CN108608194B

CN108608194B - Shock absorber dismounting device

Info

Publication number: CN108608194B
Application number: CN201810715383.9A
Authority: CN
Inventors: 徐俊; 瑜明阳; 胡大炜; 王绍军; 孟庆杰; 刘记心
Original assignee: 719th Research Institute of CSIC
Current assignee: 719th Research Institute of CSIC
Priority date: 2018-06-29
Filing date: 2018-06-29
Publication date: 2023-06-20
Anticipated expiration: 2038-06-29
Also published as: CN108608194A

Abstract

The invention discloses a vibration damper dismounting device, which belongs to the technical field of vibration damping and noise reduction and comprises a vibration damper, a structural member, a base, a limiting mechanism, a pressure applying mechanism and a power source mechanism. The shock absorber comprises a first plate surface, a second plate surface and a first body; the structural member comprises a first side face, a second side face and a second body; the limiting mechanism comprises a first height locking piece and a second height locking piece, and the first height locking piece is provided with a first end, a second end and a first middle section; the second height locking piece is provided with a third end, a fourth end and a second middle section; the pressure applying mechanism comprises a cover plate, a pressing plate, a first pressure rod and a second pressure rod, and the cover plate is detachably connected with the second side face; the pressing plate is provided with a third side surface and a fourth side surface; the first pressure rod is provided with a fifth end, a sixth end and a third middle section; the second pressure bar is provided with a seventh end, an eighth end and a fourth intermediate section. The invention achieves the technical effects of convenient disassembly of the shock absorber and reduction of maintenance cost.

Description

Shock absorber dismounting device

Technical Field

The invention belongs to the technical field of vibration reduction and noise reduction, and particularly relates to a vibration damper dismounting device.

Background

Vibration and noise reduction are an important aspect of environmental protection. On board ships, large vibrations and noise are often generated. The main measures for vibration and noise reduction of ships are three: firstly, carrying out low-noise design on mechanical equipment; secondly, controlling the vibration transmission path of the mechanical equipment; thirdly, control is carried out at the receiving end.

In the conventional vibration/noise reduction technology, often, tens of devices are integrally mounted on a large-scale floating raft vibration damper to uniformly damp mechanical devices in a concentrated area. Because the weight of the whole floating raft vibration damper is usually more than ten tons, and the load of the vibration damper positioned at the lower layer of the large floating raft vibration damper is also more than ton, the rigidity of the vibration damper is correspondingly higher, and the rubber vibration damper exceeding the service life is often required to be maintained or replaced. However, more devices are arranged on the large-sized damper, and an auxiliary pipeline is also connected, so that the damper cannot be disassembled, and the replacement cost is high.

In summary, in the existing vibration damping and noise reduction technology, there is a technical problem that the vibration damper is inconvenient to detach and has high maintenance cost.

Disclosure of Invention

The invention aims to solve the technical problems that the shock absorber is inconvenient to detach and has high maintenance cost.

In order to solve the technical problems, the invention provides a damper dismounting device, which is characterized by comprising a damper, wherein the damper comprises a first plate surface, a second plate surface and a first body, and the first body is positioned between the first plate surface and the second plate surface; the structure comprises a first side face, a second side face and a second body, wherein the first side face is provided with a first guide hole and a second guide hole, the second side face is provided with a third guide hole and a fourth guide hole, the second body is located between the first side face and the second side face, and the first side face is located between the second plate face and the second body; the base is detachably connected with the first plate surface, and the first plate surface is positioned between the base and the first body; the limiting mechanism comprises a first height locking piece, wherein the first height locking piece is provided with a first end, a second end and a first middle section, the first height locking piece is detachably connected with the first plate surface through the first end, the first height locking piece is detachably connected with the second plate surface through the second end, and the first middle section is positioned between the first end and the second end; the second height locking piece is provided with a third end, a fourth end and a second middle section, the second height locking piece is detachably connected with the first plate surface through the third end, the second height locking piece is detachably connected with the second plate surface through the fourth end, the second middle section is located between the third end and the fourth end, and the first body is located between the first middle section and the second middle section; the pressure applying mechanism comprises a cover plate which is detachably connected with the second side surface, and the second side surface is positioned between the cover plate and the second body; the pressing plate is provided with a third side surface and a fourth side surface, and the fourth side surface is positioned between the third side surface and the cover plate; the first pressure rod is provided with a fifth end, a sixth end and a third middle section, the first pressure rod is connected with the third side face through the fifth end, the first pressure rod is connected with the second plate face through the sixth end, and the third middle section is positioned in the first guide hole and the third guide hole; the second pressure rod is provided with a seventh end, an eighth end and a fourth middle section, the second pressure rod is connected with the third side surface through the seventh end, the second pressure rod is connected with the second plate surface through the eighth end, and the fourth middle section is positioned in the second guide hole and the fourth guide hole; the power source mechanism comprises a hydraulic head, the hydraulic head is fixedly connected with the cover plate, the hydraulic head is fixedly connected with the fourth side face, and the hydraulic head is positioned between the cover plate and the fourth side face; a hydraulic pump; the hydraulic pipe is provided with a first infusion end, a second infusion end and a fifth intermediate section, the hydraulic pipe is communicated with the hydraulic head through the first infusion end, the hydraulic pipe is communicated with the hydraulic pump through the second infusion end, and the fifth intermediate section is located between the first infusion end and the second infusion end.

Further, the first plate surface is provided with a first through hole and a second through hole; the base is provided with a third through hole and a fourth through hole.

Further, the device further comprises a first bolt, wherein the first bolt is detachably connected with the first plate surface through the first through hole, and the first bolt is detachably connected with the base through the third through hole.

Further, the device further comprises a second bolt, wherein the second bolt is detachably connected with the first plate surface through the second through hole, and the second bolt is detachably connected with the base through the fourth through hole.

