RU59088U1 - DESIGN OF THE METAL FRAME OF THE CONSTRUCTION VOLUME BLOCK FOR A SMALL BUILDING - Google Patents

Abstract

The proposed technical solution of the utility model relates to construction and can be used in the design of mobile blocks of collapsible type for low-rise buildings and attic superstructures. The invention relates to the construction of a load-bearing building block that is rectangular in plan, moreover, several such blocks can be placed next to each other or stacked on top of each other to build a building or superstructure. The technical result of the proposed solution is to create a rational design of the frame of volumetric blocks of increased factory readiness and transportability, reducing the metal consumption and the complexity of manufacturing the building. The technical result is achieved due to the fact that the racks of the outer walls of the frame are made of perforated bent profiles attached with their upper ends to the outer belts of the supporting horizontal trusses, which are located around the frame perimeter at the top of the columns and are attached to them, while the bearing elements of the floor section, columns and the outer truss belts are located inside the block, which eliminates the formation of “cold bridges”. The frame is made with the possibility of installing it in several tiers, for this the columns at the upper and lower ends are equipped with protruding plates, which, when bunked or more, are superimposed on each other and fastened together with bolts, ensuring the perception of all vertical loads. In the proposed design of the frame of the volume unit (except the block of the last floor) there is no ceiling section and its functions are performed by the floor section above the installed block. In this design, the spatial rigidity of the block without the ceiling section is provided by a horizontal truss located along the inner contour of the block and rigidly connected to the corner columns.

Description

The proposed technical solution of the utility model relates to construction and can be used in the design of mobile blocks of collapsible type for low-rise buildings and attic superstructures.

The invention relates to the construction of a load-bearing building block that is rectangular in plan, moreover, several such blocks can be placed next to each other or stacked on top of each other to build a building or superstructure.

Building blocks of the above-mentioned purpose are known, having supporting walls, bearing sections of the floor and ceiling and four corner columns connected to the supporting structures of the floor and ceiling (see GB 2040334, 1980, class E 04 B 1/348). The disadvantage of this invention is that the floor and ceiling sections having shaped metal beams are connected to the shaped metal columns of the wall section along its horizontal edges.

The closest prototype to the proposed design are factory-made box-shaped blocks (patent RU 2120003 class E 04 B 1/348).

The frames of the outer walls of these blocks are made of bent steel profiles of the channel and C-shaped section and with a heater within their height.

The disadvantage of these blocks is that the frame elements of the outer walls protrude on their outer surface, which can lead to the formation of "cold bridges" and require additional measures to eliminate them. Another disadvantage of the prototype design is that when the blocks are installed on top of each other in buildings with several floors, the floor floors consist of two layers, including the ceiling structure of the underlying unit and the floor structure of the overlying unit. This leads to increased metal consumption and the complexity of manufacturing a building.

A significant disadvantage of the known inventions is that the columns are connected to the supporting structures of the floor and ceiling sections by welding.

The objective of this technical solution is to create a rational design of blocks that eliminates the disadvantages inherent in the prototype and allows you to make blocks of high factory readiness and transportability.

The problem is solved in that the racks of the outer walls of the frame are made of perforated bent profiles attached by the upper ends to the outer

horizontal supporting trusses, which are located along the perimeter of the frame at the top of the columns and are attached to them, while the supporting sections of the floor section, columns and outer trusses are located inside the unit, which eliminates the formation of “cold bridges”.

The frame is made with the possibility of installing it in several tiers, for this the columns at the upper and lower ends are equipped with protruding plates, which, with a two-tier or more arrangement, are superimposed on each other and fastened together with bolts ensuring the perception of all vertical loads. In contrast to the well-known solutions of blocks for buildings in the proposed design of the frame of the volumetric block (except for the block of the last floor) there is no ceiling section and its functions are performed by the floor section above the installed block. In this design, the spatial rigidity of the block without the ceiling section is provided by a horizontal truss located along the inner contour of the block and rigidly connected to the corner columns.

