NO138117B - BUILDING ELEMENTS AND FORMWORK AND PROCEDURES FOR MANUFACTURE OF THE SAME - Google Patents

Abstract

building element as well as formwork and method for producing the same. -

Description

The invention relates to a building element, particularly in the form of

a plate-shaped, possibly curved finished part for buildings, furniture, vessels, ship hulls or the like, which element has as its basic body a body of a light building material, in particular of foam plastic, polystyrene foam or polystyrene concrete, which has at least approximately vertical and horizontal channels for the absorption of support bodies or reinforcement inlays, in particular load-bearing columns and crossbars made of reinforced concrete, cement-glued concrete or the like. The invention further relates to a formwork and a method for producing such a building element.

It is already known to design finished parts for walls,

roofs and the like in the form of reinforced concrete slabs, as ready-made parts

ter of wood or also of steel. The known building elements of this kind have the disadvantage that they are relatively expensive to manufacture and difficult to transport when damage is to be prevented. Besides, must

they also have heat and sound insulation.

Furthermore, building boards made of foamed polystyrene are known which consist of slotted boards provided with plaster on both sides with steel rods embedded in the foam along the edge, the steel rods serving as a post-like reinforcement.

Another construction part of this type consists in a base body consisting of synthetic foam being glued together with a cover material formed of hard plates under an interlayer of hard fiber plates which serve as reinforcement. In this case, there are also arranged in the base body some soyle-like through-holes which are filled with concrete. However, these boreholes lie parallel to each other and run in a vertical direction. The construction parts have the disadvantage that, due to the use of hard fiber boards, they are expensive to manufacture

and moreover, despite the use of these plates, only have little rigidity against twisting. Also occurs when assembling a building

with such plates a poor transmission of thrust and longitudinal forces in the plane of the wall, as this force transmission is completely interrupted at the joints between the individual plates. In addition, an adaptation of these plates to the building requirements or cutting them to size on the construction site is practically not possible.

There are also known building elements, where a body made of foam plastic has channels for receiving reinforcement inserts which branch out, in particular run obliquely. By means of support bodies or reinforcement insert, it was achieved that the building element, despite insufficient compressive, tensile and bending strength of the foam plastic, achieved great stability. As a support body or reinforcement inlays can be arranged in cement-glue concrete parts, steel concrete, concrete, wood, metal or plastic parts with tube-shaped, round or angular cross-sections.

With these construction elements, buildings, ship hulls, furniture, vessels or the like can be quickly and easily assembled from single parts with large surfaces, while entire house walls and roofs can also be transported by trucks or helicopters. These building elements are distinguished by extremely light weight, elastic structure, insensitivity to earthquakes and other vibrations and a temperature insulation which, for a wall thickness of 20 cm, is approximately the same as for a 2 m thick brick wall. With fugelo's construction method, the appearance of drafts can be avoided. Any damage to the building elements during transport does not lead to expensive repair work. When erecting buildings from these building elements, only weak foundations are required. The building elements are moisture repellent (not absorbent), enable an extremely easy laying of installations, as no chiselling or drilling work is required and are also electrically non-conductive, highly flammable and have a bearing capacity that corresponds to normal construction methods.. They have a great firmness against decay, fungi, aging and chemicals. Apart from the fact that the building elements as finished parts can be produced in series, arbitrary shapes of these such as rounded corners, spherical curvatures and the like are possible.

In the production of buildings or the like using such building elements, the walls are first built up, after which, possibly rebar is pulled into the channels and finally concrete is stuffed into them, injected, vibrated or pressed. In this connection, it is essential to ensure that no concrete-free spaces form in the channels, which mainly depends on the consistency of the concrete. This is particularly associated with difficulties with the building elements, where the vertical and horizontal channels cross each other at approximately right angles, as especially when the concrete is shaken in, air spaces can easily form, especially towards the middle of the horizontal channels.

The purpose of the present invention thus consists in

to obtain a building element which has all the advantages of the known building element of the type described at the outset, but where, in addition, by at least approximately vertically crossing horizontal and vertical channels, any lump formation is avoided regardless of whether the concrete is shaken, injected, is pressed or stopped into the channels.

