RU32146U1 - Building structure (options), volumetric block of building structure - Google Patents

Abstract

1. A building structure comprising an internal spatial frame with horizontal elements of floor floors and vertical elements of external and internal walls, with at least a part of the vertical elements of the frame made passing in plan through the vertices of the corners conjugated on the sides of the hexagons. 2. The building structure according to claim 1, characterized in that the interfloor ceilings, the external and internal walls of the building are made with the formation of interconnected volumetric blocks in the form of regular hexagonal prisms. 3. The building structure according to claims 1 and 2, characterized in that the floor slabs of each floor are supported on the horizontal elements, and the external and internal walls are supported on the floor slabs of the corresponding floor. 4. The building structure according to claims 1 to 3, characterized in that it has in plan a honeycomb structure comprising at least one group of building blocks, including a central and six peripheral building blocks, made in the plan in the form of regular hexagons, at least the central blocks in the vertical plane are aligned. 5. The building structure according to claims 1 to 4, characterized in that a staircase-elevator unit is arranged in coaxial central volumetric blocks and engineering communications are carried out. 6. A building structure comprising volumetric blocks bounded by lateral faces, wherein at least one volumetric block is made in plan in the form of a hexagon. 7. The building structure according to claim 6, characterized in that it contains at least six building blocks in plan, five of which are peripheral, adjacent along the perimeter to the central block, made in the form of

Description

Building structure (options), volumetric block of the building structure.

The inventive utility model relates to the field of construction and can be used in the construction of residential, office or industrial buildings.

Currently, buildings from prefabricated and monolithic building blocks have become widespread in the practice of construction. For example, the construction of multi-storey buildings from installed on top of each other and conjugated in terms of volumetric blocks such as a recumbent glass or cap having a prismatic shape is known. In terms of the design of such buildings, they usually consist of blocks forming rooms, for example, residential apartments, a staircase and elevator unit.

Known, for example, the construction of the building from the U-shaped volumetric basic and non-flush blocks SU, 1838528, A3. Each U-shaped block consists of two walls and a plate rigidly connected to them and supported on them. Blocks have different designs: monolithic, precast or precast monolithic. At least one of the walls can be made in the form of a frame and filling the frame opening. In this case, the building structure is made in the form of a frame with vertical and horizontal elements.

A variety of space-planning decisions of the building is achieved by the layout of the main and non-flush U-shaped blocks. The blocks can be mounted on top of each other with the support of the walls along the entire length or with the point support. In addition, the blocks can be installed by rotating them 180 degrees in a vertical plane.

However, the use of two sizes of blocks and their rectangular shape in terms of limits the architectural and space-layout capabilities of the building structure, in addition, it requires an increased consumption of material and increases the complexity of the construction of the building.

IPC 8; E04B1 / 348

The present utility model is based on the task of creating a building structure and a building block for such a design, which allow expanding the possibilities of architectural and space-planning solutions while reducing the expendable material and laboriousness of work.

The problem is solved in that in the construction of the building, including the volumetric blocks bounded by the side walls, according to the proposed utility model, at least one volumetric block is made in plan in the form of a hexagon.

According to one embodiment of the proposed utility model, the building structure contains at least six volumetric blocks in plan, five of which are peripheral, adjacent along the perimeter to the central block having the shape of a regular hexagonal prism.

The implementation of at least one of the volumetric blocks in the form of a regular hexagonal prism provides a fairly wide variety of architectural and space-planning solutions.

For example, around the indicated hexagonal block six (possibly smaller) volume blocks (peripheral blocks) can be arranged, each of which can also be made in the form of a regular hexagonal prism, or of another shape, for example, a truncated pyramid made in plan in the form of a hexagon, trapezoid, or another form.

In a preferred embodiment, the utility model is implemented in the construction of a multi-storey building containing external and internal walls and interfloor ceilings forming interconnected volumetric blocks made in the form of regular hexagonal prisms.

This design provides compact development with a wide variety of architectural and planning solutions.

Moreover, the building structure may have in plan a honeycomb structure containing at least one volumetric group

blocks, including a central and six peripheral surround blocks,

Depending on the architectural and planning decision of the structure, various pairings are possible in terms of the indicated groups of volume units.

For the rational use of the internal space of the building, the staircase and elevator unit and ensuring good insolation of the rooms, it is advisable that the central volume unit be configured to accommodate the staircase and elevator unit and the peripheral units of the premises.

Depending on the structure of the building, either all or part of the peripheral blocks will have inner side walls and outer side walls forming the outer walls of the building.

It is advisable to carry out volumetric blocks with a cross-sectional area of 15 m to ZOm.

The indicated dimensions are sufficient for placement in one volume unit of a one-room apartment (about 25 m in area), or of a stair-elevator unit, or of one of the rooms of a multi-room apartment (room, kitchen, other utility rooms).

