RU2641153C1 - Light steel structure - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: light steel structure comprises at least two first positioning elements, respectively located at the two ends of the two opposing C-shaped steel plates in the longitudinal direction of the C-shaped steel plates to form a beam in a rectangular tubular moulde. Wherein the first positioning elements form respectively combined points on the two end surfaces of the beam. Several beams are connected to one another by means of the combined points and form the transverse beams and columns of the building. Also, at least two second positioning elements, respectively, are located at the two ends of the C-shaped steel plate in the longitudinal direction of the C-shaped steel plate to form a rafter. Wherein the second positioning elements form assembly points on the two end surfaces of the rafter, respectively. Several rafters are located between the adjacent beams through the assembly points and are made in the form of a floor surface, a wall surface, and a roof of a building.

EFFECT: increasing the bearing capacity of the structure.

7 cl, 8 dwg

Description

Field of Invention

The present invention relates to the construction of buildings, in particular to a light steel structure made of C-shaped steel plates.

State of the art

As environmental concerns become widespread, industries have their own ways to avoid environmental pollution, the greenhouse effect, and global warming to achieve the goal with minimal production waste and minimal resource consumption. For example, in the architectural industry, the most economical building materials and structures are focused on achieving structural strength requirements, called green architecture. Lightweight steel structures are one element of green architectures. Because light steel structures have the characteristics of safety, high performance, light components, etc. and are environmentally friendly, lightweight steel structures are being developed quickly. For example, in the United States, there were 120,000 buildings with such requirements in 1998. For Japan, after the Hanshin earthquake in 1995, development and research in light steel technology and related construction specifications accelerated. In addition, in Japan, related measures have also been taken to allow such technology to be suitable for use in that country. Light steel technology has benefited all of Japan. In recent years, these technologies have also been introduced in Taiwan.

Basically, C-shaped steel plates are the main components of a light steel structure. C-shaped steel plates can be made in the form of various transverse beams, columns or rafters. Typically, these transverse beams, columns or rafters are connected to each other by soldering. However, such soldering requires professional welders and high-quality welding techniques, which increases costs. In addition, C-shaped steel plates are machined with a metal or zinc coating so that the structure is corrosion-resistant (stainless); however, welding damages the anti-corrosion coating, as a result of which the structure will be susceptible to rust. Therefore, welding is not recommended for joining C-shaped steel plates. In this regard, some manufacturers have developed components for joining a C-shaped steel plate by blocking. For example, similar technologies are described in TW patent number 437782, 514089, 590134, 590135, M276067, M297972 and M314222. However, it is difficult to have a basic building foundation by connecting a C-shaped steel plate to conventional components. In addition, conventional components are insufficient for structural strength and convenience.

Disclosure of the invention

One of the objectives of the present invention is to provide a lightweight steel structure in which positioning elements are positioned at the two ends of a C-shaped steel plate (s) to form transverse beams, columns or rafters. Further, any two of the aforementioned components are further connected to each other by means of positioning elements. Thus, C-shaped steel plates can be formed as the main skeleton of a building by blocking in a quick and convenient way.

Another objective of the present invention is that the first positioning elements in a single structure can not only be combined with two C-shaped steel plates to form a transverse beam or column into a rectangular tubular shape, but also serve as connecting elements between the transverse beams (crossbars) or columns. Thus, the assembly of the structure is very convenient.

Another objective of the present invention is that the second positioning elements in a single structure can be connected by a C-shaped steel plate and an adjacent crossbar (or column). Thus, the supporting base of the floor surface, the surface of the walls, and the roof of the building can be assembled quickly and conveniently.

Another objective of the present invention is that the first positioning elements and the second positioning elements are located on the end surfaces of the two ends of the transverse beam (or columns, or rafters); the angle of the surface of the end surface of the cross member (or columns, or rafters) can be adapted to build an inclined roof or cornices. Thus, the construction of the roof of the building can be more convenient.

