JPH04119702A - Mesh antenna - Google Patents

Abstract

PURPOSE:To change the shape of a mesh mirror surface into a desired shape by employing at least one of stand-offs for a truss fixing a cable network as a moving stand-off and making the said moving stand-off movable vertically and in a radial direction at a right angle to the vertical direction. CONSTITUTION:At the design of a cable network 2, a moving direction and its quantity of a movable stand-off 5 are calculated for a scheduled change or revision of a shape of a mesh mirror surface. When distortion takes place to the mesh mirror surface 1 on a satellite or it is required to revise the mesh mirror surface 1 afterward, a drive mechanism 6 is driven to move the prescribed moving stand-off 5 thereby moving a cable network mount point 4 at this upper end to a position 4' shown in figure. Thus, the mirror surface support face is shaped as shown in 2'. Thus, the mesh mirror surface 1 is revised or changed into a desired shape.

Description

Detailed Description of the Invention [Industrial Application Field] The present invention relates to a mesh mirror surface constituting a radio wave reflecting surface, a cable network supporting the mesh mirror surface, and a support including standoffs for fixing the cable network. This invention relates to a mesh antenna consisting of a structure.

[Prior Art] Figures 4 (a), (b), (c), and (d) are a perspective view of a mesh mirror surface, a perspective view of a cable network, and a plan view of a cable network, respectively, of a conventional example of a truss-type mesh antenna. FIG. 5 is a front view of the antenna assembly, and FIG. 5 is a detailed explanatory view of a part of FIG. 4(d).

This type of mesh antenna is required to be lightweight as it is mounted on an artificial satellite, and a mesh is used for the reflecting mirror surface of the antenna. The cable network 2 is attached to the mirror support surface of the network 2, which cable network 2 is attached to a plurality of standoffs 1 of the support structure truss 3.
5, the main parts were fixed at cable network attachment points 4.

[Problems to be Solved by the Invention] In the conventional mesh antenna described above, the cable network including the mesh mirror surface is fixed to a supporting structure, and in particular, due to severe temperature changes in space, not only the mesh mirror surface itself but also the cable network Thermal deformation that occurs during this process affects the mesh mirror surface, and although materials with small expansion coefficients are used for the mesh, cable, and support structure, there are limits, and it is difficult to maintain the accuracy of the mesh mirror surface. There are drawbacks.

An object of the present invention is to provide a mesh antenna that develops a structure in which changes in the mesh mirror surface that occur during use can be corrected or changed into a predetermined shape by remote control.

[Means for Solving the Problems] In the mesh antenna of the present invention, the attachment point of the cable network that supports the mesh mirror surface is fixed, and the cable network is attached in a direction parallel to the central axis of the support structure that fixes the cable network. , at least one movable standoff slidably secured to the support structure in at least one of a radial direction perpendicular thereto and a tangential direction perpendicular to those two directions; and a drive mechanism that moves according to the direction and amount of the sliding movement.

[By operating the action drive mechanism and moving the movable standoff to move the cable network attachment point to a predetermined position, the shape of the mirror support surface of the cable network is adjusted and the mesh supported on the support surface is adjusted. The mirror surface can be changed into a predetermined shape.

[Example] Next, an example of the present invention will be described with reference to the drawings.

1(a), (b), (c), and (d) are respectively a perspective view of a mesh mirror surface of an embodiment of the mesh antenna of the present invention, a perspective view of the antenna assembly, and a plan view of the cable network; Front view of antenna assembly, second <
4. FIG. 3 is an explanatory diagram of changes in the cable network 2 due to the operation of the movable standoff 5 shown in FIG. 1(d). This mesh antenna is a truss-type mesh antenna that reflects radio waves. A mesh mirror surface 1 to which the mesh mirror surface 1 is attached, a cable network 2 that supports the mesh mirror surface 1 while maintaining the mirror surface shape, and a truss-structure support structure (hereinafter referred to as a lath) that supports the cable stand network 2. 3
, a movable standoff 5, and a drive mechanism 6 for moving the movable standoff 5 to a predetermined position. The mesh mirror surface 1 is a reflection of radio waves having a specific dimension depending on the wavelength, and is attached to the mirror support surface of the cable trunk 2 so that the shape of the mirror surface is formed according to the shape of the mirror support surface of the cable buttwork 2. The cable network 2 has a cable having a net-like structure in order to maintain the mesh mirror surface 1 in a predetermined shape, constitutes a mirror support surface, and has a truss 3 as the main part.
standoff 15 and is fixed to the movable standoff 5 at cable network attachment points 4. Truss 3 is
The structural material is constructed into a truss structure, with standoffs 15 at the top.
It is a supporting structure that projects. Each movable standoff 5 has one cable network attachment point 4 fixed at its end and is attached to the longitudinal members of the truss 3 in one direction (up and down) and in the radial direction (
It is fixed to the truss 3 so as to be slidable in the front-rear direction) via a drive mechanism 6. The drive mechanism 6 is a device that slides a designated movable standoff 5 in a designated direction and amount.

