HU183339B - Variable building construction - Google Patents

Abstract

Variable building construction for buildings with a small number of stories having a foundation, holders for space limiting and space dividing panels, platform and space covering members and the building construction being mounted together from panels by way of detachable connection. For the variable building construction longitudinal beams (1a), cross-beams (1 b) forming frame (1), limiting plates (2) made of non-comburent material on silicate base, connecting groove (4) being formed along the circumference of the panels, slat (7) being inserted into the connecting grooves (4) of the adjacent panels, an upper floor beam (21), a bottom sill (23) and auxiliary connecting members, angle stanchions (13) are provided.

Description

The invention is a variable building structure with a small number of buildings, such as houses, terraced houses, communal buildings, e.g. motels, kindergartens, garages, lofts, etc. The structure of the building includes foundations, boundary and partition brackets, as well as floor and floor covering elements. The enclosing, partitioning, floor and enclosing elements are made up of panels having dimensions built on a common base module and, where appropriate, suitable for receiving windows and doors. Panels with the same function can be interchangeably exchanged. The adjacent panels are provided with connecting parts and / or auxiliary switching means. Each panel is a sandwich element having solid boundary panels and at least one intermediate layer therebetween, preferably an insulating layer. Along the perimeter of the sandwich element, the panel is enclosed in a frame consisting of longitudinal and transverse supports, preferably having a U-section, forming the load-bearing frame of the panel. The panels are removable and disassembled using removable joints.

Low-rise buildings, and in particular low-demand communal buildings, service buildings, weekend houses, etc. it is important that they can be produced quickly, with simple tools and with little on-site work. Previously, such buildings were built of traditional building materials, usually brick.

Conventional construction requires a great deal of time and on-site work, and there is virtually no opportunity to dismantle and reconstruct this temporary building once it has been completed. In principle, although the brick from demolition can be reused, some of it will break down or break, and in most cases, the dismantling of windows and doors built into the building will often cause significant damage.

Other low-rise buildings, eg. motels, kindergartens, garages and other utility or communal buildings have therefore, over the past decades, sought to use as widely as possible prefabricated elements, usually concrete panels, and less often lightweight but highly expensive metal structures. These have the potential to be assembled with minimal on-site work and more or less non-destructive disassembly, but the elements can still be difficult to work with and even more difficult to scale with on-site work.

Known structures made of concrete are extremely disadvantageous because of the heavy weight of the elements, which makes transportation and on-site installation difficult. Such buildings require a strong foundation and the use of high-performance construction machinery for on-site work.

The metal panels are easy to move, relatively light in weight with respect to their load-bearing capacity, but require great expertise and good tooling. To date, wooden structures are competitive in the field of application as they are made of lightweight and easily machined elements.

However, despite the use of wood preservatives developed in recent decades, there is still the problem that wood, due to its organic nature, is sensitive to moisture, fungi and other, eg. animal pests. Therefore, even after their construction, wood-bearing structures require constant conservation, which is expensive.

It is an object of the present invention to provide a variable building structure which eliminates the handicaps of previously known buildings of similar function, low level and generally less demanding. In particular, the aim is to develop a structure consisting of lightweight, easy to transport and install elements. The primary requirement is for the elements to be easily machined, practically customizable with the tools and techniques customary in the wood industry, even on site.

It is also an object of the present invention to provide a structure that is resistant to fungi, rodents and other pests and is not sensitive to moisture and other climatic influences. It is also important that the building elements can be produced simply and with high productivity.

It is also a task that the existing building can be dismantled and re-assembled easily, quickly and without damage. It is also a task that the various elements of the building structure, such as partition and partition panels, floor and ceiling panels, can be fabricated and assembled in a structurally identical manner.

The inventive idea is based on the realization that a structure which, while being based on silicate but which is similar to casting, can be easily and productively produced, easily molded, extruded and machined, best suits the intended purpose. It is recognized that these properties are best met by a combination of asbestos, perlite, and cement, from which panel vases, baffles and, where appropriate, other accessories can be easily made. Said material can be made by simple means to form partitioning and partitioning panels, whether they are solid or have a door and window structure.

