KR101282703B1 - Space Simulator - Google Patents

Abstract

The space environment simulation apparatus of the present invention has a shroud forming a cryogenic space in order to simulate the interior of the thermal vacuum chamber by the injection of LN2, an LN2 storage tank for supplying the LN2 to the shroud, and a vacuum inside the thermal vacuum chamber. Low vacuum pump to make a state, a low temperature pump to make the temperature inside the thermal vacuum chamber to a cryogenic state, a helium compressor connected to the low temperature pump to supply the cooled and compressed helium to the low temperature pump, the low vacuum pump and A cooling water tank for supplying a cooling fluid to cool the helium compressor, and a cooling device for cooling the cooling fluid of the cooling water tank, wherein the cooling device uses the LN2 from the LN2 discharge pipe of the shroud. The cooling fluid of the tank is characterized in that for cooling.

Description

Space Simulator

The present invention relates to a space environment simulation equipment, by making the inner shroud of the thermal vacuum chamber to cryogenic temperature using LN2 to arbitrarily create a space environment, the space for cooling the cooling water for cooling the pump of the thermal vacuum chamber using the waste LN2 Environmental simulation equipment.

The space environment is a high vacuum environment, a high temperature environment caused by solar radiation, and a harsh environment where cryogenic temperatures are repeated.

Satellites continue to be exposed to the space environment from the moment they are launched from the ground and enter the orbit, and these harsh space environments can cause malfunctions in major parts of satellites, which can lead to mission failure.

In other words, because the space environment is very different from the environment on earth, satellites observed to work properly on the ground may show unexpected dysfunctions in the space environment. This is a very important issue.

Therefore, satellites must check the function and operation state through space environment test on the ground, and for this purpose, space environment simulation equipment called thermal vacuum chamber is needed to simulate the space environment.

Torr 이하의 고진공으로 이루어질 수 있도록 진공펌프들을 구비하고, 열제어계는 -196℃ 이하의 우주 냉암흑을 모사하기 위해 액화질소(이하 'LN2'라 함)로 냉각되어지는 슈라우드(shroud)와 부대장치들을 구비한다.Generally, the vacuum chamber is divided into a vacuum system and a heat control system.

Vacuum pumps are provided to achieve a high vacuum of less than Torr, and the thermal control system is a shroud and ancillary apparatus cooled by liquid nitrogen (hereinafter referred to as 'LN2') to simulate space dark below -196 ℃. Equipped with.

This cosmic cold dark simulation is achieved by filling the cryogenic LN2 inside the shroud installed inside the thermal vacuum chamber.

The conventional cryogenic simplicity for a thermal vacuum chamber forms a certain space, a shroud that is injected with LN2 (liquid nitrogen) to form a cryogenic space that simulates a space environment, and recovers the LN2 filled in the shroud after a space environment simulation. LN2 storage tank for resupply, and the LN2 pump is located between the LN2 storage tank and the shroud to apply pressure to transport the LN2.

LN2 below -160 ° C is supplied from the LN2 storage tank to the shroud, and the inside of the vacuum chamber is cooled to -190 ° C by the temperature of LN2 supplied to the shroud to simulate the effect of space cold dark.

In addition, in order to create and maintain a vacuum inside the thermal vacuum chamber, a low temperature pump is required, and the low temperature pump maintains the vacuum inside the thermal vacuum chamber by using a helium compressor.

At this time, in order to operate the helium compressor normally, the cooling water is supplied and cooled, and in general, the cooling water is supplied from the cooling tower.

Accordingly, the temperature of the refrigerant in the cooling tower installed outside in the summer, the temperature rises, there was a problem in using the helium compressor.

In addition, there is a problem in that it is expensive to provide a separate cooling device for cooling the cooling water.

The background technology of the present invention is disclosed in Korean Unexamined Patent Publication No. 10-2005-0065945.

Republic of Korea Patent Publication No. 10-2005-0065945

In order to solve the above problems of the present invention, more specifically using the LN2 discharged from the space environment simulation apparatus to reduce the cost, to provide a space environment simulated value that can reduce the risk of emitting low-temperature LN2. I want to do that.

