JP2022520745A - Self-reset damper that consumes frictional energy using a wedge-shaped sliding block and its manufacturing method - Google Patents

Abstract

The present invention discloses a self-reset damper that consumes frictional energy using a wedge-shaped sliding block and a method for manufacturing the same. The damper includes a wedge-shaped block group, a bottom plate screw, a first shape memory alloy rod and a second shape memory alloy rod, and the first wedge-shaped block and the second wedge-shaped block correspond to the positions of the first mounting holes. The third wedge-shaped block and the fourth wedge-shaped block are provided with the positions of the second mounting holes and the positions of the third mounting holes, respectively, and the first shape memory alloy rod is provided with the positions of the second mounting holes. The second shape memory alloy rod passes through the position of the third mounting hole, the first shape memory alloy rod and the second shape memory alloy rod are parallel, and the bottom plate screw is the position of the first mounting hole. Is located between the first shape memory alloy rod and the second shape memory alloy rod, and is arranged perpendicular to the plane formed by the first shape memory alloy rod and the second shape memory alloy rod. The present invention realizes a self-reset function by utilizing the high restoring force of the first shape memory alloy rod and the second shape memory alloy rod.

Description

This application was submitted to the China Patent Office on June 13, 2019, the application number is 201910509543.9, and the title of the invention is "a self-reset damper that consumes frictional energy using a wedge-shaped sliding block and a method for manufacturing the same." Claims the priority of the Chinese patent application, the entire contents of which are incorporated in this application by reference.

The present invention relates to the technical field of steel structures for construction, and particularly to a self-reset damper that consumes frictional energy using a wedge-shaped sliding block and a method for manufacturing the same.

A damper is a device that uses damping characteristics to mitigate mechanical vibration and consume kinetic energy. Currently, general friction dampers include a normal friction damper, a mall friction damper, a sumitomo friction damper, a piezoelectric smart friction damper, and the like. Friction dampers are a type of damper that consumes a lot of energy, has a stable structure, is easy to install, and is convenient. However, the conventional friction damper can only realize energy consumption and does not have a self-reset function.

Based on this, it is an object of the present invention to provide a self-reset damper that consumes frictional energy using a wedge-shaped sliding block so that the damper has a self-reset function, and a method for manufacturing the same.

In order to achieve the above object, the present invention provides the following technical solutions.
A self-reset damper that consumes frictional energy using a wedge-shaped sliding block, which comprises a wedge-shaped block group, a bottom plate screw, a first shape memory alloy rod and a second shape memory alloy rod.
The wedge-shaped block group includes a first wedge-shaped block with a small lower part and a large upper part, a second wedge-shaped block with a small upper part and a large lower part, a third wedge-shaped block with a large left and a small right, and a wedge-shaped block with a small left and a large right. Included,
The first wedge-shaped block and the second wedge-shaped block are vertically symmetrical, and the small end of the first wedge-shaped block and the small end of the second wedge-shaped block are arranged so as to face each other.
The third wedge-shaped block and the fourth wedge-shaped block are symmetrical, and the small end of the third wedge-shaped block and the small end of the fourth wedge-shaped block are arranged so as to face each other.
The first wedge-shaped block, the second wedge-shaped block, the third wedge-shaped block, and the fourth wedge-shaped block form a sealing structure having a through hole in the center.
The two slopes of the first wedge-shaped block are in contact with the upper slope of the third wedge-shaped block and the upper slope of the fourth wedge-shaped block by sliding friction, respectively, and the two slopes of the second wedge-shaped block are respectively the first. 3 Contacted with the lower slope of the wedge-shaped block and the lower slope of the 4th wedge-shaped block by sliding friction.
The first wedge-shaped block and the second wedge-shaped block are respectively provided with the positions of the first mounting holes.
The third wedge-shaped block and the fourth wedge-shaped block are provided with the positions of the second mounting holes and the positions of the third mounting holes, respectively.
The first shape memory alloy rod sequentially passes through the positions of the second mounting holes of the third wedge-shaped block and the fourth wedge-shaped block.
The second shape memory alloy rod sequentially passes through the positions of the third mounting hole of the third wedge-shaped block and the fourth wedge-shaped block.
The first shape memory alloy rod and the second shape memory alloy rod are parallel to each other.
The bottom plate screw sequentially passes through the positions of the first mounting holes of the first wedge-shaped block and the second wedge-shaped block, and then passes through the positions of the first mounting holes.
The bottom plate screw is located between the first shape memory alloy rod and the second shape memory alloy rod, and is arranged perpendicular to the plane formed by the first shape memory alloy rod and the second shape memory alloy rod. Being done
Threads for fixing the first wedge-shaped block and the second wedge-shaped block by tightening to the bottom plate nut are installed at both ends of the bottom plate screw.
Both ends of the first shape memory alloy rod and the second shape memory alloy rod are fastened to tension nuts, respectively, and the third wedge-shaped block and the fourth wedge-shaped block form the first shape memory alloy rod and the said. A screw thread is installed to limit the sliding of the second shape memory alloy rod along the axial direction.

Further, the position of the first mounting hole penetrates the center of the upper surface and the lower surface of the first wedge-shaped block and the second wedge-shaped block.

