KR20110058447A - Weightlessness offering apparatus for deployment test of solar panel - Google Patents

Abstract

PURPOSE: A weightlessness offering apparatus for a deployment test of a solar panel is provided to implement a perfect weightless state by allowing a support cable supporting the weight of a solar panel to slide along two axes. CONSTITUTION: A weightlessness offering apparatus for a deployment test of a solar panel comprises a pair of rails(100) which are arranged in parallel, first slide members(200) which are installed in the rails and slid along the rails, a guide rail(300) which connects the first slide members, a second slide member(400), and a support cable(500) which is connected to the second slide member and a solar panel and supports the weight of the solar panel.

Description

Gravity-free state providing device for development of solar panel {WEIGHTLESSNESS OFFERING APPARATUS FOR DEPLOYMENT TEST OF SOLAR PANEL}

The present invention relates to an apparatus for providing a zero gravity state for a solar panel development test, and more particularly, a solar cell capable of implementing a perfect zero gravity state during a solar panel development test by allowing a support cable for supporting the solar panel's own weight to be movable along two axes. The present invention relates to a device for providing a zero gravity state for a panel development test.

In general, when a satellite is launched into space by a projectile, the satellite is mounted in the projectile while the solar panel attached to the satellite body is folded in order to reduce its volume.

When the satellite climbs the orbit, it unfolds the folded solar panel to generate power using solar energy.

If the satellite's solar panels are not well deployed in orbit, they will not produce the power required by the satellites, and thus the satellites will lose their function.

However, since the space where the satellite operates is a gravity-free space, the development test conducted on the ground can also be carried out in a zero gravity state to increase reliability.

The solar panel has a structure in which a plurality of solar panels are connected in an accordion form, and the apparatus for providing a zero gravity state for the development test of the conventional satellite solar panel, as shown in FIG. 1, has a deployment structure 20 and a zero gravity state. It consists of a guide beam 30 and the bungee cable 40 to implement.

In the gravity-free state providing apparatus for the development test of the satellite solar panel as described above, the solar panel 10 is installed on the deployment structure 20, the solar panel 10 by the bungee cable 40 installed on the guide beam 30 Self-weight is supported.

When the development test of the solar panel 10 is performed, the binding member (not shown) which restrained the solar panel 10 in the folded state is released, and the solar panel 10 is unfolded by this.

At this time, the bungee cable 40 connected to each solar panel slides along the guide beam 30 to support the self-weight of the solar panel 10 to implement a zero gravity state.

However, since the solar panel 10 is folded and unfolded in an accordion shape, a force is generated in the directions of arrows A and B of FIG. 2 when the solar panel 10 is deployed.

As described above, since the movement of each solar panel during the development test of the actual solar panel 10 has a characteristic of two-axis movement in the horizontal direction, as a conventional weightless state providing apparatus having one degree of freedom in FIG. Since the forces in the direction of the arrow A and B can not be canceled, there is a problem that does not occur in the outer space caused the degradation of the reliability and accuracy of the solar panel development test.

The present invention is to solve the above problems, an object of the present invention is to enable the support cable for supporting the self-weight of the solar panel slides along two axes, the solar panel can implement a perfect weightless state during the development test It is to provide a weightless state providing device for the test panel.

According to the present invention, in the development test of a solar panel formed by folding a plurality of solar panels, a pair of rails formed in parallel with each other so as to be able to slide along the rails A first slide member provided on the rail, a guide rail installed to interconnect the first slide members, a second slide member installed to slide along the guide rail, and connected to the second slide member. It is achieved by a support cable connected to the solar panel and supporting the solar panel's own weight.

The first slide member and the second slide member may include a cover installed to surround the rail and the guide rail, and at least one or more friction bearings formed between the rail and the guide rail and the cover.

The apparatus may further include a turnbuckle formed in one region of the support cable.

In addition, each of the first slide member, the guide rail, the second slide member, and the support cable may be provided in a number corresponding to the number of the solar panel solar panels, and each support cable may be connected to each solar panel.

As a result, the support cable supporting the self-weight of the solar panel can be slidably moved along the two axes, so that a perfect weightless state can be realized during the solar panel development test, and the verification of the solar cell deployment mechanism can be performed more accurately and reliably. It has an effect.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail with reference to the accompanying drawings.

The accompanying drawings show exemplary forms of the present invention, which are provided to explain the present invention in more detail, and the technical scope of the present invention is not limited thereto.

