CN115491628B

CN115491628B - Be used for wire rope tinning processingequipment

Info

Publication number: CN115491628B
Application number: CN202211168144.9A
Authority: CN
Inventors: 范本涛
Original assignee: Nantong Yifan Steel Rope Co ltd
Current assignee: Nantong Yifan Steel Rope Co ltd
Priority date: 2022-09-23
Filing date: 2022-09-23
Publication date: 2024-01-19
Anticipated expiration: 2042-09-23
Also published as: CN115491628A

Abstract

The invention discloses a tinning processing device for a steel wire rope, which comprises a tinning processing heat energy recovery mechanism, wherein the tinning processing heat energy recovery mechanism comprises a heating main body and a heat preservation shell frame, the heating main body is electrically connected through an external power supply, the tinning processing heat energy recovery mechanism further comprises a heat energy recovery main body, the heating main body is fixedly arranged through the inner end of the heat preservation shell frame, the heat energy recovery main body comprises an outer guide wheel, a heat storage block, an inner guide wheel and a chain belt, the heating main body is positioned on the upper side of the middle part of the heat energy recovery main body, the outer guide wheel is symmetrically and rotatably arranged at the inner end of the heat preservation shell frame, the heat storage block is uniformly distributed at the outer end of the chain belt, the heat storage block is fixedly connected with the chain belt, the inner guide wheel is symmetrically and rotatably arranged at the inner end of the lower part of the heat preservation shell frame, and the outer end of the outer guide wheel and the heat storage block are rotatably extruded together. The invention relates to the technical field of steel wire rope processing equipment, which can improve the utilization rate of heat energy and better meet the use requirement.

Description

Be used for wire rope tinning processingequipment

Technical Field

The invention relates to the technical field of steel wire rope processing equipment, in particular to a tin plating processing device for a steel wire rope.

Background

Tin plating and its alloy are coating with good weldability and certain corrosion resistance, and are widely used in electronic components and printed circuit boards; the preparation of the tin layer is widely applied in industry due to simplicity and easiness in electroplating, dip plating, chemical plating and other methods except for physical methods such as hot dipping, spraying and the like, wherein the physical method is to smear tin outside a target after heating and melting the tin, and then cool and fix the tin for tinning;

the conventional steel wire rope tinning work mainly adopts the traction equipment to drag the steel wire to pass through the tin water of heating, leaves the heating zone after the steel wire is stained with tin water and dispels the heat and solidify and reach the purpose of tinning, because the heat dissipation in-process needs to run off a large amount of heat, causes certain energy extravagant problem, so a scheme that can alleviate above-mentioned problem is urgently needed.

Disclosure of Invention

The invention aims to provide a tinning device for a steel wire rope, which is used for solving the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a be used for wire rope tinning processingequipment, includes tinning processing heat recovery mechanism, tinning processing heat recovery mechanism includes heating main part and heat preservation shell frame, heating main part is through external power supply electric connection, tinning processing heat recovery mechanism still includes the heat recovery main part, the heating main part is through the inner fixed mounting of heat preservation shell frame, the heat recovery main part includes outer guide pulley, heat accumulation piece, interior guide pulley and chain belt, the heating main part is located the middle part upside of heat recovery main part, the inner at the heat preservation shell frame is installed in outer guide pulley symmetry rotation, heat accumulation piece evenly distributed is at the outer end of chain belt, heat accumulation piece and chain belt fixed connection are in the same place, interior guide pulley symmetry rotation is installed at the lower part inner of heat preservation shell frame, the outer end of outer guide pulley rolls the extrusion together with the heat accumulation piece, the outer end of chain belt is cup jointed and is installed the outer end of inner guide pulley.

Preferably, the heating main body comprises a heater, the heater passes through external power supply electric connection, the heating main body still includes heat-conducting plate, baffle and heat preservation shell, the lower extreme fixed connection of heat-conducting plate is in the upper end of heat preservation shell, the heater pastes the lower extreme at the heat-conducting plate, heater and heat-conducting plate fixed connection are in the same place, baffle symmetry fixed connection is at the side of heat-conducting plate, the side fixed connection of baffle is at the inner of heat preservation shell frame.

Preferably, the lower end of the inner side of the heat conducting plate is provided with a groove.

