RU2215103C1 - Multistory building - Google Patents

Abstract

FIELD: civil engineering, multistory residential and public buildings built with bearing crosswalls, in particular. SUBSTANCE: multistory building includes spatial system formed by internal and external bearing crosswalls with side vertical ribs on which non-split prefabricated-monolithic or monolithic discs of ceilings are leant. Ceilings are fitted with longitudinal reinforced concrete bars with through longitudinal fittings along their plane, over whole length of building and anchored in external lateral bearing walls or their ribs. Lateral monolithic reinforced concrete bars with through coupling fittings anchored in longitudinal side reinforced concrete bars are placed above middle bearing lateral walls in discs of ceilings over entire width of building. Longitudinal external walls are leant story-by-story over layer of mortar against discs of ceilings and above point of linking with upper ceiling are fitted with springy gasket. Partitions on each story are leant against ceilings on each story. EFFECT: reduced usage of materials and consumption of energy for erection of building. 4 cl, 12 dwg

Description

 The invention relates to civil engineering, in particular to multi-story residential and public buildings, performed with transverse load-bearing walls.

 Known multi-storey building with load-bearing external walls and ceilings in the form of box slabs, belts (shelves) which form the floors of floors, and the ribs - the inner transverse walls [1]. A distinctive feature of the building is that beams-walls are embedded in the supporting external walls at the levels of each floor at the ends, and their walls form the internal load-bearing wall of the building, and the shelves of these beam-walls form adjoining and rigidly attached to the wall parts of the lower and upper floors . The length in such an I-beam beam-wall with the required pitch placed transverse short consoles also in the form of beam-walls. When each beam-wall is placed in the building system, a cellular monolith is formed. The well-known multi-story building is characterized by high load-bearing capacity, compactness and great potential for the beneficial use of its volume. However, the well-known building is characterized by a complex construction technology, determined by its supporting structure, has a narrow range of space-planning solutions, which allows it to be used only for regular planning structures inherent, for example, to garages, hotels, and to the least extent suitable for housing .

 A multi-storey building is known, including at least two buildings, interconnected by staircase and elevator structures. In each body of the ceiling in the form of reinforced concrete monolithic or precast monolithic disks, they are contour-supported on closed reinforced belts located in external load-bearing walls [2]. Supporting floors can be carried out on internal load-bearing walls. The well-known multi-storey building is characterized by reduced labor costs for its construction and installation; when using it, a reduction in material consumption can be achieved, especially when the building height is up to 5-6 floors.

 At the same time, a variety of architectural and planning solutions is not provided in a well-known building, since the layout of a building can only be block (of several buildings). In addition, with an increase in the height of the building, a significant difference in deformations appears in the differently loaded internal and external walls. In combination with temperature movements, this leads to the formation of large cracks in the junction of the inner walls with the outer ones, reduces the operational reliability and durability of buildings.

 Closest to the proposed is a multi-storey building, including load-bearing transverse walls made of a width equal to the width of the building with vertical stiffeners and external insulation of the external transverse walls, longitudinal walls and floor slabs [3]. In a well-known building, a substantial reduction in construction and installation costs is most fully ensured, and planning possibilities are revealed to a certain extent.

 However, in the well-known technical solution due to the use of panel structures, the architectural and artistic appearance of the building is repeated many times, which leads to uniformity of development. In addition, the famous building is characterized by a sufficiently high resource consumption for its construction. The use of prefabricated structures requires a significant consumption of metal for embedded parts; there is a need for a large amount of welded work. The lack of redistribution of load between prefabricated structural elements causes increased material consumption and mass of the building.

 The invention solves the problem of reducing material consumption and energy consumption for the construction of the building, ensuring the versatility of the building for any space-planning decisions.

