HU176632B - Water-proof,bearing thin-shell construction of optional span and length assembled from members - Google Patents

Abstract

Load-bearing and water-tight roofing comprises support elements 1 of inverted channel form. The centre line of each element 1 may be flat, or curved in the vertical plane to the extent that the height of the arch above the chord is at most 10% of the length of the element. The elements 1 are interconnected end-to-end by spigot and socket joints. Sheet roofing elements 9 of, e.g. plastics, which are flat or arcuate in cross-section are seated on and fastened to the support elements at overlapping joints. The width of the sheet roofing elements 9 is between one quarter and two thirds of their length. Cross-ties 5 may be employed between the support elements 1, which may be of glass fibre reinforced polyester resin. <IMAGE>

Description

FIELD OF THE INVENTION The present invention relates to an arbitrarily spaced and longitudinal, load-bearing and water-tight space-covering shell structure made up of elements, preferably plastic support and shell elements and fasteners.

There are many types of spacer structures made of glass fiber reinforced polyester resin elements. It is justified by the fact that a few millimeters of elements made of a few millimeters of wall thickness can be used to assemble a space-covering structure capable of bridging large openings, with or without light transmission, with or without thermal insulation. Of the narrow elements made of fiber-reinforced plastics, one or two circular or elliptical arc pieces provide the support, i.e., the arc pieces at least a quarter, ii. they are the size of a quarter ellipse. (Hintersdorf: Tragwerke aus Plasten, pp. 31-33, Saechtling: Bauen mit Kunststoffen, pp. 208-209 and 454, IfL-Mitt. 5/1966/12, p. 448, Rühle: Raumliche Dachtrag- 'werke, Konstruktion und Ausführung, 1970, Bánd 2, p. 138, Sebestyén: Lightweight construction, Bp, 1972, pp. 41-42.

A common drawback of known structures is that the bridging of the support into one or two pieces greatly limits the bridging size but also results in a very large element length, which causes great difficulties in manufacture, transport, storage and assembly. This also applies if the holders are the building:

they are parallel to the longitudinal direction of the span and longitudinal spaced shell structure. In addition, a single element can only support a single support, requiring a wide variety of size elements and manufacturing templates. Finally, structural solutions 5 that can only be made of metal require costly corrosion protection.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a space cover consisting of elements of favorable size for serial production, transport, storage, and assembly, suitable for bridging large and custom-sized supports, waterproof, heat-insulating and corrosion-resistant, disassembly and reassembly. it also allows for natural illumination.

The present invention is based on the discovery that a simple, easy-to-use and easy-to-use, low-battery set of plastics material, preferably fiberglass polyester, can be assembled in a system and numbers connected to the free aperture to be covered to provide the desired spacing and length.

The shell structure according to the invention consists in its support elements being open boxes extending downwards, the center of which is curved in the vertical plane so that the height of the arc above the string does not exceed 10% of the length of the element. Its end elements are downwardly expanding and at least partially open boxes. Preferably, the support and end members have a joint extending at one end, the outer contour of the cross-section of this extension being no larger than the internal contour of the cross-section of the elements. The support members and end members may be used to lay and fasten the shell elements, sometimes by overlapping, to the supporting arches formed by means of connecting joints and fasteners or by gluing. One dimension of the shell members is the sum of the axial spacing of the support arches and the overlap, and the other size is preferably between one quarter and two thirds of the former.

In the embodiment of the shell structure according to the invention, the connecting members and fasteners are made of the supporting members and end members, respectively. brackets formed by gluing are joined to one another by their belts or extensions and, if necessary, carry shell elements.

The brackets, respectively. under the end members straps fastened to their belts may be used as needed. If necessary, insulating boards are located on the belts of the supports and end members. The soles rest on the support by inserting a ledge element.

In the drawings depicting an exemplary embodiment of the shell structure according to the invention, Fig. 1 is a side view of a variant of the support element, Figs. longitudinal section of the

Fig. 5 is a cross-sectional view of the former, Fig. 6 is a longitudinal section of the roof structure, Fig. 7 is a cross-section of the former, Fig. 8 is a top view, Fig. 9 is a side view of another version Fig. 12 is a side view of the end member, Fig. 13 is a cross-sectional view of the former, Fig. 14 is a longitudinal section of this version of the roof structure, Fig. 15 is a cross-sectional view and finally Fig. 16 is a top view.

1-8. 9-16, the shells are in any case used, while the shells 9-16. In the alternative embodiment of Figures 1 to 4, the retaining arches are arranged side by side and separate shelling may be omitted.

1 or 1 piece of plastic. la bracket extending downwards and open box, two lower 2 and lower box With belts 2a and 2b. 1 and 1 respectively. The brackets 3 are provided at one end with pre-holes 3 and at the other end with 4 or 4 sealed ends. Connector 4a is provided. 4, 4a connector nipple II-II cross section of the outer contour of the same size as one, carrier element la II cross section of the inner _körvonal-: size. The support elements 1, la are connected by placing the end of one of these elements with the drill bit 3 on the connector extension 4, 4a of a similar element and then joining and screwing or gluing them together. If necessary, the attachment site <is fastened with a strap 5 which is screwed or glued to the belts 2, 2a, 2b of the two adjacent members. By means of the same strap 5, the bracket 1, la can be reinforced in other places. Watertightness interest- _{<átlaminálhatjuk} in the screw connection.