Preferably, the tinning heat energy recovery mechanism further comprises a guide main body, the guide main body comprises a heat insulation cover, a bending roller, a first sliding rod, a first guide sleeve and a fixed shaft, the lower end of the heat insulation cover is fixedly arranged at the upper end of the middle of the heat insulation shell, the bending roller is positioned at the inner side of the heat insulation cover, the lower end of the bending roller is pressed at the upper end of the heat conducting plate, the first sliding rod penetrates through the first guide sleeve in a sliding manner, the outer end of the first guide sleeve is fixedly connected with the heat insulation shell, the upper end of the first sliding rod is fixedly connected with the lower end of the fixed shaft, the fixed shaft penetrates through the bending roller, the bending roller and the fixed shaft are rotatably arranged together, the fixed shaft further penetrates through the heat insulation cover, and the fixed shaft is in sliding contact with the heat insulation cover.

Preferably, the guiding main body further comprises a tin guiding groove, and the tin guiding groove is uniformly formed in the outer end of the bending roller.

Preferably, the guide main body further comprises a balance weight, and the side end of the balance weight is fixedly connected to the side end of the fixing shaft, which is opposite to the press bending roller.

Preferably, the side end of the heat preservation cover is hollowed out and provided with a guide groove, and the fixed shaft is in sliding contact with the guide groove.

Preferably, the tinning processing heat energy recovery mechanism further comprises a compression guide body, the compression guide body comprises a compression guide wheel, a second guide sleeve, a second sliding rod and a bearing seat, the second guide sleeve, the second sliding rod and the bearing seat are symmetrically arranged on the outer side of the compression guide wheel, the bearing seat and the compression guide wheel are rotationally connected together, the lower end of the bearing seat is fixedly connected to the upper end of the second sliding rod, the second sliding rod penetrates through the second guide sleeve, the second guide sleeve is in sliding contact with the second sliding rod, and the second guide sleeve is symmetrically and fixedly connected to the outer side end of the heat insulation shell frame.

Preferably, the compressing actuating main body further comprises a tension spring, the tension spring is sleeved on the outer side of the second sliding rod, the upper end of the tension spring is fixedly connected to the lower end of the bearing seat, and the lower end of the tension spring is fixedly connected to the upper end of the second guide sleeve.

Preferably, the first sliding rod is a hexagonal prism, and the inner end of the first guide sleeve is wrapped at the outer end of the first sliding rod.

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

1. the heat storage block rotates along the outer end of the inner guide wheel by means of external force, so that the heat storage block and a target steel wire synchronously move, after the steel wire passes through the heating main body for galvanization, tin on the outer surface of the target steel wire is solidified by utilizing a gap between the heat storage block and the heating main body, after a part of the steel wire which is just solidified moves to the upper end of the heat storage block, heat of the steel wire is evenly distributed to the heat storage block, heat energy stored by the heat storage block is transferred to an unheated galvanized steel wire to be preheated, heat energy of the just galvanized steel wire is absorbed by the heat storage block, and the heated heat storage block is brought to the unheated steel wire to be preheated by a chain belt, so that the purpose of reducing the heat loss of the heating main body is achieved, the heating energy of the heating main body is further reduced, and the purpose of saving energy is achieved; the inner part of the heat conducting plate is used for containing molten tin, the heater is used for heating the heat conducting plate, so that tin is kept in a liquid state, after the steel wire passes through the inner side of the heat conducting plate, the high-temperature molten tin is stained, and after the tin-receiving part of the steel wire leaves the inner side of the heat conducting plate, the tin is solidified on the outer surface of the steel wire; the groove gathers molten tin, so that the problem that one surface of the steel wire, which is contacted with the heat conducting plate, is difficult to receive tin is solved, and compared with the existing working mode of direct heating and cooling, the energy utilization rate is improved.

