CN211523594U - Energy-consuming type connecting node for hanging steel column - Google Patents

Abstract

The utility model relates to a building structure node field specifically is a power consumption formula connected node for hanging steel column. The opening type damper is arranged between the first end plate and the second end plate, the opening direction of the opening type damper is horizontally arranged, one edge portion of the opening type damper is fixedly connected with the first end plate, the other edge portion of the opening type damper is fixedly connected with the second end plate, and a gap is formed between every two adjacent opening type dampers. Under the earthquake effect, when hanging the substructure floor and taking place great displacement between the layer, the upper portion hangs the steel column and probably take place great mutual dislocation with lower part, and great crooked horizontal migration can take place for U type attenuator this moment, and U type attenuator can dissipate a large amount of seismic energy at this in-process, reduces displacement between the layer to the harm of structure, improves the shock resistance of steel frame suspended structure system, reduces the potential safety hazard.

Description

Energy-consuming type connecting node for hanging steel column

Technical Field

The utility model relates to a building structure node field specifically is a power consumption formula connected node for hanging steel column.

Background

With the continuous development of construction technology, various novel structural forms appear, the giant steel frame suspension structural system is a novel structural system for suspending partial secondary structures on a main structure, the structural system gives full play to the tensile property of steel, reduces the influence of earthquake action on the structure, and generates excellent social and economic benefits.

In a giant steel frame suspended structure system, it is difficult to provide sufficient lateral force stiffness to the floor of the suspended substructure floor. Under the effect of wind load or earthquake load, the suspended substructures between floors and main structure floors possibly have large interlayer displacement difference between the substructures, and the connecting parts of the suspended steel columns between the substructures can be damaged, so that large potential safety hazards are caused.

Disclosure of Invention

In order to solve the technical problem, the utility model aims at providing an energy dissipation formula connected node for hanging the steel column can consume the energy that the earthquake produced, reduces the earthquake to the destruction that hangs the steel column and cause, reduces the potential safety hazard.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides an energy consumption formula connected node for hanging steel column, includes upper and lower parallel arrangement's first end plate and second end plate, be provided with opening type attenuator between first end plate and the second end plate, the opening direction level of opening type attenuator sets up for the energy of dissipation earthquake at the horizontal direction input, an limit portion and first end plate fixed connection of opening type attenuator, another limit portion and second end plate fixed connection of opening type attenuator, it is adjacent be provided with the clearance between the opening type attenuator for provide the deformation space for the opening type attenuator.

Further, the open type dampers are U-shaped dampers and are sequentially arranged along the horizontal direction; viscoelastic media are filled in the U-shaped damper, and spaces formed by the adjacent U-shaped dampers and the two end plates.

Further preferably, two adjacent U-shaped dampers with opposite opening directions form a group.

Further preferably, the first end plate, the second end plate and the U-shaped damper are fixed through first high-strength bolts, and the first high-strength bolts penetrate through the opening sides of the first end plate and the U-shaped damper and the second end plate.

Further, this power consumption formula connected node still includes the protective sheath that sets up in first end plate and second end plate tip.

Preferably, a clamping groove corresponding to the first high-strength bolt is formed in one side, facing the first high-strength bolt, of each protective sleeve, notches are formed in the upper end and the lower end of each clamping groove, and cylindrical bayonets are formed in the positions, along the height direction of the protective sleeves, of the clamping grooves;

the nut of the first high-strength bolt is located inside the notch, the width of the notch is slightly larger than that of the nut, and the rod portion of the first high-strength bolt is located inside the cylindrical bayonet.

Preferably, second high-strength bolts are connected between the first end plate and the U-shaped damper and between the second end plate and the U-shaped damper, and second bolt holes are formed in the positions of the second high-strength bolts;

the first high-strength bolt is positioned in the first bolt hole, and the position of the first high-strength bolt in the first bolt hole can be moved;

the minimum distance between the edge of the second bolt hole and the edge of the first bolt hole is larger than the thickness of the flange plate of the suspended steel column.

Further preferably, the U-shaped damper is made of SMA nickel titanium shape memory alloy.

The utility model has the advantages as follows:

(1) under the earthquake effect, when hanging the substructure floor and taking place great displacement between the layer, the upper portion hangs the steel column and probably take place great mutual dislocation with lower part, and great crooked horizontal migration can take place for U type attenuator this moment, and U type attenuator can dissipate a large amount of seismic energy at this in-process, reduces displacement between the layer to the harm of structure, improves the shock resistance of steel frame suspended structure system, reduces the potential safety hazard.

(2) Viscoelastic medium filled in the space formed by the inner part of the U-shaped damper, the adjacent U-shaped damper and the two end plates and the U-shaped damper deform cooperatively, and a large amount of seismic energy can be dissipated by mutual dislocation of layers in the viscoelastic medium.

(3) In order to ensure the safety of the whole structure, a certain gap is arranged between the U-shaped dampers which are arranged oppositely to each other, and a certain deformation space is provided for the U-shaped dampers.

