CN212942315U - AOP (argon oxygen decarburization) electroosmosis anode connection structure - Google Patents

Abstract

The utility model belongs to the technical field of building waterproofing, especially an AOP electroosmosis positive pole linking structure, including the connecting plate, the surface mounting of connecting plate has the superconducting wire locating component who is used for fixed anodal superconducting wire, and superconducting wire locating component includes positioning seat and stabilizing block, the one end of stabilizing block is the stiff end, the other end is the free end, the stiff end of stabilizing block with the positioning seat articulates, be equipped with locking Assembly between the free end of stabilizing block and the positioning seat; the AOP electroosmosis anode connection structure of the utility model is convenient to install, and can more stably fix the anode superconducting wire in the concrete or brick wall building, thereby ensuring the continuous waterproof effect; the connection structure can be spliced according to the actual installation mode of the positive superconducting wire, and meanwhile, the distance between two groups of connection structures can be adjusted, so that the connection structure is more convenient to use, adapts to different installation requirements, and effectively reduces the installation difficulty and the production cost.

Description

AOP (argon oxygen decarburization) electroosmosis anode connection structure

Technical Field

The utility model belongs to the technical field of the building is waterproof, concretely relates to AOP electroosmosis is anodal links up structure.

Background

Concrete or brick wall construction is the most common existing construction, and if the concrete or brick wall construction is not subjected to reasonable waterproof measures, in rainy days, rainwater is easy to permeate a wall body to soak the inner wall of a building, the AOP (Advanced osmostic Pulse) technology adopts a series of low-voltage Pulse charges to ionize water molecules in capillary tubes in concrete or brick walls according to the electroosmosis principle (Electro-Osmosis) of water, then the ionized water molecules are actively guided to the outer side of the structure (namely the cathode direction of the upstream face) through capillary holes in the structure, and simultaneously, the water on the outer side is prevented from entering the inner side, in the practical case, the water pressure of more than 600 meters is successfully resisted, and as long as the system keeps the working state, water molecules always move towards the direction of the negative electrode, so that the inner side of the structure is kept in a dry state permanently, and the humidity of the air in the structure can be effectively reduced.

The original AOP electroosmosis positive superconducting wire is simply clamped, and because the positive superconducting wire needs to be fixed for a long time, the simple clamping is difficult to ensure the stability and the durability of the fixation of the positive superconducting wire, so that the waterproof effect is influenced.

SUMMERY OF THE UTILITY MODEL

For solving the above-mentioned problem that exists among the prior art, the utility model provides an AOP electroosmosis positive pole links up structure has convenient to use, easily installation and the good characteristics of stability ability.

In order to achieve the above object, the utility model provides a following technical scheme: an AOP (automatic optic-mechanical plane) electroosmosis anode connection structure comprises a connection plate, wherein one end face of the connection plate is provided with a connection strip, and the other end face of the connection plate is provided with a splicing groove for embedding the end part of the connection strip; the superconducting wire positioning assembly is used for fixing an anode superconducting wire and comprises a positioning seat and a stabilizing block, one end of the stabilizing block is a fixed end, the other end of the stabilizing block is a free end, the fixed end of the stabilizing block is hinged with the positioning seat, and a locking assembly is arranged between the free end of the stabilizing block and the positioning seat; and positioning grooves which are of semicircular structures are respectively arranged on the opposite surfaces of the positioning seat and the stabilizing block.

As an optimal technical scheme of the utility model, two symmetric distribution's connecting block is installed to the lateral surface tip of connecting strip splice the inslot wall install two sets ofly with the corresponding elasticity locking Assembly of connecting block.

As a preferred technical solution of the present invention, the elastic locking assembly includes a locking elastic block and an expansion spring, a connecting groove is formed in the inner wall of the splicing groove, one end of the locking elastic block is movably embedded into the connecting groove, and the other end extends out of the connecting groove, and the expansion spring is distributed between the end surface of the embedded end of the locking elastic block and the bottom of the connecting groove; the outer side surface of the connecting block is an inclined surface, and the outer side surface of the extending end of the locking elastic block is an inclined surface.

As an optimized technical scheme of the utility model, the embedding end outer wall of locking bullet piece is fixed with a spacing ring the port inner wall of spread groove be fixed with No. two spacing rings that a spacing ring is corresponding.

