CZ308994B6 - Building system - Google Patents

Abstract

The building system comprises prism shaped modules (1, 8, 9, 10, 14) with a longitudinal protrusion on the upper side and a corresponding longitudinal groove on the lower side and a vertical groove on at least one front side for the connecting pin (11) and on at least on one side by at least one auxiliary vertical groove for the pins of other building elements. The modules (1, 8, 9, 10, 14), the connecting pin (11) and the building elements are made of a material containing 10% by weight blends of crushed recycled polymers, 10 to 80 % by weight inert filling materials selected from the group of sand, crushed glass, crushed aggregate, rubber, metal sawdust, wood sawdust, crushed ceramics, crushed construction and technological recyclates, max. 1% by weight of coloured powder pigment, maximum 10 % by weight UV stabilizers and maximum 10% by weight fire retardants. Furthermore, the system comprises spacers (2, 4, 7, 12, 15) connectable to the modules (1, 8, 9, 10, 14) with two holes one above the other for inserting steel pipes (6).

Description

Building system

Field of technology

The invention relates to a building system interconnecting individual building elements and comprising prism-shaped modules provided with a longitudinal protrusion on the upper side and a corresponding longitudinal groove on the lower side and a vertical groove on the at least one front side for the connecting pin and at least one auxiliary vertical groove for the pins of adjacent building elements.

State of the art

The current technological solutions of buildings are mainly dependent on the use of classic building elements, construction adhesives, mortar, concrete and similar materials based on cement, water, chemistry, inert materials and various fillers. With already assumed error rate, ie tolerance for accuracy, axial perpendicularity and dimensions of the structure. All this is conditioned by loss-making technological breaks and the need for a large number of tools and heavy equipment, including considerable costs for the import and transfer of material. The contamination of the surroundings of the building and the need for a large number of professional workers to carry out the construction is also not negligible. Due to the high weight of the existing lintels and beams, crane technology and a larger number of workers are required during assembly. There is a risk of injury during handling.

Various building systems are also known which comprise modules of different shapes, in particular a prism, which are assembled together without the use of adhesives, only with the aid of different pins. Their main disadvantage is that they only allow vertical construction, not horizontal. They use common construction techniques to create floors and ceilings, which loses their greatest advantage, ie easy construction using a minimum amount of construction technology.

For example, a building lintel is a load-bearing building element that is placed above building openings in order to transfer pressures to the masonry. The upper part of the opening is the lintel. The load-bearing structure of the lintel is subjected to a load that is transmitted from the ceiling to the masonry, columns or pillars. The supporting structure of the lintel consists of vaults or lintels, which can be either brick, monolithic or prefabricated. In terms of composition, the translations differ in aperture size, total length of the translation, length of the translation, height and width of the translation. Lintels and lintels can have different shapes, can be made of different types of material and can be made with different technologies.

Brick lintels - are used only rarely today. Previously, it was the most frequently used method, for example, it was made of reinforced strip steel or arched with a flat bottom surface.

Steel lintels made of I-beams - are used and used where the openings are larger and where the lintel is more loaded. These lintels made of I-shaped steel girders are made by first placing them on concrete substrates in cement mortar, securing the steel girder in the correct position and then there is a double way of proceeding:

1) To secure the beam against tipping over, bricks are placed on the lower flanges and the sides are lined with bricks on cement mortar. The sides must be secured for a time with boards or planks pulled with steel wire. The inner part of the lintel is concreted. After the concrete has hardened, the auxiliary formwork is removed and the lintel is plastered. To prevent the plaster from falling off and holding up better, the lower flanges are covered with wire mesh. For perimeter walls, the lintel must be provided with thermal insulation.

2) The whole I-beams are concreted from all sides, a reinforced concrete lintel with reinforcement from steel I-beams is created. However, a supported formwork must be made into which it will be concreted. Prefabricated reinforced concrete components - today they do not comply due to thermal insulation regulations,

-1 CZ 308994 B6 because the thermal bridges they create in the structures are an open way for heat to escape from the rooms.

A beam is a load-bearing part of a technical work that is intended for the transmission of forces. This is usually a static transfer of force from other bodies, rather rarely it is a type of dynamic stress. The term we most often encounter especially in construction and architecture in large buildings, in the field of mechanical engineering especially in large machinery.

