are the same, so during the above 7-day experimental period, the readings of the two electricity meters show equal production every day The energy value confirms that the two sets of equipment are sufficiently identical. After these 7 days of operation, one of the two AC power production units "6200A" remained unchanged, while the other AC power production unit "6100A" was modified to a different configuration "6100B", as shown on the left of Figure 6B Icon.

The power production unit 6200B of FIG. 6B is the same as the unmodified power production unit 6200A of FIG. 6A. Furthermore, the elements 6351B, 6361B, 6352B, 6362B, 6500B, 6600B of FIG. 6B are the elements 6351A, 6361A, 6352A, 6362A, 6500A, 6600A of FIG. 6A. In addition, although the configuration of the power production unit 6100B in FIG. 6B is different from the power production unit 6100A in FIG. 6A, the power elements in the power production unit 6100B in FIG. 6B are still the elements configured in the production unit 6100A in FIG. 6A. For example, the PV strings 6111B and 6112B of FIG. 6B are the same as the PV strings 6111A and 6112A of FIG. 6A, respectively. The same DC/AC modulator 6130B of FIG. 6B is the same as the DC/AC modulator 6130A of FIG. 6A.

The six (6) steps in the next section describe how to modify the power generation unit 6100A to become a 6100B architecture. The 6100B is like the architecture configured on the left side of FIG. 2B. Step 1 is to add a configuration of a set of decoupling diodes 6311B between the parallel solar panel strings 6111B and 6112B and the 3-phase DC/AC modulator 6130B following the MPPT architecture. Step 2 is to add a set of energy storage 6410B configuration In the architecture of 6100B. In step 3, the energy storage 6410B is connected to the DC input terminal of the DC/AC modulator 6130B through another set of decoupling diodes 6312B and switch SW1. Step 4 Add another three-phase DC/AC modulator 6130S (20kW) to the 6100B architecture, and the modulator 6130S operates according to the direction of the designed MEUPT controller 6420B. Step 5 is to connect the DC/AC modulator 6130S to the energy storage 6410B through another set of decoupling diodes 6313B and switch SW2. Step 6 is to connect the output of the modulator 6130S to the power meter 6351B and the kWh 6361B through the switch SW3. Note that the "truncated diode group" referred to in this article can be referred to as a "blocking diode" in the professional field of diodes. In addition, the switches SW1, SW2, and SW3 configured in FIG. 1B can enable the 6100B to introduce relevant devices into the experiment (or separate from the experiment) at an appropriate time according to the execution steps of the experimental design.

On the first night after the above configuration is adjusted; switch SW2 and SW3 to open, and SW1 to switch to the path. In this way, the modulators 6130B and 6230B can be put into operation early the next morning. The electric meters 6351B and 6352B that measure the two power outputs of the power generating units 6100B and 6200B both find that the cumulative reading before this operation is the same. In addition, from measuring the increase in the voltage of the energy storage 6410B terminal, it can be confirmed that the energy storage 6410B starts charging early. As shown by the cumulative readings of the kilowatt-hour meters 6361B and 6362B for the day, the two power generating units 6100B and 6200B provide equal electrical energy to the three-phase AC grid. This experimental procedure does prove that the added interceptor diode group 6311B and energy storage 6410B will not change the power of the power generation unit 6100B and the production of electrical energy.

The switches SW1, SW2, and SW3 are all switched to the night after the first day of operation (the second night). Modulators 6130B and 6230B also in the early hours of the next day The operation starts, and the modulator 6130S operates at a lower power within about 15 minutes after the modulators 6130B and 6230B start to operate. After that, the modulator 6130S increases the DC/AC conversion power approximately every 2 minutes; this process of increasing the conversion power is consistent with the designed energy storage control program. The two power production units 6100B and 6200B come down all day long until they are close to the power provided by the sunset to the three-phase grid, which can be obtained from the readings of two kilowatt-hour meters at the end of the next day. As a result, the cumulative increase reading of the kilowatt hour meter 6351B (for unit 6100B) reached more than twice that of the kilowatt hour meter 6352B (for unit 6200B). Therefore, the above experimental results show that the cumulative increase in power provided by the adjusted power generation unit 6100B to the grid in one day is more than twice the cumulative increase in power provided by the unadjusted power generation unit 6200B. This experiment was carried out for six consecutive days, and the switches SW1, SW2 and SW3 still kept the path, and the adjusted power production unit 6100B provided the grid with more than twice the power every day as the power production unit 6200B.

