RU2506376C1 - Concrete building with light steel volume frame and method of its assembly - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to the field of construction, in particular to a concrete building with a volume of lightweight steel frame and a process for its construction. The building includes a wall surrounding a lightweight steel frame, a panel overlap surrounding the light steel frame, coupled with a wall surrounding the lightweight steel frame to form a volumetric light steel construction section, and concrete is poured into the volumetric light steel frame of the construction section. Each wall surrounding the light steel frame and the panel surrounding the light steel frame contain an overlap of welded mesh reinforcement, and multiple steel lattice sections, separated from one another and each having multiple holes stretched. Each steel grid profile consists of two parallel ribs and the multiple corner webs there between formed as a single piece. Jumpers and stretched holes limit the bridges formed by stretching the angled edges.

EFFECT: lower consumption of metal and reduced complexity of construction of buildings.

12 cl, 7 dwg

Description

This application claims priority on the basis of Chinese patent application No. 20100104259.2, filed January 29, 2010 with the State Intellectual Property Office of the PRC. The entire contents of this application is included in the materials of this application by reference.

Technical field

The proposed invention relates to the field of construction and construction technologies, and in particular to a concrete building with a light steel three-dimensional frame and the method of its construction.

State of the art

In the field of construction technologies, concrete structures can be used not only for low-rise and high-rise construction, but also for pre-fabricated buildings and, accordingly, are widely used.

For concrete structures poured in place, steel reinforcement and formwork may be required in place, which requires laborious work and lengthens the construction time.

Pre-curable composite wall components are fabricated at the factory and assembled on site. However, due to the need to solve the problems of tight connection between the prefabricated elements and the seepage of water through the joints between the prefabricated elements, the cost of construction can be high.

CN 1958984A, China's published patent application, describes a composite concrete building with a steel mesh frame and a method for constructing it in which cold-stamped thin steel is used for the steel frame and the traditional wooden or steel formwork is replaced with a steel mesh. The original steel mesh is produced at the factory and mounted in place on the steel mesh frame. Then concrete is poured in place to obtain a solid wall structure. However, this design has the following disadvantages.

Firstly, the steel grating profile used in the mesh frame is a cold-stamped part with a thickness of 1.0-4.0 mm and a C-shaped, U-shaped or Z-shaped cross-section. In the jumper between two parallel corner edges, openings are formed and evenly distributed. A reinforcing edging is formed around the periphery of each opening, which forms a U-shaped jumper between two adjacent openings. The process of manufacturing a steel grating profile is quite complicated. The openings of the openings must be punched with a stamp in a thin steel sheet, and then cold bent on a separate device. Depending on the proportion of the area of the openings in the total area of the steel grating profile, the number of scraps of steel sheets sent to waste can reach 10-15%. Moreover, a special production line may be required to produce a steel grating profile, which will increase the cost of production.

Secondly, the steel mesh used for the frame is a flat mesh obtained by cold stamping a galvanized steel sheet with a thickness of 0.3 to 0.6 mm. On a flat mesh, filaments of a shape in the form of convex strips are formed, located parallel at a predetermined distance, and the steel mesh is fixed on the surface of the steel skeleton by the protruding sections of the filament strips. The steel mesh does not take on part of the structural loads and is used simply as a formwork, which can cause an increase in the cost of construction and increase the metal consumption of the structure. After curing concrete on the surface of the steel mesh, plastering may be required to level the surface, which increases the complexity of the process.

Another published Chinese patent application CN 101654925A describes a concrete building with a cast spatial truss and a method for constructing it. However, the method uses a fixed formwork that cannot be reused, which can increase the cost of construction. In addition, since the formwork cannot be removed, it is inconvenient to determine the density of the hardened concrete.

SUMMARY OF THE INVENTION

Constructive variants of the present invention are intended to solve at least partial, at least one of the existing problems. Accordingly, a concrete building with a light steel volumetric frame is proposed. The frame of such a building is simple and easy to manufacture, does not require expensive equipment and can reduce the amount of metal used. A method for constructing a concrete building with a light steel volumetric frame is also proposed.

