CN211735770U - Wood structure energy-consumption tensile connecting piece - Google Patents

Abstract

The utility model relates to a timber construction power consumption tensile connecting piece, including rigidity power consumption skeleton, high damping power consumption layer and base, the upper and lower both ends of rigidity power consumption skeleton all are equipped with the power consumption bridge portion, are equipped with between the front and the back and insert the seam, and the bottom is fixed on the floor panel through the base, back connection shingle nail, and high damping power consumption layer is inserted and is located and insert in the seam. Compared with the prior art, the utility model has the advantages of good power consumption ability and the reliable performance of multistage power consumption.

Description

Wood structure energy-consumption tensile connecting piece

Technical Field

The utility model relates to a connecting piece of timber structure building especially relates to a timber structure power consumption tensile connecting piece.

Background

In the building industry, a large amount of energy is consumed in the processes of material production, construction, use and maintenance, and a large amount of carbon emission is generated. Compared with other building materials, the wood has obvious advantages in the aspects of carbon fixation, energy conservation, environmental protection and the like, and meanwhile, the wood structure has the advantages of rapidness in construction, good earthquake resistance and the like. Therefore, the wood structure is developed vigorously, and the development and application of modern wood structure houses in China are promoted, so that the method is an important measure for realizing energy conservation, emission reduction and sustainable development of the building industry.

In modern wood structures such as light wood structures, orthogonal laminated wood structures and laminated wood structures, both ends of a wood shear wall can generate large tensile force and upward pulling displacement under the action of an earthquake, so that tensile connecting pieces are often required to be arranged at corners or beside door openings to improve the bearing capacity of the wall body.

However, the conventional tensile metal connecting piece only depends on the yield of the nail to dissipate energy, has poor energy consumption capability, often causes unexpected damage phenomena such as shearing and pulling out of the nail, metal plate fracture, wood splitting and the like, and cannot effectively control the damage position and failure mode of the wood structure, so that the anti-seismic performance of the whole structure cannot reach the expected design target.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a timber construction power consumption tensile connecting piece in order to overcome the defect that above-mentioned prior art exists.

The purpose of the utility model can be realized through the following technical scheme:

the utility model provides a timber construction power consumption tensile connecting piece, includes rigidity power consumption skeleton, high damping power consumption layer and base, the upper and lower both ends of rigidity power consumption skeleton all are equipped with power consumption bridging portion, are equipped with the slotting between the front and the back, and the bottom is fixed on the floor board through the base, and the back is connected the shingle nail, high damping power consumption layer is inserted and is located in the slotting.

The inserting seam penetrates through two sides of the rigid energy dissipation framework, the connecting piece further comprises a high-damping protective layer, and the high-damping energy dissipation layer and the rigid energy dissipation framework are arranged in the high-damping protective layer after being inserted into the inserting seam.

The front of rigidity power consumption skeleton is equipped with the first patchhole that is used for the screw to pass through, and the back is equipped with the first mounting hole that is used for the fix with screw, be equipped with the second patchhole that is used for the screw to pass through on the high damping power consumption layer, the front of high damping protective layer is equipped with the third patchhole that is used for the screw to pass through, and the back is equipped with the second mounting hole that is used for the fix with screw, the position of first patchhole, second patchhole, first mounting hole, third patchhole and second mounting hole aligns, and first patchhole, second patchhole and third patchhole aperture are the same, and first patchhole, second patchhole and third patchhole's aperture is greater than screw tail end pin fin diameter, makes the screw only with rigidity power consumption skeleton back fixed in shingle.

The base comprises a bottom plate and two connecting plates for connecting the rigid energy dissipation framework, the bottom ends of the two connecting plates are respectively connected with the bottom plate, and the bottom plate is fixed on a floor panel.

The connecting plate is a right triangle, one right-angle side is connected with the bottom plate, and the other right-angle side is arranged close to the wall panel.

The bottom plate still includes the steel backing plate, be equipped with the third mounting hole on the bottom plate, be equipped with the fourth mounting hole on the steel backing plate, after third mounting hole and fourth mounting hole align, fix steel backing plate and bottom plate on floor's board by the bolt, the bottom of base has the difference in height of predetermineeing with the bottom of rigidity power consumption skeleton.

