NO131765B - - Google Patents

Description

Method of manufacture of

rod-shaped building element.

Previously known rod-shaped building elements are usually produced for a specific application purpose. A building structure therefore requires a greater number of different building elements. Production of the various building elements is naturally time-consuming and requires a large inventory. The provision of a building structure of the various elements also becomes correspondingly complicated and requires specialist knowledge.

The purpose of the present invention is to provide

a method for the production of building elements which exhibit continuous pinholes arranged at an equal distance from each other and from the ends of the element. Such a rod-shaped building element will

be universally applicable, i.e. that in connection with a construction

construction, then usually only a building element of different length is required with ells without studs at the end for use as sleepers, ties, studs, crossbeams, struts, intermediate ridges and rafters, etc. Such building elements can be delivered from stock and an unskilled person can plan and erect a demanding construction project without the need for specialist knowledge, machines or tools. Already when planning a building, it is possible to save time, as corresponding routing paper on a scale of 1:20 or 1:10 can be used for the building element's construction module. When transparent drawing paper is placed on the grid base, anyone can draw up a floor plan and walls for a building with a pencil without a scale and ruler, select materials and order all accessories for a building from stock.

A wooden construction made from such building elements is generally applicable in high-rise buildings as stud, cross-timber or skeleton constructions, as well as for tie beams, carriers or links and internally as a cover, partition walls, barriers, storage racks, exhibition stands, etc.

The method according to the invention thus consists in the production of a building element which exhibits continuous pinholes arranged at an equal distance from each other and from the ends, and the method according to the invention is characterized by the fact that two deck boards are placed in a template and between these shorter intermediate boards, separated by spacer strips, which are glued together with the cover boards of a block, that the spacer strips are removed to form dowel holes between the intermediate boards and that the block is then cut lengthwise into rod-shaped building elements.

The invention shall be illustrated with reference to the attached drawings, where: Fig. 1 shows a template and the basic parts for manufacturing the building elements. Fig. 2 is a side elevation of a block joined by the basic parts. Fig. 3 is a perspective view of the block after being removed from the mold and removal of the spacer strips used in the manufacture. Fig. 4 illustrates the separation of the block into individual building elements. Fig. 5 shows a plurality of building elements bundled together into a bundle. Fig. 6-9 show different design variants of the building elements. Fig. 10 shows an embodiment of a building structure produced from building elements. Fig. 11 shows a truss beam made from building elements. Fig. 12-14 are examples of corner and cross connections, as well as arranging an intermediate wall in connection.

In fig. 1 shows a template consisting of a base plate 1 and

two impact angles 2. On the base plate 1, a lower deck board 3 is placed if both ends are positioned at a certain distance from the impact angles by means of their respective strips 4. Intermediate boards 5, 6 are placed on the lower deck table 3 and spacer strips 7 between them. Both outer intermediate boards 5 abut against the impact angles 2 and are somewhat longer than the other intermediate boards 6, which are all the same. On this layer of intermediate boards 5,6 and spacing strips 7, an upper deck table 8 with strips 9 at both ends is placed. The intermediate boards 5 and 6 are now glued together with the cover boards 3 and 8 and form with these a block, as can be seen from fig. 2. The block is now taken out of the template 1 and the distance strips 7 are pulled out and the strips 4 and 9 are removed. As can be seen from fig. 3 shows the thus produced block dowel holes 10 in the places where the distance strips were located. Furthermore, there is a pin 11 on each of the ends. Next, the individual rod-shaped building elements 13 are cut up in a saw 12, as can be seen from fig. 4. The building elements manufactured in this way all have exactly the same length and exactly the same positioned and equally sized tenons and tenon holes, without any wood waste being produced during the manufacture. The block gluing also achieves good stability and always consistent quality of the individual elements.

For the production of the building elements according to the described method, wood of second- and third-class quality can be used. A maximum utilization of material can be achieved, as the narrowest strips can be glued together to form tables and

in their entirety serve for the production of blocks. A further selection of quality is made possible by the prettiest boards being used as cover boards, while the less pretty ones are cut up into intermediate boards.

The production of the building elements can take place in a sawmill and planer, whereby a high economy is achieved. As can be seen from fig. 5, a majority of identical building elements 13 produced in this way can be packed in large bundles and brought into the trade as semi-finished products. Fig. 6 shows a number of different length, rod-shaped building elements 14 whose pinholes 15 are all the same distance from each other and whose length is equal to or a multiple of the distance between two pinholes 15. At the ends, these building elements have pins 16 whose cross-section is equal to the cross-section of the pinholes and whose length is equal to half the thickness of the building element. Fig. 7 shows a building element 17 which is only provided with pin holes 18 and without pins at the ends. Fig. 8 shows a building element 19 with pin holes 20 and pins 21 at the ends, the length of which is twice the thickness of the building element.