When creating a residential or office building with adjacent rooms, for example with multi-room apartments, an additional peripheral volume unit adjoins at least two peripheral volume units.

In this case, the formation of rooms that do not have external walls with window openings is possible. Such premises can be equipped as corridors - halls, bathrooms and other office premises. Rooms with exterior walls with window openings have good insolation.

In order to simplify the construction of utilities (plumbing, sewer, ventilation), it is advisable that these communications pass through the central volume units.

The problem is also solved by the fact that the construction of the building contains an internal spatial frame with horizontal elements of interfloor ceilings and vertical elements of external and internal walls, while at least a part of the vertical frame elements are made passing in plan through the vertices of the corners of the hexagons mated on the sides,

Interfloor ceilings, external and internal walls are made in the form of filling the frame openings with the formation of volumetric blocks in the form of regular hexagonal prisms. Depending on the technological solution of the design, the filling of the frame can be monolithic, precast-monolithic, prefabricated, brick, etc.

The problem is also solved by the fact that the volumetric block of the building structure containing the side walls, according to the proposed utility model, is made in the form of a regular hexagonal prism.

Thanks to the indicated form of the block, a wide variety of architectural and planning decisions of the building structure is provided with a minimum number of standard sizes of mounting elements and the simplicity of the construction technology.

Other advantages of the claimed utility model will be described with examples of the best options with reference to the drawings, in which:

FIG. 1 - building structure from volumetric blocks in plan;

FIG. 2 is a view 2-2 of FIG. 1, a fragment of a vertical section of a building;

FIG. 3 - volumetric blocks in plan, basic standard sizes;

FIG. 4 - central volume unit in plan with engineering communications;

FIG. 5 - volume unit;

Fig, 7 is a fragment of a volume unit, a brick-monolithic embodiment;

FIG. 8 is a fragment of a volume unit, a brick embodiment.

In FIG. 1 shows the construction of the building in plan, containing volumetric blocks 1 made in plan in the form of equal regular hexagons. The shape of the hexagon allows the most rational arrangement of blocks among themselves without the use of non-flush elements, as well as reduce material consumption. In addition, due to the hexagonal shape in terms of volumetric blocks, compact development with a wide variety of architectural and planning solutions is provided.

According to one embodiment, the design has in plan a honeycomb structure comprising at least one group of volume units, including a central volume unit and six peripheral volume units. The design shown in FIG. 1, has one central block li, six peripheral blocks 12-7 located around the perimeter of the central block li and two additional peripheral blocks Is, Isc placed between pairs of peripheral blocks: 14 - Is and Is - 1b / respectively.

A different space-planning solution of the building structure is also possible, for example, it can combine several groups of volume blocks, or consist of one group of volume blocks, including one central and six (possibly less, for example five) peripheral volume blocks.

In the preferred embodiment shown in FIG. 2 and FIG. 5, the volume blocks are made in the form of regular hexagonal prisms.

A variant is possible in which only the central block is made in the form of a regular hexagonal prism, and the peripheral blocks have a different shape, for example, in the form of a truncated pyramid with a plan shape in the form of a trapezoid, hexagon, etc.

regular hexagonal prisms mounted coaxially on top of each other.

The design contains an internal spatial frame with horizontal elements of interfloor ceilings 2 and vertical elements of external and internal walls, 3 and 4, respectively. External, internal walls 3 and 4, respectively, and floors 2 are made with the formation of regular hexagonal prisms conjugated to each other, coaxially placed one above the other. Only coaxial placement of central units is possible. In addition, hexagonal prisms of volumetric blocks of one floor can be rotated at an angle relative to prisms of volumetric blocks of another floor.

Coaxial central volumetric blocks li (Figure 1) are formed with the formation of a staircase and elevator unit 5, and peripheral blocks la -Ig - premises. This structure allows you to increase the workload of the staircase and elevator unit and the efficiency of the structure as a whole.

The building structure may contain on the ground floor an additional volumetric block b under the staircase hall. The specified block b may have a shape other than a hexagonal prism.

The peripheral blocks 12 - Ig (Figure 1) have lateral faces that form the outer walls 3 of the building, and lateral faces that form the inner walls 4 of the building. Such blocks in a residential building can serve as one of the rooms of a multi-room apartment (room, kitchen), or as a one-room apartment. In the last indicated embodiment, the peripheral unit can be equipped with internal partitions (not shown) dividing the space of the volume unit into functional areas: residential, kitchen, area of the sanitary unit (not shown). Thanks to the hexagonal shape of the block, good insolation of all residential premises of the building is ensured.