Another objective of the present invention is that two C-shaped steel plates are aligned with each other to form a beam in a rectangular tubular shape using the first positioning elements, and the first positioning element has a wire hole. Thus, cables or wires can be inserted into the inside of the beam through a wire hole and protected by C-shaped steel plates. In addition, a separation gap may be provided between the two C-shaped steel plates of the beam for ventilation and thermal insulation.

Another another objective of the present invention is that the two ends of the beam (or rafters) have positioning elements. Thus, a building can be easily modified or a structure added.

With these objectives in mind, this invention provides a lightweight steel structure comprising:

at least two first positioning elements are respectively located at two ends of two opposite C-shaped steel plates in the longitudinal direction of the C-shaped steel plates to form a rectangular tubular beam; the first positioning elements form respectively combinations of points on the two end surfaces of the beam; several beams are connected to each other using combined points and is formed in the form of crossbars and columns of a building; as well as

at least two second positioning elements are respectively located at two ends of the C-shaped steel plate in the longitudinal direction of the C-shaped steel plate to form a rafter; the second positioning elements form, respectively, the assembly points on the two end surfaces of the rafters; several rafters are located between adjacent beams using assembly points and are formed as the floor surface, wall surface and roof of the building.

In this case, each of the C-shaped steel plates of the beam has a front plate, two side plates on two sides of the front plate and two flanges, respectively, extend towards each other from the free sides of the side plates. A hole is formed between the two flanges. Each of the first positioning elements has a first lower surface and first side walls, respectively, extending from the four edges of the first lower surface in the same direction. The first side walls of the first positioning elements are fixed by the front plates and the corresponding side plates of the C-shaped steel plate to form the beam with the locking elements. The first lower surfaces of the first positioning elements are respectively located on the end surfaces of the beam to form combination points; Thus, several beams are connected to each other by means of locking elements and are formed as crossbars and columns of the building.

In addition, the C-shaped steel rafter plate has a front plate, two side plates on both sides of the front plate, and two flanges, respectively, extending towards each other from the free sides of the side plates. A hole is formed between the two flanges to accommodate the second positioning element. Each of the second positioning elements has a second lower surface and second side walls, respectively, protruding from three interconnected ribs of the second lower surface in the same direction. The second side walls of the second positioning elements are fixed to the front plate and the side plates of the C-shaped steel plate in order to form the rafter using the locking elements. The second lower surfaces of the second positioning elements, respectively, are located on the end surfaces of the rafters to form assembly points, and the second lower surface has several through holes, so that the two ends of each of the rafters are assembled between adjacent beams using through holes and stop elements, and the rafters are formed like the surface of the floor, the surface of the walls and the roof of the building.

In one embodiment, the two opposing first side walls of the first side walls of the first positioning element respectively have a gap and a flap between the cutouts, the gaps are for inserting the flanges of the C-shaped steel plate, the flap is designed to limit the flanges of the C-shaped steel plate, so that the two separation gaps formed respectively on two opposite sides of the beam.

In one embodiment, the wire hole is in the center of the first lower surface of the first positioning element.

In one embodiment, the locking element comprises an inserted nut and bolt.

Brief Description of the Drawings

FIG. 1 illustrates an exemplary schematic view of a building created by beams and rafters in accordance with the present invention;

FIG. 2 illustrates an exploded view of a beam in accordance with the present invention;

FIG. 3 illustrates a perspective view of a beam in accordance with the present invention;

FIG. 4 illustrates an exploded view of a rafter in accordance with the present invention;

FIG. 5 illustrates a perspective view of a rafter in accordance with the present invention;

FIG. 6 illustrates a schematic exploded view showing how beams should be connected to each other to form transverse beams and columns of a building in accordance with the present invention;

FIG. 7 illustrates a schematic exploded view showing how rafters should be assembled with beams to form a support base for the wall surface of a building in accordance with the present invention;

FIG. 8 illustrates a schematic exploded view showing how rafters should be assembled with beams to create the roof of a building in accordance with the present invention.

