RU2586352C1 - Frameless building with height of longitudinal bearing and end walls up to 25 meters - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to designs of frameless buildings of thin-sheet shaped wavy sections with longitudinal and end walls, and can be used at erection and multispan buildings and structures of different purpose with increased useful height and large floor span. In frameless building for increasing the useful height of up to 25 metres at maximum spacing 125 meters the wall panels are arranged vertically and are fixed to foundation and ceiling panels. Along the walls along the perimeter of building there are wind stands installed vertically, which are fixed to foundation and ceiling panels and interconnected by crossbars, and crossbars are fixed to wall panels. Wind posts can be additionally installed in the opening zone of wall panels and fixed to wall panels bolts in height. Configuration of cross section of wind posts can be different and is selected by calculation. Structural design of frameless building depends on dimensions, loads and effects. Wind posts are preferably made from steel with strength characteristics, appropriate to classes S255-C550.

EFFECT: invention increases rigidity and bearing capacity of wall panels, providing high strength of wall design and high technology construction in general, as well as enlarging the application of frameless buildings and range of possible volume-surface planning solutions while ensuring maximum possible use of useful height.

15 cl, 7 dwg

Description

The invention relates to the field of construction, and in particular to structures of frameless buildings from thin-sheet profiled undulating sections with longitudinal load-bearing and end walls and can be used in the construction of single and multi-span buildings and structures for various purposes with increased useful height, including long-span.

A promising direction in the development of the construction of frameless buildings from metal thin-sheet profiled elements is to increase their internal free volume, including usable height.

Known steel structures of prefabricated frameless buildings of the company HONCO. In particular, the building of Honko Buildings International, LTD (SA) with a convex or flat roof is known, containing two load-bearing walls made of interconnected wave-shaped sections, connected to at least one end wall, fixed to the foundation and to the floor (see Patent RU 2463411, EBB 1/342, 2012).

Frameless buildings are known from the production of Exergy CJSC, which are a structure with a span of up to 75 m, containing at least one end wall fastened together, two supporting longitudinal walls, a ceiling and a roof covering made of profiled undulating sections. Bearing and end wall sections are continuous to the entire height of the structure, are installed vertically and fixed to the foundation. Structural section - the main structural element of all buildings is made of steel corrugated profiled sheet with a thickness of 0.8-2.0 mm, a height of 128 mm and a width of 1 meter. The walls are made of corrugated profiled sheets with a thickness of 0.8 mm to 2.0 mm with double corrugation. The corrugations of the wall panels are arranged vertically. Hinge joints of the walls with the foundation and coating. Transverse geometric immutability of the building is ensured by the end walls. Connections of all structural elements of the building are bolted. Together with TSNIISK them. Kucherenko (Moscow) developed an enterprise standard that defines production and installation standards, and certified frameless construction technology (http://www.exergia48.ru/; http://lioninvest.by/p581.html; http: // www .stu.lipetsk.ru / education / chair / kaf-mk / science / scienmat / 4189 /).

In all these well-known solutions of frameless buildings, the height of wall structures is limited by the extreme flexibility of typical structural profiled undulating sections to about 6 meters (http://www.stroybud.org/arhitektura.html).

The building of Exergia CJSC is known, which contains many basic structural sections, each of a profiled metal thin-sheet main panel formed with a given section on the basis of one basic panel element, interconnected by bolts in the structure of the bearing longitudinal and end walls and coatings. Bearing longitudinal walls made of composite structural sections have increased strength and rigidity, and therefore, increased bearing capacity, because the main sheet profile of the structural section is reinforced with a wall plate. It involves the full inclusion in the work of the main profile and the overhead gain sheet. The wall lining as part of the structural section allows you to increase the length of the main panel, as well as increase the span of a frameless building. The assembled sections are assembled vertically, interconnected by lateral edges by means of bolts, forming longitudinal bearing walls. The wall fence is installed vertically, fixed to the foundation at the bottom (see patent RU 2403357, Е04Н 1/00, Е04Н 1/08, 2010). This decision was made as a prototype.

However, such a known composite structural section from the main panel, reinforced with a wall plate, cannot be used for the construction of walls up to 25 meters high, because it does not have sufficient rigidity and load-bearing capacity for this, and an increase in its length makes installation at the construction site difficult. With an increase in the height of the walls of the building, the bearing capacity and deformability of the wall bearing composite structural sections is not provided for design loads. Thus, the main disadvantage is that the height of wall structures is limited by the ultimate flexibility of composite structural profiled sections.

The task to be solved in this proposal is to develop an effective design of a frameless building with an increased usable height from thin-sheet profiled undulating sections with longitudinal load-bearing and end walls by increasing the rigidity and load-bearing capacity of wall panels.

