RU2129195C1 - Butt joint for components of multiple span sectional building - Google Patents

Abstract

FIELD: construction engineering. SUBSTANCE: butt joint incorporates external reinforced concrete ribbed wall panels, columns, span-pieces, and covering slabs. Wall panels are provided with supporting members for resting of covering slabs so that their surface is located in common horizontal plane with upper end face of wall panel. Construction posts of garret storey are resting on upper end faces of wall panels. Covering slabs are supported by split column or by supporting components arranged on side faces of span-pieces. Span-pieces are of width which is equal to thickness of column. Span-pieces are positioned in common horizontal plane with covering slabs. EFFECT: higher efficiency. 2 cl, 6 dwg

Description

 The invention relates to the field of construction and can be used in the construction of multi-storey multi-span buildings, including with an attic floor.

 Known for the construction of multi-storey buildings, made in the form of columns connected by crossbars, on which floor slabs are laid. The columns located on the periphery of the building are double, and the crossbars are mounted on columns in pairs and cover ordinary columns on both sides (1).

 Also known is the platform joint of floor slabs and frame supporting elements of the frame of a multi-storey multi-span building. The joint includes the upper crossbar of the underlying frame element, the floor slabs supported on it and connected to them, and the lower crossbar of the overlying frame element mounted on the floor slabs and connected to them. The crossbar of the overlying frame element is installed in the grooves of adjacent floor slabs. The connection of the crossbars of frame elements with plates can be carried out in a known manner, for example, in welding, followed by concrete coating (2).

 Both described analogs reduce the useful volume of the building.

 Another known butt connection of the crossbar to the column includes embedded plates located in the lower zone of the joint installed on the side surface of the crossbar, embedded parts of the column and overlays connecting both embedded elements in welding. In the upper zone of the crossbar, releases of the supporting reinforcement are made, connected to the releases of the reinforcement embedded in the column (3). This design provides a limited private solution for supporting the crossbar on the column and does not provide a solution for connecting the floor slabs to the column or supporting the floor slabs on a non-bearing prefabricated wall, or supporting the supporting structures of the overlying floor on this wall.

 The closest analogue adopted for the prototype of the claimed invention is the design of a quick-assembly multi-span building in which the interface of the wall panel with the coating plate is placed in one plane: the upper plane of the coating is at the same level with the upper face of the wall panel. In this case, the coating plate is supported on special metal tables, anchored in the ribs of the wall panel (4).

 The disadvantage of this constructive solution is the limited height of the building to the height of the ribbed outer wall panel and, as a result, the unresolved nodes of the supporting structures of the overlying floor on this panel; in addition, the prototype provides for the use of columns with a height of one floor or a height of the entire building, which leads to the expansion of the range of products used.

 The objective of the proposed utility model is to increase the area of the building and the number of floors and simplify the installation technology of its constituent structures.

 This problem is solved in that the butt joint of the elements of a prefabricated multi-span building includes an external ribbed reinforced concrete panel of vertical cut, supporting elements, columns and slabs supported on the outer ribbed reinforced concrete panel in the same horizontal plane with its upper end. The supporting elements are mounted on the wall of the outer ribbed panel at a distance from the upper end of the panel, equal to the thickness of the floor slab. The floor slab is supported at one end on these support elements. Its upper plane is combined with the end face of the ribbed wall panel with a supporting embedded part. The second end of the floor slab rests on columns or crossbars mounted between columns. The overlying floor has load-bearing structures, the supporting part of which is installed above the floor slab of the underlying floor, is located above the vertical edges of the outer panel and is rigidly connected with the supporting embedded part in the zone of its adjacency to the end of the outer ribbed panel. Adjacent floor slabs are supported by one of their corners on the column head, and on top of these corners there is an overlying column placed coaxially with the lower column and connected to it by vertical reinforcing bars. The rods are passed in the gaps between the floor slabs and are welded to embedded parts mounted at the ends of both columns. The gaps between the slabs and columns are monolithic. In addition, the crossbars mounted between the columns can have a width equal to the thickness of the column face associated with the crossbar, and can be supported by supporting elements located on the columns. Supporting elements are also installed on the lateral faces of the crossbars, on which floor slabs are laid with their free ends. The upper surfaces of the floor slabs and the upper edges of the crossbars are located in the same horizontal plane, and the gaps between them are concreted.