In practice, the beam can be a transverse strut, inclined reinforcement or a horizontally embedded bracket, etc. Beams are therefore considered to be horizontal load-bearing structures, the predominant static stress is bending.

The beams form the main load-bearing structure of the ceramic ceiling and can be reinforced concrete or ceramic concrete with steel reinforcement, where the reinforcement transmits tensile stresses in the structure, compressive stresses are taken over by either the concrete or the ceramic fitting itself. which transfer loads to the beams are usually made of a ceramic material, lightened by cavities and reinforced by internal ribs, so that they have a low weight and show sufficient strength within their dimension.

The disadvantages of these ceilings include: the assembly of individual elements is laborious and requires compliance with technological regulations, the full load-bearing capacity of the ceiling structure is achieved after hardening and curing of the grouted concrete and by this time the beams must be supported. When recycling beams, it is necessary to use special crushing machines and subsequent separation of steel reinforcement from used ceramics or aggregates. Due to the absorbency of the materials used in the beams, it is necessary to protect the beam against moisture, which can significantly shorten its life and static properties.

The essence of the invention

The above-mentioned drawbacks are largely eliminated by a building system connecting the individual building elements and comprising prism-shaped modules provided with a longitudinal protrusion on the upper side and a corresponding longitudinal groove on the lower side and a vertical groove on the at least one front side for the connecting pin and on at least one side by at least one auxiliary groove in the vertical direction for the pins of adjacent building elements, according to the invention. Its essence is that the modules, pin and building elements are made of a material containing at least 10% by weight, a mixture of crushed recycled polymers, 10 to 80% by weight, inert filling materials selected from the group of sand, crushed glass, crushed aggregate, rubber, metal sawdust , wood sawdust, crushed ceramics, crushed construction and technological recyclates, max. 1% by weight, colored powder pigment, max. 10% by weight. UV stabilizers and max. 10% mass, fire retardants, and also contain spacers connectable to the modules and provided with two holes placed one above the other for inserting steel pipes.

The modules are preferably selected from the group consisting of a base module with through-going auxiliary grooves, a beam base module with auxiliary grooves provided with stops, a base module with a shoulder for accommodating an end spacer, a corner base module and an end base module with a shoulder for accommodating the end collar strut.

The spacers are preferably selected from the group of struts provided with longitudinal pins, a base strut provided with pins with stops, a beam strut provided with a collar on its underside, an end collar strut and an end strut.

The building system in a preferred embodiment comprises an upper flap and a lower flap formed by a planar surface provided with protrusions for attachment to modules and / or spacers.

- 2 CZ 308994 B6

The pipes can be provided with a locking mandrel and the modules can be connected to the spacers with a nut screw.

On the outside, the modules can be equipped with a holder for vertical gardens. The basic modules are preferably provided with housings for holding window frames and door frames.

The pins are preferably provided at their ends with protrusions and cutouts for connecting two adjacent pins.

The building and construction system consists of individual components that interlock with each other using grooves and locks and pins dry. The components have a specific size and function in the overall design. No construction adhesives are needed to join the components, thus eliminating all wet processes and technological breaks, which have a negative effect on the price and time of construction.

The system functions as a whole. By means of interconnected grooves and locks and pins in the shape of two connected triangles, a dowel, also called a bow, but not exclusively, the structure of the building gradually gains great mechanical strength and rigidity. Thanks to the mechanical interconnection of individual building elements, the structure behaves flexibly and absorbs external mechanical influences, so it is also suitable for seismically active areas.

Calibrated structural elements guarantee high construction accuracy and minimal joints between individual modules. Thanks to the interconnectedness and shape accuracy, the entire system guarantees a level and adherence to construction angles. Automatically corrects any inaccuracies on the part of the builder.

The lintels and beams of the building system are composed of individual components that fit into each other and as a whole form a solid, rigid structure with a high load-bearing capacity. The advantage of such a construction over the existing one is simple handling without mechanization and crane technology, high assembly speed, low weight of individual components, implementation without technological breaks, the absence of any formwork, wet processes and chemicals.