Further, the axis at the position of the second mounting hole and the axis at the position of the third mounting hole are parallel to each other, are on the same horizontal plane, and are symmetrically distributed on both sides of the axis at the position of the first mounting hole. Penetrating the left and right surfaces of the third wedge block and the fourth wedge block,
The distance between the position of the second mounting hole and the position of the third mounting hole is larger than the diameter of the bottom plate screw.

Further, a first protrusion is provided on the first slope of the first wedge-shaped block, and the first protrusion matches a recess provided on the upper slope of the third wedge-shaped block.
A second protrusion is provided on the second slope of the first wedge-shaped block, and the second protrusion coincides with a recess provided on the upper slope of the fourth wedge-shaped block.
A third protrusion is provided on the first slope of the second wedge-shaped block, and the third protrusion coincides with a recess provided on the lower slope of the third wedge-shaped block.
A fourth protrusion is provided on the second slope of the second wedge-shaped block, and the fourth protrusion coincides with a recess provided on the lower slope of the fourth wedge-shaped block.

Further, the angle value of the acute angle formed by the slope of the first wedge-shaped block, the second wedge-shaped block, the third wedge-shaped block, and the fourth wedge-shaped block and the first shape memory alloy rod is between 30 and 60 °. It is in.

Further, the material of the first wedge-shaped block, the second wedge-shaped block, the third wedge-shaped block, and the fourth wedge-shaped block is cast iron.

A method for manufacturing a self-reset damper that consumes frictional energy using a wedge-shaped sliding block.
Determine the acute angle value between the slope of the first wedge-shaped block, the second wedge-shaped block, the third wedge-shaped block, and the fourth wedge-shaped block and the horizontal plane.
The first wedge-shaped block, the second wedge-shaped block, the third wedge-shaped block, and the fourth wedge-shaped block are processed according to the angle value, and the first wedge-shaped block is a wedge-shaped block having a small bottom and a large top. The second wedge-shaped block is a wedge-shaped block with a large bottom and a small top, the third wedge-shaped block is a wedge-shaped block with a large left and a small right, and the fourth wedge-shaped block is a wedge-shaped block with a small left and a large right.
Using a wire brush or a blast cleaning method, the floating rust on the slopes of the first wedge-shaped block, the second wedge-shaped block, the third wedge-shaped block, and the fourth wedge-shaped block is removed.
Determine the length and diameter of the bottom plate screw, the first shape memory alloy lot and the second shape memory alloy lot, respectively.
Depending on the length and diameter, the material of the bottom plate screw, the material of the first shape memory alloy lot and the material of the second shape memory alloy lot can be transferred to the bottom plate screw, the first shape memory using the turning technique or the rolling technique. Processed into an alloy lot and the second shape memory alloy lot,
Threads are threaded on the anchors at both ends of the bottom plate screw, the first shape memory alloy rod, and the second shape memory alloy rod, respectively.
The positions of the first mounting holes are drilled in the first wedge-shaped block and the second wedge-shaped block, respectively.
The position of the second mounting hole and the position of the third mounting hole are made in the third wedge-shaped block and the fourth wedge-shaped block, respectively.
The first wedge-shaped block and the second wedge-shaped block are arranged vertically symmetrically so that the small end of the first wedge-shaped block and the small end of the second wedge-shaped block face each other, and the third wedge-shaped block and the first wedge-shaped block are arranged vertically. The four wedge-shaped blocks are arranged symmetrically so that the small end of the third wedge-shaped block and the small end of the fourth wedge-shaped block face each other, and the first wedge-shaped block, the second wedge-shaped block, and the third wedge-shaped block are arranged symmetrically. The wedge-shaped block and the fourth wedge-shaped block form a sealing structure having a through hole in the center.
The first shape memory alloy rod is sequentially passed through the positions of the second mounting holes of the third wedge-shaped block and the fourth wedge-shaped block.
The second shape memory alloy rod is sequentially passed through the positions of the third mounting hole of the third wedge-shaped block and the fourth wedge-shaped block.
Tension nuts are attached to and fixed to both ends of the first shape memory alloy rod and the second shape memory alloy rod, respectively.
Thread the bottom plate screws sequentially through the positions of the first mounting holes of the first wedge-shaped block and the second wedge-shaped block.
It includes attaching and fixing bottom plate nuts to both ends of the bottom plate screw.
Further, specifically, it is possible to open the positions of the first mounting holes in the first wedge-shaped block and the second wedge-shaped block, respectively.
The diameter of the bottom plate screw is applied to the first wedge-shaped block and the second wedge-shaped block so that the position of the first mounting hole penetrates the center of the upper surface and the lower surface of the first wedge-shaped block and the second wedge-shaped block, respectively. Including opening the position of the matching first mounting hole
Specifically, it is possible to open the positions of the second mounting holes and the positions of the third mounting holes in the third wedge-shaped block and the fourth wedge-shaped block, respectively.
The position of the second mounting hole and the position of the third mounting hole penetrate the left and right surfaces of the third wedge-shaped block and the fourth wedge-shaped block, and the axis of the position of the second mounting hole and the third mounting. The diameters of the first shape memory alloy rod and the second shape memory alloy rod match the diameters of the first shape memory alloy rod and the second shape memory alloy rod in the third wedge-shaped block and the fourth wedge-shaped block, respectively, so that the axes of the hole positions are parallel to each other and are located on the same horizontal plane. Includes opening the position of the second mounting hole and the position of the third mounting hole.