Further, the first plate surface is provided with a first threaded hole and a second threaded hole; the second plate surface is provided with a third threaded hole and a fourth threaded hole; the first end is provided with a fifth threaded hole; the second end is provided with a sixth threaded hole; the third end is provided with a seventh threaded hole; the fourth end is provided with an eighth threaded hole.

Further, the device also comprises a first fastening bolt, wherein the first fastening bolt is detachably connected with the first plate surface through the first threaded hole, and the first fastening bolt is detachably connected with the first end through the fifth threaded hole; the second fastening bolt is detachably connected with the first plate surface through the second threaded hole, and the second fastening bolt is detachably connected with the third end through the seventh threaded hole; the third fastening bolt is detachably connected with the second plate surface through the third threaded hole, and the third fastening bolt is detachably connected with the second end through the sixth threaded hole; and the fourth fastening bolt is detachably connected with the second plate surface through the fourth threaded hole, and the fourth fastening bolt is detachably connected with the fourth end through the eighth threaded hole.

Further, the second plate surface is provided with a first positioning groove; the sixth end is located in the first positioning groove.

Further, the device comprises a second plate surface provided with a second positioning groove; the eighth end is located in the second positioning groove.

Further, the sixth end is spherical; the eighth end is spherical.

Further, the hydraulic head is a jack.

The beneficial effects are that:

the invention provides a damper dismounting device, which is characterized in that a base is detachably connected with a second plate surface of a damper, a first end of a first height locking piece in a limiting mechanism is detachably connected with the first plate surface of the damper, and a second end of the first height locking piece is detachably connected with the second plate surface of the damper; the third end of the second height locking piece in the limiting mechanism is detachably connected with the first plate surface of the damper, the fourth end of the second height locking piece is detachably connected with the second plate surface of the damper, and the first body of the damper is located between the first middle section of the first height locking piece and the second middle section of the second height locking piece. The cover plate in the pressure applying mechanism is detachably connected with the second side surface of the structural member, the fifth end of the first pressure rod in the pressure applying mechanism is connected with the third side surface of the pressing plate in the pressure applying mechanism, the sixth end of the first pressure rod is connected with the second plate surface of the shock absorber, and the third middle section of the first pressure rod passes through the first guide hole on the first side surface of the structural member and the third guide hole on the second side surface of the structural member; the seventh end of the second pressure rod in the pressure applying mechanism is connected to the third side of the pressure plate, and the eighth end of the second pressure rod is connected to the second plate surface of the damper such that the fourth intermediate section of the second pressure rod passes through the second guide hole in the first side of the structural member and the fourth guide hole in the second side of the structural member. And then, fixedly connecting a hydraulic head in the power source mechanism with the cover plate and the fourth side surface of the pressing plate respectively, wherein a first infusion end of a hydraulic pipe in the power source mechanism is communicated with the hydraulic head, and a second infusion end of the hydraulic pipe is communicated with the hydraulic pump. If the vibration damper needs to be disassembled, the hydraulic pump provides pressure for the hydraulic head so that the hydraulic head is gradually stretched. And then, pressure is applied to the pressing plate, the pressing plate drives the first pressure rod and the second pressure rod to apply pressure to the shock absorber, and the shock absorber can be disassembled after the shock absorber is compressed to be separated from the structural part. Thereby achieving the technical effects of conveniently disassembling the shock absorber and reducing the maintenance cost.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of a damper removing apparatus according to an embodiment of the present invention;

wherein, 100-the damper, 110-the first board, 120-the second board, 130-the first body;

200-structural members, 210-first side, 211-first guide holes, 212-second guide holes, 220-second side, 221-third guide holes, 222-fourth guide holes, 230-second body;

300-a base;

410-first height lock, 411-first end, 412-second end, 413-first intermediate section, 420-second height lock, 421-third end, 422-fourth end, 423-second intermediate section;

500-pressure applying mechanism, 510-cover plate, 520-pressing plate, 521-third side, 522-fourth side, 530-first pressure lever, 531-fifth end, 532-sixth end, 533-third intermediate section, 540-second pressure lever, 541-seventh end, 542-eighth end, 543-fourth intermediate section;

610-hydraulic head, 620-hydraulic pump, 630-hydraulic pipe, 631-first infusion end, 632-second infusion end, 633-fifth intermediate section.

Detailed Description

The invention discloses a damper dismounting device, which is characterized in that a base 300 is detachably connected with a second plate surface 120 of a damper 100, a first end 411 of a first height locking piece 410 in a limiting mechanism is detachably connected with the first plate surface 110 of the damper 100, and a second end 412 of the first height locking piece 410 is detachably connected with the second plate surface 120 of the damper 100; the third end 421 of the second height locking member 420 of the limiting mechanism is detachably connected with the first plate surface 110 of the shock absorber 100, and the fourth end 422 of the second height locking member 420 is detachably connected with the second plate surface 120 of the shock absorber 100, so that the first body 130 of the shock absorber 100 is located between the first middle section 413 of the first height locking member 410 and the second middle section 423 of the second height locking member 420. The cover plate 510 of the pressure applying mechanism 500 is detachably connected to the second side 220 of the structural member 200, the fifth end 531 of the first pressure lever 530 of the pressure applying mechanism 500 is connected to the third side 521 of the pressure plate 520 of the pressure applying mechanism 500, and the sixth end 532 of the first pressure lever 530 is connected to the second plate 120 of the damper 100 such that the third intermediate section 533 of the first pressure lever 530 passes through the first guide hole 211 of the first side 210 of the structural member 200 and the third guide hole 221 of the second side 220 of the structural member 200; the seventh end 541 of the second pressure bar 540 in the pressure applying mechanism 500 is coupled to the third side 521 of the pressure plate 520 and the eighth end 542 of the second pressure bar 540 is coupled to the second plate surface 120 of the shock absorber 100 such that the fourth intermediate section 543 of the second pressure bar 540 passes through the second guide hole 212 in the first side 210 of the structural member 200 and the fourth guide hole 222 in the second side 220 of the structural member 200. Then, the hydraulic head 610 in the power source mechanism is fixedly connected with the cover plate 510 and the fourth side 522 of the pressing plate 520 respectively, the first infusion end 631 of the hydraulic tube 630 in the power source mechanism is communicated with the hydraulic head 610, and the second infusion end 632 of the hydraulic tube 630 is communicated with the hydraulic pump 620. If disassembly of shock absorber 100 is desired, hydraulic head 610 is gradually extended by hydraulic pump 620 providing pressure to hydraulic head 610. And then applies pressure to the pressing plate 520, the pressing plate 520 drives the first pressure rod 530 and the second pressure rod 540 to apply pressure to the shock absorber 100, and after the shock absorber 100 is compressed to be separated from the structural member 200, the shock absorber 100 can be disassembled. Thereby achieving the technical effect of conveniently disassembling the shock absorber 100 and reducing the maintenance cost.