The ends of the arch formed by the support members 1, 1a are formed by one end member 6, 6a, one end of which is closed and has a base surface 7, 7a, with which the end member 6,6a lies on the support 8 _and preferably the other end a connector 4, 4a for attaching the end member 6, 6a to the support member 1, la. The support 8 is a reinforced concrete or steel structure, 5 containers, space elements, etc. may.

The bracket is thus two 6 and 4 respectively. 6a and a number of support members 1, la corresponding to the spacing. One of the brackets 1, la must be cut off the connector extension 4, 4a, or, if the spacing differs from the module sizes determined by the length of the support bracket 1, la, one of the brackets 1, la towards the extension 4 4a pieces must be removed (7,

Figures 15, 16 1A).

For the separate sheathing of the roof structure, a sheathing element 9 made of plastic is used, the length of which corresponds to the axial distance of the supporting arches, including the necessary overlap. The shell 9 has a cross-section following the curvature of the support 1 and has a longitudinal section in the form of a wavy line having a size of 5-15 m ² which is favorable for manufacture and transport. The shell member 9 is fastened by riveting to the support arc and to the adjacent shell member 9 overlapped therewith. If it is necessary to insulate the roof structure, it is necessary to use 2 or 3 roof insulation. this can be done by insulating boards 10 on their 2a and 2b.

9-16. In the embodiment of Figs. 1 to 4, the brackets 1a are joined to each other by inserting the belts 2b into the belts 2a (Fig. 14), so that a watertight connection 13 is established and the shell elements 9 can be omitted unless otherwise justified.

The roof capacity of the roof structure allows the suspension of a conveyor belt, running cat or other conveying equipment. They serve their 2 and. steel beams 11 attached to belts 2a and 2b.

In an exemplary embodiment, the centerline of the support 1 is 7.5 m with a radius of curvature of 20 m and an arc height of 350.5 mm, or 4.7% of the arc length. The 4 extension joints extend the center line's arc length by 350 mm. The center line of the end member 6 has an arc length of 1800 mm, to which is also added a 350 mm long connector 4. The elements 1, 6 have a cross-sectional height of 800 mm, a width of their belts 2 of 200-200 mm and a total width of the elements of approximately 1400 mm.

With two brackets 6 and three brackets 1, openings 24 m, four brackets 30 m and five brackets 1 34 can be bridged. Any intermediate spacing, as mentioned above, can be accomplished by cutting one of the supports 1 to the required length, while also removing the connector 4 from it. so e.g. in the case of Fig. 7, the 28 m opening is bridged by shortening the portion of the support member 1A to 4966 mm by cutting off the portion containing the connector 4. The shell member 9 is 6,500 mm long and has a width of 2150 mm including the overlaps of the support arches, 6 m and overlapping.

In another embodiment of the example, the distance between the center plane of the two adjacent support members 1a is 1500 mm. If 9 shell elements are used, the size including the overlaps is 2000 x 4150 mm.

The main advantages of the shell structure according to the invention can be summarized as follows:

Batteries can be serially manufactured from plastic, with low space requirements (stackable) and weight, allowing for a more economical on-site production instead of on-site production. The structure is simple to install and does not require complicated and expensive scaffolding. Waterproofing and thermal insulation are solved, so there is no need to make insulation from coiled materials. Its appearance is modern, it can be made of colored, translucent or covering material, its material is corrosion resistant. It can be disassembled, repositioned and reused in other sizes. Finally, it requires a small number of parts to be stocked.

Claims (5)

Cavity shell structure comprising, preferably plastic, support and shell elements and fasteners, of arbitrary span and length, with load-bearing and watertight shell structure, characterized in that its support elements (1, 1a) are open at the bottom, open at the bottom, a part of which has a centerline curved arc height above the string not exceeding 10% of the length of the element, and end portions (6, 6a) which are widening boxes at least partially open at the bottom, with support and end portions (1, la, or 6, 6a) preferably having at one end a connecting extension (4, 4a), the outer circumference of which has a cross-section (II-II) not larger than the inner circumference (0-1, III-III) of the elements. 5, the connecting members (4, 4a) and the connecting members (4, 4a) and the connecting members (4, 4a) and fasteners by means of adhesives or gluing are assembled and, if necessary, they are laid overlapping and fastened with fasteners (10). 9) one of its dimensions is the sum of the axial spacing of the support arches and the overlap, while the ratio of their shorter and longer sides is preferably between one quarter and two thirds. (Priority: July 27, 1978) 15 An embodiment of the shell structure according to claim 1, characterized in that the connecting elements (4a) and the fastening elements (4a) and the fastening elements (4a) are formed from the support elements (1a) and end elements (6a). the support arches formed by gluing together with their curved profile belts (2a, 2b) are formed into one another by means of a watertight connection (13) and, if necessary, carry shell elements. (Priority: 09/10/1979) Embodiment of the shell structure according to claim 1, characterized in that the support elements (1) and / or the support elements (1) and / or (3) respectively. 25 are provided with straps (5) attached to their belts (2) under the end members (6). (Priority: July 27, 1978) Embodiment of the shell structure according to claim 1 or 3, characterized in that the supporting elements (1) and / or the support elements (1) and / or (3) respectively. insulating on the belts (2) of the end members (6) There are 30 boards (10). (Priority: July 27, 1978) 5. Shell structure according to any one of claims 1 to 6, characterized in that there is a ledge element (12) between the base surfaces (7, 7a) and the support (8). (Priority: 09/10/1979)