CN220980822U - Combined electromechanical anti-seismic bracket - Google Patents

Abstract

The utility model discloses a combined electromechanical anti-seismic support, which relates to the field of anti-seismic supports and comprises a bottom assembly support, wherein the bottom assembly support comprises an assembly support, a plurality of mounting sliding holes are formed in the inner walls of two sides of the assembly support, mounting sliding blocks are slidably mounted in the corresponding two mounting sliding holes, contact plates are fixedly mounted on the mounting sliding blocks, and side fixing supports are mounted on two sides of the bottom assembly support. According to the utility model, the integrated anti-vibration support is divided into the upper part and the lower part through the arrangement of the structures such as the bottom bearing support, the side fixing support and the like, so that when the anti-vibration support is used on electromechanical equipment, the anti-vibration support can be suitable for the electromechanical equipment with a certain range of size through the use of the bottom bearing support and the side fixing support, the applicability of the anti-vibration support is greatly improved, and meanwhile, the combined anti-vibration support can effectively relieve vibration waves at the connecting part when receiving vibration impact.

Description

Combined electromechanical anti-seismic bracket

Technical Field

The utility model relates to the technical field of anti-seismic supports, in particular to a combined electromechanical anti-seismic support.

Background

The electromechanical shock-resistant support limits the displacement of the auxiliary electromechanical engineering facilities, controls the vibration of the facilities, and transmits the load to various components or devices on the bearing structure, thereby having great effect in the fixation of building and industrial equipment.

In the prior art, in order to achieve the electromechanical anti-seismic effect, the adopted support is generally integrated, the size of the support is larger, the applicability is poorer, the support can only be used on equipment with the same size, the universality is lower, and meanwhile, the anti-seismic effect is not good because of rigid body propagation, so that the combined electromechanical anti-seismic support is required to meet the demands of people.

Disclosure of utility model

The utility model aims to provide a combined electromechanical anti-seismic bracket, which solves the problems that the volume is large, the applicability is poor, the combined electromechanical anti-seismic bracket can be only used on equipment with the same size, the universality is low, and the anti-seismic effect is not good due to rigid body propagation.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a modular electromechanical antidetonation support, includes the end assembly support, the end assembly support is including the assembly support, a plurality of installation slide holes have all been seted up on the both sides inner wall of assembly support, equal slidable mounting has the installation slider in two corresponding installation slide holes, and fixed mounting has the contact plate on the installation slider, the side fixed bolster is all installed to the both sides of end assembly support, all installs composite connection structure on side fixed bolster and the end assembly support, the location spout has been seted up to one side that the assembly support is close to side fixed bolster, has seted up the rotation on the one side inner wall that the location spout kept away from the contact plate and has been pulled the hole, fixed mounting has same installation slide bar on the both sides inner wall of installation slide hole, and installation slide bar slidable mounting is on the installation slide bar.

Preferably, the side fixed bolster is including the side position support, and two flexible spouts have all been symmetrically seted up to the side that two side position supports are close to each other, and equal slidable mounting has flexible slider in four flexible spouts, and fixed mounting has same top clamp plate between four flexible sliders, and fixed mounting has same flexible slide bar on the both sides inner wall of flexible spout, flexible slider slidable mounting on flexible slide bar.

Preferably, a limiting chute is formed in one side, close to the main bearing support, of the side bearing support, and the limiting chute corresponds to the positioning chute in position.

Preferably, the assembly support is provided with a positioning cavity, the inner wall of the bottom of the positioning cavity is provided with a communication hole, and the communication hole is communicated with the limiting chute.

Preferably, the combined connection structure comprises a limiting clamping rod and a positioning clamping rod, wherein the limiting clamping rod is slidably arranged in the positioning sliding groove, and the positioning clamping rod is slidably arranged in the positioning cavity.

Preferably, a half-moon-shaped clamping groove is formed in the limiting clamping rod, a connecting rod is fixedly mounted at the bottom of the positioning clamping rod, and the connecting rod is clamped with the half-moon-shaped clamping groove.

Preferably, the limiting clamping rod is fixedly provided with a pulling sliding rod, the pulling sliding rod is slidably arranged in the rotating pulling hole, the positioning cavity is slidably provided with a reset spring, and two ends of the reset spring are respectively contacted with the inner wall of the top of the positioning cavity and the positioning clamping rod.

