RU2471685C1 - Installation for vacuum thermocycling of photoconverter panels - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: invention relates to space hardware testing, namely to installations for simulation of spacecraft components operation modes. Installation for vacuum thermocycling of photoconverter panels includes vacuum chamber consisting of two communicating compartments. In one compartment, two cryopanels are installed in parallel with possibility to place tested panel between them. In the second compartment there is thermal panel made as assembly of filament lamps. The cryopanels and thermal panel are positioned vertically, and thermal panel compartment is placed over cryopanel compartment. The cryopanels are installed with possibility of additional placement of thermal panel between them. The thermal panel is provided with reciprocating mechanism of vertical action and thermal insulation at the side facing cryopanel.

EFFECT: higher accuracy of thermal simulation of outer space conditions.

3 cl, 4 dwg

Description

The invention relates to tests of space technology, namely, to installations for simulating the thermal conditions of operation of elements of spacecraft, and can be used to test full-size, large-sized panels of photoconverters (FP) on the effects of thermal cycles.

The main requirement for installations for thermocyclic vacuum tests of typical photoconverter panels is a quick temperature change in the range from minus 190 ° C to plus 200 ° C.

Known vacuum thermal cycling plants have basically two configurations. The first installations are single-chamber, and temperature changes are realized by alternating operation of heaters and refrigerators, which are located in one chamber. Thermal cycling is carried out in tight contact and heat transfer between the test structure and the heater or refrigerator.

As an illustration, you can bring the well-known installations for vacuum thermal cycling, given in the descriptions to SU 573610, IPC ² F04B 37/14, G01N 3/18, SU 1508006, IPC ⁴ F04B 37/14.

A disadvantage of the known structures is the high inertia of the system during the establishment of thermal conditions associated with the inclusion and shutdown of the heating element. In addition, the known installations do not allow to test bulky products and, in particular, panels of spacecraft photoconverters.

The second - two-chamber with hot and cold temperature zones, in which the test product moves from the low-temperature zone with cryopanels to high-temperature with a thermal panel. Thermal cycling is carried out under conditions of thermal absorption and radiation. These include a device for thermocyclic testing of panels of photovoltaic batteries, described in the description of RU 2040076, IPC ⁶ H01L 31/18. It contains a vacuum chamber with two parallel flat cryopanels in the cold compartment and a heater in the form of a block of incandescent lamps in the hot compartment with one cryopanel, as well as with a rack mechanism for moving the test panel.

The disadvantages of the known device are the possibility of mechanical damage to the fragile test panels during their movement between temperature zones, the complexity of the movement mechanism and its placement in the vacuum chamber, the large horizontal dimensions of the installation, as well as the long time of vacuum pumping due to the large volumes of the vacuum chamber.

The present invention is based on the task of creating an installation for thermocyclic vacuum testing of photoconverter panels, which will achieve a technical result expressed in increasing the accuracy of thermal imitation of space conditions, the safety of the tested FP from mechanical damage, simplifying the design, reducing power consumption and reducing production space occupied installation.

The technical result is achieved in that in an installation for vacuum thermal cycling of photoconverter panels, including a vacuum chamber, consisting of two communicating compartments, in one of which two cryopanels are installed in parallel with the possibility of placing a test panel between them, in the other a thermal panel in the form of a block of incandescent lamps, moreover, the cryopanels and the thermal panel are located vertically, and the compartment of the thermal panel is located above the compartment of the cryopanels, which are installed with the possibility of additional placement between them of the thermal panel, while the latter is equipped with a mechanism for reciprocating movement in the vertical plane and thermal insulation from the side facing the cryopanel. The movement mechanism of the thermal panel can be made in the form of a geared motor controlled by a frequency drive. The cryopanel compartment can be made in the form of a horizontal cylindrical body.

The vertical arrangement of the cryopanels and the heat panel in the respective compartments one above the other allows not only to reduce the production space occupied by the installation, but also to reduce energy costs due to the reciprocating movement of the heat panel in the vertical plane, reducing the time of vacuum pumping and the rejection of the cryopanel in the heat compartment.

Providing the thermal panel with a movement mechanism and thermal insulation, as well as the possibility of placing it between the cryopanels and the panel under test, allow, firstly, to conduct thermal cycles when the panel under test is stationary, preventing mechanical damage. Secondly, in comparison with the prototype, eliminate the expensive auxiliary cryopanel, while reducing not only the cost of the installation, but also the energy consumption for thermal cycling in vacuum.

