CN114843937A

CN114843937A - Rubber pad assembly devices of conductor spacer fastener

Info

Publication number: CN114843937A
Application number: CN202210732753.6A
Authority: CN
Inventors: 姚建生; 姚栋宇; 程广荣; 朱小强
Original assignee: Jiangsu Tiannan Electric Power Co ltd
Current assignee: Jiangsu Tiannan Electric Power Co ltd
Priority date: 2022-06-27
Filing date: 2022-06-27
Publication date: 2022-08-02
Anticipated expiration: 2042-06-27
Also published as: CN114843937B

Abstract

The invention discloses a rubber pad assembling mechanism of a spacer wire clamp, which comprises a multi-position assembling disc body, a split type compensation gluing mechanism, a pressure pad mechanism and a plurality of clamping assembling base bodies, wherein the clamping assembling base bodies are annularly and uniformly distributed on the top end surface of the multi-position assembling disc body; the clamping assembly base body is used for clamping the wire clamp main body, the clamping assembly base body can drive the wire clamp main body to be in an opening state or a closing state, and the clamping assembly base body can drive the wire clamp main body to be in the closing state or drive the wire clamp main body to be repeatedly switched between the opening state and the closing state when facing the split type compensation gluing mechanism. The invention can realize the alternate operation of different procedures of a plurality of wire clamp main bodies and greatly improve the production efficiency.

Description

Rubber pad assembly devices of conductor spacer fastener

Technical Field

The invention relates to the technical field of spacer processing, in particular to a rubber pad assembling mechanism of a spacer wire clamp.

Background

The spacer is a fitting which is installed on the split conductors and fixes the space between the split conductors to prevent the conductors from mutually whipping and to suppress the breeze vibration and the sub-span oscillation. The edge of the spacing rod is connected on the lead by a wire jacket.

As shown in fig. 1, the cable clamp is composed of a cable clamp main body 50 capable of opening and closing and a rubber pad 60 installed inside the cable clamp main body 50, and the rubber pad 60 mainly prevents the cable clamp main body 50 supported by metal from directly contacting with a wire to damage the cable.

In the prior art, the process of installing the rubber pad 60 on the wire clamp body 50 is mainly as follows: manually gluing the inner side surface of the wire clamp 50, and then pressing the rubber pad 60 on the inner side surface of the wire clamp main body 50 by a manual or stamping mechanism until the shape is formed; the manual gluing has the disadvantage that the manual gluing is inefficient and only one clamp body 50 can be coated at a time.

Disclosure of Invention

The invention aims to provide a rubber pad assembling mechanism of a spacer wire clamp, which aims to solve the technical problem that in the prior art, the manual gluing efficiency is low, and one worker cannot operate a plurality of spacers at the same time.

In order to solve the technical problems, the invention specifically provides the following technical scheme:

a rubber pad assembling mechanism of a spacer wire clamp comprises a multi-position assembling disc body, a split type compensation gluing mechanism, a pressure pad mechanism and a plurality of clamping assembling base bodies, wherein the clamping assembling base bodies are annularly and uniformly distributed on the top end face of the multi-position assembling disc body, the multi-position assembling disc body can perform intermittent rotation in one direction, and the split type compensation gluing mechanism and the pressure pad mechanism are sequentially arranged beside the periphery of the multi-position assembling disc body along the rotating direction of the multi-position assembling disc body;

the clamping assembly base is used for clamping the wire clamp body and can drive the wire clamp body to be in an opening state or a closing state, the clamping assembly base is just right and can drive the wire clamp body to be in a closing state or a driving state when the split type compensation gluing mechanism repeatedly switches between the opening state and the closing state, and the clamping assembly base is just right and can drive the wire clamp body to be in the opening state when the pressure pad mechanism.