According to the invention in a broad sense, a concrete building with a light steel volumetric frame is proposed. The building includes: wall volumetric light steel frame; volumetric light steel frame of the floor slab connected to the wall volumetric light steel frame, with the formation of the volumetric light steel frame of the construction section. Concrete is poured into a volumetric lightweight steel frame of a building section, in which each wall volumetric lightweight steel frame and each volumetric light steel frame of a floor slab contain welded mesh reinforcement and a plurality of steel grating profiles. Steel grating profiles are spaced one from the other, and each has a plurality of elongated holes. To join together several steel grating profiles, welded mesh fittings are welded to them. Each steel grating profile contains two parallel corner ribs and many jumpers between them. Two corner ribs and many jumpers are made as a single part. Between the jumpers and between the corner ribs are stretched holes. A plurality of jumpers and a plurality of elongated holes are formed by stretching two corner edges.

Another object of the invention in a broad sense is a method of constructing a concrete building with a light steel three-dimensional frame. The method includes:

(1) connecting welded mesh reinforcement to steel grating profiles spaced from each other and each having a plurality of elongated holes. In this case, a wall lightweight steel frame and a volumetric lightweight steel frame of the floor slab are formed, respectively, in which each steel grating profile contains two parallel corner ribs and many jumpers between two corner ribs. Two corner ribs and many jumpers between them are made as a single part. Between the jumpers and between the corner ribs are stretched holes. Many jumpers and many stretched holes are formed by stretching two corner ribs;

(2) fixing the lower edge of the wall volumetric light steel frame to the foundation, the connection of the wall volumetric light steel frame and the volumetric light steel frame of the floor slab to form the volumetric light steel frame of the building section;

(3) installation of removable formwork on a volumetric light steel frame of a construction section with the formation of a chamber for pouring concrete in a volumetric light steel frame of a construction section; and

(4) pouring concrete into concrete pouring chambers and selectively removing formwork to form a solid building block.

For a concrete building with a light steel volumetric frame and, accordingly, the method of its construction according to the present invention, a wall volumetric light steel frame and a volumetric light steel frame of a floor slab are formed by welding mesh welded reinforcement and steel grating profiles, each of which has many stretched holes, so the use of steel grating profiles can simplify and facilitate the process, save materials and costs, time and investment in industrial equipment. Moreover, formwork can be removed and reused, further reducing costs.

Other features and advantages of the structural variants of the invention will be partially given in the further description, partially will be obvious from the further description, or may be established in practice by using the present invention.

Brief Description of the Drawings

These and other features and advantages of the structural variants of the invention will be more clear and obvious from the following description with reference to the accompanying drawings, in which:

Figure 1 is a schematic view from above of a wall volumetric light steel frame of a concrete building according to the invention.

Figure 2 is a vertical section of a concrete building with a light steel surround frame along the line aa in figure 1.

Figure 3 is a perspective view of a volumetric light steel frame of a construction section formed by a wall volumetric light steel frame and a volumetric light steel frame of a floor slab according to the present invention.

Figure 4 is a schematic illustration of a steel grating profile with extended openings used in a volumetric wall lightweight steel frame and in a volumetric light steel panel ceiling according to the present invention.

5 is a schematic illustration of a welded mesh reinforcement in a wall volumetric lightweight steel frame and in a volumetric lightweight steel frame of a panel ceiling according to the present invention.

6 is a schematic isometric view of the insulating panel of a concrete building with a light steel surround frame according to the invention.

7 shows the sequence of steps of the method of constructing a concrete building with a light steel volumetric frame according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

Details of the invention will be disclosed in the description of structural options. Given structural options with reference to the drawings are illustrative, explanatory and are used for a General understanding of the invention. They should not be construed as limiting the invention. The same or similar elements and elements having the same or the same functions are denoted by the same numeric positions throughout the description.

In the description, unless expressly agreed otherwise, the relative terms are “central”, “longitudinal”, “lateral”, “front”, “rear”, “right”, “left”, “internal”, “external”, “lower” , “Top”, “horizontal”, “vertical”, “above”, “under”, “top”, “bottom”, as well as derivatives from them (for example, “horizontally”, “down”, “up” and t .d.) should be understood as referring to orientation only when demonstrated on drawings and explanations thereof. These relative terms are given for convenience of description and do not require that the proposed device was designed or operated in that orientation.

