CN217974792U - Energy-saving anti-seismic light steel structure - Google Patents

Abstract

The utility model discloses an energy-conserving antidetonation light gauge steel structure relates to building structure technical field. The utility model discloses a mounting bracket, the inboard of mounting bracket is provided with body frame subassembly and side bearer subassembly respectively, and the body frame subassembly is including first I-steel, first slider and first locating hole, and the side bearer subassembly is including second I-steel, trapezoidal link and high strength bolt, and the inboard of mounting bracket is provided with a plurality of first I-steels, and the both ends of a plurality of first I-steels are provided with a plurality of second I-steels, and the one end that first I-steel was kept away from to every second I-steel all is provided with trapezoidal link. The utility model discloses an inboard fixed strengthening frame of first I-steel and second I-steel for form a plurality of triangular structure between first I-steel and strengthening frame, second I-steel and the strengthening frame, and then effectively promote its tensile, bending resistance and shear strength, make it can bear vertical and horizontal load, anti-seismic performance is excellent.

Description

Energy-saving anti-seismic light steel structure

Technical Field

The utility model belongs to the technical field of building structure, especially, relate to an energy-conserving antidetonation light-duty steel construction.

Background

The light steel structure is a building structure, it regards steel as the residential building of the bearing beam column of the building, it has advantages such as light, intensity, etc., the light steel structural member is generally made in the factory, in order to reduce the work load on the spot, shorten the construction cycle;

for example, the application number of the light steel structure for the building is CN201921612711.9, the light steel structure for the building adopts that cushion blocks are arranged on the upper surface and the lower surface of a steel frame, slots are formed in the cushion blocks, then the second plug-in component is inserted into the slots, the sleeve is in threaded rotary connection with the outer wall of the second plug-in component, then the outer wall of the sleeve is in rotary connection with the inner wall of the side component, and then the external member is in threaded rotary connection with the outer walls of the sleeve and the side component, so that the second plug-in component and the steel frame are in effective sleeved connection with the sleeve through the external member;

however, in the actual use process of the light steel structure in the patent, the supporting member is only a single steel frame, so that the shock resistance of the light steel structure is poor, and meanwhile, the heat preservation performance and the sound insulation performance of the light steel structure are poor, so that the energy is not saved.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an energy-conserving light-duty steel construction of antidetonation to solve the problem that proposes in the above-mentioned background art.

In order to solve the technical problem, the utility model discloses a realize through following technical scheme: the utility model provides an energy-conserving antidetonation light steel structure, includes the mounting bracket, the inboard of mounting bracket is provided with body frame subassembly and side bearer subassembly respectively, the body frame subassembly is including first I-steel, first slider and first locating hole, the side bearer subassembly is including second I-steel, trapezoidal link and the bolt that excels in, the inboard of mounting bracket is provided with a plurality of first I-steel, every first locating hole has all been seted up to four end angle departments on first I-steel top, every four end angle departments of first I-steel bottom all are fixed with first slider, and are a plurality of the both ends of first I-steel are provided with a plurality of second I-steel, every first locating hole has all been seted up to four end angle departments on second I-steel top, every four end angle departments of second I-steel bottom also all are fixed with first slider, first slider and first locating hole sliding connection, every the one end that first I-steel was kept away from to the second I-steel is provided with trapezoidal link, every four end angle departments that trapezoidal link is close to one end all are provided with the bolt that excels in, the mounting bracket passes through the both sides fixed bolt that excels in and the second I-steel both sides fixed connection and the mounting bracket, there are located the both sides fixed bolt that excels in and the second I-steel both sides fixed link.