Space environment of the present invention is the LN2 is injected into the shroud to form a cryogenic space to simulate the interior of the thermal vacuum chamber into the space environment, the LN2 storage tank for supplying the LN2 to the shroud, the vacuum inside the thermal vacuum chamber Low vacuum pump to make a state, a low temperature pump to make the temperature inside the thermal vacuum chamber to a cryogenic state, a helium compressor connected to the low temperature pump to supply the cooled and compressed helium to the low temperature pump, the low vacuum pump and A cooling water tank for supplying a cooling fluid to cool the helium compressor, and a cooling device for cooling the cooling fluid of the cooling water tank, wherein the cooling device uses the LN2 from the LN2 discharge pipe of the shroud. The cooling fluid of the tank is characterized in that for cooling.

In addition, the cooling device is characterized in that the cooling fluid is installed in the cooling water inlet pipe flowing into the cooling water tank.

In addition, the cooling device includes a cooling plate, the LN2 discharge pipe is bent and attached to one side of the cooling plate, the cooling water inlet pipe is bent and attached to the other side is characterized in that the cooling fluid is cooled.

In addition, the cooling plate is characterized in that it is made of a metal with high thermal conductivity.

Space environment simulator of the present invention by using the LN2 discharged from the space environment simulator to cool the cooling water for cooling the low vacuum pump and helium compressor, thereby reducing the risk of lowering the low temperature LN2 To provide a space environment model.

1 is a schematic diagram of the space environment simulation apparatus of the present invention
Figure 2 is a schematic diagram showing an embodiment of cooling the cooling water of the present invention

Hereinafter, the technical idea of the present invention will be described more specifically with reference to the accompanying drawings.

However, the accompanying drawings are only examples to illustrate the technical idea of the present invention in more detail, and thus the technical idea of the present invention is not limited to the accompanying drawings.

The configuration and form of the space environment simulation apparatus 1000 of the present invention will be described with reference to FIG.

torr 이하의 진공상태를 만들고, -196℃이하의 우주 냉암흑을 모사하기 위해 LN2가스와 저온펌프(120)를 이용하여 극저온의 우주와 같은 환경을 모사해주는 장비이다. Space environment simulation apparatus 1000 of the present invention using a low vacuum pump 130 on the ground

It is a device that simulates the environment of cryogenic space by using LN2 gas and low temperature pump 120 to make a vacuum below torr and simulate space cold darkness below -196 ℃.

The space environment simulation apparatus 1000 is a thermal vacuum chamber 100, shroud 110, LN2 storage tank 150, low vacuum pump 130, low temperature pump 120, helium compressor 121, cooling water tank ( 140, and a cooling device 160.

The shroud 110 is injected with LN2 to form a cryogenic space in order to simulate the interior of the thermal vacuum chamber 100 into a space environment.

The LN2 storage tank 150 is a storage tank stored by the LN2 and serves to store the LN2 supplied to the shroud 110.

In addition, the LN2 storage tank 150 is introduced into the shroud through the LN2 injection pipe 151, and the LN2 is discharged through the LN2 discharge pipe 152 after cooling the shroud.

The low vacuum pump 130 gives a vacuum inside the thermal vacuum chamber 100.

The low temperature pump 120 makes the temperature inside the thermal vacuum chamber 100 in a cryogenic state.

The helium compressor 121 is connected to the low temperature pump 120 and supplies the cooled and compressed helium to the low temperature pump 120.

The cooling water tank 140 supplies cooling fluid to the low vacuum pump 130 and the helium compressor to cool the low vacuum pump 130 and the helium compressor.

In addition, the cooling water tank 140 is a cooling fluid discharge pipe 142 and the low vacuum pump 130 and the helium compressor 121 is supplied to the low vacuum pump 130 and the helium compressor 121. After cooling, the cooling fluid includes a cooling water inlet pipe 141 flowing back into the cooling water tank 140.

The cooling device 160 cools the cooling fluid of the cooling water tank 140 by using the LN2 from the LN2 discharge pipe 152, and may be installed in the cooling inlet pipe.

In order to simulate the space environment, LN2 is supplied from the LN2 storage tank 150 to the shroud 110, and thus the temperature inside the thermal vacuum chamber 100 is lowered to form a cryogenic space.

In this case, the low temperature pump 120 and the low vacuum pump 130 are used to form a cryogenic space of -190 ° C. inside the thermal vacuum chamber 100.