As a preferable scheme of the invention, the split type compensation gluing mechanism comprises an arc-shaped mounting seat, a main engaging body and at least one compensation engaging body, one end of each of the main engaging body and the compensation engaging body is mounted on the arc-shaped mounting seat, the other end of each of the main engaging body and the compensation engaging body extends to the upper side of the top end face of the multi-position assembly tray body, the wire clamp main body can rotate through the main engaging body or the compensation engaging body when being in an open state, the wire clamp main body can be folded on the main engaging body when facing the main engaging body, and the wire clamp main body can be folded on the compensation engaging body when facing the compensation engaging body.

As a preferable scheme of the present invention, the main engaging body and the compensation engaging body are both formed with a glue storage inner cavity, the side walls of the main engaging body and the compensation engaging body are both provided with a plurality of glue releasing channels for communicating the outside with the glue storage inner cavity, and the main engaging body and the compensation engaging body are both provided with a glue overflow driving assembly;

the glue overflow driving assembly is used for extruding the glue in the glue storage inner cavity so as to enable the glue to overflow to the outside from the glue releasing channel, and before the wire clamp main body is in a closed state, the glue overflow driving assembly performs an action of extruding the glue in the glue storage inner cavity.

In a preferred embodiment of the present invention, the main engaging body and the at least one compensation engaging body are different in shape from each other, and at least a part of the main engaging body and the at least one compensation engaging body is in engagement with an inner edge of the wire clamp body.

As a preferable aspect of the present invention, all the glue releasing channels are staggered with each other between the orthographic projection positions of the glue releasing channels on the wire clamp main body by being respectively aligned with the wire clamp main body, so that the glue overflowing from all the glue releasing channels can cover the inner side surface of the wire clamp main body.

As a preferred scheme of the present invention, the clamping assembly base includes a mounting block, a corner mounting portion, two clamping portions, and a driving component;

the installation piece install in on the top face of multiposition assembly disk body, and the axis of installation piece with diameter coincidence or parallel on the terminal surface is decided to multiposition assembly disk body, the corner installation department install in the outer end of installation piece, the corner installation department can with the rotation axis of fastener main part is spacing in the center of self, two the clamping part centre gripping respectively is in the both sides of fastener main part, driving part set up in on the installation piece, and driving part can drive the clamping part with the rotation axis of fastener main part rotates as the center.

As a preferable scheme of the present invention, a first cavity and a second cavity are formed inside the mounting block, and the first cavity and the second cavity are respectively located at two ends of an axis of the mounting block;

the driving part comprises a first sliding driving block, a second sliding driving block, an elastic resetting piece and a synchronous linear extrusion assembly, the clamping part is movably connected with the first sliding drive block through a hinge rod, the first sliding drive block is slidably nested in the first cavity, so as to divide the first cavity into two first sealed cavities, the second slide driving block is slidably nested in the second cavity, the second cavity is divided into two second sealing cavities, the second sealing cavity close to the outer end of the mounting block is communicated with the first sealing cavity close to the outer end of the mounting block through a first communicating air channel, the other first sealing cavity is communicated with the outside atmosphere through a second communicating air channel, the elastic reset piece is connected between one end face of the second sliding drive block and the inner wall of the mounting block, and the other end face of the second sliding drive block extends out of the second cavity.

As a preferable scheme of the present invention, the synchronous linear extrusion assembly includes a driving disc and an extrusion head, the driving disc is rotatably mounted at the center of the multi-position assembly disc, one end of the extrusion head is connected to the second sliding drive block, the other end surface of the extrusion head is a curved surface, a plurality of inner grooves and outer grooves are uniformly arranged on the peripheral side surface of the driving disc, and the end of the curved surface of the extrusion head is in extrusion contact with the inner grooves or the outer grooves.

As a preferable scheme of the present invention, the glue overflow driving assembly includes a storage cylinder installed on the arc-shaped installation seat, a cylindrical inner cavity is formed inside the storage cylinder, a pressure circular plate is installed on an inner wall of the storage cylinder in a slidable manner, the pressure circular plate can divide the cylindrical inner cavity into two sealing cavity parts, one of the sealing cavity parts is communicated with the glue storage inner cavity through an extrusion communicating pipe, the sealing cavity part connected with the extrusion communicating pipe is used for placing glue, the pressure circular plate can translate in the cylindrical inner cavity to extrude the glue located on one side of the pressure circular plate to overflow into the extrusion communicating pipe, and the other sealing cavity part can be connected with an air outlet nozzle of an external air pump through an extrusion driving pipe.

