KR101433907B1 - Cooling system for nuclear power plant by using sea water - Google Patents

Abstract

The present invention relates to a nuclear emergency cooling system using seawater, and more particularly, to a nuclear emergency cooling system using seawater, and more particularly, to a nuclear emergency cooling system using seawater, The present invention relates to a nuclear emergency cooling system.
According to the present invention, when a normal cooling system becomes inoperable due to an abnormality of a power system or the like of a nuclear power plant, a system for instantly introducing seawater by using a natural head difference without supplying external power is operated , And to maintain the safety of the nuclear power plant by maintaining the cooling state of the nuclear power plant by using sufficient seawater.

Description

{COOLING SYSTEM FOR NUCLEAR POWER PLANT BY USING SEA WATER}

The present invention relates to a nuclear emergency cooling system using seawater, and more particularly, to a nuclear emergency cooling system using seawater, and more particularly, to a nuclear emergency cooling system using seawater, The present invention relates to a nuclear emergency cooling system.

Nuclear power plants have been used as useful power resources. However, as shown in the past Chernobyl and Fukushima Nuclear Power Plants in Japan, it has been shown to be beneficial in terms of environmental damage to a wide range of surrounding areas when an unexpected abnormality occurs in a power plant. There is a problem that it is perceived as a dangerous facility which is not so bad. Especially, when the core is exposed and melted due to no cooling water being supplied to the reactor, it causes radiation leakage to the surrounding area, resulting in a very lethal danger. However, until such an emergency occurs, There is a problem in that there is insufficient research on the solution measures to be made promptly without waiting for the control to be performed and without supplying external power.

SUMMARY OF THE INVENTION The present invention has been made to overcome the above problems, and it is an object of the present invention to provide a system and a method for operating the system in which, when a normal cooling system becomes inoperable due to an abnormality of a power system of a nuclear power plant, So that the cooling state of the reactor or the like can be maintained by using the sufficiently supplied seawater to maintain the safety of the nuclear power plant.

In order to achieve the above object, according to the present invention, an emergency cooling system (first emergency cooling system) of a nuclear power plant installed in the sea is provided with a nuclear reactor circulating water containing heat generated through a nuclear reaction in a reactor A steam generator for generating steam for driving a turbine from the cooling water present therein by the heat of the nuclear water circulation water; A sensor for detecting a change in pressure or temperature of the steam generator; A switch for introducing seawater to be supplied to the emergency generator into the steam generator when the pressure or temperature of the sensor is detected to be higher than a reference value by a predetermined value or more; And an emergency cooling pipe for transmitting the seawater flowing through the switch to the steam generator, wherein the steam generator is configured to supply the seawater to the steam generator using the water head difference corresponding to the sufficient position head of the secured seawater (Hereinafter, referred to as 'minimum water surface') when the sea surface of the nuclear power plant installation point is the lowest.

At least two pairs of the switch and the emergency cooling pipe may be installed to perform the emergency cooling function at the same time.

At least two sensors may be installed to perform an emergency cooling function at the same time.

According to another aspect of the present invention, a nuclear emergency cooling system (second emergency cooling system) installed on the sea includes a reactor equipped with a core in which a nuclear reaction process proceeds; A sensor for sensing pressure or temperature change of the reactor; (GBS) module (hereinafter, referred to as 'reactor module') including the reactor, when the pressure or temperature of the sensor is raised above a reference value by a predetermined value or more, A switch for introducing seawater to be supplied; And an emergency cooling pipe for transmitting the seawater flowing through the switch to the inside of the reactor module, wherein the discharge port for discharging the seawater introduced from the emergency cooling pipe into the reactor module comprises: (Hereinafter referred to as " highest water level ").

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A discharged cooling water storage module for discharging and storing seawater continuously flowing into the reactor module; And a cooling water discharge pipe discharging the cooling water from the reactor module to the discharged cooling water storage module.

The marine nuclear reactor emergency cooling system may further include a steam discharge pipe for discharging the steam generated by the reactor cooling to the discharged cooling water storage module.

The steam discharge pipe may include a nozzle for discharging steam to the discharged cooling water storage module, and the nozzle may be located below the discharged cooling water storage module on the steam discharge pipe.