The implementation of the invention

See FIG. 1-5. FIG. 1 illustrates a lightweight steel structure in accordance with the present invention. FIG. 1 is provided for the purpose of illustration, but does not limit the present invention. Building 1 includes many beams 2 and rafters 3. In this case, the beams 2 are assembled with each other with the formation of transverse beams 11 and columns 12 of building 1. Rafter 3 is assembled between the transverse beam 11 and column 12, rafter 3 serves as a supporting frame for the sealing plate, and the rafter 3 can be formed as a surface of the floor 13, the surface of the wall 14 or the roof 15 of the building 1.

Here, the beam 2 consists of two C-shaped steel plates 4 and at least two first positioning elements 5. In this case, the C-shaped steel plate 4 has a front plate 41, two side plates 42 on two sides of the front plate 41 and two flanges 43, respectively extending toward each other from the free sides of the side plates 42. An opening 45 is formed between the two flanges 43. The first positioning element 5 has a first lower surface 51 in a rectangular shape, and the first side walls 53 are respectively extended from the four edges of the first lower surface 51 in the same direction. When assembling the holes 45 of the two C-shaped steel plates 4 are opposite to each other.

Next, the first two positioning elements 5 are respectively located at the two ends of the two C-shaped steel plates 4 in the longitudinal direction of the C-shaped steel plates 4. Thus, the first side walls 53 of the first positioning element 5 correspond to the front plates 41 and side plates 42 of the two C-shaped steel plates 4. In addition, the two opposite first side walls 53 of the first side walls 53 respectively have a gap 52 and a shutter 57 between the clearances 52. The clearances 52 and the shutter (shutter) 57 correspond to the flanges 43 of the C-arr. of the steel plates 4. The gaps 52 are for inserting the flanges 43 of the C-shaped steel plates 4, so that the shutter 57 is designed to limit the flanges 43 of the C-shaped steel plates 4, so that the two separation gaps 22 are respectively formed on two opposite sides of the two opposite C-shaped steel plates 4. Then, the first side walls 53 of the first positioning elements 5 are locked with the front plates 41 and the corresponding side plates 42 of the C-shaped steel plates 4 with several locking elements 6 for the formation of a beam 2 of rectangular tubular shape. Therefore, the first lower surface 51 of the first positioning element 5 is located on the end surface of the beam 2 to create a combination point 21 for connection with other beams 2. Thus, several beams 2 are combined with each other using combination points 21 and several locking elements 6 and formed as transverse beams 11 and columns 12 of building 1.

When the beam 2 is long, the first few positioning elements 5 can be locked in suitable sections between the two ends of the two C-shaped steel plates 4 in the longitudinal direction of the C-shaped steel plates 4. Therefore, the beam 2 may have bamboo-connecting structures to increase structural strength of the beam 2. Accordingly, the supporting efficiency of the beams 11 and the columns 12 formed by the beams 2 can be improved.

In addition, the wire hole 56 is located in the center of the first lower surface 51 of the first positioning element 5. Thus, electrical cables, network cables or telephone wires can be inserted into the wire hole 56 and received in the crossbars 11 or columns 12. Accordingly, the cross beams 11 and columns 12 can not only have a beautiful appearance, but can also protect wires and cables.

Rafter 3 contains a C-shaped steel plate 4 and at least two second positioning elements 7. The structure of the C-shaped steel plate 4 for forming the rafter 3 is the same as that of the C-shaped steel plate 4 for forming the beam 2. The second positioning element 7 has a second lower surface 71 and second side walls 72, respectively, protruding from three interconnected ribs (edges) of the second lower surface 71 in the same direction. The second side walls 72 of the second positioning element 7 are locked with the front plate 41 and the side plates 42 of the C-shaped steel plates 4 with several locking elements 6 to form the rafter 3. The second lower surface 71 of the second positioning element 7 is located on the end surface of the rafter 3 to form assembly point 31. Thus, the two ends of each of the rafters 3 can be mounted between adjacent beams 2. Accordingly, the rafters 3 can serve as a support frame for the surface of the floor 13, p surface of wall 14 and roof 15 of the building 1.