The variability in the possibility of strengthening the static properties of the lintel by inserting galvanized steel thick-walled pipes into the structure is also not negligible. Another important element of the system is the fixed connection of the lintel, ie the beam, to the perimeter walls, which at the same time firmly tightens the building. All this only on the basis of the mechanical interconnection of the individual elements of the structure. Compared to conventional lintels and beams, the weight is up to 50% lower. When using beams in the floor and ceiling construction, we also get enough space for electrical wiring, water, waste and other technologies with easy access in case of repair.

In addition, the beams built into the perimeter walls of the foundations, in conjunction with the floor beams, make it possible to build the building on piles. All this without the use of traditional wet technologies, adhesives and other chemicals. Only by mechanical connection of individual components. Unlike existing technologies, the whole system can be disassembled and used in another project without losing its useful and strength properties.

Due to the material composition of the individual components, there is no need to further plaster and protect the beams or lintels. In addition, the air pockets in the beams and lintels can be filled with loose thermal insulation, such as Perli, as required.

The material from which the individual elements of the building system are made is composed of a mixture of crushed, granular, recycled polymers, technical and food, inert filling materials such as sand, crushed glass, crushed aggregate, rubber, metal sawdust, wood sawdust, crushed ceramics, other crushed construction and technological recyclates and other possible additives, such as pigment, UV stabilizers, thermal insulators, fire retardants, etc. The ratio of individual components in the mixture in% is determined by the use and function of the component and its demands on physical

-3GB 308994 B6 properties and requirements such as hardness, flexibility, toughness, UV resistance, heat resistance, weight and more. The resulting mixture is a thermoplastic that is processed in an extruder and then cast, extruded or pressed into the desired shape.

Advantages of the building system • Modular solution guaranteeing compliance with technological procedures.

• Construction speed.

• Concurrence of crafts at the same time, minimizing time for crafts and professional work.

• Elimination of the need for construction adhesives and plasters.

• No technological breaks.

• Possibility of self-construction, medium demands on craftsmanship.

• Low weight of all components.

• 100% recyclable.

• Reuse of building elements, the possibility of disassembly without loss of useful properties.

• Recycled material, hygienically safe, resistant to moisture and mold, normal resistance -50 to +70 degrees C, not easily flammable, non-absorbent.

• The service life of the material used is at least 200 years.

• Minimum storage requirements.

• Also suitable for seismic hotspots.

• Construction designed for construction on piles, such as floodplains, coastal areas, structures on water, etc.

The solution can also be used as a multifunctional kit. All elements of the kit are then made in a scale of 1:10. Their shape is identical to the original building elements of the Lisrec system. The kit consists of the same as in real construction.

The future builder can build his dream house cleanly, at the same time learning the exact procedures and composition of the construction in a fun way, as he will in reality. A practical tool for builders, architects and designers. Educational kit for children, where they can build a house and other buildings on a smaller scale. They will gain a relationship with this building system from an early age.

It is therefore a kit with the fact that all elements are identical to the building system. Thanks to the kit, real buildings can be modeled at a scale of 1:10. The structure is assembled in the same way as in real construction. The kit is made of polymer.

The kit is suitable for:

• Future self-help builders - The possibility of involving the whole family. They materialize their dreams and at the same time train in the process of assembling the structure. They can try a number of variants before deciding on a definitive one and buy components in real size.

-4GB 308994 B6

The kit will come with more parts than necessary so that the builder can add a garage, swimming pool, workshop with links to the catalog and types, to test what it will look like and to consider a larger purchase of real building materials.

• Children - they build real scale houses, ie constructions, not unrealistic toys. They gain a positive attitude, creativity and trust in the system. They can materialize their ideas. When they are big, they will use this system to build what they have dreamed of.

• Architects and designers - they can test their ideas. Better than 3D visualization on PC. They can offer the client a project that can be touched.

• Students - as a school aid.

• Creative - they can make full use of their skills and implement them on a large scale.

• Modelers and do-it-yourselfers - an ideal platform for the implementation of their projects.

Clarification of drawings

The building system according to the invention will be described in more detail on the basis of a specific exemplary embodiment with the aid of the accompanying drawings, in which FIG. 1 shows an axonometric view of a foundation beam. Fig. 2 is a top view of a floor and ceiling beam. Fig. 3 is an axonometric view of the floor and ceiling beam. Fig. 4 is an axonometric view of a beam for a window and door lintel, and Fig. 5 is an axonometric view of a pipe in a structure.

