RU2093934C1 - Reflector (design versions) - Google Patents

Abstract

FIELD: large-area space antennas for communications satellites, space radiotelescopes, side-looking radars, solar concentrators. SUBSTANCE: reflector has central reflecting surface with flexible ribs spring-loaded for scanning and attached on one end to it, as well as flexibl nonstretching guys calibrated in lengh and joined with first ends to tensioning mechanism and with second ends, to ribs. The latter are arranged in parallel to each other in two diametrically opposite directions. Peripheral reflecting surface (first deesing form) is built up of separate stiff rectangular shaped boards arranged in tandem and fixed on ribs for displacement along them. Peripheral surface (second desing version) is provided with shaped jumpers joined with ribs and curtain and placed perpendicular to ribs. When in transit, peripheral reflecting surface iss folded up into two rolls secured on central reflecting surface. EFFECT: enlarged span of tens of meters at small mass and size in traveling position; simplified design; improved accuracy of reflecting surface. 5 cl, 8 dwg

Description

 The inventions relate to large-area space antennas used for communications satellites, space radio telescopes, side-scan radars, as well as large-scale transformable structures mounted on spacecraft and used in solar panels, solar energy concentrators and other deployable structural elements of spacecraft.

 Known deployable reflector (see US patent N4608571, NKI / US 343-781P), containing a Central reflective surface of the ribs, one end connected to the Central reflective surface, and a peripheral reflective surface mounted on elastic ribs.

 The main disadvantage of this technical solution is the inability to manufacture a reflector with a diameter of more than 4.5 m.

 Known reflector (see ed. Certificate of the USSR N1832351, H 01 Q 15/20 1993), selected as a prototype for the claimed technical solution options "Reflector" and containing a central reflective surface, elastic, spring-loaded ribs connected to it by one end inextensible guy wires, the first ends of which are connected to a tensioning mechanism provided with a drive, and a peripheral reflective surface fixed to the ribs. Radial ribs are spring-loaded for coagulation and are located in radial directions. The pull mechanism is located on the back of the central reflective surface. Braces, the first ends of which are connected to the tensioning mechanism, are located with the back of the ribs and passed through the blocks. By means of the pull-up mechanism, the guy wires are shortened and the ribs are straightened until the end surfaces of the blocks touch. The peripheral reflective surface is made of flexible fabric.

 The main disadvantage of this technical solution is the impossibility of using it in large deployable reflectors due to the significant construction height of the ribs. In addition, this technical solution cannot be used to create large-sized antennas operating in the high-frequency region of the spectrum and requiring high accuracy of the reflective surface.

 The technical problem solved by the proposed options for the reflector is the development of a large reflector that allows compact folding in the transport position and reliable deployment to the working position, which is distinguished by its low weight and simplicity of design, ensuring high accuracy of the reflecting surface. In this case, the technical problem solved by the first version of the reflector is the development of a reflector that meets the above requirements, with a rigid reflective surface for operation in the high-frequency range of the radiation spectrum. The technical problem solved by the second version of the reflector is the development of a reflector that meets the above requirements with a flexible peripheral reflective surface for operation in the low-frequency range of the radiation spectrum.

 The technical problem is solved by the proposed reflector options in principle by the same technical way.

 According to the first embodiment, in a reflector containing a central reflective surface, elastic, spring-loaded ribs connected to it at one end, flexible inextensible guy wires, the first ends of which are connected to a tensioning mechanism provided with a drive, and a peripheral reflective surface fixed to the ribs, are new that the reflector is provided with a focal structure mounted on a central reflective surface, while the tension mechanism is fixed to the focal structure. The ribs are parallel to each other in two diametrically opposite directions and are spring loaded for deployment. The peripheral surrounding surface is made of separate rigid rectangular profiled shields arranged sequentially one after another and fixed on the ribs with the possibility of movement along them. The guy wires are etched in length, and their second ends are connected to the ribs through the shields of the peripheral reflective surface, with at least two guy wires connected to each shield.

 According to the second variant, in a reflector containing a central reflective surface, elastic, spring-loaded ribs connected to it, flexible inextensible guy wires connected to it at one end, the first ends of which are connected to a tensioning mechanism provided with a drive, and a peripheral reflective surface made of a flexible web and fixed to the ribs, new is that the reflector is equipped with a focal structure mounted on a central reflective surface, while the tension mechanism is fixed to the focal structure. The ribs are parallel to each other in two diametrically opposite directions and are spring loaded for deployment. The peripheral reflective surface is provided with profiled jumpers connected to the ribs and the web, placed perpendicular to the ribs. The guy wires are etched in length, and their second ends are connected to the ribs through jumpers, with each jumper connected to at least two guy wires.

