JPH08330821A - Antenna device - Google Patents

Abstract

PURPOSE: To facilitate and lighten the constitution of an antenna device for satellite loading and to securely set an auxiliary reflecting mirror after launching. CONSTITUTION: The auxiliary reflecting mirror 3 installed at the front position of a main reflecting mirror 1 is supported to the main reflecting mirror by plural stems 4 composed of highly elastic materials. When the stems 4 are in an expanding state, the auxiliary reflecting mirror 3 is installed in a prescribed position against the main reflecting mirror 1. When the stems 4 are elastically deformed, the auxiliary reflecting mirror 3 is moved to a position approximated to the main reflecting mirror 1 so as to set the mirror 3 in a stored state. At the time of storing the antenna device in a rocket together with a satellite, the stems 4 are elastically deformed, the auxiliary reflecting mirror 3 is moved to the main reflecting mirror side 1 and the device is set to be the stored state. Then, the elastic force of the stems 4 is restored, the auxiliary reflecting mirror 3 is installed in the prescribed position and the function of an antenna is displayed after the satellite is launched.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an antenna device such as a parabolic antenna having a sub-reflecting mirror facing a main reflecting mirror, and more particularly to an antenna device used in artificial satellites and the like.

[0002]

2. Description of the Related Art A parabolic antenna device used in an artificial satellite or the like has a structure in which a main reflecting mirror is folded because the parabolic antenna device needs to be housed in the fairing of a rocket together with the satellite when the artificial satellite is launched. For example, a configuration is adopted in which a plurality of main reflecting mirrors are formed into a petal shape, are housed in a state where they are stacked, and are deployed in a parabolic shape after being launched. Further, together with this, or the main reflecting mirror is not folded, it is necessary to have a structure capable of accommodating a sub reflecting mirror arranged at a position projecting forward of the main reflecting mirror. For example, in an offset type antenna device, the sub-reflecting mirror is located in the vicinity of one circumferential surface of the main reflecting mirror, and the length of the supporting stem is short, so the entire sub-reflecting mirror is folded along the satellite side surface and launched. It is configured to extend this.

However, in a normal parabolic antenna device that is not of the offset type, the sub-reflecting mirror is arranged on the axis of the main reflecting mirror and is supported by a plurality of stems extending from the peripheral edge of the sub-reflecting mirror. However, it is difficult to adopt a configuration in which the stem is simply folded and stored. For this reason, conventionally, a configuration is adopted in which the stem has an extension mast structure, and the mast can be expanded and contracted by an extension mechanism such as a spring and a damper, and an extension mechanism such as a motor and a gear.

[0004]

However, if such an extension mechanism is adopted, the number of components is increased and the weight is increased, which is unavoidable when mounted on an artificial satellite or a rocket. Further, if a failure occurs in the extension mechanism after launching, the sub-reflecting mirror cannot be set to the proper position, the parabolic antenna device cannot function, and communication may be disabled.

[0005]

SUMMARY OF THE INVENTION It is an object of the present invention to provide an antenna device which simplifies the structure and reduces the weight, and which can surely set the sub-reflecting mirror after the launch.

[0006]

In the antenna device of the present invention, the sub-reflecting mirror installed in front of the main reflecting mirror is supported by a plurality of stems made of a highly elastic material. The high elastic material that constitutes this stem is a shape memory alloy,
Materials such as polymer materials and carbon fibers are preferred. Also, when the stem is in the extended state, the sub-reflecting mirror is installed at a predetermined position with respect to the main reflecting mirror, and when the stem is elastically deformed, the sub-reflecting mirror is moved to a position close to the main reflecting mirror and stored. To be configured.

Further, in the present invention, there is provided a holding means for holding the sub-reflecting mirror in a state where the stem is elastically deformed, and when the holding by the holding means is released, the sub-reflecting mirror is returned by elastic return of the stem. Is preferably installable at a predetermined position. This holding means is composed of, for example, a wire rope whose one end is fixed and whose other end is disconnected by a remote operation.When both ends are connected, the wire rope forcibly holds the sub-reflecting mirror at the storage position. The holding force for the sub-reflecting mirror is released when the connected state is released.

[0008]

When the antenna device is housed in the rocket together with the artificial satellite, the stem is elastically deformed, and the sub-reflecting mirror is moved to the main reflecting mirror side to bring it into the housed state. As a result, the antenna device can be downsized and can be easily stored in the rocket. For example, if you hang a wire rope on the front of the main reflector and connect both ends to one side of the artificial satellite, the sub-reflector will be pressed by the wire rope, and will be more than the plane connecting the peripheral edge of the main reflector. It will be stored inside.

