KR20210054874A - Cooling system using liquefied oxygen - Google Patents

Abstract

The present invention relates to a cooling system using liquefied oxygen, which can prevent congelation of a liquefied oxygen transfer pipe, occurring when cool air is directly generated with the liquefied oxygen, by generating the cool air with a liquid cooled by the liquefied oxygen. To this end, the present invention provides a cooling system using liquefied oxygen, comprising: an oxygen storage vessel storing liquefied oxygen; a liquid tank having a vacant space therein, wherein the vacant space is filled with a liquid of a first temperature; a heat exchanger disposed within the liquid tank, cooling the liquid through the liquefied oxygen discharged from the oxygen storage vessel at a second temperature lower than the first temperature, and discharging, to the outside, gaseous oxygen gasified from the liquefied oxygen according to cooling of the liquid; a transfer pipe transferring the cooled liquid of the second temperature; an air blowing fan installed near the transfer pipe and cooling surrounding air by the cooled liquid of the second temperature which flows along the transfer pipe to supply the cooled air to the outside; and a reduction pipe connected between the transfer pipe and the liquid tank and, if the liquid, flowing in the transfer pipe, is changed from the second temperature to a third temperature greater than the second temperature by the air blowing fan, making the liquid of the third temperature reduced to the liquid tank.

Description

Cooling system using liquefied oxygen {COOLING SYSTEM USING LIQUEFIED OXYGEN}

The present invention relates to a cooling system using liquefied oxygen, and more particularly, liquefied oxygen generated when cooling air is directly generated using liquefied oxygen as cooling air is generated using a liquid cooled by liquefied oxygen. It relates to a cooling system using liquefied oxygen capable of preventing freezing of a conveying pipe.

In general, a cooling device maintains the indoor air temperature at a low temperature using a cooling cycle, and performs a cool air function while discharging the liquid oxygen (LOX) filled in an oxygen container to the outside in a cooled state. do.

A conventional cooling device includes a body for discharging cooled oxygen and an oxygen container for supplying cooled oxygen gas to the body.

The main body discharges oxygen gas provided from the oxygen container through a cold air blower formed at the upper end. The oxygen container is installed inside or independently installed outside the main body to store the light blue liquid oxygen compressed to a temperature of -183°C or less, and provides the liquid oxygen through a transfer pipe.

Inside the main body, a transfer pipe connected to the oxygen container is connected to one end of an opening/closing control device that controls the output amount of oxygen gas, and a discharge pipe facing the air outlet is connected to the other end of the opening/closing control device, and oxygen gas discharged through the discharge pipe. The blower fan is configured so that the blower is radiated through the air vent.

Looking at the operation of the cooling device configured as described above, first, the opening valve of the oxygen container is opened to evaporate liquefied oxygen, thereby maintaining the atmospheric state supplied to the opening/closing control device of the main body through the transfer pipe.

After that, when the opening/closing control device is opened, the cooled oxygen gas is discharged through the discharge pipe, and at the same time, the blowing fan rotates and very strong cold air is discharged through the ventilation opening.

However, in the cooling device according to the prior art, as the cooled oxygen gas directly moves along the conveying pipe and circulates around the blowing fan, the temperature of the conveying pipe decreases, resulting in a phenomenon in which frost is trapped in the conveying pipe. Since the conveying pipe around the fan is continuously exposed to the wind by the blowing fan and has a lower temperature, there is a problem in that the inner pipe is frozen.

Korean Patent Publication No. 10-2018-0119409 (published on November 2, 2018)

Therefore, the present invention was derived to solve the above-described problem, and the present invention is a liquefaction that occurs when cooling air is directly generated using liquefied oxygen as cooling air is generated using a liquid cooled by liquefied oxygen. An object thereof is to provide a cooling system using liquefied oxygen that can prevent freezing of an oxygen transfer pipe.

In addition, the present invention provides a cooling system using liquefied oxygen that can prevent freezing of the conveying pipe by allowing oxygen gas to heat exchange in the water tank to cool the liquid in the water tank, and to form cooling air using the cooled liquid. It has its purpose to provide.