 The solution of this problem is achieved by the fact that in a multi-storey building, including supporting transverse walls along its entire width with vertical stiffeners located at the lateral ends of the transverse walls and with external insulation of the external transverse walls, as well as longitudinal walls and floor slabs, overlaps are combined into flat through for the entire length and width of the building, the disks are equipped in their plane along the lateral sides with longitudinal reinforced concrete bars with through-length reinforcing bars for the entire length of the building, anchored at the ends in external transverse load-bearing walls or in their vertical lateral ribs, above the average load-bearing transverse walls in the floor disks for the entire width of the building there are transverse monolithic reinforced concrete beams with through-link reinforcement, anchored by the ends in the longitudinal side reinforced concrete beams, the average transverse load-bearing walls are made discrete with discontinuities along their length, the vertical stiffeners of the external transverse load-bearing walls are made through across the entire height of the building and provided through their edges with a through vert Kalnoy working reinforcement and the longitudinal outer walls are supported on a floor by floor layer solution on wheels overlaps on top and at the interface with the upper ceiling provided with an elastic gasket.

 In this case, the longitudinal side and transverse reinforced concrete beams of each floor disk can be made integral with the floor slab from monolithic reinforced concrete, and the floor disks are rigidly combined with transverse load-bearing walls.

 Overlapping disks can also be formed by prefabricated slabs of continuous cross-section, interconnected between the sides by inter-plate seams, and by the ends of the plates are combined in supporting nodes by means of reinforcing outlets from their ends and transverse monolithic reinforced concrete beams placed in concrete over transverse load-bearing walls.

 The overlapping disk can also be formed by prefabricated multi-hollow plates with open cavities at the ends, in which concrete keys of a monolithic reinforced concrete beam are placed, made over each transverse load-bearing wall, and flat reinforcing cages with upper working reinforcement are placed in the inter-plate seams at the ends of the multi-hollow plates across the beam.

 The external transverse load-bearing walls can also be made discrete with gaps in the plan, provided with vertical stiffeners of the angular profile at the corners of the building, and in the gap between the corner ribs they are made floor-by-floor, taking loads in these places only within one floor.

 The combination of slabs of each floor into flat disks, continuous through the entire length and width of the building, equipped with longitudinal reinforced concrete beams along the sides with longitudinal reinforcement through the entire length of the building, anchored at the ends in the external transverse load-bearing walls or in their vertical side ribs, allows to realize overlapping (1) continuous system with great opportunities for the redistribution of forces under load between adjacent spans. In addition, (2) in each span of overlap between adjacent transverse walls, the bearing of a flat floor slab as a plate supported along the contour (on transverse load-bearing walls and on lateral longitudinal through bars). Moreover, (3) this plate in each span between the transverse load-bearing walls under load also works under conditions of biaxial expansion. As a result of the implementation of these three conditions, the value of the calculated forces in the cross-sections of the floor is reduced, which allows, in comparison with analogues and prototype [3], to significantly reduce the material consumption of floors and the metal consumption for their reinforcement.

 This type of overlapping, combined with the placement of transverse beams over intermediate transverse load-bearing walls with through-link reinforcement anchored with ends in the longitudinal side reinforced concrete beams, allows not only effective spacing, but also transverse load-bearing walls to be discrete in plan, freeing up space in the resulting gaps to ensure a free layout of the premises.

 The implementation of vertical stiffeners of the external transverse walls through the entire height of the building with through vertical reinforcement located along the edges of the stiffeners allows you to create buttresses hidden in the outer walls of the building, capable of absorbing the spacer forces transmitted by the ceilings equally along the height of the building. And in combination with lateral longitudinal beams with through longitudinal reinforcement as part of the floor disks, they provide a complete perception of all longitudinal spacer forces arising from the bending of the floor. In this case, the supporting system of the house is a single effective spatial spacer structure with an internally perceived strife. In this case, through the connecting reinforcement placed in the ceiling above the transverse load-bearing walls perceives the transverse direction of the building.

 The implementation of longitudinal load-bearing walls floor-by-floor supported on a solution layer on the floor disks and the device for interfacing the walls of each floor on top with the upper floor by placing an elastic gasket on the contact can significantly reduce the forces acting in the wall, eliminate contact stresses at the point of support of the wall on the floors and ensure external tightness walls in places of its interfacing with floor disks. In general, this allows you to build a light energy-efficient outer wall with high and uniform thermal resistance with the widespread use of both low-strength local porous materials and lightweight building envelopes with effective insulation.

