FI64430C - TAK - Google Patents

Description

______. 1 Γ_, ANNOUNCEMENT r a a ι r \ 8 <11) UTLÄGGNINGSSKRIFT 644 30 c Patent issued 10 11 1933

Patent ncddclat (51) Kv.lk. ^ IntCI.3 E 04- D 3/35 »1/28 SUOMI - FINLAND (21) P * tenttlh» k * mu * - PttentansOknlng 801021 (22) H »k» ml « ptlv · —Anrikknlngidig 01.0it.80 (23) Start * M —Glltlghettdig 0l.0t.80 (41) Become Public - Bllvlt offentllg 0 ^ .10.80

Patent ·] · Board of Registration (44) Date of Nihttvlkslpanon Ja kuLIulkalsun—

Patent- och registerstyralMn 'Anaökan utlagd oeh utUkrlftan publlcerad 29.07.83 (32) (33) (31) Pry4 * «y etuoikeus - Begird prlorltet 01. f) U.79

Sweden-Sverige (SE) 7903009-4 (71) Träullsplattfabrikemas Eörsäljnings AB, Box 42012, S-126 12 Stockholm 1 + 2, Sweden-Sverige (SE) (72) Per Herrmann, Bromma, Sweden-Sverige (SE) (74) ) The present invention relates to a roof which rests on roof parts and which, on the other hand, consists of a layer of small, standardized, load-bearing, slab-like building elements, e.g. the size is substantially the same as the distance between the center lines of the two orifice beams, and possibly of additional insulation above and / or below said layer, and on the other hand of several layers of rain protection, which are made of cardboard, plastic fabric or sheet metal. The invention also relates to a method of manufacturing and installing such a roof and to a large assembled element included in the roof.

According to a known method, such a roof is manufactured and installed on site by installing the roof parts and fixing it one element and one layer at a time. In this case, a lot of standardized elements are used today, which form both the above-mentioned, load-bearing, slab-like building elements and additional insulation. This known roof system has many advantages. As for the roof frame itself, the designer has freedom in terms of material choice and spans. In addition, do not depend on dimensional restrictions 64430 during manufacture and transportation. The body can be dimensioned in the best way by taking advantage of the continuity of the brush and the most economical cross-section. As for the tulfie for the various building elements in the known roof system, do not depend on the factory design service. Production in stock is possible and delivery time is short. In addition, the transport space is as small as possible.

The disadvantage of the known roof system is that the construction site is weather dependent and that the installation takes time. In addition, the design has the disadvantage that the roof contains quite a lot of parts that need to be ordered and kept in mind. Attempts have been made to eliminate the dependence on the weather and to speed up the installation by using larger, prefabricated roof elements which, with the exception of the outer rain protection layers, are assembled into all the parts contained in the roof, including the roof rafters. More specifically, a predetermined number of said, standardized, load-bearing building elements are attached to two beams, each corresponding to a longitudinally split roof hollow, and provided with additional insulation and a rain protection layer. In installation, the roof elements are placed side by side.

This outlined proposal greatly reduces the dependence on the weather and, of course, makes it possible to install the roof quickly, as even the placement and installation of roof trusses separately on the building is eliminated. However, this largely lacks the advantages of the known roof system described above in terms of dimensioning flexibility and the possibility to easily adapt the system to different objects.

The object of the present invention is to develop a roof, a method of manufacturing and installing a roof and a large element while maintaining the advantages of a known roof system, whereby rapid installation is possible regardless of the weather. According to the invention, the roof consists of larger roof elements, hereinafter referred to as large elements, which are assembled in advance without the use of load-bearing beams or the like, each in a row of predetermined number of building elements, optionally with additional insulation and at least one additional rain cover. sadesuojakerroksilla.

Other features of the invention appear from the appended claims.

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The invention will now be described in more detail with reference to the embodiments shown in the accompanying drawing, in which: Figures 1 to 3 show schematic views of principle differences between three different roof manufacturing and installation methods, namely by known methods, using assembled tipping elements and ; Figure 4 shows an end view of a large element according to the invention; Fig. 5 shows a cross-sectional view in the direction of arrows V-V on the same subject; Figure 6 shows an end view of another large element of the invention; Fig. 7 shows a cross-sectional view in the direction of arrows VII-VII on the same subject; Fig. 8 is a schematic end view of a roof installation using the principle of the invention; Figures 9 to 12 show two different ways of lifting the assembled roof elements according to the invention; Figs. 13 to 15 show perspective views of another preferred method for lifting a roof element of the invention, and Fig. 13 shows a lifting brush steel with loops, Fig. 14 this brush blade mounted on the longitudinal edge side of a large element and Fig. 15 a connection of a lifting frame to a large element.

In the different figures, the same reference parts are given to the same or similar parts.

As is known, a row of standardized, load-bearing building tiles, one of which is shown in point 2, according to the figure, for roof trusses 4 pre-mounted on the main beam or wall 3 of a building.