The main frame assembly further comprises a reinforcing frame, second sliders, second positioning holes, an upper steel frame and a lower steel frame, an upper steel frame is arranged at the upper end of the first I-beams, a lower steel frame is arranged at the lower ends of the first I-beams, first sliders are fixed at four end corners of the bottom end of the upper steel frame, first positioning holes are formed at four end corners of the top end of the lower steel frame, the reinforcing frame is fixed at the upper end and the lower end of the inner side of each first I-beam, four second sliders are fixed at two ends of each first I-beam and between the two reinforcing frames, two second positioning holes are formed at two ends of the upper end and the lower end of each first I-beam, the reinforcing frames are fixed at the inner sides of the upper steel frame and the lower steel frame, two second sliders are fixed at two ends of the upper end of the upper steel frame, two second positioning holes are formed at two ends of the upper end of the lower steel frame, and two second sliders are fixed at two ends of the lower end of the lower steel frame.

Further, the inner side of each trapezoidal connecting frame is provided with a trapezoidal sound insulation layer.

Furthermore, reinforcing frames are fixed to the upper end and the lower end of the inner side of each second I-steel, four second sliding blocks are fixed to the two ends of each second I-steel and located between the two reinforcing frames, two second positioning holes are formed in the two ends of the upper end and the lower end of each second I-steel, and the second sliding blocks are connected with the second positioning holes in a sliding mode.

Further, I-shaped heat preservation layers are arranged on the inner sides of the first I-shaped steel and the second I-shaped steel.

Furthermore, a triangular heat-insulating layer is arranged on the inner side of each first I-shaped steel and between the first I-shaped steel and the reinforcing frame, and a triangular heat-insulating layer is arranged on the inner side of each second I-shaped steel and between the second I-shaped steel and the reinforcing frame.

Further, go up the inboard of steelframe and be located and all be provided with the triangle heat preservation between steelframe and the strengthening frame, the inboard of steelframe down just is located and also all is provided with the triangle heat preservation between steelframe and the strengthening frame down.

The utility model discloses following beneficial effect has:

1. the utility model discloses a holistic structure cooperation design, make through first slider between body frame subassembly and the side bearer subassembly, first locating hole, second slider and second locating hole conveniently fix a position and assemble, conveniently make it unable to remove to both sides to it after the equipment finishes simultaneously, body frame subassembly and side bearer subassembly after conveniently will assembling through high strength bolt are fixed with the mounting bracket, and then carry out spacing fixed to its both ends, and through welding two limiting plates in the both sides of mounting bracket after fixed, and then thoroughly avoid body frame subassembly and side bearer subassembly to break away from the mounting bracket is inboard, through the inboard reinforcing frame of fixing of first I-steel and second I-steel, make first I-steel and reinforcing frame, form a plurality of triangular structure between second I-steel and the reinforcing frame, and then effectively promote its tensile, bending resistance and shear strength, make it can bear vertical and horizontal load, anti-seismic performance is excellent.

2. The utility model discloses a structural design of I-shaped heat preservation, triangle heat preservation and trapezoidal puigging for effectively promote heat preservation, the sound insulation performance of this structure in the in-service use, it is energy-conserving effectual, and because first I-steel and second I-steel inboard all are provided with I-steel heat preservation and triangle heat preservation, make and to reduce the material when first I-steel of production preparation and second I-steel, whole dead weight is light.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments are briefly introduced below, it is obvious that the drawings in the description below are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a schematic structural view of the inner side of the mounting rack of the present invention;

FIG. 3 is a schematic view of the main frame assembly and the side frame assembly of the present invention;

fig. 4 is an exploded view of the main frame assembly of the present invention;

FIG. 5 is an exploded view of the side frame assembly of the present invention;

fig. 6 is an exploded view of the inner side of the first i-steel of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