According to the invention, the cross section of the horizontal channels or of the tracks that form these, at least at one end of the same extended towards the vertical channels or against the tracks that form these, in order to facilitate penetration of. the concrete to be introduced into the horizontal channels.

With the help of this precaution, it is achieved that upon introduction. of concrete, in the course of its upward ascent in the vertical channels, this will certainly also fill the horizontal channels, as the concrete

penetrates through the widened openings into the horizontal channels.

The size of the cross-sectional expansion or the width of the cross-section for the horizontal channels from the center towards the mouth of the vertical channels depends on the consistency of the concrete and its insertion method. It must be larger for vibrated concrete than, for example, for very fluid concrete that is poured in.

In an advantageous way, the extension is produced in a trumpet shape, with which it is achieved that accumulations of the concrete penetrating into the horizontal channels are avoided.

In an appropriate way, the expansion proceeds symmetrically in relation to the horizontal longitudinal middle plane of the horizontal channel. This results in the fact that, when joining the building elements, one does not need to pay attention to which end edges of these must lie up and which must lie down. In the case of asymmetrical expansions, it is more favorable when introducing liquid concrete if the expansions of the horizontal channels are directed downwards, in the case of rammed or vibrating concrete, on the other hand, it is more favorable that the expansions extend upwards.

Most advantageously, the extensions are arranged at both mouths of the horizontal channels in the vertical channels because the penetration of the concrete from both ends of the horizontal channels is thereby facilitated.

An even distribution of the concrete in the interior of the horizontal channels is achieved above all when the expansions follow a further

design of the invention are arranged symmetrically in relation to the building element's vertical longitudinal middle plane.

For the production of the building elements according to the invention, a formwork which consists of a house and a lid is advantageously used, as there are molded pieces arranged both at the bottom of the house and also in the lid to form the horizontal channels with extensions, the end of each at the bottom of the shaped piece arranged in the housing lies opposite the end of the shaped piece arranged in the lid.

With such a formwork, the building elements according to the invention are produced in an appropriate way by first filling the house with light building material, then putting the lid on the house under pressure. of its form pieces in the light building material and the formwork is removed after hardening of said light building material. Thereby, not only is simple and cheap production achieved, but it is also achieved that the light building material itself becomes solid during the curing process.

Further details of the invention will be apparent from the following detailed description with reference to the drawing which shows some exemplary embodiments of the invention, as fig. 1 schematically shows a wall built up with the building elements according to the invention for the introduction of concrete and in section the line I-1 in fig. 2, fig. 2 is a section along the line II-II in fig. 1, fig. 3 is a section through a -horizontal channel with upwardly widening mouths, fig. 4 is a section through a horizontal channel with downwardly widening mouths, fig. 5 is a section through a horizontal channel with upwards and downwards widening mouths, fig. 6 is a section through a horizontal channel where the mouths expand more strongly upwards than downwards, fig. 7 is a partial section of a formwork along the line VII-VII in fig. 8 and fig. 8 is a section along the line VIII-VIII in fig. 7.

The one in fig. 1 in section along the line I-1 in fig. The wall shown in 2 is made up of building elements which consist of a base body 1 of a light building material, for example styrofoam concrete. Each of these base bodies has on its end surfaces semicircular grooves 2, 3, 4»5, which together with the end surface grooves in adjacent building elements form circular channels, the grooves 2, 3 running horizontally and the grooves 4>5 running vertically. Perpendicular to the vertical tracks 4 > 5, in the example shown in each building element there is also arranged a horizontal channel 6 which in the longitudinal middle plane has a circle-shaped cross-section which expands trumpet-shaped towards the vertical tracks 4j 5 and thus also towards the vertical channels that are formed using these tracks. This trumpet-shaped expansion of the cross-section is also arranged at the lower horizontal grooves 3, whereby when additional building elements are added under the exposed wall, horizontal channels are created which expand trumpet-shaped upwards towards the vertical channels.