As a preferable aspect of the present invention, the pressure pad mechanism includes a telescopic driving assembly and a pad clip mounted on one end of the telescopic driving assembly, the other end of the telescopic driving assembly is fixed, and an axis of the telescopic driving assembly is parallel to a diameter of the fixed end surface of the multi-position mounting plate.

Compared with the prior art, the invention has the following beneficial effects:

according to the invention, the plurality of wire clamp main bodies are assembled simultaneously through the clamping and assembling base body, so that part of the wire clamp main bodies can be subjected to a gluing process, and part of the wire clamp main bodies can be subjected to a pad pressing process and a folding and solidifying process respectively; due to the special mode of repeatedly opening and closing the wire clamp main body to glue, the wire clamp can be automatically opened when the wire clamp main body is pressed and cushioned on the basis of the opening and closing clamping wire clamp main body, and the production efficiency is further improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

FIG. 1 is a schematic structural view of a wire clamp according to an embodiment of the present invention;

FIG. 2 is a top view of an overall structure in an embodiment of the invention;

FIG. 3 is a top view of the clamping assembly housing according to the embodiment of the present invention;

FIG. 4 is a cross-sectional view of an embodiment of an excessive glue drive assembly.

The reference numerals in the drawings denote the following, respectively:

10-assembling the tray body in multiple positions; 20-a split type compensation gluing mechanism; 30-a pressure pad mechanism; 40-clamping and assembling the base body; 50-a clamp body; 60-rubber pad;

21-arc mounting base; 22-a primary bite body; 23-compensation bite body; 24-glue storage inner cavity; 25-a glue release channel; 26-an overflow driving assembly;

261-a storage cartridge; 262-a cylindrical lumen; 263-pressing the circular plate; 264-extruding the driving tube; 265-extruding a communicating tube;

41-mounting block; 42-corner mounting portion; 43-a drive member; 44-a clamping portion; 45-a first cavity; 46-a second cavity; 47-a first connecting airway; 48-a second communicating air passage;

431-a first slide drive block; 432-a second slide drive block; 433-an elastic restoring member; 434-synchronous linear extrusion assembly;

4341-drive disc; 4342-extrusion head;

31-a telescopic drive assembly; 32-shim clip.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 2-4, the present invention provides a rubber pad assembling mechanism for a spacer clip, which comprises a multi-position assembling disc body 10, a split type compensation gluing mechanism 20, a pressure pad mechanism 30 and a plurality of clamping assembling base bodies 40, wherein the plurality of clamping assembling base bodies 40 are annularly and uniformly distributed on the top end surface of the multi-position assembling disc body 10, the multi-position assembling disc body 10 can perform intermittent rotation in one direction, and the split type compensation gluing mechanism 20 and the pressure pad mechanism 30 are sequentially arranged beside the peripheral side of the multi-position assembling disc body 10 along the rotation direction of the multi-position assembling disc body 10; the clamping assembly base body 40 is used for clamping the wire clamp main body 50, the clamping assembly base body 40 can drive the wire clamp main body 50 to be in an open state or a closed state, the clamping assembly base body 40 can drive the wire clamp main body 50 to be in a closed state or drive the wire clamp main body 50 to be repeatedly switched between the open state and the closed state when facing the split type compensation glue coating mechanism 20, and the clamping assembly base body 40 can drive the wire clamp main body 50 to be in an open state when facing the pressure pad mechanism 30.

In fig. 2, a plurality of wire clamp bodies 50, namely, two wire clamp bodies 50 on the left side of fig. 2, and two wire clamp bodies 50 in the vertical direction are assembled simultaneously through the clamping and assembling base body 40, the gluing process is implemented on four wire clamp bodies 50 in total, and the rest two wire clamp bodies 50 can be respectively subjected to the pressing pad process and the folding and solidifying process, and different processes can be performed in a staggered manner through the station switching setting of the rotation of the multi-position assembling disc body 10, so that the production efficiency is improved.