Preferably, the installation slide bar is connected with an installation spring in a sliding manner, two ends of the installation spring are respectively contacted with the installation slide block and the inner wall at the bottom of the installation slide hole, the telescopic slide bar is connected with a telescopic spring in a sliding manner, and two ends of the telescopic spring are respectively contacted with the telescopic slide block and the inner wall at the top of the telescopic slide groove.

The beneficial effects of the utility model are as follows:

According to the utility model, the integrated anti-vibration support is divided into the upper part and the lower part through the arrangement of the structures such as the bottom bearing support, the side fixing support and the like, so that when the anti-vibration support is used on electromechanical equipment, the anti-vibration support can be suitable for the electromechanical equipment with a certain size range through the use of the bottom bearing support and the side fixing support, the applicability of the anti-vibration support is greatly improved, and meanwhile, the combined anti-vibration support can effectively relieve vibration waves at the connecting part when receiving vibration impact.

According to the utility model, through the arrangement of the combined connection structure and other structures, the bottom assembly support and the side fixing support can be stably combined and connected together, so that the combined installation function of the anti-seismic support is effectively achieved, and the functionality of the anti-seismic support is improved.

Drawings

FIG. 1 is a schematic diagram of the general structure of a combined electromechanical anti-seismic bracket according to the present utility model;

FIG. 2 is a schematic diagram of a sectional front view of a combined electromechanical anti-seismic bracket according to the present utility model;

FIG. 3 is a schematic view of the portion A in FIG. 2 of a combined electromechanical anti-seismic bracket according to the present utility model;

FIG. 4 is a schematic side view of a combined electromechanical anti-seismic bracket according to the present utility model;

Fig. 5 is a schematic top view of a portion B of fig. 4 of a combined electromechanical anti-seismic bracket according to the present utility model.

In the figure: 1. a bottom assembly support; 101. a total bearing support; 102. a contact plate; 103. installing a sliding hole; 104. installing a sliding block; 105. installing a sliding rod; 106. installing a spring; 107. positioning a chute; 108. rotating the spanner hole; 2. a side fixing bracket; 201. a side support; 202. a top platen; 203. a telescopic chute; 204. a telescopic slide block; 205. a telescopic slide bar; 206. a telescopic spring; 207. limiting sliding grooves; 208. a communication hole; 209. a positioning cavity; 3. a combination connection structure; 301. a limit clamping rod; 302. pulling the slide bar; 303. half-moon shaped clamping groove; 304. positioning a clamping rod; 305. a connecting rod; 306. and a return spring.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments.

Referring to fig. 1-5, a combined electromechanical anti-seismic bracket comprises a bottom assembly bracket 1, wherein the bottom assembly bracket 1 comprises an assembly bracket 101, a plurality of mounting sliding holes 103 are formed in the inner walls of two sides of the assembly bracket 101, a mounting sliding block 104 is slidably mounted in each of the two corresponding mounting sliding holes 103, a contact plate 102 is fixedly mounted on the mounting sliding block 104, side fixing brackets 2 are mounted on two sides of the bottom assembly bracket 1, combined connection structures 3 are mounted on the side fixing brackets 2 and the bottom assembly bracket 1, a positioning sliding groove 107 is formed in one side, close to the side fixing brackets 2, of the assembly bracket 101, a rotating spanner hole 108 is formed in the inner wall of one side, far from the contact plate 102, of the positioning sliding groove 107, a same mounting sliding rod 105 is fixedly mounted on the inner walls of two sides of the mounting sliding holes 103, the mounting sliding block 104 is slidably mounted on the mounting sliding rod 105, a user places electromechanical equipment on the bottom assembly bracket 1, then the side fixing brackets 2 are fixedly mounted on the bottom assembly bracket 1 through the combined connection structures 3, and the electromechanical equipment is fixed through interaction between the side fixing brackets 2 and the bottom assembly bracket 1.

Further, the side fixing support 2 comprises side support bases 201, two telescopic sliding grooves 203 are symmetrically formed in the side, close to each other, of the two side support bases 201, telescopic sliding blocks 204 are slidably mounted in the four telescopic sliding grooves 203, the same top pressing plate 202 is fixedly mounted between the four telescopic sliding blocks 204, the same telescopic sliding rod 205 is fixedly mounted on the inner walls of the two sides of the telescopic sliding grooves 203, and the telescopic sliding blocks 204 are slidably mounted on the telescopic sliding rods 205.