In this embodiment, the locking element 6 is an assembly of the inserted nut 61 and the bolt 62. During operation, the holes 46, 55, 73 open on the C-shaped steel plates 4, the first positioning elements 5 and the second positioning elements 7. Then, the inserted nuts 61 are correctly installed in holes 46, 55, 73. Next, the bolts 62 are inserted into the inserted nuts 61 and are located with the inserted nuts 61.

Accordingly, when assembling the building 1, the number and size of the C-shaped steel plates 4, as well as the number of the first positioning element 5 and the second positioning element 7 can be calculated in advance in accordance with the structure of the building 1. Thus, these components can be manufactured in a factory and then transported to the construction site.

At the construction site, several beams 2 are connected to each other using combination points 21 formed on the first lower surfaces 51 of the first positioning elements 5, and are formed as crossbars 11 and columns 12 of the building structure 1. In detail FIG. 6 is a schematic exploded view showing how the crossbar 11 should be assembled with the column 12. As shown, the front plate 41 of one of the C-shaped steel plates 4 of the standing beam 2 is locked to the first lower surface 51 of the first positioning member 5 of the lying beam 2 by locking elements 6, and two C-shaped steel plates 4 of the lying beam 2 are blocked on the first side wall 53 of the first positioning element 5 by the locking elements 6. Accordingly, the standing beam 2 and the lying beam 2 can be soy ineny with each other to be made in the form of transverse beams 11 and columns 12 of the building 1.

When the assembly of the crossbeams 11 and the columns 12 of the building 1 is completed, the support frame of the surface of the floor 13, the surface of the walls 14 and the roof 15 of the building 1 can be assembled using rafters 3. As an example, the surface of the wall 14, as shown in FIG. 7, the assembly points 31 of the second positioning elements 7 at both ends of the rafter 3 are attached to the C-shaped steel plates 4 of the beam 2, and the second positioning elements 7 of the rafter 3 and the C-shaped steel plates 4 of the beam 2 are locked to each other by the locking elements 6. Then, the two ends of the C-shaped steel plate 4 of the rafters 3 are locked with the second side walls 72 of the second positioning element 7 using the locking elements 6. Accordingly, the supporting frame of the surface of the wall 14 can be formed by several rafters 3, and the following plate sealing procedures can be performed on the support frame of the wall surface 14 to create the wall surface 14 of the building 1. Similarly, the support frame of the floor surface 13 and the roof 15 of the building 1 can be assembled using rafters 3.

When the roof of building 1 has a sloping surface, as shown in FIG. 8, the end surface of the beam 2 and rafters 3, assembled on both sides of the roof column 12, as well as from the end surface of the beam 2 to support the roof, can be cut to have an inclined plane for joining the inclined surface of the roof. Thus, a roof with a sloping surface can be assembled using beams 2 and rafters 3 through connecting points 21 formed on the first positioning elements 5 and through assembly points 31 formed on the second positioning elements 7. Thus, no additional components are required when roof construction. Therefore, the assembly of the building 1 may be convenient.

Based on the foregoing, in the present invention, the two ends of the C-shaped steel plates are arranged with positioning elements for forming transverse beams, columns or rafters. Then, any two of the above components are further connected to each other by means of positioning elements. Thus, C-shaped steel plates can be formed as the basis of a light steel building by blocking in a quick and convenient way.

In addition, in the present invention, C-shaped steel plates are assembled with the first and second positioning elements to form the beams, columns and rafters of the building, and then the transverse beams (traverses), columns and rafters are assembled with each other using the first and second positioning elements . Thus, builders can pre-calculate the number and size of C-shaped steel plates, as well as the number of first positioning elements and second positioning elements using a computer program. Thus, components for building a building can be manufactured at the factory using a one-time process, and then the components are transported to the construction site. Accordingly, the construction procedures at the construction site can be simplified to increase the efficiency of the installation of the building.