The technical result consists in the possibility of creating a frameless building from thin-sheet profiled undulating sections with longitudinal load-bearing and end walls with increased usable height of up to 25 meters with a maximum span of up to 125 meters, increasing the rigidity and load-bearing capacity of wall panels, including long ones. High strength of the wall structure and high-tech construction as a whole are ensured. The scope of frameless buildings and the arsenal of possible space-planning solutions have been expanded. The maximum possible useful use of the height is provided.

The essence of the invention lies in the fact that in a frameless building with a height of longitudinal bearing and end walls of up to 25 meters, containing two longitudinal bearing and at least one end wall, including structural sections bolted together by bolts - profiled wave-shaped panels fixed to the foundation and to ceiling covering panels, the peculiarity is that additionally there are installed wind posts along the walls connected by crossbars, while the crossbars are bolted to the wall panels, and each I wind rack is made of a profile of increased rigidity and is fixed to the foundation and to the ceiling panel of the coating. The peculiarity is that the fixing of the wind posts to the foundation is preferably performed hinged. In addition, the fixing of the wind posts to the ceiling cover panels is advantageously accomplished by means of a sheet hinge. Also, wind racks can be additionally installed in the area of wall openings, while the wind racks must be bolted to the wall panel in height. Wall panels can be made continuously to the entire height of the walls or with at least one mounting joint on bolts along the height of the walls. The peculiarity is that bent profiles of increased stiffness, in particular, single or interconnected, closed sections, can be used as wind racks. Also, rolling profiles can be used as wind racks. Wind racks can be made both single-branch, and multi-branch. The building, in particular, is designed with a span of up to 125 meters. In addition, the wind posts are preferably made of steel with strength characteristics corresponding to classes C255-C550.

The set of essential features allows you to get the specified technical result.

Additional installation of wind racks connected by crossbars, and simultaneous fastening of crossbars to wall panels, fastening panels in height from a plane, allows to reduce the estimated length of wall panels and distribute horizontal loads, to ensure uniform stress distribution. Reinforcing wall panels, the rack-and-beam structure serves as a compensator for deformations, increases the rigidity of cross sections, and this allows to increase the length of the panel of the structural section. A more uniform redistribution of efforts across the width of the section of the panel, increased strength and reliability, and, therefore, bearing capacity.

The use of a sheet hinge in the mating zone of the racks with the ceiling panel compensates for the vertical movement of the coating structure. The additional use of wind racks in the area of the organization of the opening, bolted to the wall panel in height, allows to increase its strength.

The use of steel with the strength characteristics corresponding to the C255-C550 classes for the manufacture of wind racks provides them with increased strength and reduced weight.

The proposed solution to the wall construction meets the requirements of strength, stability and rigidity, which makes it possible to increase the useful height of the walls to 25 meters with a maximum span of 125 meters with a decrease in material consumption and simplification of installation. This is also determined by the theoretical calculation of the bearing capacity and deformability, which is confirmed by experimental tests of fragments of the structural element of the bearing longitudinal walls. Provided increased rigidity and bearing capacity of wall panels. Strengthening the wall panels of the frameless building along the entire perimeter with the formation of a single integral structure allows for a significantly increased usable height to perceive impacts.

In FIG. 1 shows a node for attaching a wind bolt to a wind rack, general view; in FIG. 2 - node mount the wind rack to the foundation, General view; in FIG. 3 - the attachment point of the wind rack to the foundation, section AA in FIG. 2; in FIG. 4 - the site of attachment of the wind strut to the coating, General view; in FIG. 5 - a fastening unit of the wind strut to the coating, view 1-1 in FIG. four; in FIG. 6 - a fastening unit of the wind strut to the coating, view 2-2 in FIG. four; in FIG. 7 - the attachment site of the wind strut to the coating, view 3-3 in FIG. four.

The frameless building contains structural sections, each in the form of a metal profiled wave-like thin-sheet panel 1, formed with a given section on the basis of one basic panel element, fastened together by means of bolts in the construction of two supporting longitudinal and at least one end walls, ceiling and roof . Wall panels 1 are mounted vertically and fixed to the foundation 2 and to the ceiling panels 3. Wall panels 1 can be continuous to the full height of the walls or can be made with one or more mounting joints on bolts along the height of the walls. Wall panels 1 are preferably made of sheet steel of class C245-C-345 with a thickness of 0.8-2.0 mm with double corrugation based on one base panel element (not shown). Advantageously, the base panel element is a fairly flat building panel comprising two longitudinally elongated main profiles, each provided with a plurality of longitudinal minor profiles located at the same distance from each other and superimposed on the main profiles, observing the general relief of the panel profile, the gutters and profile ridges are smoothed, thus forming one central flat part and a flat side at each edge of the panel. The corrugations of the wall panels are arranged vertically. The width of each wavy section is one meter, the corrugation depth is 128 mm, the length depends on its purpose. Wavy sections can have a protective coating, for example, zinc, paint, zinc with an additional paint and varnish, polymer, electrolytic with an additional polymer, protective and decorative paint and varnish, aluminum zinc, etc.