Further, depending on the length and diameter, the material of the bottom plate screw, the material of the first shape memory alloy lot, and the material of the second shape memory alloy lot can be obtained from the bottom plate screw, the first, using a turning technique or a rolling technique. Before processing into the shape memory alloy lot and the second shape memory alloy lot, further
It includes heat-treating the material of the bottom plate screw, the material of the first shape memory alloy lot, and the material of the second shape memory alloy lot, respectively.

Further, it is specifically determined that the length and diameter of the bottom plate screw, the first shape memory alloy lot and the second shape memory alloy lot are determined, respectively.
Obtaining by calculating the length and diameter of the bottom plate screw, the first shape memory alloy lot, and the second shape memory alloy lot based on the rigidity of the damper, the magnitude of the output, the energy consumption, and the self-reset ability. including.

According to the specific examples provided in the present invention, the present invention achieves the following technical effects.
In the damper of the present invention, the first wedge-shaped block and the second wedge-shaped block press the third wedge-shaped block and the fourth wedge-shaped block, so that the first shape memory alloy rod and the second shape memory alloy rod are stretched axially. Also, by driving the third wedge-shaped block and the fourth wedge-shaped block with the higher restoring force of the first shape memory alloy rod and the second shape memory alloy rod, the first wedge-shaped block and the second wedge-shaped block are compressed. Finally, the bottom plate bolts provide a self-reset of the damper.

In order to more clearly explain the embodiment of the present invention or the technical solution of the prior art, the drawings that need to be used in the embodiments are briefly introduced below, but the drawings in the following description are clearly described. , Only a few embodiments of the invention, and for those skilled in the art, other drawings can be obtained based on these drawings without any creative effort.
FIG. 6 is a structural diagram of a self-reset damper that consumes frictional energy using a wedge-shaped sliding block provided by an embodiment of the present invention. It is a structural schematic diagram of the slope of the wedge-shaped block group provided by the embodiment of this invention. FIG. 6 is a schematic cross-sectional structure of a self-reset damper that consumes frictional energy using a wedge-shaped sliding block provided by an embodiment of the present invention. It is a schematic of the application of the self-reset damper which consumes the frictional energy using the wedge-shaped sliding block provided by the embodiment of this invention.

1 1st wedge-shaped block
2 Second wedge-shaped block
3 Third wedge-shaped block
4 4th wedge-shaped block 5 Bottom plate screw 6 1st shape memory alloy rod 7 2nd shape memory alloy rod 8 1st mounting hole position 9 2nd mounting hole position 10 3rd mounting hole position 11 Slope of 1st wedge-shaped block 12 Upper slope of the 3rd wedge-shaped block 13 Lower slope of the 3rd wedge-shaped block 14 Slope of the 2nd wedge-shaped block 15 Damper
16 Steel column 17 Bottom plate 18 Shaped steel foundation

The technical solutions in embodiments of the invention will be clearly and fully described below in conjunction with the drawings in embodiments of the invention, but clearly described embodiments are one of the embodiments of the invention. It is only a part, not all embodiments. All other embodiments obtained by one of ordinary skill in the art based on embodiments of the invention without creative work shall be within the scope of protection of the invention.

It is an object of the present invention to provide a self-reset damper that consumes frictional energy using a wedge-shaped sliding block so that the damper has a self-reset function, and a method for manufacturing the same.

In order to make the above objects, features and advantages of the invention more clear and understandable, the invention will be described in more detail below, along with drawings and specific embodiments.

FIG. 1 is a structural diagram of a self-reset damper that consumes frictional energy using a wedge-shaped sliding block provided by an embodiment of the present invention, and as shown in FIG. 1, the frictional energy using the wedge-shaped sliding block is used. It is a self-reset damper to be consumed and includes a wedge-shaped block group, a bottom plate screw 5, a first shape memory alloy rod 6 and a second shape memory alloy rod 7.

The wedge-shaped block group includes a first wedge-shaped block 1 with a small bottom and a large top, a second wedge-shaped block 2 with a small top and a large bottom, a third wedge-shaped block 3 with a large left and a small right, and a small left and a large right. The wedge-shaped block 4 is included, and in the present embodiment, the material of the first wedge-shaped block, the second wedge-shaped block, the third wedge-shaped block, and the fourth wedge-shaped block is cast iron or steel.

The first wedge-shaped block 1 and the second wedge-shaped block 2 are vertically symmetrical, and the small end of the first wedge-shaped block 1 and the small end of the second wedge-shaped block 2 are arranged so as to face each other, and the third wedge-shaped block is arranged. 3 and the fourth wedge-shaped block 4 are symmetrical, and the small end of the third wedge-shaped block 3 and the small end of the fourth wedge-shaped block 3 are arranged so as to face each other, and the first wedge-shaped block 1 and the second wedge-shaped block 3 are arranged so as to face each other. The wedge-shaped block 2, the third wedge-shaped block 3, and the fourth wedge-shaped block 4 form a sealing structure having a through hole in the center.