As an optimal technical scheme of the utility model, still include adjusting bolt connecting plate terminal surface has been seted up and has been held the adjustment tank of connecting strip utilize adjusting bolt with connecting plate fixed connection behind the connecting strip embedding adjustment tank.

As a preferred technical scheme of the utility model, locking Assembly includes connection piece and hand bolt, the connection piece is fixed the free end terminal surface of steady piece works as utilize hand bolt to make connection piece and positioning seat fixed connection after steady piece and the positioning seat are closed.

As a preferred technical solution of the present invention, the locking assembly includes a connecting piece, a locking rod and an elastic telescopic rod, the connecting piece is fixed on the free end surface of the stabilizing block, an installation seat is installed on the top surface of the positioning seat, the bottom end of the elastic telescopic rod is connected with the installation seat by a rotating shaft, and the top end of the elastic telescopic rod is fixedly connected with the locking rod; the end face of the connecting piece is provided with a notch for the elastic telescopic rod to penetrate through.

As a preferred technical solution of the present invention, the elastic telescopic rod includes a telescopic connecting rod, a mounting rod and a return spring, a movable groove for movably embedding the bottom end of the telescopic connecting rod is formed in the top surface of the mounting rod, a third limiting ring is fixed on the outer wall of the embedding end of the telescopic connecting rod, a fourth limiting ring is fixed on the inner wall of the port of the movable groove, and the return spring is sleeved on the telescopic connecting rod and located inside the third limiting ring and the fourth limiting ring; locking blocks are fixedly arranged at two ends of the bottom surface of the locking rod, and locking grooves capable of containing the locking blocks are respectively formed at two ends of the top surface of the connecting piece.

Compared with the prior art, the beneficial effects of the utility model are that: the AOP electroosmosis anode connection structure of the utility model is convenient to install, and can more stably fix the anode superconducting wire in the concrete or brick wall building, thereby ensuring the continuous waterproof effect; the connection structure can be spliced according to the actual installation mode of the positive superconducting wire, and meanwhile, the distance between two groups of connection structures can be adjusted, so that the connection structure is more convenient to use, adapts to different installation requirements, and effectively reduces the installation difficulty and the production cost.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of a splicing structure of two connecting plates in the present invention;

FIG. 3 is a schematic front sectional view of the connection plate of the present invention;

fig. 4 is an enlarged schematic view of a portion a of fig. 3 according to the present invention;

fig. 5 is a front structural schematic view of a first form of the locking assembly of the present invention;

fig. 6 is a schematic front view of another form of the locking assembly of the present invention;

in the figure: 1. a connecting plate; 2. a superconducting wire positioning assembly; 3. adjusting the bolt; 4. a connecting strip; 5. connecting blocks; 6. a first adjusting groove; 7. splicing grooves; 8. locking the elastic block; 9. connecting grooves; 10. a tension spring; 11. a first limit ring; 12. a second limiting ring; 13. positioning seats; 14. a stabilizing block; 15. positioning a groove; 16. connecting sheets; 17. a manual bolt; 18. a locking lever; 19. a telescopic connecting rod; 20. mounting a rod; 21. a third limiting ring; 22. a fourth limiting ring; 23. a return spring; 24. a mounting seat; 25. a notch; 26. a locking block; 27. a locking groove; 28. a movable groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example 1

Referring to fig. 1-5, the present invention provides the following technical solutions: an AOP (automatic optic-mechanical plane) electroosmosis anode connection structure comprises a connection plate 1, wherein one end face of the connection plate 1 is provided with a connection strip 4, and the other end face of the connection plate 1 is provided with a splicing groove 7 for embedding the end part of the connection strip 4; the superconducting wire positioning assembly 2 for fixing the anode superconducting wire is mounted on the surface of the connecting plate 1, the superconducting wire positioning assembly 2 comprises a positioning seat 13 and a stabilizing block 14, one end of the stabilizing block 14 is a fixed end, the other end of the stabilizing block 14 is a free end, the fixed end of the stabilizing block 14 is hinged with the positioning seat 13, and a locking assembly is arranged between the free end of the stabilizing block 14 and the positioning seat 13; locating slots 15 which are semicircular structures are respectively formed in opposite surfaces of the locating seat 13 and the stabilizing block 14, when the connecting plate 1 of the connecting structure is fixed in a concrete or brick wall building through bolts, a group of connecting structures are installed at certain transverse distances, if one connecting structure is installed at intervals of 30cm, the positive superconducting wire is fixed through the superconducting wire locating component 2, and the connecting structures can be assembled in the longitudinal direction according to actual installation requirements, as shown in the attached drawing 2, the positive superconducting wire is fixed in a U-shaped bent structure.

