KR20120095337A - An atomic reactor equipment and nuclea waste management using there with of a nuclear explosion prevention rule of duplication structure tank block - Google Patents

Abstract

The present invention relates to a nuclear waste treatment method and a reactor facility, and more particularly, to a meteorological condition such as a typhoon during the operation of nuclear reactors of a plurality of nuclear power plants installed according to the installation location of the river inland and coastal seashore area of the global village. Nuclear power plants will be shut down due to deterioration, heavy waves such as earthquakes and volcanic eruptions, or nuclear reactors will explode, resulting in the worst events in the world's nuclear power generation. By re-installing the double-pipe structured tank tank reactor using nuclear explosion prevention to several nuclear power plants to prevent explosion and to prevent environmental pollution such as nuclear waste, it is not affected by weather conditions and is not affected by earthquakes and tsunamis. Nuclear reactors are safe and It relates to a nuclear waste disposal method and reactor equipment capable of continuous operation.
Block tanks 599 for nuclear waste treatment storage at eight locations of the double-pipe structure having a double diameter structure of the reactor building 688 along the outer wall circumference of the reactor building 688 of the nuclear power plant 672. And a radiation-connected structure, the reactor 811 is the first wall of the pellet (683) and the second wall of the fuel pipe (689) to protect the third wall due to the high earthquake of magnitude 5 or more. When a plurality of safety valves 472 are opened when the inside of the reactor pressure vessel 813 explodes, nuclear wastes that are exploded into each block piping line 599 pass through, and the nuclear wastes are stored in each block tank 598. When dismantling a reactor such as a nuclear power plant that has reached the end of its service life, cutting by a remote control or using a robot 700 is used. When the internal pressure of the reactor pressure vessel 813 stops, a plurality of safety valves 472 are closed. Always multiple All valves 472 are closed and various reactors can be installed on the barge 591 of the ocean, and the installation position of the nuclear power plant is adjusted to 40 meters above sea level so as not to be restricted by weather conditions. Safe and continuous operation of nuclear power plants by re-installing the dual-structure block tank reactor facility in which the reactor in the nuclear fuel chamber does not explode to prevent the nuclear reactor 811 of the power plant from being exploded and the environment from being contaminated by nuclear waste. Nuclear waste treatment method and nuclear reactor facility using nuclear explosion prevention of double-block block tank, which ensures safety of nuclear power plant and nuclear reactor renovation

Description

An Atomic reactor equipment And Nuclea waste management using there with of a nuclear explosion prevention Rule of Duplication Structure TANK Block}

The present invention relates to a nuclear waste treatment method and a nuclear reactor facility, and more particularly, to a meteorological condition such as typhoon during the operation of nuclear reactors of a plurality of nuclear power plants installed according to the installation location of the river inland and coastal seashore area of the global village. Nuclear power plants will be shut down due to deterioration, heavy waves such as earthquakes and volcanic eruptions, or nuclear reactors will explode, resulting in the worst events in the world's nuclear power generation. By re-installing the double-pipe structured block tank reactor using nuclear explosion prevention to several nuclear power plants to prevent explosion and environmental pollution such as nuclear waste, it is not affected by weather conditions and is not affected by earthquakes and tsunamis. Nuclear reactors are safe and The present invention relates to a nuclear waste treatment method and a reactor facility capable of continuously operating.

In general, power generation methods such as thermal power generation and nuclear power generation require large-scale power generation facilities, and in order to operate such power generation facilities, a huge amount of energy source is also required. And the structure of nuclear power is the same as that of thermal power. Among them, fossil fuels such as petroleum and coal used for thermal power generation are the main causes of global warming and environmental pollution.They are highly dependent on other fuels, so they are depleted of resources and develop alternative energy to replace them. The problem is also seriously emerging.

On the other hand, eco-friendly and permanent energy sources and space photovoltaic power generation methods using natural energy such as solar heat, tidal power, wave power, wind power and hydropower have been developed and applied. In addition, the power generation methods are not free from constraints on the natural environment, installation location, cost, etc., and thus, all the problems in the present invention can be solved in the ocean from such a situation.

For this reason, thermal power plants burn fuel and produce power by rotating turbines using high pressure steam, and hydroelectric power plants produce power using wheels or pump aberrations. As a power plant that converts potential energy by a car into electric power, the installation place is preferably a place where the difference between tides is as large as possible.

In other words, when the seawater is pushed into the high tide, it is induced and stored in the reservoir built on the coast, and when the water flows out of the ebb tide, the seawater stored from the reservoir is dropped into the sea to generate power by driving a generator as in the case of pumping power generation. to be.

In addition, as an operation example of a conventional tidal power plant, a reims tidal power plant in Reims estuary, France, which can use a tidal difference of up to 13 [m] is famous. Here, the generation of 10,000 [kw] x 24 units of 240,000 [kw] is generated by using a tidal difference of up to 13 [m] and an average of 8.5 [m]. The biggest problem with this power generation method is the location condition, and the condition that the tidal difference of seawater is up to 10 [m] or more, and that the coast is suitable for the construction of the reservoir must be met.

In Korea, tidal power generation plans are being planned in several places centered on Garorim Bay, Chungnam. Garolim Bay is known to be a very favorable candidate for the construction of a maximum tidal flat of 7.9 [m], a land area of 120 [㎡], a dike length of 2.1 [km] and a capacity of 400,000 [kw].

In particular, nuclear energy is a source of less pollution than fossil fuels. This nuclear energy is in the limelight as a future new power source.

But this nuclear energy is not without problems. Not only is there a limited reserve of uranium, which is a raw material for nuclear power plants, but the more troublesome problem is the disposal of nuclear waste.

Environmental pollution from nuclear waste can fatally destroy our only planet, so in order to understand the structure of nuclear power, we need to be able to understand the structure of boilers and melting furnaces. Water reactors are boiling water reactors and pressurized water reactors. Power reactors are mainly used for light reactors. In addition, multipurpose hot gas furnaces and new conversion furnaces are used for gas cooling furnaces.

In the case of hydraulic equipment, when the water is taken out from the control pond or reservoir, it is not necessary to install the settlement because these ponds are also used as the settlement. In addition, in the dam-type power plant, the reservoir acts as a water tank, so no water tank is installed.

1 is a flow chart of nuclear, hydro, and thermal power generation of the prior art level.

If such a dam for power generation is first classified by its use, a simple intake dam 680 used in a waterway power plant, a slightly larger dam 680 used to raise the water level on the upstream side in a dam waterway power plant, and a water intake In order to store water for a period of time, there are huge reservoir dams (680), which form a reservoir or a reservoir by blocking a valley or a river (dam-type power plant).

However, the main points to be careful when constructing the dam 680 is listed as follows. First, it was to be reasonably designed to be safe even under flood and other external forces. The following dam 680 type was to be selected as the most economical in consideration of the topography and geology. By raising the water level-this is called drainage-it was necessary to reduce the damage to a minimum and to safely discharge its maximum flow rate in the event of a flood so that there was no danger to the power plant and all downstream equipment.

As described above, dams for power generation on land are very difficult and seriously difficult to install on land according to economic reasons and environmental impact assessment.

Reference can be made to the publication 10-2010-0027087, which is readily understood. Omitted below

In addition, the conventional nuclear power plant 672 has a central control room 781 that controls the operation of the nuclear power plant 672, as shown in the figure and processes all the work by a computer.

Nuclear power is the third source of energy after hydro and thermal power. Nuclear power is the application of nuclear power and the ability to do energy. Energy is a dynamic physical quantity. It is divided into energy such as

Nuclear fission is a phenomenon in which an atomic nucleus is split into two atomic masses of similar mass, and nuclear fusion is a phenomenon in which a small nucleus of nuclear masses coalesces into a large atomic nucleus, and enormous energy is released during nuclear fission or fusion reactions.

Energy converts from one form to another and can be transformed into any energy or any other energy. If any energy is changed to another energy, the total amount of energy does not change, and various energies eventually turn into heat energy and run off into the atmosphere.

Water stored in the dam 680 has potential energy, wind or river water has kinetic energy, high temperature and high pressure steam has thermal energy, and both coal and petroleum have chemical energy.

The reactor 811 is a device that uses nuclear energy by controlling the fission reaction to occur slowly.

In the structure of nuclear power generation,

First, the electron 784 is composed of an atomic nucleus 815 and an electron 785 surrounding it. The atomic nucleus 815 combines the proton 820 and the neutron 821 with a strong nuclear force (the binding force between the nucleus (proton and neutron collectively) in the nucleus).

]쯤이나 그 질량은 원자 질량의 대부분을 차지한다.The radius of the nucleus 815 is about [10 ^-14 m], the neutrons 821 constituting the nucleus 815 are electrically neutral, the mass is almost the same as the proton 820, the diameter of the nucleus 815 is [

], But its mass accounts for most of the atomic mass.

The structure of nuclear power is identical to that of thermal power. Since nuclear power is also generated by rotating steam turbines (267), nuclear power and thermal power generation differ only in how steam is generated. Thermal power plants burn coal, oil, and natural gas in boilers (783), and steam turbines (267). The nuclear power plant generates nuclear fission in the reactor 811 to generate steam from the heat to rotate the turbine 267.

The structure of an atom (a helium atom) is an atomic nucleus 815 in which protons 820 and neutrons 821 are combined, and charges of electrons 785 (static static electricity on objects [stopping electricity on friction objects]). The amount of static electricity the object carries is called negative, and the proton's charge is positive. Charges of the same sign repel each other and charges of different signs attract each other.

Elements in the nucleus 815 have the same number of protons 820 but different numbers of neutrons 821. Isotopes of hydrogen are the same as the number of protons 820 in tritium and hydrogen in deuterium. For example, since the number of neutrons (821) is different, tritium is called isotope in light and deuterium. When the number of protons 820 plus the number of neutrons 821 is the mass number, the half-life of uranium 238 (679) is 4.51 × 10 ⁸ years, which is shorter than that of uranium 238 (679).

The nucleus of uranium (815) is a model of a red bead, which is a neutron (821), and the paran beads are protons (820), and the isotopes of uranium 238 (679), uranium 235 (812) and uranium 234 are neutrons (821) Depends on the weight. First, uranium 238 (679) is the most abundant uranium in nature, and unfortunately it is not capable of fission. The next is uranium 235 (812) and uranium 234, which contains only a small amount of natural uranium, so nuclear fission is uranium 235 (812).

The nucleus resulting from the collapse of the radiation nucleus 815 is unstable and contains the property of becoming even stable, which is spontaneous decay, that is, it emits gamma rays to alpha particles or beta particles by itself and becomes a stable atom 784 itself. Uranium 235 (812) has the greatest properties. Therefore, the main player in nuclear power generation is uranium 235 (812).

Because nuclear fission, as we have now said, occurs in the form of the collapse of radioactive material.

However, waiting for the natural decay of uranium 235 (812) can not take out the energy, so the artificial destruction of uranium 235 (812) to destroy the particles to generate nuclear fission. What do you crash into? To solve the question, the charge of the atomic nucleus 815 of uranium 235 is positive. When the protons 820 collide with positive charges, they repel each other according to the law of charges and ignite the protons 820.

In that sense, since the neutron 821 is electrically neutral, the neutron 821 can be easily accessed and, of course, the collision is simple.

When neutrons 821 collide, uranium 235 (812) breaks down into barium (pale yellow or silver-white barium oxidizes well in the air) or krypton (krypton is a colorless, odorless gas that is slightly mixed in the air). The neutrons 821 come out 2-3, when this large energy is generated.

Originally, uranium 235 (812) absorbed slow neutrons 821 well, but because neutrons (821) newly born in nuclear fission are fast, they can't catch neutrons (821). Or heavy water (heavy water refers to water having a higher molecular weight than ordinary water) or a moderator 819 such as graphite.

The neutron 821 will bounce if it hits a heavy one, but if it is a particle of similar size, the neutron 821 will eventually slow down and become a thermal neutron. Thermal neutrons are not hot but can be interpreted to mean thermally moving particles. Neutrons with energy below leV (electron volts) are called thermal neutrons, and the neutrons collide with other uranium 235 (812) to split and collide with each other. 1 eV? 1keV is called the slow neutron 812, and 100keV? 10MeV is called the fast neutron 821.

Since one or two neutrons (821) are produced in one fission, after the chain reaction, it is probably good to have a large number of neutrons, but it is not. If the number of neutrons 821 is large, the chain reaction is also excessive, the energy generated when the nuclear fission exceeds the dangerous level, and the reactor, 811, which causes the nuclear fission chain reaction to proceed in an ideal state, explodes.

In order to prevent such an explosion, a control rod 798 made of cadmium is inserted into and taken away from the reactor 811 in order to control the chain reaction of the nuclear fission. The control rod 798 eats the neutrons 821 generated from the nuclear fission, so the moderator ( 819 slows down the neutron 821. In nuclear fission, controlling the speed and number of neutrons 821 is much the same as that of a horse.

When 1 kg of uranium 235 (812) is split, neutrons 812 are popped out of barium and krypton, and the mass is 1 g of light when compared to 1 kg of original uranium 235 (812).

According to Einstein's E = mc ² equation, this lightened mass is transformed into barium by the kinetic energy of krypton and neutrons (812), which is theoretically the same heat as a mass of about 2150 tons of oil. In fact, one kilogram of uranium 235 (812) generates 20 billion kcals of energy, which is about 500 laps around the earth with gasoline, 300 tons of coal, and 2 million liters of oil. . When one uranium nucleus is split into one neutron, two or three neutrons 812 are released.

The structure of the various reactors 811 will be described as follows.

A steam dryer 786 is formed on the upper side of the separator 818 inside the body of the reactor 811, and a control rod on the fuel assembly 671 below the jet pump 325 and the separator separate from the lower side of the separator 818. 798). All of them are power reactors 811, which are mainly used for light water reactors.

A light water reactor is a moderator (819), which is a light water reactor (811) using ordinary water. There are two types of light water reactors, boiling water type and pressurized water type. The power reactor is a reactor 811 developed for power generation.

In the structure of the boiling water reactor 811, the boiling water type boils water to produce steam and turns the turbine 267. The pressure control pool 856 traps water 654 under the pressure vessel 813 in the fuel, water, control rod 798, and recirculation pump 855 inside the reactor pressure vessel 813 inside the reactor 811. Outside the reactor 811, the steam pipe 779 line, etc. consists of a turbine (267) and a generator, the steam remaining after power generation by using steam steam in the condenser (790) water supply By recirculating the hard water (water) into the reactor by the pump 857 to the inside of the reactor, the recirculation water inside the condenser 790, the cooling water 816 to the circulating water pump 858, the external waterproof passage To cool water 816.

In the structure of the pressurized water reactor 811, the pressurized water does not pressurize to make steam, but produces hot water, which exchanges water and steam in the steam generator 810 to turn the steam turbine 267. Inside the reactor 811, a fuel, water, control rod 798 inside the reactor pressure vessel 813, and a coolant pump 859 outside the steam generator 810 and outside the generator 810 on the side of the pressure vessel 813. And a turbine 267 and a generator 213 as an intermediate portion of the pressure vessel 813 and the generator 810 and inject the coolant 816 into the condenser 790 to cool the water into the waterproof passage. 816 is discharged, and water is supplied to the steam generator through a feed pump 857 connected to the condenser.

In the structure of a gas cooling furnace, it is a reactor which uses graphite as a moderator 819 and carbon dioxide 164 as a coolant. Using natural uranium or enriched uranium (about 1%, 812) as a fuel and carbon dioxide (164) as a coolant improves steam conditions because it is superheated, so thermal efficiency similar to thermal power can be obtained.

In the structure of the multipurpose hot gas furnace, graphite is used as the moderator 819, helium gas 163 is used as the coolant, and uranium 812 and thorium are used as the fuel. The heat of helium gas 163 is transmitted to the water to generate steam.

In the structure of the new conversion furnace, the newly developed and noticed new conversion furnace can increase the utilization of nuclear fuel much more than the existing reactor. Hard water is used as the coolant. As they rise between fuels, they become hot and produce steam. Water and steam are separated in the steam drum 792. This steam is sent to the turbine 267 to generate electricity. As moderator 819, heavy water is used. Since heavy water does not absorb neutrons 812 better than hard water, utilization efficiency of uranium is good, and as a fuel, plutonium 801 is mixed with natural uranium. The state in which a nuclear fission chain reaction continues at a constant rate is called a threshold.

The difference between the atomic bomb and the nuclear reactor is that the fuel of the reactor 811 containing a little uranium 235 (812) has a small possibility of nuclear fission by the neutron 812 caused by the nuclear fission, so that no intense chain reaction such as an atomic bomb occurs. Is to explode in a flash, and nuclear power is controlled by burning uranium 235 (812) with a thin mixture of fuel to burn slowly. Nuclear fuel made by baking low-enriched uranium is called pellet (683) and shreds pellet (683). The fuel rods filled in the Kaloy tube are the fuel rods, and the fuel assembly 671 collects the bundles of the fuel rods in a square bundle.

Another problem is that because uranium 235 (812) is only 0.7% in nature, we are studying uranium 238 (679) as fuel, which is about 140 times that of uranium 235 (812). Plutonium 801 that can be produced is produced in the production process is uranium 238 (679) neutrons (821) collide with the uranium 239 (653) beta (β) radiation is emitted, the neptunium (662) Plutonium 801 is produced after the neutrons 821 are extruded from the body of the neptunium 662 while the alpha (α) particles are separated.

This is because the plutonium 801 becomes a fuel of the reactor 811 because nuclear fission can be performed. So it's like changing the nuclear fission uranium 238 (679) to nuclear fission plutonium (801), and in the spent fuel rod (689) there is plutonium from the uranium 238 (679), which is taken out and used as fuel for the reactor (811). To use.

In the structure of a fast growing furnace (FBR), first, the center of the fuel rod 689 is uranium enriched with about 20% of uranium 235 (812), or a mixture of natural uranium and plutonium (801). Is surrounded by natural uranium. In the fuel rod 689, plutonium 801 produced from uranium 238 (679) is taken out and used as the next fuel.

Secondly, the coolant uses liquid metal sodium, and there is no need to slow down the neutron 821, so that the moderator 819 is not contained.

Third, the heat generated in the reactor 811 is transferred to the other liquid metal sodium in the intermediate heat exchanger 657.

The fourth heat exchanger 658 turns the turbine 267 by converting water into steam with liquid or sodium heat.

Fast breeders are often associated with the production of atomic bombs, and many are opposed. The reactor is the world's largest fast growing reactor, a super phoenix plant in France, built in Craymarville on the banks of the Rhone River.

The stability of the reactor 811 will be described as follows.

First of all, the reactor 811 is unlikely to explode due to the control rod 798. However, if the control rod 798 does not move due to a failure, the temperature in the reactor 811 keeps rising and will not explode when the temperature increases. ? The question arises, but there is no inherent safety in the reactor.

Intrinsic safety is referred to as the Doppler effect and the void effect. The Doppler effect is the following process, when the temperature in the reactor 811 first rises, uranium 238 (679) eats neutrons (821), the fission embers of uranium 235 ( Since the number of neutrons 821 for nuclear fission is reduced, the nuclear fission is weakened, and thus the temperature in the reactor 811 is naturally lowered to restore stability.

Another one is the void effect, which is called a bubble. When the temperature in the reactor 811 rises, bubbles are generated, and the effect of the moderator 819 is weakened, so that the speed of the neutron 821 is not slowed down. You can't catch neutrons 821 well, in other words. Nuclear fission will be less so that the temperature in the reactor (811) will also be lowered to restore stability.

Nuclear power costs more to build than thermal power, and nuclear power costs less than thermal power. The core is made by inserting the fuel assembly 671 in sequence, and the bottom of the reactor 811 is fixed with a reinforced concrete mat of several meters in thickness.

In some deserts in the United States, various types of cores were made and tested, but experiments were carried out with a lot of fuel and a large number of control rods (798) at once. In view of this, the reactor 811 has been proven safe.