Part of the peripheral blocks can only be formed by the internal walls of the building (not shown). Such blocks may

serve as a utility room: corridor - hall, sanitary unit, dressing room, etc.

In FIG. 1 peripheral blocks la, 1z / are made in the form of one-room apartments, peripheral blocks 1b Ig are combined into a two-room apartment, and peripheral blocks 14, Is Is combined into a three-room apartment. A different layout of apartments is possible.

Depending on the functional purpose of the building, volume blocks are performed with a cross-sectional area of 15 m to ZOm. If there are one-room apartments in the building, it is advisable to carry out volumetric blocks 1 with a cross-sectional area (S) from 1 bm to 25 m. In FIG. 3 shows the basic unit sizes: IS 25.85 m, II - S 16.56 m, III - S 24.65 m. Such blocks can perform various functions: a one-room apartment, rooms in a multi-room apartment, a corridor, a staircase and elevator unit, office space.

In the central block li (Fig. 4), followed by wiring along the peripheral blocks, engineering communications 7 are arranged (water risers, electrical wiring, etc.).

In FIG. 5 shows a peripheral volumetric block, which is a regular hexagonal prism, the side faces of which form the outer walls 3 and the inner walls 4 of the building. The outer walls 3 of the volumetric block are made with window openings 8 provided with metal frames 9 for glass filling. Window openings 8 may occupy only part of the outer wall 3 or the outer wall may be fully glazed. At least one inner wall 3 is made with a doorway 10. The block has an overlap 2.

The building structure can be formed on the basis of an internal spatial framework with horizontal elements of interfloor ceilings and vertical elements of external and internal walls. At least part of the vertical frame elements are made passing in plan through the vertices

angles of hexagons conjugated on the sides. Interfloor ceilings, external and internal walls of the building are performed with the formation of volumetric blocks in the form of regular hexagonal prisms.

Various filling of the frame is possible, for example, monolithic, brick, glass (for external walls) and so on. For example, monolithic or prefabricated floor slabs of each floor are supported on horizontal elements, and external and internal walls are supported on floor slabs of the corresponding floor.

The building structure and building blocks can have various well-known designs: monolithic, precast-monolithic, precast, brick, brick-monolithic.

The choice of technology is determined by financial and time costs, the environment, the purpose of the building and other factors.

The volume unit shown in FIG. 5 represents

prefabricated-monolithic structure containing prefabricated internal walls 4, reinforced concrete floor 2, monolithic external walls 3 and corner posts 11.

The inner walls 4 are made of rectangular reinforced concrete slabs, and the floors are prefabricated from the main rectangular slabs and two non-flanged triangular slabs (not shown). At the same time, adjacent blocks can have common or double internal walls. Overlapping can be made of hexagonal plates.

The prefabricated monolithic option provides a fairly cheap and fast technology for the construction of a building using a minimum number of panel sizes.

In FIG. b shows the composite mounting elements of the prefabricated construction of the volume unit: internal wall panels 12, external wall panels 13 with window openings 14, main rectangular panels 15 of the floors and non-flange triangular panels 16 of the floors.

The prefabricated structure, as well as the prefabricated-monolithic one, provides a fairly cheap and fast technology for building a building using a minimum number of panel sizes.

FIG. 7 is a brick monolithic embodiment, and FIG. 8 brick version of the volume unit. As shown in FIG. 7 option, the inner walls (not shown) are made of brick, the outer walls 4 contain a brick section of the wall 17 with a window opening 8, monolithic vertical racks and jumpers 18 above the window openings. According to the embodiment shown in FIG. 8, the outer 4 and inner (not shown) walls are made of brick (wall 19). In this case, the uprights can be reinforced, and reinforced concrete lintels are made above the window openings 20. Overlappings in the described embodiments can be made of reinforced concrete slabs (for example, a main rectangular and two non-triangular). As in the previously described embodiments, the outer walls can be completely glazed. Moreover, they contain supporting frames.

Prefabricated brick and brick options are characterized by the greatest possibilities of architectural and planning solutions.

It is also possible monolithic technology for the manufacture of building structures and building blocks, which is carried out according to the well-known technology by creating reinforcing cages with the subsequent construction of concrete walls and ceilings.

The given implementation examples serve solely the purpose of illustrating the claimed utility model and should not be construed as limiting its scope, which is determined by the utility model formula given below.

