DE3643963A1 - Load-bearing framework of a reflector - Google Patents

Abstract

In the case of a load-bearing framework of a reflector (7) which is connected to a foundation - preferably so that it can rotate about a vertical axis (13) - and is constructed as a lattice which is composed of triangles and has a triangular horizontal base frame (1) one of whose rods runs parallel to a horizontal axis (8) about which the reflector (7) is arranged such that it can pivot on the upper end of the load-bearing framework, a simple and cheap design is achieved in that the load-bearing framework has at its upper end a triangular frame (4) which is in the opposite direction to the base frame (1) and whose corners (a, b, c) are in each case connected to the corners (A, B, C) of the base frame (1). <IMAGE>

Description

The invention relates to a support frame Reflector with the features according to the preamble of Claim 1.

Supporting frames for reflectors, which as a truss in Steel structures are formed in numerous Chen designs and different sizes known. The reflectors, usually called parabolic mirrors are usually used as Communication antennas or radio telescopes are on their convex side by a lattice-like support construction held, which in turn on the support frame around a horizontal axis, the so-called elevation axis, are pivotally hinged. Next is the support frame such dish antennas in most cases on one Circular rail around a vertical axis, the so-called Azimuth axis, rotatably supported, what as a wheel and track System is called. The well-known frames are due to their static indeterminacy and numerous Complex design and manufacturing hubs.

A support frame of the type mentioned is set up in the Fucino room center "Fucino 3 " in Italy and belongs to an antenna system operated by Telespazio SpA, Rome. This previously known support frame has a square intermediate frame running horizontally to the triangular base frame, on the corner points of which braces are supported in pairs, which form two triangular disks and carry the two bearings for the pivotable mounting of the reflector at their tip. The side of the support frame facing the reflector forms two quadrilaterals with inner struts. The system of this support frame is therefore often indefinite and therefore difficult to calculate.

The invention has for its object a support frame to create that compared to the previous ones Support frames are constructed more simply and with the least possible manufacturing effort. The solution to this Task lies in the characteristics of the characteristic part of claim 1.

The advantages associated with the invention are in primarily in the fact that a statically determined load system is procured with a minimum number from bars. Nonetheless, is the greatest possible Stability ensures that the support frame without exception composed of triangular discs is. The total of eight triangular discs are in the Normally with only twelve straight lines Striving formed. Only if the kink lengths the bars of the side wall disks become too large it is appropriate to use intermediate struts so that the Sidewalls in four - or a multiple of four - further triangles can be divided.

The new support frame can be used for practical all reflectors, both in terms of their shape as also with regard to their area of application. You can thus not only in communications engineering and Radio astronomy, but also for capturing Solar energy can be used. She is preferred Use for smaller systems.  

The new support frame can move around a vertical axis rotatably arranged, but also firmly anchored. The latter is preferably provided for when the reflector only around a horizontal axis is pivotally arranged.

The fact that the bearing for the pivotable bracket of the reflector at two corner points of the upper frame the forces can be arranged directly in the Cornerstones initiated and derived via the bars will.

The third corner can be particularly advantageous of the upper frame one hinged to the reflector Arrange length adjustment swivel, whereby in the same way the forces are transferred to the rods will.

Further advantageous configurations in the invention are the subject of claims 4 to 9.

In the drawing, several embodiments of the Invention shown schematically. It shows:

Fig. 1 is a provided with a parabolic reflector and rotatably supported on a circular rail support frame in perspective view,

Fig. 2 shows the supporting frame according to Fig. 1 in the vertical central section,

Fig. 3 shows the same support frame in plan view,

Fig. 4 is a running rail on the circular wheels chassis in a larger scale, in a vertical section,

Fig. 5 shows another embodiment of a support frame with a centrally disposed in the base frame rotary bearing in perspective view,

Fig. 6 shows a supporting frame with a arranged at the corner of the base frame rotary bearing in perspective view,

Fig. 7, the pivot bearing in the direction of arrow VII in Fig. 6 and

Fig. 8 is a non-rotatably arranged support frame in a further embodiment with intermediate struts in an oblique view.

As can be seen from FIG. 1, the supporting frame shown has a triangular base frame 1 with corners A , B , C , on each of which a wheel chassis 2 is arranged, which is supported on a circular rail 3 arranged horizontally on a foundation. Parallel to the base frame 1 , the support frame has at its upper end a frame opposite the base frame 1 with three corners a , b , c , the corners of the same name of the base frame 1 and the top frame 4 lying opposite one another in space. At the corner points a and b of the upper frame, a bearing 5 is arranged, on which the supporting structure 6 of a reflector 7 is pivotally articulated about a horizontal axis 8 (elevation axis). The corner point c forms the articulated base for the drive 9 of a spindle 10 , which is articulated with its end 11 to the Tragkonstruk tion 6 so that the reflector when actuating the spindle supply can perform a movement in the usual way, for example by one horizontal to a vertical position of its axis of symmetry. Between the base frame 1 and the upper frame 4 three triangular frames are made by six rods 12 , which form a total of six adjoining triangular wall panels. The three wall disks pointing upwards run, as shown in FIG. 3, in a vertical plane. The base frame 1 and the upper frame 4 each form an equilateral triangle, through the center of gravity of which a vertical axis 13 (azimuth axis) extends, around which the support frame can be rotated on the circular rail 3 .