2. The method comprises the steps that a target steel wire is pressed into the inner side of a heat conducting plate by using a bending roller to carry out tinning, heat energy loss of the bending roller is relieved at the outer side of the bending roller by using a heat insulation cover, the moving direction of a fixed shaft is guided by using a first guide sleeve, so that the purpose of stabilizing the vertical direction of the bending roller is achieved, the lower end of the bending roller is extruded together with the inner end of the heat conducting plate through the steel wire, the target steel wire is pressed into a heating main body to carry out tinning through the bending roller, the purpose of stabilizing the trend of the target steel wire tinning is achieved, and the stability of tinning is further ensured; the upper part of the steel wire is difficult to receive tin after being extruded by the bending roller, when the steel wire initially leaves the bending roller, the residual molten tin in the tin guiding groove is poured at the upper end of the steel wire, so that the molten tin flows downwards along the steel wire until solidification is achieved, and further, the effect of uniform galvanization is achieved; the balance weight is utilized to overcome the bias of the bending roller to the first slide bar, so that the aim of balancing the pressure direction above the first slide bar is fulfilled, and the sliding stability of the first slide bar along the first guide sleeve is further ensured; the fixed shaft penetrates through the heat insulation cover through the guide groove to provide buffer distance for the bending roller, so that self-adaptive steel wire tension of the bending roller is facilitated.

3. The weight of the compaction guide wheel is utilized to act on the steel wire, so that the steel wire can be firmly extruded at the upper end of the heat storage block, the effect of increasing the friction force between the steel wire and the heat storage block is achieved, the traction force of the steel wire is utilized to drive the heat storage block, and further the aim of driving the heat recovery main body to operate through driving the chain belt to rotate through the heat storage block is achieved, so that the steel wire and the heat recovery main body are compacted through the weight of the compaction guide wheel, the aim of driving the heat recovery main body to operate through the traction force of the steel wire is achieved, the heat recovery main body is prevented from being independently provided with kinetic energy traction operation, the energy conversion part is reduced through the mode of reducing the power source, the overall operation resistance is further reduced, and the energy utilization rate is improved; the pressure of the compression guide wheel to the steel wire is enhanced by using a tension spring; the six edges of the first slide bar are utilized to prevent the first slide bar from rotating in the first guide sleeve, so that the stability of the first slide bar in the direction is improved.

Drawings

FIG. 1 is a schematic diagram of the main structure of the present invention;

FIG. 2 is a schematic view of a heat energy recovery main body structure of the present invention;

FIG. 3 is a schematic view of a split structure of a heating body according to the present invention;

FIG. 4 is a schematic view of a guiding body splitting structure according to the present invention;

FIG. 5 is an enlarged schematic view of the guide body of the present invention at A;

fig. 6 is a schematic view of the structure of the compression actuation body of the present invention.

In the figure: 1. a tinning heat energy recovery mechanism; 2. a heat energy recovery main body; 3. heating the body; 4. a guide body; 5. a heat preservation shell frame; 6. compressing the actuating body; 7. an outer guide wheel; 8. a heat storage block; 9. an inner guide wheel; 10. a chain belt; 11. a heat conductive plate; 12. a baffle; 13. a thermal insulation shell; 14. a heater; 15. a thermal insulation cover; 16. bending rollers; 17. a tin guiding groove; 18. a first slide bar; 19. the first guide sleeve; 20. balance weights; 21. a fixed shaft; 22. a guide groove; 23. compressing the guide wheel; 24. a tension spring; 25. a second guide sleeve; 26. a second slide bar; 27. and a bearing seat.

Detailed Description

The technical solutions of the embodiments of the present invention will be clearly and completely described below in conjunction with the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments.

In the description of the present invention, it should be noted that, directions or positional relationships indicated by terms such as "upper", "lower", "inner", "outer", "front", "rear", "both ends", "one end", "the other end", etc., are directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, are for improving the connection between the description and the drawings and increasing the clarity of description, and do not indicate or imply that the apparatus or elements referred to must have a specific direction, be constructed and operated in a specific direction, and thus should not be construed as limiting the present invention.