Unless expressly agreed otherwise, terms related to joints, bonds, etc., such as “connected” and “interconnected”, are used for connections in which structures are fastened or connected to each other directly or through intermediate parts, as well as rigid or movable joints.

A concrete building with a light steel volumetric frame according to the present invention will be described below with reference to the drawings.

As shown in FIGS. 1-5, a concrete building with a light steel volumetric frame according to the present invention comprises a wall volumetric light steel frame 1, a volumetric light steel frame 2 of a floor slab, and concrete.

As shown in FIG. 3, a volumetric lightweight steel frame 2 of a floor slab is connected to a wall volumetric lightweight steel frame 1, forming a volumetric lightweight steel frame of a building section. Concrete is poured into a lightweight volumetric steel frame of the construction section. Removable formwork 3 is installed on a lightweight volume steel frame of the construction section before pouring concrete, and formwork 3 is selectively removed after the concrete has cured for reuse.

It should be noted that the expression “formwork 3 is selectively removed after curing concrete” means that this choice may depend on the requirements of the project. For example, in one case, the formwork 3 on the outer side of the wall volumetric lightweight steel frame 1, forming the outer wall of a concrete building with a light steel volumetric frame, may not be removed, but remain constant, and therefore, the insulation panel 8 can be attached to the formwork 3 on the outer side of the wall volumetric light steel frame 1, forming the outer wall of the concrete building with a light steel volumetric frame. That is, the insulating layer is placed on the outer wall of the concrete building with a light steel surround frame, thereby improving the thermal insulation of the building. However, the formwork 3 under the volumetric light steel frame 2 of the panel floor and the formwork 3 on the wall volumetric light steel frame 1, which do not form the outer wall of a concrete building with a light steel volumetric frame, can be removed. Naturally, in another case, all formwork 3 can be removed.

Each of the wall frames 1 and the panels 2 of the floor slab contains welded mesh reinforcement 4 and a plurality of steel grating profiles 11. The steel grating profiles 11 are spaced apart from each other, and each of them has a plurality of elongated holes 113. For connecting several steel grating profiles 11 together they are welded to the welded mesh reinforcement 4.

Each steel grating profile 11 consists of two parallel corner ribs 111 and a plurality of connecting jumpers 112. Two corner ribs 111 and jumpers 112 are made as a single part. The jumpers 112 and the openings 113 between them themselves are formed by stretching the two corner ribs 111.

In a concrete building according to the present invention, a wall volumetric lightweight steel frame 1 and a volumetric lightweight steel frame 2 of a panel overlap are formed by welding together a welded wire mesh 4 and several steel grating profiles 11. In this case, a plurality of jumpers 112 and a plurality of stretched holes 113 are formed by stretching two corner ribs 111, so that the steel grating profile 11 can simplify the manufacture, save materials and costs, time and investment in industrial equipment.

In some structural embodiments, a concrete building with a light steel surround frame may be multi-story, as shown in FIG. 2. For example, an eight-story building is shown. Each floor of a concrete building with a light steel spatial frame is formed by one tier of a solid building block, and each solid building block is formed by the horizontal abutment of one or more building sections. For example, in the structural embodiment shown in FIGS. 1-2, one solid building block is formed by ten building sections.

Each construction section is formed by pouring concrete of one volumetric light steel frame. The frame of the construction section is formed by one volumetric lightweight steel wall frame 1 and one volumetric lightweight steel frame 2 panel overlap. Several solid building blocks, successively mounted on top of each other, form a multi-storey concrete building with a light steel volumetric frame, in which the wall frame 1 of the upper tier of the integral building block is attached to the wall frame 1 of the adjacent lower tier of the integral building blocks. The wall frame 1 of the upper tier of solid building blocks can be connected to the wall frame 1 of the adjacent lower tier of solid building blocks, for example, a connecting element. The lower edge of the wall frame 1 of the lower tier of the solid building blocks is mounted on the foundation 13. The upper edge of the wall frame 1 of the upper tier of the solid building blocks is connected to the frame 2 of the panel ceiling serving as a roof.