At least two pairs of the switch and the emergency cooling pipe may be installed to perform the emergency cooling function at the same time.

At least two sensors may be installed to perform an emergency cooling function at the same time.

According to another aspect of the present invention, an onshore nuclear emergency cooling system using seawater comprises: a sensor for sensing a pressure or temperature change on an element in an onshore nuclear power plant including a reactor, a steam generator; A switch for introducing seawater to be supplied to the cooling water into each part of the nuclear power plant when the pressure or temperature of the sensor is raised to a predetermined value or higher; An emergency cooling water injection pipe connected to the seawater and delivering the seawater introduced from the switch as emergency cooling water to the corresponding part in the nuclear power plant; And an emergency cooling water discharge pipe for discharging the emergency cooling water in the nuclear power plant to a vessel in the marine vessel which is maritime or marine in the vicinity of the land.

In the emergency cooling water injection pipe, one end connected to the sea water is connected to a seawater supply pipe of a ship which rides in the vicinity of the ground in case of emergency, and the seawater supply pipe of the ship can supply seawater to the emergency cooling water injection pipe have.

The offshore nuclear reactor emergency cooling system using the seawater may further include an emergency transmission line supplied with electricity from a ship which is in a maritime state in the vicinity of an emergency in the case of emergency, and a cooling pump for operating the supplied electric furnace cooling system.

According to another aspect of the present invention, there is provided a method for cooling an emergency condition of a nuclear power plant installed in a marine environment, the method comprising the steps of: (a) Sensing a pressure or a temperature change of a steam generator that generates steam for driving a turbine from the cooling water existing therein by the heat of the circulating water flowing into the circulating water; And (b) opening the switch when the pressure or temperature of the sensor is detected to be higher than a reference value, thereby introducing seawater into the emergency generator for supplying steam to the steam generator.

According to another aspect of the present invention, there is provided a method for cooling an emergency nuclear power plant installed in a marine environment, the method comprising the steps of: (a) controlling a pressure of a reactor equipped with a core Or sensing a temperature change by the sensor; (GBS) module (hereinafter, referred to as a 'reactor module') including the reactor by opening the switch when a pressure or temperature of the sensor is raised to a reference value or more, Further comprising the step of introducing seawater to be supplied to the emergency cooling water, and after the step (b), discharging the seawater continuously flowing into the reactor module to the discharged cooling water storage module through the cooling water discharge pipe .

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And discharging the steam generated by the reactor cooling to the discharged cooling water storage module through the steam discharge pipeline.

According to another aspect of the present invention, there is provided a method for cooling an onshore nuclear emergency cooling system using seawater, comprising the steps of: (a) Sensing a pressure or temperature change on the element; (b) opening the switch when the pressure or the temperature of the sensor is raised to a predetermined value or higher, and introducing the seawater to be supplied to the cooling water into each part of the nuclear power plant; And (c) discharging the emergency cooling water in the nuclear power plant to a vessel in the marine vessel which has been maritimely or marine in the vicinity of the land.

In the step (b), one end of the pipe for introducing the seawater to be supplied to the cooling water into each part of the nuclear power plant is connected to the seawater supply pipe of the ship which rides in the emergency in the vicinity of the land, The water supply pipe can supply seawater to the emergency cooling water injection pipe by a pump.

Further comprising an emergency transmission line for receiving electricity from a ship which has been docked near the land in the emergency, and a cooling pump for operating the supplied electric furnace cooling device.

According to the present invention, when a normal cooling system becomes inoperable due to an abnormality of a power system or the like of a nuclear power plant, a system for instantly introducing seawater by using a natural head difference without supplying external power is operated , There is an effect that the safe state of the nuclear power plant can be maintained by maintaining the cooling state of the nuclear reactor etc. using the fully supplied seawater.