Examples of embodiments of the invention

The basic module 14, i.e. the main structural element, which is the basis for the system elements, is in the shape of a rectangular block. On the upper side with an elongated protrusion and on the lower side provided with an elongated cutout into which the upper elongated protrusion of the structural part of the adjacent base module 14 fits, which is located below this base module 14 in the structure. plane of structural elements. In both faces of the base module 14 there are, but not exclusively, recessed cut-outs for inserting connecting pins 11 and locks in the shape of two connected triangles, a dowel, also called a bow, but not exclusively. These cut-outs for inserting the connecting pins 11 and the structural spacers 15 are also located on the longer side of the base module 14, i.e. on its side at 1/3 and 2/3 of the length of the base module 14, but not exclusively. After the insertion of the connecting pins 11, these cut-outs interconnect, i.e. connect the base module 14 with the adjacent modules and the spacers located below and above the module, or next to it. The opening for the insertion of the connecting pin 11, which connects the module to the adjacent modules located below and above the module, also passes vertically through the center of the module.

The other structural elements of the system are dimensionally derived from the base module 14 so that they can be interconnected by means of cutouts for pins and protrusions based on the shape of the connecting pins 11 and the base module 14.

The basic module 14 and the derived building elements of the system further pass vertically through technical penetrations intended for the routing of electrical, data and other cables, low voltage conductors, water pipes, hoses, waste pipes, heating pipes and other technologies. Unused technical penetrations can be further filled with loose thermal insulation material, sand and the like according to the requirements for other physical properties of the structure. In the corner building modules are

-5CZ 308994 B6 in addition, vertical penetrations are placed on the possible penetration of the threaded rod binding the structure vertically.

The connecting pins 11 have an elongated shape in the shape of two connected triangles, i.e. a dowel, also called a bow - but not exclusively, with dimensions fitting into the cut-outs of the base module 14. The connecting pin 11 generally slides vertically into the cut-outs in the base module 14 and adjacent building structures. modules and building system elements. The function of the connecting pin 11 is a fixed detachable connection, i.e. the binding of the building elements of the system to each other. Overlaps are formed at both ends of the connecting pin 11, which have the function of interconnection and preventing horizontal penetration of water and dirt. The overlaps of the opposite connecting pins 11 fit tightly together. Connecting pins 11 intended for attaching other elements to facades, fences and the like do not have to have these overlaps.

The spacers 15 ensure the exact distance between the base modules 14 at the double wall. These are usually perimeter load-bearing walls or reinforced structures. The longer longitudinal sides are provided with protrusions, such as pins. These protrusions slide into the slots in the base module 14 and the adjacent building blocks of the system. When pushed in, the structures are tied together again and strengthened. The spacers 15 have different lengths and slide above each other so as to interconnect the individual layers of the structure in the vertical direction. In the spacers 15 there are openings on the wider side into which the thick-walled beam pipes 6, water and waste pipes, electrical and data cables, vacuum cleaner pipes, ventilation and the like are inserted. The base struts 12 intended for lintels, rings and other supporting elements have additional protrusions which fit into the prepared cut-outs in the designated structural modules and prevent vertical movement of the modules. Beam spacers 4 provided with a collar are used for floors and ceilings, which ensures a precise distance between the individual spacers and at the same time fills the area with the lower flap 5, the outer collar spacers 7 bind the ceiling with perimeter walls and partitions parallel to the beams. In addition, the base struts 12 with protrusions have holes drilled on the narrower end side through the insertion screw 13.

The lintels are formed of at least two thick-walled steel tubes 6 inserted into base struts 12 with protrusions, which prevent vertical movement of the basic beam modules 10 provided with notches for these protrusions. The lintels are mainly designed for static bridging of openings above windows and doors. The tubes 6 can have openings in the sides into which metal pins are inserted through the spacers, preventing the horizontal movement of the tubes 6 in the spacers. In the basic version, the tubes 6 are secured against sliding out by a locking pin 16, which is firmly inserted into the galvanized steel thick-walled tube 6 and pulled over the building element by a screw with a washer.