Specifically, as shown in fig. 1, fig. 2 and fig. 3, in this embodiment, two connecting blocks 5 are installed at the end of the outer side surface of each connecting strip 4, two sets of elastic locking assemblies corresponding to the connecting blocks 5 are installed on the inner wall of each splicing groove 7, when the splicing of the linking structures is performed, the connecting strip 4 of one linking structure is embedded into the splicing groove 7 of another linking structure, and the splicing stability of the two sets of linking structures is ensured by the cooperation of the elastic locking assemblies and the connecting blocks 5.

Specifically, as shown in fig. 1, fig. 2, fig. 3 and fig. 4, in this embodiment, the elastic locking assembly includes a locking elastic block 8 and a telescopic spring 10, a connecting groove 9 is formed in an inner wall of the splicing groove 7, one end of the locking elastic block 8 is movably embedded into the connecting groove 9, and the other end of the locking elastic block extends out of the connecting groove 9, and the telescopic spring 10 is distributed between an end surface of an embedded end of the locking elastic block 8 and a groove bottom of the connecting groove 9; connecting block 5's lateral surface is the inclined plane, the end lateral surface that stretches out of locking bullet piece 8 is the inclined plane, during in another splice groove 7 that links up the structure is embedded into to connecting strip 4 that links up the structure, because connecting block 5's lateral surface is the inclined plane, the end lateral surface that stretches out of locking bullet piece 8 is the inclined plane, during the embedding, locking bullet piece 8 and the cooperation of connecting block 5 inclined planes, locking bullet piece 8's inclined plane produces thrust to connecting block 5, connecting block 5 is to the inboard removal of spread groove 9, expanding spring 10 in the compression spread groove 9, after locking bullet piece 8 crosses connecting block 5, under expanding spring 10's elastic action, locking bullet piece 8 resets, form the block cooperation with connecting block 5, guarantee the stability that two sets of structures link up the concatenation.

Specifically, according to fig. 4, in this embodiment, a first limit ring 11 is fixed on an outer wall of an embedded end of the locking elastic block 8, a second limit ring 12 corresponding to the first limit ring 11 is fixed on an inner wall of a port of the connection groove 9, and the first limit ring 11 and the second limit ring 12 limit a moving range of the locking elastic block 8, so as to prevent the locking elastic block 8 from being separated from the connection groove 9.

Specifically, as shown in fig. 1 and fig. 3, in this embodiment, the adjusting bolt 3 is further included, a first adjusting groove 6 capable of accommodating the connecting strip 4 is formed in the end surface of the connecting plate 1, the connecting strip 4 is embedded into the first adjusting groove 6 and then fixedly connected with the connecting plate 1 by the adjusting bolt 3, when the longitudinal distance between the two sets of linking structures needs to be adjusted, the adjusting bolt 3 is firstly unscrewed, the length of the connecting strip 4 embedded into the first adjusting groove 6 is changed, and then the adjusting bolt 3 is screwed.

Specifically, according to fig. 1 and 5, in this embodiment, the locking assembly includes a connecting piece 16 and a manual bolt 17, the connecting piece 16 is fixed to the free end face of the stabilizing block 14, after the stabilizing block 14 and the positioning seat 13 are closed, the connecting piece 16 is fixedly connected to the positioning seat 13 by the manual bolt 17, and when the positive superconducting wire is fixed, the manual bolt 17 is screwed down, the stabilizing block 14 is lifted up, the positive superconducting wire is placed in the positioning groove 15, the stabilizing block 14 is covered, and the manual bolt 17 is screwed down.