The helium compressor 121 compresses helium so that a gaseous helium is supplied to the low temperature pump 120 as a liquid helium, and the liquid helium becomes a gaseous helium in the low temperature pump 120. By absorbing heat, the temperature of the low temperature pump 120 is lowered, and the temperature of the thermal vacuum chamber 100 to which the low temperature pump 120 is attached is lowered to form a space in a cryogenic vacuum state.

That is, the temperature inside the thermal vacuum chamber 100 is lowered below the freezing point of water to condense the water vapor, the temperature is lowered and the freezing point condenses in the order of gas lower than water condensation inside the thermal vacuum chamber 100 The cryogenic hollow state is formed inside the thermal vacuum chamber 100.

At this time, the low vacuum pump 130 drops the pressure inside the thermal vacuum chamber 100 before operating the low temperature pump 120, a small amount of gas in the interior of the thermal vacuum chamber 100 It is preferred to use when remaining.

2, the form and structure of the cooling device 160 of this invention are demonstrated in detail.

The cooling device 160 is located in the coolant inlet pipe 141 and cools the fluid flowing in the coolant inlet pipe 141 using the LN2 discharge pipe 152 discharged after cooling the shroud 110. It is a device for cooling.

The cooling device 160 includes a cooling plate 161, the LN2 discharge pipe 152 is attached to one side of the cooling plate 161, the cooling water inlet pipe 141 is attached to the other side.

At this time, when the LN2 discharge pipe 152 and the cooling water inlet pipe 141 is attached to the cooling plate 161, it is preferable to be bent and formed in the attached position to maximize the area in contact with the cooling plate 161. Do.

In addition, the cooling plate 161 is preferably made of a metal such as copper having a high thermal conductivity.

Therefore, the cooling device 160 cools the cooling plate 161 by using the low LN2 in the LN2 discharge pipe 152, and cools the cooling water inlet pipe 141 attached to the cooling plate 161. By cooling, the cooling fluid flowing in the cooling water inlet pipe 141 is cooled.

The cooling fluid cooled through the cooling device 160 flows back into the cooling water tank 140, is discharged through the cooling water discharge pipe 142, and again the low vacuum pump 130 and the helium compressor 121. To cool.

Therefore, the space environment simulation apparatus 1000 of the present invention uses the LN2 discharged from the LN2 discharge pipe 152 to cool the low vacuum pump 130 and the coolant cooling the helium compressor 121, It provides a space environment simulation apparatus 1000 that can reduce costs and reduce the risk of releasing low-temperature LN2 into the atmosphere.

1000: Space Environment Simulator
100: thermal vacuum chamber 110: shroud
120: low temperature pump 121: helium compressor
130: low vacuum pump 140: cooling water tank
141: cooling water inlet pipe 142: cooling water discharge pipe
150: LN2 storage tank 151: LN2 injection tube
152: LN2 discharge pipe 160: cooling device
161: cold plate

Claims (4)

Shroud 110 to form a cryogenic space to the LN2 is injected to simulate the interior of the thermal vacuum chamber 100 into the space environment;
An LN2 storage tank 150 for supplying LN2 to the shroud 110;
Low vacuum pump to make the interior of the thermal vacuum chamber 100 in a vacuum state;
A low temperature pump 120 which makes the temperature inside the thermal vacuum chamber 100 in a cryogenic state;
A helium compressor (121) connected to the low temperature pump (120) to supply the cooled and compressed helium to the low temperature pump (120);
A cooling water tank (140) for supplying a cooling fluid to cool the low vacuum pump (130) and the helium compressor (121);
And a cooling device 160 for cooling the cooling fluid of the cooling water tank 140.
The cooling device 160 is a space environment simulation device, characterized in that for cooling the cooling fluid of the cooling water tank 140 by using the LN2 from the LN2 discharge pipe 152 of the shroud (100).
The method of claim 1,
The cooling device 160 is a space environment simulation apparatus, characterized in that the cooling fluid is installed in the cooling water inlet pipe 141 is introduced into the cooling water tank (140).
The method of claim 2,
The cooling device 160 includes a cooling plate 161, the LN2 discharge pipe 152 is bent and attached to one side of the cooling plate 161, the cooling water inlet pipe 141 is bent and attached to the other side Space environment simulation apparatus characterized in that the cooling fluid is cooled.
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