In accordance with the object of the present invention, the variable building structure according to the invention is a low-level structure, such as houses, terraced houses, communal buildings, e.g. motels, kindergartens, garages, lofts, etc., - which include foundation, spatial and spatial brackets, and floor and spatial elements, including spatially enclosed, spatial, spatial and spatial elements, and optionally built on common base modules consisting of suitable panels, panels having the same function interchangeably, adjacent panels having connecting portions and / or auxiliary coupling means, each panel having a sandwich element having solid boundaries and at least one intermediate layer, preferably a heat-insulating layer, is enclosed in a frame consisting of longitudinal and transverse members, preferably having a U-section, forming the load-bearing frame of the panel, The panels are assembled and disassembled repeatedly - designed in such a way that both the frame lengths and cross members of the panel and the boundary panels are non-combustible, fungicidal and insect-resistant silicate-based, preferably cement-bonded and preferably moldable in wood. manufactured elements, along the boundary edges of the panel the boundaries of the boundary plates 21

183,339 or extending outwardly with the open side of the U-section of the frame forming a connecting trench for connection with the adjacent panel or other structural member along longitudinal boundary edges of adjacent space boundary panels, space divider panels and space overlay panels a hollow bar is inserted into the connecting trench complementary to each other in a hollow section of tubular cross-section, along the shorter border edges of the boundary panels, the upper guide beam, preferably T-section, is used to distribute the loads, while the lower cross member of the frame is lower and usually drive the space limiting panel horizontal deflection preventing, at the same time the length of the frame holder supporting the lateral direction, and the load which eg. it also extends along the shorter boundary edges of the partition panels to connect to the overlapping panels, while below is suitable for joining the room floor and / or the base, space boundary panels meeting each other or space divisions in planes; corner posts and / or auxiliary trusses.

A further feature of the variable building structure of the present invention may be that the upper guide beams and the lower sole beams are provided with an engaging nest for receiving and supporting the longitudinal frames of the space boundary panels. The retaining nest is formed by omitting or removing a portion of the ribs of the upper guide beams and the lower sole beams extending into the connecting trench. The size of the anchoring nest in the direction of the longitudinal axis of the upper guide beam and the lower sole beam is adapted to the overall cross-sectional dimension of the longitudinal supports of the panels to be supported.

The panels are bounded by one-sided fasteners to the frames, e.g. called. pop with nails and / or glue. Sealing strips are sealed between the vertical members of the frames and the trusses or trusses they receive, and between the upper horizontal members of the frames and the truss-forming ribs of the upper guide beams, and between the lower horizontal members of the frames and the truss-forming ribs of the lower beams.

The joints between adjacent panels of the same function are filled with an airtight sealing strip. Spatial boundary panels meeting each other or spatial panels or spatial panels, and joining spatial panels to each other or spatial panels, and finally joining spatial panels and spatial panels to the floor, are preferably provided with cornering strips.

The enclosure panels and the enclosure panels have at least one vapor barrier layer and optionally a waterproof cover, e.g. waterproof plaster. The base beams of the floor and / or the space bounding panels are fixed by means of anchors to the base body.

The variable building structure according to the invention has several advantageous properties compared to similar structures known hitherto. The most important of these is that the building blocks of the structure are lightweight, easy to machinize - practically resembling wood - the elements can be quickly assembled and disassembled, resistant to insects and fungi and are non-flammable. These elements make it possible to assemble a structure with minimal on-site work and without the use of any sophisticated construction machine. The construction of the load-bearing frame and boundary panels of panels made of asbestos, perlite and cement components also means that the structure is resistant to moisture just like silicate-based construction materials in general, and therefore no preservation measures are required after installation.

Due to the low weight of the batteries, not only on-site assembly but also transportation is cheap and easy. The non-flammability of the structure allows electrical wires to be inserted between its elements without being included in a pipe. The fabrication of the elements can be carried out with the existing equipment of the asbestos-cement factories.

Optional loosening of the structural elements gives the structure a great deal of variability, so that the same building elements may perform a different function in another building after the structure has been dismantled. Also thanks to its removable bonding mode, the interior of buildings can be easily transformed by simply and quickly moving partitions.