In addition, since the first positioning elements and the second positioning elements are located on the end surfaces of the two ends of the cross member (or column, or rafters), the angle of the end surface of the transverse beam (or column, or rafters) can be changed to assemble a roof or cornices having an inclined surface without additional components. Thus, the assembly of the building can be convenient.

In addition, two C-shaped steel plates are connected to each other to form a beam in a rectangular tubular shape using the first positioning elements, and the first positioning element has a wire hole. Therefore, cables or wires can be inserted into the inside of the beam and protected by C-shaped steel plates. In addition, a separation gap may be provided between the two C-shaped steel plates of the beam for ventilation and thermal insulation.

Claims (9)

1. Lightweight steel structure containing: at least two first positioning elements, respectively located at two ends of two opposite C-shaped steel plates in the longitudinal direction of the C-shaped steel plates for forming the beam in a rectangular tubular shape, the first positioning elements form respectively combined points on the two end surfaces of the beam, moreover, several beams are connected to each other using combined points and form the transverse beams and columns of the building; as well as at least two second positioning elements respectively arranged at two ends of the C-shaped steel plate in the longitudinal direction of the C-shaped steel plate to form the rafters, the second positioning elements form respectively the assembly points on the two end surfaces of the rafters, with several rafters located between adjacent beams through assembly points and are made in the form of a floor surface, wall surface and building roof. 2. The light steel structure according to claim 1, in which each of the C-shaped steel plates of the beam has a front plate, two side plates on two sides of the front plate and two flanges, respectively, extending towards each other from the free sides of the side plates, an opening is formed between the two flanges, each of the first positioning elements having a first lower surface and first side walls, respectively extending from the four edges of the first lower surface in the same direction, For the first time, the side walls of the first positioning elements are blocked by the front plates and the corresponding side plates of the C-shaped steel plates to form the beam using the locking elements, the first lower surfaces of the first positioning elements correspondingly located on the end surfaces of the beam to form combining points so that several beams are connected to each other by means of locking elements and formed transverse beams and columns of the building. 3. The light steel structure according to claim 1, wherein the two opposite first side walls of the first side walls of the first positioning element respectively have gaps and a flap between the gaps, the gaps being designed to insert flanges of a C-shaped steel plate of the beam, and the transverse plate is intended to limit the flanges of the C-shaped steel plates of the beam so that two separation gaps are respectively formed on two opposite sides of the beam. 4. The light steel structure according to claim 2, in which a wire hole is made in the center of the first lower surface of the first positioning element. 5. The light steel structure according to claim 2, in which each of the locking elements comprises an inserted nut and bolt, the front plate and side plates of the C-shaped steel plate of the beam, as well as the first lower surface and the first side walls of the first positioning element, respectively, have holes moreover, the holes are designed to accommodate inserted nuts and inserted bolts. 6. The light steel structure according to claim 1, in which the C-shaped steel rafter plate has a front plate, two side plates on two sides of the front plate and two flanges, respectively, extending towards each other from the free sides of the side plates, and between two flanges form an opening for accommodating a second positioning element, each of the second positioning elements having a second lower surface and second side walls, respectively, extending from three connected between both ribs of the second lower surface in the same direction, the second side walls of the second positioning element being fixed with the front plate and the side plates of the C-shaped steel plate with the formation of the rafters using locking elements, the second lower surfaces of the second positioning elements correspondingly located on the end surfaces of the rafters with the formation of assembly points, the second lower surface having several through holes so that the two ends of each of the rafters are assembled I wait for adjacent beams through the through holes and fixing elements, as well as rafters made in the form of a floor surface, surface of the walls and roof of the building. 7. The light steel structure according to claim 6, in which each of the locking elements comprises an inserted nut and bolt, the front plate and side plates of the C-shaped steel rafter plate, as well as the second lower surface and second side walls of the second positioning element, respectively, have holes moreover, the location of these holes of the C-shaped steel plate corresponds to the location of these holes of the second positioning element, and the holes are designed to accommodate the inserted nuts and insertable bolts.

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