Example 2

Referring to fig. 1, fig. 2, fig. 3, fig. 4 and fig. 6, the present invention provides the following technical solutions: an AOP (automatic optic-mechanical plane) electroosmosis anode connection structure comprises a connection plate 1, wherein one end face of the connection plate 1 is provided with a connection strip 4, and the other end face of the connection plate 1 is provided with a splicing groove 7 for embedding the end part of the connection strip 4; the superconducting wire positioning assembly 2 for fixing the anode superconducting wire is mounted on the surface of the connecting plate 1, the superconducting wire positioning assembly 2 comprises a positioning seat 13 and a stabilizing block 14, one end of the stabilizing block 14 is a fixed end, the other end of the stabilizing block 14 is a free end, the fixed end of the stabilizing block 14 is hinged with the positioning seat 13, and a locking assembly is arranged between the free end of the stabilizing block 14 and the positioning seat 13; locating slots 15 which are semicircular structures are respectively formed in opposite surfaces of the locating seat 13 and the stabilizing block 14, when the connecting plate 1 of the connecting structure is fixed in a concrete or brick wall building through bolts, a group of connecting structures are installed at certain transverse distances, if one connecting structure is installed at intervals of 30cm, the positive superconducting wire is fixed through the superconducting wire locating component 2, and the connecting structures can be assembled in the longitudinal direction according to actual installation requirements, as shown in the attached drawing 2, the positive superconducting wire is fixed in a U-shaped bent structure.

Specifically, as shown in fig. 1, fig. 2 and fig. 3, in this embodiment, two connecting blocks 5 are installed at the end of the outer side surface of each connecting strip 4, two sets of elastic locking assemblies corresponding to the connecting blocks 5 are installed on the inner wall of each splicing groove 7, when the splicing of the linking structures is performed, the connecting strip 4 of one linking structure is embedded into the splicing groove 7 of another linking structure, and the splicing stability of the two sets of linking structures is ensured by the cooperation of the elastic locking assemblies and the connecting blocks 5.

Specifically, as shown in fig. 1, fig. 2, fig. 3 and fig. 4, in this embodiment, the elastic locking assembly includes a locking elastic block 8 and a telescopic spring 10, a connecting groove 9 is formed in an inner wall of the splicing groove 7, one end of the locking elastic block 8 is movably embedded into the connecting groove 9, and the other end of the locking elastic block extends out of the connecting groove 9, and the telescopic spring 10 is distributed between an end surface of an embedded end of the locking elastic block 8 and a groove bottom of the connecting groove 9; connecting block 5's lateral surface is the inclined plane, the end lateral surface that stretches out of locking bullet piece 8 is the inclined plane, during in another splice groove 7 that links up the structure is embedded into to connecting strip 4 that links up the structure, because connecting block 5's lateral surface is the inclined plane, the end lateral surface that stretches out of locking bullet piece 8 is the inclined plane, during the embedding, locking bullet piece 8 and the cooperation of connecting block 5 inclined planes, locking bullet piece 8's inclined plane produces thrust to connecting block 5, connecting block 5 is to the inboard removal of spread groove 9, expanding spring 10 in the compression spread groove 9, after locking bullet piece 8 crosses connecting block 5, under expanding spring 10's elastic action, locking bullet piece 8 resets, form the block cooperation with connecting block 5, guarantee the stability that two sets of structures link up the concatenation.

Specifically, according to fig. 4, in this embodiment, a first limit ring 11 is fixed on an outer wall of an embedded end of the locking elastic block 8, a second limit ring 12 corresponding to the first limit ring 11 is fixed on an inner wall of a port of the connection groove 9, and the first limit ring 11 and the second limit ring 12 limit a moving range of the locking elastic block 8, so as to prevent the locking elastic block 8 from being separated from the connection groove 9.

Specifically, as shown in fig. 1 and fig. 3, in this embodiment, the adjusting bolt 3 is further included, a first adjusting groove 6 capable of accommodating the connecting strip 4 is formed in the end surface of the connecting plate 1, the connecting strip 4 is embedded into the first adjusting groove 6 and then fixedly connected with the connecting plate 1 by the adjusting bolt 3, when the longitudinal distance between the two sets of linking structures needs to be adjusted, the adjusting bolt 3 is firstly unscrewed, the length of the connecting strip 4 embedded into the first adjusting groove 6 is changed, and then the adjusting bolt 3 is screwed.