Example 1

Referring to fig. 1-2, a tinning processing device for a steel wire rope comprises a tinning processing heat energy recovery mechanism 1, wherein the tinning processing heat energy recovery mechanism 1 comprises a heating main body 3 and a heat preservation shell frame 5, the heating main body 3 is electrically connected through an external power supply, the tinning processing heat energy recovery mechanism 1 further comprises a heat energy recovery main body 2, the heating main body 3 is fixedly installed through the inner end of the heat preservation shell frame 5, the heat energy recovery main body 2 comprises an outer guide wheel 7, a heat storage block 8, an inner guide wheel 9 and a chain belt 10, the heating main body 3 is positioned on the upper side of the middle part of the heat energy recovery main body 2, the outer guide wheel 7 is symmetrically and rotatably installed at the inner end of the heat preservation shell frame 5, the heat storage block 8 is fixedly connected with the chain belt 10, the inner guide wheel 9 is symmetrically and rotatably installed at the lower inner end of the heat preservation shell frame 5, the outer end of the outer guide wheel 7 and the heat storage block 8 are in rolling extrusion together, and the inner end of the chain belt 10 is sleeved and installed at the outer end of the inner guide wheel 9; the heat storage block 8 rotates along the outer end of the inner guide wheel 9 by means of external force, so that the heat storage block 8 and a target steel wire synchronously move, after the steel wire passes through the heating main body 3 for galvanization, tin on the outer surface of the target steel wire is solidified by utilizing a gap between the heat storage block 8 and the heating main body 3, after a part of the steel wire which is just solidified moves to the upper end of the heat storage block 8, heat energy stored by the heat storage block 8 is transferred to a non-heated galvanized steel wire to preheat the heat energy of the steel wire which is just galvanized by the heat storage block 8, and the heated heat storage block 8 is brought to the non-galvanized steel wire to preheat by the chain belt 10, so that the purpose of reducing the heat loss of the heating main body 3 is achieved, the heating energy of the heating main body 3 is further reduced, and the purpose of saving energy is achieved.

Example two

Referring to fig. 3, the heating main body 3 includes a heater 14, the heater 14 is electrically connected through an external power supply, the heating main body 3 further includes a heat conducting plate 11, a baffle 12 and a heat insulation shell 13, the lower end of the heat conducting plate 11 is fixedly connected to the upper end of the heat insulation shell 13, the heater 14 is attached to the lower end of the heat conducting plate 11, the heater 14 is fixedly connected with the heat conducting plate 11, the baffle 12 is symmetrically and fixedly connected to the side end of the heat conducting plate 11, and the side end of the baffle 12 is fixedly connected to the inner end of the heat insulation shell frame 5; the inner part of the heat conducting plate 11 is used for containing molten tin, the heat conducting plate 11 is heated by the heater 14 to keep tin in a liquid state, after the steel wire passes through the inner side of the heat conducting plate 11, the steel wire is stained with molten tin after being subjected to high temperature, and after the tin-receiving part of the steel wire leaves the inner side of the heat conducting plate 11, the tin is solidified on the outer surface of the steel wire.

The lower end of the inner side of the heat-conducting plate 11 is provided with a groove; the groove gathers molten tin, so that the problem that the surface of the steel wire, which is contacted with the heat conducting plate 11, is difficult to receive tin is prevented.

Example III

Referring to fig. 4, the tinning heat energy recovery mechanism 1 further includes a guiding body 4, the guiding body 4 includes a heat insulation cover 15, a bending roller 16, a first sliding rod 18, a first guide sleeve 19 and a fixed shaft 21, the lower end of the heat insulation cover 15 is fixedly installed at the upper end of the middle of the heat insulation shell frame 5, the bending roller 16 is located at the inner side of the heat insulation cover 15, the lower end of the bending roller 16 is pressed at the upper end of the heat conducting plate 11, the first sliding rod 18 slides through the first guide sleeve 19, the outer end of the first guide sleeve 19 is fixedly connected through the heat insulation shell frame 5, the upper end of the first sliding rod 18 is fixedly connected at the lower end of the fixed shaft 21, the fixed shaft 21 penetrates through the bending roller 16, the bending roller 16 and the fixed shaft 21 are rotatably installed together, the fixed shaft 21 also penetrates through the heat insulation cover 15, and the fixed shaft 21 is in sliding contact with the heat insulation cover 15; the target steel wire is pressed into the inner side of the heat conducting plate 11 by using the bending roller 16 to carry out tin plating work, the heat energy loss of the bending roller 16 is relieved by using the heat insulation cover 15 to cover the outer side of the bending roller 16, and the moving direction of the fixed shaft 21 is guided by using the first guide sleeve 19, so that the purpose of stabilizing the vertical direction of the bending roller 16 is achieved, the lower end of the bending roller 16 is extruded with the inner end of the heat conducting plate 11 together through the steel wire, the target steel wire is pressed into the heating main body 3 to carry out tin plating through the bending roller 16, the purpose of stabilizing the tin plating trend of the target steel wire is achieved, and the stability of the tin plating work is further ensured.