1 is a schematic diagram showing a schematic structure of a cooling system of a nuclear power plant located in the sea;
Fig. 2 is a diagram showing an operating structure of an emergency cooling system at the time of occurrence of a specific emergency situation in a nuclear power plant located in the sea;
3 is a diagram showing an operating structure of an emergency cooling system when another specific emergency situation occurs in a nuclear power plant located in the sea;
Fig. 4 is a diagram showing the structure of an emergency cooling system using an emergency feed and an inflow of seawater when an emergency occurs in a nuclear power plant installed on the land adjacent to the ocean.
Fig. 5 is a view showing a state in which a ship for emergency operation of an emergency cooling system using an emergency feeder and a seawater inflow from a nuclear power plant installed on the land adjacent to the ocean.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

1 is a schematic diagram showing a schematic structure of a cooling system of a nuclear power plant located on the sea.

GBS (gravity-based-structure) is a type of structure that secures the stability of a structure by the gravity generated by the gravity of a huge structure itself. GBS is mainly used with steel and reinforced concrete and is used for construction of an offshore plant . After the GBS structure is completed, it is lifted to the target point using a turbo boat, and the ballasting system is used to set it on the sea floor.

The reactor (110) is the core facility of the nuclear power plant. The heat generated in the reactor 110 through the nuclear reaction is contained in the reactor water circulation water and flows through the circulation water pipe 11 and the reactor water circulated into the steam generator 120 flows into the steam generator internal pipe The steam is generated by transferring heat to the cooling water 20 existing in the steam generator while flowing through the steam generator 12. Conversely, the cooling water 20 deprives the heat of the reactor water circulating through the steam generator internal pipe 12, and the reactor water circulating through the pipe 13, which is returned to the reactor 110, As shown in FIG.

The steam generated in the steam generator 120 is transferred through the steam pipe 14 to drive the turbine 130 by its thermal energy so that the generator 140 is operated to generate electric power .

The cooling system according to the present invention uses seawater 30 as a cooling solvent for maintaining the temperature of circulating cooling water. That is, the steam entering the condenser 150 after driving the turbine 130 enters the seawater inflow pipe 15 and is rapidly condensed into the cooling water by the circulating water. The condensed cooling water flows into the cooling water inflow pipe 16 The cooling water 20 in the steam generator 120 is replenished and filled.

In such a nuclear cooling system, the failure of a nuclear cooling system due to an accident can be classified into two situations according to the degree of the situation.

1) Situation 1: All electric fields lose their function and the existing cooling system becomes inoperative, so that the failure of the feed-water-pump 17, which is illustrated in Fig. 1, and the failure of the cooling water supply pump 17 The cooling water can not be supplied to the steam generator 120 due to the occurrence of an accident due to the breakage of the pipe 16 connected to the steam generator 120.

2) Situation 2: When all the electric fields lose their functions and the existing cooling system becomes inoperable, the cooling water can not be supplied to the reaction furnace 110 shown in FIG. 1, It refers to the accident situation.

Hereinafter, the structure of the emergency cooling system according to the present invention in accordance with the occurrence of Situation 1 and Situation 2 as described above with reference to Figs. 2 and 3 will be described.

FIG. 2 is a diagram showing an operating structure of an emergency cooling system at a specific emergency situation in a nuclear power plant located in the sea.

That is, FIG. 2 shows a system configuration for coping with 'situation 1' as described with reference to FIG.

It is desirable to secure the position head at a position of at least 5m from the free water surface at the target water depth 20 ~ 30m. The switch 203 is provided on the outer wall of the GBS module. The switch 203 is connected to a steam generator 204 and connected to a sensor 202 for opening and closing the switch 203 according to the pressure or temperature of the steam generator 204. Also, one or more emergency cooling pipelines 201 are connected to the switch 203 and the emergency cooling pipeline 201 is connected to the steam generator 204 inside the GBS module. From this structure, the sensor 202 is opened by the operation of the state 1, so that the switch is opened, so that the cooling water is supplied to the steam generator 204 by supplying the seawater to the steam generator 204 from the outside.

The design of the reactor building 250, in which the reactor 220 is located to supply the seawater to the steam generator using the water head difference according to the sufficient position head of the secured seawater, The steam generator 204 should be located at least 5 meters below the free surface.