In some structural embodiments, the panel 2 of the floor slab can be connected to the wall frame 1 by welding to form a three-dimensional light steel frame of the construction section. You can also connect the frame 2 panel overlap with the wall frame 1 connecting elements.

In other embodiments, as mentioned above, the formwork 3 may constantly remain on the outside of the wall volumetric lightweight steel frame 1, forming the outer wall of the concrete building. In other words, after the concrete has cured, the formwork 3 on the outside of the wall volumetric light steel frame 1 forming the outer wall of the concrete building may not be removed, and the insulation panel 8 may be attached to the formwork 3, thereby improving the thermal insulation of the building.

In one case, as shown in FIG. 4, for example, each steel grating profile 11 in the wall volumetric light steel frame 1 and the volumetric light steel frame 2 of the floor slab can be made of one steel sheet, by applying multiple slots between two corner ribs 111 in the longitudinal direction (i.e., the left and right directions in FIG. 4) of the corner ribs 111 and then stretching the two corner ribs 111 in a direction transverse to the corner ribs 111 (i.e., the upper and lower directions in FIG. 4), so between a plurality of jumpers 112 and a plurality of elongated holes 113 bounded by jumpers 112 are formed between two corner ribs 111. Thus, steel grating profiles 11 can be very simple to manufacture, save materials, reduce time and labor.

It should be noted that the structure of the wall frame 1 is essentially the same as the panel 2 of the floor slab, except that before pouring concrete, the removable formwork 3 is installed on two sides of the wall frame 1, while the removable formwork 3 is simply installed on the lower surface of the frame 2 panel overlap.

In some design options, the doors and windows of the building can be designed depending on the requirements of the project. For this reason, in sections of the wall volumetric light steel frame 1 provide door and window openings in order to place the doors and windows of the building, respectively. On both sides of the doorway and window opening, respectively, left in horizontal directions on the sections of the wall volumetric light steel frame 1, there are bordering elements 6. Each bordering element 6 contains longitudinal reinforcing steel bars and horizontal clamps or contains vertical reinforcing bars, vertical steel profiles and horizontal clamps. In addition, connecting beams 7 are placed above the door and window openings. Each connecting beam 7 contains horizontal reinforcing steel bars and vertical shanks. According to the project, a stairwell may be preformed in a volumetric light steel frame 2 of a panel ceiling.

As shown in FIG. 5, welded wire mesh 4 can be made by welding reinforcing steel rods 41 arranged horizontally and reinforcing steel rods 42 arranged vertically. The welded mesh reinforcement 4 is welded with a plurality of steel lattice profiles 11 spaced from each other, each having a plurality of elongated holes 113, thereby forming a wall volumetric light steel frame 1 and volumetric light steel frame 2 of a panel ceiling, respectively.

In some structural embodiments, the insulating panel 8, placed on the outer wall of a concrete building with a light steel spatial frame can be a composite insulating panel. As shown in FIG. 6, the insulating panel 8 comprises (sequentially from the inside out) the insulating layer 801 of polystyrene or mineral wool, a layer of anti-cracking composition or a protective layer 802 of the panel and a decorative surface layer 803.

A method of constructing a concrete building with a light steel spatial frame according to the present invention will be described below with reference to Fig.7. A method of constructing a concrete building according to the present invention includes the following operations:

(1) joining together steel grating profiles 11 spaced from each other and each having a plurality of elongated holes 113, using welded wire fittings 4 to form respectively a wall volumetric light steel frame 1 and a volumetric light steel frame 2 panel overlap, in which each the steel grating profile 11 comprises two parallel corner ribs 111 and a plurality of jumpers 112 between two corner ribs 111, the two corner ribs 111 and the plurality of jumpers 112 being made as a single part b, and a plurality of jumpers 112 between two corner ribs 111 and a plurality of stretched holes 113 bounded by jumpers 112 are formed by stretching two corner ribs 111;