In addition, the present invention provides a cooling system using liquefied oxygen capable of controlling the oxygen storage container to be opened or closed by checking the temperature of the oxygen gas transfer pipe, and controlling the oxygen concentration to be maintained. There is a purpose.

Other objects of the present invention will become more apparent through examples described below.

A cooling system using liquefied oxygen according to an aspect of the present invention includes an oxygen storage container for storing liquefied oxygen; A liquid tank in which an empty space is formed and a liquid of a first temperature is filled in the empty space; The liquid is cooled to a second temperature lower than the first temperature through liquefied oxygen disposed in the liquid water tank and discharged from the oxygen storage container, and vaporized oxygen vaporized from the liquefied oxygen is externally cooled by cooling the liquid. A heat exchanger discharged to the furnace; A transfer pipe for transferring the cooled liquid of the second temperature; A blowing fan installed in the vicinity of the transfer pipe and cooling the surrounding air by the cooled liquid of the second temperature flowing along the transfer pipe to supply cooling air to the outside; And when the liquid having a second temperature, which is connected between the transfer pipe and the liquid tank, is converted to a third temperature higher than the second temperature by the blowing fan, the liquid of the third temperature is transferred to the liquid tank. It includes a reducing tube to reduce to.

The cooling system using liquefied oxygen according to the present invention may have one or more of the following embodiments.

For example, further comprising first and second submersible motors installed in the liquid bath and controlling a flow of liquid filled in the liquid bath, wherein the first submersible motor allows the liquid to flow in the direction of the heat exchanger. By controlling the liquid to be cooled by the heat exchanger, the second submersible motor may control the cooled liquid to flow into the transfer pipe.

For example, a liquid measurement sensor that is disposed on the inner side of the liquid tank and senses the amount of liquid filled in the liquid tank, compares the amount of the sensed liquid with a preset reference liquid amount, and provides a liquid shortage notification. Can include.

For example, it may further include a load sensor disposed below the oxygen storage container, measuring the weight of the liquefied oxygen stored in the oxygen storage container, and providing a notification of insufficient liquefied oxygen.

For example, it may further include a temperature sensor installed near the transfer pipe, sensing the temperature of the transfer pipe and closing the oxygen storage container when the temperature is lower than a preset temperature.

For example, the heat exchanger includes an inlet for introducing the liquefied oxygen, an outlet for discharging the vaporized oxygen, a coil disposed to correspond to the flow of the liquefied oxygen, a heat sink disposed along the outer periphery to recover heat, and the coil It may contain a coolant to be frozen by.

For example, the heat exchanger may be connected to an intake silencer for reducing noise generated when discharging the vaporized oxygen.

For example, the intake silencer includes a housing and a resistance plate disposed to cross each other at a predetermined interval within the housing, and when the vaporized oxygen is discharged, the flow rate of the vaporized oxygen is reduced by the resistance plate to reduce noise. Can be reduced.

For example, the blowing fan is installed in each of the front and rear of the conveying pipe based on the conveying pipe, and the blowing fan installed in the front and the blowing fan installed in the rear are installed to face opposite directions. Cooling air may be supplied in both directions, or the blowing fan installed in the front and the blowing fan installed in the rear may be installed to face the same direction, thereby increasing the strength of the cooling air supplied in one direction.

The cooling system using liquefied oxygen according to the present invention provides the following effects.

The present invention has an effect of preventing freezing of a liquefied oxygen transfer pipe that occurs when cooling air is directly generated using liquefied oxygen as cooling air is generated using a liquid cooled by liquefied oxygen.

The present invention has the effect of preventing freezing of the conveying pipe by allowing oxygen gas to heat exchange in the water tank to cool the liquid in the water tank, and to form cooling air using the cooled liquid.

The present invention has the effect of checking the temperature of the oxygen gas transfer pipe to determine whether to open or close the oxygen storage container, and to control the oxygen concentration to be maintained by detecting the oxygen concentration.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a schematic diagram showing a cooling system using liquefied oxygen according to the present invention.
2 is a diagram showing a heat exchange structure of a cooling system using liquefied oxygen according to the present invention.
3 is a perspective view showing a heat exchanger of a cooling system using liquefied oxygen according to the present invention.
4A to 4C are views showing a blowing fan and a conveying pipe of a cooling system using liquefied oxygen according to the present invention.
5 is a cross-sectional view illustrating the structure of an intake silencer of a cooling system using liquefied oxygen according to the present invention.