After the artificial satellite is launched,
When the end of the wire rope is released from one side of the artificial satellite, the force pressing the sub-reflector against the power supply disappears, and the elastic force of the stem restores the extended state to the sub-reflector. Is installed at a predetermined position to exert the function of the antenna.

[0010]

Next, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing an entire configuration of an embodiment in which the present invention is applied to a satellite dish-equipped parabolic antenna, and FIGS. 2 (a) and 2 (b) are a front view and a partially broken side view of the housed state. Is. As shown in FIG. 1, it is assumed that the main reflecting mirror 1 is formed in a required parabolic shape and is fixed and supported at a predetermined position on one side surface of the artificial satellite S in an already expanded state. The power feeding unit 2 is fixedly supported at the axial center position of the main reflecting mirror 1. The sub-reflecting mirror 3 is the main reflecting mirror 1
The stem 4 is supported by the other end of the stem 4, which is connected at one end to each of the three positions on the peripheral edge thereof, and is held at a position directly facing the power feeding part 3.

The stem 4 is made of a material having high elasticity.
For example, it is formed of a shape memory alloy, a polymer material, carbon fiber or the like in the shape of an elongated rod, and due to its high elastic force, it is possible to hold the sub-reflecting mirror 3 in the extended state in the normal state as described above. However, when it receives an external force, it can be deformed within the elastic range.

On the other hand, on one side surface of the artificial satellite S on which the main reflecting mirror 1 is fixedly supported, one end portion 5a of the wire rope 5 is connected to one side position of the main reflecting mirror 1 and the other side position is provided. The other end 5b of the wire rope 5 is connected via a locking device 6. The wire rope 5 has a length that can be stretched over the front surface of the main reflecting mirror 1. The locking device 6 is composed of, for example, an electromagnet, and when a predetermined electric signal is supplied, a magnetic force is generated to connect the other end 5b of the wire rope 5 to one side surface of the artificial satellite S to generate electricity. When the signal is released, the magnetic force is lost and the other end 5b is released from the one side surface. The locking device 6 is configured to perform energization control by remote control.

In this antenna device, when it is housed in a rocket together with an artificial satellite, as shown in FIG. 2, the sub-reflecting mirror 3 is rotated about its axis by a small angle. Then, the three stems 4 are bent by its elasticity, and a part thereof is curved along the peripheral surface of the sub-reflecting mirror 3. As a result, the sub-reflecting mirror 3 is moved to the main reflecting mirror side 1, so that it can be moved to a position in contact with the front surface of the power feeding unit 2. And
While keeping this state, the wire rope 5 is hung on the front surface of the main reflecting mirror 1, and the end portion thereof is connected to one side surface of the artificial satellite S by the locking device 6. As a result, the sub-reflecting mirror 3 is pressed by the wire rope 5 and brought into contact with the power feeding portion 2, and the sub-reflecting mirror 3 is accommodated inside the plane connecting the peripheral portions of the main reflecting mirror 1. Become. Therefore, in this state, the antenna device can be downsized,
It is advantageous to store in the rocket fairing.

Then, after the artificial satellite is launched,
Power supply to the locking device 6 is stopped by remote control. As a result, as shown in FIG. 3A, the other end 5b of the wire rope 5 is released from one side surface of the artificial satellite S, and the force pressing the sub-reflecting mirror 3 against the power feeding unit 2 disappears. . Therefore, as shown in FIG. 3B, the stem 4 is returned to the extended state by the elastic force of itself, and the sub-reflecting mirror 3 is gradually rotated back to be moved to the front position of the main reflecting mirror 1. Finally, as shown in FIG. 3C, when each stem 4 is completely straightened, the high elastic force of each stem 4 causes the sub-reflecting mirror 3 to move to a predetermined position, that is, the feeding unit 2. It can be installed at the axial center position of the main reflecting mirror 1.

As described above, in the antenna device of this embodiment, the sub-reflecting mirror 3 is held in the retracted state against the high elasticity of the stem 4 itself, and the restriction of the stem 4 is released to increase the high elastic force. Since the stem 4 is extended by this to set the sub-reflecting mirror 3 at a predetermined position, components such as a motor and a damper are not necessary at all, and the weight of the antenna device can be reduced. Further, it is possible to reliably deploy the antenna device without causing an accident such as the inability to deploy the antenna that is caused by the failure of these components.

