FI56897C - INNERTAK - Google Patents

Description

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Patent c9ddolat '(51) Kv.ik.' / Int.a. · F 24 · H 9/08 E 04- B 5/55 ENGLISH —FINLAND (21) l * t * nttlhak # «mi» —Pw «nttn .etinJn «1 ^ 3 ^ / 72 (22) HtkamitpUvl —AmBknlnpdig 19 * 05.72 '' (23) Alkupllvft — GlMghttsdag 19.05.72 (41) Tullut julklMkii - BlIvK offuntllg 23, 11.7 2

Patent · och regirterttyrelsen '7 Anteion uttagd och uti ^ kriftM puumnd 31.12.79 (32) (33) (31) Pyydetty «tuolkeu * —Begird priorhat 22.05 * 71 The Republic of Germany 2125538.9 (71) Stramax Aktiengesellschaft, Sihlfeldstrasse 10, CH 8003 Zurich,

Switzerland-Switzerland (ÖH) (72) Molf Leu, Biel b / Basel, Switzerland-Switzerland (CH) (71 *) Forssan & Salomaa Oy (5 * 0 Ceiling - Innertai

The invention relates to a ceiling with heat pipes supported by racks to be attached to the roof frame and provided with buckets for supporting the ceiling tiles, which racks consist of rigid units assembled in several parts.

A well-known ceiling that can be manufactured by the dry construction method is marketed under the name "Stramax" (trademark). In this known ceiling, gypsum building tiles are suspended from the ceiling by T-rails which go into the edge grooves in the building tiles and by wires arranged on the T-rails. The heating pipes are in slabs and elongated U-shaped bracket sections, the branches of which are connected to aluminum sheets cast on gypsum tiles. On the other hand, the wet-laid ceiling "Stramax" (trademark) is also known, in which rod-shaped round irons are suspended from the ceiling and pipes are placed on the wheel irons. Elongated U-shaped sections of the lamellae with laterally projecting wings are placed on the pipes, which are cast into the ceiling.

In a dry-laid ceiling as defined at the beginning, changes in length occur in the pipes, which depend on the temperature of the water flowing through. These changes in length should not be passed on to building tiles with a different coefficient of expansion than pipes. If the building tiles are a frangible material, e.g. gypsum, then the lamellae cannot be rigidly attached to the building tiles, as the expansion of the lamellae would lead to cracking of the tiles. The ceiling should also withstand compression from below so that, for example, partitions can be supported on the ceiling. It is further desirable to be able to make the tiles independently of the tubes and lamellae to assemble the parts only at the point of use.

The object of the invention is to provide a dry-roofed ceiling as defined above in such a way that it can be mounted and supported in a simple manner from tiles, chutes, pipes and ceiling-mounted means with respect to the pressure from below, and its tiles are supported by pipes.

The invention is characterized in that of said parts the holding plates are provided with an upturned notch for the heating pipes so that they can be placed on racks from above, in addition the holding plate has a bent part which can be lifted and lowered to an angle bracket fixed in the roof frame. depending on their distance from the roof and that the brackets are known per se to be placed over the heat pipes between the holding plates so that the roof plates can be screwed from below, mainly to the branches of the brackets.

In order to manufacture the ceiling according to the invention, the structures supporting the entire system are attached to the ceiling. The pipes are then placed in place from above, so that the adjustability of the hangers allows the pipe system to be brought to the correct height, thus providing axial displacement. Lamellas are placed on top of the pipes, on which the plates resting from below, which in turn are likewise fixed by means of corresponding metal hangers.

It is expedient for large-area tiles to be attached to the singers, for example with screws. This method of attaching the lamellae to the pipes is used whenever the lamellae are of such a substance that there is no risk of the tiles being damaged due to changes in the temperature of the tiles or lamellae required by the temperature. This is the case when the tiles are, for example, plasterboard tiles or metal cassettes or metal tiles.

If the tiles are gypsum, it is expedient for the T-shaped holders, the flange of which goes to the edge grooves of the gypsum tiles, in each case to have an lug which is suspended in one pipe. In this embodiment of the invention, the gypsum tiles are freely movable relative to the chants and the pipes and yet suspended from the pipes.

When, as far as possible, the lamellae have to cover almost the entire length of the tubes 3 56837 in order to obtain good heat transfer, the points in the tubes where the rigid structures can adhere to the tubes are relatively narrow, so that the rigid structures themselves are kept narrow. As such, the rigid structures are made of sheet metal, for example, and have an upwardly open notch in which the pipes are placed.

It is advantageous when the per se rigid structure in each case consists of a pipe-receiving holding plate and a ceiling-mounted corner plate, which are movable relative to one another and can be fastened to one another. In this way, the distance of the pipe in the rigid structure from the ceiling can be precisely set. In addition, the distance of the ceiling from the ceiling can be chosen arbitrarily with a corresponding design of the rigid structures.

In the ceiling according to the invention, hot water for heating or cold water for cooling can be passed through pipes, which for simplicity are referred to herein as heating pipes. Protection is required not only for a fully finished ceiling, but also for parts shaped according to the invention, in particular for rigid structures per se, which are shaped to support pipes and to support slabs.

