FR2463058A1 - Earth satellite heating control - has two heat radiators operated by sun position connected by tube to heat insulated panel - Google Patents

Abstract

The heating control system for an earth satellite includes a panel which is thermally insulated from the atmosphere within which it is located. Connected to this panel is one or more heat transfer tubes (4) connected between two cooling members (6,8). These cooling members are mounted respectively on two heat radiators (10,12). One radiator (10) is a north radiator, and the other is a south radiator. Both radiators incorporate heat exchanger tubes (14). These two radiators discharge heat (PV1) from the insulated panel and also the heat (PV2 and PV3) from the two cooling systems. Their operation varies with the position of the sun, so that the total heat discharged remains the same at all times.

Description

INSURING INSTALLATION WITHOUT ADJUSTMENT
DISCHARGE OF HEAT AND STABILIZATION
OF THE TEMPERATURE.

The present invention relates to an installation ensuring without adjustment the heat dissipation and the st, temperature stabilization in a building element capable of radiating heat, such as in particular an element mounted on the panel. a satellite looking at the earth, an element which is connected to a heat tube connected itself to a radiator.

On the earth panel of the satellites are mounted electrical components radiating considerable heat but which must, at the same time operate within a narrow temperature range, this earth panel itself being unable to radiate any heat. The heat appearing in such construction elements is transmitted in current devices by a heat tube to one of the side radiators. Since the charge of this radiator varies under the effect of variable solar radiation and variable energy dissipations coming from the radiator itself, it is necessary to achieve stabilization of the temperature of the building element or of the components of the panel-earth via a regulating system and an auxiliary heating device. This has the disadvantages of only partial use of the useful surfaces of the radiator and the additional weight of the batteries, regulating systems and heater.

This is why the invention proposes to simplify the cooling and stabilization of the temperature of the construction elements which are thermally isolated from the external environment, so as to ensure a saving in weight as well as to use the surfaces as much as possible. of existing radiators.

The problem thus posed has been solved by associating, in accordance with the invention, two coolers or heat absorbers to the heat tube connected to the heat radiating construction element, one of these coolers being connected to a South radiator. and the other to a North radiator, the radiators being arranged in such a way on the satellite that the sum of their charges produced by solar radiation and by heat losses is substantially constant.

située entre les deux refroidisseurs.The evacuation of a PV1 heat from a component of the earth panel is carried out by one or more heat tubes so that the dissipated heat is applied to the North radiator or to the South radiator or else partially to each of these radiators, according to the load PV2, PV3 of these coolers as determined by the sun and their own heat losses. The total charge of the two radiators always has the same value within a certain range of fluctuations, namely Sun + PVi + PV2 + PV3 while the heat lost PV1 is distributed in proportions varying with the load and the temperature level in the two radiators: consequently, the requirement of a stabilization of the temperature of the component is satisfied without the need for an independent control system or heater. The heat is dissipated by a heat tube leading to at least two coolers which are placed respectively near the North and South radiators, the heat source to be evacuated

located between the two coolers.

 Heat dissipation and temperature stabilization are thus achieved without adjustment and the radiator surfaces are used to the maximum. Any subsequent heating to stabilize the temperature becomes unnecessary, since the total charge of the two radiators always remains the same.

The following advantages are obtained by the recommended means
- Elimination of heating devices and thermal energies, which means saving in weight.
- Reduction of radiator surfaces and therefore further saving in weight.

- High reliability thanks to the absence of any electronic adjustment.

- Good electromagnetic compatibility.

 - Ability to change the location of components on the ground panel.

 - Possibility of a good verification of the heat tube system in the gravitational field.

Other advantages, characteristics and possible applications of the invention will appear on reading the following description of the accompanying drawings, in which
Fig. 1 shows the basic arrangement of the device according to the invention, the structure of the satellite itself not being drawn for reasons of clarity.

 Figs 2 and 3 show variants of this device.

 Fig. 1 represents, on a satellite which is not drawn, a ground panel thermally insulated from the external environment and which is, in the device according to the invention, in direct contact with one or more heat tubes 4 These tubes 4 have at their ends coolers 6,8, one of these coolers 6 being connected to the heat tube radiator North 10 and the cooler 8 to the heat tube radiator South 12. The heaters 10,12 are each made up of several heat tubes 14 and are subjected to the variable action of the sun.