In the evening after the six-day experiment, the SW2 and SW3 switches were disconnected. During the five consecutive days during which the switches SW2 and SW3 remain open, the electrical energy supplied from the power generating units 6100B and 6200B to the grid every day returns to the same amount of power supply. Later in the evening, switch SW2 and SW3 into channels again. And keeping the switches SW2 and SW3 operating in the path for the next 5 consecutive days, the daily cumulative power supply power measured by the power generating unit 6100B every day becomes more than double the cumulative power supply power daily of the power generating unit 6200B.

As explained earlier; performing this experiment can undoubtedly confirm; the predictions proposed in Section 2 of the patent announcements (US2016/0036232 and US2017/0149250A1); there is indeed residual power in the PV power plant. In particular, after the DC power generated by the PV power plant is captured by the 3-phase DC/AC modulator, about half of the DC power remains unextracted, and the excess power becomes surplus power.

There are two ways to eliminate the aforementioned adverse consequences. The first method is to incorporate the MEUPT optimizer into the power generation system following the principles described in the cited reference publication patents. Another method is to follow the principles described herein, and according to the present invention, it is proposed to extract power sequentially (sexually) according to the adjustment of the load working factors of phase A, phase B, and phase C. Please note that the present invention replaces the traditional simultaneous (sexual) power extraction method with a sequential (sexual) power extraction method.

Section IV: capturing sequential power proposal

The proposal in the principle described in this paper; the implementation of the sequential phase A, B and C phase power extraction can ensure that the three phases do not overlap in the time of power extraction. When performing sequential power extraction in each PWM duty cycle, Phase A first extracts DC power in a timely manner; Phase B extracts DC power immediately after extracting power in Phase A; C corresponds to the last appropriate DC power extraction . By doing this, the power intensity of the extracted power is P _x , and it can be equal to the input maximum DC power value P _mx in each phase. This sequential power harvesting method is different from the simultaneous power harvesting method. The maximum power harvested by the simultaneous power harvesting method can only be equal to one third (1/3) of P _mx .

In order to make the following analysis intuitive and realistic, let us assume that the AC frequency is 50 Hz and the PWM frequency is 18 KHz. This assumption may be such that the phase angle of the AC power ¹⁰ proceeds in exactly the duration of each PWM duty cycle. Figure 5A shows the proposed circuit for applying this new power extractor. The new power extraction circuit is similar to the conventional circuit shown in FIG. 3A. Please note that the simultaneous regulator 310 used in the conventional power extractor shown in FIG. 3A is currently replaced by the sequential controller 510 and becomes the circuit shown in FIG. 5A.

It should be emphasized here that the power extraction adjusted by the simultaneous regulator is the power extraction started at the same time; that is, the method of simultaneous power extraction is absolutely following 3 single-phase DC/AC modulators At the same time, power extraction is started. On the contrary, the power extraction regulated by the sequential controller performs power extraction in chronological order; that is, the power extraction process performed by the sequential power extractor follows the proposed basis Phase A, Phase B Adjust the load working factor with phase C to extract power sequentially.

List an example of implementation; Figure 5B shows a 3-phase DC/AC modulator that uses a sequential controller to control 3-phase power extraction. When performing this power extraction method, the A-phase power extraction is scheduled (controlled) to start at the beginning of the PWM duty cycle, with a duration of d _A (t); the B-phase power extraction arrangement (controlled) is at the A stage Start at the end of power extraction, the duration is d _B (t); and phase C power extraction is scheduled (controlled) to start at the end of phase B power extraction, the duration is d _C (t). In this way, the power extraction of the three phases is arranged (controlled) in sequence and operates seamlessly. As can be seen in FIG. 5B, this power extraction method ensures that no overlapping power extraction periods occur. In actual execution, there may be a transition time interval between the end of one power extraction and the beginning of the next power extraction. However, in each PWM duty cycle, this time interval can be very short, it can be designed to be 33%, 20%, 10% or even 1% below the PWM duty cycle. Therefore, the maximum intensity P _x of the extracted power of each phase can be designed to be equal to its input maximum DC power value P _mx ; and if the simultaneous power extraction method is used, only the relative maximum DC power P can be extracted A certain ratio of _mx (up to one third).

