JP2665756B2 - Launch lock mechanism of blind type 3-axis control active solar sail - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a launch lock mechanism of a blind type three-axis control active solar sail used for three-axis attitude control of an artificial satellite such as a geostationary satellite.

[Conventional technology]

There are various types of disturbance torque that disturb the attitude of the geostationary satellite. However, the disturbance torque has been dramatically increased due to an increase in size of a solar cell panel or the like.

Conventional correction control of the posture variation due to the disturbance torque is as follows.
This has been done by a fixed solar sail using the radiant pressure of sunlight or by supporting the solar cell panel with bearings and rotating the motor to appropriately control the angle.

However, by the rotation control of the fixed type solar sail or the solar panel, the three axes cannot be actively controlled, and the rotation of the solar panel is supported by bearings and controlled by a motor in principle. Although it is possible, not only the weight of the rotation control mechanism is increased, but also there is a problem in reliability because of the sliding portion.

In order to solve this problem, the present inventors have previously proposed a blind type three-axis control active solar sail as shown in FIG. 3A (Japanese Patent Application No. 61-301308). That is, in the drawing, reference numeral 21 denotes a solar cell panel mounted on an artificial satellite, and reference numeral 22 denotes a blind solar sale section mounted at the tip of the solar cell panel 21.
A blade rotatably supported by a torsion bar in the length direction of the panel 21 on the left and right sides of the tip end of 21
23 _-1 , 23 _-2 , ... 24 _-1 , 24 _-2 , ... The blades _23-1 , _23-2 ,... On one side indicate a closed state, and the blades _24-1 , _24-2,.

FIGS. 3 (B) and 3 (C) are a plan view and a side view showing a part of the blind solar sail portion having such a configuration in an enlarged manner. At both ends of each of the divided blind type blades _23-1 , _23-2 ,..., Torsion bars 25, 26 are attached, and the other end of one torsion bar 25 is attached and fixed to a frame 27. The pivot 28 is supported under tension. The torsion bar 26 at the other end is connected to a frame 27 via a magnetic driver 29.
The magnetic driver 29 is configured to open and close the blades _23-1 , _23-2 ,.... Reference numeral 30 denotes a lower panel of the solar cell panel when it is folded and mounted at launch.

The bridging type three-axis control active solar sail configured as described above has no sliding portion by selectively controlling the opening and closing of a large number of divided blind type blades, both ends of which are supported by torsion bars, by driving an electromagnet. The three-axis control torque can be easily generated with a simple mechanism.

[Problems to be solved by the invention]

By the way, the blind type three-axis control active solar sail has a reduced rigidity in order to reduce the weight of the blind and is supported by a torsion bar. May not be able to withstand the launch environment.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the invention is to provide a launch lock mechanism of a lightweight blind type 3-axis control active solar sail with a simple configuration for improving environmental resistance at launch. And

[Means and actions for solving the problems]

In order to solve the above problems, the present invention provides a solar cell panel mounted on an artificial satellite or the like which is used by being folded and deployed at the time of launch. In a blind-type three-axis control active solar sail in which a solar sail composed of divided blind-type blades is arranged, a pair of blade retainers are provided on a lower surface panel adjacent to a solar sail outer frame when the solar cell panel is folded, The retainer is rotatably supported in a state where the blade holding portions are opposed to each other and urged to open the holding portions, and when the solar cell panel is folded, a pair of blades is pressed by the pressing force of the solar sail outer frame. The retainer is driven so that the blade holding portion holds the blade against the opening urging force, and the At the time of the opening operation, the blade holding portion is rotationally urged by releasing the pressing force of the solar sail outer frame to open the blade holding, or a pair of blade retainers is attached to the solar sail outer frame. Are rotatably supported in a state where the blade holding portion of the blade retainer is opposed to and biased to open the blade holding portion, and when the solar cell panel is folded, when the solar cell panel is folded. By the pressing force of the lower panel adjacent to the solar sail outer frame,
The pair of blade retainers are driven so that the blade holding portion teaches the blade against the opening urging force,
At the time of the deployment operation of the solar cell panel, the blade holding portion is rotationally urged by releasing the pressing force of the lower surface panel of the solar cell panel to release the holding of the blade.