The guiding main body 4 also comprises a tin guiding groove 17, and the tin guiding groove 17 is uniformly arranged at the outer end of the press bending roller 16; the upper part of the steel wire is difficult to receive tin after being extruded by the bending roller 16, when the steel wire initially leaves the bending roller 16, the upper end of the steel wire is poured with residual molten tin in the tin guiding groove 17, so that the molten tin flows downwards along the steel wire until solidification is achieved, and further, the uniform galvanization effect is achieved.

The guide main body 4 further comprises a balance weight 20, and the side end of the balance weight 20 is fixedly connected with the side end of the fixed shaft 21, which is away from the press bending roller 16; the balance weight 20 is utilized to overcome the bias of the bending roller 16 to the first slide bar 18, so that the purpose of balancing the pressure direction above the first slide bar 18 is achieved, and the sliding stability of the first slide bar 18 along the first guide sleeve 19 is further ensured.

Referring to fig. 5, a guide groove 22 is hollowed out at the side end of the heat insulation cover 15, and a fixed shaft 21 is in sliding contact with the guide groove 22; the fixed shaft 21 penetrates through the heat insulation cover 15 through the guide groove 22, so that the fixed shaft 21 can move upwards along the inside of the guide groove 22 to buffer the bending roller 16 from the self-adaptive steel wire tension of the bending roller 16.

Example IV

Referring to fig. 6, the tinning heat energy recovery mechanism 1 further includes a compression guiding body 6, the compression guiding body 6 includes a compression guide wheel 23, a second guide sleeve 25, a second slide bar 26 and a bearing seat 27, the second guide sleeve 25, the second slide bar 26 and the bearing seat 27 are symmetrically arranged at the outer side of the compression guide wheel 23, the bearing seat 27 is rotationally connected with the compression guide wheel 23, the lower end of the bearing seat 27 is fixedly connected with the upper end of the second slide bar 26, the second slide bar 26 penetrates through the second guide sleeve 25, the second guide sleeve 25 is in sliding contact with the second slide bar 26, and the second guide sleeve 25 is symmetrically and fixedly connected with the outer side end of the heat insulation shell frame 5; utilize the weight that compresses tightly guide pulley 23 to act on the steel wire for the steel wire can firmly extrude in the upper end of heat accumulation piece 8, play the effect that increases the frictional force between steel wire and the heat accumulation piece 8, utilize the steel wire traction force to drive heat accumulation piece 8, and then reach and drive chain belt 10 through heat accumulation piece 8 and rotate, make heat accumulation piece 8 self can reciprocate into waste heat recovery work, compress tightly steel wire and heat recovery main part 2 through the weight that compresses tightly guide pulley 23, play and drive heat recovery main part 2 moving purpose with the help of the traction force of steel wire, thereby avoided heat recovery main part 2 to set up kinetic energy alone and pull the operation, through the mode that reduces the power supply, reduced energy conversion part, and then reached and reduced whole running resistance, improved energy utilization ratio.

The compression guide main body 6 further comprises a tension spring 24, the tension spring 24 is sleeved on the outer side of the second slide rod 26, the upper end of the tension spring 24 is fixedly connected to the lower end of the bearing seat 27, and the lower end of the tension spring 24 is fixedly connected to the upper end of the second guide sleeve 25; the tension spring 24 is used for reinforcing the pressure of the compression guide wheel 23 on the steel wire, so that the transmission guide force is facilitated.

