CN214497848U - Wallboard and energy consumption node for connecting wallboard and frame beam - Google Patents

Abstract

The utility model provides a power consumption node that is used for wallboard and frame roof beam to be connected, include: the device comprises a frame body, a connecting rod and at least two supporting plates; the frame body consists of a bottom plate, a top plate and two side plates; the connecting rod is inserted into the frame body through a first through hole formed in the top plate, the connecting rod is in clearance fit with the first through hole, and threads are formed at one end, extending out of the frame body, of the connecting rod; at least one supporting plate is connected between one side plate and the connecting rod; the remaining support plate is connected between the other side plate and the connecting rod. After the energy consumption node is embedded in the wallboard, the wallboard is assembled and constructed in a splicing mode through the energy consumption node, the construction speed is favorably improved, the construction difficulty is reduced, and the vibration transmission efficiency from an external structure to the wallboard is reduced.

Description

Wallboard and energy consumption node for connecting wallboard and frame beam

Technical Field

The utility model relates to a building structure connected node field especially relates to a wallboard, be used for the power consumption node and the wallboard assembly method that wallboard and frame roof beam are connected.

Background

In recent years, the wall panel parts in the buildings in China are developed vigorously, and especially the laths and the integral plates enter a new development period. The lath and the integral plate are fast in assembly speed, easy to maintain, high in economic benefit and wide in application range, and accord with the current building assembly development trend in China.

In the prior art, the connection method of the light wall board and the main body structure mainly comprises the steps of connecting the light wall board and the main body structure through bolts, U-shaped steel clamps, tube plates and the like, welding or bolt connection is needed on site, the wall board can only be used as a load, and vertical seams are easily formed between the wall board and between the wall board and the frame body column, so that use is affected. The lack of flexibility is the greatest disadvantage of connecting the wall panels to the frame. Therefore, a new connection method with energy consumption performance needs to be developed.

SUMMERY OF THE UTILITY MODEL

In order to solve the defects in the prior art, the utility model provides a wallboard, be used for the power consumption node and the wallboard assembly method that wallboard and frame roof beam are connected.

The utility model adopts the following technical scheme:

an energy dissipating node for a wall panel to frame beam connection, comprising: the device comprises a frame body, a connecting rod and at least two supporting plates;

the frame body consists of a bottom plate, a top plate and two side plates, wherein the two side plates are mutually parallel and vertically arranged on the bottom plate, and the top plate is parallel to the bottom plate and is arranged on the two side plates;

the connecting rod is inserted into the frame body through a first through hole formed in the top plate, the connecting rod is in clearance fit with the first through hole, and threads are formed at one end, extending out of the frame body, of the connecting rod;

at least one supporting plate is connected between one side plate and the connecting rod; the remaining support plate is connected between the other side plate and the connecting rod.

Preferably, the supporting plate is a U-shaped plate, and two ends of the supporting plate are respectively connected with the side plate and the connecting rod; the plurality of support plates are symmetrically disposed about the connecting rod.

Preferably, one end of the connecting rod inserted into the frame body is provided with a safety plate, and the projection area of the safety plate on the top plate is larger than the area of the first through hole.

Preferably, the support plate is made of a low-yield steel plate, and the frame body and the safety plate are both made of metal structures; and the safety plate is attached to the bottom plate.

Preferably, one side that the connecting rod was kept away from to two curb plates all is equipped with the reinforcing bar that is used for with wallboard reinforced connection, and reinforcing bar perpendicular to curb plate setting.

Preferably, the box body structure further comprises two auxiliary plates arranged on two opposite sides of the frame body, and the frame body and the two auxiliary plates are matched to form the box body structure.

Preferably, the first through hole is a kidney-shaped hole, and the long axis direction of the first through hole is parallel to the connecting line direction of the two side plates.

The energy dissipation node for connecting the wallboard and the frame beam is embedded in the wallboard.

Preferably, the first through hole is a waist-shaped hole, and the long axis direction of the first through hole and the connecting line direction of the two side plates are both located in the width direction of the wallboard.

A method of wallboard assembly comprising the steps of:

s1, mounting a pre-buried unit for providing a second through hole for the connecting rod to pass through on the frame beam;

s2, embedding the energy consumption node for connecting the wallboard and the frame beam in the wallboard;

s3, mounting the frame beam, aligning the wall plate with the frame beam, and passing the connecting rod through the second through hole and locking the connecting rod by a nut.

The utility model has the advantages that:

(1) the utility model provides an energy consumption node that is used for wallboard and frame roof beam to be connected, because there is not connection structure between safety plate and the bottom plate, there is not connection structure between connecting rod and the roof, consequently when this energy consumption unit receives the shake, the peripheral hardware structure will vibrate and pass through the connecting rod transmission and give the backup pad to the surrender through the backup pad realizes consuming energy, has reduced the vibration transmission efficiency of peripheral hardware structure to the framework. In the power consumption node, the setting of backup pad has realized the stability of relative position between connecting rod and the framework, and U template structure has further reduced the backup pad to the vibration transmission efficiency between connecting rod and the safety shield, is favorable to the backup pad to surrender the power consumption.