Specifically, according to fig. 1 and fig. 6, in this embodiment, the locking assembly includes a connecting piece 16, a locking rod 18 and an elastic telescopic rod, the connecting piece 16 is fixed on the end surface of the free end of the stabilizing block 14, an installation seat 24 is installed on the top surface of the positioning seat 13, the bottom end of the elastic telescopic rod is connected with the installation seat 24 by a rotating shaft, and the top end of the elastic telescopic rod is fixedly connected with the locking rod 18; a notch 25 through which the elastic telescopic rod penetrates is formed in the end face of the connecting piece 16, when the positive superconducting wire is fixed, the elastic telescopic rod is turned to one side, the stabilizing block 14 is lifted, the positive superconducting wire is arranged in the positioning groove 15, the stabilizing block 14 is covered, the locking rod 18 is pulled to enable the elastic telescopic rod to relax, the elastic telescopic rod is turned over, the elastic telescopic rod is arranged in the notch 25, the locking rod 18 is located outside the connecting piece 16, then the locking rod 18 can be loosened, the elastic telescopic rod automatically retracts, the locking rod 18 and the connecting piece 16 form a clamping structure, and the positive superconducting wire is fixed.

Specifically, according to fig. 1 and fig. 6, in this embodiment, the elastic telescopic rod includes a telescopic connecting rod 19, a mounting rod 20 and a return spring 23, a movable groove 28 for movably embedding the bottom end of the telescopic connecting rod 19 is formed in the top surface of the mounting rod 20, a third limiting ring 21 is fixed on the outer wall of the embedding end of the telescopic connecting rod 19, a fourth limiting ring 22 is fixed on the inner wall of the port of the movable groove 28, and the return spring 23 is sleeved on the telescopic connecting rod 19 and is located inside the third limiting ring 21 and the fourth limiting ring 22; locking blocks 26 are fixed at two ends of the bottom surface of the locking rod 18, locking grooves 27 capable of containing the locking blocks 26 are respectively formed at two ends of the top surface of the connecting piece 16, when the elastic telescopic rod is in diastole, the telescopic connecting rod 19 is stretched relative to the mounting rod 20, meanwhile, the third limiting ring 21 and the fourth limiting ring 22 are utilized to compress the return spring 23, and the return spring 23 provides elastic force for automatic return of the telescopic connecting rod 19.

The utility model discloses a theory of operation and use flow: the utility model discloses an AOP electroosmosis anodal connection structure, when using, utilize the bolt to fix connection plate 1 of connection structure in concrete or brick wall building, and every certain lateral distance installation a set of connection structure, if install one at the interval of 30cm, anodal superconducting wire utilizes superconducting wire locating component 2 to fix;

in example 1, when the positive superconducting wire is fixed, the manual bolt 17 is screwed off, the stabilizing block 14 is lifted, the positive superconducting wire is placed in the positioning groove 15, the stabilizing block 14 is covered, and the manual bolt 17 is screwed;

in embodiment 2, when the positive superconducting wire is fixed, the elastic telescopic rod is turned over to one side, the stabilizing block 14 is lifted, the positive superconducting wire is placed in the positioning groove 15, the stabilizing block 14 is covered, the locking rod 18 is pulled to expand the elastic telescopic rod, the elastic telescopic rod is turned over to be placed in the notch 25, the locking rod 18 is located outside the connecting piece 16, and then the locking rod 18 can be released, the elastic telescopic rod automatically retracts to enable the locking rod 18 and the connecting piece 16 to form a clamping structure, and the positive superconducting wire is fixed;