In the present invention, various transformations may be applied and various embodiments may be provided, and specific embodiments will be illustrated in the drawings and will be described in detail in the detailed description. However, this is not intended to limit the present invention to a specific embodiment, it should be understood to include all conversions, equivalents, and substitutes included in the spirit and scope of the present invention. In describing the present invention, when it is determined that a detailed description of a related known technology may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof does not preclude in advance.

Terms such as first and second may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another component.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings. In the description with reference to the accompanying drawings, the same or corresponding components regardless of the reference numerals are given the same reference numerals, and duplicates thereof. Description will be omitted.

Hereinafter, a cooling system using liquefied oxygen according to embodiments of the present invention will be described in detail with reference to FIGS. 1 to 5.

1 is a schematic diagram showing a cooling system using liquefied oxygen according to the present invention, FIG. 2 is a diagram showing a heat exchange structure of a cooling system using liquefied oxygen according to the present invention, and FIG. 3 is a liquefied oxygen according to the present invention. Is a perspective view showing a heat exchanger of a cooling system using, and FIGS. 4A to 4C are views showing a blowing fan and a conveying pipe of a cooling system using liquefied oxygen according to the present invention, and FIG. 5 is a diagram illustrating a liquefied oxygen according to the present invention. It is a cross-sectional view illustrating the structure of the intake silencer of the used cooling system.

As shown in FIGS. 1 to 5, the cooling system 100 using liquefied oxygen according to the present invention may be largely composed of a main body 10 and an oxygen storage container 110.

The main body 10 forms a certain space therein, and the liquid tank 120, the heat exchanger 130, the transfer pipe 140, the blowing fan 150, the reduction pipe 160, the first and The second underwater motors 170a and 170b, a liquid measurement sensor 180, and an intake silencer 190 may be included.

The main body 10 includes a cold air outlet 12 formed at an upper end and an air intake 11 formed at a lower end. The body 10 may discharge oxygen gas cooled through the cold air outlet 12 to the outside, and may suck in external air through the air inlet 11. Here, the cold air outlet 12 and the air inlet 12 are formed of a plurality of blades, and angles of the air in and out of the air may be varied by adjusting the angles of each of the blades.

The oxygen storage container 110 may be provided inside or separately provided outside the body 10.

The oxygen storage container 110 is a container for storing liquefied oxygen obtained by compressing oxygen to a temperature of minus 183°C or less, and may be connected to the opening/closing valve 111 and the gas discharge port 112 at the top. When the opening/closing valve 111 is opened, the oxygen storage container 110 discharges the filled liquefied oxygen to the outside. Will be discharged.

The gas outlet 112 connected to the oxygen storage container 110 is configured to be connected to an opening/closing control device (not shown). The opening/closing control device includes a physically variable valve capable of adjusting the supply amount of oxygen gas discharged by an electric signal.

The oxygen storage container 110 may be connected to the heat exchanger 130 by passing through the liquid tank 120 through an inlet pipe 13 in which an opening/closing control device is installed. Oxygen gas stored in the oxygen storage container 110 may be introduced into the inlet 131 of the heat exchanger 130 through an opening/closing control device.

In one embodiment, the present invention may further include a load sensor (not shown) disposed below the oxygen storage container 110 to measure the weight of liquefied oxygen stored in the oxygen storage container 110. The load sensor is set as a reference point with the weight of the oxygen storage container 110 in which liquefied oxygen is not stored as a zero point, and the residual degree of liquefied oxygen by measuring the weight of the oxygen storage container 110 after liquefied oxygen is stored. Can be checked. If the weight of the oxygen storage container 110 is within a preset error range from the reference point, the load sensor may determine that the liquefied oxygen stored in the oxygen storage container 110 is insufficient and provide an alarm. The load sensor is configured to allow the user to recognize the replacement timing of the oxygen storage container 110, and for example, the load sensor may be implemented as a load cell.