But what if an earthquake occurs? To answer questions, explain the following:

First of all, the nuclear power plant 672 is built on a solid ground, and the ground is firm and unstable, and if the earthquake strikes, it is stabilized like a stove so that the fire on the floor automatically shuts off. As a result, a large number of control rods 798 are inserted at a time, and the reactor 811 is emergency stopped.

Huge amount of radiation is generated in the reactor 811. The cross-sectional view of the reactor structure is as follows. The reactor 811 is once secured by five layers of walls. The inner pellet 683 of the fuel rod 689 was called the first wall, the cladding tube 682 surrounding the fuel rod 689 was called the second wall, the reactor pressure vessel 813 was called the third wall, and the pressure vessel ( The containment vessel 808 on the circumferential surface was called the fourth wall, and the reactor building 688 on the outer side of the containment vessel 808 was called the fifth wall.

However, at the dawn of April 26, 1986, the Soviet Union's Chernobyl nuclear power plant exploded, causing the worst of 30 years of world nuclear power. The amount of radioactive material sprayed on Earth in the Chernobyl accident was far greater than the amount of ashes of all nuclear tests conducted by countries around the world. The Chernobyl reactor 811 is a graphite deceleration boiling type, so that the moderator 819 is graphite, so it was not possible to extinguish the fire with water when an accident occurred. Because water reacts with graphite to produce carbon monoxide, the flames are more intense. Helicopters sprayed large amounts of sand, lead, and neutron (821) absorbing boron.

As recently as early April 2011, a large earthquake in Japan's oceans caused several nuclear power plants to explode, causing further damage to the world by radioactive pollution.

In order to prevent the explosion of the reactor 811 and to ensure the safety of the reactor 811, the facility is equipped with a safety reactor 811 having a double pipe (double canister) structure, and to solve the radiation waste treatment method and to minimize the explosion of the nuclear power plant. It is filled with absolute safety measures.

The present invention has been made to solve the above problems, weather conditions such as typhoons and earthquakes, such as typhoons, during the operation of nuclear reactors of a number of nuclear power plants installed in accordance with the installation location of the river inland and coastal coastal areas of the global village Do not allow the reactor to explode under any adverse conditions so that nuclear power can be shut down or the reactors explode from the strongest waves such as volcanic eruptions. And by re-installing the double pipe structure block tank reactor using nuclear explosion prevention to several nuclear power plants to prevent environmental pollution such as nuclear waste, etc., it is not affected by weather conditions and is not affected by earthquakes and tsunamis. Reactors run safely and continuously It is an object of the present invention to provide a nuclear waste treatment method and a reactor facility.

In addition, the present invention by installing a plurality of double pipe structure block tanks on the circumference of the existing reactor body in preparation for the shutdown of the reactor and before and after the reactor explosion nuclear waste that can eliminate the reactor operation and maximize the explosion protection of the reactor It is another object to provide a treatment method and a reactor facility.

In addition, the present invention is to produce a low-cost energy by using a double-pipe reactor of a nuclear power plant, a nuclear waste treatment method that can solve the environmental pollution problem as a fuel substitute for expensive petroleum, coal fuel, etc. of thermal power generation And another aim is to provide a reactor facility.

Nuclear waste treatment method and a nuclear reactor facility using the nuclear explosion prevention of the dual-structure block tank according to the present invention for achieving the above object, a huge amount of radiation is generated inside the reactor 811 of the reactor facility, the reactor 811 is Numerous double pipe structure block tank for nuclear waste storage, which is a radiation connecting the reactor 811 of nuclear power generation safely consisting of five protective walls and the circumferential surface of the reactor pressure vessel 813, the third wall of the reactor 811. A reactor facility using nuclear power in a nuclear power plant body (1) comprising 598, wherein the nuclear power plant generates nuclear fission within the reactor 811 to produce steam from the heat to produce a steam turbine (267). Steam turbine (267) for generating power by rotating), and the generator (772) for switching the power produced from the steam turbine and Rotor coil 774 which is a rotating electromagnet installed along the circumferential surface of the shaft 198 that connects the steam turbine 267 and the generator 772, and is installed along the circumferential surface of the rotor coil 774 A generator unit including an armature coil 773 for a generator which is a non-rotating coil and a frame 775 integrally fixing the generator 772 and the shaft 198 to the steam turbine 267; Cooling water (287) piping line 352 having a connection structure with the condenser 790 in the lower portion of the steam turbine (267) body of the power generation unit, the conduit line (169) and the coolant ( 287. A circulating water pump 858 is connected to the pipe line 352. A water supply pump 857 is formed at the rear of the condenser 790 and outside the reactor 811, and is located in front of the water supply pump 857. A plurality of coolant pumps 859 are formed outside the reactor pressure vessel 813 body in which the uranium 812 fuel is stored. Installed in the reactor pressure vessel 813 is a safety device control rod 798 is installed, when a shake occurs, the control rod 798 is automatically inserted a lot at a time, the reactor is an emergency stop, the pressure vessel 813 of the reactor Installation outside the body Is connected to the steam generator 810 and the steam dryer 786, the containment vessel 808 corresponding to the fourth wall of the reactor 811 and the upper part of the reactor building 688 corresponding to the fifth wall. After processing a plurality of through holes at a constant 45 ° angle with an oxygen cutting machine and a construction machine, the plurality of through holes block a plurality of safety valves 472 while forming a block pipe line 74 having a double pipe structure. A double pipe structure having a diameter of twice the diameter of the reactor building 688 along the outer wall circumference of the reactor building 688 and connected to a flange with a bolt 24 and a nut 25 to the pipe line 74. Nuclear waste treatment storage tank (599) and radiation type connection structure is formed in 8 block tanks (598) of the reactor and protects the pellet (683), the first wall of the reactor (811), and the fuel rod (689), the second wall. Reactor, which is the third wall due to high earthquake of magnitude 5 or more, When the inside of the pressure vessel 813 is exploded, a plurality of safety valves 472 are opened, and the nuclear wastes exploded through the block piping line 74 at each point passes, whereby the nuclear wastes are stored in each of the block tanks 598 and have a lifetime. When dismantling a reactor such as a nuclear power plant, cutting by a remote control or a robot 700 is used. When the explosion inside the reactor pressure vessel 813 stops, a plurality of safety valves 472 are closed and the reactor is normally operated. A plurality of safety valves 472 are closed and various nuclear reactors can be installed on the barge 591 of the sea, and the installation position of the nuclear power plant is adjusted to 40 m above sea level so as not to be restricted by meteorological conditions, thereby being affected by earthquakes and tsunamis. To prevent the nuclear reactor (811) of the nuclear power plant from being exploded and to prevent the environment from being polluted by nuclear waste. By re-installing the dual-structure block tank reactor facilities, such as the blast furnace does not explode, to ensure a safe and continuous operation, it is characterized in that the safety of the nuclear power plant to ensure safe operation and the reactor 811 renovation.

Here, in the waste generated from the nuclear power plant and a method of treating the same, when the pressurized water reactor 811 is used when the air in the building and the air contained in the water in the reactor 811 are gases, the radioactivity is weakened. The active membrane-type gas hold-up device 213 discharges purge air to the outside, or the power plant building ventilation is discharged to the plurality of symmetric filters 214 or vented air is discharged from the exhaust tower 215. Can be.

On the other hand, when the water leaked from the valve of the nuclear power plant and the regeneration solution of the ion exchange resin in the general water in the building is a liquid, the wash water is collected in the storage tank 216 and filtered by the filter 217, then radioactivity measuring device ( 218) and then measure the radioactivity and confirm that there is no harm, then send it to the sea with cooling sea water. After the water other than the wash water is purified by the filter 217, the filtered water and distilled water may be reused as a reactor coolant, and a monitoring post 219 for monitoring may be formed.

In addition, when the hybrid species in the building of the nuclear power plant, such as cloth, work clothes, shoes, etc., the ion exchange resin and the filter medium are solid, the filter sludge and the used resin liquid are stored in the storage tank 216 and solidified with concrete. Put the drum container 220 and compress the paper or cloth to reduce the volume and attenuate, and all of them are solidified into concrete and filled in the drum container 220, the waste storage building to move and store the waste by a forklift inside the site (332) ) And a monitoring monitoring post 219 may be further formed.

In addition, the nuclear fuel used in the nuclear power plant and the remaining uranium 812 is processed in the reprocessing plant 228 and then processed into uranium fluoride 812 in the conversion plant 229 to the enrichment plant 230 as a nuclear fuel. And convert the uranium fluoride 812 to uranium dioxide in the conversion plant (229) and processed into pellets 683 state to produce fuel rods and the plutonium (801) processed in the reprocessing plant (228) is converted? Fuel rods 689 are made in the processing plant 231, and these reprocessed fuel rods 689 are moved back to the nuclear power plant 672. The nuclear power plant 672 and the reprocessing plant 228 are enriched in the plant. The conversion and processing plant 231 to the 230 and the conversion plant 229 may be formed on the upper surface of the barge deck deck of the sinking type of the upper sea level of 40 meters.

In addition, the high-level wastes, which are wastes from the reprocessing process in the nuclear power plant 672, have long half-lives and need to be stored for thousands of years, so that nuclear wastes are buried deep in layers or ocean floors. Method, and the method of nuclear fission in the reactor 811 to convert to other materials, such as sending to space, etc. At this time, the permanent disposal method of high-level waste, construction machinery heavy equipment rudder, excavators and ships and double pipe structure drum (220) The space rocket 612 and the space rocket launch pad 646 may be further formed on the upper surface of the barge deck deck 591.

In addition, in the case of a failure in the reactor 811 of the nuclear power plant 672, when the repair and maintenance work period takes more than three months, the reactor 811 piping line is blocked by the safety valve 472 and then separately The boiler 783 may be connected to the reactor power generation facility to provide a thermal power generation facility for emergency power generation by supplying high temperature, high pressure steam.

In addition, the double-pipe block tank 598 of the nuclear waste storage tank of the nuclear power plant 672 is composed of an inner block tank (596) and an outer block tank (599) to firmly block the block tank 598 of the double pipe structure. The inner wall of the inner block tank (596) and the outer wall of the outer block tank (599) circumferential surface of the inner block tank (221) to the steel plate (221), Tyrongji steel bar (600) and O-ring steel bar (601) to the steel plate bracket (165) As an assembly process such as computer underwater cutting and welding, the hydraulic cylinder door (624) to allow forklifts to enter and exit the manhole and the manhole cover on the walls of the respective inner block tank (596) and outer block tank (599). Nuclear waste treatment method and nuclear reactor facility using nuclear explosion prevention of a dual-structure block tank characterized in that the (ii) is further formed.

As described above, the present invention of the problem solving means is deteriorated weather conditions such as typhoons, earthquakes, volcanic eruptions, etc. during the operation of nuclear power reactors of a number of nuclear power plants installed in accordance with the installation location of the river inland and coastal coastal areas of the global village In order to overcome this situation, the nuclear reactors will not be able to explode under any severe conditions, and nuclear reactors will be decommissioned. By re-installing the double pipe structure block tank reactor using nuclear explosion prevention to several nuclear power plants to prevent environmental pollution, nuclear reactors of nuclear power plants are safe and secured without being affected by earthquakes and tsunamis without being restricted by weather conditions. Continuous operation can be performed.

In addition, the present invention can be installed in the circumferential surface of the existing reactor body in order to stop the reactor and before and after the explosion of the reactor by installing a plurality of double pipe structure block tank can eliminate the reactor stop operation and maximize the explosion protection of the reactor.

In addition, the present invention by using a double-pipe reactor of the nuclear power plant to produce low-cost energy, it is possible to solve the environmental pollution problem as a fuel to replace expensive petroleum, coal fuel, etc. of thermal power generation.

In addition, the block tank of the double pipe structure, which is a nuclear waste storage tank of the present invention can act as a dust collector, thereby distributing high-temperature, high-pressure gas heat to the atmosphere, thereby greatly contributing to environmental improvement projects.

1 is a flow chart of nuclear, hydro, thermal power generation of the prior art level.
[1-1] is a side view showing the thermal power generation structure of the upper surface of the barge deck deck of the marine power generation by burning heavy oil,
1-2 is a partial perspective view of a partial structure perspective view of the inside of the boiler 783 and the outside of the boiler 783 and a steam pipe connection structure connected to the turbine and the generator,
1-3 is a perspective view of a power generation unit including a rotor coil 774 and a frame 775 fixed to an electric coil 773 installed on a steam turbine 267 and a shaft 198, and a power plant control room ( 781) a perspective view partially showing the inside,
1-4 is a side view showing the isotope structure of hydrogen in the structure of the atomic nucleus and the structure of the atom from the side,
1-5 is a perspective view showing the structure of nuclear fission of uranium 235 (812), which is a nuclear fuel,
1-6 is a side view (top view) partially illustrating a method of using a control rod to control a chain reaction of nuclear fuel fission in a reactor 811 inside a nuclear power plant body 1, and an intermediate side view is an atomic bomb and a reactor; A side view showing the difference between the lower drawing is a reactor fuel generation diagram showing the process of generating the plutonium 801 in the uranium 238 (679).
1-7 is a lower perspective view showing the core of the nuclear power plant 672, and the upper end is a perspective view showing the interior of the water reactor.
1-8 is a side view showing the structure of a boiling water reactor 811 among various reactors, and a bottom view is a side view showing the structure of a pressurized water reactor 811,
1-9 is a side view showing the structure of a gas cooling furnace among various reactors 811, and a middle view is a side view showing the structure of a multi-purpose hot gas furnace, and a diagram showing the structure of a new conversion furnace. Side view.
1-10 is a side view showing the structure of a fast growth reactor (FBR) among various reactors (811), the middle is a side perspective view showing the reaction process of the fast growth furnace, the bottom is a structure of nuclear power generation This is a side view showing the difference between the structure of thermal power plant and thermal power plant.
1-11 is a side cross-sectional view showing the reactor structure divided from the first wall to the fifth wall.
1-12 is a schematic view of a conventional diesel engine and an exploded assembly model of an electric motor.
1-13 is a perspective view showing a hydroelectric operation and a seal type formed inside a hydraulic cylinder;
1-14 is a cross-sectional view showing the structure and function of the transformer on the barge deck deck 591 of the ocean and the cross section of the transmission tower and transmission line,
1-15 is a perspective view showing an ultra-high voltage substation inside the nuclear power plant body 1 in the ocean,
1-16 is a side view showing a power supply process from a nuclear power plant to a home and a perspective view showing a secondary substation structure,
1-17 is a configuration diagram of a conventional fire fighting equipment pump operation method,
1-18 is a conventional 〃 〃 configuration diagram,
1-19 is a configuration diagram of a conventional compressor installation,
1-20 is a partial side view showing a partial side of a conventional fire hydrant equipment,
1-21 is a plumbing facility system diagram of a conventional sprinkler facility,
[Fig. 1-22] is a pump operation diagram showing the installation state of a plunger pump, a turbine pump and a sewage pump in a conventional piston pump.
2 is a schematic representation of the scheme of a reactor 811 installation of a nuclear power plant body 1 according to the invention.
3 is a flowchart illustrating a method of cutting or using a robot 700 by remote control inside the reactor 811 according to the present invention.
4 is a flowchart illustrating a nuclear fuel movement process and a nuclear reactor 811 renovation inspection scene according to the present invention.
5 is a flowchart illustrating an assembly process method showing a barge for mounting a nuclear power plant body 1 according to the present invention;
5-1 is a diagram showing the formation of a body of a marine power plant (barge hull manufacturing process showing the front and side of a steel pipe banding method for a pipe block of a barge hull and a welded basic method inside a pipe of a double pipe structure)
FIG. 5-2 is a partial partial detailed configuration diagram showing in detail the side and cross-section of a double pipe block piping connection portion of a barge hull inside a power plant body in the ocean, and a whole configuration showing a coupling method of a barge hull inside a power plant body. Is a schematic diagram of
[Figure 5-3] is a block diagram of the barge unit tank decomposition coupling scheme showing the barge hull of the marine power plant body bar by bar unit tank,
[Fig. 5-2], [Fig. 5-3] ... each is a block diagram illustrating an embodiment according to the configuration of the present invention;
It is a configuration diagram of a dry farming dock assembly method showing the combined tank unit in the sea and seabed using a tugboat 636 and a helicopter 647,
[Fig. 5-4], [Fig. 5-5], [Fig. 5-6] .... each is a block diagram illustrating an embodiment according to the present invention configuration.
5-4 is a seam safety tool kit band jig 621 on the top of a semi-submersible work line of the sea to make a welding connection to each of the tank block pipe 598 of the floating breeding hull of the marine power plant body of the present invention. Partial side block combination for partial tank block piping unit for tank block piping 598 and band jig stand 621 showing the tank block piping side connection method configuration diagram showing underwater cutting and underwater welding preparation process Method of construction
5-5 shows the details of the bracket 165 on the port plug block 606 for the port plug and the port plate for port plug 607 of the connection block coupling means for connecting the block pipe 598 for the tank of the power plant body of the present invention. Portion of the block piping unit connection for one partial tank Partial side detailed view showing the port shaft of the plug block 606 of the coupling separating means of the outer block tank 599 of the pyramid type, the plate 607 for the port plug and the lug ( 21) Partial partial side view of the external block tank (599) vertical horizontal connection showing the coupling method in detail
5-6 is a subsidiary poison connection for connecting a large subsidiary poison 595 to a small subsidiary poison 593 and a medium subsidiary poison 594 for each type of subcultured poison into the body of the marine power plant of the present invention. Connector lug hinge socket (613) Umbrella folding, Umbrella unfolding type hydraulic cylinder or hydraulic cylinder jockey (623) showing the way of using a deep sea bottom low-rise excavator with a drill machine drill tank holding (pier column) Barge hull block piping connection method of the barge hull 592 at the bottom of the holding tank is a detailed configuration of the barge hull block pipe assembly connection maritime assembly part showing the partial cross-section front part in detail.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are provided as examples to ensure that the spirit of the present invention can be fully conveyed to those skilled in the art. Therefore, the present invention is not limited to the embodiments described below, but may be embodied in other forms. In the drawings, the width, length, thickness, and the like of the components may be exaggerated for convenience. Like numbers refer to like elements throughout.

First, in the material selection of the reactor facility of the present invention, eight block tanks having a double pipe structure having a diameter of twice the size of the reactor building along the outer wall of the reactor building of the nuclear power plant are rolled steel for KSD 3515 welded structure. The steel plate and barge hull supporting and reinforcing the inner block tank and the outer block tank, which are installed outside the circumferential surface of the support tank, in the holding tank and block pipe having cylindrical shape as rolled steel for KSD 3515 welded structure. The KSD 3560 heat-resistant steel (KS symbol; HRS, H-Heat R-Resisting S-Steel) is used for the rolled steel for KSD 3560 boilers. ; Horizontal × length × height × iron plate thickness (Tie), 600M × 800M × 40M × 18mm) Type 2 (barrel hull of the medium-sized floating dock holding tank; horizontal × length × height × iron plate thickness (tee) 2 mm × 3.2 km × 40 M × 22 mm) and 3 types (barge hull of the upper part of the large floating dock holding tank; width × height × height × steel plate thickness, 10 km × 12 km × 40 M × 24 mm) The standard type of pipe bridge of 92,500km tunnel crossing the five great ocean poles (width × length × 4 corner diameter × steel plate thickness × manufacturing unit length, 15M × 15M × π15M × 24mm × 500M) and the pier diameter of 5M Standardly, the bridge diameter is increased by 5m to 1m with the reddish-type jointing area per km according to the sea depth. It is set up to 300M height, and then the height is adjusted within the sea level (SLL) and the bottom of the sea level 40M to ensure the safe navigation of the maritime ship, and the thermal power plant installed on the barge hull, nuclear reactor facility, nuclear fuel reprocessing plant, etc. are formed. , Five ocean meat Organized by the load of the bridge body was dispersed and reasonable for such can be renovated by using a nuclear explosion prevention of the double tank structure block nuclear waste processing method and nuclear power generation equipment.