The invention will now be described in more detail with reference to the accompanying drawings, in which: FIG. The attached drawings show

Figure 1 is a side view of one of the panels that make up the building, a

Figure 2 is a longitudinal sectional view taken along plane II-II in Figure 1, a

Figure 3 is a cross-sectional view taken along the ΠΙ-III plane in Figure 1, a

Fig. 4 is a possible embodiment of the spatial delimitation panel

Figure 5 is another embodiment of the same, a

Figure 6 is a possible embodiment of the partition panel, a

Fig. 7 is another embodiment of a partition panel, a

Figure 8 shows the relationship between the partition panels, a

Figure 9 shows the relationship between the boundary panels, a

Figure 10 is the intersection of space boundary and space divider panels, a

Figure 11: Corner meeting of the space bounding panels, a

Figure 12 is the relationship between the space bounding panel and the plinth, a

Figure 13 is the intersection of the space bounding panel and the space enclosing panel, a

Figure 14 is the intersection of space divider and span panels.

Fig. 1 is a side view of a space bounding panel K formed as shown in Figures 2 and 3 from the frame 1 as a load-bearing frame and the bounding plates 2 attached thereto. The frame 1 is formed by the longitudinal supports la and the transverse supports lb. The panel comprises the insulating pad 3 and at least one vapor barrier layer 5, which is preferably located along an inner plane of one of the bounding panels 2 facing the insulating pad 3.

The outer boundary plate 2 of the space bounding panel K may be covered with a waterproof plaster 6. To each other som3

183 339, the longitudinal supports la of the delicate panels, as shown in FIG. 3, form a closed space associated with turning the open side of their U-sections towards each other, the connecting trench 4.

Fig. 1 also shows the lower sole beam 20, the rib 20a of which extends into the opening of the cross-member 1b, also of U-section, thereby stabilizing the panel in position. It can also be seen in Fig. 1 that a portion of the rib 20a is missing and this is the so-called rib. The mounting slot 24 allows the panel to be positioned on the lower sole beam 20. The retaining nest 24 should be sized to provide free space for the longitudinals la of adjacent panels.

Figure 4 shows a larger cross-section of a space bounding panel K than before.

The outer sides of the U-shaped longitudinal rails la are joined by the bounding plates 2. Both the frame 1 forming the load-bearing frame and the bounding plates 2 consist of a mixture of asbestos and cement, optionally with perlite. They are therefore lightweight and easy to work with. Along the lower boundary plate 2, the vapor barrier layer 5 is formed. plastic or bitumen sheet, whereas the insulating pad 3 is a foam material, e.g. may be polystyrene foam.

5 is a similar structure. With the exception that the U-shaped rails la are replaced by rectangular parallelogram rails la. In such a case, it is desirable to place the auxiliary plates 2a within the bounding plates 2 near the frame 1. In this case, a connection trench 4 is formed between these sections extending beyond the longitudinal members la, which in Fig. 4 is formed between the spine and the legs of the U-shaped longitudinal members la.

Figures 6 and 7 show one possible embodiment of the partition panels B. Again, the former shows the case where the members of the frame 1 are U-shaped, while in the latter case the frame 1 is composed of members having a rectangular parallelogram. The insulating cushion 3 may be similar to that of the space barrier panels K, this time acting as a sound insulator, whereas in the former case it is more insulating. For B partition panels, 5 vapor barrier layers are not required.

Figure 8 illustrates the relationship of the space divider panels B to each other. The connecting trench 4 between the longitudinal extensions 1 of the frame 1 of the adjacent partition panels B is filled by the guest strip 7, by means of which a power transmission connection is established between the adjacent partition panels B.

It is expedient to insert a sealing strip 8 in the part of the connection trench 4 left open by the guest strip 7 and to seal the groove formed between the edges of the adjacent panels 2 with the sealing strip 9. The guest strip 7 is preferably made of wood and the sealing strip 8 and the strip 9 may be made of plastic. The latter have primarily an airtight function.

In principle, the connection of the space bounding panels K shown in Figure 9 to one another is quite similar. Also, the connecting groove 4 with the sealing strips 8 also has a guest strip 7 in the connecting groove 4 formed between adjacent longitudinal supports 1a of the U-section. There is no difference in the air-tightness created by the sealing strip 9 inserted in the grout between the bounding plates 2.