The length of the elements 2 corresponds to the distance between the center lines of the rafters 4 so that the rafters can act as supports for adjacent rows of building elements 2. An insulating layer is placed on the layer of the elements 2, which may also consist of standardized elements, which are represented here by the insulating plate 6. At least two rain protection layers 8 and then are then applied to the layer of the insulating plates 6. 10.

According to the proposal shown in Fig. 2, the assembled roof elements are manufactured in advance from the elements 2 and 6 and from the rain protection layers 8, which are attached to the brackets 4 'supported by them. The assembled elements according to Figure 2 are placed side by side to form a roof / 4 64430, the ridges 4 ', the sides of which abut each other, form a pair of roof ridges. Finally, one or more additional rain protection layers 10 are applied.

The embodiments according to Figures 1 and 2 have the advantages and disadvantages mentioned in the introduction.

A large element according to the invention, which is shown in Fig. 3 and in two different embodiments in Figs. 6, 7 are constructed of standardized, self-supporting, reinforced chipboard tiles 2, insulation tiles 6, which are a "sandwich" combination of chipboard and cellular plastic, and a rain cover layer of roofing board 8. However, the large element according to the invention has no load-bearing elements similar to ors 4 '. Instead, they are placed on the roof trusses 4, which are pre-assembled on the building 3, which is evident from the fact that in Fig. 3 the large element is shown above the beams 4 as slightly floating.

The means by which the large elements are held together are conventional for joining different parts, such as glue and nails and the groove connection shown in Figures 5, 7, such as are at least necessary to keep the elements together to withstand the stresses during lifting, transport and installation. These connecting means are represented by longitudinal strips 12 and 14, which are on the upper and lower sides of the large element, extending in pairs. along the longitudinal edges. Figures 4, 5 do not show lists 14 which may have a function to be described in more detail below.

Figures 8 show a method for installing and manufacturing a roof by means of a large element according to Figures 4 and 5. The length of the building elements 2 corresponds to the distance between the center lines of two adjacent roof rafters 4. The large elements are placed side by side on the roof rails 4, to which they are attached by suitable means. In the embodiment shown, these means are already known ties per se. These ties include fittings 16 located on the upper side of the rafters 4, which carry parts 18 parallel to the rafters 4, which are made of round steel. The piece of steel strip 20 is placed under the round steel 18 and extends at each end up to a strip 12 belonging to two adjacent large elements, and is here nailed to the element 2 by nails 22. The strips 12 are fastened to the element 2 by nails 24.

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As can be clearly seen from the figures, the width of the layer formed by the insulating tiles 6 is smaller than that of the tile layer 2, so that a shoulder is formed on each side to which the strip 12 is attached. This shape provides an intermediate space between the respective tile layers 6 of two large elements extending side by side. This space is filled with narrow extension plates 26, which may be similar to the insulation plates 6, although lower due to the strips 12. A roofing board 28 is attached to the upper side of the extension plate 26, preferably by spot gluing. The width of the roofing board 28 is such that it overlaps with the adjacent layers of the insulation boards 6 and is glued on top of these. Figure 8 on the right shows the connection point in the finished state. The roofing board 8 preferably extends over the entire width of the large element, also down the shoulder and under the slats 12. This achieves a particularly secure seal.

It should be noted that the width of the roofing board 28 is able to withstand greater stresses caused by the movements of the roof parallel to the roofing board due to its width between the point gluing at the insulation boards 6 and the extension board 26 than if the roofing board extended only over a narrow joint gap.

The lower strips 14 can be used as fasteners for detachable, threaded lifting eyes 30 as shown in Figure 9. Figure 11 shows how a large element can be lifted by means of such lifting loops 30. Lifting sleds can be used instead of removable lifting eyes, as shown in Figures 10 and 12. Such a lifting carriage can be constructed of demountable longitudinal U-beams 32, cohesive transverse beams 34 and threaded lifting eyes 36.

Figure 10 shows how the beams 32 are positioned below the top large element of the Large Element Stack. In this case, the lifting carriage must first be dismantled at at least one of its corners, after which it must be re-connected under the large element.

Figures 13 to 15 show another method for lifting large elements. Prior to the installation of the strips 12, a groove 40 is milled in each layer formed by the chipboards 2 reinforced on each longitudinal edge side. More specifically, the grooves 40 are milled through the wood reinforcement 42 of the wood chipboards 2. Lifting steels 44, on which lifting loops 46 of wadding or wire are threaded, are placed in the grooves 40, whereby the loops 46 are pulled into the sawing slots 47 of the wood chipboards 2 so that they rise on the upper side of the corresponding slab where they can be threaded. through the pre-drilled holes 48 in the putty strip 12. The list 12 can then be nailed shut. When the large element is completed with its lifting eyebolts 46 installed, it can be lifted by means of a lifting frame 50. The frame 50 is provided with carabiner hooks 52, the positions of which correspond to the corresponding lifting loops 46 of the large element.