With this configuration, during launch, the blinds are sandwiched and fixed by the retainer in conjunction with the folding and storage of the solar cell panel, so that it can withstand the environment at the time of launch and retain its function, and when the panel is deployed, In conjunction therewith, the retainer can be released from the blind, and the opened blind can be appropriately driven to generate three-axis control torque.

〔Example〕

Hereinafter, embodiments will be described. FIG. 1 (A) is a plan view of a first embodiment of a launch lock mechanism of a blind type three-axis control active solar sail according to the present invention, and FIG. 1 (B) is a cross section taken along the line XX '. FIG. 1 (C) shows the Y-
It is sectional drawing which followed the Y 'line. In the figure, 1 is a solar sail outer frame supported at one end of a solar cell panel,
A blade 2 is rotatably supported on the outer frame 1 by torsion bars 3 attached to both ends thereof. Reference numeral 4 denotes a spring tension adjusting device for the blade 2 attached to the solar sail outer frame 1, and reference numeral 5 denotes a magnetic driver for driving the blade 2 also attached to the solar sail outer frame 1. Reference numerals 6 and 6 denote a pair of L-shaped blade retainers, and dampers 7 made of silicon rubber or the like are fixed to the bent portions 6a and 6a by bonding or the like. The support shaft is positioned on the lower panel 8 when the panel is folded, so that the blades 2 supported by the solar sail outer frame 1 can be clamped by the dampers 7, 7 attached to the bent portions 6a, 6a. 9 so as to be rotatable.

When the solar cell panel is unfolded in which the lower panel 8 is separated from the outer frame 1 of the solar sail, the support shaft 9 is moved so that the dampers 7, 7 of the pair of blade retainers 6, 6 are separated from each other in conjunction with the unfolding operation. Is provided with a spring 10. Reference numeral 11 denotes a damper provided on the outer frame 1 side of the substrate portions 6b, 6b of the blade retainers 6, 6, and the outer frame 1 is provided when the panel is folded.
To be in contact with the lower surface of the.

Next, the operation of the launch lock mechanism configured as described above will be described. 1 (A) to 1 (C) show the locked state of the launch lock mechanism. When the satellite is launched, the solar cell panel is folded and the outer frame of the solar sail attached to the top panel is shown. 1 and the lower panel 8 are in close contact with each other. Therefore, the blade retainers 6, 6 rotatably attached to the lower panel 8 have their base portions 6b, 6b pressed by the solar sail outer frame 1 via the dampers 11, 11, and are bent by the bent portions 6a, 6a. The blade 2 is clamped and fixed by the provided dampers 7, 7, and is in a locked state. Thus, the low-rigidity blade 2 is connected to the blade retainers 6, 6 via the dampers 7, 7.
, It is possible to sufficiently withstand the environment at the time of launch.

Next, when the solar cell panel is deployed after the satellite launch operation is completed, as shown in FIG. 1 (D), since the lower surface panel 8 of the solar sail outer frame 1 attached to the upper surface panel is separated, the blade retainer 6 is removed. , 6 have no pressing force on the substrate portions 6b, 6b, and the biasing force of the spring 10 causes the blade retainers 6, 6 to rotate so that their tip dampers 7, 7 are separated from each other. As a result, the blade 2 is released and enters an unlocked state. In this state, the opening and closing of the blade 2 is controlled by the driver 5, and three-axis control torque can be generated.

FIG. 2A is a plan view showing a second embodiment of the present invention, and FIG. 2B is a cross-sectional view taken along the line ZZ '. In this embodiment, the substrate portion of the L-shaped blade retainer 12 is
The intermediate portion of 12b, 12b is pivotally attached to the solar sail outer frame 1 by a support shaft 13 and held. And Solar Sale Outer Frame 1
A spring 14 is interposed between the lower surface of the blade retainer 12 and the rear end of the substrate portion 12b of the blade retainer 12. Dampers 15, 16 are fixed to the rear ends of the bent portion 12a and the substrate portion 12b, respectively, by bonding or the like.

Next, the operation of the launch lock mechanism having such a configuration will be described. At the time of launching the satellite, since the solar cell panel is folded, the solar sail outer frame 1 attached to the upper panel and the lower panel 8 are in close contact with each other. Yes,
Since the rear end of the substrate portion 12b of the blade retainer 12 is pressed by the lower panel 8 via the damper 16, the damper 15 of the bent portion 12a is pressed toward the blade 2, and the blade 2 15 and locked.