The liquid tank 120 is formed in an approximately rectangular shape, and is formed so that all surfaces are closed, and an empty space is formed therein, so that a liquid may be filled in the internal space. The liquid to be filled in the liquid tank 120 may be general water (H2O) or may be made of a special coolant that facilitates cooling. When the liquid is initially filled in the liquid tank 120, the liquid may have a first temperature, and the temperature may be varied by the heat exchanger 130 and the reduction tube 160 during the cooling process.

In one embodiment, the liquid tank 120 may be equipped with a liquid measurement sensor 180 that senses the amount of liquid. The liquid measurement sensor 180 is disposed on the inner side of the liquid tank 120 to sense the amount of liquid filled in the liquid tank 120, and compares the sensed amount of liquid with a preset reference liquid amount to notify the lack of liquid. Can provide. The liquid shortage notification may be provided as a screen that can be visually checked on the main body 10 or as an alarm alarm that can be checked audibly.

For example, the liquid measurement sensor 180 may be composed of a plurality of sensors installed at predetermined intervals on one side of the inner wall of the liquid tank 120. The liquid measurement sensor 180 may be formed of a sensor array arranged in a row in the height direction of the liquid tank 120, and may use a sensor having an output voltage decrease according to an increase in temperature. The liquid measurement sensor 180 generates a constant output voltage according to the temperature of the liquid in the liquid portion and the phenomenon of generating a remarkably low output voltage in the liquid-free portion, the transient voltage occurring at the boundary portion. You can measure the current height of the liquid, i.e. the amount of liquid.

The liquid tank 120 may have one end of the transfer pipe 140 and one end of the reduction pipe 160 so as to be positioned lower than the height of the liquid. Here, as one end of the transfer pipe 140 and one end of the reduction pipe 160 are located spaced apart from the lowermost end surface of the liquid tank 120, suction and discharge of the liquid can be easily performed.

The liquid tank 120 has a heat exchanger 130, a first submersible motor 170a, and a second submersible motor 170b therein, and the internal liquid temperature is varied by the heat exchanger 130, and The liquid inside may flow by the first and second underwater motors 170a and 170b.

The first and second underwater motors 170a and 170b control the flow of the liquid filled in the liquid tank 120 and may circulate the liquid at a preset pressure and speed.

The first submersible motor 170a controls the liquid in the liquid tank 120 to flow in the direction of the heat exchanger 130 so that the liquid of the first temperature is lower than the first temperature by the heat exchanger 130. It may be cooled to a liquid, and may serve as a stirrer for the liquid in the liquid bath 120.

The second underwater motor 170b is connected to one end of the transfer pipe 140 disposed in the liquid tank 120 to control the liquid of the second temperature to flow to the transfer pipe 140. When controlling the liquid to flow into the transfer pipe 140, the second underwater motor 170b may form a pressure of a predetermined size or more so that the liquid is reduced to the reduction pipe 160 through the transfer pipe 140.

That is, the liquid in the liquid tank 120 may continuously circulate the liquid tank 120, the transfer pipe 140, and the reduction pipe 160, and the cooling air is transferred to the outside by the blowing fan 150 during the circulation process. Can be supplied.

The heat exchanger 130 is disposed in the liquid tank 120 and receives liquefied oxygen from the oxygen storage container 110 to cool the liquefied oxygen. That is, the heat exchanger 130 cools the liquefied oxygen gas discharged from the oxygen storage container 110 to cool the liquid filled in the liquefied water tank 120 to a second temperature lower than the first temperature, and liquefies the liquid according to cooling of the liquid. Vaporized oxygen vaporized from oxygen gas can be discharged to the outside.

In one embodiment, referring to FIG. 3, the heat exchanger 130 has an inlet 131 through which liquefied oxygen discharged from the oxygen storage container 110 flows in, and the liquefied oxygen discharges the vaporized oxygen gas vaporized during the heat exchange process. It may include a discharge port 132, a coil 133 disposed to correspond to the flow of liquefied oxygen, a heat sink 134 disposed along the outer periphery to recover heat, and a coolant 135 rapidly frozen by the coil.