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments obtained by a person skilled in the art based on the embodiments of the present invention are within the scope of the present invention; wherein reference to "and/or" in this embodiment indicates and/or two cases, in other words, reference to a and/or B in the embodiments of the present invention indicates two cases of a and B, A or B, and describes three states in which a and B exist, such as a and/or B, and indicates: only A and not B; only B and not A; includes A and B.

Also, in embodiments of the present invention, when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When a component is considered to be "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. The terms "vertical", "horizontal", "left", "right" and the like are used in the embodiments of the present invention for illustrative purposes only and are not intended to limit the present invention.

Referring to fig. 1, fig. 1 is a schematic diagram illustrating an overall structure of a damper dismounting device according to an embodiment of the invention. The embodiment of the invention provides a damper dismounting device, which comprises a damper 100, a structural member 200, a base 300, a limiting mechanism, a pressure applying mechanism 500 and a power source mechanism. The shock absorber 100, the structural member 200, the base 300, the stopper mechanism, the pressure applying mechanism 500, and the power source mechanism will now be described in detail below:

for shock absorber 100:

the shock absorber 100 includes a first plate 110, a second plate 120, and a first body 130, the first body 130 being located between the first plate 110 and the second plate 120; the first plate surface 110 is provided with a first through hole and a second through hole.

Referring to fig. 1, the first plate 110 may be located below the second plate 120, and the second plate 120 and the first plate 110 are symmetrically distributed with respect to the first body 130, i.e. the second plate 120 and the first plate 110 may be parallel to each other. A first through hole matched with the first bolt described below may be provided on the first plate surface 110 such that the first bolt may pass through the inside of the first through hole, and at this time, the inner diameter of the first through hole may be greater than or equal to the diameter of the first bolt. A second through hole matched with the second bolt described below may be provided on the first plate surface 110, i.e., the second bolt may pass through the inside of the second through hole, and at this time, the inner diameter of the second through hole may be greater than or equal to the diameter of the second bolt. The first through holes and the second through holes may be distributed at the left and right ends of the first plate 110, that is, the first through holes are close to the left side of the first plate 110, and the second through holes are close to the right side of the first plate 110. Of course, the first plate 110 and the first plate 110 may not be symmetrically distributed with respect to the first body 130, for example, the first plate 110 and the first plate 110 may have an included angle.

For the base 300:

a base 300 is detachably connected to the first panel 110, and the first panel 110 is located between the base 300 and the first body 130; the base 300 is provided with a third through hole and a fourth through hole.

With continued reference to fig. 1, the base 300 may be provided with a third through hole that matches the first bolt, that is, the first bolt may pass through the inside of the third through hole after passing through the first through hole, where the inner diameter of the third through hole may be greater than or equal to the diameter of the first bolt. The base 300 may be provided with a fourth through hole matched with the second bolt, that is, the second bolt may pass through the inside of the fourth through hole after passing through the second through hole, and at this time, the inner diameter of the fourth through hole may be greater than or equal to the diameter of the second bolt. The first through hole on the first plate 110 may be aligned with the third through hole on the base 300, and the second through hole on the first plate 110 may be aligned with the fourth through hole on the base 300. Because the first bolt passes through the first through hole and the third through hole, and the second bolt passes through the second through hole and the fourth through hole, the base 300 and the first plate 110 can be detachably connected with each other, thereby achieving the technical effect of being favorable for detaching and installing the base 300 and the first plate 110.

In order to detachably connect the base 300 and the first panel 110, the damper dismounting device provided in the embodiment of the invention may further include a first bolt and a second bolt. A first bolt is detachably connected to the first panel 110 through the first through hole, and the first bolt is detachably connected to the base 300 through the third through hole; the second bolt is detachably connected to the first plate surface 110 through the second through hole, and the second bolt is detachably connected to the base 300 through the fourth through hole.

With continued reference to fig. 1, the first bolt may sequentially pass through the first through hole located on the first board 110 and the third through hole located on the base 300, and then the nut and the first bolt passing through the third through hole are screwed together, where the nut may be located on a side close to the third through hole, i.e. the third through hole is located between the nut and the first through hole, so that the base 300 and the first board 110 are detachably connected; alternatively, the first bolt may sequentially pass through the third through hole located on the base 300 and the first through hole on the first board 110, and then the nut and the first bolt passing through the first through hole are screwed, and the nut may be located at a side close to the first through hole, that is, the first through hole is located between the nut and the third through hole, so that the base 300 and the first board 110 are detachably connected.

The second bolt can sequentially pass through the second through hole positioned on the first plate surface 110 and the fourth through hole positioned on the base 300, then the nut is in threaded connection with the second bolt passing through the fourth through hole, and the nut can be positioned at one side close to the fourth through hole, namely, the fourth through hole is positioned between the nut and the second through hole, so that the base 300 and the first plate surface 110 are detachably connected; alternatively, the second bolt may sequentially pass through the fourth through hole located on the base 300 and the second through hole located on the first board 110, and then the nut and the second bolt passing through the second through hole are screwed, and the nut may be located at a side close to the second through hole, that is, between the second through hole and the fourth through hole, so that the base 300 and the first board 110 are detachably connected.