 In addition, in the reflector according to the first and second options, the first ends of guy wires adjacent to one rib can be connected to a node.

 In the reflector according to the first and second options, the peripheral reflective surface in the transport position of the reflector can be folded into two rolls fixed to the central reflective surface.

 In addition, in the reflector according to the first and second options, the first ends of the guy wires can be connected into nodes, and the tension mechanism is equipped with additional elastic links, stoppers and stops. The number of additional elastic links, stoppers and stops is chosen equal to the number of nodes, while the nodes are fixed to the stoppers, each of which is connected with a drive by an additional elastic link. Holes are made in the stops, through which additional elastic links are passed, and the size of the holes is chosen smaller than the size of the stoppers.

 The combination of formulated features allows you to create a reflector of large dimensions, allowing its compact folding into a transport position and reliable deployment to a working position, characterized by a small weight and simplicity of design with high precision reflective surface. In this case, the first version of the reflector solves this problem using a rigid reflective surface, and the second using a flexible reflective surface.

 The placement of elastic, spring-loaded ribs connected at one end to the central reflective surface, parallel to each other in two diametrically opposite directions, allows the creation of large reflectors that allow the folding of their peripheral reflective surfaces and deployment. At the same time, the ribs spring-loaded for deployment provide not only the deployment of the reflector from the position folded on the front of the reflector, but also in combination with flexible inextensible guy wires, length-calibrated, the first ends of which are connected to the tension mechanism, and the second ends with ribs, provide high accuracy and a given the shape of the reflective surface after the deployment of the reflector.

 The implementation according to the first embodiment of the peripheral reflective surface in the form of separate rigid rectangular profiled shields arranged sequentially one after another and fixed on the ribs with the possibility of movement along them, allows us to solve the tasks for reflectors with a rigid reflective surface.

 The connection with each shield of at least two guy rods in combination with stoppers and stops and the connection to the nodes of the first ends of guy rods adjacent to one rib provides, in addition, high reliability of the successful deployment of the reflector. The connection of the second ends of the guy wires with the ribs through the shields of the peripheral reflective surface eliminates, in addition, the need for an additional drive to align the edges of the boards with each other, since the alignment occurs automatically due to the force arising from the tension of the guy wires.

 The implementation according to the second embodiment of the peripheral reflective surface from a flexible web attached to the ribs and jumpers placed perpendicular to the ribs allows us to solve the problems for reflectors with a flexible reflective peripheral surface.

 The connection with each jumper of at least two braces in combination with stoppers and stops and the connection to the nodes of the first ends of braces connected to one rib ensures the accuracy of the reflective surface.

 Moreover, the execution of the peripheral reflective surface from separate profiled rigid shields that are mounted on the ribs with the possibility of movement along them, according to the first embodiment and the implementation of a flexible reflective peripheral surface according to the second embodiment with transverse jumpers connected to the ribs and perpendicular to them, makes it possible to collapse a peripheral reflecting surface of the reflector in rolls and place in a volume limited by the head fairing of the rocket, a reflector of great effect clear area.

The essence of the proposed technical solutions is illustrated by the following drawings:
FIG. 1 isometric image of the first variant of the reflector,
FIG. 2 is an isometric image of a second variant of the reflector,
FIG. 3 attachment site of a rigid shield of the peripheral reflective surface to the rib,
FIG. 4, 5 the attachment point of the guy to the edge of the reflector with a flexible reflective surface (view from the back of the reflective surface),
FIG. 6 is a schematic illustration of a first embodiment of a reflector in a collapsed position (cross section),
FIG. 7 is a schematic illustration of a tension mechanism,
FIG. 8 is a schematic illustration of the connection of the first ends of guy wires into a knot.

 The first version of the proposed reflector is arranged as follows.

 The reflector according to the first embodiment comprises a central reflective surface 1 and a peripheral reflective surface 2, spring-loaded elastic ribs 3, flexible inextensible guy wires 4, focal structure 5, a tension mechanism.

 The central reflective surface is a power element that perceives inertial loads when the reflector is brought to the OIZZ. As shown in FIG. 1, it can be made in the form of a hard carbon fiber or metal shield made in the form of a rectangle of the required profile.

 The ribs can be made of high strength steel. In fact, the ribs are flat springs, generally straightforward in a free unloaded state. The ribs are spring-loaded at the deployment, that is, in the working position of the ribs and when they are rolled into a spiral position, elastic forces appear in the elastic ribs-springs, which tend to return the rib to a free rectilinear state. At one end, the ribs are fixed on a central reflective surface. They are located parallel to each other by two groups in diametrically opposite directions. In FIG. 1 shows a reflector containing four ribs, with two ribs directed in two diametrically opposite directions, which are connected to the central reflecting surface at its two opposite ends.

