RU2462569C2 - Architectural construction system of bulk modules to erect buildings - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: system comprises bulk modules arranged in plan as quadrangles. A quadrangle is symmetrical relative to a larger diagonal. Angles making tops, through which a larger diagonal stretches, are equal to accordingly 120° and 60°. Angles making tops, through which a smaller diagonal stretches, are equal to 90°. Modules are placed to form a square as a planning figure. The outer wall of the building is formed by walls of modules crossing at the right angles. Each module contacts in the inner space of the building with its walls with two adjacent modules. The long side of the module contacts with the short side of one adjacent module, and its short side contacts with the long side of the second adjacent module. Modules are installed to form an inner core, which is square in plan. The bulk module slab is supported with vertical supports. A grid, along which vertical supports are placed, is orthogonal within its sections separated with a long diagonal. Extreme rows of grids in these sections are parallel to module walls.

EFFECT: invention provides for simplicity of use, wide spectrum of application and high mobility.

3 cl, 6 dwg

Description

The invention relates to the construction, in particular of residential and social buildings, from prefabricated building blocks.

A polygonal architectural system is known, consisting of volumetric prismatic modules, the power frames of which are made in the form of trapezes, joined to each other during the building layout in such a way that some of their bases form a closed circular space inside the building, and others - external walls ( SU No. 524897, CL E04H 1/00, 1976).

The described structural solutions have a number of drawbacks: when developing their architectural and planning solutions, the combination of spatial forms that give a new quality is not used - the power frames of prismatic volume modules when they are combined into a building are not taken into account as pile grillages, which leads to a more complicated and expensive construction of foundations for such houses. The use of traditional layout forms of a building and structures justified for brick walls, self-supporting reinforced concrete panels, concrete blocks brings with it many old drawbacks: inefficient use of materials, building spaces, underloaded structural elements, corridors unnecessary for housing.

Also known is the architectural and construction system of volumetric modules for the construction of buildings, including volumetric modules made in plan in the form of quadrangles, some side walls of which form the inner enclosed space of the building, while others form its external sides (RU No. 2107137, Е04Н 1/00, 1996).

The well-known architectural and construction system of three-dimensional modules for the construction of buildings relates mainly to low-rise construction, while it does not fit well into the relief. In addition, it does not have a ready-made system of pedestrian and transport communications, does not scale, is not intended to include various functions in it, and does not have the possibility of vertical growth.

The task to which the proposed technical solution is directed is to expand the functionality of the device both in the field of low-rise and high-rise construction.

The technical result achieved is that ease of use is ensured: it is possible to develop a spatial solution of a building on the basis of ready-made modules in a short time; a wide range of system applications: from low-rise to high-rise buildings, from residential to industrial; scalability of modules (module dimensions, floor height, step of vertical supports are specified, or the proposed options are used); free planning, with the possibility of choosing a structural system, from the frame system to structural plates; high mobility of the system: it is possible to change the plan of the system, consistent growth of the system, change in the internal structure; universality, modularity of sizes; saving of territory (it is possible to install exploitable roofs with car passages and parking lots that do not require additional sections for these purposes); glazed passages or open streets for pedestrians or vehicles are laid down in the module plan; adaptability to terrain; focus on nature conservation (exploited roofs with vegetative cover on them instead of those destroyed under the building).

The problem is solved in that the architectural and construction system of volumetric modules for the erection of buildings, including volumetric modules made in plan in the form of quadrangles, some side walls of which form the inner enclosed space of the building, while others form its outer sides, differs in that in volume the module is given in plan the shape of a quadrangle symmetrical with respect to the larger diagonal, while the angles that make up the vertices through which the large diagonal passes are equal to 120 and 60 °, respectively the angles that make up the vertices through which the smaller diagonal passes are equal to 90 °, and when using a square as a planning figure, the external wall of the building is formed by the walls of the modules intersecting at right angles, and each module contacts its walls with two adjacent modules in the interior of the building so so that its long side is in contact with the short side of one adjacent module, and its short side is in contact with the long side of the second neighboring module, while the modules are placed with the formation of an internal square core in terms of the core, in addition, the grid along which the vertical supports are placed that support the overlap of the volume module is orthogonal within its sections separated by a long diagonal, while the extreme rows of grids of these sections are parallel to the walls of the module. In this case, the dimensions of the grid along which the vertical supports are placed that support the overlapping of the volume module are 6 × 6 m. In addition, at least one of the modules contains a communication zone in its volume, preferably occupying a part of its volume and formed as the space between the walls modules, making up an angle of 120 ° with each other, and the internal partition of the module located parallel to them, separating the functional area.