The split type compensation gluing mechanism 20 comprises an arc-shaped installation seat 21, a main meshing body 22 and at least one compensation meshing body 23, wherein one end of the main meshing body 22 and one end of the compensation meshing body 23 are installed on the arc-shaped installation seat 21, the other end of the main meshing body 22 and the other end of the compensation meshing body 23 extend to the position above the top end face of the multi-position assembling tray body 10, the wire clamp main body 50 can rotate to pass through the main meshing body 22 or the compensation meshing body 23 when being in an open state, the wire clamp main body 50 can be folded on the main meshing body 22 when being opposite to the main meshing body 22, and the wire clamp main body 50 can be folded on the compensation meshing body 23 when being opposite to the compensation meshing body 23. The shape of the main engaging body 22 and the shape of the compensation engaging body 23 are different, and the main engaging body 22 and at least one of the compensation engaging bodies 23 are at least partially matched with the inner side edge of the wire clamp main body 50.

The wire clamp body 50 needs to move to the gluing position following the rotation of the multi-position fitting tray body 10, so that the gluing equipment in the position does not obstruct the passage of the wire clamp body 50 and gluing of the wire clamp body 50 can be realized.

During gluing, only a glue layer needs to be covered on the main engaging body 22 and the compensation engaging body 23, and the wire clamp main body 50 can be repeatedly engaged on the main engaging body 22 and the compensation engaging body 23 respectively, so that the gluing process is realized.

The one-time coverage area of the gluing process is wide, the wire clamp main body 50 is uniform in a mode of adhering glue through occlusion, and the repeated gluing process is easy to realize.

Since the wire clamp main body 50 is rotated and occluded, and the two movable sides of the wire clamp main body 50 do not move in parallel, so that the whole inner side surface of the wire clamp main body 50 is difficult to cover by using an occlusion body, the main occlusion body 22 can compensate the occlusion bodies 23 to complement each other only by the special rotating feeding staggered construction mode, so that the glue is more uniformly covered on the wire clamp main body 50.

A glue storage inner cavity 24 is formed in each of the main engaging body 22 and the compensation engaging body 23, a plurality of glue releasing channels 25 for communicating the outside with the glue storage inner cavity 24 are arranged on each of the side walls of the main engaging body 22 and the compensation engaging body 23, and a glue overflow driving assembly 26 is mounted on each of the main engaging body 22 and the compensation engaging body 23; the glue overflow driving component 26 is used for extruding the glue inside the glue storage cavity 24 so as to enable the glue to overflow from the glue release channel 25 to the outside, and before the wire clamp main body 50 is in a closed state, the glue overflow driving component 26 performs an action of extruding the glue inside the glue storage cavity 24.

By staggering the time point of the glue overflowing action driven by the glue overflowing driving assembly 26 and the time point of the completely closed wire clamp body 50 back and forth, the phenomenon that the closing pressure of the wire clamp body 50 influences the seepage of the glue is avoided.

Wherein all the glue releasing channels 25 are staggered with each other between the orthographic projection positions on the wire clamp main body 50 by respectively aligning with the wire clamp main body 50, so that the glue overflowing from all the glue releasing channels 25 can cover the inner side surface of the wire clamp main body 50.

Because a gap must exist between the glue releasing channel 25 and the adjacent glue releasing channel 25, so that the glue cannot completely cover the surface of single occlusion, the number of the compensation occlusion bodies 23 can be increased to change the position of the glue releasing channel 25 of single occlusion facing the wire clamp main body 50 through the special mode of rotary feeding staggered construction, so as to realize the coverage of the glue.