(2) fixing the lower edge of the wall volumetric light steel frame 1 to the foundation 13 and connecting the wall volumetric light steel frame 1 with the volumetric light steel frame 2 of the panel ceiling to form the volumetric light steel frame of the building section;

(3) the installation of removable formwork 3 on the volumetric light steel frame of the construction section with the formation of a chamber for pouring concrete in the volumetric light steel frame of the construction section; and

(4) pouring concrete into concrete pouring chambers and selectively removing formwork 3 to form a solid building block, with each floor of a concrete building with a light steel volumetric frame formed by one tier of a solid building block.

When a concrete building with a light steel volumetric frame is a multi-storey building, operations (1) - (4) are repeated to form several tiers of solid building blocks, while the lower edge of the wall frame 1 of the upper tier of solid building blocks is attached to the wall frame 1 of the adjacent lower tier of solid building blocks, for example, using steel connecting elements, thus forming a multi-storey concrete building. Each solid building block is formed by the horizontal abutment of one or more building sections. Each building section is made by pouring concrete into a lightweight volumetric steel frame of a construction section formed by one volumetric lightweight steel wall frame 1 and one lightweight volumetric steel frame 2 of a panel ceiling. Several solid building blocks are sequentially mounted on top of each other and form a multi-storey concrete building with a light steel volumetric frame. Volumetric lightweight steel frame 2 panel overlap can be connected to the wall volumetric lightweight steel frame 1 by welding or connecting elements.

As already mentioned, each steel grating profile 11 is formed by applying a plurality of narrow longitudinal sections between two corner ribs 111 and further stretching the two corner ribs 111 in the transverse direction.

In one embodiment, the method of constructing a concrete building with a light steel spatial frame additionally provides for: placing an insulation panel 8 on the outer wall of the concrete building. In this case, the formwork 3 on the outer side of the wall spatial light steel frame 1, forming the outer wall of the concrete building with the light steel spatial frame, is left fixed, and the insulation panel 8 is attached to the formwork 3 on the outer side of the wall frame 1, forming the outer wall of the concrete building.

When using the method of constructing a concrete building with a light steel volumetric frame according to the invention, steel grating profiles 11 forming a wall volumetric light steel frame 1 and a lightweight volumetric steel frame 2 of a floor slab simplify and facilitate the process, save materials and costs, time and investment in industrial equipment. Moreover, formwork 3 can be removed for reuse, further reducing costs.

The terms throughout the description “constructive option”, “some options”, “one constructive option”, “separate example”, “another example”, or “some examples” mean that individual features, structures, materials or parameters given for an example or constructive options relate to at least one of the options or examples of the invention. Verbal expressions, such as “in some constructive variants”, “according to one of the constructive variants of the invention”, “in a constructive variant”, “in one case”, “in another case”, or “in some cases” in different places of description are not necessarily refer to only one specific example embodiment of the invention. Moreover, individual features, structures, materials or parameters may be combined in any suitable way in one or more design options or examples.

Although explanatory examples have been presented and described, it will be understood by one of ordinary skill in the art that in structural embodiments, without departing from the spirit and meaning of the invention, there may be changes, variations and modifications. All of them are included in the scope of the present invention.

Claims (12)