Here, the inlet 131 may be connected to the oxygen storage container 110 through the inlet pipe 13, and the discharge port 132 may be formed to face the outside through the discharge pipe 14. The coil 133 may have a hollow formed therein so that liquefied oxygen may flow through the hollow, or may be disposed near a tube through which liquefied oxygen flows, and thus may be cooled by liquefied oxygen.

The heat exchanger 130 can cool the liquid of the first temperature in the liquid tank 120 to a second temperature lower than the first temperature by the coolant 135 frozen by the coil 133 and at the same time, the coolant ( As the heat of the liquid filled in the liquid tank 120 is received from the heat sink 134 cooled by 13), the liquid having the first temperature may be cooled to a second temperature lower than the first temperature.

The heat exchanger 130 may be connected to an intake silencer 190 for reducing noise generated when discharging vaporized oxygen, that is, gas through the discharge port 132.

Referring to FIG. 5, the intake silencer 190 is made to include a housing 191 forming an exterior and a resistance plate 192 disposed to cross each other at predetermined intervals within the housing 191, and During discharge (flow in the F direction), the flow rate of vaporized oxygen is reduced by the resistance plate 192 to reduce noise.

On the other hand, the intake silencer 190 can be of any shape as long as it has a structure capable of reducing the noise of the gas, for example, a method of increasing the resistance value by the through hole when the gas exits, including a plurality of through holes ( Injecting method), a method of increasing the resistance value according to the difference in the size of the hollow when the gas exits by varying the size of the internal hollow may be formed in a structure capable of.

The transfer pipe 140 may have one end disposed in the liquid tank 120 and the other end connected to the reduction tube 160 to transfer the liquid in the liquid tank 120. The transfer pipe 140 may be formed in a straight line or a curved shape, and in particular, in the vicinity of the blowing fan 150 may be formed in a curved shape to increase the supply efficiency of cooling air.

In one embodiment, the present invention may further include a temperature sensor (not shown) installed near the transfer pipe 140 to sense the temperature of the transfer pipe 140. The temperature sensor senses the temperature of the transfer pipe 140 and controls to close the oxygen storage container 110 when the temperature of the transfer pipe 140 is lower than a preset temperature. This is to stop the supply of liquefied oxygen for cooling the liquid in order to prevent the occurrence of frost and freezing in the transfer pipe 140 because the cooled liquid of the second temperature flows through the transfer pipe 140. For example, the temperature sensor may be made of a non-contact sensor so as to be less affected by the temperature of the transfer pipe 140.

The blowing fan 150 is installed in the vicinity of the transfer pipe 140 and the reduction pipe 160, and provides air to the transfer pipe 140 by the cooled second temperature liquid flowing along the transfer pipe 140. The ambient air may be cooled, and the cooled air may be supplied to the outside through the cold air outlet 12.

The blowing fan 150 may adjust the intensity of the wind according to the user's control, and the amount of cooled air supplied to the outside may vary according to the intensity of the wind.

The blower fan 150 may be configured in plural, and may be disposed at the front and rear sides of the transfer pipe 140 based on the inner front and rear surfaces of the main body 10, that is, the transfer pipe 140.

As shown in FIG. 4B, when the blowing fan 150a installed in the front and the blowing fan 150b installed in the rear are installed to face opposite directions, cooling air may be supplied to both the front and rear directions of the main body 10, respectively. I can. In this case, the main body 10 may include cold air vents 12 at both the front and rear sides, and may be implemented to enable cold air in both directions.

As shown in Fig. 4c, when the blowing fan 150a installed in the front and the blowing fan 150b installed in the rear are installed to face the same direction, cooling air is supplied only to the front of the main body 10, It can increase the strength of the cooling air.

The reduction pipe 160 is connected between the transfer pipe 140 and the liquid tank 120, and the liquid of the second temperature flowing through the transfer pipe 140 is at a third temperature higher than the second temperature by the blowing fan 150 When converted to, the liquid of the third temperature can be reduced to the liquid bath 120. The first temperature, the second temperature, and the third temperature mentioned in the present invention do not limit the exact temperature values, and are simply described as having a second temperature lower than the first temperature and a third temperature higher than the second temperature.

Meanwhile, the transfer pipe 140 and the reduction pipe 160 have been described separately for convenience when describing the present invention, but may be viewed as one configuration.