The first slide bar 18 is in a hexagonal prism shape, and the inner end of the first guide sleeve 19 is wrapped at the outer end of the first slide bar 18; the six edges of the first slide bar 18 are used for preventing the first slide bar 18 from rotating along the first guide sleeve 19, so that the stability of the first slide bar 18 is improved.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a be used for wire rope tinning processingequipment, includes tinning processing heat recovery mechanism (1), tinning processing heat recovery mechanism (1) are including heating main part (3) and heat preservation shell frame (5), heating main part (3) are through external power supply electric connection, its characterized in that: the tinning heat energy recovery mechanism (1) further comprises a heat energy recovery main body (2), the heating main body (3) is fixedly arranged at the inner end of the heat preservation shell frame (5), the heat energy recovery main body (2) comprises an outer guide wheel (7), a heat storage block (8), an inner guide wheel (9) and a chain belt (10), the heating main body (3) is positioned at the upper side of the middle part of the heat energy recovery main body (2), the outer guide wheel (7) is symmetrically and rotationally arranged at the inner end of the heat preservation shell frame (5), the heat storage block (8) is uniformly distributed at the outer end of the chain belt (10), the heat storage block (8) is fixedly connected with the chain belt (10) together, the inner guide wheel (9) is symmetrically and rotationally arranged at the inner end of the lower part of the heat preservation shell frame (5), the outer end of the outer guide wheel (7) is in rolling extrusion with the heat storage block (8), the inner end of the chain belt (10) is sleeved and arranged at the outer end of the inner guide wheel (9), the heating main body (3) comprises a heater (14), the heater (14) is electrically connected with the outer guide wheel (3) through a power supply, the heat conducting plate (11) and the heat conducting plate (13) is further connected with the upper heat preservation shell (13), the heater (14) is attached to the lower end of the heat conducting plate (11), the heater (14) is fixedly connected with the heat conducting plate (11), the baffle (12) is symmetrically and fixedly connected to the side end of the heat conducting plate (11), the side end of the baffle (12) is fixedly connected to the inner end of the heat conducting plate (11), the tinning heat energy recovery mechanism (1) further comprises a guide main body (4), the guide main body (4) comprises a heat insulating cover (15), a bending roller (16), a first sliding rod (18), a first guide sleeve (19) and a fixed shaft (21), the lower end of the heat insulating cover (15) is fixedly arranged at the upper end of the middle part of the heat insulating cover (5), the bending roller (16) is positioned at the inner side of the heat insulating cover (15), the lower end of the bending roller (16) is pressed to the upper end of the heat conducting plate (11), the first sliding rod (18) penetrates through the first guide sleeve (19) in a sliding mode, the outer end of the first guide sleeve (19) is fixedly connected to the heat insulating cover (5), the upper end of the first sliding rod (18) is fixedly connected to the fixed shaft (21) in a penetrating mode, the lower end of the fixed shaft (21) is rotatably penetrates through the roller (21), the fixed shaft (21) is in sliding contact with the heat preservation cover (15); tinning processing heat recovery mechanism (1) still includes compresses tightly and draws main part (6), compress tightly and draw main part (6) including compressing tightly guide pulley (23), second guide pin bushing (25), second slide bar (26) and bearing frame (27) symmetry set up in the outside that compresses tightly guide pulley (23), bearing frame (27) and compressing tightly guide pulley (23) rotate to be connected together, the lower extreme fixed connection of bearing frame (27) is in the upper end of second slide bar (26), second slide bar (26) run through second guide pin bushing (25), second guide pin bushing (25) and second slide bar (26) sliding contact, second guide pin bushing (25) symmetry fixed connection is in the outside end of heat preservation shell frame (5).

2. A device for tinning a wire rope according to claim 1, characterized in that: the lower end of the inner side of the heat conducting plate (11) is provided with a groove.

3. A device for tinning a wire rope according to claim 1, characterized in that: the guiding main body (4) further comprises a tin guiding groove (17), and the tin guiding groove (17) is uniformly formed in the outer end of the bending roller (16).

4. A device for tinning a wire rope according to claim 1, characterized in that: the guide main body (4) further comprises a balance weight (20), and the side end of the balance weight (20) is fixedly connected with the side end of the fixed shaft (21) back to the press bending roller (16).

5. A device for tinning a wire rope according to claim 1, characterized in that: the side end of the heat preservation cover (15) is hollowed out and provided with a guide groove (22), and the fixed shaft (21) is in sliding contact with the guide groove (22).

6. A device for tinning a wire rope according to claim 1, characterized in that: the compression actuating main body (6) further comprises a tension spring (24), the tension spring (24) is sleeved on the outer side of the second sliding rod (26), the upper end of the tension spring (24) is fixedly connected to the lower end of the bearing seat (27), and the lower end of the tension spring (24) is fixedly connected to the upper end of the second guide sleeve (25).

7. A device for tinning a wire rope according to claim 1, characterized in that: the first sliding rod (18) is of a hexagonal prism shape, and the inner end of the first guide sleeve (19) is wrapped at the outer end of the first sliding rod (18).