(4) The energy-consuming type connecting node comprehensively adopts a U-shaped damper made of SMA (shape memory alloy), and the high damping characteristic of the SMA shape memory alloy can dissipate a large amount of seismic energy in the process.

When the node is subjected to larger bending horizontal movement under the action of an earthquake, due to the superelasticity of the SMA intelligent material, the node can be restored to the original state when the load is unloaded, and the node has certain self-resetting capability, so that the influence of the structure under the action of the earthquake is reduced.

(5) The first high-strength bolt penetrates through the first end plate, the second end plate and the U-shaped damper, so that the connecting node has certain strength, the connecting node is prevented from being insufficient in bearing capacity to connect a lower suspension steel column, and the reliability of the node is improved; because the attenuator becomes the U type setting, the connected node both ends can receive great pulling force and produce big deformation, and the effectual restraint of first high-strength bolt is out of shape this kind.

The first high-strength bolt that runs through all is equipped with fixation nut in first end plate, the second end plate outside and U type attenuator inboard, and inboard nut can prevent that connected node from probably receiving great pressure and being destroyed in the work progress, ensures that connected node is not destroyed in the work progress.

(6) The protective sheath sets up the cylindricality bayonet socket, and easy to assemble can prevent that the bolt from being damaged.

(7) The nut of first high-strength bolt is arranged in the notch of protective sheath, can prevent that viscoelastic medium from the adhesion on the nut, easy to assemble and dismantle the bolt.

The first bolt hole for inserting the first high-strength bolt and the notch for placing the nut allow the bolt to move in the first high-strength bolt, and the first high-strength bolt is prevented from being sheared and damaged due to the fact that the first high-strength bolt is subjected to overlarge pressure by the end plate and the side face of the U-shaped damper.

(8) When the installation, hang the flange board of steel column and arrange in between two high strength bolt, make the atress more even, can improve the fastness of whole structure.

Drawings

Fig. 1A and 1B are structural diagrams of a connection node according to the present invention;

fig. 2 is a schematic view of a U-shaped damper according to the present invention;

fig. 3 is a schematic view of an end plate of the present invention;

fig. 4A and 4B are enlarged views of a portion a in fig. 5 according to the present invention;

FIG. 5 is a schematic view of the huge steel frame of the present invention.

The notations in the figures have the following meanings:

10-first end plate 11-second end plate 12-U-shaped damper 13-viscoelastic medium

14-first high-strength bolt 140-first bolt hole 15-second high-strength bolt 150-second bolt hole

16-protective sleeve 160-notch 161-cylindrical bayonet

20-suspension steel column 30-frame beam 31-frame column 32-floor beam

Detailed Description

The technical solution of the present invention will be clearly and completely described below with reference to the following embodiments and the accompanying drawings. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example 1

An energy dissipation type connection node for hanging a steel column 20 is disclosed, as shown in fig. 1A and 1B, and comprises a first end plate 10, a second end plate 11, and two U-shaped dampers 12 arranged between the two end plates and opposite to each other, wherein the two U-shaped dampers 12 are horizontally arranged in an opening direction and face the outside of the end plates. Two groups of second high-strength bolts 15 are respectively connected with the first end plate 10, the U-shaped damper 12, the second end plate 11 and the U-shaped damper 12. The first high-strength bolt 14 penetrates through the first end plate 10, the second end plate 11 and the U-shaped damper 12. The viscoelastic medium 13 is filled in the U-shaped damper 12, and the space formed by the adjacent U-shaped damper 12 and the two end plates, and the viscoelastic medium 13 is connected with the U-shaped damper 12, the first end plate 10 and the second end plate 11 by using super glue.

As shown in fig. 2 and 3, the U-shaped damper 12, the first end plate 10, and the second end plate 11 are respectively provided with a first bolt hole 140 and a second bolt hole 150, in this embodiment, the first bolt hole 140 is an elliptical bolt hole, and the second bolt hole 150 is a circular bolt hole. The second high-strength bolt 15 is used for a circular bolt hole; the first high-strength bolt 14 is used for an oval bolt hole.

As shown in fig. 1A, two end portions of the first end plate 10 and the second end plate 11 are respectively provided with a protective sleeve 16, one side of each protective sleeve 16 facing the first high-strength bolt 14 is provided with a slot corresponding to the first high-strength bolt 14, the upper end and the lower end of each slot are provided with a notch 160, in this embodiment, the notch 160 is square, and the slot is provided with a cylindrical bayonet 161 at the notch 160 along the height direction of the protective sleeve 16.

The nut of the first high-strength bolt 14 is located inside the notch 160, and the width of the notch 160 is slightly larger than the width of the nut, and the rod of the first high-strength bolt 14 is located in the cylindrical bayonet 161.

In this embodiment, the U-shaped damper 12 is made of SMA nitinol.