For structural member 200:

the structural member 200 includes a first side 210, a second side 220, and a second body 230, the first side 210 is provided with a first guide hole 211 and a second guide hole 212, the second side 220 is provided with a third guide hole 221 and a fourth guide hole 222, and the second body 230 is located between the first side 210 and the second side 220, and the first side 210 is located between the second panel 120 and the second body 230.

With continued reference to fig. 1, the structural member 200 may refer to structural members 200 of the vibration damping device. The first side 210 may be located at a position below the structure 200 and the second side 220 may be located at a position above the structure 200. The first side 210 and the second side 220 may be symmetrically distributed with respect to the second body 230, i.e., the second panel 120 and the first panel 110 may be parallel to each other. A first guide hole 211 is provided in the first side 210 to match the first height locker 410 of the limiting mechanism, that is, the first height locker 410 may pass through the inside of the first guide hole 211 such that a first middle section 413 of the first height locker 410 is positioned in the first guide hole 211 and the first guide hole 211 is positioned between a first end 411 and a second end 412 of the first height locker 410. The first side 210 is further provided with a second guide hole 212 matching with the second height locker 420 of the limiting mechanism, that is, the second height locker 420 may pass through the inside of the second guide hole 212 such that the second middle section 423 of the second height locker 420 is located in the second guide hole 212, and the second guide hole 212 is located between the third end 421 and the fourth end 422 of the second height locker 420.

A third guide hole 221 is provided in the second side 220 to match the first height locker 410 of the limiting mechanism in that the first height locker 410 may pass through the inside of the third guide hole 221 such that a first middle section 413 of the first height locker 410 is positioned in the first guide hole 211 and the third guide hole 221 is positioned between the first end 411 and the second end 412 of the first height locker 410. A fourth guide hole 222 is also provided in the second side 220, which is matched with the second height locker 420 in the limiting mechanism, that is, the second height locker 420 may pass through the inside of the fourth guide hole 222 such that the second middle section 423 of the second height locker 420 is located in the fourth guide hole 222 and the fourth guide hole 222 is located between the third end 421 and the fourth end 422 of the second height locker 420. The movement direction of the first height lock 410 is restricted by the first guide hole 211 and the third guide hole 221 such that the first height lock 410 moves in a direction toward the first guide hole 211 or the first height lock 410 moves in a direction toward the third guide hole 221. The movement direction of the second height locker 420 is restricted by the second guide hole 212 and the fourth guide hole 222, i.e., the second height locker 420 moves in a direction toward the second guide hole 212 or the second height locker 420 moves in a direction toward the fourth guide hole 222.

For the limiting mechanism:

the spacing mechanism includes a first height lock 410 and a second height lock 420.

The first height locker 410 is provided with a first end 411, a second end 412 and a first intermediate section 413, the first height locker 410 is detachably connected with the first panel 110 through the first end 411, the first height locker 410 is detachably connected with the second panel 120 through the second end 412, and the first intermediate section 413 is positioned between the first end 411 and the second end 412. The second height locking member 420 is provided with a third end 421, a fourth end 422 and a second middle section 423, the second height locking member 420 is detachably connected with the first plate surface 110 through the third end 421, the second height locking member 420 is detachably connected with the second plate surface 120 through the fourth end 422, the second middle section 423 is located between the third end 421 and the fourth end 422, and the first body 130 is located between the first middle section 413 and the second middle section 423.

With continued reference to fig. 1, the first height locking member 410 may sequentially pass through the first guide hole 211 on the first side 210 of the structural member 200 and the third guide hole 221 on the second side 220 of the structural member 200, so that the first height locking member 410 may move up and down in the first guide hole 211 and the third guide hole 221. After the first height locking member 410 passes through the third guide hole 221, the first end 411 of the first height locking member 410 may contact with the first panel 110 of the damper 100, and when the first height locking member 410 is pressed downward, the first end 411 of the first height locking member 410 presses the first panel 110 of the damper 100, that is, generates pressure on the first panel 110 toward the base 300, so that the first panel 110 of the damper 100 approaches the second panel 120, and then the damper 100 and the structural member 200 are separated from each other, which is beneficial to withdrawing the damper 100 from the lower side of the structural member 200, thereby achieving convenient disassembly of the damper 100; there is no need to replace both shock absorber 100 and structural member 200 to reduce the technical effect of maintenance costs.

The second height locking piece 420 may sequentially pass through the second guide hole 212 on the first side 210 of the structural member 200 and the fourth guide hole 222 on the second side 220 of the structural member 200, so that the second height locking piece 420 may move up and down in the second guide hole 212 and the fourth guide hole 222. After the second height locking member 420 passes through the fourth guide hole 222, the fourth end 422 of the second height locking member 420 may contact the first panel 110 of the shock absorber 100, and when the second height locking member 420 receives downward pressure, the fourth end 422 of the second height locking member 420 presses the first panel 110 of the shock absorber 100, that is, generates pressure on the first panel 110 toward the base 300, so that the first panel 110 of the shock absorber 100 approaches the second panel 120, and then the shock absorber 100 and the structural member 200 are separated from each other, which is beneficial to withdrawing the shock absorber 100 from below the structural member 200, thereby achieving convenient disassembly of the shock absorber 100; there is no need to replace both shock absorber 100 and structural member 200 to reduce the technical effect of maintenance costs.

In order to facilitate the disassembly of the first height locking member 410 from the first plate surface 110 and the second plate surface 120, the second height locking member 420 is disassembled from the first plate surface 110 and the second plate surface 120. The first plate surface 110 is provided with a first threaded hole and a second threaded hole; the second plate surface 120 is provided with a third threaded hole and a fourth threaded hole; the first end 411 is provided with a fifth threaded hole; the second end 412 is provided with a sixth threaded hole; the third end 421 is provided with a seventh threaded hole; the fourth end 422 is provided with an eighth threaded bore. The dismounting device for the shock absorber provided by the embodiment of the invention can further comprise a first fastening bolt, a second fastening bolt, a third fastening bolt and a fourth fastening bolt.