Let us set the duration of each PWM duty cycle to D. The load working factor of phase A extracted power is defined as d _A (t)/D; the load working factor of phase B extracted power is d _B (t)/D; the load working factor of phase C extracted power is equal to d _C ( t)/D. According to the principle described here, this article recommends setting the three load working factors as: d _A (t)/D=2/3 cos ² (ω t), d _B (t)/D= 2/3 cos ² (ω t+120°), and d _C (t)/D=2/3 cos ² (ω t-120°). Then, according to the calculated load working factor, three individual corresponding time lengths of power extraction are allocated. Please note the sum of the power extraction durations of these three phases; dA(t)+dB(t)+dC(t) is exactly equal to D, which is the duration of one PWM duty cycle.

As mentioned earlier, the period of one PWM duty cycle is equal to the time interval of ¹⁰ phase angle advance in the AC power cycle; therefore, if the phase difference between the A phase, B phase, and C phase is 120°±1 ⁰ ; + It also fits within the allowable range of the existing power grid. Three pairs of the sum of the power P (t) carried in the power _{line; P (t) = P A} (t) + P B (t) + P C (t) = P mx (2/3) (cos 2 (ω t) +cos ² (ω t+120°)+cos ² (ω t-120°))=P _mx (2/3)(3/2)=P _mx . In other words, the total power carried by the three-phase power line at any time can be basically equal to the maximum DC power generated. In other words, if the sequential power extraction method is followed, there will be no excess surplus energy. Another argument is that: in combination with a sequential power extractor, the 3-phase DC/AC modulator can completely extract all the generated DC power, essentially achieving zero residual energy.

To reiterate, the principle described in this article is to sequentially and seamlessly extract the relative power of each of the three-phase power. When the 3-phase power extraction method is changed to sequential, the extracted power intensity can be designed to be equal to the input maximum DC power P _mx . Then according to the principles described in this article, it is further proposed; adjust the load working factors of the three phases to 2/3 cos ² (ω t) of phase A and 2/3 cos ² (ω t+120°) of phase B, respectively. , And 2/3 cos ² (ω t-120°) of phase C. Through this approach, the three-phase power extraction process can be performed sequentially; the three-phase power extraction can also be completed completely seamlessly within a PWM duty cycle; and A phase, B phase and C The phase difference between the output AC power of the phases is within the allowable range acceptable to the grid by 120°±1°.

Therefore, when a three-phase DC/AC modulator is added to the proposed sequential power extraction controller; the designed DC/AC modulator can capture and convert the maximum DC power generated by the entire string of photovoltaic solar panels P _mx without excess surplus power; and the output AC power can also meet the grid specifications.

Section 5: Design considerations for sequential controllers

Take an example; this paper proposes that the start time of PWM can be used to start the power extraction of phase A, the duration is (2/3)D * cos(ω t); then the signal of phase A power extraction is applied The change (from the period of phase A power extraction cycle on to cycle off) to trigger and start phase B power extraction, the duration is (2/3) D * cos(ω t+120°); then apply phase B power The captured signal changes (from phase B power extraction cycle on to cycle off) to trigger and start phase C power extraction.

To give another example: Since a PWM duty cycle clearly advances the AC power phase value (for example, ¹⁰ ), a list can be constructed; the determined end time of the phase A power extraction is taken as the "first time value" , And the determined end time of the B-phase power extraction as the "second time value". This list contains expanded column items that can represent the entire power cycle (for example, 180 columns represent 180 ⁰ changes per ¹⁰ phases). Since the power delivered is proportional to the square of the voltage, and the square of the sine-cosine pulsed oscillating voltage will produce a power ripple with twice the frequency of the oscillating voltage, the power cycle generated by the 360 ⁰ voltage cycle becomes 180 ⁰ .

Two continuous time axes are used in each column of the schedule, and the two time axes that can be set periodically in a PWM period are designed to correspond to the start time of the A-phase power extraction (start of PWM) and power extraction The ending time (the first time value in the column); then corresponds to the start time of the B-phase power extraction (the first time value in the column) and the end time of the power extraction (the second time in the column) Time value); then corresponds to the start time (second time value in the column) of the C-phase power extraction and its end time (the end of the PWM). When the 180 columns are completed, it means that the DC/AC modulation conversion process of an AC power cycle has been completed. Then the same process can be repeated before the next round of DC/AC modulation conversion...etc. However, in this embodiment, a clock having a time resolution better than 1/180,000 seconds (or 5 microseconds) must be used.

The "synchronization module" or "simultaneous (control) module" in the traditional three-phase DC/AC modulator uses the maximum power and minimum power point of the AC power cycle to start PWM synchronously; in this way, with the If the phase/frequency in the power grid drifts occasionally, the output AC power pulsating phase can drift accordingly. In addition, the principle of the “synchronization module” described here can also adopt a “synchronization element” to guide the power extraction corresponding to the phase/frequency drift in the power grid.

