CN221034362U - Building supporting structure - Google Patents

Abstract

The application relates to the technical field of supporting structures, in particular to a building supporting structure which comprises a cross rod, wherein two hanging rods are inserted into the cross rod, the upper end of each hanging rod is connected with a connecting rod in a threaded manner, the upper end of each connecting rod is connected with a first expansion screw in a threaded manner, the outer surface of each hanging rod is sleeved with a first fixing plate and a second fixing plate, and the lower end of each first fixing plate is clamped with the cross rod. The application can be through being provided with the horizontal pole, the diagonal rod, the connecting plate I and the connecting plate II, when the device is used, the connecting plate I and the connecting plate II are respectively arranged at the two ends of the diagonal brace, the diagonal rod is connected with the horizontal pole through the connecting plate I, the diagonal rod is connected with the wall through the connecting plate II, and the horizontal wave vibration force and the horizontal vibration force generated by earthquake are counteracted through arranging a plurality of diagonal rods, so that the supporting structure has good damping effect.

Description

Building supporting structure

Technical Field

The application relates to the technical field of supporting structures, in particular to a building supporting structure.

Background

The building structure refers to a system which is formed by various components (roof truss, beam, plate, column and the like) and can bear various actions in building construction, wherein the actions refer to various factors which can cause the system to generate internal force and deformation, such as load, earthquake, temperature change, foundation settlement and the like, and in the building engineering construction process, a damping device is generally used for installing electric equipment or a ventilating duct so as to prevent the equipment from being damaged in the earthquake.

The supporting structure in the prior art usually only uses the vertical rod to support, so that the supporting structure can only resist partial vibration force (longitudinal wave) in the vertical direction, if the supporting structure is greatly rocked or vibrated to easily break or deform, the supporting structure is damaged, and when the supporting structure is damaged, the building is caused to fall, so that not only is the economy lost, but also the personal safety is threatened.

Disclosure of utility model

In order to increase the stability of the supporting structure and enable the supporting structure to have a good damping effect, the application provides the building supporting structure.

The application provides a building support structure, which adopts the following technical scheme: including the horizontal pole, peg graft in the inside of horizontal pole has two jib, every the equal threaded connection of upper end of jib has the connecting rod, every the upper end threaded connection of connecting rod has the inflation screw first, every the surface of jib has all cup jointed fixed plate first and two fixed plates second, every the lower extreme of fixed plate first all with the looks joint of horizontal pole, every the equal fixedly connected with connecting plate first of surface of fixed plate second, every the diagonal bar is all installed to the top of connecting plate first, every connecting plate second is all installed to the upper end of diagonal bar, every connecting plate second is kept away from the equal fixedly connected with mounting panel of a side of horizontal pole, every the inflation screw second is all installed to the inside of mounting panel.

Optionally, draw-in groove one has been seted up to the inside of horizontal pole, the inner wall sliding connection of draw-in groove one has four cardboard one, every the equal threaded connection of surface of cardboard one has the bolt one.

Optionally, two pipe hoops are arranged above the cross rod, the outer surface of each pipe hoop is fixedly connected with two fixing plates III, and the outer surface of each bolt I is spliced with the corresponding fixing plate three phases.

Optionally, two longitudinal bars are arranged above the cross bar, and a clamping groove II is formed in each longitudinal bar.

Optionally, the inside of every draw-in groove two all sliding connection has V type clamping device, every V type clamping device all uses bolt two to be connected with the vertical pole.

Optionally, the inside of every the diagonal bar has all offered draw-in groove three, every the inside of draw-in groove three is all sliding connection has the cardboard second, every the inside of cardboard second is all threaded connection has the bolt third, every the inside of connecting plate one and connecting plate two all cup joints with the bolt three-phase that corresponds.

Optionally, the surface of every the jib has all cup jointed fixed plate IV, and every the surface of jib all threaded connection has bolt IV, every bolt IV all contacts with corresponding fixed plate IV.

In summary, the application has the following beneficial technical effects:

1. When the device is used, the first connecting plate and the second connecting plate are respectively arranged at two ends of the diagonal brace, the diagonal rods are connected with the cross bars through the first connecting plates, the diagonal rods are connected with the wall through the second connecting plates, and the diagonal rods are additionally arranged to offset transverse wave vibration force and horizontal vibration force generated by an earthquake, so that the support structure achieves the aim of good damping effect.