Instead of the shown semicircular cross-section of the tracks 2, 3, 4, 5, other cross-sectional shapes can also be used, for example right-angled. As the grooves 2 arranged at the upper end faces of the building elements together with the grooves 3 arranged at the lower end faces of adjacent building elements form a horizontal channel in each case, the further horizontal channels 6 can also be omitted. However, the building elements can also have several mutually parallel horizontal channels of the same type as channel 6. Likewise, one or more vertical channels can also be arranged which extend through each building element from top to bottom. What is essential is that the cross-section of the horizontal channels is at all times extended towards the vertical channels to facilitate the insertion of the concrete to be lined into the horizontal channels.

After the construction of the wall with the base bodies 1 and after possible insertion of reinforcements in the horizontal and/or vertical channels, concrete is emptied from above into the vertical channels, in which it penetrates vertically downwards and first through the extensions 7,

8 into the bottom horizontal groove 3. When it is filled, it rises

the concrete in the vertical channels up to the next horizontal channel

6 and fills this through expansions 9, 10. It then rises

further in the vertical channels up to the uppermost horizontal channel or track 2, which is likewise filled to completion.

Instead of those in fig. 1 and 2 shown trumpet-shaped extensions can be used arbitrarily differently designed extensions. In fig. 3 is shown in a straight line upwards extending extensions 11, 12 and in fig. 4 is shown in a straight line downwards extending extensions 13, 14-Which of the two variants according to fig. 3 or 4 to be chosen depends on the consistency of the concrete to be inserted, and on the nature of the insertion. In the case of very fluid concrete, the example in fig. 4 better suited than that in fig. 3, while when introducing rammed concrete, the example in fig. 3 to be better suited. It will appear that for the example in fig. 3 and that in fig. 4, one and the same building element is suitable, as this in the example of fig. 4 compared to the example in fig. 3 is only arranged 180° rotated about the horizontal. When building a wall, however, when using the building elements in fig. 1 to 4, it is taken into account whether the extensions should extend upwards or downwards.

In order not to have to pay attention to which end surfaces of the building elements are to be arranged upwards, downwards, to the left or right, the extensions are most appropriately arranged symmetrically both horizontally and vertically, as shown for example in fig. 5, where the extensions 15 > 16 proceed symmetrically both in relation to the horizontal longitudinal middle plane of the horizontal channel and also symmetrically in relation to the vertical longitudinal middle plane. Moreover, the beginning of the extensions in the examples of fig. 3 to 5 in the longitudinal middle plane of the building element, which entails the advantage that the concrete penetrating from both sides is fashioned on the

narrowest place in the horizontal channel.

Due to the expanded cross-sections at the place of the mouths of the horizontal channels in the vertical channels above the filled concrete at the crossing points of the horizontal and vertical channels an increased pressure against the walls of the base body. In order to safely avoid a hollowing out in these places, as schematically shown in fig. 5, most advantageously one or more connecting elements 17 are arranged at the expansion sites which connect the outer surfaces of the building elements to each other.

Fig. 6 finally shows a variant, where the extensions 18, 19 are arranged asymmetrically in relation to the horizontal longitudinal middle plane of the base body 1.

Finally, in fig. 7 and 8 show part of a formwork which is advantageously suitable for manufacturing the building elements according to the invention. It consists of a housing 20 and a lid 21 which is placed on the housing 20. Both at the bottom of the housing 20 and on the lid 21 are arranged form pieces 22, 23, 24, 25 which, after inserting the light building material, form the horizontal channels with their extensions. The tracks in the vertical channels or the grooves for the horizontal channels in the end walls are also shaped with the help of ribs 26, 27. The end of each shaped piece 22, 24 arranged at the bottom of the housing 20 lies respectively opposite the end of the shaped piece 23, 25 arranged on the lid 21. The ends of the Form pieces facing each other can immediately lie next to each other, so that the channels are already produced during the design. In an advantageous way, however, as shown in fig. 7 and 8, arranged at a certain distance from each other, so that by shaping in the space 28, 29 between the end surfaces of the opposite ends of the moldings present on the lid 21 and at the bottom of the housing 20, a wall is formed in the channel of the base body, which for filling concrete can be checked through.