The two slopes of the first wedge-shaped block 1 are brought into contact with the upper slope of the third wedge-shaped block 3 and the upper slope of the fourth wedge-shaped block 4 by sliding friction, respectively, and the two slopes of the second wedge-shaped block 2 are brought into contact with each other by sliding friction. , The lower slope of the third wedge-shaped block 3 and the lower slope of the fourth wedge-shaped block 4, respectively, are brought into contact with each other by sliding friction.

FIG. 2 is a schematic structural view of the slope of the wedge-shaped block group provided by the embodiment of the present invention, and as shown in FIG. 2, the first slope of the first wedge-shaped block 1 has a first protrusion. The first protrusion is provided so as to match the recess provided on the upper slope 12 of the third wedge-shaped block, or the first recess is provided on the first slope of the first wedge-shaped block 1 and the first recess is provided. , Matches the protrusion provided on the upper slope 12 of the third wedge-shaped block.

A second protrusion is provided on the second slope of the first wedge-shaped block 1, and the second protrusion matches the recess provided on the upper slope of the fourth wedge-shaped block 4 or the first wedge-shaped block 1 A second recess is provided on the second slope of the above, and the second recess matches the protrusion provided on the upper slope of the fourth wedge-shaped block 4.

A third protrusion is provided on the first slope of the second wedge-shaped block 2, and the third protrusion matches a recess provided on the lower slope of the third wedge-shaped block, or the second wedge-shaped block 2 A third recess is provided on the first slope of the above, and the third recess matches the protrusion provided on the lower slope 13 of the third wedge-shaped block.

A fourth protrusion is provided on the second slope of the second wedge-shaped block, and the fourth protrusion matches a recess provided on the lower slope of the fourth wedge-shaped block, or is a second of the second wedge-shaped block. A fourth recess is provided on the two slopes, and the fourth recess coincides with a protrusion provided on the lower slope of the fourth wedge-shaped block.

As shown in FIG. 2, the two slopes of the first wedge-shaped block 1 correspond to protruding peaks or recessed valleys that match the upper slope 12 of the third wedge-shaped block and the upper slope of the fourth wedge-shaped block, respectively. The two slopes of the second wedge-shaped block 2 correspond to the protruding peaks or recessed valleys that match the lower slopes 13 of the third wedge-shaped block and the lower slopes of the fourth wedge-shaped block, respectively. The peaks or valleys extend along the slope direction of the wedge-shaped block. In the present embodiment, on the slope 11 of the first wedge-shaped block (including the first slope and the second slope of the first wedge-shaped block), a protruding mountain extending along the slope direction of the wedge-shaped block is provided, and the first wedge-shaped block is formed. Matching recessed valleys (recessed V-shaped structure) are installed on the upper slope 12 of the third wedge-shaped block and the upper slope of the fourth wedge-shaped block that are in frictional contact with the slope 11 of the block, and the second On the slope 14 of the wedge-shaped block (including the first slope and the second slope of the second wedge-shaped block), a protruding mountain extending along the direction of the slope of the wedge-shaped block is installed, and frictional contact with the slope 14 of the second wedge-shaped block is installed. Matching recessed valleys (recessed V-shaped structure) are installed on the lower slope 13 of the third wedge-shaped block and the lower slope of the fourth wedge-shaped block.

The installation of mutually matching protruding peaks or recessed valleys on the slopes of each wedge block is beneficial to the stability of the wedge block group structure, such as out-of-plane displacement of the wedge block and demolition of the wedge block group structure. prevent.

FIG. 3 is a schematic cross-sectional structure of a self-reset damper that consumes frictional energy using a wedge-shaped sliding block provided by an embodiment of the present invention, and as shown in FIG. 3, the first wedge-shaped block 1 The acute angle value between the slope of the second wedge-shaped block 2, the third wedge-shaped block 3, and the fourth wedge-shaped block 4 and the horizontal plane is between 30 and 60 °.

The first wedge-shaped block 1 and the second wedge-shaped block 2 are respectively provided with the positions 8 of the first mounting holes.

The position 8 of the first mounting hole penetrates the center of the upper surface and the lower surface of the first wedge-shaped block 1 and the second wedge-shaped block 2.

The third wedge-shaped block 3 and the fourth wedge-shaped block 4 are provided with the positions 9 of the second mounting holes and the positions 10 of the third mounting holes, respectively, with the axes of the positions 9 of the second mounting holes. The axes of the position 10 of the third mounting hole are parallel to each other, are located on the same horizontal plane, and are symmetrically distributed on both sides of the axis of the position 8 of the first mounting hole. 4 Penetrating the left and right surfaces of the wedge-shaped block 4, the distance between the position 9 of the second mounting hole and the position 10 of the third mounting is larger than the diameter of the bottom plate screw 5.

The first shape memory alloy rod 6 sequentially passes through the position 9 of the second mounting hole of the third wedge-shaped block 3 and the fourth wedge-shaped block 4.

The second shape memory alloy rod 7 sequentially passes through the position 10 of the third mounting hole of the third wedge-shaped block 3 and the fourth wedge-shaped block 4.

The first shape memory alloy rod 6 and the second shape memory alloy rod 7 are parallel to each other.

The bottom plate screw 5 sequentially passes through the position 8 of the first mounting hole of the first wedge-shaped block 1 and the second wedge-shaped block 2.