The floor and ceiling are formed by ceiling and floor beams, end struts 2, beam struts 4, lower flap 5 and upper flap 3. The beams provide statics and at the same time pull the opposite masonry together. A lower flap 5 is inserted from above between the individual beams, which forms a ceiling which locks the secondary beam spacers of the adjacent parallel beams. In the same way, these beam spacers are connected from above by an upper flap 3, which forms the upper floor area. The resulting gap between the lower flap 5 and the upper flap 3 serves to guide cables, pipes, recessed lighting, air conditioning, thermal insulation backfill and other technologies. The interconnection and interconnection of individual floor elements and components creates a solid, rigid structure, suspended in the surrounding perimeter walls. All components are designed so that the builder can easily slide them from top to bottom into the prepared locks. The resulting floor structure is immediately walkable and ready for use.

The beams are formed by end struts 2, thick-walled steel tubes 6 and beam struts 4 with a collar. The end struts 2 are inserted from above into the base modules 1, two thick-walled pipes 6 are inserted into the end struts 2 and secured by a metal pin. 6 among themselves. In addition, the tubes 6 can be through struts

-6GB 308994 B6 secured against movement by metal pins. In the basic version, the tubes 6 are secured against sliding out by a locking pin 16, which is firmly inserted into the galvanized steel thick-walled tube 6 and pulled over the building element by a screw with a washer. At the other end of the beam, an end strut 2 with a locking pin is pushed onto the tubes 6 again. The end struts 2 are secured against release from the base module 1 by the upper base module 14, which is placed on them in the upper layer, and to the other layers above them. Thus, in addition to the static function of the floor and ceiling, these beams perform the function of retracting the opposite walls in which they are anchored. Beam - foundations, where the foundation module 1 is tightened by a screw 13 with the outer shell of the building by the girder basic module 10.

The end strut 2 of the beam has protrusions on the underside, which slide tightly into the cut-outs in the base module L. Furthermore, it has two openings for tight insertion of thick-walled pipes 6, which can be secured from above by a metal pin against sliding out. In the basic version, the tubes 6 are secured against sliding out by a locking mandrel 16, which is firmly inserted into the galvanized steel thick-walled tube 6 for the entire length and pulled over the building element by a screw with a washer. The upper tube 6 is firmly secured against sliding out by means of a screw which is passed through the washer through the base module 1 and the end spacer 2 and screwed into the locking darkness 16 inserted in the tube 6. This is how it is secured at the other end. This tightens the floor structure to the perimeter wall.

The base module 1 is identical in size to the base module 14, but is extended on the longer sides by ribbed surfaces into which the end struts 2 of the beams are inserted. The inner base module 1 is further retracted with the outer beam base module 10, i.e. the perimeter wall, two screws 13 which pass through the base module 1, the base spacer 12 and the outer beam base module 10 and are finally secured by a nut with a decorative cover. Thus, a very strong connection of the modules into one unit takes place, and by mutually horizontal interconnection of these modular units by thick-walled pipes 6 inserted through the foundation struts 12, a very strong self-supporting foundation-foundation strip is formed. This connection of modules is then repeated on the floor, where it ensures the function of the wreath. For greater strength, the tubes 6 can be placed around the circumference at the same height and stretched with a steel rope, which will be firmly terminated in the eye at both ends and tightened with tensioners. This creates a firm pull of the wreath over the corners where the pipes meet.

The locking tab 16 prevents the tube 6 from moving in the structure. It is firmly inserted into the galvanized steel thick-walled tube 6. By screwing the screw into the locking dark 16, the darkness is stretched inside the tube 6 and firmly fixed to the inner wall of the tube 6. Vmt passes through the building element and protrudes. The washer threaded on the vmt under the vmtu head prevents the vmt head from being crushed into the body of the building element, which is thus firmly retracted to the thick-walled wall 6.

The vertical garden is a facade element composed of individual components. These are façade pins without end overlaps, double-sided base module, façade holder, grille, dowel holder and dowel. The façade pins are inserted into the basic double-sided module from the outside. A universal façade holder is slid onto them, and a grid is slid onto it, which serves as a decorative support for climbing plants. The installation of the sealant is as follows: The sealant brackets are slid onto the façade pins. A soil mortar is finally placed between the two holders of the mortar. Everything is variable and can be adapted to the plants that will be grown on the facade. The vertical garden can also be used as a fence, where the fence is made of basic modules such as a simple wall and the components of the vertical garden are applied to this wall as on the facade.