Along the walls around the perimeter of the building there are vertically installed wind posts 4, which are interconnected by crossbars 5, and crossbars 5 are fixed to wall panels 1. Between the posts 4 and crossbars 5, in particular, a hinge joint is made. The step of fastening the crossbars 5 to the panel 1 depends on the height and wind region (wind load), for example, 500 mm across the width of the panel. The pitch of the racks depends on the wind area (wind load). Wind posts 4 are made of high rigidity steel, preferably steel with strength characteristics corresponding to classes C255-C550. Each wind strut 4 is fixed to the foundation 2, for example, it can be hinged, rigidly clamped, and fixed in the mating zone to the ceiling panel 3, in particular by means of a sheet hinge or, for example, by directly attaching the ceiling panel 3 by means of known mounting parts. The length of the wind posts 4 is determined by operational requirements and the decision of the general layout of the building. Wind racks 4 and crossbar 5 are located so as not to close the windows and openings of the building. Wind racks 4 and crossbars 5 are combined among themselves in the set sequence. For example, wind racks 4 can be installed along the vertical joints of the wall panels 1 and are interconnected by horizontal crossbars 5, bolted to the wall panels 1.

Wind racks 4 can be simultaneously used to further strengthen the wall panels 1. So they can be additionally installed in the opening area of the wall panels 1 and fixed to the wall panels 1 with bolts in height. The cross-sectional configuration of the wind struts 4 can be different and is selected by calculation, depending on the requirements for the building in terms of strength and design of nodes. As wind racks 4, it is possible to use bent profiles of increased rigidity, both single and closed sections, interconnected. It is also possible to use rolled profiles of increased rigidity as wind racks 4. Wind racks 4 can be made as single-branch, and multi-branch. The constructive implementation of a frameless building depends on the overall dimensions, loads and effects.

Assembly of frameless building structures is carried out on bolts with wrenches at a construction site. Connections of all structural elements of the building are made by means of bolts, without the use of welding. All components of the building, with the exception of the elements of wall openings and openings in the coating, are steel elements of cold forming, are manufactured in the factory on specialized well-known automatic lines. Bolt holes are also factory installed.

The standardness and transportability of structural elements, the possibility of pre-fabrication of them at factories makes it possible to effectively carry out the construction of various, including large-span buildings and structures. The design of a frameless building provides the ability to perform in a wide variety of options, depending on the space-planning solution or depending on economic preferences - an increase in the number of additional elements, the implementation of structural sections of longitudinal load-bearing walls with overlays. The high speed of installation of the building is provided. Allows you to maximize the use of the internal space of the building, as no supporting structures standing inside, increase the usable height and usable volume of the frameless building. It makes it possible to simplify the transportation and assembly of large-height wall panels and their installation in the conditions of the construction site, thereby significantly reducing the construction time of buildings. It will increase the competitiveness of frameless buildings.

Thus, a technically accessible and effective implementation concept has been developed to increase usable height, which allows for the construction of a variety of large-span frameless buildings and structures.

Claims (15)

1. A frameless building with a height of longitudinal bearing and end walls of up to 25 meters, containing two longitudinal bearing and at least one end wall, including structural sections bolted together by bolts - profiled wave-shaped panels fixed to the foundation and to the ceiling panels, characterized in that additionally along the walls there are installed wind racks connected by crossbars, while the crossbars are bolted to wall panels, and each wind rack is made of a profile of increased rigidity and fixed to the foundation and to the ceiling panel of the coating. 2. The building according to claim 1, characterized in that the fastening of the wind posts to the foundation is made hinged. 3. The building according to claim 1, characterized in that the fastening of the wind racks to the ceiling panels of the coating is made by means of a sheet hinge. 4. The building under item 1, characterized in that the wind racks are additionally installed in the area of the wall openings, while they are bolted to the wall panel in height. 5. The building under item 1, characterized in that the wall panels are made continuously to the entire height of the walls. 6. The building according to claim 1, characterized in that the wall panels are made with at least one mounting joint on bolts along the height of the walls. 7. The building according to p. 1, characterized in that the bent profiles are used as wind racks. 8. The building according to claim 7, characterized in that single bent profiles are used. 9. The building according to claim 7, characterized in that the bent profiles connected together are used. 10. The building according to claim 7, characterized in that the bent profiles with closed sections are used. 11. The building according to claim 1, characterized in that the rolling profiles are used as wind racks. 12. The building under item 1, characterized in that the wind racks are made single-branch. 13. The building according to claim 1, characterized in that the wind racks are multi-branch. 14. The building under item 1, characterized in that it is made with a span of up to 125 meters. 15. The building under item 1, characterized in that the wind racks are made of steel with strength characteristics corresponding to classes C255-C550.

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