In addition, cooling water is supplied to the inside of the steam generator 204 due to a failure of the cooling water feed pump 206 or the feed-water-pump pipeline 207, which is an existing cooling system, The pressure inside the steam generator should be lower than the head head pressure due to the seawater at the location of the pipe and steam generator 204 in order to introduce seawater through the emergency cooling pipeline. It is preferable that a valve 205 or an opening / closing switch 203 which can be opened or closed according to pressure or temperature is installed in the steam generator pipeline so as to lower the pressure inside the steam generator 204 when the situation 1 occurs.

On the other hand, by providing one or more emergency cooling pipes, sensors, and switches in case of a problem in the emergency pipeline 201, the sensor 202 or the switch 203, the reliability of the entire system can be increased.

3 is a diagram showing an operating structure of an emergency cooling system at the time of occurrence of another specific emergency situation in a nuclear power plant located in the sea.

That is, FIG. 3 shows a system configuration for coping with 'situation 2' as described with reference to FIG.

A switch 312 is provided on the outer wall of the lower end of the outer wall of the GBS module and connected to a reactor 220 inside the module and provided with a sensor 310 that can be opened or closed according to the temperature or pressure change of the reaction path 220 have. The switch 312 is provided with one or more emergency cooling pipelines 309 so that seawater can flow into the reactor building 250 in the GBS module passively when the situation 2 occurs. In other words, the cooling system shown in FIG. 3 has a structure for preventing the exposure of the core by filling the inside of the nuclear GBS with seawater when the recovery of the nuclear power plant is difficult due to the occurrence of an abnormal state, I have.

For this purpose, the method is adopted in which seawater is continuously introduced until the position head of the free water surface (20 ~ 30m) of the seawater outside the GBS module and the position head of the seawater flowing into the GBS are equal to each other. The cooling water outlet (311) of the emergency cooling pipeline (309) in the GBS module must be located in the module at least 3 m higher than the average sea level of the sea nuclear installation area so that the cooling water in the GBS module equals the average sea level head In case of overtaking, the inflow of seawater should be possible.

On the other hand, in this cooling system, continuously generated steam is continuously supplied to the reactor module (hereinafter referred to as 'Module # 2'), which is a GBS module in which the building is located, And a steam discharge pipeline 313 which can be sent to a discharged cooling water storage module (hereinafter referred to as 'Module # 1') 350, which is another GBS module located next to the steam generator 360.

Also, the present cooling system is capable of continuously sending seawater to the GBS module Module # 1 350 (350) in order to allow seawater to flow continuously and to keep the introduced seawater at a sufficiently cool temperature as cooling water. And a pipeline 314 for discharging cold water.

The pipe 313, which emits steam generated by the reactor cooling, is located below the GBS module Module # 1 350, which allows the discharged steam to be discharged to the atmosphere through the secondary cooling water through the nozzle, So that the emission time is delayed and the pollutants contained in the steam are passed through the secondary cooling water to have an effect of purifying once.

The steam generated in the GBS module Module # 2 360 and sent to the GBS module Module # 1 350 through the steam discharge pipeline 313 flows through the steam discharge pipe 315 ) To lower the internal pressure of the GBS module Module # 1 (350).

Meanwhile, by providing one or more emergency cooling pipes, sensors, and switches in case of a trouble in the emergency pipeline 309, the sensor 310 or the switch 312, the reliability of the entire system can be increased.

FIG. 4 is a diagram showing the structure of an emergency cooling system using an emergency feed and an inflow of seawater when an emergency occurs in a nuclear power plant installed on the land adjacent to the ocean, FIG. 5 is a view showing a state in which a ship for operating the emergency cooling system is in a docked state Fig.

That is, the emergency cooling system according to the present invention performs emergency cooling and restoration of the functions of the power supply system in the state of a failure of the cooling system due to the failure of the off-site power supply of the nuclear power plant installed on the land adjacent to the ocean and the failure of the emergency power generation system . This emergency cooling system requires the design of a number of emergency cooling water injection piping connected to the sea and an additional off-site power transmission facility, and is designed to recover power and cooling system functions quickly from a floating offshore structure in an emergency. The specific structure will be described below. Each pipe on the drawing is shown to be distinguishable by color, and a drawing number is separately indicated to describe what each color means (40,50).