The housing for mounting window frames and door frames is anchored in the notches for the pins of the basic module, which are on the narrower side. The housing has two pin-shaped projections on one side and a cut-out on the long side, into which the window or door frame is subsequently inserted. Gradually, as the layers of the base modules grow on top of each other, the individual housings are gradually pushed into the notches for the pins in place of the window or door opening at the edges of the wall. Once achieved necessary

-7 CZ 308994 B6 height of all cases above each other, the window or door frame is inserted into the cut-out. Securing against falling out is solved by the depth of the cut-out and the side screws with which the frame is screwed into the housing.

Other building and decorative elements derived from the dimensions, shapes, functions and use of the basic building system module and other building modules and compatible with the construction of the building system.

Building system in 1:10 scale as a kit. The elements of the kit are made in a scale of 1: 10. Their shape is identical to the original building elements of the system, but may differ in minor insignificant details. The kit consists of the same as in real construction. The kit is made of ABS polymer or recycled polyethylene.

In real construction, the assembly time for a new building system is reduced to ΙΟχ compared to the current classic ones. In the case of comparisons for wet processes, it shortens from days to minutes. After assembly and interconnection, the building elements are immediately 100% functional and ready for use, without the need for additional insulation, plaster and the like.

The size and weight of the individual modules are also favorable with regard to the possibility of involving family members as well. Due to zero construction dust and the absence of construction chemicals, the construction system is also suitable for allergy sufferers.

Industrial applicability

The building system according to the invention finds use in the construction of technical buildings, social housing, hobby workshops, garden program, garages, sheds, fences, vertical gardens, swimming pools, family houses and housing construction.

Claims (9)

PATENT CLAIMS A building system connecting individual building elements and comprising modules (1, 8, 9, 10, 14) in the shape of a prism provided with a longitudinal protrusion on the upper side and a corresponding longitudinal groove on the lower side and a vertical groove on the connecting pin at least on one front side. (11) and on at least one side with at least one auxiliary groove in the vertical direction for the pins of adjacent building elements, characterized in that the modules (1, 8, 9, 10, 14), the connecting pin (11) and the building elements are made of material containing at least 10% by weight, mixture of crushed recycled polymers, 10 to 80% by weight, inert filling materials selected from the group of sand, crushed glass, crushed aggregate, rubber, metal sawdust, wood sawdust, crushed ceramics, crushed construction and technological recyclates, max 1% by weight, color powder pigment, max 10% by weight. UV stabilizers and max. 10% mass, fire retardants, and also contain spacers (2, 4, 7, 12, 15) connectable to the modules (1, 8, 9, 10, 14) and provided with two holes placed one above the other for insertion steel pipes (6). Building system according to claim 1, characterized in that the modules (1, 8, 9, 10, 14) are selected from the group consisting of a base module (14) with through-going auxiliary grooves, a beam base module (10) with grooves provided with stops, base module (1) with shoulder for accommodating the outer strut (2), corner base module (9) and end base module (8) with shoulder for accommodating the outer collar strut (7). Building system according to claim 1 or 2, characterized in that the struts (2, 4, 7, 12, 15) are selected from the group of struts (15) provided with longitudinal pins, the base strut (12) provided with pins with stops, the beam strut (4) provided with a collar on its underside, end collar strut (7) and end strut (2). Building system according to any one of claims 1 to 3, characterized in that it comprises an upper flap (3) and a lower flap (5) formed by a planar surface provided with protrusions for attachment to modules and / or spacers. Building system according to any one of claims 1 to 4, characterized in that the pipes (6) are provided with a locking mandrel (16). Building system according to any one of claims 1 to 5, characterized in that the modules (1, 8, 9, 10, 14) are connected to the spacers (2, 4, 7, 12, 15) by a screw (13) with a nut . Building system according to any one of claims 1 to 6, characterized in that the modules (1, 8, 9, 10, 14) are provided on the outside with a holder for vertical gardens. Building system according to any one of claims 1 to 6, characterized in that the base modules (1) are provided with housings for holding window frames and door frames. Building system according to any one of claims 1 to 7, characterized in that the connecting pins (11) are provided at their ends with projections and cut-outs for connecting two adjoining connecting pins (11).