The clamping assembly base body 40 comprises a mounting block 41, a corner mounting part 42, two clamping parts 44 and a driving part 43; the installation piece 41 is installed in on the top terminal surface of multiposition assembly disk body 10, and the axis of installation piece 41 with diameter coincidence or parallel on the fixed terminal surface of multiposition assembly disk body 10, corner installation department 42 install in the outer end of installation piece 41, corner installation department 42 can with the rotation axis of fastener main part 50 is spacing in the center of self, two clamping part 44 centre gripping respectively is in the both sides of fastener main part 50, actuating member 43 set up in on the installation piece 41, and actuating member 43 can drive clamping part 44 uses the rotation axis of fastener main part 50 rotates as the center.

Due to the special rotary feeding staggered construction mode, when the multi-position assembling disc body 10 rotates, the positions of the wire clamp main bodies 50 are staggered, namely after the multi-position assembling disc body 10 rotates by 60 degrees, the positions of the wire clamp main bodies 50 need to be processed once, and therefore the driving structure is further reduced by utilizing a synchronous processing mode.

A first cavity 45 and a second cavity 46 are formed inside the mounting block 41, and the first cavity 45 and the second cavity 46 are respectively located at two ends of the axis of the mounting block 41; the driving part 43 comprises a first sliding driving block 431, a second sliding driving block 432, an elastic restoring piece 433 and a synchronous linear extrusion assembly 434; the clamping portion 44 is movably connected with the first sliding drive block 431 through a hinge rod, the first sliding drive block 431 is slidably nested with the first cavity 45 to divide the first cavity 45 into two first sealed cavities, the second sliding drive block 432 is slidably nested with the second cavity 46 to divide the second cavity 46 into two second sealed cavities, the second sealed cavity close to the outer end of the mounting block 41 is communicated with the first sealed cavity close to the outer end of the mounting block 41 through a first communicating air channel 47, the other first sealed cavity is communicated with the outside atmosphere through a second communicating air channel 48, the elastic reset piece 433 is connected between one end face of the second sliding drive block 432 and the inner wall of the mounting block 41, and the other end face of the second sliding drive block 432 extends out of the second cavity 46.

The synchronous linear extrusion assembly 434 includes a driving disk 4341 and an extrusion head 4342, the driving disk 4341 is rotatably mounted at the center of the multi-position assembly disk 10, one end of the extrusion head 4342 is connected to the second sliding drive block 432, the other end surface of the extrusion head 4342 is a curved surface, a plurality of inner grooves and outer grooves are uniformly arranged on the peripheral side surface of the driving disk 4341, and the end of the curved surface of the extrusion head 4342 is in extrusion contact with the inner grooves or the outer grooves.

When the driving disk 4341 rotates by 60 degrees, the squeezing head 4342 is squeezed to slide toward the outer end of the second cavity 46, which causes the volume of the second sealing cavity at the outer end to decrease, so that the squeezed gas moves into the first sealing cavity at the outer end through the first communicating channel 47, which causes the gas pressure in the first sealing cavity to increase, and thus the high pressure in the first sealing cavity drives the first sliding-driving block 431 to slide toward the inner end, which causes the wire clamp body 50 to open.

The glue overflow driving assembly 26 includes a storage cylinder 261 mounted on the arc-shaped mounting base 21, a cylindrical inner cavity 262 is formed inside the storage cylinder 261, a pressure circular plate 263 is slidably mounted on an inner wall of the storage cylinder 261, the pressure circular plate 263 can divide the cylindrical inner cavity 262 into two sealing cavity parts, one of the sealing cavity parts is communicated with the glue storage inner cavity 24 through an extrusion communicating pipe 265, the sealing cavity part connected with the extrusion communicating pipe 265 is used for placing glue, the pressure circular plate 263 can translate in the cylindrical inner cavity 262 to extrude the glue located on one side of the pressure circular plate 263 to overflow into the extrusion communicating pipe, and the other sealing cavity part can be connected with an air outlet nozzle of an external air pump through an extrusion driving pipe 264.

The pressure pad mechanism 30 includes a telescopic driving assembly 31 and a pad clip 32 mounted on one end of the telescopic driving assembly 31, the other end of the telescopic driving assembly 31 is fixed, and the axis of the telescopic driving assembly 31 is parallel to the diameter of the fixed end face of the multi-position assembling tray 10.