The execution of the mechanism in the form of a gear motor controlled by a frequency drive allows the thermal panel to be moved at a given speed, simulating a change in thermal conditions close to space orbits when the spacecraft moves from the shadow of the Earth and the Moon to the Sun and vice versa.

Figure 1 schematically shows a General view of the cross section of the installation for vacuum thermal cycling of FP panels in the "cooling" of the panel; figure 2 is a General view of a longitudinal section of the installation in the mode of "cooling" the panel; figure 3 is a General view of the cross section of the installation in the heating mode of the panel FP; figure 4 is a General view of a longitudinal section of the installation in the heating mode of the panel FP.

The apparatus for vacuum thermal cycling of FP panels contains a vacuum chamber consisting of a horizontal cylindrical compartment 1 with two vertical parallel cryopanels 2, 3 and compartment 4 in the form of a rectangular parallelepiped for accommodating the thermal panel 5. The rectangular housing of compartment 4 is mounted on the housing of cylindrical compartment 1 along the longitudinal generatrix , they communicate through a longitudinal groove corresponding to the dimensions of the thermal panel 5, and are hermetically connected. Cryopanels 2, 3 are installed in the compartment 1 at a distance that ensures the placement of the thermal panel 5 in the space between them and the tested panel FP 6.

The thermal panel 5 consists of sections of halogen lamps, is installed in the compartment 4 in a suspended position and is equipped with a mechanism 7 for vertical reciprocating movement in the space between one of the cryopanels, for example, cryopanel 2 and the test panel 6. The surface of the thermal panel 5 facing the cryopanel 2, equipped with thermal protection. The movement mechanism 7 is located outside the housing of the compartment 4 and can be made in the form of a gear motor controlled by a frequency drive.

Cryopanels 2, 3 are connected to the cooling system 8 for regulating the supply of cryogenic liquid.

The housing of the cylindrical compartment 1 from one end is connected to the evacuation system 9. From the other end, a door 10 is placed for loading and unloading the tested FP 6 panels.

The installation is equipped with sensors 11, 12 for monitoring the temperature on the tested surfaces of the panel FP 6.

Installation for vacuum thermal cycling works as follows.

The test panel ФП 6 is loaded through door 10 into compartment 1, placed between cryopanels 2, 3, and sensors 11, 12 are installed on it. Turn on the vacuum system 9. When the required vacuum is reached, turn on the cooling system 8. When the set negative temperature is reached, the reference time starts exposure panel FP 6 at a negative temperature.

For a certain time before the end of the exposure time at negative temperature, the thermal panel 5 is turned on at the rated power.

After exposure to a negative temperature, the mechanism 7 is turned on and the thermal panel 5 from compartment 4 is lowered at a predetermined speed, moving into compartment 1 into the space between the cryopanel 2 and the tested FP panel 6. The position of the thermal panel 5 is fixed by turning off mechanism 7. Turning on the thermal transfer mechanism 7 Panel 5 is produced according to the program, and shutdown from the limit switches installed in the final positions of the thermal panel 5 inside the compartment 4 of the vacuum chamber.

Having fixed the position of the thermal panel 5, after it reaches a predetermined temperature, the exposure time starts at a positive temperature. At the end of the exposure time, the thermal panel 5 is moved at a given speed to the compartment 4, and the thermal cycle is completed.

At the end of the exposure time of the tested FP 6 panel at a positive temperature, the cryopanels 2, 3 have a predetermined negative temperature, and the next thermal cycle begins.

Claims (3)

1. Installation for vacuum thermal cycling of panels of photoconverters, comprising a vacuum chamber, consisting of two communicating compartments, in one of which two cryopanels are installed in parallel with the possibility of placing a test panel between them, in the other - a thermal panel in the form of a block of incandescent lamps, characterized in that cryopanels and a heat panel are arranged vertically, and a compartment of a heat panel is located above a compartment of cryopanels, which are installed with the possibility of additional placement between them of a heat panel Do, the latter is provided with a mechanism for reciprocating movement in a vertical plane and insulated from the side facing the cryopanels. 2. Installation according to claim 1, characterized in that the movement mechanism of the thermal panel is made in the form of a gear motor controlled by a frequency drive. 3. Installation according to claim 1, characterized in that the cryopanel compartment is made in the form of a horizontal cylindrical body.

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