When designing and constructing the nuclear power plant, the emergency cooling water pipes 404 and 405 and the emergency transmission line 406 are installed to be connected to the marine docking facility as shown in FIG. When a trouble occurs in the nuclear power plant cooling system and the electric system, the ship 411 bites and connects to the emergency cooling water pipes 404 and 405 and the emergency transmission line 406 as shown in FIG. The ship 411 shown in FIG. 5 can supply emergency power and cooling water equally to all the nuclear power plants designed as shown in FIG.

The pressurized light water reactor type nuclear power plant consists of core cooling (401), primary cooling (402), and secondary cooling (403: radioactive uncooled cooling water piping) system.

One or more emergency cooling water pipes, sensors, and switches may be installed in the emergency cooling water pipe, sensor or switch 408 in case of a problem, thereby enhancing the reliability of the entire system.

The emergency cooling water pipe is composed of an injection pipe 404 and an exhaust pipe 405.

The injection piping 404 is connected to the float pipe 410 and the injection piping 404 and the discharge piping 405 are opened and closed by the switch and sensor 408.

The cooling water discharged through the radiation exposure chilled water pipe 401 and discharged to the discharge pipe 405 is stored in the float tank 407 as it is exposed to radioactivity.

The cooling water discharged through the radioactive unexplored cooling water pipe 402 and discharged to the discharge pipe 405 is discharged to the outside of the nuclear power plant since it is not exposed to radioactivity.

Since the cooling water passing through the radioactive unexposed cooling water pipe 403 is discharged to the existing pipe line, no additional discharge pipe is required.

The emergency transmission line (406) supplies power to the direct cooling pump (409) when the off-site power supply and the emergency power generation facility are both in failure, and restores the function.

The emergency cooling system is designed and operated to cope with various emergency situations, respectively. Examples of such emergency situations and their corresponding coping functions are illustrated below.

In the first embodiment, the pump function is lost.

In this case, since the cooling water pipe lines 401, 402, and 403 remain functional, cooling water is injected from the floating fluid through the injection pipe 404 to recover the cooling function.

The second embodiment is a case in which the power loss of the off-axis power supply and the emergency generator is lost, that is, all power is lost.

In this case, the power supply to the pump 409 is attempted through the emergency transmission line 406.

When the pump 409 does not operate, the cooling water is directly supplied through the injection pipe 404 as in the first embodiment, and then circulated.

11: Circulating water pipe 12: Steam generator inner tube
13: Pipes returning to the reactor
14: Steam pipe 15: Seawater inflow pipe
16: cooling water inlet pipe 17: cooling water feed pump (feed-water-pump)
20: cooling water 30: seawater
110: Reactor 120: Steam generator
130: Turbin 140: Generator
150: condenser
201: Emergency cooling pipeline 202: Sensor
203: switchgear 204: steam generator
206: feed-water-pump
207: Pipeline 220: Reactor
250: reactor building
309: Emergency cooling pipeline 310: Sensor
311: Cooling water outlet 312:
313: Pipeline for steam discharge 314: Pipeline for secondary cooling water discharge
350: Emissive cooling water storage module 360: Reactor module
401: Radiation exposed cooling water piping 402: Radiation unexposed cooling water piping
403: radioactive unexposed cooling water pipe 404,405: emergency cooling water pipe
406: emergency transmission line 407: tank of float
408: sensor or switch 410: pipe of float
411: Ships

Claims (21)