1 to 5, the reactor facility of the present invention is configured as a barge-mounted type detachably assembled to the deck deck upper part and the deck deck bottom part of the barge body, which is the accident-free global village nuclear power plant body 1, as shown in FIGS. As shown in the drawing, the pipe manufacturing process 705 of the marine nuclear power plant body 1 is described.

Manufacturing Process (705) consists of small diameter electric resistance welded pipes and SAL to large diameter steel pipes (22? 82 inch OD, 747) and spiral welded steel pipes (400A? 2600A; A = m / m, 760). 3/8? 8 inch OD, 706) and medium-caliber cage molded electric resistance welded tube (8? 24 inch OD, 739) are manufactured separately by the general industry (the city symbols are shown for detailed description).

The first is the manufacturing process flow of small-diameter electric resistance welded tube and SRM (SRM; 3 / 8-8 inch O.D, 705).

Second is the manufacturing process flow of medium diameter cage forming electric resistance welded tube (8 ~ 24 inch O.D, 739),

Third is the manufacturing process of large diameter steel pipes (22-82 inch O.D, 747),

Fourth, the manufacturing process of spiral welded steel pipes (400A ~ 2600A, 760).

In addition, since conventional launching facilities (dockyards) in shipyards are provided (width x length, 131m x 530m), barge block piping (width x length x length, 20m x 30m x 500m or less) Construction of block pipes in one unit, construction of manholes and doors to completely secure the safe launching conditions, renovation of block unit tanks, lifting barges and tugboats on submersible and semi-working submarines, lifting vessels, launchers and navigators. Each piece of equipment is formed on the top of the barge deck deck so that the mooring system can be automatically fixed and released using the

The nuclear power plant body (1) is KSD 3515 material thickness of 24mm and the high tensile iron plate (597) to a certain dimension welding the same as the basic method of welding (713) joints, butting the neck cross-section of the adhesive metal to be inserted into the weld The shape of the welded joint groove (H type, I type, K type, J type, V type, H type, X type, V type chamfered, 727) is welded 713 improved chamfering for welding. The computer network includes a block piping 598 for the internal piping 14 and the external piping 14 for the area of the inner pipe 14 and the area of the outer pipe 14 so as to be designed in consideration of tensile strength and sheet thickness. Tie, a high-strength iron plate 597 cut by an oxygen cutting machine and a computer laser cutter, which allows up to an error of 2/100 or less, depending on the selected dimensional specification. Longji steel bar 600, O-ring steel bar (601), Tub lug plate 602, horizontal bulkhead 609, bulkhead manhole 610, manhole cover 152, hatch cover 153, block flange connection large flange 614, the flange Machining hole 615 and the long hole hole (LONG HOLE, 616) of the hole for the portable lug plate 607, the band jig stand 621, which is a marine safety assembly tool, and the steel plate welding coupling bracket 165 The welding improvement surface is formed in the manufacturing factory by cutting the laser under water, but the unmanned camera 184 of the control system transmits the cutting machine and the cutting state so as to check the work site, but through the calculation of the computer control server 51. Submerged cutting and computer laser cutting device formed to display the work site status on the monitor 52, and the welding to fill the grooves in the shape of the various welded joint grooves of the welding improved surface produced by the cutting device.

After the groove is finished, the grinder is finished, and three rolls are changed (749). The machine operation control unit moves to the crane 861 equipment, and the block pipe 598 is divided into the inner pipe 14 and the outer pipe 14 with a length of 1,000M. After the banding welding, the flanges for the block tank connection are welded (mounted welding, 751) by the standardization of the flanges on both the inner pipe (abbreviation for the inner pipe) and the outer pipe (abbreviation for the external pipe). Next, the inner tube and the exterior are designed by the O-ring steel bar 601, and the scarf welding holes 602 are arranged in an orderly manner, and after the welding process 751, the barrier ribs are formed on the thi long paper steel bar 600 and the horizontal bulkhead 609. Attached to the manhole 610, the manhole cover 152 and the hatch cover 153, the attachment part portable lug plate (607) and the lug hinge socket (613) is attached to the first inspection by visual (MT) If welding is not good, take a second inspection with paint spray (PT) after re-welding. If welding is bad, re-amend the welding.In the case of the 3rd temporary welding, replace the welding welder so that the welder can be welded, and then proceed with thorough work supervision so that the main welding can be done. After being assembled and assembled with a water-tight pipe support, a single floating dock is formed, and the wire rope 19, lever block 123, and turn-back claw rope 629 and block unit tank are formed with the bolt and nut for the lug shaft. It is a prerequisite according to the installation process in the sea that is attached to the flange joint by the buoy flag pole rubber balloon 628 and the bellest butterfly valve 305 of the sea assembly position identification air buoy.

The block pipe 598 is moved to the tugboat, and then the subculture dock coupling part is transferred to the work site, and then assembled by the band jig 621 of the semi-submersible work ship 637, the prop of the barge hull 591. Connect the lug shaft 606 to the holding tank 590, the inner block tank 596 and the outer block tank 599 for the portable lug plate 607 to either the top or the bottom of the tank. But the port rug pin 608 is fastened to the machining hole of the lug shaft 606 after the bolt nut is coupled to the pin 608 so that the pin does not deviate and is installed in a bending manner, but the barge hull of the bottom of the support tank 590 ( 591) The sinking prevention and upsetting device of the marine nuclear power plant body (1), which is provided and fixed with the pedestal adjustment mechanism working key bed (616) and the excavator (845) device, and the top of the deck deck at the top and bottom of the holding tank barge hull after manufacturing assembly. Formed at the bottom of the mount An integrated power plant arrangement is formed.

The multiple disaster-free global nuclear power plants (Tunnel Dock) body (1) is supported by a marine plant structure, which is a marine steel structure that is installed and operated as a disaster marine environment disaster prevention control device and all of marine development equipment. Marine dock after disassembly and assembly of parts on the land by the holding tank top barge hull 591 and the holding tank bottom barge hull 592 formed by the holding tank 590 under the dock hull deck upper part (SDU) of the dock. In consideration of the situation in the offshore installation area, small parts of the subsidiary dock (593), medium sized subsidiary plants (594), and large nuclear plants (595) were installed separately. Regulations by the International Maritime Safety Association, depending on the depth of the ocean, to the North Pole (NP) and the South Pole (SP) region of the Equator (EL) or to the Great Ocean latitudes and longitudes. It may be selected according to the specifications of the ordering party (omitted under the UN Security Council, the International Economic Development Association, and other cooperative organizations).

The parts of the nuclear power plant body (1) are made of marine (marine, subsea) iron structural metals according to the manufacturing process according to the safe design of the floating ship hull at any industrial site of the marine vessel manufacturing plant or the heavy metal processing industry. The steel sheet is selected from a high strength steel sheet or a tough metal sheet and formed into a block forming pipe 598 for tanks in a forming or roll forming machine according to the sheet thickness. (C) V-shape, (c) Round-shape, Press-brake type with angle bending method Roller bending method and three bending rollers Bending or bending method of steel plate for piping (598) ) Is manufactured and then welded (tech welding, 751) to the seam.

" 형식의 쇄기, 185)가 통상 선박제조공장인 일체의 산업현장에서 작업공구로 실제 현장에서 사용되고 있다After the tank block pipe 598 is welded to a plurality of blocks, the original design number for each unit of the block unit pipe 14 is indicated so that the identification number is written out to the outside of the pipe, so that the main welding 713 is the next manufacturing process. The detailed description of the shape of the welded joint and the shape of the groove will be described as follows, but in the form of various types of jigs ("a", "∩", "T") to prevent the sinking of the ship when the ship is dried. Jig, 22) and wedges ("

"Type Wedges, 185) are commonly used as actual working tools in any industrial field, a shipbuilding factory.

As described above, in the basic method of welded joint, the welded joint (a) is a butt jointed joint with one block pipe 598, and (b) corner jointed method and (c) edge jointed method for other steel plate reinforcement. (d) Overlap joints, (e) T joints, (f) Cross joints, single cover plate and fillet joints, and double cover plate joints. Has the same form as the basic method of welded joints. The thickness of the cross-section of the adhesive metal in the weld is called a throat, and the welding of overlapping joints, tee joints, or the direction of the neck forming the welding angle (45˚) with the surface of the base material (fillet weld) ), And the weld area is explained in chapter, but the welding work is actually used in the field.

Butt joints are harder to be welded to the inside as the plate thickness becomes thicker. Therefore, the ends of the joints are appropriately cut to make them completely welded.The figures below are the shape of the weld joint grooves, H type, I type, K type, J type, After dividing into V type, H type, X type, and V type, oxygen cutting is performed in the form of iron plate improvement, and then it is temporarily welded after cutting the grinder.

The figure is a side view of the iron plate improved surface for welding welding plate,

As shown in the shape of the grooves, the steel plate improved surface removes rust and impurities from the weld surface before welding of the grinder cutting and merges one block pipe 598 into another block pipe 598 after welding seam work. The two block pipes are welded by another two pipes, and the inner and external pipe welding seams are separated by zigzag distance gaps at regular intervals. Pipe and valve connection to outside of external pipe to both ends of pipe Large flange (614) Two inner and outer large flanges (614) are fixedly mounted by welding joints to one end and the length of the block pipe large flange The stopper iron plate 625 of the block piping 598 seals the inside of the block piping by welding at both ends into the inside of the 3m external piping. The

Thus, the partition manhole 610 and the manhole cover 152 and the hydraulic hatch cover 153 is produced around the suture stopper plate 625 and must be installed for on-site work at the top of the sea level and valve and equipment replacement after work. Pyramid acts as an auxiliary support for supporting the holding tank 590, which is a block pipe 598 of the double pipe structure at the bottom of the upper portion of the barge hull (591) of the top of the holding tank (590) according to the bottom of the seabed, and the central holding tank (590). Type inner block tank (596) and outer block tank (599) in the outer circumference of the block tank (596) is a reinforcement plate Tielongji steel bar (T LonG) for the combination of the block pipe inner support tank and the outer support tank of the dual structure 'Steel BAR; 600) and tee type reinforcing steel plates or O-ring steel bars ("O" Ring steel BAR; 601), which are used as a welding material to the holding tanks and auxiliary tanks inside and outside the block tanks. In this case In order to alleviate the welding defect of the double block piping, a scarf welding hole 602 is designed so that welding can be firmly performed on the reinforcing steel sheet, and then an oxygen cutting operation process is performed.

On the other hand, in the coupling method of the barge hull (591) deck deck of the top of the holding tank and the upper portion of the iron tower 116, the lug pin shaft 606 to the lug pin shaft 606 for coupling the steel tower 116 for the block to the coupling portion. A coupling bolt 603 and a nut 604 are provided to combine the floating dock (barge hull), the holding tank, the vertical bulkhead 605 inside the inner and outer supporting tanks, the central holding tank and the inner and outer supporting tank blocks. Horizontal bulkhead inside the auxiliary support tank block in the form of a stand-up dock holding tank and a pyramid type with a detachable port plug pin 606 and a port plug 607 or a portable plug pin 608. 609, the partition manhole 610, which is an emergency passage, a manhole cover 152, a hatch cover 153 that is a hydraulic safety control device, and a lug hinge socket 613 configured to a floating dock hull for sea assembly. The hatch cover (153) and other attachments In order to couple the large flange 614 and the large flange 614 connected to the block tank, the bolt nut is double-tightened from the sea level (SLL) to the plate joint processing hole 615 for vertical and horizontal disassembly coupling. High-strength bolt and high-strength nut are connected to a plurality of joint processing holes 615. First, the high-strength bolt and high-strength nut are partially connected to the odd and even number of portable plug plates. Insert the nut into the bolt thread body at both ends of the lug pin shaft and bind the portable lug pin 608 to the lug pin processing hole so that the tank block is never released from the tank block joint processing hole 615. Characterized by the configuration of the main portion including the maritime safety assembly method, the first stage is a pin shaft coupled to only one part of the coupling point of the plurality of dog pin shaft 606 The remaining portion is a constant angle of inclination may be bundled into a lug hole machining pin shaft 606 at the point where this meets processed hole 615 of each side to adjust the spring 468 is pushed out of the shaft (606).

Auxiliary equipment included in the marine safety assembling method of the aquaculture dock and the subsidiary parts of the subsidiary equipment for the anchor as a construction machine to install as an excavator (845) and a helm and a launcher 887 preferably as follows: Explain.

Jakki bed 616, which is a double-pipe vertical tank or barge hull underlay adjustment mechanism, a shaft 606 that is tightly adjusted to the long hole 616 of the long hole of each block piping unit or vertical horizontal hinge joint, and the upper deck deck A guide rail 618 for transporting the equipment and a helicopter stop 619 at the top of the floating deck deck deck are equipped with a submersible hydraulic cylinder for submersible work for the combined work of a block pipe or a double pipe tank frame of a priority folding type or Band jig unit for hydraulic cylinder operation key (623) and block pipe (598) combination tool for maritime safety work for submerged ships for underwater cutting and underwater welding of double frame structure tank frame coupling separation or block connection part (621) hydraulic cylinder is installed on the submersible work vessel, the ball is a submersible barge control submarine dock or submersible submerged control device H which requires prevention of sinking or extension of sinking time (time required for source structure) in case of stray butterfly valve 622, the floating culture hull engine and other power motors before and after the operation (WARMING UP) Dr. Venturation (585), a device of HVAC System, and a switch button-on door open-on and a switch-button-off device, which controls the hydraulic pressure inside the aquaculture dock or intake control device of mineral resources. A hydraulic cylinder door 624 that is door closed, a stopper plate that blocks or filters foreign substances from ballast or pump inlet openings (perforated plates of many processing holes, 625), and air piping lines for preventing ship sinking. ), And the emergency engine 226 for extending the ship's sinking prevention is provided with a double pipe structure tank for preventing the access of other ships during the assembly of the dock's safety maritime as a block piping unit. An airborne buoyant flag balloon 628 for position identification is provided with a rope rope 629 and a rope connection knot hook 630 attached to a tugboat or aquaculture dock, and the emergency stairs or inside the block pylon 116. A discharge suction vacuum pump for adjusting the balance between the step 631 and the elevator or the elevator 636 to the inside and outside of the barge hull 591 by the conveyor 633 for the mineral or mechanical equipment transportation device and the barge hull 592. 635 and the air flotation ship 634 of the air suction discharge method for the lifting of the sinking ship, the parts are manufactured in a marine ship manufacturing plant or an industrial site of heavy industry and then safety assembly method after moving the sea level (SLL) site It is formed by this tugboat 666.

Accordingly, a semi-submersible work line 637 on which an air flotation line 634 for preventing sinking of a ship or a double pipe structure tank block, a band jig for block tank joining for offshore work, and a rope fixing for a ship mooring device are fixed. A plurality of bollards 638 for termination or hull berth are installed on the industrial tank prior to maritime safety assembly and installed after transporting a plurality of bollards 638 to the top of the hull deck deck of the holding tank upper barge hull and the holding tank lower barge hull.

As described above, all parts for the aquaculture dock are detected in the industrial field and then procured as a general ship, and the skilled person should make the best efforts to achieve the accident-free target by adding safety to the arrangement of the aquaculture dock. The mooring device anchor (639) Wo, Anchor (639) linkage chain (anca chain; 640) dumps aquaculture dock on the bottom of the seabed to anchor the barge hull, and when the sea depth is deeper than the continental shelf, it is used as a drilling machine for oil drilling. After digging the bottom of the seabed, the anchored dock hulls the submerged settlement. The aquaculture dock refers to a set of non-powered lines coupled to barge hulls at the top and bottom of the holding tank 590.

As described above, in order to submerge the aquaculture dock hull, an air receiver tank 145 for an air storage tank, a cooling fan 645, which is an air liquefaction device cooling mechanism of HV Systems, an ad balloon 77 and an airship (78) and heater fan (HIT FAN) 642, which allows the hot air balloon 914 or the tub 188 to be raised in the air, and any person skilled in the artisans who engage in war, maritime and international diplomatic disputes. Satellite launchers (643) for expulsion and deportation outside of the global disaster-free atmosphere, Mooring Tower (644) for controlling and controlling the satellites and airships or nuclear bombs and missiles, and space equivalent to the satellites Installed in the rocket launcher 646 and the air compressor 80, which is an air compressor, by an air blower winch 137 operated by the air supplied from the air compressor 80, and a floating deck hull deck upper end (SDU). A crane 861, a wire rope 19 included in the crane 861, a wire rope chain 915, and an air blower winch 137 from the rear of the air compressor 80 to the front and rear of the air receiver tank. The air hose 109 is connected to the front and the bottom deck portion (SDL) of the aquaculture dock hull is equipped with an electromagnet magnet 645, a lematic 916 to transport the loess or cement to the pipe or high-pressure hose, and the le The mixing equipment mechanical mixer 73 is located in front of the matic 916 and the lever block 123 is provided for each tonnage capacity so that the unit can be combined in a block pipe 598 unit having a double pipe structure. After joining to the turn-buckle 640 again to fasten the coupling object, and the steel plate bracket 165 is provided with a male and female coupling hole in the steel plate bracket to be coupled to the holding tank or auxiliary tank coupling portion welded to the block pipe Flange back and flange The gasket packing or the rubber packing 32 is inserted in the middle of the large flange 614 by the gap between the large flange 614 and the large flange 614 so as to withstand the high pressure. 598) The tank block pipe flange, which is a double pipe structure inside and outside, is joined to the flange.

On the other hand, in the block piping 598, the joint portion is a stopper plate 625 to the flange connection portion to the air hose 109 pressure air generated in the air compressor 80 is mounted on the semi-submersible work line 637 Pressure air is stored inside the block piping to detect defects in the welded area of the block piping, and if there is no abnormality, if there is no abnormality, the appropriate amount of air is stored in the block piping and the block piping is placed on the water above the sea level (SLL). After drifting and settling the floating raft evenly, the rope and wire rope 19 and the wire rope chain 915 are fastened to the tugboat, and the block pipe 598 is transferred to the safety assembly site at the sea level.

As shown in FIG. 5, the connection method for each block piping unit of the double pipe structure type arrived at the marine safety assembly site, the dimension of the block piping unit length is omitted below.

(AB), (BC), (AC), and (AB) in English for the convenience of explanation, and (AR), (AQ), (AP), (AO), (AN), and (AM) within the distance. , Each with a distance,

In the method for manufacturing and installing the large-scale offshore nuclear power plant subculture dock 595 of the present invention, the developed view of [FIG. 5-1] is described as [FIG. 5-3] as follows.

The above block piping is (AB), (BC), (AC), and the triangle symmetrical form (ABC), (AB'C ') is a constant angle of (AB) (BC) (AC) of equilateral triangle. The angle of the three sides (60 °) and the constant angle of inclination (16) are precisely manufactured in three places where one side and one side meet.

The length of the three sides of the triangle of (ABC) and (AB) (BC) (AC) of (AB'C ') of the block piping is the same, and the length of (BC) when the height of the junction is about 10,000 meters Is approximately 12,621 meters and is a column on the center of the double pipe structure, which is a vertical column at the center of the subculture dock at the height (AL) and is centered on the height (AL) and (AB'C ') A) is joined to the vertex of the branch and the work process proceeds while contacting the semi-submersible work line 637 as the block pipe joining means and the mobile telephone of the short-range wireless communication device as the tug 636.

Here, the two sides (ABC) and (AB'C ') of the butt symmetry, the inclination angle (16) is combined with the (45 °) angle, and the angle of inclination (16) when the length of the height of the (AL) vertical column is enlarged As is enlarged, the triangular pyramid-type pipe area is enlarged, and the joint dimensions are constant.