Here, in the above-mentioned embodiment, the case where the sub-reflecting mirrors are housed while bending one end of the three stems along the circumference of the sub-reflecting mirrors has been described. However, depending on the elastic force of each stem, Even if the stem is simply curved toward the main reflecting mirror, it should be easy to hold the sub-reflecting mirror in the storage position, and when the holding is released, the stem should return to the fully extended state. For example, the bent state of each stem is not limited to the state of the above-described embodiment, but the sub-reflecting mirror can be housed in a bent state in any direction.

Here, in the above-mentioned embodiment, an example in which the locking device is constituted by an electromagnet is shown, but both ends of the wire rope are directly connected to one side surface of the artificial satellite, and one end of the wire rope is connected by a heater. It may be configured such that it is burnt and cut, or it is chemically corroded by a chemical or the like and then mechanically cut by a cutter or the like. In any case, the wire may be arbitrarily released from the connected state.

[0018]

As described above, according to the present invention, the sub-reflecting mirror installed in front of the main reflecting mirror is supported by a plurality of stems made of a highly elastic material. When it is stored in the rocket, the stem can be elastically deformed and the sub-reflector can be moved to the main reflector side to put it in the stored state. Can be installed in the position of, and it is possible to reduce the size and weight with a small number of parts,
Moreover, it is possible to obtain an antenna device suitable for mounting an artificial satellite that can surely function as an antenna device.

Particularly, in the present invention, the sub-reflecting mirror is installed at a predetermined position with respect to the main reflecting mirror when the stem is in the extended state, and the sub-reflecting mirror is brought close to the main reflecting mirror when the stem is elastically deformed. The sub-reflector can be set to the stored state and the used state by simply elastically deforming the stem and releasing the elastically deformed state by configuring the sub-reflector to move to the position to be in the stored state. , It becomes possible to perform these operations easily.

Further, in the present invention, a wire rope having both ends connected to an artificial satellite or the like is provided as a holding means for holding the state in which the stem is elastically deformed and the sub-reflector is housed.
This wire rope is used to forcibly hold the sub-reflector in the storage position, and the holding force for the sub-reflector is released when the connected state is released. If you release the connection of
The elastic force of the stem restores the extended state, and the sub-reflecting mirror can be installed at a predetermined position to configure the antenna device.

[Brief description of drawings]

FIG. 1 is a perspective view of an embodiment of an antenna device of the present invention.

2A and 2B are a front view and a side view of a housed state of the antenna device of FIG.

FIG. 3 is a side view sequentially showing the unfolding operation of the antenna device of the present invention.

[Explanation of symbols]

 1 Main Reflector 2 Feed Part 3 Sub Reflector 4 Stem 5 Wire Rope 6 Locking Device

Claims (6)

[Claims] 1. An antenna device comprising: a main reflecting mirror; a sub-reflecting mirror installed in front of the main reflecting mirror; and a plurality of stems for holding the sub-reflecting mirror at the position. An antenna device characterized in that the stem is made of a highly elastic material. 2. The antenna device according to claim 1, wherein the highly elastic material forming the stem is a material such as a shape memory alloy, a polymer material, or carbon fiber. 3. The stem has a sub-reflecting mirror installed at a predetermined position with respect to the main reflecting mirror when the stem is extended, and the sub-reflecting mirror is moved to a position close to the main reflecting mirror when the stem is elastically deformed. The antenna device according to claim 1 or 2, wherein the antenna device is configured to be stored. 4. The main reflecting mirror is a main reflecting mirror of a parabolic antenna, one end of the stem is connected to a peripheral portion of the main reflecting mirror,
The antenna device according to any one of claims 1 to 3, which is composed of three stems that support a sub-reflecting mirror at the other end. 5. A holding means for holding a state in which the sub-reflecting mirror is housed by elastically deforming the stem, and when the holding by the holding means is released, the stem is elastically returned to bring the sub-reflecting mirror to a predetermined position. The antenna device according to claim 1, which can be installed. 6. The holding means is composed of a wire rope whose one end is fixed and whose other end is disconnected by a remote operation, and when both ends are connected, the sub-reflecting mirror is forced to the storage position by the wire rope. 6. The antenna device according to claim 5, wherein the antenna device is configured to be held in place and the holding force for the sub-reflecting mirror is released when the connected state is released.