The rigid energy dissipation framework is formed by bending a rigid plate, an elliptical hole is formed in the bending position of the rigid plate, and the rib parts left after the elliptical hole is formed are bent to form the energy dissipation bridge parts.

And the two ends of the rigid plate are provided with tongues and grooves which are connected with each other after being bent.

The upper end and the lower end of the rigid energy-consuming framework are respectively provided with a plurality of energy-consuming bridge parts.

Compared with the prior art, the utility model discloses following beneficial effect has:

1) the rigid energy dissipation framework with high rigidity and large bearing capacity ensures that the connecting node has enough initial rigidity and bearing capacity, and the characteristic that the energy dissipation tensile connecting piece firstly generates shear deformation on the high-damping energy dissipation layer under the action of an earthquake to dissipate energy and depends on the plastic deformation of the energy dissipation bridge part to further dissipate the energy when the energy is large is utilized, so that the connecting node is ensured to have good energy dissipation capacity and multi-stage energy dissipation reliability.

2) On one hand, the high-damping protective layer can protect the rigid energy-consuming framework from being corroded by the environment, so that the durability of the connecting piece is effectively improved, on the other hand, the stress concentration of the energy-consuming bridge part can be reduced, and the bearing capacity of the connecting piece is effectively improved.

3) The wood structure can dissipate a large amount of energy by depending on the energy-consuming tensile connecting piece under the action of an earthquake, the tensile connecting piece does not have unfavorable phenomena of nail shearing or pulling out, metal plate fracture, wood splitting and the like, the full play of the anti-seismic performance of the wood structure is effectively guaranteed, and meanwhile, the disaster maintenance cost of the wood structure building is greatly reduced.

4) The construction is convenient, the method is applicable to various wood structure systems such as light wood structures, orthogonal laminated wood structures and laminated wood structures, and has wide prospects in practical engineering application.

Drawings

FIG. 1 is a schematic diagram of the components of the present invention;

FIG. 2 is a schematic space diagram of an application environment of the present invention;

fig. 3 is a schematic front view of the assembled structure of the present invention, wherein (a) is a complete front view and (b) is a front view after removing the high damping protection layer;

fig. 4 is a schematic view of the assembled back of the present invention, wherein (a) is a complete back schematic view, and (b) is a back schematic view after removing the high damping protection layer;

FIG. 5 is a schematic view of the unfolded space of the rigid dissipative skeleton;

FIG. 6 is a schematic view of a base;

wherein: 1. the energy-consuming device comprises a rigid energy-consuming framework, 2 high-damping energy-consuming layers, 3 high-damping protective layers, 4, a base, 1-1, the front side of the rigid energy-consuming framework, 1-2, the back side of the rigid energy-consuming framework, 1-3, an energy-consuming bridge part, 1-A, a first insertion hole, 1-B, a first installation hole, 1-2-1, a rigid single plate, 1-2-A, a convex rabbet, 1-2-B, a concave rabbet, 2-A, a second insertion hole, 3-A, a third insertion hole, 3-B, a second installation hole, 4-1, a bottom plate, 4-2, a connecting plate, 4-3, a steel base plate, 4-A1, a fourth installation hole, 4-A2 and a third installation hole.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings and specific embodiments. The embodiment is implemented on the premise of the technical solution of the present invention, and a detailed implementation manner and a specific operation process are given, but the scope of the present invention is not limited to the following embodiments.

A wood structure energy consumption tensile connecting piece is shown in figures 1-4 and comprises a rigid energy consumption framework 1, a high-damping energy consumption layer 2 and a base 4, energy consumption bridge parts 1-3 are arranged at the upper end and the lower end of the rigid energy consumption framework 1, an insertion seam is arranged between the front surface and the back surface, the bottom of the rigid energy consumption framework is fixed on a floor panel through the base 4, the back surface of the rigid energy consumption framework is connected with the floor panel, and the high-damping energy consumption layer 2 is inserted into the insertion seam.