Thus, the horizontal pipe (DE) in the (ABC) triangle is (BD) and (CE), and the angle of inclination (16) is a tree branch type in the form of a single-pipe flange with a pipe unit block. It is joined by automatic valve of type, and pipe (DE) is used with smaller pipe diameter than (AB) and (AC), and (BC) and (CE) parts are used for control pipe connection parts reducer (35). However, it is divided into four types (ABC) and (AB'C '), which are combined and connected in asymmetrical (ABC) (AB'C') and a large-scale nuclear power plant subculture dock (595). ), The four sides of the hollow space angle (120 ˚) of the circumference of the four sides of the block leaving the empty space of the angle divided into four block pipe joining means of the present invention docking docking separation porter plug plate 607 of the present invention And lug plae of the pinshaft 606 for coupling port separation plug port separation plug of the present invention A plurality of machining holes 615 are formed in the steel plate, and the two symmetrical machining holes are machined vertically and horizontally symmetrically, and one pin shaft 606 in one machining hole in two machining holes is correlated to one place. After the block is connected horizontally to the sea level, the block pipe is divided into (ARS), (AQT), (APU), (AOV), (ANW), (AMX), and (ABC). After confirming the completion of the partial joining process, one pipe mounted in one processing hole is submerged first, and then one pipe floats on the water. The remaining lug pin shaft 606 is engaged with the adjustment spring 468 or the hydraulic cylinder operation key 623.

At this moment, the tugboat is ordered with the wire rope 19 and the rope 629 of the tugboat to split the vertical block pipe into the wire chain block 648 (including the mutual pulling). Thus, it should be recognized that the size and dimension shape of the port plugs 607 and the pin shaft 606 vary depending on the pipe diameter.

In order to identify the diving position of the block piping, the rubber tubing for air input 188 inside the container is strictly adhered to and fixedly fixed to one end of the block piping using a rope. The assembly of the block piping is completed while reversing.

As described above, the aquaculture poison of the present invention is a marine disaster prevention and marine environment, characterized in that the smooth, flexible, decomposed coupling of the block pipe 598 of several hundred tons or partial and tens of thousands of tons of partial weight. The operation of offshore steel structures, including the purpose of harmful relief equipment and comprehensive disaster prevention system for industrial development, includes the use of gravity and buoyancy to control diving, distributing the load of objects according to tidal currents. .

In the block piping coupling method of the subculture dock, the joining portion is a recessed portion, as shown in Figs. 5-5 and 5-6, as shown in Figs. 5-5 and 5-6. Piers and tunnels are formed in nuclear power plants without the need for diving personnel (piles) regardless of depth.

The nuclear power plant body (1) is odd to the holding tank at a constant inclination angle with the pyramid type external block tank (599) in a vertical and horizontal manner to the vertical block horizontal circumference tank block 598 of the outer circumference of the barge hull center holding tank (590) Two lug plates 607 are welded to four circumferences and the outer block tank 599 is welded to the outer wall of four circumferential tanks. Formed with even numbers (including two, four, six, eight, and one long hole), the lug plate material is used as the steel plate for mechanical construction, and the plate thickness is 150mm at the pin shaft 606. Is 300mm in diameter and the shaft length is 800mm, and after processing the external thread in 150mm increments at both ends of the pin shaft 606, the nut 604 is coupled and the lug is released. To fit into a 608 is processing a Ø15 mm through-holes in two places on the pin shaft (606), wherein the processing is such that the lug plate and the shaft or pin bonding sites finishing work so as to be easily coupled.

In connecting the block piping, after joining one hole with one pin shaft in the processing hole 615 of the two lug plates and one lug plate, the object first prior to joining the lower end for joining after diving But

As shown in [Fig. 5-5], it is necessary for vertical and horizontal coupling, and according to the size and shape of the block piping, the processing holes are expanded to four places in two places, except for one place, a plurality of adjustment springs 468 are provided. Attached

5-6 is a partial front side detailed view for explaining the front side connection method of the block pipe for connection in the sea of the block pipe connection portion in detail.

The vertical horizontal block pipe coupling separation port plug plate 607 is arranged in a third position of the outer circumference of the block piping, one lug plate at the central position of the block piping to six processing holes 615 Another set of five hole drilling holes of two lug plates is the same as six hole drilling holes and the hole of the hole of the pin jointed to join the block pipe to the lower left corner of the right pipe block pipe. 616) two sets of precision cutting process welding on the two lug plate to bind the block piping coupling separation lug pin shaft 606 to the long hole (616) of the long hole on the sea level (SLL) line, so that the two block piping is sea level horizontal The piping block on the front side and the piping block on the side are hingedly coupled to the lower barge hull 592 and two triangular piping blocks of pyramid type. The connected pipe block is connected to the upper part of the lower barge, and the ballast opening and the butterfly valve 622 are sealed to the lower barge, and the high-performance submersible pump 36 is operated to fill the ballast tank inside the barge hull, and the bottom of the sea level is filled. As an aquaculture poison slowly lands.

At this time, the pyramid-type vertical and horizontal block piping connection flange connection bolt nut joining work and pin shaft coupling for joining the lug plate of the welding work site to the semi-submersible work line 637 for sea work at sea level Subsidiary dock function of submerged dock after completion of connection work of block pipe connection part with band tool stand (621) In case of diving, the plate-type wire rope (19) and lever block (123) and turn-back (640) for lug of pipe block and block pipe coupling part of horizontal type of 1,000m height and search light for submarine mineral resources (232), the underwater lighting (843) for the seabed exploration lens glass, the reinforcing steel plate bracket (165) operation of the pipe connection portion after the construction proceeds, but the marine sphere of the present invention The vertical pipe block in the center of the water is assembled in the form of a vertical tank with a diameter of Ø12m, and is formed by a core drill 917 attached to a drilling machine 908 for oil drilling to carry out oil drilling to the center of the vertical tank. It is a pipe that moves the excavated soil of the strata and the harmful gas of the strata caused by the operation of the Chubong bar. It is formed of a steel plate bracket 165 and the steel beam 149 to support.

On the other hand, it leads to the subsea submersible elevator 632 of the transportation device and the air piping line 181 of HBV system around the inner pipe, and the bulkhead manhole (diameter 998Øcm, 610) and the hatch cover (horizontal × Vertical; 800 × 2000, 153) and outside of the vertical tank, a staircase 631 for emergency staircases with a skeletal vertical

5-4] will be described as follows for a detailed description so that the block pipe connection can be submerged to the bottom of the sea surface, the band jig 621 is the pier installation of the submarine floor bridge bridge and the bottom floor floor It is used as a pier framework to enable cement concrete work of bridge bridges (not shown) to allow construction of submarine tunnels that connect the five oceanic poles without digging the bottom of the seabed to the top. Pipeline connection is provided by reciprocating double-circuit to supply production power of turbine generator 800, a tidal power generator in the sea, to Francis land (not shown) and pelton water wheel (not shown) of a large hydro generator (not shown). Collecting crude oil and natural gas produced by sea bed excavation or manganese nodules 909 loaded on the seabed, and collecting manganese nodules 909 As a means of transportation, this equipment and device includes a versatile and versatile system that forms an emergency tunnel line that can be bypassed in the event of a tunnel line failure in a zigzag symmetry. It is a device of a no-hazard global marine nuclear power plant which is characterized by changing the course of the typhoon to the sea and making it possible to prevent fire.

As shown in the drawing, the connection joint of the block pipe 598 unit is connected to the sea level by lever block 123 and turnbuckle 640, and the pyramid type external support tank is a block pipe. And, the block block unit of the block piping unit installed outside the holding tank is inserted into the bracket (165) processing hole of the plate for the separation of the port block, the lever block hook is operated left and right by the lever block handle while both block piping is joined. . At this time, the part under the water is very difficult to proceed the progress of the problem to solve the problem is solved by the semi-submersible work line 637 for the sea work.

As shown in the drawing, the electrolyzed water is identified as indicated in the brackets and the seawater welding work site at the bottom of the sea level is separated from the tank frame in the double pipe structure and the submerged cutting at the block connection area so that seawater cannot penetrate. And band jig bands on both sides with rubber packing (32) on the sealed parts in a rectangular work place after installation with band jig band 621, which is a tool for safety equipment for underwater welding, and guide rail 618 for transporting equipment. (621) attached to the top of the guide rail (618) attached to the semi-submersible work line 637, block pipe connection Hydraulic cylinder jock 623 for underwater work, the band jig stand 621 is in close contact with each other and joined do.

The band jig stand 621 joined to the semi-submersible work line 637, as in the form of a tank, a manhole is formed in the upper end of the tank and is formed by a hydraulic hatch cover 153 or an electrolytic water discharge pipe and an air piping line, and then the bottom of the tank. In order to pump water trapped inside the tank, a small or emergency engine 226, a high performance wing pump 327, and a drain valve installed inside the jig are opened to drain the trapped water and the infiltrated water while the block piping is carried out. The welding work and the flange joint bolt nut work are safe work.

After the completion of the work, the worker of the semi-submersible work ship 637 confirms the completion of work, and after completing the welding inspection and the flange joining work inspection of the work site, closes the hydraulic cylinder jockey 623 and then boards the worker inside the cabin to close the hydraulic cylinder jockey. After diving off, dive, move to the location and arrive at the stop. Finished the description of the block pipe connection method of the double pipe structure of the present invention as described above, the upper and lower barge hull coupling separation method of the aquaculture dock as follows,

In the normal barge hull separation method

The barge hull is manufactured according to the pyramid-type double pipe structure connection method as described above because it is to be connected at sea level and follows the shipbuilding construction method in the shipbuilding and heavy industry. However, since the part to be seated on the sea floor is to be a steel structure that withstands water pressure, it is selected according to the thickness tensile strength of steel sheet, and is selected as a suitable and reasonable high-strength material. ) Are attached to the bottom and left and right of the barge hull,

The disaster prevention ship is connected to the rope bollard 638 for rope fixing of the ship mooring device in the upper part of the disaster prevention ship tangled ropes of the present invention is produced according to the conditions of the sea dried and barge hull corner portion is produced in the shape of an egg-shaped curve do. As shown in Fig. 5, the connection of the control line and the control line connecting portion is formed by the flange connection of the double pipe structure and is assembled and connected to the double pipe structure block pipe by the connecting node of 100 meters. The lower deck barge hull upper deck deck or holding tank and auxiliary support tank upper deck deck bottom four corners are composed of flange joints or lug pin shafts.

Large marine nuclear power plant floating farm (515) is capable of smoothly and smoothly transporting the capacity of cranes with capacity as many as shipbuilding and heavy industries, and can transfer sea resources of 400,000 tons or millions of tons from the sea to hundreds of kilometers above the sea level. It is applied to the installation work with bridges and piers that connect the five oceans over the sea level horizon while submerging to the bottom of the seabed below 10,000 meters, and the foundation of concrete civil works, which is put into the foundation work of the piers to the bottom of the seabed, is established. Submerged barge control submarine dock for marine disaster prevention and marine environment industry development, which is selected as a method and means for subsea tunnel construction for Gas is burned by burner boom 920 for removing harmful gas Nuclear facilities and peaceful in the disaster-free world marine nuclear power plant, characterized in that arranged distributed along the longitude and latitude of the world and then prepared for the global nuclear power construction is formed on the support sikdok.

The aquaculture dock is not limited to the function of a crude oil drilling ship and does not set the principle that it should be like a crude oil drilling ship. The aquaculture dock according to the present invention gathers a plurality of block pipings of one object and processes them strictly and orderly in the sea level. By installing according to the order, the aquaculture dock is completed and after the operation of the crude oil borehole, the mixer 73 inside the machine room of the loess and cement mixing equipment for filling the borehole is configured and operated. This is an essential condition of maritime safety and is a marine structure that includes a multi-functional multifunctional structure to solve the politics of stagnation and the crisis of the global economy or unemployment. The location where the mixer 73 is installed is the MUD FEED ROOM. ), Or Mad Feed Selisectorum (Dough).

The above-mentioned offshore structure is a block unit, and the parts are combined at the sea level with the barge hull at the top and bottom, the holding tank of the double pipe structure and the auxiliary support tank of the pyramid type, and the marine nuclear power plant body (1) sinks to the bottom of the sea level, followed by the double pipe. Structural (including vertical column tank) The block piping is merged into the left and right end subculture dock centers, and then semi-submersible working line 637 for sea work of sea level (SLL) is combined by bolting and welding work underwater.

As described above, the large marine nuclear power plant floating farm (595) is buoyancy generated and generated by the weight of the hull and sea level gravity, the large marine nuclear power plant floating farm (595) slowly rises to the sea and magnifies the barge. This description is the same as the rising sun. Again, the high-pressure vertical multistage pump 8 and the doctor vent fan 195 are operated to open the manhole 610 and the hatch cover 153 and submerge in the seabed. The valve disc inside the butterfly valve 622 is opened and then floated to the sea.

In this way, depending on the depth of the seabed, depending on the type of flotation poison, if one piece of equipment floats up to the sea, another piece of equipment sinks to the seabed and works similarly to the precipitation of the precipitation, thus preventing harmful tidal conditions. The discharge sprayed water 38 and the curtain water film 39 are provided in the firefighter nozzle 10 hanging in the bottom of the plurality of small balloons and 77 and the airship 78 at the level of the tube in advance. By controlling the air flow in advance by moving the pipe level through the agatematton that checks the flow of the updraft and the downdraft and the flow rate of the phyto pipe and the animomatone flowmeter, which form a mountain range while discharging, Disappeared somewhere, the global village continues to be permanent, and joins the international social order to carry out war-teratomic nuclear or missile tests in line with global human-made disasters. The ability to ever resolve the territorial waters dispute or disputes are added.

Hereinafter, a nuclear waste treatment method and a reactor facility according to a preferred embodiment of the present invention will be described in more detail.

As shown in FIGS. 1 to 5, the nuclear waste treatment method and the nuclear reactor facility using the nuclear explosion prevention of the conventional dual-structure block tank have a large amount of radiation generated inside the reactor 811 of the nuclear reactor facility, resulting in a nuclear reactor 811. ) Is a double pipe structure for storing nuclear waste, which is a radiation connecting the reactor 811 of nuclear power generation, which consists of five layers of protective walls safely, and the circumferential surface of the reactor pressure vessel 813, the third wall of the reactor 811. It is used in nuclear reactor equipment using nuclear power generation of the nuclear power plant body 1 including the block tank 598.

The nuclear power generation generates a nuclear fission in the reactor (811) to produce steam from the steam to rotate the steam turbine (267) to produce power, and the power generated from the steam turbine (267) The rotor coil 774 which is a rotating electromagnet installed along the circumferential surface of the shaft 198, which is a rotating shaft connecting the generator 772 and the steam turbine 267 to the generator 772, and the rotor coil ( 774, an armature coil 773 for a generator which is a non-rotating coil installed along a circumferential surface and a frame 775 integrally fixing the generator 772 and the shaft 198 to the steam turbine 267. A power generation unit including; Cooling water (287) piping line 352 having a connection structure with the condenser 790 in the lower portion of the steam turbine (267) body of the power generation unit, the conduit line (169) and the coolant ( 287. A circulating water pump 858 is connected to the pipe line 352. A water supply pump 857 is formed at the rear of the condenser 790 and outside of the reactor 811, and is located in front of the water supply pump 857. A plurality of coolant pumps 859 are formed outside the reactor pressure vessel 813 body in which the uranium 812 fuel is stored. Is installed.

The safety device control rod 798 is installed inside the reactor pressure vessel 813. When shaking occurs, the control rod 798 is automatically inserted a lot at a time, and the reactor stops emergencyly.

The connection structure is formed by the steam generator 810 and the steam dryers 786 installed outside the pressure vessel 813 body of the reactor, and includes a containment vessel 808 corresponding to the fourth wall of the reactor 811. Block pipe line 74 having a double pipe structure is formed in the plurality of through holes after the plurality of through holes are processed by an oxygen cutting machine and a construction machine at a predetermined 45 ° angle in the upper part of the reactor building 688 corresponding to the fifth wall. A plurality of safety valves 472 are flanged to the block piping line 74 with bolts 24 and nuts 25 with gaskets 32 and along the outer wall of the reactor building 688. Nuclear waste treatment storage block tank 599 and radiation type connection structure are formed in eight double-pipe block tanks 598 having a diameter of twice the size of the building 688. ) And the cover pipe 682 protecting the second rod 689. When the inside of the reactor pressure vessel 813, which is the third wall, explodes due to an earthquake of 5 or more intensity, a plurality of safety valves 472 are opened, and the nuclear wastes exploded through the block piping line 74 at each location pass through the block tank ( 598) Nuclear waste is stored in each location, and when dismantling a reactor such as a nuclear power plant that has reached the end of its life, using a remote control cutting or a robot 700, and when the explosion inside the reactor pressure vessel 813 stops, a plurality of safety valves ( 472) are closed and the safety valves 472 are always closed when the reactor is in operation, and nuclear reactors can be installed at sea level 40m above sea level so that various reactors can be installed on the barge 591 of the sea and not restricted by weather conditions. Adjust the position so that the nuclear reactor (811) of the nuclear power plant of the nuclear power plant cannot be exploded without being affected by an earthquake or tsunami and dispose of the nuclear power. The double-block block tank reactor facility, in which the reactor in the nuclear fuel chamber does not explode so that the environment is not contaminated by the nuclear power plant, is installed in the nuclear power plant. It is characterized by ensuring that.

In the waste generated from the nuclear power plant and a method of treating the same, an active membrane type that weakens radioactivity when the pressurized water reactor 811 is used when the air inside the building and the air contained in the water inside the reactor 811 is a gas. The gas hold-up device 213 discharges the purge air to the outside air or the power plant building ventilation is configured to discharge all of the vented air or the vented air to the plurality of symmetric filters 214 or the vented air.

When the regeneration solution of the ion exchange resin is liquid in the water leaked from the valve of the nuclear power plant and the general purpose water in the building, the wash water is collected in the storage tank 216, filtered by the filter 217, and then the radioactivity meter 218. The radioactivity level is measured to confirm that there is no harm, and then flows to the sea with cooling sea water. After the water other than the wash water is purified by the filter 217, the filtered water and distilled water are reused as the reactor coolant, and a monitoring post 219 for monitoring is formed.

In the case of the hybrid species inside the building of the nuclear power plant, such as cloth, work clothes, shoes, etc., the ion exchange resin and the filter medium are solid, the filter sludge and the used resin liquid are stored in the storage tank 216 and solidified with a concrete drum ( 220) and the paper and cloth are compressed to reduce the volume and attenuate, so that all of them are hardened with concrete, filled in the drum (220), and the waste is stored to move the waste by a forklift inside the site and store it. Surveillance monitoring post 219 is further formed

The nuclear fuel used in the nuclear power plant and the natural uranium 812 are processed in the reprocessing plant 228 and then processed into uranium fluoride 812 in the conversion plant 229 to move the nuclear fuel to the enrichment plant 230. The uranium fluoride 812 is converted to uranium dioxide in the conversion plant 229 and processed into pellets 683 to produce fuel rods, and the plutonium 801 processed in the reprocessing plant is converted to a processing plant 231. Fuel rods 689 are made in these reprocessing fuel rods 689 so that the fuel is moved back to the nuclear power plant 672 and converted to the nuclear power plant 672 and the reprocessing plant 228 with the enrichment plant 230. Conversion and processing plants 231 are formed on the upper surface of the sinking barge deck deck of 40 meters above sea level.

High-level wastes, which are wastes from reprocessing in nuclear power plants (672), have long half-lives and need to be stored for thousands of years, so that nuclear wastes are buried in polar glaciers, deeply buried in layers or ocean floors, The nuclear fission in the reactor (811) to convert to other materials, such as sending to space, etc. At this time, the permanent disposal method of high-level waste, construction machinery heavy equipment aviation, excavators and ships and double pipe structure drum barrel 220 612 and space rocket launchers 646 are additionally formed on the barge deck deck 591.

In case of failure in the reactor 811 of the nuclear power plant 672, the maintenance and repair work period is more than three months. A thermal power plant is additionally formed to enable emergency power generation by supplying steam of high temperature and high pressure by operating the 783).