in addition, still can splice like the form shown in figure 2 to two sets of linking structures to the in-service use demand, when carrying out the concatenation of linking structure, make in the splice groove 7 of another linking structure of splice bar 4 embedding of a linking structure to utilize the cooperation of elasticity locking Assembly and connecting block 5, guarantee the stability of two sets of linking structure concatenations.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The utility model provides a positive linking structure of AOP electroosmosis, includes connecting plate (1), its characterized in that: one end face of the connecting plate (1) is provided with a connecting strip (4), and the other end face is provided with a splicing groove (7) for embedding the end part of the connecting strip (4); the surface of the connecting plate (1) is provided with a superconducting wire positioning component (2) for fixing an anode superconducting wire, the superconducting wire positioning component (2) comprises a positioning seat (13) and a stabilizing block (14), one end of the stabilizing block (14) is a fixed end, the other end of the stabilizing block is a free end, the fixed end of the stabilizing block (14) is hinged with the positioning seat (13), and a locking component is arranged between the free end of the stabilizing block (14) and the positioning seat (13); and positioning grooves (15) which are of semicircular structures are respectively arranged on the opposite surfaces of the positioning seat (13) and the stabilizing block (14).

2. The AOP electroosmotic positive electrode adapter structure according to claim 1, wherein: two symmetrically distributed connecting blocks (5) are installed at the end part of the outer side surface of the connecting strip (4), and two groups of elastic locking assemblies corresponding to the connecting blocks (5) are installed on the inner wall of the splicing groove (7).

3. The AOP electroosmotic positive electrode adapter structure according to claim 2, wherein: the elastic locking assembly comprises a locking elastic block (8) and an expansion spring (10), a connecting groove (9) is formed in the inner wall of the splicing groove (7), one end of the locking elastic block (8) is movably embedded into the connecting groove (9), the other end of the locking elastic block extends out of the connecting groove (9), and the expansion spring (10) is distributed between the end face of the embedded end of the locking elastic block (8) and the bottom of the connecting groove (9); the outer side surface of the connecting block (5) is an inclined surface, and the outer side surface of the extending end of the locking elastic block (8) is an inclined surface.

4. An AOP electroosmotic positive electrode adapter structure according to claim 3, wherein: the outer wall of an embedded end of the locking elastic block (8) is fixed with a first limiting ring (11), and the inner wall of a port of the connecting groove (9) is fixed with a second limiting ring (12) corresponding to the first limiting ring (11).

5. The AOP electroosmotic positive electrode adapter structure according to claim 1, wherein: the connecting plate is characterized by further comprising an adjusting bolt (3), a first adjusting groove (6) capable of accommodating the connecting strip (4) is formed in the end face of the connecting plate (1), and the connecting strip (4) is embedded into the first adjusting groove (6) and then fixedly connected with the connecting plate (1) through the adjusting bolt (3).

6. The AOP electroosmotic positive electrode adapter structure according to claim 1, wherein: the locking assembly comprises a connecting piece (16) and a manual bolt (17), the connecting piece (16) is fixed on the end face of the free end of the stabilizing block (14), and when the stabilizing block (14) and the positioning seat (13) are closed, the connecting piece (16) is fixedly connected with the positioning seat (13) through the manual bolt (17).

7. The AOP electroosmotic positive electrode adapter structure according to claim 1, wherein: the locking assembly comprises a connecting piece (16), a locking rod (18) and an elastic telescopic rod, the connecting piece (16) is fixed on the end face of the free end of the stabilizing block (14), an installation seat (24) is installed on the top surface of the positioning seat (13), the bottom end of the elastic telescopic rod is connected with the installation seat (24) through a rotating shaft, and the top end of the elastic telescopic rod is fixedly connected with the locking rod (18); and a notch (25) for the elastic telescopic rod to penetrate through is formed in the end face of the connecting piece (16).

8. The AOP electroosmotic positive electrode adapter structure of claim 7, wherein: the elastic telescopic rod comprises a telescopic connecting rod (19), a mounting rod (20) and a reset spring (23), a movable groove (28) for movably embedding the bottom end of the telescopic connecting rod (19) is formed in the top surface of the mounting rod (20), a third limiting ring (21) is fixed on the outer wall of an embedding end of the telescopic connecting rod (19), a fourth limiting ring (22) is fixed on the inner wall of a port of the movable groove (28), and the reset spring (23) is sleeved on the telescopic connecting rod (19) and is positioned on the inner sides of the third limiting ring (21) and the fourth limiting ring (22); locking blocks (26) are fixed at two ends of the bottom surface of the locking rod (18), and locking grooves (27) capable of accommodating the locking blocks (26) are respectively formed at two ends of the top surface of the connecting piece (16).

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