 The execution of longitudinal lateral and transverse reinforced concrete beams at the same time with a flooring disk made of monolithic reinforced concrete and the rigid combination of a flooring disk with transverse load-bearing walls makes it possible to create a rigid spatial structure in a single technological cycle that provides the most complete redistribution of forces from the action of the whole complex of vertical and horizontal loads, to the full extent by including in the work on the perception of these loads both floors and load-bearing walls, and thereby minimize the size s section of load-bearing structures and thus provide for the erection of the building a minimum consumption of the basic building materials.

 The implementation of floor disks with prefabricated floor slabs of a solid section provides a highly efficient rigid spatial load-bearing structure of the building using precast-monolithic reinforced concrete produced by homebuilding enterprises.

 The implementation of floor disks with prefabricated multi-hollow slabs with open cavities at their ends in combination with monolithic reinforced concrete beams over load-bearing walls, concrete dowels and flat reinforcing cages placed in inter-plate seams across load-bearing walls allows creating a highly effective rigid spatial load-bearing structure of the building using prefabricated monolithic reinforced concrete produced by enterprises of the construction industry.

 The implementation of the external transverse load-bearing walls discrete with gaps in plan, filled with a floor-supported energy-efficient masonry or a self-supporting multilayer enclosing structure, reduces the volume of external insulation of the external (end) transverse load-bearing walls, thereby increasing the operational reliability of the building walls, their thermal uniformity, and also due to reduce the volume of external insulation to reduce the cost of building walls.

In general, all the described features presented in the claims reflect the universal structural system of a multi-story building. All of the above signs, as follows from the above, determine the differences of the proposed multi-storey building from the known ones, make it possible to solve the problem posed in the present invention, and also to obtain a significant effect, expressed as:
- (1) in the reliability and versatility of the design solution, providing the expansion of architectural and planning capabilities;
- (2) to reduce the material and metal consumption of load-bearing structures, reduce labor and energy costs during construction;
- (3) in reducing operating costs by increasing operational reliability and durability.

 In general, the proposed technical solution meets the criterion of novelty, since the achieved technical results by the proposed solution are superior to the known ones, and the above-mentioned features of the proposed technical solution are not known in the above amount and provide an ultimately total result. This makes it possible to consider the proposed technical solution in accordance with the requirements of an inventive step.

 In FIG. 1 shows the supporting structural system (structure) of the proposed multi-storey building; figure 2 - the proposed building, a plan of flat floors made of precast-monolithic reinforced concrete; figure 3 is the same plan of the interfloor flat floor made of monolithic reinforced concrete; figure 4 is the same diagram of the spacer forces arising in the plane of the overlap from the effects of the vertical payload; figure 5 is the same, a diagram of the transmission of thrust to the transverse load-bearing walls and deformations, section AA in figure 4; figure 6 is the same, the design of the interface of the precast-monolithic overlap with transverse bearing walls, section aa - in figure 4; in FIG. 7 is the same as in FIG. 6, a view along BB; in Fig.8 is the same, the coupling of the longitudinal floor-supported wall with overlap, a section along BB - in Fig.7; in FIG. 9 - the proposed building, the node interface prefabricated-monolithic floors of hollow core slabs with transverse load-bearing walls (plan); figure 10 is the same as in figure 9, a section along G-G; 11 - the proposed building, a plan for the placement of transverse bearing and longitudinal floor-supported walls.

 The proposed multi-storey building (Fig. 1 ... 11) includes a spatial supporting system (Fig. 1) formed by internal 1 and external 2 with lateral vertical ribs 3 transverse load-bearing walls, on which the floor disks are supported 4. Transverse load-bearing walls 1 can be and walls 5 of the staircase and elevator unit. The floor disks 4 can be made with consoles 6, taken out of the outline of the transverse load-bearing walls 1, 2, for placing balconies, bay windows, loggias, etc., of architectural details.