2. According to the utility model, through the components such as the vertical rod, the V-shaped clamping device, the suspender, the connecting rod and the like, when the device is used, the first expansion screw needs to be driven into a wall body, the first expansion screw is connected with the suspender through the fixed connecting rod, then the cross rod is fixed on the suspender through the bolt IV and the fixing plate IV, the vertical rod is fixed through the V-shaped clamping device, the vertical supporting force is provided through the suspender, the vertical vibration force generated by an earthquake is counteracted through the installation of the vertical rod, and therefore the purpose of increasing the damping effect of the supporting structure is achieved.

Drawings

FIG. 1 is a schematic view of an overall three-dimensional structure in an embodiment of the application;

FIG. 2 is a schematic view of a front cross-sectional structure in an embodiment of the present application;

FIG. 3 is an enlarged schematic view of the structure shown at A in FIG. 2 in accordance with an embodiment of the present application;

fig. 4 is an enlarged schematic view of the structure at B in fig. 2 according to an embodiment of the present application.

Reference numerals: 1. a cross bar; 2. a boom; 3. a connecting rod; 4. an expansion screw I; 5. a first fixing plate; 6. a second fixing plate; 7. a first connecting plate; 8. a diagonal rod; 9. a second connecting plate; 10. a mounting plate; 11. an expansion screw II; 12. a clamping groove I; 13. a clamping plate I; 14. a first bolt; 15. a fixing plate III; 16. a pipe clamp; 17. a longitudinal bar; 18. a clamping groove II; 19. a V-shaped clamping device; 20. a second bolt; 21. a clamping groove III; 22. a second clamping plate; 23. a third bolt; 24. a fixing plate IV; 25. and a bolt IV.

Detailed Description

The application is described in further detail below with reference to fig. 1-4.

The embodiment of the application discloses a building support structure. As shown in fig. 1-4, the horizontal rod 1 is included, a clamping groove one 12 is formed in the horizontal rod 1, four clamping plates one 13 are slidably connected to the inner wall of the clamping groove one 12, bolts one 14 are connected to the outer surface of each clamping plate one 13 in a threaded mode, the outer surface of each bolt one 14 is connected with a corresponding fixing plate three 15 in an inserting mode, a transverse supporting effect is provided through the arranged horizontal rod 1, the inclined rod 8 is convenient to install, the clamping plates one 13 can be conveniently fixed by the bolts one 14 through the clamping groove one 12, and plugs are required to be installed at two ends of the horizontal rod 1.

Referring to fig. 2, 3 and 4, two pipe clamps 16 are arranged above the cross rod 1, two fixing plates three 15 are fixedly connected to the outer surface of each pipe clamp 16, the outer surface of each bolt one 14 is spliced with the corresponding fixing plate three 15, two longitudinal rods 17 are arranged above the cross rod 1, clamping grooves two 18 are formed in the longitudinal rods 17, V-shaped clamping devices 19 are slidably connected to the inner parts of the clamping grooves two 18, each V-shaped clamping device 19 is connected with the longitudinal rods 17 through bolts two 20, the pipe clamp 16 can be conveniently fixed through the pipe clamp 16, the pipe clamp 16 can be conveniently fixed through the fixing plates three 15 and the bolts one 14, the vertical vibration force generated by vibration can be counteracted through the longitudinal rods 17, and the longitudinal rods 17 can be conveniently fixed with the hanging rods 2 through the V-shaped clamping devices 19 and the bolts two 20.

Referring to fig. 2 and 3, two hanging rods 2 are inserted into the cross rod 1, four fixing plates 24 are sleeved on the outer surface of each hanging rod 2, four bolts 25 are connected to the outer surface of each hanging rod 2 in a threaded mode, each four bolt 25 is in contact with the corresponding four fixing plates 24, main vertical supporting force can be provided through the arranged hanging rod 2, the bottom of the cross rod 1 can be conveniently fixed through the arranged four fixing plates 24, and the four fixing plates 24 can be conveniently fixed through the arranged four bolts 25.

Referring to fig. 1 and 2, the upper end of each suspender 2 is connected with a connecting rod 3 in a threaded manner, the upper end of each connecting rod 3 is connected with an expansion screw 4 in a threaded manner, the outer surface of each suspender 2 is sleeved with a fixing plate 5 and two fixing plates 6, the lower end of each fixing plate 5 is clamped with a cross rod 1, the outer surface of each fixing plate 6 is fixedly connected with a connecting plate 7, an inclined rod 8 is arranged above each connecting plate 7, the suspender 2 can be conveniently fixed through the connecting rod 3, the suspender 2 and the connecting rod 3 can be conveniently installed through the expansion screw 4, the fixing plates 6 can be conveniently and horizontally installed through the fixing plates 5, the cross rod 1 and the inclined rod 8 can be conveniently connected through the fixing plates 6 and the connecting plates 7, and transverse vibration force and horizontal vibration force generated by an earthquake can be reduced through the inclined rod 8.