A comparison of the features of the claimed solution with the features of analogues and prototype indicates its compliance with the criterion of "novelty."

The features of the characterizing part of the claims solve the following functional tasks:

The signs "... the volumetric module is given in plan the shape of a quadrangle symmetrical with respect to the larger diagonal, while the angles that make up the vertices through which the large diagonal passes are equal to 120 and 60 °, and the angles that make up the vertices through which the smaller diagonal passes are 90 ° ... »Provide the ability to build from volume modules a wide range of planning figures.

Signs "... when using a square as a planning figure, the external wall of the building is formed by the walls of the modules intersecting at right angles, with each module in its interior contacting its walls with two adjacent modules so that its long side is in contact with the short side of one adjacent module, and its short side is in contact with the long side of the second neighboring module, while the modules are placed with the formation of the inner square in terms of the core ... "provide the layout of the volumetric modules of the square building plan, which includes the inner core of the building, which can be used as a passage corridor or atrium (multi-light space with insolation through the roof light), formed by the communication zones of 2 quadrangles modules and the core - see Fig 4), or an open courtyard.

The signs "... the grid along which the vertical supports are placed that support the overlapping of the volumetric module is orthogonal, within its sections separated by a long diagonal, while the extreme rows of grids of these sections are parallel to the walls of the module ..." simplify the design work of the building and ensure reliable roof support, in addition, the design of the building is simplified if there are several levels of module placement (several floors of the building).

The sign "... at least one of the modules contains a communication zone in its volume, preferably occupying a part of its volume and formed as a space between the walls of the module, which make an angle of 120 ° with each other, and the internal partition of the module parallel to them, separating the functional zone ... ”Makes it possible to combine the communication zones of neighboring modules for through movement through the internal space of the building and access to the functional areas of the building.

The features of the second claim make it possible to minimize the number of vertical supports (they provide sufficiently large sizes of areas free of vertical supports in the case of alternative structural solutions of overlapping, such as spatial frames).

The signs of the third paragraph of the claims provide a predetermined layout of the internal space of the modules and make it possible to form a communication zone (intended for organizing the flow of people and vehicles through the building) and a functional area (office, production area, residential premises, etc.) when using the modules to form a square plan of the building.

The invention is illustrated by drawings, where in Fig.1 - shows a General view of the module in plan; figure 2 shows a grid of vertical supports with a modular grid for the layout of vertical supports and the division of the module into zones; figure 3 shows a General view of the layout of the modules in a square-shaped building in plan; 4 shows a grid of vertical supports for the planning figure of a square with a modular grid for arranging vertical supports and dividing the module into zones; figure 5 shows a variant of the uneven division of the building into zones; figure 6 shows a scheme for testing the layout of the building shape on the planning grid.

The drawings show the first side walls 1, the second side walls 2, a large diagonal 3 passing through peaks 4 and 5, peaks 6 and 7 through which a smaller diagonal 8 passes, the location of the vertical supports 9, communication 10 and / or functional 11 zone , internal partitions 12, building 13 and its external sides 14, core 15.

The volume module is made in the form of a quadrangle with the first side walls 1 (short sides) and the second side walls 2 (long sides). The shape of the module in plan (see Fig. 1) is symmetrical with respect to the larger diagonal 3, while the angles that make up the vertices 4 and 5 through which the large diagonal 3 passes are equal to 120 and 60 °, respectively, and the angles that make up the vertices 6 and 7, through which passes a smaller diagonal of 8, equal to 90 °. Since the module plan is conditionally divided into two equal parts with respect to the larger diagonal 3 - rectangular triangles with legs 1, 2 and hypotenuse - the larger diagonal 3 of the quadrangle are formed in the plan. Both legs are divided into seven and four parts (see figure 2), respectively, for large 2 and small 1 leg. The exact ratio of legs is 1.73, used to build a figure in the plan. When dividing the legs into parts, a rounded value of 1.75 is used. When perpendiculars are laid off from each leg from the points obtained by dividing the legs into seven and four parts, a grid is formed orthogonal within its sections separated by a long diagonal 3. Eleven parts are postponed for 2 legs, each of which can be called a step module of vertical supports ( in the drawings, dots show the locations of the vertical supports 9). This parameter is variable and is set by the designer to achieve the required size of the quadrangle module. Thus, scalability of the modules of the quadrangle is achieved. The pitch module of the vertical supports will depend on the required step of the vertical supports. Examples of the standard pitch module of vertical supports: 6; 7.2; 8; 9 meters. Other sizes are possible.