Depending on the size of the system, the wheel trolleys 2 have at least one wheel 15 which is mounted about a horizontal axis and which is supported on the circular rail 3 fastened to a foundation 16 . For centering and absorption of the horizontal forces during the rotary movement about the vertical axis 13 , support rollers 17, which surround the head of the rail 3 , are mounted on the base frame 1 in pairs ( FIG. 4).

In the embodiment of FIG. 5, the base frame 1 of the support frame has a central pivot bearing 18 , the eye part of which is fastened to the foundation of the system in the center of the circular rail 3 . The pin part of the pivot bearing 18 is connected via a strut 19 to the three corner points of the base frame 1 . The wheel trolleys 2 'need by the central guidance of the pivot bearing 18 no on the circular rail 2 ' supporting support rollers. The upper frame 4 'is made smaller in this embodiment compared to the embodiment according to the previous example, so that the wall panels of the side walls are all inclined inwards, ie towards the vertical axis 13 .

In the embodiment of FIG. 6, the vertex C of the base frame 1 is provided 'of the supporting frame with a pivot bearing 18', while the two vertices A and B each having a wheeled undercarriage 2 'roll without lateral support. The pivot bearing 18 'is so out that it - in contrast to the pivot bearing 18 of the previous embodiment - can also absorb vertical support forces. For this, the support frame only requires two wheel trolleys 2 '. In this embodiment, the vertical axis 13 is shifted further towards the reflector 7 , which is advantageous for certain applications. The same applies to the further possible training, in which the vertical and horizontal axes cross.

Fig. 8 shows a support frame, the upper frame 4 '' is not parallel to the base frame 1 and the side walls are stiffened by a triangle so that the rods 12 'are each halved by a node 20 . The same applies to the basic frame 1 and the upper frame 4 ''. The corner points A , B and C of the base frame 1 are firmly anchored to the foundation in this embodiment, while the corner points a and b of the upper frame 4 '', which are higher than the corner point c and the two bearings 5 for the pivotable holder of the reflector, not shown, are arranged higher. This construction creates a larger space on the back of the reflector.

Claims (10)

1. Support frame of a reflector, which - preferably rotatable about a vertical axis - is connected to a foundation and is constructed as a truss composed of triangles, which has a triangular horizontal base frame, one of whose rods runs parallel to a horizontal axis about which the reflector at the upper end of the support frame is pivotally arranged, characterized in that the support frame at its upper end has a base frame ( 1 , 1 ') opposite the triangular frame ( 4 , 4 ', 4 ''), the corner points of which ( a , b , c are each connected to the corner points ( A , B , C ) of the base frame. 2. Support frame according to claim 1, characterized in that the bearings ( 5 ) for the pivotable mounting of the reflector ( 7 ) are arranged at two corner points ( a , b ) of the upper frame ( 4 , 4 ', 4 ''). 3. Support frame according to claim 2, characterized in that at the third corner point ( c ) of the obe ren frame ( 4 , 4 ', 4 '') on the reflector ( 7 ) articulated length-adjusting device (spindle 10 ) is pivotally arranged. 4. Support frame according to claim 1, 2 or 3, which is supported with wheels on a circular rail, characterized in that the trolleys ( 2 ) laterally around the head of the rail ( 3 ) encompassing support rollers ( 17 ) rotatable about a vertical axis. 5. Support frame according to claim 1, 2 or 3, which is supported by wheels on a circular rail, characterized in that the vertical axis ( 13 ) by a rail in the center of the circle ( 3 , 3 ') and on the base frame ( 1 , 1st ') On the one hand and on the foundation on the other hand arranged pivot bearing. 6. Support frame according to claim 5, characterized in that the pivot bearing ( 18 ') on the reflector ( 7 ) facing corner point ( C ) of the base frame ( 1 ') is arranged. 7. Support frame according to claim 5, characterized in that the pivot bearing ( 18 ) is arranged in the center of the base frame ( 1 ) and connected via struts ( 19 ) with the corner points ( A , B , C ). 8. Support frame according to one of the preceding An sayings, characterized in that the upward tapering triangles on the sides walls run in a vertical plane. 9. Support frame according to one of the preceding claims, characterized in that the upper frame ( 4 , 4 ') to the base frame ( 1 , 1 ') is arranged in parallel. 10. Support frame according to claim 8 or 9, characterized in that the base frame ( 1 , 1 ') and the upper frame ( 4 , 4 ') each form an equilateral triangle.