The bottom plate screw 5 is located between the first shape memory alloy rod 6 and the second shape memory alloy rod 7, and is formed by the first shape memory alloy rod 6 and the second shape memory alloy rod 7. It is placed perpendicular to the plane.

At both ends of the bottom plate screw 5, threads are provided for fixing the first wedge-shaped block 1 and the second wedge-shaped block 2 by tightening the bottom plate nuts.

Both ends of the first shape memory alloy rod 6 and the second shape memory alloy rod 7 are fastened to tension nuts, respectively, and the third wedge-shaped block 3 and the fourth wedge-shaped block 4 form the first shape memory. A screw thread is installed to limit the sliding of the alloy rod 6 and the second shape memory alloy rod 7 along the axial direction.

In the damper of the present invention, the first wedge-shaped block 1 and the second wedge-shaped block 2 are the third wedge-shaped blocks 3 and the fourth so that the first shape memory alloy rod 6 and the second shape memory alloy rod 7 are stretched in the axial direction. The first wedge shape is formed by pressing the wedge shape block 4 and driving the third wedge shape block 3 and the fourth wedge shape block 4 with a higher restoring force of the first shape memory alloy rod 6 and the second shape memory alloy rod 7. The block 1 and the second wedge-shaped block 2 are pressed, and finally, the self-reset of the damper is realized by the bottom plate bolt.

Further, the first wedge-shaped block 1 and the second wedge-shaped block 2 are in frictional contact with the third wedge-shaped block 3 and the fourth wedge-shaped block 4, respectively, and energy is consumed by the friction, and at the same time, the first shape memory alloy rod 6 and Since the energy consumption capacity of the second shape memory alloy rod 7 itself is utilized, the damper of the present invention has a better energy consumption effect.

In the present invention, the self-reset damper that consumes frictional energy using a wedge-shaped sliding block is an external energy-consuming component that uses a shape memory alloy that is easy to install and is not easily damaged. Depending on the combination form, self-reset of the target component is realized, and the larger the diameter of the shape memory alloy lot, the stronger the output and self-reset capability.

The present invention further provides a method for manufacturing a self-reset damper that consumes frictional energy using a wedge-shaped sliding block, and the manufacturing method includes the following.
The angle value of the acute angle between the slope of the first wedge-shaped block 1, the second wedge-shaped block 2, the third wedge-shaped block 3, and the fourth wedge-shaped block 4 and the horizontal plane is determined.

The first wedge-shaped block 1, the second wedge-shaped block 2, the third wedge-shaped block 3, and the fourth wedge-shaped block 4 are processed according to the angle value, and the first wedge-shaped block 1 has a wedge shape with a small bottom and a large top. The second wedge-shaped block 2 is a wedge-shaped block having a large bottom and a small top, the third wedge-shaped block 3 is a wedge-shaped block having a large left and a small right, and the fourth wedge-shaped block 4 has a small left. The right is a large wedge-shaped block.

A wire brush or a blast cleaning method is used to remove floating rust on the slopes of the first wedge-shaped block 1, the second wedge-shaped block 2, the third wedge-shaped block 3, and the fourth wedge-shaped block 4.

Determine the length and diameter of the bottom plate screw 5, the first shape memory alloy lot 6 and the second shape memory alloy lot 7, respectively.

Depending on the length and diameter, the bottom plate screw material, the first shape memory alloy lot material and the second shape memory alloy lot material can be combined with the bottom plate screw 5, the first shape, using turning technology or rolling technology. It is processed into a memory alloy lot 6 and the second shape memory alloy lot 7.

Threads are threaded on the anchor portions at both ends of the bottom plate screw 5, the first shape memory alloy rod 6 and the second shape memory alloy rod 7, respectively.

The position 8 of the first mounting hole is drilled in the first wedge-shaped block 1 and the second wedge-shaped block 2, respectively.

The position 9 of the second mounting hole and the position 10 of the third mounting hole are drilled in the third wedge-shaped block 3 and the fourth wedge-shaped block 4, respectively.

The first wedge-shaped block 1 and the second wedge-shaped block 2 are arranged vertically symmetrically so that the small end of the first wedge-shaped block 1 and the small end of the second wedge-shaped block 2 face each other, and the third wedge-shaped block 1 is formed. The block 3 and the fourth wedge-shaped block 4 are arranged symmetrically so that the small end of the third wedge-shaped block 3 and the small end of the fourth wedge-shaped block 4 face each other. The second wedge-shaped block 2, the third wedge-shaped block 3, and the fourth wedge-shaped block 4 form a sealing structure having a through hole in the center.

The first shape memory alloy rod 6 is sequentially passed through the position 9 of the second mounting hole of the third wedge-shaped block 3 and the fourth wedge-shaped block 4.

The second shape memory alloy rod 7 is sequentially passed through the position 10 of the third mounting hole of the third wedge-shaped block 3 and the fourth wedge-shaped block 4.

Tension nuts are attached to and fixed to both ends of the first shape memory alloy rod 6 and the second shape memory alloy rod 7, respectively.

The bottom plate screw 5 is sequentially passed through the position 8 of the first mounting hole of the first wedge-shaped block 1 and the second wedge-shaped block 2.

Bottom plate nuts are attached to both ends of the bottom plate screw 5 and fixed.