1. a mounting frame; 2. a limiting plate; 3. a first I-steel; 4. an I-shaped heat insulation layer; 5. a reinforcing frame; 6. a triangular heat-insulating layer; 7. a first slider; 8. a first positioning hole; 9. a second slider; 10. a second positioning hole; 11. an upper steel frame; 12. a lower steel frame; 13. a second I-steel; 14. a trapezoidal connecting frame; 15. a high-strength bolt; 16. trapezoidal puigging.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-6, the present invention relates to an energy-saving anti-seismic light steel structure, which comprises an installation frame 1, wherein the inner side of the installation frame 1 is respectively provided with a main frame component and a side frame component, the main frame component comprises first i-beams 3, first positioning holes 7 and first positioning holes 8, the inner side of the installation frame 1 is provided with a plurality of first i-beams 3, in order to facilitate the positioning and assembling among the first i-beams 3, four end angles at the top end of each first i-beam 3 are respectively provided with a first positioning hole 8, four end angles at the bottom end of each first i-beam 3 are respectively fixed with a first slider 7, the first sliding block 7 is connected with the first positioning hole 8 in a sliding mode, the main frame assembly further comprises a reinforcing frame 5, a second sliding block 9, a second positioning hole 10, an upper steel frame 11 and a lower steel frame 12, in order to be matched with the side frame assembly to be attached to the mounting frame 1 conveniently, the upper steel frame 11 is arranged at the upper end of each first I-shaped steel 3, the lower steel frame 12 is arranged at the lower end of each first I-shaped steel 3, in order to be convenient for assembling the upper steel frame 11 and the lower steel frame 12 with the first I-shaped steels 3, the first sliding block 7 is fixed at four end corners at the bottom end of the upper steel frame 11, and the first positioning hole 8 is formed at four end corners at the top end of the lower steel frame 12;

in order to effectively improve the tensile strength, the bending strength and the shear strength of the first I-steel 3, the upper steel frame 11 and the lower steel frame 12 and enable the first I-steel 3, the upper steel frame 11 and the lower steel frame 12 to bear vertical and horizontal loads, the upper end and the lower end of the inner side of each first I-steel 3 are respectively fixed with a reinforcing frame 5, and the inner sides of the upper steel frame 11 and the lower steel frame 12 are respectively fixed with a reinforcing frame 5;

in order to assemble the main frame assembly and the side frame assembly conveniently, four second sliders 9 are fixed at two ends of each first I-beam 3 and between the two reinforcing frames 5, two second positioning holes 10 are formed at two ends of the upper end and the lower end of each first I-beam 3, two second sliders 9 are fixed at two ends of the upper end of the upper steel frame 11, two second positioning holes 10 are formed at two ends of the upper end of the lower steel frame 12, two second positioning holes 10 are formed at two ends of the lower end of the upper steel frame 11, two second sliders 9 are fixed at two ends of the lower end of the lower steel frame 12, and the second sliders 9 are in sliding connection with the second positioning holes 10;

in order to improve the overall strength by matching with the main frame assembly, the side frame assembly comprises second I-beams 13, a trapezoid connecting frame 14 and a high-strength bolt 15, a plurality of second I-beams 13 are arranged at two ends of the first I-beams 3, in order to facilitate positioning and assembling of the second I-beams 13, first positioning holes 8 are formed in four end corners of the top end of each second I-beam 13, and first sliding blocks 7 are fixed at four end corners of the bottom end of each second I-beam 13;

in order to effectively improve the tensile strength, the bending strength and the shear strength of the second I-beams 13, reinforcing frames 5 are fixed at the upper end and the lower end of the inner side of each second I-beam 13, so that the side frame assembly and the main frame assembly can be conveniently assembled, four second sliding blocks 9 are fixed at two ends of each second I-beam 13 and between the two reinforcing frames 5, and two second positioning holes 10 are formed at two ends of the upper end and the lower end of each second I-beam 13;