Section 6: Conclusion

As mentioned in the first section, the traditional DC/AC single-phase modulator uses a PWM power extractor to extract input DC power. When the load duty factor in a PWM duty cycle is adjusted by cos ² (ω t)(or sin ² (ω t)) at time t, the output AC power will meet the grid specifications. Please note that there are two regions in the energy space of each PWM duty cycle; one is the energy region that is captured, and the other is the remaining energy region. The referenced patent publication teaches that when integrating over several AC power cycle periods, the amount of remaining electrical energy is at least as large as the extracted electrical energy. In other words, a single-phase DC/AC modulator can only capture and convert up to half of the input DC power. The extracted electrical energy will be converted into AC power and provided to the corresponding power transmission line on the grid; but the remaining energy can only be converted into heat energy unless it is captured and stored in the MEUPT optimizer... and other equipment.

As described in Section 2, the traditional three-phase DC/AC modulator operates three identical single-phase DC/AC modulators. Each single-phase DC/AC modulator can capture and convert half of the input DC power to AC power that meets grid specifications. Please note that since the three modulators simultaneously start energy harvesting, the input DC power can only be equal to one-third of the maximum DC power generated. Therefore, a three-phase DC/AC modulator can only extract at most half of the power provided by the DC power source and convert it into AC power that meets the grid specifications. The output AC power of these three single-phase DC/AC modulators must be 120° out of phase with each other. In addition, the three single-phase output AC power is provided to customers using power on the grid through 3 or 4 power lines.

In other words; the traditional photovoltaic power generation industry uses traditional DC/AC modulators and uses a simultaneous power extraction mechanism in its design; therefore, the law of conservation of energy forces the sum of the three maximum power intensities P _x that can be extracted to be less than the PV group One third of the maximum power P _mx of the DC power generated by the string (ie P _x <(1/3)P _mx ). Mathematics can be deduced that the maximum total power output of traditional three-phase AC power output is P(t)=(3/2)P _x ; that is, less than (1/2)P _mx (or the DC power generated by the PV string Half). Therefore, when using a traditional three-phase DC/AC modulator, at least half of the DC power produced by the PV string becomes surplus power. But the remaining energy can only be converted into heat energy unless it is captured and stored in MEUPT optimizer...etc.

The theoretical derivation described in Section 2 of this article reveals the serious consequences of the "simultaneous power extraction" design used by the traditional three-phase DC/AC inverter industry. This design method has been followed for a long time in the three-phase DC/AC modulator industry; and the inverter industry does not even understand the serious consequences of such a design. In this paper, it is the first time that the serious consequences of this method of energy extraction are revealed. The serious consequences of this design lead to "the sum of the three AC power outputs of the traditional three-phase DC/AC modulator is less than half of the input DC power." The conventional (common) design method for extracting electrical energy disclosed in this article is indeed used in this way in the green power industry; especially in the photovoltaic power industry.

There are two ways to eliminate the above undesirable consequences. The first method is to incorporate the MEUPT optimizer into the energy system following the principles described in the cited reference publication patent. Another method is to follow the principles described in this article; to follow the sequence (sexual) power extraction that adjusts the load working factors of Phase A, Phase B, and Phase C as proposed by the present invention.

Section 4 describes the principle of sequential power extraction and load factor adjustment. Sequential energy harvesting is performed in each PWM duty cycle; first, phase A extracts DC power at the appropriate time; phase B extracts DC power immediately after phase A extracts the power; finally, phase C extracts the power at the appropriate time Take DC power. In this way, the intensity P _{x of} the extracted maximum power can be equal to the maximum input DC power P _mx produced in the A, B, or C phase. This sequential power extraction is completely different from the simultaneous power extraction method. The maximum power that the simultaneous power extraction can extract can only be equal to one-third (1/3) of P _mx .