Specifically, it is possible to make the position 8 of the first mounting hole in the first wedge-shaped block 1 and the second wedge-shaped block 2, respectively.
In the first wedge-shaped block 1 and the second wedge-shaped block 2, respectively, the position 8 of the first mounting hole penetrates the center of the upper surface and the lower surface of the first wedge-shaped block 1 and the second wedge-shaped block 2. Includes drilling position 8 of the first mounting hole that matches the diameter of the bottom plate screw.

Specifically, it is possible to make the position 9 of the second mounting hole and the position 10 of the third mounting hole in the third wedge-shaped block 3 and the fourth wedge-shaped block 4, respectively.
The position 9 of the second mounting hole and the position 10 of the third mounting hole penetrate the center of the left and right surfaces of the third wedge-shaped block 3 and the fourth wedge-shaped block 4, and the position of the second mounting hole. The first shape memory alloy rod is attached to the third wedge-shaped block 3 and the fourth wedge-shaped block 4, respectively, so that the axis of 9 and the axis of the position 10 of the third mounting hole are parallel to each other and are located on the same horizontal plane. This includes drilling the position 9 of the second mounting hole and the position 10 of the third mounting hole that match the diameters of the 6 and the second shape memory alloy rod 7.

Depending on the length and diameter, the bottom plate screw material, the first shape memory alloy lot material and the second shape memory alloy lot material can be combined with the bottom plate screw 5, the first shape, using turning technology or rolling technology. Before processing into the memory alloy lot 6 and the second shape memory alloy lot 7, further
It includes heat-treating the material of the bottom plate screw 5, the material of the first shape memory alloy lot 6, and the material of the second shape memory alloy lot 7, respectively.
Specifically, determining the length and diameter of the bottom plate screw 5, the first shape memory alloy lot 6 and the second shape memory alloy lot 7 is specifically defined.
The length and diameter of the bottom plate screw 5, the first shape memory alloy lot 6, and the second shape memory alloy lot 7 are calculated based on the rigidity of the damper, the output magnitude, the energy consumption, and the self-reset ability. Including that.

In the manufacturing process, as the angle between the slope of the wedge-shaped block and the horizontal plane changes from small to large, the rigidity, output, energy consumption, and self-reset ability of the damper are gradually increased, and the recoverable elastic deformation is gradually decreased. Predetermine the angle value of the angle between the slope of the wedge block and the horizontal plane according to the different usage environment. Also, depending on the usage requirements of the various components, the stiffness, damping and deformation parameters of the components are preset so that the manufactured dampers meet the requirements for energy consumption, shock absorption and self-reset capabilities. , Obtain the performance parameters of shape memory alloy rods, ie length and diameter.

The damper of the present invention can be used in various environments. Taking the base node of a pillar of a building structure as an example, the damper of the present invention can be applied to a building structure under the influence of an earthquake. The response of the building structure can be effectively controlled, the main structure can be protected from damage, or the damage can be significantly reduced. In the event of an earthquake, the bolts of the base node receive a force and are displaced, so that the first wedge-shaped block 1 and the second wedge-shaped block 2 press the third wedge-shaped block 3 and the fourth wedge-shaped block 4, so that the first wedge-shaped block 1 and the second wedge-shaped block 2 are pressed. The 1-shape memory alloy rod 6 and the 2nd shape memory alloy rod 7 are stretched to cause elongation deformation, and further, the restoring force of the 1st shape memory alloy rod 6 and the 2nd shape memory alloy rod 7 causes the third wedge-shaped block 3 to be stretched. And the fourth wedge-shaped block is driven so as to press the first wedge-shaped block 1 and the second wedge-shaped block 2, and the restoring force is transmitted to the bottom plate bolt to realize the self-reset of the node.

At the same time, the compression between the first wedge-shaped block 1 and the second wedge-shaped block 2 arranged vertically and the third wedge-shaped block 3 and the fourth wedge-shaped block 4 arranged left and right causes frictional slip, and thus the wedge shape. Friction of the block group Friction and energy consumption occur between each wedge-shaped block in contact. Since the material of the shape memory alloy rod itself has a certain energy consumption capacity, the energy consumption and shock absorption at the node are the first wedge-shaped block 1 and the second wedge-shaped block 2, the third wedge-shaped block 3 and the fourth wedge-shaped block. Friction between and provided in cooperation by the first shape memory alloy rod 6 and the second shape memory alloy rod 7 effectively avoids damage to the main structure.

Depending on the needs of the various components under the influence of the earthquake, the stiffness, damping, and deformation parameters of the components are preset, the angle between the slope and the horizontal plane of each wedge block of the damper, and the shape memory alloy. By designing the length and diameter of the rod, the rigidity of the friction damper, the magnitude of the output, the energy consumption and the self-reset ability can be adjusted, and the structural form has stable friction performance and the structure is simple. be.