The inserting seam penetrates through two sides of the rigid energy dissipation framework 1, the connecting piece further comprises a high-damping protective layer 3, and after the high-damping energy dissipation layer 2 is inserted into the inserting seam, the high-damping energy dissipation layer and the rigid energy dissipation framework 1 are arranged in the high-damping protective layer 3.

The front surface of the rigid energy dissipation framework 1 is provided with a first insertion hole 1-A for a screw to pass through, the back surface is provided with a first mounting hole 1-B for fixing the screw, the high damping energy dissipation layer 2 is provided with a second insertion hole 2-A for the screw to pass through, the front surface of the high damping protective layer 3 is provided with a third insertion hole 3-A for the screw to pass through, the back surface is provided with a second mounting hole 3-B for fixing the screw, the first insertion hole 1-A, the second insertion hole 2-A, the first mounting hole 1-B, the third insertion hole 3-A and the second mounting hole 3-B are aligned in position and are connected and fixed with a wall panel through screws, the first insertion hole 1-A, the second insertion hole 2-A and the third insertion hole 3-A have the same aperture, and the first mounting hole 1-B and the second mounting hole 3-B have the same aperture, and the apertures of the first insertion hole 1-A, the second insertion hole 2-A and the third insertion hole 3-A are larger than the diameter of the nail head at the tail end of the screw, so that the screw only fixes the back surface of the rigid energy-consuming framework on the wall panel, and the front surface and the energy-consuming bridging parts can deform relative to the back surface instead of being fixed by the screw.

As shown in fig. 6, the base 4 comprises a bottom plate 4-1 and two connecting plates 4-2 for connecting the rigid energy dissipation framework 1, the bottom ends of the two connecting plates 4-2 are respectively connected with the bottom plate 4-1, the bottom plate 4-1 is fixed on a floor panel, wherein the rigid energy dissipation framework 1 and the connecting plates 4-2 are connected by welding. The bottom of the base 4 and the bottom of the rigid energy dissipation framework have a preset height difference. The connecting plate 4-2 is a right triangle, one right-angle side is connected with the bottom plate 4-1, and the other right-angle side is arranged close to the wall panel.

The bottom plate 4-1 also comprises a steel backing plate 4-3, a third mounting hole 4-A2 is arranged on the bottom plate 4-1, a fourth mounting hole 4-A1 is arranged on the steel backing plate 4-3, and the steel backing plate 4-3 and the bottom plate 4-1 are fixed on the floor panel by bolts after the third mounting hole 4-A2 is aligned with the fourth mounting hole 4-A1.

As shown in fig. 5, the rigid energy-consuming framework 1 is formed by bending a rigid plate, an elliptical hole is formed in the bending position of the rigid plate, the rest rib parts after the elliptical hole is formed form energy-consuming bridge parts 1-3 after being bent, the rib parts are basically in a U shape after being bent, grooves and tongues for connecting the rib parts after being bent are arranged at two ends of the rigid plate, the groove and tongue parts are connected in a buckling mode through convex grooves and tongues 1-2-a and concave grooves and tongues 1-2-B, a plurality of energy-consuming bridge parts 1-3 are respectively arranged at the upper end and the lower end of the rigid energy-consuming framework 1, and the rigid plate is made of steel or a memory alloy material.

Under the action of an earthquake, the tensile connecting piece has good energy consumption capability by utilizing the characteristics that the high-damping energy consumption layer firstly generates shear deformation energy consumption and further consumes energy through plastic deformation of the energy consumption bridge part when the energy is large; meanwhile, the rigid energy-consuming framework ensures that the tensile connecting piece has higher bearing capacity and node rigidity; in addition, the high-damping protective layer can protect the rigid energy-consuming framework from being influenced by environmental corrosion, and the durability of the tensile connecting piece is effectively improved. The utility model discloses an energy consumption tensile connecting piece is applicable in modern wood structures such as light-duty timber structure, quadrature veneer lumber structure and plywood veneer lumber structure, and the range of application is wide, adopts the utility model discloses an energy consumption tensile connecting piece can effectively control the damage of timber structure, improves timber structure's antidetonation power consumption ability.

