JPS5948299A - Thermal-louver - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Technical Field to Which the Invention Pertains] The present invention relates to a thermal louver which is a heat radiation control device for a spacecraft such as an artificial satellite.

[Prior art and its problems] Generally, most of the surface of a spacecraft such as an artificial satellite is covered with a vacuum heat insulating material, and the other part is made into a heat-radiating surface.

Depending on the amount of internal heat generated, some or all of the heat dissipation surface may
Even though it is equipped with a heat dissipation control device that can increase or decrease the amount of heat dissipated, keeping the internal temperature constant at 3C. Thermal louvers are one of the most popular types of heat radiation control equipment.

FIG. 1 shows a sectional view showing the operating state of a conventional thermal louver, and FIG. 2 shows a perspective view.

Bimetal spring (
The blade row (3) rotated by the driving force of step 2) is supported by bearings (4) at both ends in a blind manner, and the temperature of the heat dissipation surface (1) attached to the heat dissipation surface (1) increases. Accordingly, the bimetal spring (2) changes the rotation angle of the blade row (3) and increases or decreases the area of the heat dissipation surface (1) exposed to space, thereby increasing the amount of heat dissipation from the heat dissipation surface (1). Adjust the amount of heat. On the back side of the heat dissipation surface (1), electronic equipment (5
) and other heat transfer elements that can generate heat in electronic equipment (6)
etc. will be installed.

The heat dissipation surface (1) is 0.8.11 (Opt 1 cal
They are made of materials with surface characteristics such as 5olar efrector) and silver Teflon, which have low absorption of sunlight and high emissivity.

When the blade row (3) is fully closed (FIG. 1a), the heat radiation surface (1) is covered by the blade row (3) and is in an adiabatic state.

i When the electric motor (3) is fully opened (Fig. 1b), the heat dissipation surface (1)
In the middle open state of the blade row (3) (FIG. 1C), the heat radiation amount is an intermediate value between the above two states.

As described above, the conventional thermal looper adjusts the heat radiation ttt from the heat radiation surface by the degree of opening of the blade row rotated by the El ntb force of the bi-metal spring.
Do step 1. However, there is only one bimetal spring for each row of blades, as shown in Figure M2-5-)
There are disadvantages such as the need to install 1X l/M, temperature calibration of 1 addition and bimetallic ring, and ζ complexity.

[Object of the invention] This invention improves the above-mentioned drawbacks of the thermal looper, suppresses the increase in iK)l of the thermal looper,
It also simplifies temperature calibration of bimetallic springs,
The purpose of the present invention is to provide a thermal looper that can keep the degree of opening of the blade row constant.

[Summary of the invention] In a blade row that adjusts the flow of heat from a heat dissipation surface to outer space, bimetal springs installed at both ends of the blade row that operate the entire blade row, and a device for transmitting the driving force of the bimetal spring. , transmission wires or transmission rods are provided at the tips of the disks and blade rows that amplify the driving force.

[Effects of the Invention] In the thermal looper having the above configuration, it is only necessary to install bimetallic springs at both ends of the blade row, and unlike conventional thermal loopers, there is no need to install one at each end. It reduces the heavy M of the thermal looper.

Still, since the driving force of the bimetal spring is transmitted to each couple via the rotating disk and the transmission wire, the degree of opening of each couple can be made constant. Additionally, bimetallic springs have fewer faults, which simplifies temperature calibration of bimetallic springs.

[Embodiments of the invention] Third, an embodiment of the present invention will be described.

Bimetal springs (2) installed at both ends of the blade row (3)
) operates at the temperature of the heat dissipation surface (1). When the temperature of the heat dissipating surface (1) rises and it becomes necessary to dissipate heat, it rotates in the direction of the arrow, and the rotation is amplified by the rotating disk (8) via the rotating shaft (7). A transmission wire (9) is attached to this rotating disk (8), and the wire is connected to each pair (
3), while reaching the rotating disk at the other end. When the blade row (3) is fully closed (Fig. 4a), the O blade row (3) is made of, for example, an aluminum plate with one end above the rotating end and polished on both sides (Fig. 4a). ) rotates, the blades fall down and come into contact with each other, forming a perfect reflective surface, and the heat dissipation Ifi'r (1) is covered with the reflective surface and becomes an adiabatic state.

When the blade row (3) is fully open (Fig. 4b), the rotating disk (8) rotates clockwise, the blade is in an upright state, and the heat radiation surface (1) is almost exposed. Has large heat dissipation.

In the middle open state of the blade row (3) (v44 diagram C), the upper I
4Q Indicates the amount of heat dissipation between the two states.

Other Embodiments of the Invention] FIGS. 5 and 6121 are diagrams showing the structure and operating state of another embodiment of the present invention. A bimetal spring is provided at one end of the blade row (3), and a zero spring is provided at the other end.

[Brief explanation of the drawing]

Figure 1 is a sectional view showing the operating state of a conventional thermal looper, Figure 2 is a perspective view of a conventional thermal looper, and Figure 3 is a perspective view of a conventional thermal looper.
The figure is a perspective view of the thermal looper of the present invention, and FIG. 4 is a sectional view showing the operating state of the thermal looper of the present invention. FIG. 5 and FIG. 6 are diagrams showing the structure and operating state of other embodiments of the present invention. 1... Heat dissipation surface, 2... Bimetal spring, ; 3
...blade row, 4...bearing, 5...1d child equipment,ゝ
6... Heat transfer element, 7... Rotating shaft, 8... Rotating circle.
Plate, 9...transmission wire, 10...spring.

Claims (1)

[Claims] To transmit the driving force of the bimetal spring that reduces the operation of the blade row of the thermal louver, which is the heat radiation side fil1 equipment of space vehicles such as artificial satellites, that adjusts the flow of heat from the heat radiation surface to space. Thermal louver features a disc that amplifies the driving force and a transmission wire at the tip of the wing.