(2) The utility model provides a wallboard, pre-buried have and be used for the power consumption node that wallboard and frame roof beam are connected. So, made things convenient for the wallboard to carry out assembly construction through the mode of power consumption node with the concatenation, be favorable to improving construction speed, reduce the construction degree of difficulty.

(3) The utility model provides a wallboard assembly method, at first install pre-buried unit and power consumption node respectively on frame roof beam and wallboard, then realize the equipment of wallboard and frame roof beam through being connected of power consumption node and pre-buried unit for on-the-spot hoist and mount concatenation is simple quick, has greatly promoted construction installation effectiveness.

Drawings

Fig. 1 is a schematic view of an energy consumption node for connecting a wallboard and a frame beam according to the present invention;

fig. 2 is a partial schematic view of an energy consumption node for connecting a wallboard and a frame beam according to the present invention;

fig. 3 is a schematic view of another energy consumption node for connecting the wall plate and the frame beam according to the present invention;

fig. 4 is a schematic view of a wall panel structure according to the present invention;

fig. 5 is a schematic diagram of a structure of a pre-buried unit according to the present invention;

fig. 6 is a schematic view of an embedded assembly product of a wall panel assembly method according to the present invention;

fig. 7 is a schematic view of an embedded assembly product according to another wall panel assembling method of the present invention;

fig. 8 is a schematic view of an externally-hung assembled product of a wall panel assembling method according to the present invention;

fig. 9 is a schematic view of an externally-hung assembled product according to another wallboard assembly method of the present invention;

fig. 10 is a schematic view of an externally-hung assembled product of a wall panel assembling method according to the present invention;

fig. 11 is a schematic view of an externally-hung assembled product according to another wall panel assembling method of the present invention;

fig. 12 is a flow chart of a wallboard assembly method according to the present invention.

The figure is as follows: frame roof beam 1, wallboard 2, angle steel 3, T shaped steel 3A, plane steel 3B, power consumption node 4, nut 5, backup pad 6, connecting rod 7, safety plate 8, curb plate 9, bottom plate 10, supplementary board 11, roof 12.

Detailed Description

The utility model provides a power consumption node that is used for wallboard and frame roof beam to be connected, include: frame, connecting rod 7 and two piece at least backup pads 6.

The frame body is composed of a bottom plate 10, a top plate 12 and two side plates 9, wherein the two side plates 9 are vertically arranged on the bottom plate 10 in parallel, and the top plate 12 is arranged on the two side plates 9 in parallel with the bottom plate 10. In this way, the bottom plate 10, the top plate 12 and the two side plates 9 constitute a frame body of a rectangular frame structure.

The connecting rod 7 is inserted into the frame body through a first through hole formed in the top plate 12, the connecting rod 7 is in clearance fit with the first through hole, and threads are arranged at one end, extending out of the frame body, of the connecting rod 7, so that the energy consumption node is in threaded connection with an external structure.

In specific implementation, a safety plate 8 can be arranged at one end of the connecting rod 7 inserted into the frame body. The projected area of the safety plate 8 on the top plate 12 is larger than the area of the first through hole to prevent the safety plate 8 and the connecting rod 7 from coming out of the first through hole. And the safety plate 8 rests on the base plate 10 so that further energy is consumed by friction of the safety plate 8 and the base plate 10.

At least one support plate 6 is connected between one side plate 9 and the connecting rod 7; the remaining support plate 6 is connected between the other side plate 9 and the connecting rod 7. In this way, the positioning of the connecting rods 7 with respect to the side plates 9 is achieved by the support plates 6.

In this embodiment, since there is no connection structure between the safety plate 8 and the bottom plate 10, and there is no connection structure between the connecting rod 7 and the top plate 12, when the energy dissipation unit is shocked, the external structure transmits the vibration to the support plate 6 through the connecting rod 7, so that energy dissipation is realized through the yield deformation of the support plate 6, and the vibration transmission efficiency from the external structure to the frame body is reduced.

In this embodiment, the supporting plate 6 is a U-shaped plate, and both ends thereof are connected to the side plate 9 and the connecting rod 7, respectively. The setting of backup pad 6 has realized the stability of relative position between connecting rod 7 and the framework, and U template structure has further reduced backup pad 6 to the vibration transmission efficiency between connecting rod 7 and the safety plate 8.

In specific implementation, the support plate 6 is in surface connection with the connecting rod 7, and in specific implementation, a boss for providing a connection surface attached to the end surface of the support plate 6 can be arranged on the connecting rod 7; or, the end face of the support plate 6 connected with the connecting rod 7 is set to be a cambered surface structure matched with the circumference of the connecting rod 7.

In the present embodiment, the plurality of support plates 6 are symmetrically disposed about the connecting rod 7. Fig. 3 shows a symmetrical mounting of two support plates 6. So, through the symmetric distribution of backup pad 6, be favorable to offsetting of vibration injury, further reduce vibration transmission efficiency.

