RU187505U1 - Space or ground vehicle cooling system - Google Patents

Abstract

The utility model relates to the placement and modification of devices for controlling the temperature of a spacecraft (B64G 1/50), as well as to refrigerators using electric or magnetic effects (F25B 21/00). The cooling system of a spacecraft or ground vehicle includes a covering surface of the spacecraft connected to a current source, a grid of conductors with low resistance, with small parallelogram-shaped cells on the surface of the grid, with some of the conductors located on the heated side of the spacecraft, and part on its cold side. In addition, on the cold side of the apparatus, a grid of conductors is located with a gap between it and the apparatus body. 1 s.p. f-ly, 3 ill.

Description

The utility model relates to the placement and modification of devices for controlling the temperature of a spacecraft (IPC: B64G 1/50), as well as to refrigerators using electric or magnetic effects (IPC: F25B 21/00).

Known panel of the refrigerator-emitter (according to the patent for the invention of the Russian Federation No. 2610732, according to the application 2015151478 dated 12/12/2015, B64G 1 | 50, F28F 3/00), containing a heat-emitting plate made of composite material and metal tubes for the coolant, located between the heat-emitting a plate and plates of composite material, each plate is connected to the plate and contains a section whose shape corresponds to the shape of a metal tube, characterized in that cylindrical grooves are made in the heat-emitting plate, in which the metal The heat transfer tubes, linings, and the heat-emitting plate are made of carbon-carbon composite material; the heat-emitting plate contains holes located between the tubes in which carbon fibers with a thermal conductivity of more than 300 W / mK are stretched. In addition, the space between the patch and the metal tube, as well as the heat-emitting plate and the metal tube, is filled with highly conductive grease. In addition, the metal tubes are made of aluminum, or copper, or steel. In addition, carbon fibers with high thermal conductivity in the form of parallel continuous filaments, or tapes, or fabric, or mesh are used in the carbon-carbon composite material. In addition, carbon fibers, stretched in the holes of the plate, made in the form of threads, or bundles, or ribbons, or fabric, or mesh. In addition, the panel is equipped with a stiffener.

The disadvantages of the panel are the large weight of the tubes with refrigerant, which make the structure heavier, as well as the disordered movement of the main electron carrier along the fibers, which is not stimulated by anything other than the temperature difference.

Known space telescopic refrigerator-emitter (according to the patent for the invention of the Russian Federation No. 2562006, according to the application No. 2014109336/11 of 03/11/2014, B64G 1/50, B64G 1/22, F28F 3/02), made hollow with the possibility of placement in of spacecraft (SC) elements and consisting of sliding hollow sections, including docking units that provide mechanical docking of the sections themselves, as well as, respectively, docking units for connecting hydraulic, pneumatic and electrical communications of adjacent sections of a space telescopic refrigerator-emit For their separation, characterized in that each sliding section of the space telescopic refrigerator-emitter is equipped with two 180 ° rotatable rigid heat-emitting panels connected by turning units respectively, while said heat-radiating panels repeat the shape of the sliding section and are laid in the starting position on its surface. In addition, each sliding section is equipped with two rotatable 180 ° rigid heat-emitting panels, each of which is made of at least two segments interconnected pivotally.

The disadvantages of the refrigerator-emitter are the large weight of the tubes with refrigerant, and as the screen area increases, the likelihood of a meteorite falling into it, a piece of space debris or a bullet increases, as a result of which the refrigerant will leak out and put the cooling system out of operation.

Known drip cooler-emitter (according to the patent for the invention of the Russian Federation No. 2401778, according to the application 2009142377/11 of 11/17/2009, B64G 1/50, F28D 21/00), containing a storage system and supply of a coolant, a droplet generator with an element for exciting acoustic vibrations and an output grate, a passive droplet collector with slotted channels, a transfer pump, pipelines, heaters of structural elements and a thermal stabilization system, characterized in that the slotted channels of the passive droplet collector are provided with separate coolant supply lines containing each on-off valve and an automatic flow regulator, and the transfer pump is additionally equipped with a bypass circuit with an automatic flow regulator, while the automatic flow controllers installed on the inputs of the slotted channels and in the bypass circuit of the transfer pump, as well as in the drop generator circuit, are connected through the recording unit and controls with optical sensors installed: one in the vicinity of the neck of the collector of drops, the other at a distance of at least fivefold the distance between the centers of the droplets in the direction of their movement, and the opening angle of the droplet collector is 40-70 °.

The disadvantages of the refrigerator-emitter are the large weight of the pipelines for droplet movement, a pump, a droplet generator, and there is also the possibility of a meteorite falling into it, a piece of space debris or a bullet, as a result of which the refrigerant will leak out and put the cooling system out of operation.

Known coating material with high emissivity (according to the patent for the invention of the Russian Federation No. 2262552, according to the application No. 2004-100434 / 02 of 01/15/2004, С24С 24/04, С23С 26/00), containing nickel-chromium spinel NiCr ₂ O ₄ , characterized in that it additionally contains titanium carbide TiC in the following ratio of components, wt. %:

Nickel Chrome Spinel NiCr ₂ O ₄ 90-92 Titanium Carbide TiC 8-10

The disadvantages of the coating material are not discussed, its use is proposed.

The ceramic solar screen of the Messenger spacecraft that studied Mercury is known (I. Sobolev Farewell to Mercury / /. Cosmonautics News, 2015, issue 6, pp. 59-61), which protected onboard equipment and scientific instruments from the incinerating radiation of the Sun: the outer surface was heated to 300 ° C, but in the shadow behind the shield the temperature + 20 ° C was comfortable for the equipment.