 It is advisable to make flexible inextensible guy wires from a material with a low coefficient of linear thermal expansion, for example, from Invar. Braces are tared in length. This is ensured in the manufacture of the reflector by the exact selection of the length of guy wires in accordance with the given profile of the reflector. The first ends of 6 guy wires are connected to the tensioning mechanism.

 The focal structure can be mounted on the Central reflective surface using supports 7.

 The tensioning mechanism should be placed on the focal structure.

 In accordance with the first variant of the reflector, the peripheral reflective surface is made in the form of separate rigid rectangular profiled shields 8 mounted on the edges of the frame. Shields can be made of metal or composite materials. Each shield in the manufacture of the given shape corresponding to the required profile of the reflector. In FIG. 1 shows an example of a reflector with a reflecting surface in the form of a cylindrical parabola, it is possible to perform the surface in the form of a rectangular cut of a paraboloid of revolution with corresponding profiling of the central reflecting surface and shields. Shields are mounted on the ribs with the ability to move along them. This can be provided, for example, as shown in FIG. 3, by placing on the backs of the rigid shields of the ears 9, through which ribs are passed. The gap between the ears and ribs is selected taking into account the possibility of movement of the shields relative to the ribs. Rectangular shields are located on the ribs sequentially one after another. In accordance with the fact that the ribs are placed in two groups in two diametrically opposite directions, the placement of shields sequentially one after another provides a two-leaf design of the reflector.

 The second ends 10 of the guy wires are connected to the ribs through the shields of the peripheral reflective surface. It is advisable to fix the second ends of the guy ropes to the short end of the shield, and skip the rib in the immediate vicinity of this end. At the same time, it is advisable to connect at least two guy wires with each shield, placing them on opposite ends of the boards.

 The first ends of braces adjacent to one rib, as shown in FIG. 1, can be connected to each other in nodes. Thus, the ends of guy wires are connected to one node, the other ends of which are fixed in the immediate vicinity of the same rib.

 The second variant of the proposed reflector is arranged as follows.

 The device and connection with each other of the central reflective surface, ribs, braces and placement of the tension mechanism according to the second embodiment is similar to the device of the central reflective surface, ribs, braces and placement of the tension mechanism according to the first embodiment of the reflector.

 According to the second embodiment of the reflector, the peripheral reflective surface is made of a flexible web, for example, a metal mesh, a metallized film, or a metal foil. The peripheral reflective surface is fixed on the ribs and jumpers 11. The jumpers can be made of metal. In FIG. Figure 2 shows an example of a reflector with a reflecting surface in the form of a cylindrical parabola, it is possible to make a surface in the form of a rectangular cut of a paraboloid of revolution, in this case the jumpers have a corresponding profile. Jumpers are placed perpendicular to the ribs and connected to the ribs of the reflector. According to the second embodiment of the reflector, the second ends of the guy wires are connected to the ribs through jumpers, as shown in FIG. 4, 5. The node for connecting the second end of the guy line to the rib may include a base 12, a roller 13 and a clamp with a screw 14. The base can be connected to the ribs by spot welding 15 or rivets. Each rib is connected with at least two braces.

 The first ends of guy wires adjacent to one rib can be connected to each other, as shown in FIG. 2, in a knot. Thus, the ends of guy wires are connected to one node, the other ends of which are fixed in the immediate vicinity of the same rib.

 In the transport position of the reflector in both proposed variants, the peripheral reflective surface can be folded into two rolls 16 fixed to the central reflective surface, as shown in FIG. 6. In this case, the ribs, together with the peripheral reflective surface, are rolled into a cylindrical spiral. The reflector may be provided with tie straps 17, with which the rolls are fixed on a central reflective surface. Tapes cover rolls, one ends of tapes are fixed on the central reflecting surface. The second ends of the tapes through a system of blocks can be connected to a device for fixing 18 rolls in the transport position, providing the release of tapes and adjusting the speed of opening of the ribs.

 It is advisable to place the tension mechanism with the drive on the focal structure. In addition to the drive 19, it may include a winding drum 20 connected by a mechanical transmission to a drive with which the first ends of the guy rods are connected through a system of blocks 21. In addition, the first ends of the guy wires can be connected in knots, and the tensioning mechanism is equipped with additional elastic links 22, stoppers 23 and stops 24. The number of additional elastic links, stoppers and stops is chosen equal to the number of nodes. The nodes are fixed on the stoppers, which are connected with the drive by additional elastic links, and holes 25 are made in the stops, through which additional elastic links are passed. The size of the holes is chosen smaller than the size of the stoppers. Additional elastic links can be made of nylon cord. As shown in FIG. 8, the stopper can be made in the form of a spear tip, inside which a knot is placed, and an emphasis in the form of a funnel, the cone angle of which is equal to the angle of the funnel cone. An additional elastic link at one end is connected to the stopper and passed into the hole located at the base of the funnel. Through the block system, the other end of the link is fixed to the winding drum. The emphasis should be placed on the focal structure.