The principle suggested in this article: the start time of power extraction of phase A, phase B, and phase C should be directed and adjusted by the sequence controller. In this way, the three-phase power extraction is converted into three sequentially extracting power; the maximum power intensity extracted in this way can be equal to the maximum DC power P _mx input by the generator. And using the principles described here, the three load working factors can be further adjusted to 2/3 cos ² (ω t) of phase A, 2/3 cos ² (ω t+120°) of phase B and 2/3 cos ² (ω t-120°) of phase C. Through this adjustment method, the three-phase power extraction process can be successfully completed sequentially and completely seamlessly within a PWM working cycle. In this way, the phase difference of the AC power output by Phase A, Phase B and Phase C is within 120°±1°; it is within the allowable range of the grid code. Therefore, when using the proposed 3-phase DC/AC modulator of the sequential power extractor; this newly designed DC/AC modulator can capture and convert all (or substantially all) produced maximum Electricity P _mx has no (or very little) excess energy. In addition, the output AC power generated can easily comply with the 3-phase AC grid specifications.

Although the case has been disclosed as above by way of implementation, it does not limit the case. Anyone who is familiar with this skill can make various changes and modifications within the spirit and scope of the case, so the scope of protection of the case should be attached The application within the scope of the patent application shall prevail.

510‧‧‧sequential regulator

DFA‧‧‧Load working factor regulator

L‧‧‧Inductor

D‧‧‧Diode

C‧‧‧Capacitor

QA-QC‧‧‧switch

Claims (14)