Claims (33)

1. A building structure comprising an internal spatial frame with horizontal elements of floor floors and vertical elements of external and internal walls, with at least a part of the vertical elements of the frame made passing in plan through the vertices of the corners conjugated on the sides of the hexagons. 2. The building structure according to claim 1, characterized in that the interfloor ceilings, the external and internal walls of the building are made with the formation of interconnected volumetric blocks in the form of regular hexagonal prisms. 3. The building structure according to claims 1 and 2, characterized in that the floor slabs of each floor are supported on horizontal elements, and the external and internal walls are supported on the floor slabs of the corresponding floor. 4. The building structure according to claims 1-3, characterized in that it has in plan a honeycomb structure containing at least one group of building blocks, including a central and six peripheral building blocks, made in the plan in the form of regular hexagons, while at least the central blocks in the vertical plane are coaxial. 5. The building structure according to claims 1 to 4, characterized in that a staircase-elevator unit is arranged in coaxial central three-dimensional blocks and engineering communications are carried out. 6. A building structure comprising volumetric blocks bounded by lateral faces, wherein at least one volumetric block is made in plan in the form of a hexagon. 7. The building structure according to claim 6, characterized in that it contains at least six building blocks in plan, five of which are peripheral, adjacent to the perimeter to the central unit, made in the form of a regular hexagonal prism. 8. The building structure according to claims 6 and 7, characterized in that the peripheral volumetric blocks are made in the form of regular hexagonal prisms. 9. The building structure according to claims 6-8, characterized in that at least two peripheral volumetric blocks adjoin an additional peripheral volumetric block. 10. The building structure according to claims 6 to 9, characterized in that it has in plan a honeycomb structure comprising at least one group of building blocks, including a central and six peripheral building blocks, made in the form of regular hexagonal prisms. 11. The building structure according to claims 6-10, characterized in that it is multi-story with coaxial arrangement of central volumetric blocks, while a staircase-elevator unit is arranged in coaxial central volumetric blocks, and rooms are located in peripheral blocks. 12. The building structure according to claims 6-11, characterized in that the volumetric blocks are made with a cross-sectional area of 15 to 30 m ² . 13. The building structure according to claims 6-12, characterized in that at least at the part of the peripheral blocks the volumetric block has at least one side face that forms the inner wall of the building and at least one side face that forms part of the outer wall of the building. 14. The construction of the building according to claims 6-13, characterized in that it contains utilities arranged in a central volume unit. 15. The building structure according to claims 6-14, characterized in that it is made according to the technology selected from the group: prefabricated, precast-monolithic, monolithic, brick-monolithic, brick. 16. The building structure according to claims 6-15, characterized in that the overlap of the at least one volumetric block is made up of a main rectangular slab and two non-flange triangular slabs. 17. The building structure according to claims 6-16, characterized in that at least one side wall of the volumetric block comprises a support frame and a filling of the frame opening. 18. The building structure according to claims 6-17, characterized in that at least a part of the outer walls of the peripheral volumetric blocks is made with glass filling of the frame opening. 19. The construction of the building, containing the outer and inner walls and floors, forming interconnected volumetric blocks made in the form of regular hexagonal prisms. 20. The building structure according to claim 19, characterized in that it has in plan a honeycomb structure comprising at least one group of building blocks, including a central and six peripheral building blocks. 21. The building structure according to PP.19 and 20, characterized in that in the vertical plane the volumetric blocks are made coaxially, while in the coaxial central volumetric blocks a staircase-elevator unit is arranged and engineering communications are carried out. 22. The building structure according to claims 19-21, characterized in that the volumetric blocks are made with a cross-sectional area of 15 to 30 m ² . 23. The building structure according to claims 19-22, characterized in that at least at the part of the peripheral blocks the volumetric block has at least one side face that forms the inner wall of the building and at least one side face that forms part of the outer wall of the building . 24. The construction of the building according to claims 19-23, characterized in that it is made according to the technology selected from the group: prefabricated, precast-monolithic, monolithic, brick-monolithic, brick. 25. The building structure according to claims 19-24, characterized in that the overlap of at least one building block is made up of a composite rectangular main floor slab and two non-flange triangular floor slabs. 26. The building structure according to PP.19-25, characterized in that at least one side wall of the volume unit contains a support frame and filling the frame opening. 27. The building structure according to PP.19-26, characterized in that at least part of the outer walls of the peripheral volumetric blocks are made with glass filling the frame opening. 28. Volumetric block of a building structure containing side walls, characterized in that it is made in the form of a regular hexagonal prism. 29. The volume unit according to claim 28, characterized in that it is a structure selected from the group: prefabricated, precast-monolithic, monolithic, brick-monolithic, brick. 30. Volumetric block according to paragraphs 28 and 29, characterized in that part of the side walls are made as the outer walls of the building, and part - the inner walls of the building. 31. The volume unit according to claims 28-30, characterized in that it comprises an overlap consisting of a main rectangular and two non-flange triangular floor slabs. 32. Volumetric block according to claims 28-31, characterized in that at least one side wall comprises a support frame and a filling of the frame opening. 33. The volume unit according to claims 28-32, characterized in that it has glass filling.