 The proposed reflector options work as follows.

 In the manufacture of the reflector, the first ends of the guy rods are connected into knots, embedded in the stoppers, which are installed in the stops. Then each guy is adjusted to a length at which the peripheral reflective surface assumes a predetermined reflector shape. This can be done, for example, by rotating the rollers and then fixing them with screws.

 In the transport position, the ribs, together with the peripheral reflective surface attached to them, are folded into two rolls and fixed on the central reflective surface. Before folding the reflector, additional links are etched to the required length, guy wires and etched ends of additional links are laid on the surface of the reflector and the supports of the focal structure. In this position, the rolls can be prevented from being unfolded with tie rods.

 In the collapsed position, the reflector is put into the orbit of the artificial satellite. After putting into orbit, the operation of deployment of the reflector is carried out. When stripping strips, the rolls are released and, due to the elastic forces of the ribs, the rolls begin to unfold. The roll deployment speed is limited by tie straps and a regulator. After the ribs are deployed, the predetermined shape of the reflector is ensured by pulling the drive units until the stoppers touch the stops. In this position, the length of the guy wires and the shape of the reflector will correspond to those in the manufacture.

 In the first embodiment, the shields of the peripheral reflective surface during manufacture are profiled in accordance with the specified profile of the paraboloid. In the free state of the ribs and when folding into rolls, the shields of the peripheral reflective surface are located at a certain distance from each other. In the process of pulling up, the shields move towards each other with the formation of a continuous two-leaf peripheral reflective surface.

 In the second embodiment, the peripheral reflective surface is solid. Thus, the predetermined shape of the reflective surface of the reflector is ensured by the corresponding profiling of the central reflective surface, each shield, or, for the second option, jumpers, adjusted in the manufacture of guy lengths and elastic forces of the ribs, which in combination allows you to restore the reflector shape in space, similar to that made.

 The proposed inventions can be used in space technology in the development of side-scan radar antennas, space radio telescopes and communication satellite antennas with a span of up to ten meters with minimum weight and dimensions for the given dimensions in transport position. The proposed designs can be made at enterprises specializing in the manufacture of space technology.

Claims (5)

 1. A reflector comprising a central reflective surface, elastic, spring-loaded ribs connected to it at one end, flexible inextensible guy wires, the first ends of which are connected to a tensioning mechanism provided with a drive, and a peripheral reflective surface fixed to the ribs, characterized in that the reflector is provided with a focal structure mounted on a central reflective surface, while the tension mechanism is fixed to the focal structure, and the ribs are parallel to each other in two diametrical in opposite directions and spring-loaded for deployment, while the peripheral reflective surface is made of separate rigid rectangular profiled shields arranged sequentially one after another and fixed on the ribs with the possibility of movement along them, while guy wires are etched in length, and their second ends are connected to the ribs through shields of the peripheral reflective surface, with at least two guy wires connected to each shield.  2. A reflector comprising a central reflective surface, elastic, spring-loaded ribs connected to it at one end, flexible inextensible guy wires, the first ends of which are connected to a tensioning mechanism provided with a drive, and a peripheral reflective surface made of a flexible web and fixed to the ribs, characterized in that the reflector is equipped with a focal structure mounted on a central reflective surface, while the tension mechanism is mounted on the focal structure, and the ribs are parallel but to each other in two diametrically opposite directions and are spring loaded for deployment, and the peripheral reflective surface is equipped with profiled jumpers connected to the ribs and the web, placed perpendicular to the ribs, while the guy wires are length-etched, and their second ends are connected to the ribs through the jumpers, each jumper connected to at least two guy wires.  3. The reflector according to claim 1 or 2, characterized in that the first ends of the guy wires adjacent to one rib are connected in a knot.  4. The reflector according to claim 1 or 2, characterized in that the peripheral reflective surface in the transport position of the reflector is folded into two rolls fixed to a central reflective surface.  5. The reflector according to claim 1 or 2, characterized in that the first ends of the guy wires are connected into nodes, and the tensioning mechanism is provided with additional elastic links, stoppers and stops, the number of additional elastic links, stoppers and stops being chosen equal to the number of nodes, while the nodes fixed on the stoppers, each of which is connected with an additional elastic link with the holes, and holes are made in the stops, through which additional elastic links are passed, while the size of the holes is chosen smaller than the size of the stops.

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