In fig. 9 shows a corner element 22 which has a pin hole

23 which has the same cross-section and the same distance as the pin holes in the building elements 14, 17 and 19. In addition, the corner element has pins 24 at both ends.

The one in fig. 10 shown skeleton construction is made up of building elements as shown in figures 6,9. Horizontal building elements 25 according to fig. 7, of which there are two on top of each other at each location and which are offset in relation to each other so that their pin holes 26 match. The vertical building elements according to fig. 8 has pin holes 28 and at the ends pins 2 9 designed to engage in the pin holes 26 in the building elements 25. There are also arranged horizontal building elements 30 according to fig. 6 with pin hole 31

and corner element 32 according to fig. 9 with pin holes 33 and pins 34. As will be seen, the building elements can be connected to each other by simply inserting pins into the pin holes.

In the fields between the building elements, filler plates 3 5 can be placed or plaster-bearing plates 36 can be placed on the skeleton structure.

As can be seen from fig. 10, cables 37 for heating, sanitary and electrical installation can be routed through free-standing tap holes 37 before cladding the skeleton construction. With this option for the passage of cables, a subsequent placement of slits or drilling of holes is not necessary,

so that corresponding additional work and additional costs are saved. The free dowel holes can also serve for the insertion of anchoring screws that serve to connect the wooden skeleton to the foundation or underlying building elements.

The one in fig. 11 shown truss beam consists of an upper and

a lower carrier which in turn consists of two layers of building elements 38 with pin holes 39. Furthermore, on both sides of the carriers, diagonally extending braces 40 with pin holes 41 are arranged. These braces 40 are connected to the building elements 38 by cylindrical pins

42 is inserted through the outermost pin holes 41 on the braces 40

and through pin holes 39 on the carriers.

Fig. 12 shows a corner connection with a corner element

43 with pins 44 and with upper, double-arranged, horizontal building elements 45 with pin holes 46.

Fig. 13 shows an intermediate wall in connection with upper, double building elements 47 and 48 with pin holes 49 and vertical building elements 50 and 51 with a pin 52.

Furthermore, fig. 14 a cross connection with horizontal building elements 53,54 with pin holes 55 and a corner element 56 with pins 57.

With the help of the described, standardised, prefabricated, rod-shaped building elements, it is possible to produce floor and roof parts of the desired lengths, i.e. with the help of longitudinal elements and cross-beams, frames can be produced on which decks

plates can already be glued on at the production site. These floor and roof parts can be assembled into an arbitrarily large load-bearing surface, as studs are pushed through the stud holes in adjacent building elements to achieve the necessary

high buckling strength.

Of the standardized building elements, it is possible to produce

quiet frame parts with glued-on cladding panels for external and intermediate walls. Thereby, the work process during the construction of a building can be further rationalized and accelerated. The frame parts thereby fit with the protruding pins exactly into the pin holes in the building elements consisting of tap beams and ties. It is also possible to run cables through such cover and wall parts

excessive tap holes. Furthermore, it is possible to make partitions from the building elements which are not load-bearing and only serve for room division and are removable, and which can be clamped between the floor and ceiling by means of sealing strips.

It is also possible to produce the building elements on a scale of 1:10 and 1:5 and bring them to market. The 1:10 reduced building elements can be used for model buildings in schools, by architects and other planners. The scaled 1:5 elements can be used by younger people for the construction of toy huts, houses or stables, and further for the production of furniture, exhibition furnishings, stands of all kinds, etc.

Claims (2)

1. Method for the production of building elements that have through-holes arranged at equal distances from each other and from the ends, characterized in that two deck tables (3,8) are placed in a template (1,2) and shorter ones between them, by distance strips separated intermediate boards (5,6) which are glued together with the cover boards (3,8) into a block, that the spacer strips (7) are removed to form dowel holes (10) between the intermediate boards (5,6) and that the block is then cut lengthwise in rod-shaped building elements (13) . 2. Method as stated in claim 1, characterized in that both of the outermost intermediate boards (5) in the longitudinal direction of the building element (13) have a larger dimension than the intermediate intermediate boards (6) and project beyond the deck boards (3,8) a width equal to the width of the distance strip (7) for the formation of studs (11) at the ends of the block.