The first fastening pin is detachably connected to the first panel 110 through the first screw hole, and the first fastening pin is detachably connected to the first end 411 through the fifth screw hole. The second fastening pin is detachably connected to the first plate surface 110 through the second threaded hole, and the second fastening pin is detachably connected to the third end 421 through the seventh threaded hole. The third fastening pin is detachably connected to the second panel 120 through the third threaded hole, and the third fastening pin is detachably connected to the second end 412 through the sixth threaded hole. The fourth fastening pin is detachably connected to the second panel 120 through the fourth threaded hole, and the fourth fastening pin is detachably connected to the fourth end 422 through the eighth threaded hole.

With continued reference to fig. 1, a first threaded hole may be provided in the first plate surface 110 of the shock absorber 100 that mates with a first fastening pin, and a first end 411 of the first height lock 410 may be provided with a fifth threaded hole that mates with the first fastening pin. The first end 411 of the first height locker 410 and the first plate surface 110 may be coupled to each other by the first fastening bolt sequentially passing through the fifth screw hole and the first screw hole. A third threaded hole may be provided in the second plate 120 of the shock absorber 100 that mates with a third securing pin and a second end 412 of the first height lock 410 may be provided with a sixth threaded hole that mates with the third securing pin. The second end 412 of the first height locker 410 and the second plate surface 120 may be coupled to each other by the third fastening bolt sequentially passing through the sixth and third screw holes. The first height lock 410 may be a hydraulic jack. The first end 411 of the first height lock 410 may be a piston head of a hydraulic jack and the second end 412 of the first height lock 410 may be a base of the hydraulic jack. The length of the first height locking member 410 can be controlled by the extension and shortening of the hydraulic jack piston rod, and then the distance between the first plate surface 110 and the second plate surface 120 can be controlled. When shock absorber 100 is compressed to a state in which it is separated from structural member 200, the height of shock absorber 100 can be defined at the compressed height by adjusting first height locking member 410. And then the first and

second pressure rods

530 and 540 are released by the hydraulic pump 620 described below, so that they have no force with the shock absorber 100. The shock absorber 100 can be disassembled by pulling the shock absorber 100 out of the structural member 200.

A second threaded hole may be provided in the first plate surface 110 of the shock absorber 100 to mate with a second fastening pin, and a seventh threaded hole 421 of the second height locker 420 may be provided to mate with the second fastening pin. The third end 421 of the second height locker 420 and the first plate surface 110 may be coupled to each other by the second fastening pin sequentially passing through the seventh and second screw holes. A fourth threaded hole that mates with a fourth fastening pin may be provided in the second deck 120 of the shock absorber 100 and the fourth end 422 of the second height lock 420 is provided with an eighth threaded hole that mates with the fourth fastening pin. The fourth end 422 of the second height locker 420 and the second plate surface 120 may be coupled to each other by a fourth fastening pin sequentially passing through the eighth and fourth screw holes. The second height lock 420 may be a hydraulic jack. The third end 421 of the second height lock 420 may be a piston head of a hydraulic jack and the fourth end 422 of the second height lock 420 may be a base of the hydraulic jack. The length of the second height locking member 420 can be controlled by the extension and shortening of the hydraulic jack piston rod, and then the distance between the first plate surface 110 and the second plate surface 120 can be controlled. When shock absorber 100 is compressed to a state in which it is separated from structural member 200, the height of shock absorber 100 can be defined at the compressed height by adjusting second height locking member 420. And then the first and

second pressure rods

In addition, the first height locking member 410 may include a first fastening rod, a second fastening rod and a first clamping elastic bolt, where a plurality of concave hole grooves are formed on a side surface of the first fastening rod opposite to the second fastening rod, and the plurality of concave hole grooves refer to a positive integer number of concave hole grooves, for example, 1 concave hole groove, 2 concave hole grooves, 3 concave hole grooves and the like, and a through hole is formed on the second fastening rod, and the first clamping elastic bolt can be clamped with the concave hole grooves after passing through the through hole, so as to prevent the first fastening rod from sliding up and down relative to the second fastening rod. When the first plate surface 110 and the second plate surface 120 are required to relatively move, the first fastening rod and the second fastening rod can relatively move by rotating the first clamping elastic bolt; when the shock absorber 100 needs to be drawn out, the first clamping elastic bolt can be inserted into the concave hole groove by rotating the first clamping elastic bolt, so that the first fastening rod is prevented from sliding up and down relative to the second fastening rod.

The second height locking member 420 may include a third fastening rod, a fourth fastening rod and a second clamping elastic bolt, where a plurality of concave hole grooves are formed on the side surface of the third fastening rod opposite to the fourth fastening rod, and the plurality of concave hole grooves refer to positive integer concave hole grooves, for example, 1 concave hole groove, 2 concave hole grooves, 3 concave hole grooves and the like, and a through hole is formed on the fourth fastening rod, and the second clamping elastic bolt can be clamped with the concave hole grooves after passing through the through hole, so as to prevent the third fastening rod from sliding up and down relative to the fourth fastening rod. When the first plate surface 110 and the second plate surface 120 are required to relatively move, the first fastening rod and the second fastening rod can relatively move by rotating the second clamping elastic bolt; when the shock absorber 100 needs to be drawn out, the second clamping elastic bolt can be inserted into the concave hole groove by rotating the second clamping elastic bolt, so that the first fastening rod is prevented from sliding up and down relative to the second fastening rod.

For the pressure applying mechanism 500:

the pressure applying mechanism 500 includes a cover plate 510, a pressure plate 520, a first pressure lever 530, and a second pressure lever 540.