Due to the special mode of repeatedly opening and closing the wire clamp main body 50 for gluing, the wire clamp can be automatically opened when the wire clamp is pressed and cushioned on the basis of the opening and closing clamping wire clamp main body 50, and the production efficiency is further improved.

The above embodiments are only exemplary embodiments of the present application, and are not intended to limit the present application, and the protection scope of the present application is defined by the claims. Various modifications and equivalents may be made by those skilled in the art within the spirit and scope of the present application and such modifications and equivalents should also be considered to be within the scope of the present application.

Claims

1. The rubber pad assembling mechanism of the spacer wire clamp is characterized by comprising a multi-position assembling disc body (10), a split type compensation gluing mechanism (20), a pressure pad mechanism (30) and a plurality of clamping assembling base bodies (40), wherein the clamping assembling base bodies (40) are annularly and uniformly distributed on the top end face of the multi-position assembling disc body (10), the multi-position assembling disc body (10) can rotate intermittently in one direction, and the split type compensation gluing mechanism (20) and the pressure pad mechanism (30) are sequentially arranged beside the peripheral side of the multi-position assembling disc body (10) along the rotating direction of the multi-position assembling disc body (10);

the clamp assembly base body (40) is used for clamping a clamp body (50), the clamp assembly base body (40) can drive the clamp body (50) to be in an open state or a closed state, the clamp assembly base body (40) is just opposite to the split type compensation gluing mechanism (20) and can drive the clamp body (50) to be in a closed state or to drive the clamp body (50) to be repeatedly switched between the open state and the closed state, and the clamp assembly base body (40) is just opposite to the pressure pad mechanism (30) and can drive the clamp body (50) to be in the open state.

2. The rubber pad assembling mechanism of the spacer wire clamp according to claim 1, wherein the split compensation gluing mechanism (20) comprises an arc-shaped mounting seat (21), a main engaging body (22) and at least one compensation engaging body (23), one end of each of the main engaging body (22) and the compensation engaging body (23) is mounted on the arc-shaped mounting seat (21), the other end of each of the main engaging body (22) and the compensation engaging body (23) extends above the top end face of the multi-position assembling plate body (10), the wire clamp main body (50) can rotate through the main engaging body (22) or the compensation engaging body (23) when in an open state, the wire clamp main body (50) can be folded on the main engaging body (22) when facing the main engaging body (22), and the wire clamp main body (50) can be folded on the compensation engaging body (23) when facing the compensation engaging body (23), can be folded onto the compensating bite body (23).

3. The rubber gasket assembling mechanism of the spacer wire clamp according to claim 2, wherein the main engaging body (22) and the compensation engaging body (23) are respectively provided with a rubber storage inner cavity (24), the side walls of the main engaging body (22) and the compensation engaging body (23) are respectively provided with a plurality of rubber release channels (25) for communicating the outside with the rubber storage inner cavities (24), and the main engaging body (22) and the compensation engaging body (23) are respectively provided with a rubber overflow driving assembly (26);

the glue overflow driving component (26) is used for extruding the glue in the glue storage inner cavity (24) so as to enable the glue to overflow to the outside from the glue releasing channel (25), and before the wire clamp main body (50) is in a closed state, the glue overflow driving component (26) performs an action of extruding the glue in the glue storage inner cavity (24).

4. A rubber pad assembly mechanism for a spacer clip according to claim 3, wherein the shape of the main engaging body (22) and the shape of the compensating engaging bodies (23) are different from each other, and the main engaging body (22) and at least one of the compensating engaging bodies (23) are at least partially fitted to the inner side edge of the clip body (50).

5. A rubber pad assembling mechanism of a spacer wire clamp as claimed in claim 4, wherein all the glue releasing channels (25) are staggered with each other between the orthographic projection positions of the wire clamp main bodies (50) by aligning with the wire clamp main bodies (50) respectively, so that the glue overflowing in all the glue releasing channels (25) can cover the inner side surfaces of the wire clamp main bodies (50).