Further, a limit chute 207 is provided on one side of the side support 201 near the assembly support 101, the limit chute 207 corresponds to the position of the positioning chute 107, and the limit clamping rod 301 is slidably inserted into the limit chute 207 from the positioning chute 107.

Further, a positioning cavity 209 is formed in the main bearing support 101, a communication hole 208 is formed in the inner wall of the bottom of the positioning cavity 209, the communication hole 208 is communicated with the limiting chute 207, and the sliding stability of the positioning clamping rod 304 is guaranteed by the positioning cavity 209.

Further, the combined connection structure 3 comprises a limiting clamping rod 301 and a positioning clamping rod 304, the limiting clamping rod 301 is slidably mounted in the positioning chute 107, the positioning clamping rod 304 is slidably mounted in the positioning cavity 209, and the positioning clamping rod 304 and the connecting rod 305 are downwardly slidably inserted into the half-moon-shaped clamping groove 303 to complete fixation, so that the fixation of the bottom assembly support 1 and the side fixing support 2 is achieved.

Further, a half-moon shaped clamping groove 303 is formed in the limiting clamping rod 301, a connecting rod 305 is fixedly mounted at the bottom of the positioning clamping rod 304, the connecting rod 305 is clamped with the half-moon shaped clamping groove 303, the pulling slide rod 302 is pulled to enable the pulling slide rod 302 to move in the rotating pulling hole 108, the half-moon shaped clamping groove 303 pushes the connecting rod 305 out, and then the limiting clamping rod 301 can be pulled to exit the limiting sliding groove 207.

Further, a pulling slide rod 302 is fixedly installed on the limiting clamping rod 301, the pulling slide rod 302 is slidably installed in the rotating pulling hole 108, a reset spring 306 is slidably installed in the positioning cavity 209, two ends of the reset spring 306 are respectively contacted with the inner wall of the top of the positioning cavity 209 and the positioning clamping rod 304, and under the action of the reset spring 306, the positioning clamping rod 304 and the connecting rod 305 are pushed to slide downwards and insert into the half-moon-shaped clamping groove 303, so that fixation is completed, and further fixation of the bottom assembly support 1 and the side fixing support 2 is achieved.

Further, the installation slide bar 105 is slidably sleeved with the installation spring 106, two ends of the installation spring 106 are respectively contacted with the installation slide block 104 and the inner wall of the bottom of the installation slide hole 103, the installation spring 106 is used for buffering vibration generated by the electromechanical device to the contact plate 102, the telescopic slide bar 205 is slidably sleeved with the telescopic spring 206, two ends of the telescopic spring 206 are respectively contacted with the telescopic slide block 204 and the inner wall of the top of the telescopic slide groove 203, and the telescopic spring 206 is used for pushing the telescopic slide block 204 to stably support the top pressing plate 202 so as to stably fix the electromechanical device.

The working principle of the utility model is as follows:

The user places the electromechanical device on the bottom assembly support 1, then the side fixing support 2 is fixedly installed on the bottom assembly support 1 through the combined connection structure 3, the electromechanical device is fixed through the interaction between the side fixing support 2 and the bottom assembly support 1, wherein the contact plate 102 is used for supporting the device, the installation sliding hole 103 and the installation sliding block 104 are interacted to ensure the buffer effect of the contact plate 102, the installation sliding rod 105 is used for ensuring the installation stability of the installation sliding block 104, the installation spring 106 is used for buffering the vibration of the electromechanical device on the contact plate 102, the side fixing support 2 is used for fixing the electromechanical device, the side support 201 is used for preventing the electromechanical device from falling from the bottom assembly support 1, the top pressing plate 202 is used for fixing the electromechanical device, the telescopic sliding groove 203 is used for ensuring the sliding stability of the telescopic sliding block 204, the telescopic sliding rod 205 is used for ensuring the installation stability of the telescopic sliding block 204, further ensuring the mounting stability of the top pressing plate 202, the telescopic spring 206 is used for pushing the telescopic sliding block 204 to stably support the top pressing plate 202 to stably fix electromechanical equipment, the combined connecting structure 3 is used for connecting the bottom assembly support 1 and the side fixing support 2, wherein the limit clamping rod 301 is slidably inserted into the limit sliding groove 207 from the positioning sliding groove 107, then the connecting rod 305 is pushed to slide upwards until the connecting rod 305 is mutually attached to the half-moon clamping groove 303, under the action of the reset spring 306, the positioning clamping rod 304 and the connecting rod 305 are pushed to slide downwards and insert into the half-moon clamping groove 303 to complete fixation, further fixing the bottom assembly support 1 and the side fixing support 2 is achieved, the pulling sliding rod 302 is pulled to move in the rotating pulling hole 108, the half-moon clamping groove 303 pushes the connecting rod 305 out, then the limit clamping rod 301 can be pulled out of the limit sliding groove 207, the positioning cavity 209 ensures the sliding stability of the positioning clamping rod 304 and the communication hole 208 ensures the sliding stability of the connecting rod 305 after the separation of the two.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (8)