The cover 510 and the second side 220 are detachably connected, and the second side 220 is located between the cover 510 and the second body 230. The pressing plate 520 is provided with a third side 521 and a fourth side 522, and the fourth side 522 is located between the third side 521 and the cover 510. The first pressure bar 530 is provided with a fifth end 531, a sixth end 532, and a third intermediate section 533, the first pressure bar 530 is connected to the third side 521 through the fifth end 531, the first pressure bar 530 is connected to the second plate 120 through the sixth end 532, and the third intermediate section 533 is located in the first guide hole 211 and the third guide hole 221. The second pressure lever 540 is provided with a seventh end 541, an eighth end 542, and a fourth intermediate section 543, the second pressure lever 540 is connected to the third side 521 through the seventh end 541, the second pressure lever 540 is connected to the second plate surface 120 through the eighth end 542, and the fourth intermediate section 543 is located in the second guide hole 212 and the fourth guide hole 222.

Wherein, a first positioning groove and a second positioning groove are arranged on the second plate surface 120; the sixth end 532 is located in the first positioning slot, and the eighth end 542 is located in the second positioning slot; the sixth end 532 is spherically shaped and the eighth end 542 is spherically shaped.

With continued reference to fig. 1, the cover plate 510 may exhibit a U-shape, i.e., the cover plate 510 may include a recess, a first support end, and a second support end. The groove has a space therein which can accommodate the platen 520, a hydraulic head 610 described below, and a hydraulic tube 630. The first support end and the second side 220 are attached, and a threaded hole (assumed to be a ₁ A hole) is also provided on the second side 220 with a threaded hole (assumed to be a) that mates with the bolt ₂ Holes), A) ₁ Hole sum A ₂ The holes may be aligned with one another such that the bolts pass sequentially through A ₁ Hole sum A ₂ Holes interconnect the first support end and the second side 220 of the cover plate 510. Meanwhile, when maintenance or replacement of the pressure plate 520, and/or the hydraulic head 610, and/or the hydraulic pipe 630 within the cover plate 510 is required, the cover plate 510 and the second side 220 can be separated from each other by rotating the bolts. Thereby achieving the technical effect of convenient maintenance.

The second support end is attached to the second side 220, and a threaded hole (assumed to be a ₃ A hole) is also provided on the second side 220 with a threaded hole (assumed to be a) that mates with the bolt ₄ Holes), A) ₃ Hole sum A ₄ The holes may be aligned with one another such that the bolts pass sequentially through A ₃ Hole sum A ₄ A hole for mounting the second cover plate 510The support end and the second side 220 are connected to each other. Meanwhile, when maintenance or replacement of the pressure plate 520, and/or the hydraulic head 610, and/or the hydraulic pipe 630 within the cover plate 510 is required, the cover plate 510 and the second side 220 can be separated from each other by rotating the bolts. Thereby achieving the technical effect of convenient maintenance.

The pressure plate 520 may be located between the cover plate 510 and the second side 220, i.e., the pressure plate 520 is located inside the recess in the cover plate 510. The pressing plate 520 may move inside the groove in the direction of the second side 220 or the cover plate 510. The fourth side 522 of the platen 520 may be fixedly connected to the hydraulic ram 610 such that the fourth side 522 of the platen 520 moves with the hydraulic ram 610; and the hydraulic ram 610 may be coupled to the inside of the recess, i.e., the hydraulic ram 610 may apply a pushing force to the cover plate 510 and the second side 220 such that the cover plate 510 and the second side 220 move in opposite directions. The third side 521 of the pressure plate 520 is fixedly coupled to the fifth end 531 of the first pressure bar 530, while the third side 521 of the pressure plate 520 is fixedly coupled to the seventh end 541 of the second pressure bar 540.

The second panel 120 may be provided with a first positioning groove matched with the sixth end 532 of the first pressure bar 530, that is, the first positioning groove may limit the position of the sixth end 532, so that the sixth end 532 may slide in the first positioning groove, and may be convenient to separate the sixth end 532 from the second panel 120 when the second panel 120 needs to be disassembled, because the sixth end 532 is spherical. The second plate 120 may further be provided with a second positioning groove matched with the eighth end 542 of the second pressure rod 540, that is, the second positioning groove may limit the position of the eighth end 542, and since the eighth end 542 presents a spherical shape, the eighth end 542 can slide in the second positioning groove, and also can be convenient for separating the eighth end 542 from the second plate 120 when the second plate 120 needs to be disassembled. When the hydraulic head 610 described below applies pressure to the second side 220, the pressure may be transferred to the first and second pressure bars 530 and 540 through the pressure plate 520, i.e., the pressure plate 520 applies pressure to the first and second pressure bars 530 and 540, forcing the first and second pressure bars 530 and 540 to apply pressure to the second panel 120 such that the size of the gap between the second panel 120 and the first panel 110 is reduced.

For a power source mechanism:

the power source mechanism includes a hydraulic head 610, a hydraulic pump 620, and a hydraulic tube 630.

The hydraulic head 610 is fixedly connected with the cover plate 510, and the hydraulic head 610 is fixedly connected with the fourth side 522, wherein the hydraulic head 610 is positioned between the cover plate 510 and the fourth side 522; the hydraulic head 610 may be a jack. The hydraulic tube 630 is provided with a first fluid delivery end 631, a second fluid delivery end 632 and a fifth intermediate section 633, the hydraulic tube 630 communicates with the hydraulic head 610 through the first fluid delivery end 631, the hydraulic tube 630 communicates with the hydraulic pump 620 through the second fluid delivery end 632, and the fifth intermediate section 633 is located between the first fluid delivery end 631 and the second fluid delivery end 632.