FIG. 4 is a schematic representation of the application of a self-reset damper that consumes frictional energy using a wedge-shaped sliding block, provided by embodiments of the present invention, at the base node of a column, as shown in FIG. The column 16 is welded to the bottom plate 17, the specific size of the bottom plate 17 is calculated and determined according to the cross section and foundation shape of the steel column 16, and the shaped steel foundation 18 withstands the internal force transmitted from the steel column 16. The internal force transmitted by the steel column 16 includes bending moment, shearing force, and axial force. The shaped steel foundation 18 includes upper and lower steel flange plates, steel webs, and steel reinforcing plates. The form of the cross section of the steel column 16 can be H-shaped steel, square steel pipe, rectangular steel pipe, round steel pipe, and cross-shaped steel, and can be specifically determined according to the design requirements. In the present invention, the smaller the angle value between the slope and the horizontal plane of each wedge-shaped block of the self-reset damper that consumes frictional energy using the wedge-shaped sliding block, the larger the damping frictional force of the column base and the consumption of frictional energy. This will increase the stiffness and overall rigidity of the pedestal, but this angle should not be as small as possible and is comprehensive depending on the stiffness and deformation requirements of the object. Need to be considered.

Each embodiment of the present specification has been described incrementally, and each embodiment has been examined focusing on differences from other embodiments, and is the same or similar among various embodiments. The parts can refer to each other.

Although the text has described the principles and implementation of the invention using specific examples, the description of the above embodiments is merely provided to understand the methods of the invention and its core ideas. At the same time, for those skilled in the art, certain embodiments and scope may be modified according to the ideas of the present invention. In summary, the content of this specification should not be construed as limiting the invention.

Claims (10)