The radiators 10 and 12 are used primarily for the evacuation of waste heat
PV2 and PV3 as shown schematically in the drawings. They also serve for the evacuation of the thermal energy PV1 appearing on the ground panel 2 and moreover for the stabilization of the temperatures of the components on the ground panel.

 To facilitate understanding of these phenomena, we have drawn in FIG. 1 two positions of the sun in 16 and 18. We will explain below in more detail based on these positions of the sun the operation of the object of the invention.

It is known that, for a heat tube, the location of heat sources and coolers can vary over time. It is also known that a heat tube can have several heat sources and coolers simultaneously.

If the sun is at the position shown in 16 and if the thermal load
Internal PV3 of the radiator 12 is high while that PV2 of the radiator 10 is low, or almost zero, the radiator 12 has already reached its maximum admissible load without the heat lost in PV1 being able to be evacuated further to the radiator 12.

The PV1 heat then flows to the radiator 10 possibly together with a fraction of PV3.

What has just been described is valid conversely, when the sun is at 18 and only the radiator 10 receives its radiation so that its thermal load PV2 reaches its maximum value while the load P5L is low or almost zero; in this case, the heat of PV1 flows to the radiator 12, possibly together with a fraction of PV2.

lesqu elles PV1 s'écoule partiellement dans chacun des deux radiateurs 10,12. Dans le cas de ces conditions intermédiaires, le tube de- chaleur 4 présente à chaque extrémité en 6 et en 8, un refroidisseur, à savoir deux refroidisseurs en tout.Between the two extreme cases mentioned above, we can understand all the intermediate conditions

which PV1 partially flows in each of the two radiators 10,12. In the case of these intermediate conditions, the heat tube 4 has at each end at 6 and 8, a cooler, namely two coolers in all.

According to the principle governing the heat pipes, the heat is always removed at the coldest point so that the temperature of the two coolers tends to take the same value. It follows that any particular adjustment of the temperature of the components giving off heat on the ground panel can be eliminated.

If the surfaces of the North and South radiators of a satellite are not sufficient for the evacuation of PV1. .. PV3, one or more additional radiators must be used for this evacuation. This can be achieved on the ground panel itself or by radiators on the west or east side.

 The cooling and temperature stabilization device also operates when, as shown in FIG. 2, the heat tube 4 dissipating the heat present on one side of the components A PV1 two coolers whose temperatures vary as a function of the variable losses appearing in PV3 and in PV4 and in solar radiation. The radiators 12 and 20 of these coolers have for this purpose different inclinations with respect to solar radiation.

Heat dissipation with automatic temperature stabilization also takes place when, as shown in Fig. 3, one of the radiators is replaced by another cooler whose temperature is subject to certain fluctuations. It is possible in particular to use a refrigerant circuit 22 capable of evacuating variable amounts of heat, for example, by opening and closing partial circuits extending between the valves 24, the temperature of the circuit also thus undergoing temperature fluctuations which could not be compensated only by a complicated system of regulation and heating. This is why instead of the direct connection with the radiator 10, it is the heat exchanger 26 which has been connected to the heat tube 4.

In the refrigerant circuit 22 is interposed, in addition to the controlled valves 24, a pump 28 as well as another heat exchanger 30 constituting the cooler for the refrigerant circuit 22.

 The cooling method described above and comprising a cooling circuit and an additional radiator can be used in particular for the execution of experiments in space.

Claims (2)

1 Device for dissipating heat and stabilizing the temperature in a  building element radiating heat and associated with a heat tube and  to a radiator characterized in that the heat tube connected to this element of construction extends beyond the edges of this construction element and is associated  at least two coolers. 2 Heat stabilization heat dissipation device according to the  claim 1 intended more particularly for the components carried by the panel  earth from a satellite and connected to a heat tube and a radiator, this device being characterized by the fact that the heat tube connected to this component or other construction element leads to two coolers, one of which is connected to a radiator  South and the other to a North radiator, these latter radiators being mounted on the satellite in such a way that the sum of their thermal load produced by the solar radiation and lost heat (Sun + PV1 + PV2 + PV3)  be constant.