In the wall sections between the racks installed diagonal coupling elements from a bent profile.

In the proposed design of the block, all connections of the frame elements are carried out on bolts or self-tapping screws.

All bent frame elements of the block are made of galvanized steel.

A building block with a frame of this design can be used in all types of buildings from homogeneous blocks, for example, for residential buildings, hotels, cottages, attics, etc. Blocks can be delivered to the construction site ready-made in full factory readiness or in the form of a frame with the subsequent implementation of internal and external cladding, insulation, communications after installation in place.

This block is described in more detail below with reference to the drawings.

Figure 1 is a perspective view of the structural diagram of the frame of the block.

Figure 2 is a top view of the frame of figure 1.

Figure 3 shows a section along the line 1-1 in figure 2

Figure 4 shows a section along the line 2-2 in figure 2.

5 shows a top view of a floor section.

6 shows a view of a section of a longitudinal wall.

Fig.7 shows a section along the line 3-3 in Fig.2.

As can be seen from figure 1, the frame of the building block in the form of a parallelepiped consists of four corner columns 1, lower beams 2 along the longitudinal sides of the frame connected to the columns, runs 3 sections of the floor, supported by longitudinal beams 2,

4 racks of end and longitudinal sections of walls with diagonal connections 5 and horizontal trusses 6 along the upper perimeter of the frame, interconnected and with columns. Each column 1 of a rectangular pipe has a protruding plate 7 at the upper end and a protruding base plate 8 at the lower end. The upper plates 7 and the base plates 8 are superimposed on each other when laying two building blocks in two tiers and are connected together using bolts. Thus, the columns absorb all the vertical loads acting on the building block.

The racks 4 of the outer walls are made of perforated bent profiles attached with their upper ends to the outer belts of the supporting horizontal trusses 6, which are located around the frame perimeter at the top of the columns and are attached to them, while the supporting elements of the floor section, columns and outer truss belts are located indoors block.

The floor sections above the installed unit at the same time function as the ceiling sections of the unit installed below.

The maximum dimensions of the building block: width - 3.7 m, length - 12 m, height - 3.0 m.

Figure 2 shows a horizontal truss 6 with belts parallel to the sides of the block and a triangular diagonal lattice, the elements of which are connected to the belts using self-tapping screws or combined rivets.

It is advisable to carry out trusses from thin-walled bent profiles of C-shaped and channel sections.

A truss 300-400 mm wide provides the spatial rigidity of the block frame along the upper contour. The outer truss belts are attached to the corner columns with bolts through the gusses welded to the columns. The inner belts of the longitudinal and transverse trusses are interconnected at the ends by bolts or self-tapping screws through gussets in the form of bent corners.

The outer belts of the horizontal trusses 6 are attached to the columns 1 using a flat gusset with bolt holes, which is welded to the face of the column in the factory, and when assembling the block, the outer truss belts are attached to it with the required number of bolts.

Longitudinal beams 2 are usually made of two branches facing the walls to each other. One of the branches (outer) is made of a bent profile of a C-shaped section, the other (inner) is made of a bent channel. Both branches are fastened at the ends to the column with bolts through a welded-in gusset.

Cross beams are made of a C-shaped bent profile, bolted to the ends to a gusset welded to the column.

Belts of longitudinal horizontal trusses are made of single bent channel elements of the channel section. The lattice elements are made from bent profiles of a C-shaped section, the ends of which enter between the shelves of the belts and are attached to them, forming non-shaped units.

The girders 3 of the bent profiles of the C-shaped section are supported by longitudinal beams 2, located between the shelves of their internal branch channel section, the girders are attached to the shelves of the channel channel with self-tapping screws or rivets.

Vertical racks 4 of the walls are made of zeta-shaped perforated profiles ("thermal profiles"), attached with one shelf at the top to the outer belt of the horizontal truss 6 and below to the outer branch of the beam 2.