The apparatus for providing a zero gravity state for a solar panel development test according to the present invention includes a pair of rails 100 formed in parallel and a first slide member 200 installed on each rail 100, as shown in FIG. 3. And a guide rail 300 for interconnecting the first slide member 200, a second slide member 400 installed on the guide rail 300, and a second slide member 400 to be connected to the solar panel. It consists of a support cable 500 for supporting a weight of 600.

First, the rail 100 is a pair of rods formed in parallel, and is installed on the ceiling of a test room, a crane boom, or the like by the bracket 700.

In addition, the first slide member 200 is installed on each rail 100 so that the slide can be moved along the rail 100.

As illustrated in FIG. 5, the first slide member 200 includes a cover 210 and a micro friction bearing 220.

The cover 210 has a groove corresponding to the rail 100 at a lower portion thereof, the groove being fitted to the rail 100, and a coupling hole at which the guide rail 300 is installed is formed at the upper portion thereof.

In addition, a plurality of micro friction bearings 220 are formed between the rail 100 and the cover 210 so that the first slide member 200 can slide along the rail 100.

On the other hand, the guide rail 300 is formed as a rod is fitted into the coupling hole of the first slide member 200 installed in each rail 100 to connect the first slide member 200 to each other.

In addition, as shown in FIG. 6, the second slide member 400 includes a cover 410 and a micro friction bearing 420.

The cover 410 has a groove corresponding to the guide rail 300 is formed in the upper portion is inserted into the guide rail 300, the lower ring is formed for the support cable 500 is installed.

A plurality of micro friction bearings 420 are formed between the guide rail 300 and the cover 410 such that the second slide member 400 can slide along the guide rail 300.

In addition, the support cable 500 is formed of a steel wire, one side is fixed to the ring formed on the cover 410 of the second slide member 400, the other side is connected to the solar panel 600, the solar panel 600 We support self weight of).

In this case, a turnbuckle (not shown) may be formed in one region of the support cable 500 to easily adjust the length of the support cable 500.

Each of the first slide member 200, the guide rail 300, the second slide member 400, and the support cable 500 formed as described above correspond to the number of solar panels 610 of the solar panel 600. It is provided in number, and each support cable 500 is connected to each solar panel 610 to support the weight of the entire solar panel 600.

Looking at the operation of the apparatus for providing a gravity-free state for developing a solar panel according to the present invention configured as described above with reference to Figure 4, when the solar panel 600 is deployed support cable 500 for supporting each solar panel 610 The rail 100 has a degree of freedom in the direction in which the guide rail 300 is formed and the two-axis motion generated when the solar panel 600 is deployed can be offset.

Therefore, it is possible to implement a perfect weightless state during the solar panel 600 deployment test, there is an effect that can be carried out more accurately and reliably the verification of the solar panel 600 deployment mechanism.

The embodiments and drawings attached to this specification are merely to clearly show some of the technical ideas included in the present invention, and those skilled in the art can easily infer within the scope of the technical ideas included in the specification and drawings of the present invention. It is apparent that both the modifications and the specific embodiments are included in the scope of the technical spirit of the present invention.

1 and 2 are views of the prior art.

3 is a perspective view of the apparatus for providing a zero gravity state for a solar panel development test according to the present invention.

Figure 4 is an operation of the apparatus for providing a gravity-free state for solar panel development test according to the present invention.

5 and 6 are partial perspective views of the apparatus for providing a zero gravity state for a solar panel development test according to the present invention.

<Description of the symbols for the main parts of the drawings>

 10: solar panel 20: deployment structure

 30: guide beam 40: bungee cable

100: rail 200: first slide member

210: cover 220: micro friction bearing

300: guide rail 400: second slide member

410: cover 420: micro friction bearing

500: support cable 600: solar panel

610 solar panel 700 bracket

Claims (4)

In the development test of a solar panel formed by folding a plurality of solar panels, it is formed on the top, A pair of rails formed in parallel; A first slide member installed on each rail so as to slide along the rail; A guide rail installed to interconnect the first slide members; A second slide member installed to slide along the guide rail; And a support cable connected to the solar panel and supporting the self weight of the solar panel while being connected to the second slide member. The method of claim 1, The first slide member and the second slide member, A cover installed to surround the rail and the guide rail; And at least one friction bearing formed between at least one of the rail and the guide rail and the cover. The method of claim 1, And a turnbuckle formed in one region of the support cable. The method of claim 1, Each of the first slide member, the guide rail, the second slide member, and the support cable is provided in a number corresponding to the number of the solar panel solar panels, and each support cable is connected to each solar panel. Zero gravity state providing device for development test.

Images