The block tank 598 of the double pipe structure, which is a nuclear waste storage tank of the nuclear power plant 672, includes an inner block tank 596 and an outer block tank 599, which firmly support the block tank 598 of the double pipe structure. The inner block circumferential surface of the inner block tank (596) and the inner wall circumferential surface of the outer block tank (599) are made of steel plate brackets (165) on the isotropic steel (221), the thylongji steel bar (600) and the oring steel bar (601). Assembled by the assembly process such as underwater cutting and welding of the computer, the hydraulic cylinder door 624 is provided on the wall of each of the inner block tank (596) and outer block tank (599) so that the forklift can enter and exit the manhole and the manhole cover. Is further formed

The waste from the nuclear power plant and its disposal method will be described as follows.

Hereinafter, the nuclear reactor nuclear power plant safety operation according to a preferred embodiment of the present invention will be described in more detail.

First, as shown in FIG. 2, how can the conventional reactor structure overcome the advantages of the structural defects of the reactor from natural disasters such as heavy winds and earthquakes. This will be described while identifying the countermeasures and the causes of the explosion of the nuclear reactor 811.

As shown in FIG. 1k, the reactor 811 structure is formed of five layers of protective walls, and a single reactor is formed. The reactor is a pellet, which is a reactor first wall in which the uranium 812 fuel is stored inside the pressure vessel 813 body. 683) and the cover pipe 682 protecting the fuel rod 689, which is the second wall, and the cover rod 798 and the cover pipe 682 protecting the fuel rod 689 due to excessive shaking due to the high earthquake, respectively. In the aftermath of the continuous impact, the nuclear fuel converts into explosives, leading to an explosion of the reactor 811 formed of five layers of protective walls.

Here, the following measures can be established to prevent the reactor explosion.

Firstly, various reactors in the past have no dust collector (794) and exhaust gas inlet / outlet of exhaust gas facilities like thermal power plants. Second, nuclear reactors such as nuclear explosions are used in facilities such as nuclear submarines or nuclear aircraft carriers. It is possible to carry out the safe operation continuously without any at all, and the third is that the previous reactors are reactors that cannot cope with the high temperature and high pressure expansion gas inside the reactor and the expansion liquid. It is a significant difference from the previous nuclear reactor equipment in that the reactor equipment which can endure from the present invention is made.

On the other hand, as described above, since nuclear reactors often have nuclear explosions in nuclear power plant facilities, they have serious consequences in that the operation of nuclear power plants is suspended due to the rejection of environmental groups. The structural defects of the reactor can be solved as follows.

The previous reactor 811 structure has a serious danger level in that five layers of protective walls are formed in a hermetic structure and have an explosive shape.

For this reason, block tanks 598 for nuclear waste treatment storage are installed in eight block tanks 598 having a double pipe structure serving as a dust collector 794 equivalent to a thermal power plant. The dust collector 794 is installed inside the body of the boiler 783 in a thermal power plant, while in the nuclear power plant, the block tanks 598 for nuclear waste treatment storage, which are explosives outside the body of the reactor 811, have a double pipe structure. A plurality of safety valves 472 control the inner nuclear waste treatment and nuclear reactor explosion prevention, etc., in the middle of the block piping line 74 while forming the line 74.

In particular, since the inner tank of the double-pipe block tank 598 has a cylindrical dust collector 794 structure, the steel beam 149 or the plate bracket 165 are not installed, and the outer wall and the outer block of the inner block tank 596 are not provided. The inner wall of the tank 599 is installed by welding steel plates, such as an O-ring steel bar 601 and a vertical partition 605, to a horizontal bar 609 on the inner wall of the tee long ground steel bar 600, and a partition manhole 610 to each reinforcing steel plate. Each back is processed. The inner wall of the inner block tank 596 and the inner wall of the outer block tank 599 are filled with cooling water 287 to withstand expansion gases at high temperature and high pressure gas and expanded liquid during explosion in the reactor, and are capable of withstanding hundreds of thousands of tons. It is a nuclear reactor facility of the present invention that can cope with explosions as a solid block tank even without deep sea pressure.

Meanwhile, the control rod 798 into the pressure vessel 813 in which the uranium 812 fuel is stored inside the reactor pressure vessel 813 body, which is the third protective wall of the reactor 811 before and after the earthquake, for the perfect nuclear reactor safety operation. And fuel assembly 671 such as cladding tube 682 protecting the fuel rod 689 and the feed chamber 682, which is a kneading chamber in which the ocher mixing equipment mixer 73 is installed so as to prevent severe friction and to alleviate the impact continuously. Reactor explosion can be prevented by establishing a separate supply line to supply the appropriate level of loess mixture.

On the other hand, the block pipe line 74 of the double pipe structure connecting the double pipe structure tank 598 and the various reactors 811 is selected as a high-tensile steel plate (597) material and installed in the intermediate connection portion of the block pipe line 74 The plurality of safety valves 472 can be selected from various types of valves, but are mainly used when the pressure of the liquid rises, and when the pressure of the liquid reaches a predetermined value, it automatically responds to the increase of the pressure. Relief type safety valve 474 and steam pope type safety valve 475 with opening function are mainly installed in piping system and can be used for both gas and liquid depending on the purpose. Choose.

Further, preferably, the conventional reactor facility structure is incapable of responsive to reactor explosions before and after the earthquake in a stateless defenseless state, whereas the reactor facility structure of the present invention is the primary fuel assembly 671 due to severe friction. Even though an explosion occurs, a plurality of safety valves 472 installed in the middle and middle of the block piping line 74 through the block piping line 74 of eight double pipe structures formed on the lid of the pressure vessel 813 at the upper end of the pressure vessel 813, the third wall of the reactor. Nuclear waste, which is an explosive, is moved into the double pipe block tank 598 and stored in the inner block tank 596 of the double pipe block tank 598.

In addition, eight double-pipe block piping lines 74 and safety valves 472 installed in the middle of the five-layer reactor 811 body and the middle of the double-pipe block tank 598 are installed in a hot reactor after the reactor explosion. Cooling water 287 stored in the space of the inner wall of the inner block tank (596) and the outer wall of the outer block tank (599) in order to cool the plurality of safety valves 472 formed in the block piping line 74 is opened eight blocks Cooling water (287) stored in the tank is continuously supplied inside the heated reactor, but by spraying a large amount of ocher mixture at the same time in preparation for the fire immediately after the reactor explosion accident, to minimize the damage caused by radioactive contamination and to reduce the temperature and pressure changes inside the reactor Thermometers and pressure gauges are installed on each of the protective walls so that they can be connected to the computer network to automatically detect the safety status of the reactor.

Meanwhile, the coolant 287 stored in the space of the inner wall of the inner block tank 596 and the inner wall of the outer block tank 599 of the eight double pipe block tanks 598 has a connection structure with the condenser 790 separately from the nuclear power plant. The coolant 287 pipe line 352 is provided with a purification device 809 and a plurality of coolant pumps 859 in the feed water pump 857 and the circulating water pump 858, and the upper end of the upper end of the outer block tank 599. A water tank 295 is further provided so that the coolant 287 is always filled in eight block tanks so that the coolant 287 is always circulated in each block tank when the reactor is operated.

In addition, it is possible to supply a mixture of ocher 158 equivalent to the toothpaste level to the reactor pressure vessel 813, which is the third wall, so that the safety device control rod 798 inside the pressure vessel 813 is inserted into the nuclear fuel at the time of the earthquake and at the same time. As such, the ocher 158 mixture is filled into the pressure vessel 813 and the reactor wall 808, which is the fourth wall, is filled with the ocher 158 mixture of paint level inside the containment 808, but the fifth wall is In the reactor building 688, a large amount of coolant 287 stored in the block tank is filled, so that the control rod 798 is provided in the cover pipe 682 protecting the pellet 683 as the first wall and the fuel rod 689 as the second wall. Ocher mixtures are filled in the space gaps of the back to mitigate severe friction and impact, thereby preventing various reactor 811 explosions in advance.

Thus, the loess 158 mixture of the toothpaste level, which is injected into the pressure vessel 813 at the same level as the blast furnace immediately before the large-scale explosion accident of the reactor 811, is suitable for the ocher mixture. Mixing and putting at the same time inside the pressure vessel 813, several firefighter nozzles 10 are attached to the inside and outside of the pressure vessel 813 body so that the inside of the reactor can be easily cleaned even after the earthquake occurs. The pump (8) and the vacuum pump (635) can be used to clean the reactor without input, but pay special attention so that the mixture of the loess 158 does not become solid and clean the inside of the reactor immediately after the earthquake stops. This enables continuous development without being constrained by natural disasters and maximizes the safe operation of the reactor facility.

As such, preferably, in the nuclear reactor facility of the present invention according to nuclear power reactor safety operation, alternatively, the present invention will be described in more detail as follows.

First, as described above, unlike the barge hull (591) deck deck upper end of the reactor facility holding tank using a conventional nuclear explosion prevention, the five-layered protective wall inside the body of the barge hull (591) nuclear reactors of nuclear power generation Both the 811 and the double block structure block tank 598, the inner block tank 599 for the nuclear waste treatment storage can be installed into the barge hull 591 body.

At this time, all eight block tanks 598 of the double pipe structure are collected into the barge hull 591 body and formed into block tanks 598 of one double pipe structure, and are installed on the circumferential surface of the reactor 811. Block pipe line 74 and safety valves 472 of double pipe structure can be assembled and disassembled, and guide rails 618 are installed on the deck deck to the left and right of the deck deck. A ton-capacity crane or crane 861 is formed on the guide rail 618, and the five-ply reactor 811 inside the barge hull 591 is moved and the crane or crane 861 is well equipped for installation and renovation. I use it.

On the other hand, at the place where the crane or the crane 861 passes, a double or triple sliding hetch cover 153 of a double pipe structure is installed in a double or triple, the cooling water (287) inside the large sliding hatch cover 153 body of a double pipe structure And ocher 158 to store a large amount of radiation leakage during the operation of the reactor 811.

In addition, the barge of the double pipe structure can be canceled for the reason why it is possible to cancel the installation of the reactor building 688, which is the fifth protective wall made of concrete, among the various reactors 811 installed inside the deck deck body. This is because the hull 591 itself corresponds to the fifth protective wall.

In addition, the barge hull (591) deck deck upper surface of the power generation unit of the nuclear power generation unit, the active membrane-type gas hold-up device 213 in the exhaust tower 215, the storage tank 216 and the filter 217, the radioactivity detector 218 ), A monitoring post 219, and a small machine that can reduce the noise generated during the reactor explosion are formed in the exhaust tower 215 of the rear end of one double pipe block tank 598, the inner block tank 599, and

In addition, since the barge hull 591 body itself is a nuclear power plant 672 in preparation for the time before and after the explosion of the reactor 811, the upper part of the pylon or block pylon 116 installed above the barge hull 591 deck deck. Lightning rods (not shown) are installed for the safety of nuclear power plants (672) from lightning and thunderstorms, and include nuclear power plants (672) such as rivers in coastal areas of the global village and coastal seaside areas. By making it possible to safely install the reactor 811 facility, nuclear reactor explosion prevention and nuclear waste disposal methods are achieved at once.

In other words, the body of a firefighter who participated in a nuclear firefighting had lost his hair and burned his body 10 days after the explosion, and in February 1987 a four-footed eagle was found in Charlesburg, Austria. In August of the same year, a two-headed pig was born on a farm in northern Hungary, and, like this, a nuclear explosion could have devastating consequences.

In addition, as shown in Figure 4, showing the movement of nuclear fuel and the reactor 811 renovation work, first, the uranium ore collected in the uranium mine 222 is smelted in the smelting plant yellow cake (223) Becomes The yellow cake 223 is made of uranium hexafluoride in the conversion plant 229 and sent to the enrichment plant. Since the nuclear fuel movement is formed around the nuclear power plant (672), the radioactive waste (799) and the spent fuel are sorted by the remaining uranium and radioactive waste (799) from the reprocessing plant (228), but in Korea, the reprocessing plant Since there is no (228), the problem can be solved by the barge hull (591) deck deck, which is an offshore nuclear power plant (672) on the high seas, as well as the reprocessing plant (228) and the conversion processing plant (231). It may be formed by collecting the smelting plant 233.

In addition, when repairing the reactor 811, careful attention of the operator is required to prevent radioactive contamination.

As described above, the present invention provides a nuclear waste treatment method and a nuclear reactor facility using nuclear explosion prevention of a dual-structure block tank.

Although the technical spirit of the present invention has been described in detail according to a preferred embodiment, it should be noted that the above-described embodiment is for the purpose of description and not of limitation. In addition, it will be understood that various embodiments are possible within the technical scope of the present invention.

"자 "