The modules are configured to isolate in their volume a communication zone 10 and / or a functional zone 11, the first of which is formed by the first side walls 1 forming an angle of 120 ° and the internal partitions 12 parallel to them, cutting off the functional zone 11.

A spatial system of volume modules can be used to design buildings of a polygonal shape in plan from the same volume modules according to a system defined in the plan. In the process of building buildings in a known manner prepare the foundation of the structure.

When using the square as a planning figure (Fig. 3), the outer side 14 of the building 13 is formed by the walls of the modules intersecting at right angles, with each module in its interior contacting its walls with two adjacent modules so that its long side (second side walls 2) is in contact with the short side (first side walls 1) of one adjacent module, and its short side is in contact with the long side of the second neighboring module, while the modules are placed with the formation square in the plan of the core 15. The grid along which the vertical supports 9 are located, supporting the overlap of the volume module, is orthogonal within its sections separated by a long diagonal 3, while the extreme rows of grids of these sections are parallel to the walls of the module. The dimensions of the grid on which the vertical supports 9 are placed that support the overlap of the volume module are 6 × 6 m. (This parameter is variable and is set by the designer to achieve the required size of the quad module.) When combining the step module of the vertical supports 9, each side of the quad module will correspond to the step module of the vertical supports of either side of the other quadrangular module with the same dimensions of both quadrangles. When combining the modules in terms of communication zones 10 of the adjacent modules can be joined by the ends. The dimensions of the communication zone (width, length) can be different and are set by the designer. Figure 5 shows a variant of the uneven division of the building into zones. However, the allocation of a communication zone is not necessary.

The modules are arranged vertically by stacking them on top of each other. Requirement - the vertical supports of 9 overlying levels (floors) must be arranged accordingly to the axes of the underlying levels in order to optimize the structural system. However, other options are possible.

When working out the layout of a building with a rather complex shape, a modular grid is used (see Fig. 6), which is the projection of the walls of the module onto the building area, provided that the building consists of 13 building modules (architectural volume), the shape of which is represented by a square (see Fig. 3) when the projections of the external walls 14 of one architectural volume are simultaneously the projections of the external walls of other architectural volumes in contact with them. In this case, it is immediately possible to determine the required number of modules.

Claims (3)

1. An architectural and construction system of volumetric modules for the construction of buildings, including volumetric modules made in plan in the form of quadrangles, some side walls of which form the internal enclosed space of the building, while others form its external sides, characterized in that the volumetric module is given in plan the shape of a quadrangle symmetrical with respect to the larger diagonal, with the angles making up the vertices through which the large diagonal passing being equal to 120 and 60 °, respectively, and the angles making up the vertices through which pass a smaller diagonal, equal to 90 °, and when using a square as a planning figure, the outer wall of the building is formed by the walls of the modules intersecting at right angles, each module contacting its walls with two adjacent modules in the interior of the building so that its long side contacts with the short side of one adjacent module, and its short side is in contact with the long side of the second neighboring module, while the modules are placed with the formation of the inner square which is different in terms of the core, in addition, the grid along which the vertical supports are placed that support the overlap of the volume module is orthogonal within its sections separated by a long diagonal, while the extreme rows of grids of these sections are parallel to the walls of the module. 2. The architectural and construction system of volumetric modules according to claim 1, characterized in that the dimensions of the grid along which the vertical supports are placed supporting the overlap of the volumetric module are 6 × 6 m. 3. The architectural and construction system of volumetric modules according to claim 1, characterized in that at least one of the modules contains in its volume a communication zone, preferably occupying a part of its volume and formed as a space between the walls of the module constituting each other angle 120 °, and parallel to it the internal partition of the module, separating the functional area.

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