NL8006401A - BUILDABLE TREASURY CONSTRUCTION PART. - Google Patents

Description

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Buildable truss construction part.

The invention relates to a truss construction part for space stations with longitudinal uprights and transverse posts connecting the vertices of outer sides.

When constructing large space stations, it should be assumed that 5: *. *., That these will generally consist of truss constructions pre-fabricated on earth and assembled in space. Such truss structures should therefore be relatively small in size for transportation and cost reasons for flight with a space transport device or rocket. Truss structures, however, are parts with a relatively large space requirement and therefore do not meet the requirement of relatively small dimensions. Therefore, in order to be able to use truss structures as pre-fabricated construction parts for space stations, it will be desirable to reduce such parts to a size suitable for transport, e.g. by folding together.

Foldable truss construction parts are already known for the construction of large truss structures. For example, a construction element is known from United States Patent Specification 31 44 215 under the term "STEM" (storable tubular extendible member Λ. - - - = storage-suitable extendable tubular member), which, however, has a strength and stiffness can only be exposed to small loads. Another lattice construction element is the construction element known under the term "ASTRO-Mast", which can be unfolded by hand as well as automatically extended. This "ASTRO-Mast" consists of elastically deformable individual elements connected to each other by longitudinal and transverse pillars, which moreover must themselves have a relatively high elasticity in order to be able to be folded together. It is true that such a requirement could be met with so-called spring materials, but not with the materials currently required in aerospace engineering, such as with carbon 800 6 40 1. -2- fibers or drilling fibers reinforced materials. Since, due to the high dimensional stability and the low thermal deformation degree for space applications, it is not possible to do without such materials mentioned as short plastics, it is not possible to build truss constructions according to the principle of the "ASTRO-Mast" with such materials, namely because of the insufficient elasticity.

The object of the invention is therefore to provide a framework construction part for space stations which can be collapsed to a greatly reduced size for transport in space. According to the invention, the object is achieved in that the longitudinal and transverse posts are pivotally connected to each other and in that the transverse posts comprise a pivotable central section.

With the invention it is possible to build truss structure parts, which can be folded up to very small volumes for transport. In addition, the pivotable parts of the transverse posts and the connections of the transverse posts to the longitudinal posts can be used as a hinge or as a bending hinge, e.g. are designed as a leaf spring. In addition, it is useful to provide the transverse posts with locking devices for locking the unfolded state. Diago-25 can also be used to increase the load-bearing capacity and stiffness. sewing styles, e.g. diagonal cables or extendable diagonal posts are used. In addition, according to this principle, large structures can be joined and folded to the small size required for transport.

The invention will be explained in more detail below with reference to the drawing.

Figure 1 shows a truss construction part in unfolded and folded state,

Figures 2 to 4 show different cross sections for 35 folding truss construction parts.

Figure 5 shows a truss construction part with a diagonal reinforcement.

Figures 6 and 7 each show a truss construction part 800 6 40 1 -3- with diagonal posts.

Figure 8 shows a lattice construction part with a locking device.

Figure 9 shows a truss construction part with an elastic bending hinge.

Figure 10 shows a large framework construction part assembled from several separate truss construction parts.

Figure 11 shows a foldable side surface.

Figure 12 shows a rollable side surface.

The truss construction part shown in Figs. 1a and 1b consists of three longitudinal struts 1 / which are connected at regular intervals by transverse struts 2. The longitudinal posts 1 have the shape of a corner profile, as shown, or are tubes and form the corner points of a triangular cross section. Each of the transverse posts 2 is coupled to the longitudinal posts 1 by means of a hinge 3 arranged at both ends, and each transverse post 2 also provides a different hinge 4 in the middle.

The truss construction part, which also consists of fiber-reinforced materials, can therefore be folded. For this purpose, the transverse posts 2 are folded in their hinges 3 and 4, as indicated by arrows 5, so that the truss construction part obtains the folded-up position shown in Fig. 1 b. In this situation it takes up considerably less space compared to the situation shown in fig. La and is therefore extremely suitable for transport in space.

The truss construction members may also have cross-sections other than triangular cross-sections as shown in Fig. 1. Fig. 2 to Fig. 4 show that it is also possible to construct truss construction parts with diagonal, quadrilateral, hexagonal or arbitrary cross sections. The drawings indicated with a show the folded-out state and the drawings indicated with b the collapsed state.

To increase the load-bearing capacity, the truss construction parts can also be fitted with diagonal 800 6 40 1 -4 posts. Pig.5 shows such a part, in which cables 6 are arranged as diagonal posts. In addition, tension springs 8 are provided between the longitudinal posts 1 and the transverse posts 2, i.e. in an extension piece 7, which automatically unfold, e.g. after releasing a lock. As shown in Figs. 6 and 7, rods 9 which can be changed in length can also be used for the diagonal posts. In Fig. 6, rods 9 are provided for this purpose, which are fixed with a hinge 3 of a. 10 transverse post 2 and are slidably mounted at a diagonally opposite position. In addition, a stop 10 is provided at the sliding ends of the rods 9, which abuts against the associated hinge 3 in the unfolded state. In Fig. 7, the length-adjustable rods 9 used as diagonal posts are fixedly coupled to the hinges 3 and are provided with an extension member 11 in the center. The folding resp. unfolding a truss construction part provided with diagonal posts is in no way affected thereby.