1. The utility model provides a modular electromechanical antidetonation support, includes end assembly support (1), end assembly support (1) are including assembly support (101), its characterized in that: a plurality of installation slide holes (103) are formed in the inner walls of the two sides of the total bearing support (101), installation slide blocks (104) are slidably installed in the two corresponding installation slide holes (103), contact plates (102) are fixedly installed on the installation slide blocks (104), side fixing supports (2) are installed on the two sides of the bottom total bearing support (1), combined connection structures (3) are installed on the side fixing supports (2) and the bottom total bearing support (1), a positioning slide groove (107) is formed in one side, close to the side fixing supports (2), of the total bearing support (101), a rotation spanner hole (108) is formed in the inner wall, far away from the contact plates (102), of the positioning slide groove (107), the same installation slide rod (105) is fixedly installed on the inner walls of the two sides of the installation slide holes (103), and the installation slide blocks (104) are slidably installed on the installation slide rods (105).

2. A combined electromechanical shock mount according to claim 1, wherein: the side fixed support (2) comprises side support bases (201), two telescopic sliding grooves (203) are symmetrically formed in one sides, close to each other, of the two side support bases (201), telescopic sliding blocks (204) are slidably mounted in the four telescopic sliding grooves (203), the same top pressing plate (202) is fixedly mounted between the four telescopic sliding blocks (204), the same telescopic sliding rod (205) is fixedly mounted on the inner walls of the two sides of the telescopic sliding grooves (203), and the telescopic sliding blocks (204) are slidably mounted on the telescopic sliding rods (205).

3. A combined electromechanical shock mount according to claim 2, wherein: and a limiting chute (207) is formed in one side, close to the assembly support (101), of the side support (201), and the limiting chute (207) corresponds to the positioning chute (107) in position.

4. A combined electromechanical shock mount according to claim 1, wherein: the assembly support (101) is provided with a positioning cavity (209), the inner wall of the bottom of the positioning cavity (209) is provided with a communication hole (208), and the communication hole (208) is communicated with the limiting chute (207).

5. A combined electromechanical shock mount according to claim 1, wherein: the combined connection structure (3) comprises a limit clamping rod (301) and a positioning clamping rod (304), wherein the limit clamping rod (301) is slidably installed in the positioning chute (107), and the positioning clamping rod (304) is slidably installed in the positioning cavity (209).

6. The combined electromechanical shock mount according to claim 5, wherein: the limiting clamping rod (301) is provided with a half-moon-shaped clamping groove (303), the bottom of the positioning clamping rod (304) is fixedly provided with a connecting rod (305), and the connecting rod (305) is clamped with the half-moon-shaped clamping groove (303).

7. The combined electromechanical shock mount according to claim 5, wherein: and a pulling slide rod (302) is fixedly arranged on the limiting clamping rod (301), the pulling slide rod (302) is slidably arranged in the rotating pulling hole (108), a reset spring (306) is slidably arranged in the positioning cavity (209), and two ends of the reset spring (306) are respectively contacted with the inner wall of the top of the positioning cavity (209) and the positioning clamping rod (304).

8. A combined electromechanical shock mount according to claim 1, wherein: the installation slide bar (105) is in sliding sleeve connection with an installation spring (106), two ends of the installation spring (106) are respectively contacted with the installation slide block (104) and the inner wall of the bottom of the installation slide hole (103), the telescopic slide bar (205) is in sliding sleeve connection with a telescopic spring (206), and two ends of the telescopic spring (206) are respectively contacted with the telescopic slide block (204) and the inner wall of the top of the telescopic slide groove (203).