With continued reference to fig. 1, the hydraulic pump 620 may be a hand-operated hydraulic pump 620, and the hand-operated hydraulic pump 620 may function to convert mechanical energy of a power machine (e.g., an electric motor, an internal combustion engine, etc.) into pressure energy of a fluid. The hydraulic pipe 630 may connect the hydraulic head 610 and the hydraulic pump 620, and the hydraulic pump 620 may supply the fluid to the inside of the hydraulic head 610 through the hydraulic pipe 630 so that the hydraulic head 610 is extended; or the liquid in the hydraulic head 610 is delivered to the inside of the hydraulic pump 620 through the hydraulic pipe 630 so that the hydraulic head 610 is shortened. The hydraulic pump 620 controls the extension or shortening of the hydraulic head 610, so that the distance between the pressing plate 520 and the cover plate 510 can be adjusted, and the pressure applied to the second plate surface 120 can be controlled so that the damper 100 and the structural member 200 are separated from each other or the damper 100 and the structural member 200 are in contact with each other. Thereby achieving the technical effect of conveniently disassembling the shock absorber 100 and reducing the maintenance cost. In addition, the hydraulic head 610 may be a jack, the jack is fixed between the cover plate 510 and the pressure plate 520, and the distance between the pressure plate 520 and the cover plate 510 can be adjusted by controlling the extension or shortening of the jack, so that the pressure applied to the second plate 120 is controlled to separate the damper 100 and the structural member 200 from each other, or the damper 100 and the structural member 200 are in contact with each other. Thereby achieving the technical effect of conveniently disassembling the shock absorber 100 and reducing the maintenance cost.

In order to explain the installation and operation of the damper removing apparatus according to the embodiment of the present invention in detail, the following steps will be provided for a detailed explanation:

in the first step, on the structural member 200 of the vibration damping device, guide holes (e.g., the first guide hole 211, the second guide hole 212, the third guide hole 221 and the fourth guide hole 222) are formed according to the number and diameter of the pressure rods (e.g., the first pressure rod 530 and the second pressure rod 540), and the guide holes are projected into the upper surface of the vibration damping device 100 (the guide holes may be reserved in designing the vibration damping device).

Second, the damper 100 and the structural member 200, and the fixing bolts on the structural member 200 and the base 300 are loosened.

Third, selecting a proper length of pressure bars (e.g., the first pressure bar 530 and the second pressure bar 540), and fixing the pressure bars (e.g., the first pressure bar 530 and the second pressure bar 540) on the platen 520; and are correspondingly inserted into the guide holes (e.g., the first guide hole 211, the second guide hole 212, the third guide hole 221, and the fourth guide hole 222) formed in the damper structural member 200.

Fourth, the hydraulic head 610, the hydraulic pipe 630 and the hydraulic pump 620 are connected to each other while the hydraulic head 610 is adjusted to a state of the lowest height, and the hydraulic head 610 is placed at the center of the pressing plate 520.

Fifth, the pressing plate 520 is fixed to the structural member 200 of the vibration damping device by the fixing bolts.

Sixth, the hydraulic head 610 is pressurized by the hydraulic pump 620 such that the hydraulic head 610 is raised. Since the cover 510 is in a fixed position, the cover 510 cannot be moved. In turn, pressure is applied to the platen 520, and the platen 520 causes the pressure rods (e.g., the first pressure rod 530 and the second pressure rod 540) to apply pressure to the shock absorber 100, so that the shock absorber 100 compresses (e.g., the distance between the first plate surface 110 and the second plate surface 120 decreases) when receiving the pressure.

Seventh, when the shock absorber 100 is compressed to be in a state of being separated from the structural member 200, the height locking means (e.g., the first height locking member 410 and the second height locking member 420) is fixed to the lower plate (e.g., the first plate surface 110) of the shock absorber 100 by the locking bolts. The height of shock absorber 100 is then limited to the compressed height by adjusting the height locking devices (e.g., first height locking member 410 and second height locking member 420).

Eighth, when the hydraulic pump 620 is depressurized and the pressure rods (e.g., the first pressure rod 530 and the second pressure rod 540) and the shock absorber 100 have no force therebetween, the shock absorber 100 can be pulled out from the lower side of the structural member 200, and at this time, the shock absorber 100 can be disassembled. Thereby achieving the technical effect of conveniently disassembling the shock absorber 100 and reducing the maintenance cost.

The invention provides a damper dismounting device, which is characterized in that a base 300 is detachably connected with a second plate surface 120 of a damper 100, a first end 411 of a first height locking piece 410 in a limiting mechanism is detachably connected with a first plate surface 110 of the damper 100, and a second end 412 of the first height locking piece 410 is detachably connected with the second plate surface 120 of the damper 100; the third end 421 of the second height locking member 420 of the limiting mechanism is detachably connected with the first plate surface 110 of the shock absorber 100, and the fourth end 422 of the second height locking member 420 is detachably connected with the second plate surface 120 of the shock absorber 100, so that the first body 130 of the shock absorber 100 is located between the first middle section 413 of the first height locking member 410 and the second middle section 423 of the second height locking member 420. The cover plate 510 of the pressure applying mechanism 500 is detachably connected to the second side 220 of the structural member 200, the fifth end 531 of the first pressure lever 530 of the pressure applying mechanism 500 is connected to the third side 521 of the pressure plate 520 of the pressure applying mechanism 500, and the sixth end 532 of the first pressure lever 530 is connected to the second plate 120 of the damper 100 such that the third intermediate section 533 of the first pressure lever 530 passes through the first guide hole 211 of the first side 210 of the structural member 200 and the third guide hole 221 of the second side 220 of the structural member 200; the seventh end 541 of the second pressure bar 540 in the pressure applying mechanism 500 is coupled to the third side 521 of the pressure plate 520 and the eighth end 542 of the second pressure bar 540 is coupled to the second plate surface 120 of the shock absorber 100 such that the fourth intermediate section 543 of the second pressure bar 540 passes through the second guide hole 212 in the first side 210 of the structural member 200 and the fourth guide hole 222 in the second side 220 of the structural member 200. Then, the hydraulic head 610 in the power source mechanism is fixedly connected with the cover plate 510 and the fourth side 522 of the pressing plate 520 respectively, the first infusion end 631 of the hydraulic tube 630 in the power source mechanism is communicated with the hydraulic head 610, and the second infusion end 632 of the hydraulic tube 630 is communicated with the hydraulic pump 620. If disassembly of shock absorber 100 is desired, hydraulic head 610 is gradually extended by hydraulic pump 620 providing pressure to hydraulic head 610. And then applies pressure to the pressing plate 520, the pressing plate 520 drives the first pressure rod 530 and the second pressure rod 540 to apply pressure to the shock absorber 100, and after the shock absorber 100 is compressed to be separated from the structural member 200, the shock absorber 100 can be disassembled. Thereby achieving the technical effect of conveniently disassembling the shock absorber 100 and reducing the maintenance cost.