When manufacturing the base body, the house 20 is first made

in the formwork filled with light building material. The lid 21 is then placed under pressure on the housing 20 by pressing the lid's molded pieces 23, 25 into the light building material. After the building material has hardened, the formwork is removed.

Advantageously, at least the shaped pieces have a thermal conductivity which is equal to or less than the thermal conductivity of the light building material which is being moulded. Thereby it is achieved that the heat that is released during the hardening of the light building material incorporated in the formwork is collected especially in the places which for the finished building element are exposed to greater stress, so that a faster hardening occurs in these places, which leads to a better quality for the building element.

It will be clear that the extensions can be adapted in a flow-favoring manner to the special flowability of the filling medium, preferably concrete. If concrete is vibrated, the expansions can proceed flatter than when no vibration is applied. They can be chosen so that the filling medium fills all channels in their entirety without any separation taking place.

Claims (13)

1- Building element, especially in the form of a plate-shaped, possibly -curved finished part for buildings, mobiles, shipbuilding, ship hulls or the like, which element has as its basic body a body of a light building material, especially of foam plastic, polystyrene foam or polystyrene concrete, which has in it smallest approximately vertical and horizontal channels for the reception of load-bearing bodies or reinforcement inserts, in particular load-bearing beams and transverse steps of reinforced concrete, cement-glued concrete or the like, characterized in that the cross-section of the horizontal channels (3, 6), respectively of the grooves that form these, at least at one end of the same is extended towards the vertical channels (4, 5) respectively the grooves that form these, in order to facilitate penetration of the concrete to be introduced into the horizontal channels. 2. Building element according to claim 1, characterized in that the extension (7, 8, 9 10) is produced in a trumpet shape. 3. Building element according to claim 1 or 2, characterized in that the extension (15, 16) extends symmetrically in relation to the horizontal longitudinal middle plane of the horizontal channel. 4- Building element according to one of the claims 1 to 3, characterized in that the extensions (7 8, 9, 10, 11, 12, 13, 14, 15, 16, 18, 19) are arranged at both mouths of the horizontal channels in the vertical channels. 5- Building element according to claim 4, characterized in that the extensions (7 to 16, 18, 19) are arranged symmetrically in relation to the building element's vertical longitudinal middle plane. 6. Building element according to claim 4 or 5, characterized in that the beginning of the extensions (11, 12, 13, 14, 15, 16) lie at least approximately in the longitudinal middle plane of the building element. 7. Building element according to one of claims 1 to 6, characterized in that one or more connecting elements (17) are arranged at the expansion sites (15, 16) which connect the outer surfaces of the building element to each other. 8. Formwork for the production of a building element according to one of claims 1 to 7, characterized in that it consists of a housing (20) and a lid (21), in that both at the bottom of the housing (20) and also in the lid (21 ) are arranged molding pieces (22, 23, 24, 25) which are to form the horizontal channels with extensions, the end of each molding piece (22, 24) arranged at the bottom of the housing (20) being opposite the end of the one in the lid (21) arranged form piece. (23, 25). 9. Formwork according to claim 8, characterized in that the end surfaces of the opposite ends of the molded pieces arranged on the lid (21) and at the bottom of the housing (20) have a distance from each other. 10.. Formwork according to one of claims 8 or 9, characterized in that at least the form pieces (22, 24) have a thermal conductivity which is equal to or less than the thermal conductivity of the light building material being formed. 11. Method for producing a building element according to one of claims 1-7 with a formwork according to claims 8 - 10, characterized in that first the formwork housing (20) is filled with light building material, then the lid (21) is placed on the housing (20) while pressing its form pieces (23, 25) into the light building material and the formwork is removed after hardening of said light building material. 12. Method according to claim 11 with formwork according to claim 9 or 10, characterized in that the steps of light building material that are left between the end faces of the form pieces are broken through after the removal of the formwork. 13. Method according to claim 11 or 12, characterized in that rebar is inserted into the channels. in