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" 형태의 지그) (23) 샤클, (24) 볼트, (25) 너트, (26) 와샤, (27) 힌지(정첩), (28) 플랜지 또는 플랜지마개철망, (29) 카플링, (30) 카플링 암나사산 몸체, (31) 카플링 수나사산 몸체,
(32) 가스켓트 또는 고무패킹, (33) 노즐호스 장비거치대, 분사노즐 상단부(A) 분사노즐 몸체(B) 분사노즐 하단부(C) (34) 집수정탱크 (35) 레듀사, (36) 고성능 수중펌프 (37) 펌프수차 (38) 토출분사수 (39) 물막 또는 커텐물막, (40) 소방정, (41) 감지노끈, (42) 바스켓, (43) 이중비닐텐트 또는 봉지, (44) 엘보 또는 티이엘보, (45) 연돌(굴뚝)
도로지표면 상단부(GLU), 도로지표면(GLL), 도로지표면 하단부(GLD), (46) 동력 전원 공급장치인 전원, (47) 인버터, (48) 인버터브이오(VO;vidicon off) (49) 억세스 포인터(AP; Access Point), (50) 인터넷 망, (51) (입형다단펌프) 또는 관제서버 (52) 모니터 (53) 펌프 제어보드 또는 타구어윈치 콘트롤 박스, (54) 근거리 무선통신 안테나 (55) 근거리 무선통신장치의 무선통신제어모듈, (56) 디스플레이(LCD;liquid crystal display) (57) 전자제어장치인 에이디이씨(ADC;advanced developing countrie) (58) 스위치 입력회로, (59) 전자제어장치인 엠씨유(MCU;moduler concept. unit) (60) 전자제어장치인 디이에이씨(DAC;Development Assistance Committee)
(61) 브레이크(과전류차단기), (62) 전원부, (63) 디스플레이 화면, (64) 아날로그입력, (65) 디지털 입력, (66) 각 펌프의 온오프제어를 위한 스위치인 메인 스위치버턴, (67) 보조스위치버턴 (68) 입형다단펌프 디스플레이(LCD) 입력(콤퓨터 전산망 입력), (69) 현재 압력값 또는 설정 압력값(압력설정수치) 인식명판, (70) 메모리, (71) 전선, (73) 방재물질 혼합기 믹서, (74) 블록배관라인 (75) 헝겊꺼즈, (76) 솔레노이드밸브 (77) 애드벌룬, (78) 비행선, (79) 가스통, (80) 에어콤프레샤 (81) 모바일 서비스(SMS;short messge servise) (82) 휴대용 단말기(PDA;perseNAL digital assistant)
(83) 저압차단 밸브, (84) 비상 밸브, (85) 감압 밸브
(86) 제1압력체크센서, (87) 제2압력체크센서
(88) 전자제어유닛, (89) 양수관(89a) 또는 수직 하향관(89b) (90) 볼밸브 핸들
(91) 드렌처헤드, (92) 밸브 몸체 내부 디스크
(93) 비상싸이렌
(94) 최초발화원인물질인 스파크 또는 낙뢰, (95) 전신주, (96) 변압기
(97) 레듀사 붓싱소켓,
(99) 점멸경고등, (100) 파라핀노즐마개(양초), (101) 압력계
(102) 감지센서 바이메탈, (103) 열전대온도계 스위치(감지센서)
(104) 레벨 또는 압력스위치, (105) 방유량체크용 유량계
(106) 동력모터제어모듈, (107) 밸브스위치작동용 추 또는 크레인 붐대 레벨유지 웨이트, 추
(108) 과대압력 방지스위치 또는 스위치박스, (109) 에어호스, (110) 닛플(에어호스 연결장치)
(111), 스프링쿨러헤드, (112), 반사관, (113) 가용금속(퓨우즈), (114) 정지밸브 또는 수도밸브, (115) 지하매설관, (116) 철탑 또는 블록철탑 (117) 부자, (118) 부자회로개폐기 (119) 벨, (120) 경보밸브, (121) 시험밸브, (122) 고압수도펌프, 밸브몸체중심선(VBCL or PBCL), 방화수수면하단(WLD), 방화수수면(WLL), 분출수면(WLU), (123) 레버블럭, (124) 소화기(소화기a, 소화기b, 소화기c, 소화기D, 소화기e, 소화기f) (125) 체인 (126) 시린더 또는 실린더, (127) 피스톤 또는 피스톤펌프, (128) 소화기 고정용 핀 (129) 빗장 장금장치, (130) 인명구조용 에어튜우브 (131) 로프, (132) 컨테이너, (133) 앙카볼트, (134) 라디오존데, (135) 구동바퀴 로라(도루레), (136) 레귤레이트, (137) 에어 타구어윈치 또는 타구어윈치, (138) 에어시린더 (139) 철개망태, (140) 터어빈펌프, (141) 케이싱, (142) 베인펌프 또는 가이드베인
(143) 임펠러, (144) 다이어후렘펌프, (145) 에어리시버탱크 또는 고압저장탱크, (146) 프로펠러펌프 또는 프로펠러 (147) 스큐르 또는 스큐르압축기 그리고 스큐르펌프 (148) 플런저펌프, (149) 철재빔, (150) 방재펌프 제어시스템 또는 관제시스템, (151) 오일쿨러, (152) 맨홀뚜껑, (153) 해치카버, (154) 방화문 (155) 글랜드패킹, (156) 매커니커 시일 또는 각개의 시일 (157) 제트펌프, (158) 황토 (159) 방화사 (160) 옥내소화전상자 (161) 오토소화전 (162) 호스걸이 (163) 헬륨가스(냉각재로 구분함) (164) 불연성가스(이산화탄소) (165) 철판 브라켓 (166) 발화물체(화재유형별의 A급, B급과 C급으로 분류함) (167) 나사탭 (168) 송수구 또는 소방방재 배관라인, (169) 방수로로 배관라인, (170) 인터쿨러(intercooler) (171) 배기가스 (172) 인명구조겸용 침대 노즐, (173) 토오치 또는 버너 (174) 탄산가스, (175) 하론가스, (176) 헬륨,
(177) 발화물질 파라핀테이프, (178) 비발화물질 철사, (178) 소화전(단구형a, 쌍구형b) (180) 비닐포대, (181) 공기배관라인, (182) 아프터쿨러 (183) 리밋스위치 또는 리미트스위치 (184) 무인카메라(씨씨티비), (185) 지그대 쇄기(끝이 뾰족한 틈새결합공구) (186) 스프링, (187) 무인점화기 스파크라이터 (188) 구명정 (189) 헤드탱크(압력탱크) (190) 플렉시블고압호스 또는 유압호스, (191) 도입관(수압관)
(192) 전동기 몸체(동력모터), (193) 후드, (194) 스냅링, (195) 팬, (196) 몸체프레임, (197) 몸체전방부라켓트, (198) 샤프트, (199) 회전자조립, (200) 전방베아링, (201) 고정자조립, (202) 주물프레임(모터보호용), (203) 단자박스, (204) 인양볼터, (205) 단자박스카버 (206) 후방베아링, (207) 후방부라켓트, (208) 공극, (209) 팬카바 또는 보호카바 (210) 회전자 철심, (211) 고정자 철심, (212) 고정자권선,
(213) 활성막식 가스홀드업장치
(214) 필터
(215) 배기탑
(216) 저장탱크
(217) 여과기
(218) 방사능 측정기
(219) 모니터링 포스트
(220) 드럼통
펌프몸체(PB), 펌프몸체수직라인(PBVL), 펌프몸체수평중심라인(PBCL)
(221) 등변산형강
(222) 우라늄 광산
(223) 옐로케이크
(224)
(225)
(226) 엔진(발전기) (277) 터어빈베아링, (228) 재처리공장, (229) 전환공장, (230) 농축공장, (231) 전환?가공공장, (232), 탐조등, (233) 제련공장 (234) 호칭별 노즐몸체 "호칭 100", (235) 호칭 "90", (236) 호칭 "75", (237) 호칭 "65", (238) 호칭 50, (239) 호칭 "40", (240) 호칭 "25", (241) 호칭 "100×90", (242) 호칭 "90×75" (243) 호칭 "75×65", (248) 크랭크, (249) 링크대, (250) 푸레, (251) 감속기, (252) 브이(V)밸트, (253) 플런저, (254) 고정핀 (255) 타임머, (256) 해양 케이블카아 (257) 공기밸브, (258) 안전밸브, (259) 오토 또는 오우토밸브 (260) 드레인밸브 (261) 밸트카바 (262) 흡입필터, (263) 압축기본체 (264) 펌프수차, (265) 메인밸브, (266) 산림, (267) 터빈, (268) 플라이휠, (269) 흡입구, (270) 토출구, (271) 공운전방지장치, (272) 펌프전원, (273) 제어전원, (274) 비상운전(Sequence)회로, (275) 디씨이파워공급(DC power supply)회로, (276) 마이크로콘트롤유니트(Micro control unit), (277) 디아이피(DIP)스위치설정회로, (278) 엘이이디이 디스플레이(LED display)회로, (279) M/C 구동신호 접점출력회로, (280) 모터 과부하 신호입력회로, (281) 인버터운전 데이트 입출력회로, (282) 압력감지회로, (283) 외부상태 입력회로, (284) 토출압력트랜스미터어(Transmitter), (285) 흡입/토출스위치 등의, (286) 베드프레임, (287) 냉각수 (288) 유분리탱크, (289) 흡입밸브, (290) 기어드라이븐,
(291) 에어드라이어, (292) 불씨, (293) 불꽃, (294) 불기둥,
(295) 수조탱크, (296) 게이트밸브, (297) 리턴밸브, (298) 부시 또는 트로틀부시 (299) 드렌처헤드(a,b,c,d)의 종류, (300) 진동경보장치, (301) 드레인, (302) 역정지밸브, (303) 고압보울탱크, (304) 회전펌프, (305) 버터플라이밸브, (306) 중탄산 소오다, (307) 재유입구, (308) 센튜리퓨우걸펌프, (309) 오수펌프, (310) 스파이럴 케이싱, (311) 블류우트펌프, (312) 후드밸브, (313) 양수구, (314) 펌프본체, (315) 플로우트, (316) 드러스트보울, (317) 플랙스블카프링, (318) 플로우트스위치, (319) 뒷날개, (320) 퍼올림밸브, (321) 빨아올림밸브, (322) 분출수면계, (323) 실제양정 (324) 분출양정, (325) 제트펌프, (326) 기어펌프 또는 기어, (327) 윙펌프, (330) 분리실, (331) 마그넷스위치 (332) 건물, (333) 빌딩 또는 대형건물, (334) 밸런스 (335) 언밸런스, (336) 옥내소화용펌프 (337) 로우터리펌프, (338) 로우터리회전자, (339) 프라이밍, (340) 자흡식펌프, (341) 축류펌프, (342) 혼류펌프, (343) 점성펌프
(344) 표준형 글랜드패킹, (345) 글랜드, (346) 주액랜턴링부착패킹, (347) 랜턴패킹, (348) 2중 글랜드형 패킹, (349) 드로틀부시부착패킹, (350) 냉각수출구, (351) 봉수, (352) 냉각수 입구, (353) 슬리이브내면 냉각병용 워터재킷부착패킹, (354) 슬리이브의 내부 냉각실, (355) 보조글랜드, (356) 누설액의 냉각실, (357) 글랜드 패킹짜는 방법, (358) 여덟가닥짜기, (359) 봉지짜기, (360) 격자짜기, (361) 플래싱구멍, (362) O링, (363) 스톱더, (364) 중동링, (365) 밀봉 단면, (366) 시이트링, (367) 피동링, (368) 퀀칭, (369) 쿠울링, (370) 되돌림관, (371) 핸들(Handle), (372) 격벽, (373) 축방향의 드러스트 하중, (374) 임펠러 전면에 작용하는 압력, (375) 임펠러 뒷면에 작용하는 압력, (376) 밸런스호울,
(377) 흡입압력, (378) 배면압력, (378) 밸런스구멍, (380) 전면웨어링, (381) 토출압력, (382) 배면베어링 링, (384) 뒷날개, (385) 뒷날개 설치로 인한 압력분포와 임펠러, (386) 다단펌프의 임펠러 배치, (387) 수주분리, (388) 수주결합, (389) 수격작용, (390) 축봉부, (391) 매커니컬시일의 냉각방식, (392) 스트레이너, (393) 수격펌프, (394) 옥상소방운전실 또는 크레인운전실, (395) 높고 낮은 산, (396) 폴저엔코드(Pulse Encoder), (397) 스피드콤멘드(Speed Command), (398) 모터스피드 그리고 변속기, (399) 디스크 브레이크(DISC Brakes), (400) 방파제 (401) 안전그물망(로프그물) (402) 에어(공기) 압축실(Air Chamber)
(403) 슬루우브 밸브, (404) 밸브 몸통, (405) 밸브 덮개, (406) 슬루우스 밸브, (407) 패킹누르게, (408) 패킹누르게 너트, (409) 밸브대, (410) 핸들, (411) 핸들너트, (412) 패킹, (413) 웨지 게이트 밸브, (414) 단체밸브, (415) 플렉시블 밸브, (416) 패럴렐 슬라이드 밸브, (417) 더블 디스크 게이트 밸브, (418) 스톱 밸브, (419) 플랜지형 글로우브 밸브, (420) 플랜지형 앵글 밸브, (421) 몸통, (422) 덮개(본네트), (423) 디스크, (424) 덮개붙임밸브 시이트, (425) 밸브대, (426) 밸브 누르개, (427) 핸들, (428) 덮개 끼움링, (429) 패킹누르개링, (430) 패킹 누르개, (431) 나사 끼움 형, (432) 덮개 보울트, (433) 패킹 누르개 보울트, (434) 핀, (435) 덮개 보울트용 너트, (436) 패킹 누르개 보울트용너트, (437) 핸들 너트, (438) 멈춤 나사, (439) 와셔, (440) 패킹, (441) 가스킷, (442) 밸브누르게(평면누르게(a), 원뿔누르게(b), 구면누르게(c), 스터트누르게(d)), (443) 콕(cock;1형 (444) 콕(2형), (445) 청동나사넣기 메인콕, (446) 주철플랜지형 글랜드형, (447) 청동나사넣기 글랜드콕, (448) 삼방콕, (449) 사방콕, (450) 핸들콕
(451) 첵 밸브, (452) 스윙형 첵 밸브, (453) 리프트형 첵 밸브, (454) 첵 밸브몸통, (455), 덮게, (456) 디스크, (457) 디스크핀, (458) 플러그, (459) 조정밸브, (460) 감압밸브, (461) 파이로트 작동식 감압밸브(자력식), (462) 2차측 감지구멍, (463) 다이어프램 (464) 파이로트밸브, (465), (466) 메인밸브, (467) 메인밸브스프링, (468) 조정스프링, (469) 오우토압력조절밸브, (470) 나사형 오우토압력조절밸브(a), (471) 플랜지형 압력조절밸브(b)
(472) 안전밸브, (473) 스프링식 안전밸브, (474) 리리이프식 안전밸브, (475) 증기용 포프 스프링식 안전밸브, (476) 포프식 안전밸브, (477) 온도조절밸브, (478) 오우토급수기(오우토수준조정기), (479) 오우토급수기(a), (480) 오우토수준 조정기, (481) 공기빼기밸브, (482) 오우토공기배기밸브 열동형(증기용), (483) 오우토공기배기밸브 바켓트형(온수형), (484) 냉매배관용 밸브, (485) 냉매스톱밸브, (486) 팩드밸브, (487) 팩레스밸브(벨로우즈형), (488) 팩레스 밸브(다이어프램형), (489) 팽창밸브, (490) 다이어후렘형 팽창밸브, (491) 벨로우스형 팽창밸브, (492) 부자밸브, (493) 냉매용 압력조정밸브, (494) 전자밸브, (495) 오우토급수밸브(미도시), (496) 일반형 수도꼭지(수전), (497) 지수선, (498) 분수전, (499) 보올탭, (500) 피뢰침, (501) 나사이음형 Y형 스트레이너 외형도(a) 단면도(b), (502) U형 스트레이너, (503) V형 스트레이너, (504) 관고정금속, (505) 터언버클부지지밴드, (506) 지지밴드, (507) 로울러부지지밴드, (508) 수직관 매몰용밴드, (509) 철재안경밴드, (510) 바닥밴드, (511) 트랩 (522) 앵글형 열동식 트랩, (523) 스트레이트 열동식 트랩, (524) 버키트 트랩, (525) 상향식 버키트 트랩, (526) 하향식 버키트 트랩, (527) 플로우트 트랩, (528) 임펄스 증기 트랩 (529) 수도꼭지몸통, (530) 패킹상자, (531) 패킹누르게, (532) 꼭지대, (533) 핸들, (534) 디스크, (535) 디스크패킹, (536) 내수패킹, (537) 내노화성물건패킹, (538) 고무막 또는 테프론막
(539) 열팽창이 큰 금속, (540) 열팽창이 작은 금속, (541) 타임머 또는 레벨스위치 (542) 하이레벨 알람(High Level Alarm), (543) 베이컴페일루어알람(Vacuum Fallure Alarm), (544) 스어멀 릴레이 알람(Thermal Relay Alarm), (545) 알람 리셋트 버턴(Alarm reset button), (546) 로워 레벨 스위치(Low Level Switch), (547) 플랩(flap;밸브의 혀), (548) 사운드캡(Sound Cap), (549) 첵노즐,
(550) 루우버카버, (551) 플로이트 인셔어트 스위치, (552) 지시눈금스케일, (553) 오우버플로워 콘넥션 (554) 벤트 파이프 콘넥션, (555) 플랜지 콘넥션, (556) 이중비닐 개방형 침(바늘), (557) 솔레노이드밸브 몸체, (558) 카버, (559) 스폴(Spool), (560) 스플패킹, (561) 파이로트(안내), (562) 코일, (563) 콘넥터, (564) 메니폴드(L;PTY 8" 대유량형), (565) 매니폴드(S;M5 소유량형), (566) 나사볼트, (567) 에어호스 결속구 유니온 카플링, (568) 유니온 카플링(몸체결속), (569) 2위치싱글(Single), (570) 2위치더블(Double), (571) LL; 중앙 수직형, (572) L; 수직형, (573) 수평형; M, (574) F; 피팅포함 (575) 도시기호 싱글(S;Single), (576) 더블(D; Double), (577) 에이취(H; Center Closed), (578) 아이(I; Center Pressure), (579) 제이(J; Center Exhaust), (580) 마이크로 스위치, (581) 직접 배관형, (582) 베이스 배관형, (583) 파이어 댐퍼(Fire Damper), (584) 댐퍼스핀들, (585) 닥터벤츄레이션(흡입구a, 배출구b), (586) 몽골피에의 열기구,
(587) 블량샤르의 열기구, (588) 켈리의 열기구, (589) 증기비행선, (590) 지주탱크(교각겸용), (591) 지주탱크 상단의 바지선 선체, (592) 지주탱크 하단의 바지선 선체, (593) 소형의 해양발전소 부양식독, (594) 중형의 해양발전소 부양식독, (595) 대형의 해양발전소 부양식독, (596) 내부 블록탱크(내부배관), (597) 고장력의 철판(High steel surface tension), (598) 블록배관, (599) 외부 블록탱크(지지기둥 또는 외부배관), (600) 티이롱지스틸바아 ("T"Lon'G steel bar), (601) 오링스틸바아 ("O"Ring steel bar), (602) 스카프웰딩홀 (Scarfe welding hole), (603) 러그 샤프트 결합용 볼트, (604) 러그샤프트결합분해 너트, (605) 수직격벽, (606) 포터블(portable)러그결합용 핀 샤프트, (607) 포터블러그용 플레이트
(608) 포터블러그용 핀,
(609) 수평격벽, (610) 격벽맨홀, (611) 인공위성
(612) 우주로켓, (613) 러그 힌지소켓
(614) 대형플랜지
(615) 대형플랜지 접속연결구 접합부위 가공, (616) 작키베드(

; 계류장치용) 홀 또는 플레이트 가공홀 그리고 러그 가공홀,
해수면 상단부(SLU) 해수면(SLL) 해수면 하단부(SLD)
기계실 외부(Out of Merchinery Room ; OMR)
기계실 (Merchinery Room ; MR)
기계실 내부(In of Merchinery Room ; IMR)
(616) 장공홀
(617) 이중관 구조 탱크 교각 건설용 부교식 새들형틀
(618) 가이드레일 ( Guide Rail ), (619) 헬리콥터 정류장 (

로 도시했음)
(620) 유압회전실린더(로터리 실린더[랙＆피니언형-NRP])
(621) 밴드지그대
(622) 벨러스터 버터 플라이 밸브
(623) 유압실린더 또는 유압 작키, (624) 유압실린더용 도어
(625) 마개철판
(626) 화력발전소
(627) 엔진제어모듈,(엔진제어시스템)
(628) 부이 깃대 고무풍선(629) 밧줄용 로프, (630) 로프매듭 갈고리 (631) 비상용의 계단 또는 스탭, (632) 승강기 또는 앨리베이트 (633) 콘베이어
(634) 선박침몰방지 공기 부양선, (635) 진공펌프, (636) 예인선(Air tug boat; 에어타구어 보트), (637) 반잠수작업선, (638) 볼라드 (639) 앙카 (640) 앙카용 체인, (641) 쿨링팬(Cooling Fan) (642) 공기보온용의 히터팬(Hit Fan), (643) 인공위성발사대 (644) 무어링타워(Mooring Tower), (645) 전기자석 마그넷, (646) 우주로켓발사대, (647) 헬리콥터, (648) 체인블럭, (649) 황토 또는 시멘트 혼합장비 믹서, (650) 애자, (651) 크레인 붐 또는 붐대, (652) 크레인 붐 걸고리
(653) 우라늄 239, (654) 물, (655) 직류(항상 같은 방향으로만 흐른다), (656) 교류(시소가 오르내릴 때마다 흐름의 방향이 바뀐다), (657) 중간 열교환기, (658) 열교환기, (659) 니크롬선(전류가 잘 흐르지 않는 선), (660) 전구 몸체, (661) 베이스, (662) 넵투늄, (663) 필라멘트, (664) 유리, (665) 형광 방전관, (666) 점등관, (667) 방전, (668) 탄소막대, (669) 양극(플러스; (+)로 표시함), (670) 음극(마이너스; (-)로 표시함), (671) 연료집합체, (672) 원자력 발전소, (673) 시이소 중심축 프레임(조력발전 설비장치 고정대), (674) 한류, (675) 난류, (676) 베링해협, (677) 추코트 반도, (678) 알래스카, (679) 우라늄 238, (680) 댐, (681) 노심 (682) 피복관, (683) 펠릿,
(684) 전압, (685) 전력, (686) 출구(전원), (687) 입구(전원), (688) 원자로 건물 (689) 연료봉 (690) 초고압 변전소, (691) 1차 변전소, (692) 송전소 내부 중심에 7가닥의 강철선, (693) 54가닥의 알루미늄선, (694) 연료호스, (695) 송전선 직경, (696) 오대양 육대주 횡단철도 변전소, (697) 중간 변전소, (698) 대단위 공장, (699) 중단위 공장, (700) 2차 변전소, (701) 소단위 공장, (702) 가정(태양열 주택이 포함됨), (703) 스탭 발판 걸고리, (704) 전선 균형용 케인크(초고압 전선 균형 애자),
(705) 관교량 터넬독 관 제조공정, (706) 소구경 전기 저항 용접관 및 SRM(3/8?8 inch O.D), (707) 원재료, (708) 언코일링, (709) 레벨링, (710) 사이드 트리밍, (711) 절단 및 대강연결, (712) 성형, (713) 용접 및 내외면 비드제거, (714) 초음파 및 와류탐상시험, (715) 용접부열처리, (716) 공냉, (717) 수냉, (718) 진원성형, (719) 절단, (720) 평평도 시험, (721) 구조관, (722) 교정, (723) 중간적재, (724) 유도가열로, (725) 에스알엠(SRM), (726) 열간절단, (727) 면취, (728) 수압시험, (729) 초음파 또는 와류탐상시험, (730) 무게 및 길이측정, (731) 육안 및 치수검사, (732) 나사, (733) 도유, (734) 일반 배관용, (735) 아연도금, (736) 아연도강관, (737) 보일러 튜브, (738) 냉각대,
(739) 중구경 케이지 성형 전기저항 용접관(8?24 inch O,D), (740) 코일마게철판(원재료), (741) 사이드 트라밍, (742) 케이지 성형, (743) 송유관, (744) 초음파 탐상시험, (745) 진원성형, (746) 송유관(석유산업용 강관), (747) 대구경 강관(22-82 inch O.D), (748) 엣지 밀링, (749) 3롤 밴딩, (750) 포스트 밴딩, (751) 가용접, (752) 내면 용접, (753) 백가후징, (754) 외면 용접, (755) 관단 싸이징, (756) 관단면취, (757) X-선시험, (758) 냉간 익스팬딩, (759) 마킹.포장. 출하, (760) 스파이랄 용접 강관(400A?2600A), (761) 언코일링, (762) 구조관 및 강관 말뚝, (763) 비도복 배관용, (764) 외면 브라스트 크리닝, (765), 내면 브라스트 크리닝, (766) 내면 도장, (767) 1차 도장, (768) 도장 및 도복, (769) 도복장 강관, (770) 초음파 및 X-선검사, (771) 전동차(터널독 내부 전동차)
(772) 화력 발전기(터어빈), (773) 화력발전기용 전기자코일(회전하지 않는 코일), (774) 화력발전기용 회전자 코일(회전하는 전자석), (775) 송전선, (776) 송전철탑, (777) 개폐시설, (778) 보일러, (779) 증기파이프, (780) 강력한 기체(고온?고압증기) 입구, (781) 중앙제어실(생산전력 제어실), (782) 트랜스포머룸(송전측정실), (783) 보일러, (784) 원자, (785) 전자, (786) 증기건조기 (787) 자석, (789) 탈기기, (790) 복수기(수증기를 냉각시켜 물이 되게 하는 장치, 쿨링기기), (791) 불(화력), (792) 드럼, (793) 재열기, (794) 집진기, (795) 중유탱크, (796) 중유, (797) 유조선 또는 화물선, (798) 제어봉 (799) 방사성 폐기물, (800) 플루오르화 우라늄 (801) 플루토늄, (802) 태양, (803) 햇빛, (804) 거울(반사경), (805) 반사경 반사각도 조절 프레임, (806) 모여진(집합) 햇빛, (807) 증기탑, (808) 격납용기, (809) 정화장치, (810) 증기발생기, (811) 원자로, (812) 농축우라늄(우라늄 235), (813) 원자로 압력용기, (814) 가압기, (815) 원자핵, (816) 냉각재, (817) 소음기, (818) 기수분리기, (819) 감속재, (820) 양성자, (821) 중성자
(822) 로드 앤드 피스톤 시일(ROD ＆ piston seal; UPI(a), UPH(b), (823) 피스톤 시일(OSIa, ODIb, OUIc, SPGd, SPGWe, GRf), (824) 부프 시일(Buffer seal; HBYa, HBTZb, Sealc), (825) 웨어링(Wear Ring; WRa, RYTb), (826) 스라이드링(Slide RING), (827) 디유 부시(DU Bush), (828) 오링(O-RING), (829) 로드 시일(ISIa, IDIb, IUHc), (830) 백업 시일(Back up seal; T₂/T₃(a), BRT₂/₃(b)), (831) 로드 시일 ＆ 백업 시일, (832) 다스트 시일(Dust seal; LBIa, DSIb, LPIYc, DWId, DKBIe, DKIf, DWIRg, LBHh, DKBi), (833) 핀 다스트 시일(pin dust seal; Vaya, DLIb,), (834) 다스트 위프 시일(Dust wiper seal), (835) 부프링(Buffer Ring), (836) 피스톤링, (837) 다스트링, (838) 물레방아
(839) 등변산 형강(앵글 및 부등변산 형강이 포함됨), (840) 기상관측장비 레이다, (841) 원유(기름), (842) 해저광물 뜰채 바스켓, (843) 심해저 탐색 수중조명 (844) 버킷 또는 빠레트, (845) 굴착기(스큐르 드릴; 심해저층 굴착장비) (846) 앙카 대체용 쇄기 크랭크, (847) 착암기 또는 네트, (848) 엑츄레이트, (849) 해저광물 뜰채용 공기주머니, (850) 턴박클, (851) 교각(기둥)용 레벨 기초용 밑받침대, (852) 쇄기 받침목(고정용), (853) 용접기(Arc 또는 Arj 아아크 또는 아르곤)
(854) 파이프 랙, (855) 재순환펌프 (856) 압력제어풀, (857) 급수펌프, (858) 순환수펌프, (859) 냉각재펌프, (860) 덤프트럭, (861) 크레인 또는 기중기, (862) 모터 그레이더, (863) 롤러, (864) 노상 안전기, (865) 콘크리트 배칭 플랜트, (866) 콘크리트 피니셔, (867) 콘크리트 스프레더, (868) 콘크리트 믹서트럭, (869) 콘크리트 펌프, (870) 아스팔트 믹싱 플랜트, (871) 아스팔트 피니셔, (872) 아스팔트 살포기, (873) 골재 살포기, (874) 쇄석기 (875) 공기압축기, (876) 천공기, (877) 항타 및 항발기, (878) 사리 채취기, (879) 준설선, (880) 별도의 건설기계, (882) 파일드라이버, (883) 디젤파일해머, (884) 증기해머, (885) 유압크레인, (886) 타워크레인, (887) 크롤러 크레인, (888) 트럭크레인, (889) 머캐덤롤러, (890) 탠덤롤러, (891) 탬핑롤러, (892) 타이어롤러, (893) 트랙터, (894) 트레일러, (895) 램, (896) 리드, (897) 냉각수 냉크, (898) 파일, (899) 헬밋, (900) 연료펌프, (901) 캠, (902) 연료탱크, (903) 기동장치, (904) 붐전핀 (905) 캐드워크, (906) 어댑터, (907) 어군탐지기(소나), (908) 원유시추용 드릴링머신(로터리테이블), (909) 망간단괴, (910) 뜰채그물, (911) 흡입 채집기계, (912) 해저광물 채취로봇, (913) 잠망경, (914) 고무풍선, (915) 와이어로프 체인, (916) 르메틱 운송장비, (917) 코아드릴, (918) 비이오피이 스키드(B.O.P.Skid), (919) 고무타이어, (920) 버너붐, (921) 유해적조 미생물, (922) 무공해의 천연가스, (923) 에어노즐, (924) 광물채집 뚜레박, (925) 상승기류, (926) 하강기류, (927) 황사 미세먼지, (928) 교각(다리기둥), (929) 터널, (930) 화학물질, (931) 세멘트, (932) 어족자원 확보용 그물, (933) 방재선 또는 방제선, (934) 원유시추선, (935) 시이소(지렛대), (936) 시추공, (937) 관교량, (938) 아노드(Inode; 전극판), (939) 냉각공기방울, (940) 비트, (941) 송풍기(1) Nuclear Power Plant (Tubular Bridge Submerged Tunnel Dock)
(2) Vertical multistage pump control panel or control box, (3) Manifold-Suction, (4) Manifold-Discharge, (5) Isolating pump isolation valve Valve, Ballor Butterfly) (6) Pump check valve
(7) fire or water for power generation and electrolyzed water; (8) disaster prevention and control pumps or vertical multi-stage pumps; (9) nozzle hoses or fire hoses; (10) firefighter nozzles (including control and disaster prevention); (11) Fire nozzle frame, (12) Sensor, (13) Hook, (14) Pipe or nozzle piping, Dock hull deck top (SDU), Hull deck center (SDM), Dock hull deck (SDL), Machine room Floor Surface Top (MFGU), Machine Room Floor Surface (MFG) Machine Room Floor Surface Bottom (MFGL) Surface Top (GLU), Surface (GLL), Surface Bottom (GLD), Equatorial Front (EL), North Pole (NP), South Pole ( SP), longitude (ld), latitude (abbreviated lt), (15) clearance, (16) angle of inclination, (17) disaster channel (18) hook hook, (19) wire rope (20) ) Machining hole, (21) Hook lug or porter lug,
(22) Jigs or various types of jigs ("