Next, the operation of this embodiment will be explained.

When designing the cable network 2, the direction and amount of movement of the movable standoff 5 for changing or correcting the shape of the mesh mirror surface is calculated in advance.

゛Afterwards, if distortion occurs in the mesh mirror surface 1 on the satellite or it becomes necessary to change the mesh mirror surface 1, the drive mechanism 6 is driven to move a predetermined movable standoff 5, and the J:
The cable network attachment point 4 at the end is 4° as shown in Figure 2.
Alternatively, by further moving the mirror support surface to the 4° position shown in Fig. 3, the cable network shown in Fig. 2 can be changed to the 2' shape, and further changed to the 2°° shape shown in Fig. 3. , whereby the mesh mirror surface 1 can be corrected or changed into a desired shape.

Furthermore, the number of movable standoffs 5 and drive mechanism 6 is not limited to one each.

Furthermore, by using a method such as pulling a specific portion of the cable of the cable network 2, more fine shape control can be achieved. Further, the present invention is also applicable to antennas of systems other than truss-type mesh antennas, such as radial rib or lap rib type antennas.

In particular, when the antenna is of a modular type, it can also be used in combination with an inter-module drive device.

In order to correct the mirror surface from deformation due to thermal deformation and attitude fluctuations and maintain a predetermined shape, it is necessary to instruct the control amount corresponding to the mirror surface deformation predicted on the ground, or to set up a control loop on the satellite to maintain the mirror surface shape in orbit. Possible methods include measuring the deformation and moving the drive mechanism to cancel the deformation. Even when it is desired to change the shape of the mirror surface, this can be achieved by calculating in advance the amount of drive required to achieve the desired shape, and then using commands from the ground or measuring the shape of the mirror surface in orbit.

[Effects of the Invention] As explained above, the present invention enables at least one of the standoffs of the truss that fixes the cable network to be movable so that it can be moved up and down and in the radial direction perpendicular thereto by remote control. By changing the shape of the cable network, the shape of the mesh mirror surface can be changed to a desired shape, and the standard for the coefficient of thermal expansion of the material forming the mesh antenna can be lowered, making it possible to achieve economical results. This makes it easier to maintain the shape of a large on-board antenna in orbit, making it possible to flexibly support services that require changes in antenna patterns.

[Brief explanation of the drawing]

1(a), (b), (c), and (d) are respectively a perspective view of a mesh mirror surface of an embodiment of the mesh antenna of the present invention, a perspective view of the antenna assembly, and a front view of the cable network; The front view of the assembly, FIGS. 2 and 3 are illustrations of changes in the cable network 2 due to the movement of the movable standoff 5 shown in FIG. 1, and FIG. 4(a)
, (b), (c), (d) are respectively perspective views of mesh mirror surfaces of conventional examples of truss-type mesh antennas,
Figure 5 is a perspective view of the cable network, a top view of the cable network, and a front view of the antenna assembly. J4
It is a detailed explanatory view of a part of figure (d). 1-・Mesh mirror surface, 2.2°, 2″′-・Cable network, 3.1
3-)-Russ, 4.4', 4"--Cable network attachment point, 5-
...Movable standoff, 6-drive mechanism, 15-standoff. Patent applicant Nippon Telegraph and Telephone Corporation

Claims (1)

[Scope of Claims] 1. A mesh antenna consisting of a mesh mirror surface constituting a radio wave reflecting surface, a cable network that supports the mesh mirror surface, and a support structure including standoffs that fix the cable network, comprising: One attachment point of the cable network supporting the mirror surface is fixed, and the support structure to which the cable network is fixed has two directions parallel to its central axis, a radial direction perpendicular thereto, and a tangential direction perpendicular to these two directions. at least one movable standoff slidably secured to a support structure in at least one direction thereof; and a drive mechanism for moving said movable standoff according to an individually specified sliding direction and amount. Features a mesh antenna.