The drawing shows preferred embodiments of the invention and shows Fig. 1 a ceiling with building tiles and heating pipes, section along line II in Fig. 2, Fig. 2 section along line II-II in Fig. 1, Fig. 3 in a slightly larger size than Fig. 2 section on line 2 in Fig. 2. III-III, Fig. 4 a ceiling with building tiles and heating pipes, and in which the building tiles and their fastening are shaped differently than in Fig. 1, Fig. 5 a section along the line VV in Fig. 4, and Fig. 6 a section along the line VI-VI in Fig. 4 along.

In the ceiling according to Figures 1-3, rectangular gypsum boards 2 are arranged below the roof 1 at a distance from it in the same plane, which are opposite their edges and the construction of which is known per se and the size of which can be chosen independently of the fixing to the ceiling. Metal pipes 3 are arranged parallel to each other and at a distance from each other between the roof 1 and the tiles 4 56897, which are parallel to the tiles and through which hot or cold water flows. The supply of water to the pipes is not shown, as a person skilled in the art can carry it out as he wishes.

The iron or aluminum plate is provided with lamellae 4, each of which has a bent U-shaped bracket part 5 and a wing 6 bent on each of its branches, which is at approximately a right angle to the branch, whereby both wings of the lamella are in the same plane. Similar lamellae 4 are also known from the so-called "Stramax" (trademark) system, but in it the lamellae are made of two parts which surround half of the pipe. In the present invention, the slats are in one piece and the roof tiles act as a load-bearing fastening to be attached to the pipe system. The wings 6 of the lamellae 4 are rectangular. The lamellae are pushed onto the tubes from above, whereby the bent point of the bracket part 5 rests tightly on the tube, and the branches of the bracket part face downwards towards the wings 6. The lamellae 4 extend along the pipes 3 and leave only the slit-like pipe sections free so that the pipes are almost completely covered by the lamellae. The wings 6 of the lamellae contact the gypsum board slabs 2 on their surface and are fastened to them with screws 7 so that the slabs hang from the tubes 3, whereby the tubes are axially displaceable in the bracket parts 5 of the lamellae.

At the slit-like points left free by the lamellae 4, there is a tube 3 upwards in the open notch of the retaining plate 8, which retaining plate is a kind of hook. The tubes 3 are axially displaceable relative to the holder plate. The holder plate 8 is provided with a shoulder 9 from the plate, which is bent at a right angle and arranged parallel to the tube. One leg of the corner plate 10 is fastened to this shoulder with screws, whereby by means of a slit-like long hole the angle plate can be adjusted relative to the shoulder so that the distance of the other branch of the angle plate from the tube 3 is selectable. This second leg of the corner plate 10 is fixed to the ceiling 1 by screws. The plate 2 is thus supported on the ceiling 1 from below by means of a holding plate 8 and a corner plate 10 with respect to compression.

The embodiment according to Figures 4-6 differs from the embodiment according to Figures 1-3, in particular with respect to the fastening of tiles and tile pipes, which are fixed to the ceiling in the same way as in the embodiment according to Figures 1-3. The wings 6 of the lamellae are detached therein by rectangular plates 11 and are not screwed to them. Pins or pins can be pushed through the branches of the lamella bracket parts 5 so that the brackets are not pushed upwards from the tubes due to the pressure applied to the lower surfaces of the lamellae 5 from below. The gypsum boards 11 can adhere to each other at their points of contact, i.e. be connected to each other.

At the junction of the four gypsum boards, a T-shaped holder 12 is arranged in each case, which is known per se and is arranged in an inverted T. The flange of T 5 56897 goes into the grooves 13 of the plates 11 on each side and thus supports four plates, as shown in Fig. 5. Arranged on the "arm" of the T-shaped holder 12 is an upwardly extending shoulder 14 with an open U-shaped notch extending in the direction of the plates 11 on one side, into which the tube 3 is inserted. The T-shaped holder 12 is thus provided with a hook-like structure by means of which the plate 11 is suspended from the tube 3, whereby the plate can rest upwards on the holder plate 8 when the pressure acting on the plate is applied from below.

The ceiling according to the drawing is installed by first attaching the corner plates 10 with their retaining plates 8 to the ceiling 1. The pipe system is then installed, i.e. the pipes are placed on the retaining plates 8, whereby the distance of the pipes from the ceiling to the retaining plates can be precisely adjusted. The lamellae 4 are then pushed onto the tubes 3 and secured with pins relative to the rise. Finally, the tiles are attached to the pipes. In addition, in the embodiment according to Figures 1-3, the gypsum plasterboard plates 2 are screwed onto the wings 6 of the lamellae 4. In contrast, in the embodiment according to Figures 4-6, the hook-shaped lugs 14 of the T-shaped holders 12 are pushed onto the tubes 3 and the gypsum plates 11

The retaining plate 8 with its shoulders and the corner plate 10 used in both embodiments represent in themselves a rigid structure for fixing the ceiling. The shoulder 9 is turned at an angle of 90 ° from the holding plate 8 so that the rotation of the lamellae 4 is prevented, since one of their wings 6 from below collides with the shoulder 9 when the wing is in a horizontal position. However, it is also possible to arrange the shoulder 9 and the retaining plate 10 in the same plane, whereby the lamella is rotatable during construction.