When the solar cell panel is deployed after the launching operation is completed, the solar sail outer frame 1 and the lower panel 8 are separated from each other, so that there is no pressing force on the rear end of the substrate portion 12b of the blade retainer 12, and the urging force of the spring 14 Accordingly, the blade retainer 12 rotates in the direction of the arrow, the bent portions 12a and 12b are separated from each other, and the blade 2 is opened. In this state, the opening / closing control of the blade 2 is performed by the magnetic driver 5, and the three-axis control torque can be generated.

〔The invention's effect〕

According to the present invention as described above based on the embodiments, the blade retainer is configured to automatically perform the sandwiching or opening operation of the blade in conjunction with the folding and unfolding operations of the solar cell panel, The blade of the lightweight solar sail, which is weak against the launch environment, can be easily fixed and supported by a simple mechanism, the function can be maintained, and the environmental resistance of the blade can be improved.

[Brief description of the drawings]

FIG. 1 (A) is a plan view of one embodiment of a launch lock mechanism of a blind type three-axis control active solar sail according to the present invention, and FIG. 1 (B) is a cross section taken along the line XX '. Figure,
FIG. 1C is a sectional view taken along the line YY ′ of FIG.
FIG. 2D shows the unlocked state, and FIG.
FIG. 2B is a plan view of another embodiment of the present invention, FIG. 2B is a sectional view taken along the line ZZ ′, FIG. 2C is a view showing the unlocked state, FIG. 3 (A) is a plan view showing the previously proposed blind type 3-axis control active solar sail,
FIG. 3B is a partially enlarged side view thereof. In the figure, 1 is a solar sail outer frame, 2 is a blade, 3
Is a torsion bar, 4 is a spring tension adjuster, 5 is a magnetic driver, 6 is a blade retainer, 7,11
Is a damper, 8 is a lower panel, 9 is a support shaft, 10 is a spring, 12
Denotes a blade retainer, 13 denotes a support shaft, 14 denotes a spring, and 15, 16 denote dampers.

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Yasushi Wakabayashi 2-1-1 Sengen, Tsukuba, Tsukuba, Ibaraki Space Development Corporation Tsukuba Space Center (72) Inventor Hiroyuki Nakamura 2-1-1 Sengen, Tsukuba, Ibaraki, Space The Development Corporation Tsukuba Space Center

Claims (2)

(57) [Claims] 1. A solar cell panel mounted on an artificial satellite or the like which is used by being folded and deployed at the time of launch,
In a blind 3-axis control active solar sail in which a solar sail consisting of a number of divided blind-type blades rotatably held on the solar sail outer frame is placed adjacent to the solar sail outer frame when the solar panel is folded. On the lower panel to be supported, the pair of blade retainers are rotatably supported in a state in which the blade holding portions of the blade retainers are opposed to each other and biased to open the holding portions,
At the time of folding the solar cell panel, the pressing force of the solar sail outer frame causes the pair of blade retainers to be driven to hold the blade against the opening urging force so that the blade holding portion holds the blade. In the unfolding operation, the blade holding portion is rotationally urged by releasing the pressing force of the solar sail outer frame to release the holding of the blade. Launch launch lock mechanism. 2. A tip of a solar cell panel mounted on an artificial satellite or the like that is folded and deployed at the time of launch,
In a blind type three-axis control active solar sail in which a solar sail consisting of a number of divided blind type blades rotatably held on a solar sail outer frame is arranged, a pair of blade retainers are provided on the solar sail outer frame, With the blade holding portion of the blade retainer facing and rotatably supported in a state of being urged to open the blade holding portion, when folding the solar cell panel,
By pressing the lower surface panel adjacent to the solar sail outer frame when the solar cell panel is folded, the pair of blade retainers is driven so that the blade holding portion holds the blade against the opening urging force, At the time of deployment operation of the solar cell panel, the blade holding portion is rotationally urged by releasing the pressing force of the lower surface panel of the solar cell panel, and is configured to open the blade. Launch lock mechanism of blind type 3-axis control active solar sail.