after the main frame assembly and the side frame assembly are assembled, the main frame assembly and the side frame assembly are fixed to an installation frame 1 conveniently, a trapezoid connecting frame 14 is arranged at one end, away from a first I-steel 3, of each second I-steel 13, the trapezoid connecting frame 14 and the second I-steel 13 are positioned and assembled conveniently, each trapezoid connecting frame 14 and the second I-steel 13 are connected in a sliding mode through a second sliding block 9, in order to effectively improve the sound insulation performance of the structure, a trapezoid sound insulation layer 16 is arranged on the inner side of each trapezoid connecting frame 14, high-strength bolts 15 are arranged at four end corners, close to one end of the installation frame 1, of each trapezoid connecting frame 14, the trapezoid connecting frames 14 are fixedly connected with the installation frame 1 through the high-strength bolts 15, in order to limit and fix the main frame assembly and the side frame assembly conveniently, and limiting plates 2 are fixed to two sides of the installation frame 1 and two sides of the first I-steel 3 and the second I-steel 13;

in order to effectively improve the heat insulation performance of the structure, the inner sides of each first I-shaped steel 3 and each second I-shaped steel 13 are provided with an I-shaped heat insulation layer 4, the inner side of each first I-shaped steel 3 is positioned between the first I-shaped steel 3 and the reinforcing frame 5 and is provided with a triangular heat insulation layer 6, the inner side of each second I-shaped steel 13 is positioned between the second I-shaped steel 13 and the reinforcing frame 5 and is also provided with a triangular heat insulation layer 6, the inner side of the upper steel frame 11 is positioned between the upper steel frame 11 and the reinforcing frame 5 and is provided with a triangular heat insulation layer 6, and the inner side of the lower steel frame 12 is positioned between the lower steel frame 12 and the reinforcing frame 5 and is also provided with a triangular heat insulation layer 6.

One specific application of this embodiment is: when the first I-steel 3 and the second I-steel 13 are manufactured in a factory, the reinforcing frame 5 is respectively fixed on the inner sides of the first I-steel 3 and the second I-steel 13, so that the tensile strength, the bending strength and the shear strength of the first I-steel are effectively improved, the first I-steel 3 can bear vertical and horizontal loads, and the anti-seismic performance is excellent, before the structure is actually put into use, the first I-steel 3 is assembled, the first I-steel 3 is conveniently positioned and further conveniently assembled through the sliding connection of the first sliding block 7 and the first positioning hole 8, the upper steel frame 11 is assembled at the upper ends of the first I-steel 3, the lower steel frame 12 is assembled at the lower ends of the first I-steel 3, the assembly of the main frame assembly is completed, the second I-steel 13 is placed at the two ends of the first I-steel 3, and then make things convenient for and carry out the location equipment between first I-steel 3 and the second I-steel 13 through the sliding connection between second slider 9 and the second locating hole 10, assemble trapezoidal link 14 with second I-steel 13 through second slider 9 and second locating hole 10 at last equally, accomplish the equipment between side bearer subassembly and the body frame subassembly, make its each component can only move to both ends and can't move to both sides or reciprocate, fill I-shaped heat preservation 4, triangle heat preservation 6 and trapezoidal puigging 16 respectively in body frame subassembly and the subassembly, promote overall structure's heat preservation, the sound insulation performance, the side bearer passes through high strength bolt 15 and fixes mounting bracket 1 in the outside of side bearer subassembly at last, carry out spacing fixed to its both ends, fix limiting plate 2 in the both sides of mounting bracket 1, seal body frame subassembly and side bearer subassembly.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the present invention disclosed above are intended only to help illustrate the present invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best understand the invention for and utilize the invention. The present invention is limited only by the claims and their full scope and equivalents.

Claims (7)