Although the chipboard reinforced in the previous description of certain embodiments is mentioned as forming the elements 2, other standardized building elements are also conceivable. Such are, for example, lightweight concrete slabs, trapezoidal corrugated sheet metal, etc. The insulation layer can consist not only of the described tiles 6 mineral wool, etc. For rain protection layers, it is also possible to use e.g. plastic fabric or sheet metal.

The connection between the large elements and the roof trusses 4 is of course not limited to the embodiment shown in Fig. 8, but can also be different, e.g. made by nailing.

Claims (17)

64430 A roof resting on roof trusses (4) and consisting partly of a layer of small, standardized, load-bearing, slab-like building elements (2) of substantially the same distance as the center line of two roof trusses (4), partly of possible additional insulation (6) ) on the upper and / or lower side of said layer, and partly on the rain protection layers (8, 10), characterized in that it consists of larger roof elements arranged at the edges, hereinafter referred to as large elements, assembled in advance without the use of load-bearing beams or the like. , each of a row of building elements (2) of a predetermined number, optionally provided with additional insulation (6) and at least one (8) rain protection layer, and covered with common additional rain protection layers (10). A roof according to claim 1, characterized in that each large element comprises a layer of insulation boards (6) interposed between the rain protection layer (8) and the row of building elements (2), the width of which is less than said row so as to terminate along each longitudinal edge of the building element. the shoulder of the surface of the row (2), the spaces between the shoulders of the large elements arranged at the edges, the longitudinal edges of the rows of large elements touching each other, being filled with fitted extension elements (26), preferably of the same material as the insulating plates (6) 28) which overlap with the rain protection layers (8) of adjacent large elements. A method of manufacturing and installing a roof supported by ors beams according to claim 1, which roof consists of an o-Saxon layer of small, standardized, load-bearing, slab-like building elements (2) of substantially the same distance as the center lines of two roof rafters (4), optionally additional insulation (6) on the upper and / or lower side of said layer and partly on the rain protection layers (8, 10), characterized in that the larger roof elements, hereinafter referred to as large elements, are joined together in advance by each row of building elements (2) the number is predetermined 8 64430, together with any additional insulation (6) and at least one rain protection layer (8), using as few connecting means as possible so that each large element remains together only to withstand the stresses of transport, lifting and installation, and the large elements are placed and attach to the building pre-attitude for supported roof trusses (4). Method according to Claim 3, characterized in that essentially only means are used as connecting means for fastening the building elements (2), any additional insulation (5) and the rain cover (8) to one another in a known manner. Method according to Claim 4, characterized in that a strip (12, 14) is also used as the connecting means, which is fastened along each edge of the row of building elements above and / or below. Method according to one of Claims 3 to 5, characterized in that the large elements are lifted into place on the roof truss by means of lifting carriages (32, 34, 36) which are adapted to the size of the elements. Method according to Claim 5, characterized in that the large elements are lifted into place on the ceiling by means of lifting loops (30) which are detachably placed on the fasteners at the strips (14). Method according to claim 7, characterized in that the lifting loops (46) to which the resistance parts (44) are connected are arranged along the two opposite edge sides of the element so that the loops protrude through the recesses (48) of the element on its upper side and the resisting members act against a surface which is a substantially opposite surface with respect to the upper side. A method according to claim 8, characterized in that the longitudinal groove (40) is milled on each edge side and that the rods (44), the cross-section of which is adapted to the grooves and to which a plurality of lifting loops are attached, are placed in the grooves so that the loops insert up through the recesses. A method according to claim 9, characterized in that the strips (12) are used to fasten the loops (46) in place on the upper side of the element. Large element for use in the method according to claim 3, characterized in that it consists of a row of standardized, load-bearing, slab-like building elements (2), optionally with additional insulation (6) arranged on the top and / or bottom and at least one rain protection layer (8). ) and assembled without load-bearing longitudinal members, such as set-aside beams, by means of connecting devices which can withstand the stresses during transport, lifting and installation. Element according to Claim 11, characterized in that the connecting means withstand only the stresses which occur, in addition to securing the various parts to one another. Element according to Claim 11 or 12, characterized in that the connecting means further comprise a strip (12, 14) which is fastened along each edge of the row of building elements to the upper and / or lower side. Element according to one of Claims 11 to 13, characterized in that it has fasteners (14) for the detachable connection of the lifting eyes (30). Element according to any one of claims 11 to 14, characterized in that it has a layer of insulating tiles (6) arranged between the rain protection layer (8) and the row of building elements (2), the width of which is less than said row so as to terminate each a shoulder for the surface of the row of building elements along the longitudinal edge. Element according to Claim 15, characterized in that the rain protection layer (8) extends continuously over the free surface parts of the insulating slab layer (6), the shoulders and the row of building elements (2). Element according to Claim 15 or 16, characterized in that the strip (12) is fastened to each free surface part of the row of building elements (2) near the shoulder. 10 64430