 A comparative analysis of the claimed invention with the prototype shows that it differs by the location of the supporting elements on the outer ribbed panel depending on the thickness of the floor slab, by leaning one end of the floor slab on this element with the union of its upper plane with the end of the ribbed wall panel by the supporting embedded part on which supporting structures of an overlying floor located above the vertical ribs of the outer wall panel and rigidly connected with the supporting embedded part.

 The difference also lies in the fact that adjacent ceilings are supported by one of their corners on the column head, and an overlying column is installed on top of these corners, placed coaxially with the lower column and connected to it by vertical reinforcing bars passed in the gaps between the floor slabs and welded to the mortgages parts mounted at the ends of both columns, and the gaps between the plates and columns are monolithic. In addition, the embodiment of the junction of the floor slabs of the crossbars and columns differs in the width of the crossbar equal to the thickness of the face of the columns conjugated with it, as well as the support of the floor slabs on the supporting elements located on the side faces of the crossbars and the location of the upper surface of the floor slabs and the upper faces of the crossbars in one horizontal plane . This analysis allows us to conclude that there is novelty in the proposed technical solution.

 Comparison of the claimed butt joints with other known technical solutions shows that the presence of a supporting embedded part that combines the end face of the outer ribbed wall panel and the upper surface of the floor panel located in the same end face of the horizontal plane makes it possible to build buildings, for example, due to the attic floor. The location of the supporting part of the supporting structures of the building superstructure above the vertical ribs of the outer wall panel makes it possible to transfer the load from the superstructure to the wall panel in the best possible way. Variants of supporting floor slabs on columns and on the outer ribbed wall can avoid the use of parapet panels. The use of a column that is split in height when the overlying column rests on a joint of adjacent floor slabs, is installed coaxially with the column of the underlying floor and connected to it by welding using reinforcing bars passed through the gaps between the floor slabs, it allows to simplify the structural layout of the building and expand its vertical layout .

 The use of crossbars located between the columns and having a width equal to the thickness of the column face connected to the crossbar, installing support elements on their lateral faces and installing floor slabs on them with the upper faces of the crossbars and the upper surfaces of the pit floors in the same horizontal plane allows to increase "in light "the height of the room and slightly increase the area of the building. In addition, the proposed technical solutions make it possible, firstly, to increase the useful area of the building due to the installation of the attic floor and, secondly, to mount this attic floor on existing structures without reinforcing them and without any fundamental processing. Thus, the claimed invention gives, with the totality of its features, a previously unknown technical effect that exceeds the state of the art.

 The invention is illustrated by the example of its implementation.

The drawings show:
in FIG. 1 is a fragment of a building plan with a variant of uncut columns;
in FIG. 2 - the same, in the embodiment of the platform joint of split columns;
in FIG. 3 - a longitudinal section of the building;
in FIG. 4 - node support rafter racks of the attic on the ribbed outer panel of the building, node A;
in FIG. 5 - the same, view BB;
in FIG. 6 - node supporting floor slabs on the column in the form of continuous columns, node B (rotated);
in FIG. 7 - the node supporting the floor slabs on the column in the variant of the platform joint when the column is cut, node G (rotated), the fourth floor slab conditionally not shown.

 A multi-storey multi-span prefabricated building is mounted from external ribbed reinforced concrete panels 1 of vertical cross-section, on which floor slabs are installed 2. For this, embedded parts 4 are mounted on a flat surface of 3 ribbed panels, to which the supporting elements are welded 5. In the upper part of the ribbed panel, the supporting elements are placed so that the upper surface 6 of the floor slab 2 is located in the same horizontal plane with the end face 7 of the ribbed panel. Embedded parts 4 and support elements 5 are mounted on the wall of the outer ribbed panel at a distance "h" from the upper end of the panel, equal to the thickness "h" of the floor slab. The edge 8 of the floor slab is connected to the support table at welding 9, and the upper surface of the floor slab and the end face of the ribbed panel are joined by the support plate 10, also installed on the weld: in this way, a rigid junction of the ribbed wall panel and the coating plate capable of receiving and transmitting is formed bending moment arising during the construction. The second end 11 of the floor slab in the platform joint variant is supported by a plate 14. The side faces of the lower floor column and the upper floor column 15 are provided with embedded parts 16 to which the vertical reinforcing bars 17 are welded into the columns when they are assembled into the columns. the gaps 18 between the floor slabs. Between each other floor slabs are connected using steel plates 19 for welding. The lower part of the column 15 of the upper floor is supported through pouring with fine-grained concrete 20 to the area where the ribs of four adjacent floor slabs are joined, which absorb the load from the structures of the overlying floor and transfer it to the lower columns 13. On the lower column, supporting elements 21 are welded to the embedded parts 16, on which the crossbar 22 is located, located between the columns. On these crossbars, slabs 2 of the overlap in the gap between the columns are supported. All joints between columns and floor slabs and between the upper and lower columns are monolithic with concrete 23.