Referring to fig. 1 and 2, a third clamping groove 21 is formed in each diagonal rod 8, a second clamping plate 22 is slidably connected in each third clamping groove 21, a third bolt 23 is screwed in each second clamping plate 22, a first connecting plate 7 and a second connecting plate 9 are sleeved with the corresponding third bolt 23, the second clamping plate 22 can be conveniently installed through the third clamping groove 21, and the first connecting plate 7 and the second connecting plate 9 can be conveniently connected with the diagonal rods 8 through the second clamping plate 22 and the third bolt 23.

Referring to fig. 1 and 2, the upper end of each diagonal rod 8 is provided with a second connecting plate 9, a side surface of each second connecting plate 9 far away from the cross rod 1 is fixedly connected with a mounting plate 10, an expansion screw 11 is arranged in each mounting plate 10, the mounting plates 10 can be conveniently connected through the second connecting plates 9, and the walls can be conveniently connected with the diagonal rods 8 through the mounting plates 10 and the expansion screws 11.

The implementation principle of the building support structure of the embodiment of the application is as follows: firstly, a boom 2 is installed to provide longitudinal supporting force, then a cross rod 1 is installed to provide horizontal supporting force, a plurality of diagonal rods 8 are installed to increase supporting force for the structure, a diagonal rod 8 and a longitudinal rod 17 are installed to provide damping effect for the structure, the installed diagonal rods 8 can reduce transverse vibration force and horizontal vibration force generated by earthquake, and a longitudinal rod 17 is installed to reduce vertical vibration force generated by earthquake, so that the structure has good damping effect while improving supporting stability.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (7)

1. Building support structure, comprising a cross bar (1), characterized in that: the inside grafting of horizontal pole (1) has two jib (2), every equal threaded connection of upper end of jib (2) has connecting rod (3), every the upper end threaded connection of connecting rod (3) has expansion screw one (4), every fixed plate one (5) and two fixed plate two (6) have all been cup jointed to the surface of jib (2), every the lower extreme of fixed plate one (5) all with horizontal pole (1) looks joint, every expansion screw two (11) are all installed to the equal fixedly connected with connecting plate one (7) of the surface of fixed plate two (6), every inclined rod (8) are all installed to the top of connecting plate one (7), every connecting plate two (9) are kept away from one side of horizontal pole (1) and are installed expansion screw two (11).

2. A building support structure according to claim 1, wherein: the novel cross bar is characterized in that a clamping groove I (12) is formed in the cross bar (1), four clamping plates I (13) are connected to the inner wall of the clamping groove I (12) in a sliding mode, and bolts I (14) are connected to the outer surface of each clamping plate I (13) in a threaded mode.

3. A building support structure according to claim 2, wherein: two pipe hoops (16) are arranged above the cross rod (1), the outer surface of each pipe hoop (16) is fixedly connected with two fixing plates III (15), and the outer surface of each bolt I (14) is spliced with the corresponding fixing plate III (15).

4. A building support structure according to claim 1, wherein: two longitudinal rods (17) are arranged above the cross rod (1), and clamping grooves (18) are formed in the longitudinal rods (17).

5. A building support structure according to claim 4, wherein: the inside of each clamping groove II (18) is connected with a V-shaped clamping device (19) in a sliding mode, and each V-shaped clamping device (19) is connected with the longitudinal rod (17) through a bolt II (20).

6. A building support structure according to claim 1, wherein: the inside of every diagonal bar (8) has all offered draw-in groove three (21), every the inside of draw-in groove three (21) is all sliding connection has cardboard two (22), every the inside of cardboard two (22) is all threaded connection has bolt three (23), every the inside of connecting plate one (7) and connecting plate two (9) all cup joints with corresponding bolt three (23).

7. A building support structure according to claim 1, wherein: the outer surface of each suspender (2) is sleeved with a fixing plate IV (24), the outer surface of each suspender (2) is connected with a bolt IV (25) in a threaded mode, and each bolt IV (25) is contacted with the corresponding fixing plate IV (24).