As can be seen from Fig. 8, the transverse posts 2 can also be provided with a locking device 12, to fix the unfolded position. In the exemplary embodiment shown, a locking lip 13 is arranged on one of the transverse posts 2, into which an extension portion 14 of another part of the transverse post can fall. The transverse posts 2 can also be coupled to the longitudinal posts 1 by means of elastic bending hinges 15, and also have an elastic bending hinge 15 in their center.

Leaf springs can for instance be used for this purpose, which can also contribute to the automatic unfolding of the construction.

The lattice construction parts shown in Figures 1 to 9 can also be built up into one large lattice construction part by joining different construction parts together. The advantage of folding, resp. unfolding, as shown in Fig. 10, so that such large structural parts can also be pre-manufactured for use in the space on earth and folded up to a suitably small size for transport. The cross-sections of the truss construction parts have no influence on this construction.

The truss construction parts described above can also be completely or partly covered on their side surfaces by foldable or rollable surfaces. Pig. 11 shows the cross-section of a side-walled lattice construction part with a folding surface 16, the 10 folding places 17 of which are foldably connected by hinges 18. Another embodiment for covering the side surfaces is shown in Fig. 12. These side surfaces 19 consist of this. rollable materials, such as e.g. foils, wire nets or individual wires. These foldable or rollable faces could be used either directly as an antenna surface or as a support structure for solar cells or the like.

The truss construction according to the invention can be manufactured as a statically heavy-duty part with a very high rigidity and can be folded for transport in space with a particularly economical use of space. No restrictions are to be expected from the use of modern materials, such as materials reinforced with carbon fibers, drilling fibers or glass fibers. .25 In addition to aerospace applications, such collapsible lattice parts can, of course, also be used anywhere on earth, where lattice structures of high strength or stiffness are collapsed to a very small volume with virtually complete maintenance of constructional properties for transport or storage. must become.

800 640 1

Claims (17)

1. Truss construction part for space stations with longitudinal posts and the transverse vertices connecting transverse posts, characterized in that the longitudinal and transverse posts (1,2) are pivotally connected and that the 5 transverse posts (2) have a pivotable center section (4,15 ). Truss construction part according to claim. 1, characterized in that the pivotable parts of the transverse posts (2) and the connection of the transverse posts (2). On. the longitudinal posts (1) are designed as a hinge (3,4). Truss construction part according to claim 1, with. characterized in that the pivotable part of the transverse posts (2) and the connection of the transverse posts (2) to the longitudinal posts (1) is designed as an elastic bending hinge (15). Truss construction part according to any one of claims 1 to 3, characterized in that the transverse posts (2) comprise a locking device (12) for fixing the unfolded position. Truss construction part according to any one of claims 1-4, characterized in that the transverse posts (2) comprise springs 20 (8) for automatic unfolding of the truss construction parts. Truss construction part according to any one of claims 1 to 5, characterized in that the truss construction part is provided with diagonal posts (6,9) to increase the load-bearing capacity and / or the stiffness. Truss construction part according to claim 6, characterized in that cables (6) are used for the diagonal posts. 8. Truss construction part according to claim 6, characterized in that for the diagonal posts longitudinally displaceable rods (9) are provided. Truss construction part according to claim 8, characterized in that a stop (10) is associated with the longitudinally displaceable rods (9). 35. Truss construction part according to any one of claims 1-9, characterized in that the cross section of the 800 6 40 1 i v -7 truss construction part has a triangular shape. Truss construction part according to any one of claims 1-9, characterized in that the cross-section of the truss construction part has a quadrangular shape. Truss construction part according to any one of claims 1-9, characterized in that the cross-section of the truss construction part has a hexagonal shape. Truss construction part according to any one of claims 1-12, characterized in that one or more side surfaces are partly and / or completely additionally covered by foldable surfaces (16). 14: Truss construction part according to claim 13, characterized in that the additional surfaces for absorbing forces and / or equipment parts are designed as bending-rigid plates and are optionally also locked on separate hinges (18). Truss construction part according to any one of claims 1 to 13, characterized in that a side surface is completely and / or partly covered by elastic foils, wire nets or individual wires (19). Truss construction part according to claim 15, characterized in that the covering materials (19) are rolled up from the construction part when folded. Truss construction part according to any one of the preceding claims, characterized in that the truss construction part while maintaining the foldability and / or retention. fold-out with other lattice construction parts until one large lattice construction part is combined, 8 00 6 40 1