The disadvantage of the screen is protection against external radiation, it does not protect from heat from inside the device.

The technical result of the utility model is the creation of a device for a cooling system of a space or ground vehicle that is resistant to the ingress of a meteorite, a fragment of space debris or a bullet.

This technical result is achieved in that the cooling system of a spacecraft or ground vehicle includes a covering surface of the spacecraft connected to a current source, a grid of conductors with low resistance, with small parallelogram-shaped cells on the surface of the grid, while some of the conductors are located on the heated side of the spacecraft, and part - on his cold side.

In addition, on the cold side of the apparatus, a grid of conductors is located with a gap between it and the apparatus body.

Description of figures.

The figures show the following materials.

In FIG. 1 - a grid of conductors on the surface of the apparatus, in FIG. 2 - a grid of conductors damaged by a meteorite, a fragment of space debris, or a bullet; in FIG. 3 - damage from a meteorite, a fragment of space debris or a bullet covering from parallel conductors without a grid.

The numbers on the figures indicate the following objects:

In FIG. 1 and lower: 1 - the first row of parallel conductors, 2 - the first row of conductors crossing at an acute angle, the second row of parallel conductors, 3 - parallelogram-like gaps between the conductors of the first and second row, 4 - wires leading voltage from the source to the conductors of the first and second row current, 5 - normal directions of current flow in the conductors of the first and second row.

In FIG. 2, 3: 6 - a hole from a meteorite, a fragment of space debris or a bullet, 7 - emergency directions of the current flow in the conductors of the first second row, 8 - dead ends of wires in which no current flows.

The cooling system consists of two rows of conductors 1 and 2 (Fig. 1), intersecting at an acute angle with the formation of rhomboid or parallelogram-shaped gaps between them 3. In one place, the correctness of rows 1 and 2 is violated - where the voltage is connected to conductors 1 and 2, on conductors 4 (Fig. 1), which lead to the poles of the apparatus current source. A network of conductors 1, 2 wraps the casing of the device on all sides except for the point of connection of conductors 4, each conductor of the first row is almost closed to itself, there is a gap only at the point of connection of wires 4, so each conductor of the second row is almost closed to itself with a gap in place connecting wires 4. In the absence of damage, current flows in directions 5 along the rows of conductors. In the event of a hole 6 from a meteorite, a fragment of space debris or a bullet, the current cannot flow through the hole and changes direction 7 near the hole, flowing around it. The effect of flowing around the hole would not have been observed when the conductors were arranged in one parallel row, then dead ends of wires 8 would have formed, in which no current flows, cooling would not have been carried out along the interrupted wires.

Cooling is due to the Thompson effect. Each conductor of rows 1 and 2 starts on the heated side, continues on the cold side and returns to the heated side. When switching from the heated side of the apparatus to the cold, the electrons give their heat to the atoms of the conductor, which radiate it into the surrounding space. When switching from the cold side of the apparatus to the heated one, the electrons take away heat from the atoms of the more heated conductor. The conductors of both rows can be made of an alloy of two metals, very different in atomic mass, with a predominance of the number of atoms of a lighter metal. This will allow, according to the author, to intensify the heat transfer process.

The temperature gradient is created differently at different operating distances from the Sun or another star to which the spacecraft flew. At distances of the order of the radius of the Earth’s orbit, it makes sense to use a shading shield made of ceramics. Under the shield, a temperature gradient is created due to the internal heat of the apparatus. One half of the case is made of a material that does not conduct heat well, such as ceramics, and it has a cold temperature above it. The second half of the case is made of a material that is well conductive of heat, for example, of metal, and there is a high temperature above it. At distances from the Earth’s orbit to the asteroid belt, it’s also advisable to use the temperature difference between the side of the spacecraft heated by the Sun and the cold shaded side of the spacecraft. In this case, the side that is heated by internal heat should be turned towards the Sun or another star so as not to smooth out the temperature gradient on the surface of the device. At distances farther than the asteroid belt, it makes no sense to use a cooling system, since it is already quite cold there. Heated and cooled zones can shift with the position of the Sun or another star relative to the apparatus, since the conductors of the first and second row are uniform throughout the length. If there is a zone of constant shading, for example, under the bottom of the device, facing the surface of a planet or an asteroid, above this zone the conductors do not contact the body of the device from which heat is removed, and form a gap between the network of conductors and the body of the device to increase the heat transfer area radiation of cooling conductors due to the area of the lower surface of the conductors.

When crossing the conductors of the first and second row at an acute angle, the current in each row has a component parallel to the direction of the current flow in the other row, which reduces the resistance at the intersection of the conductors. With the perpendicular arrangement of the conductors of rows 1 and 2, the currents would be perpendicular to each other and would prevent each other from flowing.

The cooling system is proposed for spacecraft, but can also be applied to ground vehicles, for example, in hot desert conditions. Conductors on the side of the apparatus heated by the Sun can be coated with a material with high emissivity, described in the prior art.

Claims (2)

1. The cooling system of a spacecraft or ground vehicle, including the covering surface of the spacecraft, connected to a current source, a grid of conductors with low resistance, with small parallelogram-shaped cells on the surface of the grid, while some of the conductors are located on the heated side of the device, and some on the cold side side. 2. The cooling system of a space or ground vehicle according to claim 1, characterized in that on the cold side of the spacecraft a grid of conductors is located with a gap between it and the body of the spacecraft.

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