"Sleeping"

""

"Jig of the form) (23) Shackle, (24) Bolt, (25) Nut, (26) Washer, (27) Hinge (Hinge), (28) Flange or Flanged Wire Mesh, (29) Coupling, (30) Couplings Female Thread, 31 Couplings Female Thread,
(32) Gasket or rubber packing, (33) Nozzle hose equipment support, upper part of injection nozzle (A) injection nozzle body (B) lower part of injection nozzle (C) (34) sump collecting tank (35) Redusa, (36) High Performance Submersible Pumps (37) Pump Aberrations (38) Ejection Sprays (39) Water or Curtain Water Curtains, (40) Fire Extinguishers, (41) Sensor Straps, (42) Baskets, (43) Double Vinyl Tens or Bags, (44) Elbow or Tie elbow, (45) stack (chimney)
Road surface top (GLU), road surface (GLL), road surface bottom (GLD), (46) power source power supply, (47) inverter, (48) inverter off (VO) (49) Access Point (AP), (50) Internet Network, (51) (Pumped Multistage Pump) or Control Server (52) Monitor (53) Pump Control Board or Targer Winch Control Box, (54) Near Field Communication Antenna (55) Wireless communication control module for short range wireless communication device, (56) Liquid crystal display (LCD) (57) Advanced developing countrie (ADC), electronic control device (58) Switch input circuit, (59) Module concept (MCU), electronic control unit (60) Development Assistance Committee (DAC), electronic control unit
(61) brake (overcurrent breaker), (62) power supply, (63) display screen, (64) analog input, (65) digital input, (66) main switch button for on / off control of each pump, ( 67) Auxiliary switch button (68) Vertical multistage pump display (LCD) input (computer computer network input), (69) Current pressure value or set pressure value (pressure setting value) Identification plate, (70) Memory, (71) Wire, (73) Disaster Prevention Mixer (74) Block Piping Line (75) Cloth Tod, (76) Solenoid Valve (77) Ad Balloon, (78) Airship, (79) Gas Cylinder, (80) Air Compressor (81) Mobile Service (Short messge servise) (82) portable digital assistant (PDA)
(83) low pressure shutoff valve, (84) emergency valve, (85) pressure reducing valve
(86) 1st pressure check sensor, (87) 2nd pressure check sensor
(88) Electronic control unit, (89) Pumping pipe (89a) or vertical downward pipe (89b) (90) Ball valve handle
(91) Drencher Head, (92) Valve Body Inner Disc
(93) emergency sirens
(94) Sparks or lightning as the first ignition source, (95) Telephone poles, (96) Transformers
(97) Redusa Bushing Socket,
(99) Flashing warning lamp, (100) Paraffin nozzle stopper (candle), (101) Pressure gauge
(102) Bimetal Sensors, (103) Thermocouple Switches (Sensors)
(104) Level or pressure switch, (105) Flowmeter for discharge check
(106) Power motor control module, (107) Valve switch operation weight or crane boom level maintenance weight, weight
(108) Overpressure protection switch or switch box, (109) Air hose, (110) Nipple (air hose coupling)
(111), sprinkler head, (112), reflector, (113) soluble metal (fuse), (114) stop or water valve, (115) underground buried pipe, (116) pylon or block pylon (117) ) Rich, (118) rich circuit breaker (119) bell, (120) alarm valve, (121) test valve, (122) high pressure water pump, valve body center line (VBCL or PBCL), fire protection water bottom (WLD), fire water Water surface (WLL), jet water surface (WLU), (123) lever block, (124) fire extinguisher (fire extinguisher a, fire extinguisher b, fire extinguisher c, fire extinguisher D, fire extinguisher e, fire extinguisher f) (125) chain (126) cylinder or Cylinder, (127) Piston or piston pump, (128) Fire extinguisher fixing pin (129) Latch lock, (130) Life-saving air tube (131) Rope, (132) Container, (133) Anchor bolt, (134 ) Radiosonde, (135) Drive Wheel Laura (136), (136) Regulate, (137) Air Tavern Winch or Tavern Winch, (138) Air Cylinder (139) Iron Mane, (140) Turbine Pump , (141) casing, (142) vane pump or guide Person
(143) Impellers, (144) Diaphragm Pumps, (145) Air Receiver Tanks or High Pressure Storage Tanks, (146) Propeller Pumps or Propellers (147) Scrubbers or Scrubber Compressors and Scrubber Pumps (148) Plunger Pumps, ( 149) Steel beam, (150) Disaster prevention pump control system or control system, (151) Oil cooler, (152) Manhole cover, (153) Hatch cover, (154) Fire door (155) Gland packing, (156) Machinery Kerr seal or individual seal (157) Jet pump, (158) Loess (159) Firebug (160) Indoor fire hydrant (161) Auto fire hydrant (162) Hose hanger (163) Helium gas (classified as coolant) (164) Incombustible gas (carbon dioxide) (165) Steel bracket (166) Extinguishing body (classified as class A, B and C by fire type) (167) Thread tap (168) Sewage or fire protection piping line, (169) Watertight passage Furnace Piping Line, (170) Intercooler (171) Exhaust Gas (172) Life Saving Bed Nozzle, (173) Torch or Burner (174) Carbon Dioxide, ( 175) halon gas, (176) helium,
(177) ignition paraffin tape, (178) non-ignition wire, (178) fire hydrant (mono-a, twin-b), (180) plastic bag, (181) air line, (182) aftercooler (183) Limit switch or limit switch (184) Unmanned camera (CTV), (185) Jig wedge (pointed crevice fitting tool) (186) Spring, (187) Drone spark writer (188) Lifeboat (189) Head tank (Pressure tank) (190) Flexible high pressure hose or hydraulic hose, (191) Introduction pipe (hydraulic pipe)
(192) Motor body (power motor), (193) Hood, (194) Snap ring, (195) Fan, (196) Body frame, (197) Front body racket, (198) Shaft, (199) Rotor Assembly, (200) Front bearing, (201) Stator assembly, (202) Casting frame (motor protection), (203) Terminal box, (204) Lifting bolt, (205) Terminal box cover (206) Rear bearing, (207) ) Rear racket, (208) air gap, (209) fan cover or protective cover (210) rotor iron core, (211) stator iron core, (212) stator winding,
(213) Active membrane type gas hold up device
(214) filters
215 exhaust tower
(216) storage tank
217 filter
218 radioactivity meter
219 monitoring posts
220 drums
Pump Body (PB), Pump Body Vertical Line (PBVL), Pump Body Horizontal Center Line (PBCL)
(221) isobar shaped steel
222 Uranium Mine
(223) Yellow Cake
(224)
(225)
(226) Engines (generators) (277) Turbine bearings, (228) Reprocessing plants, (229) Conversion plants, (230) Enrichment plants, (231) Conversion and processing plants, (232), Searchlights, (233) Smelting Nozzle Body "Nominal 100", (235) Nominal "90", (236) Nominal "75", (237) Nominal "65", (238) Nominal 50, (239) Nominal "40" , (240) nominal "25", (241) nominal "100 × 90", (242) nominal "90 × 75" (243) nominal "75 × 65", (248) crank, (249) link, 250) Puree, (251) Reducer, (252) V (V) Belt, (253) Plunger, (254) Fixed Pin (255) Timer, (256) Marine Cable Car (257) Air Valve, (258) Safety Valve, (259) Auto or Auto Valve (260) Drain Valve (261) Belt Cover (262) Suction Filter, (263) Compressor Body (264) Pump Aberration, (265) Main Valve, (266) Forest, (267) ) Turbine, (268) flywheel, (269) inlet, (270) outlet, (271) idle operation prevention device, (272) pump power supply, (273) control power supply, (274) emergency circuit, (275) DC power supply (276) Micro control unit, (277) DIP switch setting circuit, (278) LED display circuit, (279) M / C drive signal contact output circuit, (280) Motor overload signal input circuit, (281) Inverter operation data input / output circuit, (282) Pressure sensing circuit, (283) External state input circuit, (284) Discharge pressure transmitter, (285) Suction / discharge Switch, (286) bed frame, (287) coolant (288) oil separation tank, (289) suction valve, (290) gear driver,
(291) air dryer, (292) embers, (293) flame, (294) pillar of fire,
(295) tank tanks, (296) gate valves, (297) return valves, (298) bushes or throttle bushes (299) types of drencher heads (a, b, c, d), (300) vibration alarms, (301) Drain, (302) Reverse stop valve, (303) High pressure bowl tank, (304) Rotary pump, (305) Butterfly valve, (306) Sodium bicarbonate, (307) Refill inlet, (308) Centurirepu Woogal Pump, (309) Sewage Pump, (310) Spiral Casing, (311) Blowout Pump, (312) Hood Valve, (313) Pump, (314) Pump Body, (315) Float, (316) Drust Bowl, (317) Flexible Coupling, (318) Float Switch, (319) Rear Wings, (320) Lift Valve, (321) Suction Valve, (322) Ejection Level Meter, (323) Actual Head (324) Ejection Head , (325) jet pump, (326) gear pump or gear, (327) wing pump, (330) separation chamber, (331) magnet switch (332) building, (333) building or large building, (334) balance ( 335) Unbalanced, (336) Indoor Fire Extinguishing Pump (337) Rotary Pump, (338) Rotary Cycle Here, 339-priming, 340 chair-priming pump, 341 is an axial flow pump, 342, the mixed flow pump, 343, viscous pump
(344) Standard Gland Packing, (345) Gland, (346) Liquid Lantern Packing Packing, (347) Lantern Packing, (348) Double Gland Packing, (349) Throttle Bushing Packing, (350) Cooling outlet, (351) Sealed water, (352) Cooling water inlet, (353) Sealing with inner jacket for water bottle cooling bottle, (354) Internal cooling chamber of sleeve, (355) Secondary gland, (356) Cooling chamber, (357) Gland packing, (358) Eight strands, (359) Bag weaving, (360) Lattice, (361) Flashing hole, (362) O-ring, (363) Stop the, 364) Middle East Ring, (365) Sealed Section, (366) Sheet Ring, (367) Passive Ring, (368) Quenching, (369) Coiling, (370) Return Tube, (371) Handle, (372) ) Bulkhead, (373) axial thrust load, (374) pressure on the front of the impeller, (375) pressure on the back of the impeller, (376) balance hole,
(377) Suction pressure, (378) Back pressure, (378) Balance hole, (380) Front wear ring, (381) Discharge pressure, (382) Back bearing ring, (384) Rear wing, (385) Pressure due to rear wing installation Distribution and impeller, (386) Impeller placement of multistage pumps, (387) water column separation, (388) water column coupling, (389) water hammering, (390) shaft, (391) mechanical seal cooling, (392) ) Strainers, (393) Water hammer pumps, (394) Rooftop fire cabs or crane cabs, (395) High and low mountains, (396) Pulse Encoder, (397) Speed Command, (398) ) Motor speed and transmission, (399) DISC Brakes, (400) Breakwater (401) Safety nets (Rope nets) (402) Air chambers
(403) Slew valve, (404) Valve body, (405) Valve cover, (406) Slew valve, (407) Packing press, (408) Packing press nut, (409) Valve seat, (410) Handle , (411) Handle Nut, (412) Packing, (413) Wedge Gate Valve, (414) Single Valve, (415) Flexible Valve, (416) Parallel Slide Valve, (417) Double Disc Gate Valve, (418) Stop Valve, (419) flanged glove valve, (420) flanged angle valve, (421) body, (422) cover (bonnet), (423) disc, (424) cover valve seat, (425) valve seat , (426) valve presser, (427) handle, (428) cover fitting ring, (429) packing presser ring, (430) packing presser, (431) threaded type, (432) cover bolt, (433) packing presser Bolt, (434) Pin, (435) Nut for cover bolt, (436) Packing nut Nut for bolt, (437) Handle nut, (438) Set screw, (439) Washer, (440) Packing, (441) Gasket (442) Valve press (flat press (a), cone press (b), spherical presser (c), stud presser (d), (443) cock; type 1 (444) cock (type 2), (445) bronze screw main cock, (446) cast iron plan Terrain gland type, (447) Bronze screw glandcock, (448) Sambangcock, (449) Sabangcock, (450) Handlecock
(451) Check valve, (452) Swing check valve, (453) Lift check valve, (454) Check valve body, (455), Cover, (456) Disc, (457) Disc pin, (458) Plug , (459) control valve, (460) pressure reducing valve, (461) pilot operated pressure reducing valve (magnetic), (462) secondary sensing hole, (463) diaphragm (464) pilot valve, (465), (466) Main valve, (467) Main valve spring, (468) Adjustment spring, (469) Auto pressure control valve, (470) Threaded auto pressure control valve (a), (471) Flange pressure control valve (b)
(472) Relief Valves, (473) Spring Relief Valves, (474) Relief Relief Valves, (475) Steam Pope Spring Relief Valves, (476) Pope Relief Valves, (477) Temperature Control Valves, ( 478) Auto water supply (auto level regulator), (479) Auto water supply (a), (480) Auto level regulator, (481) Air bleed valve, (482) Auto air exhaust valve Thermal type (for steam) ), (483) Auto Air Exhaust Valve, Bucket Type (Hot Water Type), (484) Refrigerant Piping Valve, (485) Refrigerant Stop Valve, (486) Fed Valve, (487) Plessed Valve (Bellow Type), ( 488) Valve (diaphragm type), (489) expansion valve, (490) diaphragm type expansion valve, (491) bellows type expansion valve, (492) rich valve, (493) refrigerant pressure control valve, ( (494) Solenoid valve, (495) Auto water supply valve (not shown), (496) General type faucet (faucet), (497) Exponential line, (498) Water fountain, (499) Bowl tap, (500) Lightning rod, ( 501) Threaded Type Y Strainer External View (a) Sectional View (b), (50) 2) U type strainer, (503) V type strainer, (504) Tubular fixing metal, (505) Turnbuckle support band, (506) support band, (507) Roller support band, (508) Band, (509) Steel Glasses Band, (510) Bottom Band, (511) Trap (522) Angled Thermal Trap, (523) Straight Thermal Trap, (524) Bucket Trap, (525) Bottom Up Bucket Trap, (526) Top-down Bucket Trap, (527) Float Trap, (528) Impulse Steam Trap (529) Faucet Body, (530) Packing Box, (531) Packing Press, (532) Tap, (533) Handle, ( 534) disk, (535) disk packing, (536) waterproof packing, (537) aging resistant packing, (538) rubber or Teflon film
(539) Metals with large thermal expansion, (540) Metals with small thermal expansion, (541) Timers or level switches (542) High Level Alarms, (543) Vacuum Fallure Alarms, (544) Thermal Relay Alarm, (545) Alarm reset button, (546) Low Level Switch, (547) flap (valve tongue), (548) Sound Cap, (549) Shock Nozzle,
(550) Louver Carver, (551) Float Insertion Switch, (552) Indicator Scale, (553) Overflow Connection (554) Vent Pipe Connection, (555) Flange Connection, (556) Double Vinyl Open Needle (557) Solenoid Valve Body, (558) Carver, (559) Spool, (560) Splashing, (561) Pilot (Guide), (562) Coil, (563) Connector, (564) Manifold (L; PTY 8 "Large Flow), (565) Manifold (S; M5 Low Flow), (566) Screw Bolt, (567) Air Hose Binding Union Coupling, (568) Union Coupling (Body Bonding), (569) 2-Position Single, (570) 2-Position Double, (571) LL; Center Vertical, (572) L; Vertical, (573) Horizontal; M , (574) F; with fittings (575) City symbol Single, (576) Double, (577) H; Center Closed, (578) I (Center Pressure) ), (579) J; Center Exhaust, (580) Micro Switch, (581) Direct Piping, (582) Base Piping, (583) Fire Damper per), (584) damper pins, (585) Dr. Ventilation (intake a, outlet b), (586) hot air balloon to Mongolian pi,
(587) Hot Air's Hot Air Balloon, (588) Kelly's Hot Air Balloon, (589) Steamship, (590) Shore Tank (pier), (591) Barge Hull at Top of Tank, (592) Barge Hull at Bottom of Shore Tank , (593) small offshore power plant dock, (594) medium offshore offshore dock, (595) large offshore offshore dock, (596) internal block tank (internal piping), (597) high tensile steel plate (High) steel surface tension), (598) block piping, (599) external block tank (support column or external piping), (600) teelong steel bar ("T"Lon'G steel bar), (601) O-ring steel bar ( "O" Ring steel bar, (602) Scarf welding hole, (603) Lug shaft coupling bolt, (604) Lug shaft coupling disassembly nut, (605) Vertical bulkhead, (606) Portable Pin Shafts for Lug Coupling, (607)
(608) portable pins,
(609) horizontal bulkhead, (610) bulkhead manhole, (611) satellite
(612) Space Rocket, (613) Lug Hinge Socket
(614) Large flange
(615) Large flange connection joint processing, (616) Jackie bed