 The floor disks 4 may be formed by prefabricated reinforced concrete or cellular concrete slabs 7 of a continuous section or multi-hollow plates 8 (Fig. 2). In any case, groups of plates 7, 8, placed between the transverse load-bearing walls, are provided along the building with lateral longitudinal reinforced concrete beams 9 with through longitudinal reinforcement 10, anchored at the ends in the outer transverse load-bearing walls 2 or in their ribs 3. In the extreme spans between the outer 2 and the nearest inner 1 transverse load-bearing walls in the middle of the cell along the plates 7, 8 place an additional monolithic reinforced concrete tightening 11, the through longitudinal reinforcement 12 of which should be anchored in the transverse monolithic bars 13. The through longitudinal reinforcement 14 of the transverse beams 13 should, in turn, be anchored at the ends in the concrete of the lateral longitudinal monolithic reinforced concrete beams. In the case of a wide-building, when its width is two or more times the size of the largest step of the transverse walls, a monolithic reinforced concrete puff 11 can be made through the entire length of the ceiling 4 of the building.

 When overlapping from monolithic reinforced concrete (Fig. 3), the overlapping disk 4 is made integral with the longitudinal side bars containing the working through reinforcement 10 and the transverse bars over the transverse load-bearing walls 1, 2 containing the through reinforcement 14. The overlapping disk is filled in each span with using the lower reinforcing mesh 15. For the removal of floor disks in order to place balconies, bay windows, consoles 6 can be arranged, the working reinforcement of which is performed on the continuation of monolithic beams 9, 11, 14 or in plate 4 ozhet be placed additional working valves 16 capable of as a part of the plate section of the stress applied to this console.

 The inner 1 and outer 2 transverse load-bearing walls can be made of monolithic or precast concrete, of sufficiently strong masonry using vibro-pressed concrete blocks, high-strength ceramic or silicate bricks. Hidden monolithic reinforced concrete racks using masonry as fixed formwork can be carried out in the bearing walls. With a building height of up to 5 floors, these walls can be made of aerated concrete masonry with ceilings with aerated concrete slabs. The outer longitudinal walls 17 are performed by floor-mounted single-layer or multi-layer with external insulation on the facade.

 The stiffeners 3 of the external transverse load-bearing walls 2 are equipped with fittings 18 through the entire height of the building, which ensure that the ribs work in a bend in the vertical plane and create a spacer H in the ceiling. Outside, the bearing walls 2 are provided with a layer of insulation 19 and a lining of the outer surface of the wall (not indicated), which ensures joining along the facades of the bearing walls 2, ribs 3 with floor-mounted outer longitudinal walls 17.

 Prefabricated plates 7, 8 can be coupled at the ends with the supporting walls 1 and 2 by means of reinforcing outlets 20 from the ends of the plates 7, 8 and the transverse monolithic beams placed in concrete 13. The extreme plates 7, 8 are adjacent with their outer side to the longitudinal through beam 9, and in general, the overlap is connected in this place with the floor-supported wall 17 from below by means of an elastic gasket 21, which is made of the same insulation as the additional heat-insulating layer 22, which is placed in the wall 17 from the outside of the beam 9. Additional layer 22 of the heat insulation The cation is equipped with a facing layer 23 along the facade of the building. Between them, prefabricated plates 7, 8 on the sides are joined by interplate seams 24. Reinforcing outlets 20 from the ends of the plates 7, 8 may not be arranged, but in this case in the interplate seams 24 across the load-bearing walls 1, 2 are placed flat reinforcing bars frames 25 with transverse and upper working reinforcement (not indicated).

 The outer bearing walls 2 can be made discrete with gaps in the plan (Fig. 11, 12), and the vertical stiffening ribs can be made of a corner profile 26 with external insulation 19 and placing them at the corners of the building. In the breaks of the bearing walls 2, floor-supported walls 17 can be placed at the ends of the building between the corner stiffeners 26. In general, in the proposed multi-storey building, the load-bearing system is represented by transverse load-bearing walls 1, 2 with discrete breaks in plan and flat disks of 4 floors. The outer walls 17 and partitions (not shown) are floor-supported. In general, this provides universal and fairly free space-planning solutions.