Finally, it should be noted that the above-mentioned embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same, and although the present invention has been described in detail with reference to examples, it should be understood by those skilled in the art that modifications and equivalents may be made to the technical solution of the present invention without departing from the spirit and scope of the technical solution of the present invention, and all such modifications and equivalents are intended to be encompassed in the scope of the claims of the present invention.

Claims

1. A damper removing apparatus, characterized in that the damper removing apparatus comprises:

the vibration absorber comprises a first plate surface, a second plate surface and a first body, wherein the first body is positioned between the first plate surface and the second plate surface, and the second plate surface and the first plate surface are parallel to each other; the first plate surface is provided with a first through hole and a second through hole;

the structure comprises a first side face, a second side face and a second body, wherein the first side face is provided with a first guide hole and a second guide hole, the second side face is provided with a third guide hole and a fourth guide hole, the second body is located between the first side face and the second side face, and the first side face is located between the second plate face and the second body;

The base is detachably connected with the first plate surface, and the first plate surface is positioned between the base and the first body; the base is provided with a third through hole and a fourth through hole;

the first bolt is detachably connected with the first plate surface through the first through hole, and the first bolt is detachably connected with the base through the third through hole;

the second bolt is detachably connected with the first plate surface through the second through hole, and the second bolt is detachably connected with the base through the fourth through hole; the second bolt sequentially passes through the second through hole and the fourth through hole, then a nut is in threaded connection with the second bolt passing through the fourth through hole, and the nut is positioned at one side close to the fourth through hole;

stop gear, stop gear includes:

the first height locking piece is provided with a first end, a second end and a first middle section, the first height locking piece is detachably connected with the first plate surface through the first end, the first height locking piece is detachably connected with the second plate surface through the second end, and the first middle section is located between the first end and the second end; the first height locking piece sequentially passes through the first guide hole and the third guide hole, and moves up and down in the first guide hole and the third guide hole;

The second height locking piece is provided with a third end, a fourth end and a second middle section, the second height locking piece is detachably connected with the first plate surface through the third end, the second height locking piece is detachably connected with the second plate surface through the fourth end, the second middle section is located between the third end and the fourth end, and the first body is located between the first middle section and the second middle section; the second height locking piece sequentially passes through the second guide hole and the fourth guide hole, and moves up and down in the second guide hole and the fourth guide hole;

a pressure applying mechanism, the pressure applying mechanism comprising:

the cover plate is detachably connected with the second side face, and the second side face is positioned between the cover plate and the second body;

the pressing plate is provided with a third side surface and a fourth side surface, and the fourth side surface is positioned between the third side surface and the cover plate;

the first pressure rod is provided with a fifth end, a sixth end and a third middle section, the first pressure rod is connected with the third side face through the fifth end, the first pressure rod is connected with the second plate face through the sixth end, and the third middle section is positioned in the first guide hole and the third guide hole;

The second pressure rod is provided with a seventh end, an eighth end and a fourth middle section, the second pressure rod is connected with the third side surface through the seventh end, the second pressure rod is connected with the second plate surface through the eighth end, and the fourth middle section is positioned in the second guide hole and the fourth guide hole;

a power source mechanism, the power source mechanism comprising:

the hydraulic head is fixedly connected with the cover plate, and is fixedly connected with the fourth side face, and the hydraulic head is positioned between the cover plate and the fourth side face;

a hydraulic pump;

the hydraulic pipe is provided with a first infusion end, a second infusion end and a fifth intermediate section, the hydraulic pipe is communicated with the hydraulic head through the first infusion end, the hydraulic pipe is communicated with the hydraulic pump through the second infusion end, and the fifth intermediate section is located between the first infusion end and the second infusion end.

2. The apparatus of claim 1, wherein:

the first plate surface is provided with a first threaded hole and a second threaded hole;

the second plate surface is provided with a third threaded hole and a fourth threaded hole;

The first end is provided with a fifth threaded hole;

the second end is provided with a sixth threaded hole;

the third end is provided with a seventh threaded hole;

the fourth end is provided with an eighth threaded hole.

3. The apparatus of claim 2, wherein the apparatus further comprises:

the first fastening bolt is detachably connected with the first plate surface through the first threaded hole, and the first fastening bolt is detachably connected with the first end through the fifth threaded hole;

the second fastening bolt is detachably connected with the first plate surface through the second threaded hole, and the second fastening bolt is detachably connected with the third end through the seventh threaded hole;

the third fastening bolt is detachably connected with the second plate surface through the third threaded hole, and the third fastening bolt is detachably connected with the second end through the sixth threaded hole;

and the fourth fastening bolt is detachably connected with the second plate surface through the fourth threaded hole, and the fourth fastening bolt is detachably connected with the fourth end through the eighth threaded hole.

4. The apparatus of claim 1, wherein the apparatus comprises:

The second plate surface is provided with a first positioning groove;

the sixth end is located in the first positioning groove.

5. The apparatus of claim 4, wherein the apparatus comprises:

the second plate surface is provided with a second positioning groove;

the eighth end is located in the second positioning groove.

6. The apparatus as claimed in claim 5, wherein:

the sixth end is spherical;

the eighth end is spherical.

7. The apparatus of claim 6, wherein:

the hydraulic head is a jack.