6. A rubber pad assembling mechanism of a spacer clip according to claim 5, wherein said clamp assembling body (40) comprises a mounting block (41), a corner mounting portion (42), two clamping portions (44), and a driving member (43);

the mounting block (41) is mounted on the top end face of the multi-position assembling disc body (10), the axis of the mounting block (41) coincides with or is parallel to the diameter of the fixed end face of the multi-position assembling disc body (10), the corner mounting portion (42) is mounted at the outer end of the mounting block (41), the corner mounting portion (42) can limit the rotating shaft of the wire clamp body (50) on the center of the corner mounting portion, the two clamping portions (44) are clamped on two sides of the wire clamp body (50) respectively, the driving part (43) is arranged on the mounting block (41), and the driving part (43) can drive the clamping portions (44) to rotate by taking the rotating shaft of the wire clamp body (50) as the center.

7. A rubber gasket assembling mechanism of a spacer wire clip as claimed in claim 6, wherein the mounting block (41) is internally formed with a first cavity (45) and a second cavity (46), the first cavity (45) and the second cavity (46) being respectively located at both ends of the axis of the mounting block (41);

the driving part (43) comprises a first sliding driving block (431), a second sliding driving block (432), an elastic resetting piece (433) and a synchronous linear extrusion assembly (434), the clamping part (44) is movably connected with the first sliding driving block (431) through a hinged rod, the first sliding driving block (431) is slidably nested in the first cavity (45) to divide the first cavity (45) into two first sealed cavities, the second sliding driving block (432) is slidably nested in the second cavity (46) to divide the second cavity (46) into two second sealed cavities, the second sealed cavity close to the outer end of the mounting block (41) is communicated with the first sealed cavity close to the outer end of the mounting block (41) through a first communicating air channel (47), and the other first sealed cavity is communicated with the outside atmosphere through a second communicating air channel (48), the elastic reset piece (433) is connected between one end face of the second sliding drive block (432) and the inner wall of the mounting block (41), and the other end face of the second sliding drive block (432) extends out of the second cavity (46).

8. The rubber gasket assembling mechanism of a spacer wire clamp according to claim 7, wherein the synchronous linear extrusion assembly (434) comprises a driving disk (4341) and an extrusion head (4342), the driving disk (4341) is rotatably mounted at the center of the multi-position assembling disk body (10), one end of the extrusion head (4342) is connected to the second sliding driving block (432), the other end surface of the extrusion head (4342) is a curved surface, a plurality of inner grooves and outer grooves are uniformly arranged on the peripheral side surface of the driving disk (4341), and the curved surface end of the extrusion head (4342) is in extrusion contact with the inner grooves or the outer grooves.

9. The rubber gasket assembly mechanism of a spacer wire clamp according to claim 8, wherein the flash drive assembly (26) comprises a storage cylinder (261) mounted on the arc-shaped mounting seat (21), a cylindrical inner cavity (262) is formed inside the storage cylinder (261), a pressure circular plate (263) is slidably mounted on the inner wall of the storage cylinder (261), the pressure circular plate (263) can divide the cylindrical inner cavity (262) into two sealing cavity parts, one of the sealing cavity parts is communicated with the rubber storage inner cavity (24) through a squeezing communicating pipe (265), the sealing cavity part connected with the squeezing communicating pipe (265) is used for placing glue, the pressure circular plate (263) can translate in the cylindrical inner cavity (262) to squeeze the glue on one side of the pressure circular plate (263) to overflow into the squeezing communicating pipe, the other sealing chamber part can be connected with an air outlet nozzle of an external air pump through a squeezing driving pipe (264).

10. A rubber gasket mounting mechanism for a spacer clip according to claim 9, wherein said pressure pad mechanism (30) comprises a telescopic driving assembly (31) and a gasket holder (32) mounted to one end of said telescopic driving assembly (31), the other end of said telescopic driving assembly (31) being fixed, and the axis of said telescopic driving assembly (31) being parallel to the diameter of said fixed end face of said multi-position mounting plate (10).