1. The utility model provides an energy-conserving light-duty steel construction of antidetonation, includes mounting bracket (1), its characterized in that: the inner side of the mounting frame (1) is respectively provided with a main frame assembly and a side frame assembly, the main frame assembly comprises first I-shaped steels (3), first sliders (7) and first positioning holes (8), the side frame assembly comprises second I-shaped steels (13), a trapezoid connecting frame (14) and high-strength bolts (15), the inner side of the mounting frame (1) is provided with a plurality of first I-shaped steels (3), each first positioning hole (8) is formed in each of four end corners of the top end of the first I-shaped steel (3), each first slider (7) is fixed at each of the four end corners of the bottom end of the first I-shaped steel (3), a plurality of second I-shaped steels (13) are arranged at two ends of the first I-shaped steel (3), each first positioning hole (8) is also formed in each of the four end corners of the top end of the second I-shaped steel (13), each first slider (7) is fixed at each of the four end corners of the bottom end of the second I-shaped steel (13), each first slider (7) is connected with each first positioning hole (8), each trapezoid bolt (14) is connected with each trapezoid bolt (14), each trapezoid bolt (14) and each trapezoid connecting frame (14) is arranged at one end corner of the first I-shaped steel (3), limiting plates (2) are fixed on two sides of the mounting frame (1) and two sides of the mounting frame, which are located on the first I-shaped steel (3) and the second I-shaped steel (13).

2. An energy-saving anti-seismic light steel structure according to claim 1, characterized in that: the main frame component also comprises a reinforcing frame (5), a second sliding block (9), a second positioning hole (10), an upper steel frame (11) and a lower steel frame (12), the upper ends of the first I-shaped steels (3) are provided with the upper steel frame (11), the lower ends of the first I-shaped steels (3) are provided with the lower steel frame (12), first sliding blocks (7) are fixed at four end corners of the bottom end of the upper steel frame (11), four end corners at the top end of the lower steel frame (12) are respectively provided with a first positioning hole (8), the upper end and the lower end of the inner side of each first I-shaped steel (3) are respectively fixed with a reinforcing frame (5), two second sliding blocks (9) are respectively fixed at two ends of each first I-shaped steel (3) and between the two reinforcing frames (5), two second positioning holes (10) are respectively arranged at two ends of the upper end and the lower end of each first I-shaped steel (3), the inner sides of the upper steel frame (11) and the lower steel frame (12) are both fixed with a reinforcing frame (5), two second sliding blocks (9) are fixed at two ends of the upper end of the upper steel frame (11), two second positioning holes (10) are respectively arranged at the two ends of the upper end of the lower steel frame (12), two second positioning holes (10) are respectively arranged at two ends of the lower end of the upper steel frame (11), two second sliding blocks (9) are fixed at two ends of the lower end of the lower steel frame (12).

3. An energy-saving anti-seismic light steel structure according to claim 1, characterized in that: the inner side of each trapezoidal connecting frame (14) is provided with a trapezoidal sound insulation layer (16).

4. An energy-saving earthquake-resistant light steel structure according to claim 2, characterized in that: reinforcing frames (5) are also fixed to the upper end and the lower end of the inner side of each second I-shaped steel (13), four second sliding blocks (9) are also fixed to the two ends of each second I-shaped steel (13) and located between the two reinforcing frames (5), two second positioning holes (10) are also formed in the two ends of the upper end and the lower end of each second I-shaped steel (13), and the second sliding blocks (9) are connected with the second positioning holes (10) in a sliding mode.

5. An energy-saving anti-seismic light steel structure according to claim 4, characterized in that: and I-shaped heat preservation layers (4) are arranged on the inner sides of the first I-shaped steel (3) and the second I-shaped steel (13).

6. An energy-saving anti-seismic light steel structure according to claim 4, characterized in that: each triangle heat preservation layer (6) is arranged on the inner side of the first I-shaped steel (3) and between the first I-shaped steel (3) and the reinforcing frame (5), and each triangle heat preservation layer (6) is also arranged on the inner side of the second I-shaped steel (13) and between the second I-shaped steel (13) and the reinforcing frame (5).

7. An energy-saving anti-seismic light steel structure according to claim 2, characterized in that: go up the inboard of steelframe (11) and be located and all be provided with triangle heat preservation (6) between steelframe (11) and strengthening frame (5), the inboard of lower steelframe (12) and be located down also all be provided with triangle heat preservation (6) between steelframe (12) and strengthening frame (5).

Images