; For mooring) hole or plate processing hole and lug processing hole,
Sea Level Top (SLU) Sea Level (SLL) Sea Level Bottom (SLD)
Out of Merchinery Room (OMR)
Merchinery Room (MR)
In of Merchinery Room (IMR)
(616) Jangong Hall
(617) Double pipe structure tank bridge pier saddle frame for construction
(618) Guide Rail, (619) Helicopter Stop (

Shown)
(620) Hydraulic Rotary Cylinder (Rotary Cylinder [Rack & Pinion Type-NRP])
(621) Band Jigs
622 bellows butterfly valve
(623) Hydraulic cylinders or hydraulic actuators, (624) Doors for hydraulic cylinders
(625) Spigot
(626) Thermal Power Plant
(627) engine control module, (engine control system)
(628) Buoy Felt Balloon (629) Rope for rope, (630) Rope hook (631) Emergency stairs or staff, (632) Lift or elevator (633) Conveyor
(634) Anti-Sink Air Floats, (635) Vacuum Pumps, (636) Tug Boats, (637) Semi-Submersible Workboats, (638) Bollards (639) Anchors (640) Anchor Chain, (641) Cooling Fan (642) Heat Fan for Air Insulation, (643) Satellite Launcher (644) Mooring Tower, (645) Magnet Magnet, (646) Space Rocket Launcher, (647) Helicopter, (648) Chain Block, (649) Loess or Cement Mixer Mixer, (650) Insulator, (651) Crane Boom or Boom, (652) Crane Boom Hook
(653) Uranium 239, (654) Water, (655) Direct Current (always flows in the same direction), (656) Alternating Current (the direction of flow changes each time the seesaw rises and falls), (657) Intermediate Heat Exchanger, ( 658) heat exchanger, (659) nichrome wire (wireless current), (660) bulb body, (661) base, (662) neptunium, (663) filament, (664) glass, (665) fluorescent discharge tube , (666) tube, (667) discharge, (668) carbon rod, (669) anode (plus; denoted by (+)), (670) cathode (minus; denoted by (-)), (671) Fuel Assembly, (672) Nuclear Power Plant, (673) Siiso Central Shaft Frame (Tidal Fixture Fixture), (674) Korean Wave, (675) Turbulence, (676) Bering Strait, (677) Chukot Peninsula, (678) Alaska, (679) Uranium 238, (680) Dam, (681) Core (682) Sheath, (683) Pellets,
(684) Voltage, (685) Power, (686) Outlet (Power), (687) Inlet (Power), (688) Reactor Building (689) Fuel Rod (690) High Voltage Substation, (691) Primary Substation, (692 ) 7 strands of steel wire in the center of the station, (693) 54 strands of aluminum, (694) fuel hoses, (695) transmission line diameters, (696) the Great Ocean Transverse Railway Substation, (697) intermediate substations, (698) Large plant, (699) Intermediary, (700) Secondary substation, (701) Substation, (702) Home (includes solar housing), (703) Staff scaffolding, (704) Cable balancing cable Ultra high voltage wire balance insulator),
(705) Tube Bridge Tunnel Dock Pipe Manufacturing Process, (706) Small Diameter Electrical Resistance Welded Pipe and SRM (3/8 to 8 inch OD), (707) Raw Materials, (708) Uncoiling, (709) Leveling, ( (710) Side trimming, (711) Cutting and coarse connection, (712) Forming, (713) Welding and internal and external bead removal, (714) Ultrasonic and Vortex Testing, (715) Weld heat treatment, (716) Air cooling, (717) ) Water cooling, (718) Round molding, (719) Cutting, (720) Flatness test, (721) Structural tubes, (722) Calibration, (723) Interlapping, (724) Induction furnace, (725) SM (SRM), (726) Hot Cutting, (727) Chamfering, (728) Hydraulic Test, (729) Ultrasonic or Vortex Test, (730) Weight and Length Measurement, (731) Visual and Dimensional Inspection, (732) Screw , (733) Oiling, (734) General Piping, (735) Galvanized, (736) Galvanized Steel Pipe, (737) Boiler Tube, (738) Cooling Table,
(739) Medium-Cage Cage Formed Electrical Resistance Welded Tube (8-24 inch O, D), (740) Coil Marginal Steel Sheet (Raw Material), (741) Side Trimming, (742) Cage Forming, (743) Oil Pipe, ( 744) Ultrasonic Testing, (745) Round Shape, (746) Oil Pipe (Petroleum Pipe), (747) Large Diameter Pipe (22-82 inch OD), (748) Edge Milling, (749) 3-Roll Bending, (750) ) Post banding, (751) Weld Welding, (752) Inner Weld, (753) Bag Hugging, (754) Outer Weld, (755) Pipe End Sizing, (756) Pipe End Chamfer, (757) X-ray Test, (758) Cold Expanding, (759) Marking. Packing. Shipped, (760) Spiral Welded Steel Pipe (400A-2600A), (761) Uncoiled, (762) Structural and Steel Pipe Pile, (763) For Uncoated Tubing, (764) Exterior Blast Cleaning, (765) , Internal blast cleaning, (766) internal coating, (767) primary coating, (768) coating and doping, (769) coating steel pipe, (770) ultrasonic and x-ray inspection, (771) electric vehicle (tunnel dock) Internal electric car)
(772) Thermal power generators (turbines), (773) Thermal power generator coils (coils that do not rotate), (774) Thermal power generator rotor coils (rotating electromagnets), (775) Transmission lines, (776) Transmission towers, (777) Switchgear, (778) Boiler, (779) Steam Pipe, (780) Powerful Gas (High Temperature & High Pressure Steam) Inlet, (781) Central Control Room (Power Control Room), (782) Transformer Room (Power Transmission Measurement Room) , (783) boilers, (784) atoms, (785) electrons, (786) steam dryers (787) magnets, (789) deaerators, (790) condensers (devices for cooling steam to make water, cooling equipment) , (791) fire, (792) drum, (793) reheater, (794) dust collector, (795) heavy oil tank, (796) heavy oil, (797) tanker or cargo ship, (798) control rod (799) Radioactive Waste, (800) Uranium Fluoride (801) Plutonium, (802) Sun, (803) Sunlight, (804) Mirror (Reflector), (805) Reflector Reflector Angle Control Frame, (806) Gathered (Set) Sunlight, (807) Steam Tower, (808) Containment Container, (809) Purifier, (810) Steam Generator, (811) Reactor, (812) Enriched Uranium (Uranium 235), (813) Reactor Pressure Vessel, (814) Pressurizer, (815) Nucleus, (816) Coolant, (817) Silencer , (818) separator, (819) moderator, (820) proton, (821) neutron
(822) Rod & piston seal (ROD & piston seal; UPI (a), UPH (b), (823) Piston seal (OSIa, ODIb, OUIc, SPGd, SPGWe, GRf), (824) Buff seal ; HBYa, HBTZb, Sealc), (825) Wear Ring (WRa, RYTb), (826) Slide Ring, (827) DU Bush, (828) O-RING , 829 loaded seal (ISIa, IDIb, IUHc), (830) back up seal _{(back up seal; T 2 /} T 3 (a), BRT 2/3 (b)), (831) loaded seal and a backup seal , (832) Dust seal (LBIa, DSIb, LPIYc, DWId, DKBIe, DKIf, DWIRg, LBHh, DKBi), (833) pin dust seal (Vaya, DLIb,), (834 ) Dust wiper seal, (835) Buffer Ring, (836) Piston Ring, (837) Dasting, (838) Watermill
(839) isobars (including angle and isobars), (840) weather radar, (841) crude oil (oil), (842) submarine mineral gardening baskets, (843) deep sea search underwater lighting (844) Buckets or pallets, (845) excavators (scure drills; deep-sea excavation rigs) (846) anchor replacement wedge cranks, (847) rock drills or nets, (848) actuators, (849) subsea mineral garden pouches, (850) Turnbuckles, (851) Level foundation bases for piers, (852) Wedge supports (fixed), (853) Welders (Arc or Arj arc or argon)
(854) pipe rack, (855) recirculation pump (856) pressure control pool, (857) feed water pump, (858) circulating water pump, (859) coolant pump, (860) dump truck, (861) crane or crane, (862) motor grader, (863) roller, (864) road safety, (865) concrete batching plant, (866) concrete finisher, (867) concrete spreader, (868) concrete mixer truck, (869) concrete pump, (870) Asphalt Mixing Plant, (871) Asphalt Finisher, (872) Asphalt Spreader, (873) Aggregate Spreader, (874) Crusher (875) Air Compressor, (876) Perforator, (877) Driven and Ejector, (878 ) Saree Collector, (879) Dredger, (880) Separate Construction Machinery, (882) Pile Driver, (883) Diesel Pile Hammer, (884) Steam Hammer, (885) Hydraulic Crane, (886) Tower Crane, (887) ) Crawler Crane, (888) Truck Crane, (889) Macadam Roller, (890) Tandem Roller, (891) Tamping Roller, (892) Tire Roller, (893) Tractor, (894) Trailer, (895) Ram, ( 896) Lee , (897) Coolant chiller, (898) Pile, (899) Helm, (900) Fuel Pump, (901) Cam, (902) Fuel Tank, (903) Starter, (904) Boom Front Pin (905) CADWORK , (906) Adapter, (907) Fish Finder (Sona), (908) Oil Drilling Drilling Machine (Rotary Table), (909) Manganese Nodule, (910) Garden Net, (911) Suction Harvester, (912) Submarine Mineral Harvesting Robot, (913) Periscope, (914) Hot Air Balloon, (915) Wire Rope Chain, (916) Lematic Transport Equipment, (917) Core Drill, (918) BIOPSID, (919) Rubber Tire, (920) Burner Boom, (921) Hazardous Microorganisms, (922) Pollution-Free Natural Gas, (923) Air Nozzle, (924) Mineral Gathering Tobacco, (925) Updraft, (926) Downdraft, ( (927) Yellow dust fines, (928) Piers (pillars), (929) Tunnels, (930) Chemicals, (931) Cement, (932) Fish stock nets, (933) Disaster or control ships, (934) Crude Oil Driller, (935) Siiso (Lever), (936) Borehole, (937) Pipe Bridge, (938) Anode (I) node; Electrode plate), (939) cooling air drop, (940) bit, (941) blower

Claims (8)

Nuclear waste treatment method and nuclear reactor facilities using the nuclear explosion prevention of the conventional double-structure block tank, a large amount of radiation is generated inside the reactor 811 of the reactor facility, the reactor 811 is made of a protective layer that is safely five layers A nuclear power plant including a reactor 811 for nuclear power generation and a plurality of double pipe structure block tanks 598 for nuclear waste storage, which are radiations connecting the circumferential surface of the reactor pressure vessel 813, which is the third wall of the reactor 811, to one. In the reactor facility using nuclear power generation of the body (1), the reactor facility,
The nuclear power generation generates a nuclear fission in the reactor (811) to produce steam from the steam to rotate the steam turbine (267) to produce power, and the power generated from the steam turbine (267) The rotor coil 774, which is a rotating electromagnet installed along a circumferential surface of the shaft 198, which is a rotating shaft connecting the generator 772 and the steam turbine 267 to the generator 772, and the rotor coil ( 774) an armature coil 773 for a generator, which is a coil that is not rotated along a circumferential surface, and a frame 775 integrally fixing the generator 772 and the shaft 198 to the steam turbine 267. A power generation unit including; Cooling water (287) piping line 352 having a connection structure with the condenser 790 in the lower portion of the steam turbine (267) body of the power generation unit, the conduit line (169) and the coolant ( 287. A circulating water pump 858 is connected to the pipe line 352. A water supply pump 857 is formed at the rear of the condenser 790 and outside the reactor 811, and is located in front of the water supply pump 857. A plurality of coolant pumps 859 are formed outside the reactor pressure vessel 813 body in which the uranium 812 fuel is stored. Installed in the reactor pressure vessel 813 is a safety device control rod 798 is installed, when a shake occurs, the control rod 798 is automatically inserted a lot at a time, the reactor is an emergency stop, the pressure vessel 813 of the reactor Installation outside the body Is connected to the steam generator 810 and the steam dryer 786, the containment vessel 808 corresponding to the fourth wall of the reactor 811 and the upper part of the reactor building 688 corresponding to the fifth wall. After the plurality of through holes are processed with oxygen cutting machines and construction machines at a predetermined angle of 45 ° to the plurality of through holes, a plurality of safety valves 472 are blocked while forming block pipe lines 74 having a double pipe structure. A double pipe structure having a diameter of twice the diameter of the reactor building 688 along the outer wall circumference of the reactor building 688 and connected to the flange with a bolt 24 and a nut 25 on the pipe line 74. Nuclear waste treatment storage tank (599) and radiation type connection structure is formed in 8 block tanks (598) of the reactor and protects the pellet (683), the first wall of the reactor (811), and the fuel rod (689), the second wall. Reactor, which is the third wall due to high earthquake of magnitude 5 or more, When the inside of the energy container 813 is exploded, a plurality of safety valves 472 are opened, and the nuclear wastes exploded through the block piping line 170 at each place pass, whereby the nuclear wastes are stored in each of the block tanks 598 and have a lifetime. When dismantling a reactor such as a nuclear power plant, cutting by a remote control or robot 700 is used. When the explosion inside the reactor pressure vessel 813 stops, a plurality of safety valves 472 are closed. A plurality of safety valves 472 are closed and various nuclear reactors can be installed on the barge 591 of the ocean, and the installation position of the nuclear power plant is adjusted to 40m above sea level so as not to be restricted by meteorological conditions, thereby being affected by earthquakes and tsunamis. To prevent the nuclear reactor (811) of the nuclear power plant from being exploded and to prevent the environment from being polluted by nuclear waste. By re-installing the dual-structure block tank reactor facility in which the furnace does not explode, the nuclear power plant, etc., guarantees the safety of the nuclear power plant and ensures the renovation of the reactor 811 to ensure safe and continuous operation. And reactor equipment The method of claim 1,
In the waste generated from the nuclear power plant and a method of treating the same, an active membrane type which weakens radioactivity when using the pressurized water reactor 811 when the air inside the building and the air contained in the water inside the reactor 811 is a gas. The gas hold-up device 213 discharges the purge air to the outside air, or the power plant building ventilation is configured to be discharged to the plurality of symmetric filters 214 or to exhaust all of the vented air from the exhaust tower 215. Nuclear waste treatment method and reactor facility The method according to claim 1 or 2,
When the regeneration solution of the ion exchange resin is liquid in the water leaked from the valve of the nuclear power plant and the general purpose water in the building, the wash water is collected in the storage tank 216, filtered by the filter 217, and then the radioactivity meter 218. The radioactivity level is measured to confirm that there is no harm, and then flows to the sea with cooling sea water. The water other than the wash water is purified by the filter 217, and the filtered water and distilled water are reused as a reactor coolant, and a monitoring post 219 for monitoring is formed. The method of claim 3,
When the hybrid species inside the building of the nuclear power plant, such as cloth, work clothes, shoes, etc., the ion exchange resin and the filter medium are solid, the filter sludge and the used resin liquid are stored in the storage tank 216 and solidified with a concrete drum ( 220) and the paper and cloth are compressed to reduce the volume and attenuate, so that all of them are hardened with concrete, filled in the drum (220), and the waste is stored to move the waste by a forklift inside the site and store it. Nuclear waste treatment method and reactor facility, characterized in that the monitoring monitoring post 219 is further formed The method according to any one of claims 1 to 4,
The nuclear fuel used in the nuclear power plant and the remaining uranium 812 are processed in the reprocessing plant 228 and then processed into uranium fluoride 812 in the conversion plant 229 to move the nuclear fuel to the enrichment plant 230. The uranium fluoride 812 is converted to uranium dioxide in the conversion plant 229 and processed into pellets 683 to produce fuel rods, and the plutonium 801 processed in the reprocessing plant is converted to a processing plant 231. Fuel rods 689 are made at these fuel cells, and these reprocessing fuel rods 689 are moved back to the nuclear power plant 672 to convert the nuclear power plant 672 and the enrichment plant 230 to the reprocessing plant 228. Nuclear waste treatment method and reactor facility, characterized in that the conversion to the factory (229) and processing plants (231) is formed on the upper surface of the barge deck deck of the sinking type of 40 meters above sea level of the ocean The method of claim 5,
High-level wastes, which are wastes from reprocessing in nuclear power plants (672), have long half-lives and need to be stored for thousands of years, so that nuclear wastes are buried in polar glaciers, deeply buried in layers or ocean floors, The nuclear fission in the reactor (811) to convert to other materials, such as sending to space, etc. At this time, the permanent disposal method of high-level waste, construction machinery heavy equipment aviation, excavators and ships and double pipe structure drum barrel 220 Nuclear waste treatment method and the reactor facility, characterized in that the rocket and the space rocket launch pad (646) is further formed on the barge deck deck (591). The method of claim 6,
In case of failure in the reactor 811 of the nuclear power plant 672, the maintenance and repair work period is more than three months. Nuclear waste treatment method and reactor facility characterized in that the thermal power plant is further formed to enable emergency power supply by supplying steam of high temperature and high pressure by forming a connection structure to the reactor power generation facility by operating 783). The method of claim 7, wherein
The block tank 598 of the double pipe structure, which is a nuclear waste storage tank of the nuclear power plant 672, includes an inner block tank 596 and an outer block tank 599, which firmly support the double pipe structure block tank 598. The inner block circumferential surface of the inner block tank (596) and the inner wall circumferential surface of the outer block tank (599) are made of steel plate brackets (165) on the isotropic steel (221), the thylongji steel bar (600) and the oring steel bar (601). Assembled by the assembly process such as computer underwater cutting and welding, the hydraulic cylinder door 624 is provided on the wall of each of the inner block tank (596) and outer block tank (599) so that the forklift can enter and exit the manhole and the manhole cover. Nuclear waste treatment method and reactor facility using nuclear explosion prevention of dual-structure block tank, characterized in that further formed

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