1. Concrete building with a light steel volumetric frame, comprising: wall volumetric lightweight steel frame; volumetric light steel frame of the floor slab connected to the wall volumetric light steel frame to form a volumetric light steel frame of the construction section; and concrete poured into a spatial lightweight steel frame of a building section, in which each wall volumetric lightweight steel frame and volumetric lightweight steel frame of a floor slab comprise welded wire mesh and a plurality of steel grating profiles that are spaced apart from each other and each has a plurality of elongated holes, welded mesh reinforcement is welded to steel profile grids so as to join together a plurality of steel grid profiles, each steel grid profile comprising va parallel wing edges and a plurality of webs between two angled ribs, wherein the two wing edges and a plurality of webs are made as a single item, and a plurality of webs between two wing ribs and stretched plurality of holes defined webs are formed by stretching the two angled edges. 2. The building according to claim 1, characterized in that it is a multi-storey building, each floor of which is formed by one tier of a solid building block, and each solid building block is formed by the horizontal arrangement of one or more building sections, each building section made by pouring concrete into a volumetric lightweight steel frame of the construction section, and several solid building blocks are sequentially mounted one on the other and form a multi-storey concrete building with a light steel three-dimensional frame, in this position the wall spatial light steel frame of the upper tier of integral building blocks attached to the wall spatial light steel frame of the lower tier adjacent whole building blocks. 3. The building according to claim 1, characterized in that the volumetric light steel frame of the panel floor is connected to the wall volumetric light steel frame by welding or a connecting element. 4. The building according to claim 1, characterized in that the formwork is constantly placed on the outer side of the wall volumetric steel frame, forming the outer wall of the concrete building with a light steel volumetric frame, and the insulation panel is attached to the formwork. 5. The building according to claim 1, characterized in that each steel grating profile is made by applying a plurality of slots extending in the longitudinal direction between two corner ribs, and then stretching the two corner ribs in the transverse direction. 6. The building according to claim 1, characterized in that it further comprises:
a plurality of bordering elements located on two sides of the doorway and the window opening, which are respectively left in the horizontal spatial parts of the wall lightweight steel frame; and a plurality of connecting beams above the doorway and window opening, each bordering element comprising longitudinal reinforcing steel bars and horizontal clamps, or containing vertical reinforcing bars, vertical steel profiles and horizontal clamps; and each connecting beam contains horizontal reinforcing steel rods and vertical clamps. 7. A method of constructing a concrete building with a light steel spatial frame, including:
(1) joining together steel grating profiles spaced apart from each other and each having a plurality of extended holes, using welded wire mesh fittings to form respectively wall volumetric light steel frame and volumetric light steel frame of the ceiling panel, in which each steel grating profile contains two parallel corner ribs and many jumpers between two corner ribs, with two corner ribs and many jumpers made as a single part, and many check between the two angled ribs and a plurality of extended holes defined webs are formed by stretching the two angled ribs;
(2) fixing the lower edge of the wall volumetric light steel frame to the foundation and the connection of the wall volumetric light steel frame and the volumetric light steel frame of the floor slab with the formation of the volumetric light steel frame of the construction section;
(3) installation of removable formwork on a volumetric light steel frame of a construction section with the formation of a chamber for pouring concrete in a volumetric light steel frame of a construction section; and
(4) pouring concrete into concrete pouring chambers and selectively removing formwork to form a solid building block. 8. The method according to claim 7, characterized in that each steel grating profile is obtained by applying a plurality of slots extending in the longitudinal direction between two corner ribs, and then stretching the two corner ribs in the transverse direction. 9. The method according to claim 7, characterized in that the volumetric light steel frame of the panel overlap is connected to the wall volumetric light steel frame by welding or connecting elements. 10. The method according to claim 7, characterized in that it further includes repeating operations (1) to (4) to form several tiers of solid building blocks in order to obtain a multi-storey concrete building with a light steel volumetric frame, in which each floor of the concrete building with a light steel volumetric frame formed by one tier of a solid building block, and each solid building block is formed by the horizontal arrangement of one or more building sections, each building section is made by pouring concrete into a lightweight volumetric steel frame of the construction section, and several solid building blocks are successively mounted on top of each other and form a multi-storey concrete building with a light steel volumetric frame, in which the wall volumetric light steel frame of the upper tier of solid building blocks is attached to the wall volumetric light steel frame of the adjacent lower tiers of solid building blocks. 11. The method according to claim 10, characterized in that the wall volumetric light steel frame of a solid building block of the upper tier and the wall volumetric light steel frame of a solid building block of an adjacent lower tier are joined together by steel connecting elements. 12. The method according to claim 7, characterized in that the formwork on the outer side of the wall volumetric steel frame, forming the outer wall of a concrete building with a light steel volumetric frame, is left fixed, and the insulation panel is attached to the formwork on the outside of the wall volumetric light steel frame, forming the outer wall of a concrete building with a light steel surround frame.

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