The high damping energy consumption layer 2 and the high damping protective layer 3 can be made of high damping natural rubber, polyurethane rubber, butyl rubber or mixed rubber. The contact parts of the damping energy consumption layer and the high-damping protective layer and the rigid energy consumption framework are vulcanized and tightly fixed through adhesives such as vulcanized rubber.

Claims (9)

1. The wood-structure energy-consumption tensile connecting piece is characterized by comprising a rigid energy-consumption framework (1), a high-damping energy-consumption layer (2) and a base (4), energy-consumption bridge parts (1-3) are arranged at the upper end and the lower end of the rigid energy-consumption framework (1), an insertion seam is arranged between the front surface and the back surface, the bottom of the rigid energy-consumption framework is fixed on a floor panel through the base (4), the back surface of the rigid energy-consumption framework is connected with the wall panel, and the high-damping energy-consumption layer (2) is inserted into the insertion seam.

2. The wood-structure energy-consumption tensile connecting piece according to claim 1, wherein the insertion seam penetrates through two sides of the rigid energy-consumption skeleton (1), the connecting piece further comprises a high-damping protective layer (3), and the high-damping energy-consumption layer (2) is inserted into the insertion seam and then is placed in the high-damping protective layer (3) together with the rigid energy-consumption skeleton (1).

3. The wood structure energy consumption tensile connecting piece according to claim 2, wherein the front surface of the rigid energy consumption skeleton (1) is provided with a first insertion hole (1-A) for passing a screw, the back surface is provided with a first mounting hole (1-B) for fixing the screw, the high damping energy consumption layer (2) is provided with a second insertion hole (2-A) for passing the screw, the front surface of the high damping protective layer (3) is provided with a third insertion hole (3-A) for passing the screw, the back surface is provided with a second mounting hole (3-B) for fixing the screw, the first insertion hole (1-A), the second insertion hole (2-A), the first mounting hole (1-B), the third insertion hole (3-A) and the second mounting hole (3-B) are aligned in position, the first mounting hole (1-B) and the second mounting hole (3-B) are the same in aperture, and the aperture of the first insertion hole (1-A), the aperture of the second insertion hole (2-A) and the aperture of the third insertion hole (3-A) are larger than the diameter of a nail head at the tail end of the screw.

4. The wood structure energy-consumption tensile connecting piece according to claim 1, wherein the base (4) comprises a bottom plate (4-1) and two connecting plates (4-2) for connecting the rigid energy-consumption skeleton (1), the bottom ends of the two connecting plates (4-2) are respectively connected with the bottom plate (4-1), the bottom plate (4-1) is fixed on a floor panel, and the bottom of the base (4) and the bottom of the rigid energy-consumption skeleton (1) have a preset height difference.

5. A timber construction dissipative tensile joint according to claim 4, wherein the connecting plates (4-2) are right triangles, and one of the legs is connected to the bottom plate (4-1) and the other leg is arranged against the wall panel.

6. The wood-structure energy-consumption tensile connector according to claim 4, wherein the bottom plate (4-1) further comprises a steel backing plate (4-3), the bottom plate (4-1) is provided with a third mounting hole (4-A2), the steel backing plate (4-3) is provided with a fourth mounting hole (4-A1), and the steel backing plate (4-3) and the bottom plate (4-1) are fixed on the floor panel by bolts after the third mounting hole (4-A2) and the fourth mounting hole (4-A1) are aligned.

7. The wood-structure energy-dissipating tensile connecting member according to claim 1, wherein the rigid energy-dissipating skeleton (1) is formed by bending a rigid plate, an elliptical hole is formed at the bending part of the rigid plate, and the rib portions remaining after the elliptical hole is formed form the energy-dissipating bridge portions (1-3) after bending.

8. The wood-structure energy-dissipating tensile connector according to claim 7, wherein the rigid plates are provided at both ends thereof with tongues and grooves for coupling with each other after bending.

9. The wood-structure energy-consumption tensile connecting piece according to claim 7, wherein a plurality of energy-consumption bridging parts (1-3) are respectively arranged at the upper end and the lower end of the rigid energy-consumption framework (1).

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