In this embodiment, the U-shaped dampers 12 arranged opposite to each other form a certain gap therebetween, and embodiment 2

On the basis of the embodiment 1, as shown in fig. 5, the main body of the whole floor is a giant steel frame suspension structure system, the giant steel frame comprises giant steel frame columns 31 and giant steel frame beams 30, and the main gravity of the suspension substructure is borne by the suspension steel columns 20. The installation of the connecting node of the utility model on the giant steel frame comprises the following steps;

and S1, fixing the first end plate 10 and the U-shaped damper 12 and the second end plate 11 and the U-shaped damper 12 together through a second high-strength bolt 15, filling a viscoelastic medium 13 between the U-shaped damper 12 and the U-shaped dampers 12 which are arranged oppositely, and fixing and bonding the U-shaped dampers 12 and the U-shaped dampers by using strong glue. The first high-strength bolt 14 is connected with the first end plate 10, the U-shaped damper 12 and the second end plate 11 in a penetrating mode, and the outer sides of the first end plate 10 and the second end plate 11 and the U-shaped damper 12 are fixed through nuts. And (3) clamping the protective sleeve 16 on the first high-strength bolt 14, injecting strong glue at the joint to connect the protective sleeve 16 with the first end plate 10 and the second end plate 11, and completing prefabrication of the connection joint. In this embodiment, protective sleeve 16 is rubber.

S2, when the installation of the suspension steel columns 20 on the lower portion of the giant steel frame is completed, as shown in fig. 4A and 4B, the suspension steel columns 20 are H-shaped steel, and are divided into upper suspension steel columns 20 and lower suspension steel columns 20. The lower portion hangs steel column 20 and second end plate 11 and just corresponds, hangs the flange board of steel column 20 and is in the space department that forms between oval bolt hole and the circular bolt hole, and the steel column flange board is connected with second end plate 11 through the welding, steel column web. The upper suspension steel columns 20 and the first end plate 10 are connected in the same connection mode of the lower suspension steel columns 20 and the second end plate 11, and are connected through welding.

S3, after the connecting node is welded to the lower suspension steel beam 20, as shown in fig. 4A and 4B, the upper suspension steel beam 20 is placed at the corresponding position of the first end plate 10 of the node and connected by welding.

S4, connecting the sub-structure floor beams 32 to the middle part of the upper suspension steel columns 20.

S5, repeating steps S2-S4, namely completing the installation of the frame from the bottom layer of the suspension substructure to the top layer of the suspension substructure. At this time, the upper suspension steel column 20 of the previous installation step becomes the lower suspension steel column 20 of the next installation step.

Claims (8)

1. The utility model provides an energy-consuming connected node for hanging steel column, includes parallel arrangement's first end plate (10) and second end plate (11) from top to bottom, its characterized in that: be provided with open type attenuator between first end plate (10) and second end plate (11), the opening direction level of open type attenuator sets up for the energy of dissipation earthquake at the horizontal direction input, an limit portion and first end plate (10) fixed connection of open type attenuator, another limit portion and second end plate (11) fixed connection of open type attenuator, it is adjacent be provided with the clearance between the open type attenuator for provide the deformation space for the open type attenuator.

2. The energy consuming connecting node of claim 1, wherein: the open type dampers are U-shaped dampers (12) and are sequentially arranged along the horizontal direction; viscoelastic media (13) are filled in the U-shaped damper (12) and in spaces formed by the adjacent U-shaped damper (12) and the two end plates.

3. The energy consuming connecting node of claim 2, wherein: two adjacent U-shaped dampers (12) with opposite opening directions form a group.

4. The energy consuming connecting node of claim 2, wherein: fix first end plate (10), second end plate (11), U type attenuator (12) through first high-strength bolt (14), opening side, second end plate (11) that first high-strength bolt (14) run through first end plate (10), U type attenuator (12).

5. The energy consuming connecting node of claim 4, wherein: the energy-consuming connection node further comprises a protective sleeve (16) arranged at the end of the first end plate (10) and the second end plate (11).

6. The energy consuming connecting node of claim 5, wherein: one side, facing the first high-strength bolt (14), of each protective sleeve (16) is provided with a clamping groove corresponding to the first high-strength bolt (14), the upper end and the lower end of each clamping groove are provided with notches (160), and the clamping groove is provided with a cylindrical bayonet (161) at the notch (160) along the height direction of the protective sleeve (16);

the nut of the first high-strength bolt (14) is located inside the notch (160), the width of the notch (160) is slightly larger than that of the nut, and the rod of the first high-strength bolt (14) is located inside the cylindrical bayonet (161).

7. The energy consuming connection node of claim 5 or 6, wherein: second high-strength bolts (15) are connected between the first end plate (10) and the U-shaped damper (12) and between the second end plate (11) and the U-shaped damper (12), and second bolt holes (150) are formed in the positions of the second high-strength bolts (15);

the first high-strength bolt (14) is positioned in the first bolt hole (140), and the position of the first high-strength bolt (14) in the first bolt hole (140) can be moved;

the minimum distance between the edge of the second bolt hole (150) and the edge of the first bolt hole (140) is larger than the thickness of a flange plate of the suspension steel column (20).

8. The energy consuming connecting node of claim 7, wherein: the U-shaped damper (12) is made of SMA nickel titanium shape memory alloy.

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