In the present embodiment, the support plate 6 is made of a low-yield steel plate so as to yield and consume energy in a vibration environment. And, the frame body and the safety plate 8 both adopt metal structures. In specific implementation, the side plate 9 is welded with the bottom plate 10 and the top plate 12.

In this embodiment, one side that connecting rod 7 was kept away from to two curb plates 9 all is equipped with the reinforcing bar that is used for with wallboard reinforced connection, and reinforcing bar perpendicular to curb plate 9 sets up. So, when pre-buried on the wallboard with this power consumption node, strengthen being connected between this power consumption node and the wallboard through the reinforcing bar, be favorable to guaranteeing that this power consumption node supports the firm reliable of wallboard.

In this embodiment, the box further includes two auxiliary plates 11 mounted on opposite sides of the frame, and the frame and the two auxiliary plates 11 cooperate to form a box structure. So, through the setting of assisting board 11, realized tying up the metal sheet through the box body structure to realized the protection to framework inner structure, made things convenient for transportation, the save and the installation of power consumption node.

In this embodiment, the first through hole is a kidney-shaped hole, and the long axis direction of the first through hole is parallel to the connecting line direction of the two side plates 9.

The utility model discloses in still provide a wallboard, pre-buried on the wallboard have the utility model provides an energy consumption node 4 that is used for wallboard and frame roof beam to be connected.

In the embodiment, when the first through hole is a waist-shaped hole, the long axis direction of the first through hole and the connecting line direction of the two side plates 9 are both located in the width direction of the wall plate. So, made things convenient for connecting rod 7 to vibrate in wallboard width direction, reduced the vibration harm of wallboard in the vertical direction.

The utility model also provides a wallboard assembly method, including following step.

And S1, mounting a pre-buried unit for providing a second through hole for the connecting rod 7 to pass through on the frame beam 1.

In specific implementation, the embedded unit can adopt angle steel 3 shown in fig. 5 to 9, T-shaped steel 3A shown in fig. 10 or plane steel 3B shown in fig. 11

S2, will the utility model provides an energy consumption node 4 that is used for wallboard 2 to be connected with frame roof beam 1 is pre-buried in wallboard 2.

S3, the frame beam 1 is installed, then the wall plate 2 is aligned with the frame beam 1, the connecting rod 7 is passed through the second through hole and locked by the nut 5.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and should not be taken as limiting the invention, and all modifications, equivalents, improvements and the like that are made within the spirit and principles of the present invention should be included in the scope of the present invention.

Claims (9)

1. An energy dissipating node for connecting a wall panel to a frame beam, comprising: the device comprises a frame body, a connecting rod (7) and at least two supporting plates (6);

the frame body consists of a bottom plate (10), a top plate (12) and two side plates (9), wherein the two side plates (9) are mutually parallel and are vertically arranged on the bottom plate (10), and the top plate (12) is arranged on the two side plates (9) in parallel with the bottom plate (10);

the connecting rod (7) is inserted into the frame body through a first through hole formed in the top plate (12), the connecting rod (7) is in clearance fit with the first through hole, and threads are formed in one end, extending out of the frame body, of the connecting rod (7);

at least one supporting plate (6) is connected between one side plate (9) and the connecting rod (7); the rest of the supporting plate (6) is connected between the other side plate (9) and the connecting rod (7).

2. The energy dissipation joint for connecting wall panels with frame beams according to claim 1, wherein the support plate (6) is a U-shaped plate, the two ends of which are connected with the side plate (9) and the connecting rod (7), respectively; the plurality of support plates (6) are symmetrically arranged about the connecting rod (7).

3. The energy dissipation node for connecting a wallboard and a frame beam according to claim 1, wherein one end of the connecting rod (7) inserted into the frame body is provided with a safety plate (8), and the projection area of the safety plate (8) on the top plate (12) is larger than the area of the first through hole.

4. The energy dissipating node for the connection of wall panels to frame beams according to claim 3, wherein the support plate (6) is made of low yield steel plate, and the frame body and the safety plate (8) are made of metal; and the safety plate (8) is attached to the bottom plate (10).

5. Energy dissipation node for connection of wall panels with frame beams according to claim 4, characterized in that the sides of the two side plates (9) remote from the connecting rods (7) are each provided with a reinforcement for the reinforced connection with the wall panels, and the reinforcement is arranged perpendicular to the side plates (9).

6. The energy dissipating node for connecting a wall panel to a frame beam as claimed in claim 1 further comprising two sub-panels (11) mounted on opposite sides of the frame, the frame cooperating with the two sub-panels (11) to form a box structure.

7. The energy dissipating node for connecting a wall panel to a frame beam as claimed in claim 1, wherein the first through hole is a kidney-shaped hole and the long axis direction of the first through hole is parallel to the connecting line direction of the two side plates (9).

8. A wall panel, characterized in that, the energy consumption node (4) that is used for wall panel and frame beam to be connected as described in any one of claims 1 to 6 is pre-buried on the wall panel.

9. The wall panel according to claim 8, wherein the first through hole is a kidney-shaped hole, and the long axis direction of the first through hole and the connecting line direction of the two side plates (9) are both located in the width direction of the wall panel.

Images