A sequential power extraction control element, applied to a group of three-phase DC/AC modulators composed of three single-phase DC/AC modulators. The configuration of this control element is used to control each single-phase The sequence of the modulator in the DC power extraction and the duration of the power extraction: the first single-phase modulator in the three-phase DC/AC modulator is equipped with a first group of PWM power extractors, DC power can be extracted from the DC power source and converted into the first set of AC power to be transmitted to the first pair of cables of the three-phase AC power grid, and the frequency of the first set of AC power and the first phase must be consistent The grid specification of the AC power delivered on the first pair of cables in the three-phase AC grid; the second single-phase modulator in the three-phase DC/AC modulator is equipped with a second group of PWM power extractors, The second set of extractors can extract DC power from the DC power source and convert it into a second set of AC power for transmission to the second pair of cables of the three-phase AC power grid, and the frequency of the second set of AC power is One set of AC power is the same, but the second set of the second set of AC power conforms to the grid specifications of the AC power delivered on the second pair of cables present on the three-phase AC grid; and three-phase DC/AC modulation The third single-phase modulator in the controller is equipped with a third group of PWM power extractors. The configured third group of extractors can extract DC power from a DC power source and convert it into a third group of AC power. The frequency of the three sets of AC power is the same as that of the first set of AC power, but the third set of the third set of AC power matches the grid specifications of the AC power delivered by the third pair of cables existing in the three-phase AC grid. The sequential power extraction control element includes: Configure a sequential controller so that the first PWM power extractor has a first duty cycle during the DC power extraction, so that the second PWM power extractor performs the DC power extraction During this period, there is a second working cycle, and then the third PWM power extractor is performing DC power extraction with a third working cycle; the first, the second and the third are sequentially controlled The duty cycle does not overlap in working time, and the first, second, and third PWM extractors can be sequentially executed for power extraction; the sequential controller can also be based on the current (time) The power corresponding to one of the levels of the first group, the second group, and the third group of AC power commands and adjusts the power of the first, second, and third PWM power extractors Load working factor. The sequential power extraction control element according to claim 1, adjusts the load working factor of the first, the second and the third PWM power extractors during the AC power cycle, so that the first The time function of the load working factor of a PWM power extractor becomes 2/3 cos ² (ω t), so that the time function of the load working factor of the second PWM power extractor becomes 2/3 cos ² (ω t +120°), and the time function of the load working factor of the third PWM power extractor becomes 2/3 cos ² (ω t-120°). The sequential power extraction control element according to claim 1, further comprising: a timer; A timetable with multiple columns, where the parameters of each column correspond to a set of level information on the AC power cycle, where the parameter can represent sufficient information to determine the first and second corresponding to the AC power on the grid And the third PWM power extractor load operating factor; and an actuator, the starter can use sufficient information in the timetable to sequentially start the first, second, and third PWM power extractors To extract its corresponding power. The sequential power extraction control element according to claim 3, wherein the sufficient information is the start time and end time of the first PWM power extraction operation. The sequential power extraction control element according to claim 3, wherein the schedule includes a plurality of rows, and each row includes at least a first value and a second value, wherein the first value is equal to D * ( 2/3) * cos ² (ωt), the second value is equal to D * (2/3) * cos ² (ωt+120°), where D is the length of the PWM duty cycle and t is a certain value within the AC power cycle time. The sequential power extraction control element according to claim 1, wherein the sequential controller can adjust all corresponding load working factors according to a pilot signal. The sequential power extraction control element according to claim 1, wherein each of the first, second and third PWM power extractors The time interval between the completion of the PWM power extraction and the start of the next PWM power extraction is not greater than one-third of the PWM duty cycle. The sequential power extraction control element according to claim 1, wherein each of the first, second, and third PWM power extractors ends at the end of the PWM power extraction and starts at the next PWM power extraction The time interval between is not greater than one-fifth of the PWM duty cycle. The sequential power extraction control element according to claim 1, wherein each of the first, second, and third PWM power extractors ends at the end of the PWM power extraction and starts at the next PWM power extraction The time interval between is not greater than one-twentieth of the PWM duty cycle. The sequential power extraction control element according to claim 1, wherein each of the first, second, and third PWM power extractors ends at the end of the PWM power extraction and starts at the next PWM power extraction The time interval between is not greater than one hundredth of the PWM duty cycle. A sequential power extraction control element applied to a three-phase DC/AC modulator, where the three-phase DC/AC modulator includes a first, a second and a third single-phase DC/AC modulator, the first single-phase DC/AC modulator includes a first group of PWM power extractors, the first group of PWM power extractors can extract power from the DC power source and convert In order to have a first phase and a first set of AC power that can meet the grid specifications, the second single-phase DC/AC modulator includes a second set of PWM power extractors, the second set of PWM power extractors The controller extracts power from a DC power source and converts it into a second set of AC power with a second phase that meets the grid specifications. The third single-phase DC/AC modulator includes a third set of PWM power extraction The third group of PWM power extractors extracts power from the DC power source and converts it into a third group of AC power with a third phase that can meet the grid specifications. This sequential power extraction control element includes: a Sequential controller, when the first PWM power extractor executes power extraction, the first PWM power extractor is guided to have the first load working factor, and is executed in the second PWM power extractor When extracting power, guide the second PWM power extractor to have a second load working factor, and guide the third PWM power extractor when the third PWM power extractor executes extracting power It has a third load working factor, wherein the sequential controller can ensure that the first, second and third load working factors will not overlap during the power extraction, and in accordance with the first, The second and third load duty factors perform power extraction, wherein the configuration of the sequential controller is based on the current (the first set of AC power, the second set of AC power, and the third set of AC power The power of the AC power cycle of one of the groups corresponds to the power to command and adjust the duty cycle of the first, the second and the third PWM power extractor, wherein the configuration of the sequential controller , During the AC power cycle, the time function of the first load operating factor is 2/3 cos ² ( ω t), and the time function of the second load operating factor is 2/3 cos ² ( ω t+120 °), and the time function of this third load working factor becomes 2/3 cos ² ( ω t-120°). A three-phase DC/AC modulator system, including: a three-phase DC/AC modulator, wherein the three-phase DC/AC modulator includes a first, a second and a third single Phase DC/AC modulator, the first single-phase DC/AC modulator includes a first PWM power extractor that, when performing power extraction, guides the first PWM power extractor to have The first load duty factor, a second PWM power extractor included in the second single-phase DC/AC modulator guides the second PWM power extractor to Two load working factors, and a third PWM power extractor included in the third single-phase DC/AC modulator, when performing power extraction, guide the third PWM power extractor to have the third Three load working factors; a sequential controller to ensure that the first, second, and third load working factors do not overlap during power extraction, and are sequentially in accordance with the first, the The second and the third load work factors perform power extraction, wherein the configuration of the sequential controller is based on one of the first set of AC power, the second set of AC power, and the third set of AC power The power corresponding to the level of the power cycle is used to direct and adjust the working cycle of the first, second and third PWM power extractors, wherein the sequential controller further includes: a timer; The timetable has a plurality of columns, and the parameters of each column correspond to a set of level information on the AC power cycle, where the parameter can represent a sufficient message to Determine the first, second, and third load operating factors corresponding to AC power on the grid; and an actuator, the starter can use the sufficient information in the schedule to sequentially start the first , The second and the third PWM power extractor to extract their corresponding power. The three-phase DC/AC modulator system according to claim 12, wherein the sufficient information is the start time and end time of the operation of the first PWM power extractor. The three-phase DC/AC modulator system according to claim 12, wherein the schedule includes a plurality of columns, and each column includes at least a first value and a second value, wherein the first value is equal to D* (2/3) * cos ² ( ω t), the second value is equal to D * (2/3) * cos ² ( ω t+120°), where D is the PWM duty cycle length and t is the AC power cycle Within a time.

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