 In the proposed multi-storey building, all the loads and power influences applied to it are perceived by the supporting skeleton, the external floor-supported walls perceive the forces and influences applied to them within only one floor and provide the most effective thermal protection.

 The proposed multi-storey building is being erected in the following sequence. Transverse load-bearing walls 1,2 are arranged on the basement floor or on the erected floor, the outlets of the through reinforcement 18 of the vertical reinforcing ribs 3 are increased. At the same time, support mounting and technological equipment with the required formwork is placed under the erected ceiling, longitudinal floor-supported walls are erected 17. Then, on the mounting the technological equipment is installed on the floor disk so that the top of the floor-supported walls serves as the formwork of the lateral edges of the floors or longitudinal monolithic beams 9, the transverse beams 13 concrete iruyut directly above the top transverse bearing walls 1, 2. After a set of monolithic concrete slab is large enough strength required, installation tooling is removed from the finished slab and at its top is moved for the erection of the next floor, and the cycle is repeated until the roof of a building unit.

 In general, the proposed multi-storey building, due to the features discussed above, is distinguished by the most perfect design, is universal and allows the fullest possible use of the local production base, and can be built using a wide and diverse range of building materials and products. In combination with low material consumption, this can significantly reduce the cost of construction.

 The proposed technical solution will be mastered during the construction of mass housing buildings up to 9-10 floors high.

Sources of information
1. Patent of the Russian Federation 2121548. Multi-storey building - a cell monolith. IPC ⁶ E 04 B 1 / 16.1 / 20, 1/348, BI 31.1998.

2. USSR copyright certificate 1735547. High-rise building. IPC ⁵ E 04 H 1/00, BI 19, 1992. Publ. 05/23/92.

3. USSR author's certificate 1514885. Multi-storey large-panel building. MKI ⁴ E 04 1/02, BI 38, 1989. Publ. 10/15/89 (prototype).

Claims (5)

 1. A multi-storey building, including supporting transverse walls along its entire width with vertical stiffeners located at the lateral ends of the transverse walls and with external insulation of the external transverse walls, longitudinal walls and floor slabs, characterized in that the slabs of each floor are combined into flat through for the entire the length and width of the building, the disks are equipped in their plane along the lateral sides with longitudinal reinforced concrete beams with through-length reinforcement throughout the length of the building and anchored at the ends in the outer transverse load-bearing walls or in their vertical side ribs, above the average load-bearing transverse walls in the floor slabs across the entire width of the building, there are transverse monolithic reinforced concrete beams with through-link reinforcement, anchored by the ends in the longitudinal side reinforced concrete beams, the middle transverse load-bearing walls are made discrete with breaks in plan, the vertical stiffeners of the external transverse walls are made through throughout the height of the building and are equipped with through vertical working fittings along their edges, and longitudinal the external walls are made floor-by-stage supported along the mortar layer on the floor disks and on top at the interface with the upper floor are equipped with an elastic gasket.  2. The multi-storey building according to claim 1, characterized in that the longitudinal side and transverse reinforced concrete bars of each floor disk are made integral with the floor slab from monolithic reinforced concrete and the floor disks are combined with transverse load-bearing walls.  3. The multi-storey building according to claim 1, characterized in that the floor disks are formed by prefabricated solid section slabs interconnected at the sides by plate joints, and at the ends of the slabs they are joined in supporting nodes by means of reinforcing outlets from their ends and transverse monolithic placed in concrete reinforced concrete beams made over transverse load-bearing walls.  4. The multi-storey building according to claim 1, characterized in that the floor disks are formed by prefabricated multi-hollow plates with open cavities at the ends, in which concrete dowels of a monolithic reinforced concrete beam are placed, made over each transverse load-bearing wall, and across the inter-plate seams at the ends of the multi-hollow plates each transverse beam placed flat reinforcing cages with upper working reinforcement.  5. High-rise building according to any one of paragraphs. 1-4, characterized in that the outer transverse load-bearing walls are made discrete with gaps in the plan, are provided with vertical stiffeners of the angular profile at the corners of the building, and floor-filled their filling was performed in the gap between the corner stiffeners.

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