The frame of the floor section consists of runs running parallel to the end beams with a step corresponding to the calculated span of the flooring from profiled steel sheets or boards. A crate of zeta-shaped “thermal profiles” is fastened to the lower shelves of the girders, according to which they are sheathed from waterproof materials, for example, bakelized plywood. Between the flooring and the outer skin, a heater is placed.

The frame of each section of the wall is designed in the form of a lattice structure of vertical posts fixed at the ends. The pitch of the racks depends on the size and strength of the facing materials.

Between the racks of the wall section are placed diagonal tie elements 5 from a bent profile of a C-shaped section, fixed at the ends to the horizontal elements 2 and 6. In the longitudinal section of the wall, diagonal elements 5 can be located within each step of the racks 4 and form a triangular lattice of the vertical truss, with belts which are the longitudinal beam 2 at the bottom and the belt of the horizontal truss 6 at the top. In this case, door or window openings are performed only on the end sections of the walls.

The building block is assembled as follows:

Corner columns 1 are plumbed at the factory stand and their lower plates are fixed with four bolts each on fixed supporting tables. The lower longitudinal and transverse beams around the frame perimeter are bolted to the gussets on the columns. Between the longitudinal beams, floor runs are installed and the flooring is laid. The outer belts of the horizontal trusses are bolted to the gussets on the columns 6. The grating and the inner belts are mounted element-wise

horizontal trusses with scaffolding installed on the flooring. After installing the angled gusses connecting the inner belts of the longitudinal and transverse trusses, the scaffolds are removed. Then mount the rack 4 and the diagonal connection 5 of the wall sections.

After assembling the frame of the block, its decoration and insulation are performed. On the profiled flooring you can lay a layer of light concrete. The inner lining is made of plasterboard sheets attached to the frame elements with self-tapping screws. The outer skin is made in the form of metal, plastic or wooden siding. (It is possible to make the outer lining of the block from gypsum or foam concrete panels).

In the blocks of the upper tiers, in the floor structure, instead of insulation, soundproofing material is laid within the height of the runs. The outer cladding in the floor structure in these blocks is made of two layers of drywall attached to the girders. In this case, the horizontal trusses in the lower tier blocks are lined with plasterboard sheets, on the surface facing the inside of the room.

The gaps between the units installed side by side are sealed in place using special strips.

Before transporting the finished unit to the construction site, it is advisable to equip it with windows, doors, a bathroom, a toilet, heating radiators, electrical wiring, flooring, etc. Due to this degree of completion, the installation of the block at the construction site can be carried out within an hour.

Claims (5)

1. The design of the metal frame of the building volumetric block for a low-rise building, moreover, several such blocks can be located next to each other and / or mounted on each other, including a vertical column of long products in each corner, bearing a section of the floor connected to the columns, and two pairs opposite wall sections, characterized in that the racks of the outer walls are made of perforated bent profiles attached with their upper ends to the outer zones of the supporting horizontal trusses, which are located around the perimeter the frame is at the top of the columns and attached to them, while the supporting elements of the floor section, columns and outer trusses are located inside the unit, the frame is made to be installed in several tiers, for this the columns at the upper and lower ends are provided with protruding plates, which, in a two-tier or more arrangement, are superimposed on each other and fastened together with bolts, ensuring the perception of all vertical loads, and the floor sections above the installed unit simultaneously perform the functions a ceiling section block installed below. 2. The construction according to claim 1, characterized in that in the wall sections between the racks installed diagonal coupling elements from a bent profile. 3. The construction according to claim 1, characterized in that the joints of the wall posts with beams are made on self-tapping screws. 4. The design according to claim 1, characterized in that the longitudinal and transverse beams located along the contour of the block are attached to the columns with bolts. 5. The design according to claim 1, characterized in that all the bent elements of the frame of the block are made of galvanized steel.