As the space barrier panels K, they are provided with a vapor barrier layer 4 and a waterproof plaster 6 on their outer side. The latter is preferably used during the factory assembly of the structure, e.g. pneumatic spraying, so you do not usually need to apply special plaster layers.

In addition to the two adjacent space boundary panels, in the case shown in Figure 10, a space divider panel B is present at the node. In the horizontal section shown here, it is evident that the connection shown in Fig. 9 is completed by inserting the trench 10 into the trench formed between the longitudinal arm la of the space divider panel B and the inner boundary panels 2 of the space divider panels.

Preferably, the sealing strip 8 is also located here, along with the vertical strips of the space divider panel B covering the corners joining the enclosure corners K with the space divider panels. The latter can be secured to the longitudinal brackets la of the space bar K by means of the wood screws 12.

Because of the wood-like handling of asbestos, perlite and cement based frames 1 and 2, there is no obstacle to making screwed joints. Such wood screws 12 may also be used, as shown in Fig. 9, to fasten the edges of the bounding plates 2 to the frame 1 and the guest strip 7.

All. Fig. 2A shows the relationship between two space bounding panels K at right angles to each other. This time it is necessary to eg. a wooden pole 13, to which the longitudinal arms 1a of the space bounding panels K can be fixed by means of wood screws 12. As a perpendicular meeting, the inner connecting corner can now be covered with the corner support strip 11.

Figure 12 shows that the space boundary panel K is preferably connected to the base body 18 via the lower sole beam 20. The rib 20a of the latter extends into the cross-member lb of the U-shaped cross-section panel lb. The lower sole beam 20 is preferably secured to an anchor member 15 which is embedded in a post 17 solidified material. In this way, a reliable force transfer connection is established between the base body 18 and the space bounding panels K.

In addition to the vapor barrier layer 5 made of plastic sheet, bitumen sheet or foil, it is generally useful to include an elastic leveling layer 27 between the base body 18 and the lower sole beam 20. The upper edge of the base body 18 may be sealed by a water heater 16 attached to the space boundary panel K and / or the lower sole beam 20.

Figure 13 illustrates the connection between a space bounding panel K and a space enclosing panel L. The connection between the two adjacent L overlay panels was also noted here. The essence of the connection is that the transverse cable 1b of the space bounding panel Kb extends the rib 14a of the upper guide beam 14, which at the same time fulfills several roles.

In addition to merely connecting, it prevents the horizontal movement of the space boundary panel K and also transmits the loads from the space enclosure panel L. Preferably, the connection site is provided with a metal roofing bracket 19 which is intended to prevent the L panel from rising.

The frames 1 of the space-covering panels L are preferably formed by rectangular parallelogram cross-sections la and crossbars lb. Among the latter though-41

183,339 create power transmission connections with 7 guest slats, as seen with the space divider K and the space divider panels B. Preferably, the shell 28 is placed over the space cover panels L by inserting an additional additional insulating pad 3a and protecting it by the additional moisture barrier layer 5a.

Figure 14 illustrates the relationship between the L overlay panels L and the B partition panel. Adjacent to the span panels L is the slab beam 21, to which the inner shims 2 of the span panels L, the slab 10 and the slats 11 are fastened by means of wood screws 12.

None of the figures is marked, but it is somewhat true that the panels 2 are bounded on one side by fasteners, e.g. called. it is advisable to attach it with pop rivets to the frames 1. Referring to Figure 12, which has already been referred to, it may be mentioned that, if necessary, an additional sole beam may be arranged between the floor 22 of the building and the base body 18, the design of which may be adapted to the function of the building.

The variable building structure according to the invention is advantageous for any purpose, with a low number of buildings.