Equipped with wedge-shaped block group, bottom plate screw, first shape memory alloy rod and second shape memory alloy rod,
The wedge-shaped block group includes a first wedge-shaped block with a small bottom and a large top, a second wedge-shaped block with a small top and a large bottom, a third wedge-shaped block with a large left and a small right, and a wedge-shaped block with a small left and a large right. Included,
The first wedge-shaped block and the second wedge-shaped block are vertically symmetrical, and the small end of the first wedge-shaped block and the small end of the second wedge-shaped block are arranged so as to face each other.
The third wedge-shaped block and the fourth wedge-shaped block are symmetrical, and the small end of the third wedge-shaped block and the small end of the fourth wedge-shaped block are arranged so as to face each other.
The first wedge-shaped block, the second wedge-shaped block, the third wedge-shaped block, and the fourth wedge-shaped block form a sealing structure having a through hole in the center.
The two slopes of the first wedge-shaped block are in contact with the upper slope of the third wedge-shaped block and the upper slope of the fourth wedge-shaped block by sliding friction, respectively, and the two slopes of the second wedge-shaped block are respectively the first. 3 The side slope of the wedge-shaped block and the lower slope of the 4th wedge-shaped block are in contact with each other by sliding friction.
The first wedge-shaped block and the second wedge-shaped block are respectively provided with the positions of the first mounting holes.
The third wedge-shaped block and the fourth wedge-shaped block are provided with the positions of the second mounting holes and the positions of the third mounting holes, respectively.
The first shape memory alloy rod sequentially passes through the positions of the second mounting holes of the third wedge-shaped block and the fourth wedge-shaped block.
The second shape memory alloy rod sequentially passes through the positions of the third mounting hole of the third wedge-shaped block and the fourth wedge-shaped block.
The first shape memory alloy rod and the second shape memory alloy rod are parallel to each other.
The bottom plate screw sequentially passes through the positions of the first mounting holes of the first wedge-shaped block and the second wedge-shaped block, and then passes through the positions of the first mounting holes.
The bottom plate screw is arranged between the first shape memory alloy rod and the second shape memory alloy rod so as to be perpendicular to the plane formed by the first shape memory alloy rod and the second shape memory alloy rod.
Threads for fixing the first wedge-shaped block and the second wedge-shaped block by tightening to the bottom plate nut are installed at both ends of the bottom plate screw.
Both ends of the first shape memory alloy rod and the second shape memory alloy rod are fastened to tension nuts, respectively, and the third wedge-shaped block and the fourth wedge-shaped block form the first shape memory alloy rod and the said. A screw thread is installed to limit the sliding of the second shape memory alloy rod along the axial direction.
A self-reset damper that consumes frictional energy using a wedge-shaped sliding block featuring. The self-reset damper according to claim 1, wherein the position of the first mounting hole penetrates the center of the upper surface and the lower surface of the first wedge-shaped block and the second wedge-shaped block. The axis at the position of the second mounting hole and the axis at the position of the third mounting hole are parallel to each other, are on the same horizontal plane, and are symmetrically distributed on both sides of the axis at the position of the first mounting hole. Penetrate the left and right surfaces of the 3 wedge block and the 4th wedge block,
The self-reset damper according to claim 1, wherein the distance between the position of the second mounting hole and the position of the third mounting hole is larger than the diameter of the bottom plate screw. A first protrusion is provided on the first slope of the first wedge-shaped block, and the first protrusion coincides with a recess provided on the upper slope of the third wedge-shaped block.
A second protrusion is provided on the second slope of the first wedge-shaped block, and the second protrusion coincides with a recess provided on the upper slope of the fourth wedge-shaped block.
A third protrusion is provided on the first slope of the second wedge-shaped block, and the third protrusion coincides with a recess provided on the lower slope of the third wedge-shaped block.
A claim characterized in that a fourth protrusion is provided on the second slope of the second wedge-shaped block, and the fourth protrusion matches a recess provided on the lower slope of the fourth wedge-shaped block. Item 1. The self-reset damper according to item 1. The acute angle value between the slope of the first wedge-shaped block, the second wedge-shaped block, the third wedge-shaped block, and the fourth wedge-shaped block and the first shape memory alloy rod is between 30 and 60 °. The self-reset damper according to claim 1. The self-reset damper according to claim 1, wherein the material of the first wedge-shaped block, the second wedge-shaped block, the third wedge-shaped block, and the fourth wedge-shaped block is cast iron. Determine the acute angle value between the slope of the first wedge-shaped block, the second wedge-shaped block, the third wedge-shaped block, and the fourth wedge-shaped block and the horizontal plane.
The first wedge-shaped block, the second wedge-shaped block, the third wedge-shaped block, and the fourth wedge-shaped block are processed according to the angle value, and the first wedge-shaped block is a wedge-shaped block having a small bottom and a large top. The second wedge-shaped block is a wedge-shaped block with a large bottom and a small top, the third wedge-shaped block is a wedge-shaped block with a large left and a small right, and the fourth wedge-shaped block is a wedge-shaped block with a small left and a large right.
Using a wire brush or a blast cleaning method, the floating rust on the slopes of the first wedge-shaped block, the second wedge-shaped block, the third wedge-shaped block, and the fourth wedge-shaped block is removed.
Determine the length and diameter of the bottom plate screw, the first shape memory alloy lot and the second shape memory alloy lot, respectively.
Depending on the length and diameter, the material of the bottom plate screw, the material of the first shape memory alloy lot and the material of the second shape memory alloy lot can be transferred to the bottom plate screw, the first shape memory using the turning technique or the rolling technique. Processed into an alloy lot and the second shape memory alloy lot,
Threads are threaded on the anchors at both ends of the bottom plate screw, the first shape memory alloy rod, and the second shape memory alloy rod, respectively.
The positions of the first mounting holes are drilled in the first wedge-shaped block and the second wedge-shaped block, respectively.
The position of the second mounting hole and the position of the third mounting hole are made in the third wedge-shaped block and the fourth wedge-shaped block, respectively.
The first wedge-shaped block and the second wedge-shaped block are arranged vertically symmetrically so that the small end of the first wedge-shaped block and the small end of the second wedge-shaped block face each other, and the third wedge-shaped block and the first wedge-shaped block are arranged vertically. The four wedge-shaped blocks are arranged symmetrically so that the small end of the third wedge-shaped block and the small end of the fourth wedge-shaped block face each other, and the first wedge-shaped block, the second wedge-shaped block, and the third wedge-shaped block are arranged symmetrically. The wedge-shaped block and the fourth wedge-shaped block form a sealing structure having a through hole in the center.
The first shape memory alloy rod is sequentially passed through the positions of the second mounting holes of the third wedge-shaped block and the fourth wedge-shaped block.
The second shape memory alloy rod is sequentially passed through the positions of the third mounting hole of the third wedge-shaped block and the fourth wedge-shaped block.
Tension nuts are attached to and fixed to both ends of the first shape memory alloy rod and the second shape memory alloy rod, respectively.
The bottom plate screws are sequentially passed through the positions of the first mounting holes of the first wedge-shaped block and the second wedge-shaped block.
Attaching and fixing bottom plate nuts to both ends of the bottom plate screw,
A method of manufacturing a self-reset damper that consumes frictional energy using a wedge-shaped sliding block characterized by containing. Specifically, it is possible to make a position of a first mounting hole in the first wedge-shaped block and the second wedge-shaped block, respectively.
The diameter of the bottom plate screw is applied to the first wedge-shaped block and the second wedge-shaped block so that the position of the first mounting hole penetrates the center of the upper surface and the lower surface of the first wedge-shaped block and the second wedge-shaped block, respectively. Including opening the position of the matching first mounting hole
Specifically, it is possible to open the positions of the second mounting holes and the positions of the third mounting holes in the third wedge-shaped block and the fourth wedge-shaped block, respectively.
The position of the second mounting hole and the position of the third mounting hole penetrate the center of the left and right surfaces of the third wedge-shaped block and the fourth wedge-shaped block, and the axis of the position of the second mounting hole and the said. The first shape memory alloy rod and the second shape memory alloy rod are placed on the third wedge-shaped block and the fourth wedge-shaped block, respectively, so that the axes of the positions of the third mounting holes are parallel to each other and are located on the same horizontal plane. Includes drilling the location of the second mounting hole and the location of the third mounting hole that match the diameter.
The method for manufacturing a self-reset damper according to claim 7. Depending on the length and diameter, the material of the bottom plate screw, the material of the first shape memory alloy lot and the material of the second shape memory alloy lot can be transferred to the bottom plate screw, the first shape memory using the turning technique or the rolling technique. Before processing into the alloy lot and the second shape memory alloy lot, further
It comprises heat-treating the material of the bottom plate screw, the material of the first shape memory alloy lot, and the material of the second shape memory alloy lot, respectively.
The method for manufacturing a self-reset damper according to claim 7. Specifically, determining the length and diameter of the bottom plate screw, the first shape memory alloy lot, and the second shape memory alloy lot is specifically defined.
Includes calculating the length and diameter of the bottom plate screw, the first shape memory alloy lot, and the second shape memory alloy lot based on the damper stiffness, output magnitude, energy consumption, and self-reset capability. ,
The method for manufacturing a self-reset damper according to claim 7.

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