delete delete delete delete As an emergency cooling system of a nuclear power plant installed on the sea,
A reactor equipped with a core in which a nuclear reaction process proceeds;
A sensor for sensing pressure or temperature change of the reactor;
(GBS) module (hereinafter, referred to as 'reactor module') including the reactor, when the pressure or temperature of the sensor is raised above a reference value by a predetermined value or more, A switch for introducing seawater to be supplied; And
An emergency cooling pipe for transmitting the seawater flowing through the switch to the inside of the reactor module,
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And an outlet for discharging the seawater introduced from the emergency cooling pipe into the reactor module,
Installed at a level higher than the water surface (hereinafter referred to as "the highest water surface") when the sea surface of the nuclear power plant installation point is the highest
Wherein the cooling system comprises:
delete The method of claim 5,
A discharged cooling water storage module for discharging and storing seawater continuously flowing into the reactor module; And
A cooling water discharge pipe for discharging the cooling water from the reactor module to the discharged cooling water storage module
Further comprising: an emergency cooling system for the marine nuclear power plant. The method of claim 7,
The steam generated in the reactor cooling is discharged to the discharged cooling water storage module,
Further comprising: an emergency cooling system for the marine nuclear power plant. The method of claim 8,
The steam discharge pipe includes:
And a nozzle for discharging steam to the discharged cooling water storage module,
The nozzle
A lower portion of the discharged cooling water storage module on the steam discharge pipe
Wherein the cooling system comprises: Claim 10 has been abandoned due to the setting registration fee. The method of claim 5,
The switch and the emergency cooling pipe,
At least two pairs are installed to perform emergency cooling function at the same time
Wherein the cooling system comprises: Claim 11 has been abandoned due to the set registration fee. The method of claim 5,
The sensor includes:
Two or more installed at the same time to perform emergency cooling function at the same time
Wherein the cooling system comprises: As an offshore nuclear emergency cooling system using seawater,
A sensor for sensing pressure or temperature changes to elements in the onshore nuclear power plant, including a reactor, a steam generator;
A switch for introducing seawater to be supplied to the cooling water into each part of the nuclear power plant when the pressure or temperature of the sensor is raised to a predetermined value or higher;
An emergency cooling water injection pipe connected to the seawater and delivering the seawater introduced from the switch as emergency cooling water to the corresponding part in the nuclear power plant; And
Emergency cooling water discharge pipe discharging emergency cooling water in nuclear power plant to marine or tanker in ship near sea
A system for emergency cooling of a nuclear power plant using seawater containing. The method of claim 12,
In the emergency cooling water injection pipe,
One end connected to the seawater is connected to a seawater supply pipe of the ship which rides in the vicinity of the land in an emergency, and the seawater supply pipe of the ship is supplied with seawater to the emergency coolant supply pipe by a pump
The emergency cooling system of the onshore nuclear power plant using seawater. The method of claim 12,
An emergency transmission line for receiving electricity from a vessel which is in the vicinity of the ground in an emergency, and a cooling pump for operating the supplied electric furnace cooling system
The emergency cooling system of the onshore nuclear power plant using seawater. delete The method according to claim 5, wherein the marine nuclear emergency cooling system performs cooling in an emergency situation of a nuclear power plant installed in the sea,
(a) sensing a pressure or temperature change of a reactor equipped with a core in which a nuclear reaction process is performed; And
(b) when the pressure or temperature of the sensor is sensed to rise above a reference value, the switch is opened to open the inside of a GBS (gravity-based-structure) module Step of introducing seawater to be supplied to the emergency cooling water
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After the step (b)
Discharging the seawater continuously flowing into the reactor module to the discharged coolant storage module through the coolant discharge pipe
Further comprising the steps of:
delete 18. The method of claim 16,
Discharging the steam generated by the reactor cooling to the discharged cooling water storage module through a steam discharge pipeline
Further comprising the steps of: The method according to claim 12, wherein the onshore nuclear emergency cooling system is a method for performing cooling in an emergency situation of an onshore nuclear power plant using seawater,
(a) sensing a pressure or temperature change for each component in a terrestrial nuclear power plant including a steam generator;
(b) opening the switch when the pressure or the temperature of the sensor is raised to a predetermined value or higher, and introducing the seawater to be supplied to the cooling water into each part of the nuclear power plant; And
(c) Emergency cooling water in the nuclear power plant is discharged from the sea or from the sea to a tank in the ship which is near the land.
The method comprising the steps of: The method of claim 19,
In the step (b)
One end connected to the seawater of the pipe for introducing the seawater to be supplied as cooling water to each part of the nuclear power plant is connected to the seawater supply pipe of the ship which rides in the vicinity of the land in case of emergency and the seawater supply pipe of the ship, Supplying sea water to the emergency cooling water injection pipe
The method comprising the steps of: The method of claim 19,
An emergency transmission line for receiving electricity from a vessel which is in an emergency at sea near the land, and a cooling pump for operating the supplied electric furnace cooling system
The method further comprising the step of:

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