Claims (10)

Patent claims 1. Variable building structures, low-level buildings such as detached houses, terraced houses, communal buildings, eg. motels, kindergartens, garages, lofts, etc., which include foundation structures, boundary and partition brackets, as well as floor and enclosure elements, which also have dimensions for common bases, spacers, enclosures, floor and enclosure elements and optionally openings panels, sandwich elements having panels of identical function, interchangeable with each other, adjacent panels provided with connecting portions and / or auxiliary coupling means, each panel having a solid insulating board and at least one intermediate layer therebetween, preferably a sandwich element enclosed in a frame consisting of a load-bearing frame of the panel, preferably with U-shaped longitudinal and transverse supports, along the boundary edges of the panels h extending the containment sheets over the frame or outwardly rotating the open side of the U-sections of the frame to form a connecting trench for contacting the adjacent panel or other structural member along the longitudinal boundary edges of adjacent space boundary panels, space divider panels, and overlap panels and a guest truss is inserted in the connecting trench to form a tubular hollow hollow, and the panels are assembled and disassembled by means of removable joints, characterized by the fact that the panel has U-shaped longitudinal sections (la) and U-cross sections (lb), both limiting sheets (2) non-combustible, fungicidal and insect-resistant silicate-based, cementitious and wood-scalable, preferably molded, along the shorter limiting edges of the containment panels (K) into the connecting trench (4) of the enclosure panels (K) above the leading cross member (lbf) of the frame (1) and thereby preventing the horizontal deflection of the enclosure panel (K) 1) a laterally supporting upper beam (14) for laterally supporting its longitudinal support (1a) and also for distributing the loads from the spacing panel (L), while guiding the lower transverse support (lba) of the frame (1) and thereby the space barrier panel (K) to prevent horizontal deflection while supporting the longitudinal frame (1a) of the frame (1) laterally, a lower base beam (20), preferably T-shaped, to facilitate its distributed transfer to the base body (18), extending along the shorter boundary edges of the partition panels (B) to connect with the overlap panels (L) and below auxiliary sole beam (23) suitable for connection to a room floor (22) and / or to a base body (18), the boundary panels (K) meeting each other in different planes or the divider panels (B) and, optionally, the vertical divisions of the divider panels (B) additional connecting fittings, eg. corner posts (13) and / or auxiliary trusses (10) are provided. 2. Variable building structure according to Claim 1, characterized in that the upper guide beams (14) and the lower sole beams (20) are provided with fixing pockets (24) for receiving and supporting the longitudinal supports (1a) of the frames (1) of the boundary panels (K). Variable building structure according to claim 2, characterized in that the fixing cavity (24) is defined by the ribs (14a, 20a) of the upper guide beams (14) and the lower sole beams (20) extending into the connecting trenches (4). is formed by omitting or removing a portion of its length. Variable building structure according to claim 2 or 3, characterized in that the size of the retaining cavity (24) in the direction of the longitudinal axis of the upper guide beam (14) and the lower sole beam (20) is the lengths (1a) of the panels to be supported. ) cross-sectional size. 5. Variable building structure according to any one of claims 1 to 4, characterized in that the panels (2) are bounded to the frames (1) by means of fasteners, e.g. called. pop with nails and / or glue. 6. Referring to sections 1-5. Variable building structure according to any one of claims 1 to 3, characterized in that between the vertical members (lf) of the frames (1) and the guest (7) or trusses (10) they receive and the upper horizontal members (lfv) of the frames (1) and inserting strips (8) between the upper guide beams (14) forming the truss rib (14a) and between the lower horizontal members (lav) of the frames (1) and the truss rib (20a) of the lower sole beams (20). 7. Variable building structure according to any one of claims 1 to 3, characterized in that the joints between adjacent panels of the same function are filled with an air-tight sealing strip (9). 8. Variable building structure according to any one of claims 1 to 4, characterized in that the boundary panels (K) meeting in different planes are connected to each other or to the spatial panels (B) or to the spatial panels (L) and to the spatial panels (B) to each other or to the spatial panels. ), and finally the floor (22) of the space divider panels (K) and the space divider panels (B) 183 339 are preferably provided with corner strips (11). 9. Variable building structure according to any one of claims 1 to 3, characterized in that the space bounding panels (K) and the space covering panels (L) have at least one vapor barrier layer (5) and optionally a waterproof covering, e.g. They are provided with waterproof plaster (6). Variable building structure according to any one of claims 1 to 9, characterized in that the base beams (20) of the floor (22) and / or the space bounding panels (K) are fixed by means of anchors (15) to the base body (18). are.