 In the described embodiment, the joining of columns, floor slabs and crossbars, floor slabs are located above the region, which somewhat reduces the height of the room "in the light", but the junction of the columns is simplified.

 In the second embodiment, the column 24 is made continuous in height.

 At the level of overlap, the column is covered by a steel sleeve 25, anchored in the body of the column. Support tables 26 and 27 are welded to the clip; on table 26, slabs 2 are supported, on tables 27 - crossbar 28 located between the columns. The width of the crossbars is equal to the thickness of the face 29 of the column at the junction of the end of the crossbar. Supporting elements 31 are supported on the lateral faces 30 of the crossbar, on which the free angles 32 of the floor slabs 2 are supported. The upper edges of the crossbar and the floor slabs at the joints are joined by steel plates 33 welded to the embedded parts 34. The supporting elements 26, 27 and 31 are thus positioned that the upper face 35 of the crossbar and the upper surfaces of the floor slabs 2 are after their installation in one horizontal plane. The gaps 36 between the columns, crossbars and floor slabs are filled with monolithic concrete.

 The rafters of the attic floor 37 are located above the vertical ribs of the reinforced concrete panels 1 and are rigidly fixed to the horizontal support plates 10 mounted on the upper end faces 7 of the ribbed reinforced concrete panels, the supporting part of the rafter stands located above the upper end face of the ribbed panels. The junction of the rafter stand 37 with the base plate 10 is concreted with monolithic concrete 38.

Sources of information:
1. Japan, application 63-40021 from 1982, MKI E 04 B 1/20.

 2. USSR, A.S. 1362797 from 1987 MKI E 04 B 1/38.

 3. USSR, A.S. 1652478 from 1991 MKI E 04 B 1/38.

 4. V.I. Lugansky et al. Article "Fast-mounted buildings of modular type for storage and processing of agricultural products", the magazine "Concrete and reinforced concrete", 1992, N 1, p. 2-5, p. 3.

Claims (3)

 1. A butt joint of elements of a prefabricated multi-span building, including an external ribbed reinforced concrete panel of vertical section, supporting elements, columns and slabs supported on a ribbed reinforced concrete panel in one horizontal plane with its upper end, characterized in that the supporting elements are mounted on the wall of the outer ribbed panels at a distance from the upper end of the panel, equal to the thickness of the floor slab supported at one end on these supporting elements with the union of its upper plane with the end face of the ribs a true wall panel with a supporting embedded part, and with a second end on columns or crossbars mounted between the columns, the overlying floor having load-bearing structures, the supporting part of which is installed above the floor slab of the overlying floor, is located above the vertical edges of the outer panel and is rigidly connected with the supporting embedded part in the zone of its adjacency to the end of the outer ribbed panel.  2. The compound according to claim 1, characterized in that the adjacent floor slabs are supported by one of their angles on the column head, and an overlying column is installed on top of these corners, placed coaxially with the lower column and connected to it by vertical reinforcing bars passed in the gaps between floor slabs and welded to embedded parts mounted at the ends of both columns, and the gaps between the plates and columns are monolithic.  3. The compound according to claim 1, characterized in that the crossbars mounted between the columns have a width equal to the thickness of the column face connected to the crossbar, and are supported on supporting elements located on the columns, and supporting elements mounted on their lateral edges the ends of the floor slabs, while the surfaces of the floor slabs and the upper edges of the crossbars are located in the same horizontal plane, and the gaps between them are concreted.

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