In one embodiment, the present invention may further include an oxygen sensor (not shown) for sensing the oxygen concentration in the room. The oxygen sensor may be provided in the main body 10 and may be used to maintain a certain amount of oxygen based on the sensed oxygen concentration value. In the present invention, the output amount of the opening/closing control device may be adjusted so that the oxygen concentration value sensed by the oxygen sensor corresponds to a preset oxygen concentration.

Although the above has been described with reference to an embodiment of the present invention, those of ordinary skill in the relevant technical field can use the present invention in various ways within the scope not departing from the spirit and scope of the present invention described in the following claims. It will be appreciated that it can be modified and changed.

100: cooling system using liquefied oxygen
110: oxygen storage container
120: liquid bath
130: heat exchanger
140: transfer pipe
150: blower fan
160: reduction tube
170a: first submersible motor
170b: second submersible motor
180: liquid measurement sensor
190: intake silencer
10: main body

Claims (9)

An oxygen storage container for storing liquefied oxygen;
A liquid tank in which an empty space is formed and a liquid of a first temperature is filled in the empty space;
The liquid is cooled to a second temperature lower than the first temperature through liquefied oxygen disposed in the liquid tank and discharged from the oxygen storage container, and vaporized oxygen vaporized from the liquefied oxygen is removed from the outside according to the cooling of the liquid. A heat exchanger discharged to the furnace;
A transfer pipe for transferring the cooled liquid of the second temperature;
A blowing fan installed in the vicinity of the conveying pipe and cooling the surrounding air by the cooled liquid of the second temperature flowing along the conveying pipe to supply cooling air to the outside; And
When the liquid of a second temperature, which is connected between the transfer pipe and the liquid tank, is converted to a third temperature higher than the second temperature by the blowing fan, the liquid of the third temperature is transferred to the liquid tank. Containing a reducing tube to reduce
Cooling system using liquefied oxygen. The method of claim 1,
It is installed in the liquid tank, further comprising first and second underwater motors for controlling the flow of the liquid filled in the liquid tank,
The first submersible motor controls the liquid to flow in the direction of the heat exchanger so that the liquid is cooled by the heat exchanger,
The second submersible motor controls the cooled liquid to flow into the transfer pipe.
Cooling system using liquefied oxygen. The method of claim 1,
Further comprising a liquid measurement sensor disposed on the inner side of the liquid tank to sense an amount of liquid filled in the liquid tank, and to provide a liquid shortage notification by comparing the sensed amount of liquid with a preset reference liquid amount.
Cooling system using liquefied oxygen. The method of claim 1,
Further comprising a load sensor disposed under the oxygen storage container and measuring the weight of the liquefied oxygen stored in the oxygen storage container to provide a notification of insufficient liquefied oxygen.
Cooling system using liquefied oxygen. The method of claim 1,
Further comprising a temperature sensor installed near the transfer pipe and configured to close the oxygen storage container when the temperature of the transfer pipe is lower than a preset temperature by sensing the temperature of the transfer pipe.
Cooling system using liquefied oxygen. The method of claim 1,
The heat exchanger
Including an inlet for introducing the liquefied oxygen, an outlet for discharging the vaporized oxygen, a coil disposed to correspond to the flow of the liquefied oxygen, a heat sink disposed along an outer circumference to recover heat, and a coolant frozen by the coil doing
Cooling system using liquefied oxygen. The method of claim 1,
The heat exchanger
Connected to an intake silencer to reduce noise generated when discharging the vaporized oxygen
Cooling system using liquefied oxygen. The method of claim 7,
The intake silencer is
Including a resistance plate disposed to cross each other at a predetermined interval in the housing and the inside of the housing to reduce the noise by reducing the flow rate of the vaporized oxygen by the resistance plate when the vaporized oxygen is discharged.
Cooling system using liquefied oxygen. The method of claim 1,
The blower fan
The cooling air is supplied in both directions by installing a blower fan installed at the front and a blower fan installed at the rear to each of the front and rear sides of the transport pipe based on the transport pipe. Or, by installing the blowing fan installed in the front and the blowing fan installed in the rear facing the same direction to increase the strength of the cooling air supplied in one direction
Cooling system using liquefied oxygen.

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