CN111673226A

CN111673226A - Automatic cable tinning equipment

Info

Publication number: CN111673226A
Application number: CN202010576610.1A
Authority: CN
Inventors: 戴林军; 谢建; 刘立峰
Original assignee: Yueyang Tuobang Electronic Factory
Current assignee: Yueyang Tuobang Electronic Factory
Priority date: 2020-06-23
Filing date: 2020-06-23
Publication date: 2020-09-18

Abstract

The invention discloses automatic cable tinning equipment which comprises a base and an upright post, wherein a cross beam is arranged at the top of the upright post, the bottom of the cross beam is connected with a longitudinal guide rail and a first air cylinder, a sliding saddle is arranged on the longitudinal guide rail and connected with a cable clamping tin-injecting module, the cable clamping tin-injecting module is connected with the first air cylinder, and a tin-injecting butt joint is arranged on the cable clamping tin-injecting module; a downward-pressing type tin spraying assembly is arranged on the base; the downward-pressing type tin spraying assembly comprises a tin dissolving cavity and a nozzle assembly, and the nozzle assembly comprises a nozzle and an extrusion block; after the tin injection butt joint nozzle is in matched butt joint with the nozzle assembly, the first air cylinder drives the tin injection butt joint nozzle to press down the nozzle assembly, and the extrusion block extrudes liquid tin in the tin dissolving cavity, so that the liquid tin is sprayed on a tin feeding position of the cable through the nozzle assembly and the tin injection butt joint nozzle. The automatic tin-coating machine is simple in structure, convenient to use and low in manufacturing cost, can be used for rapidly stripping and cutting a cable, completes automatic tin coating, replaces traditional manual operation, and improves production efficiency.

Description

Automatic cable tinning equipment

Technical Field

The invention relates to the technical field of cable processing production, in particular to automatic cable tinning equipment.

Background

Cable is a generic term for optical cables, electrical cables, and the like. The cable has many purposes, is mainly used for controlling installation, connecting equipment, transmitting power and other multiple functions, and is a common and indispensable object in daily life. Installation requires special care since the cable is live.

The cable is needed to strip and cut the end insulator in the processing process, so that the conductor at the end of the cable is exposed, and the exposed conductor needs to be tinned for the convenience of subsequently installing the wiring end.

At present, the stripping and cutting and tinning processing of the end part of a cable of a small and medium-sized enterprise mainly have the following technical problems: 1. the device for tinning the cable is expensive in manufacturing cost, high in one-time investment cost and high in device maintenance and repair cost, increases the cost expenditure of small and medium-sized enterprises, and is difficult to meet the development requirements of the enterprises; 2. if the processing mode of manual stripping and cutting and tinning is adopted, the defects of high labor intensity, low processing efficiency and the like exist, and the requirement for rapidly processing the cable of an enterprise is not met.

Disclosure of Invention

The invention aims to solve the problems, provides the automatic cable tinning equipment which is simple in structure, convenient to use and low in manufacturing cost, can be used for rapidly stripping and cutting cables to finish automatic tinning, replaces the traditional manual operation, and improves the production efficiency.

In order to realize the purpose, the invention adopts the technical scheme that: the device comprises a base, wherein an upright column is arranged at the upper end of the base, a cross beam is arranged at the top of the upright column, the bottom of the cross beam is connected with a longitudinal guide rail and a first air cylinder, a saddle is arranged on the longitudinal guide rail, a cable clamping tin injection module is fixedly connected onto the saddle and connected with an extending end of the first air cylinder, and a tin injection butt joint is arranged at the bottom of the cable clamping tin injection module; a lower pressing type tin spraying component is arranged on the base and right below the tin injection butt joint nozzle; the downward-pressing type tin spraying assembly comprises a tin dissolving cavity and a nozzle assembly, the nozzle assembly comprises a nozzle and an extrusion block connected to the bottom of the nozzle, and the tin injection butt joint nozzle can be in butt joint with the nozzle assembly in a matching mode; after the tin injection butt joint nozzle is matched and butted with the nozzle assembly, the first air cylinder drives the tin injection butt joint nozzle to press down the nozzle assembly, the extrusion block extrudes liquid tin in the tin dissolving cavity, the liquid tin is sprayed on a tin feeding position of the cable through the nozzle assembly and the tin injection butt joint nozzle, a second guide rod and a third guide rod are arranged at the bottom of the cable clamping tin injection module, and a guide hole matched with the second guide rod and the third guide rod is arranged on the base.

Further, the cable clamping tin injection module comprises an upper clamping block and a lower clamping block, a second cylinder is connected between the upper clamping block and the lower clamping block, and a clamping surface groove and a tin injection surface groove are formed between the upper clamping block and the lower clamping block; when the second cylinder drives the lower clamping block to cover the upper clamping block, the clamping surface groove and the tin injection surface groove are both in a round hole shape, and the diameter of the tin injection surface groove is larger than that of the clamping surface groove.

Furthermore, an inclined opening convenient for placing a cable is arranged on the upper clamping block and the lower clamping block and at the position close to the clamping surface groove and the tin injection surface groove.

Furthermore, a countersunk through hole is formed in the axis direction of the tin injection butt joint nozzle.

Furthermore, the tin dissolving cavity is used for maintaining the electric heating tube with tin in a molten state.

Further, the connecting nozzle comprises a pipeline, a stud is arranged at the bottom of the pipeline, the stud is connected with a round hole in the top of the extrusion block through threads, a flange is arranged at the upper end of the pipeline, a pipeline butt joint section is arranged at the top of the flange, and a side hole is formed in one end, close to the extrusion block, of the pipeline; the bottom of the flange is connected with a first return spring.

Furthermore, the volume V1 of the extrusion block is the sum of the volume V2 of the side hole, the volume V3 of the inner hole of the pipeline, the volume V4 of the countersunk head through hole 1 and the volume V5 of the groove of the tin injection surface.

Further, a valve component for longitudinally separating the tin dissolving cavity 17 is arranged on the base 2 and is arranged right below the third guide rod 23; the valve component comprises a longitudinal partition plate 18, a plurality of shaft bodies 19 connected to the bottom of the longitudinal partition plate 18 and a second return spring 20 connected to the bottom of the shaft bodies 19; the top of base 2 is provided with the square groove that runs through tin dissolving cavity 17, and the bottom in square groove is equipped with the round hole, and longitudinal baffle 18 matches in square inslot, and second reset spring 20 locates in the round hole of square inslot bottom.

Further, the side of the tin dissolving cavity 17 is provided with a circular channel 21, the circular channel 21 is communicated with the tin dissolving cavity 17, a tin rod 3 is arranged in the circular channel 21, the diameter of the tin rod 3 is matched with the circular channel 21, the left side of the tin rod 3 is provided with a push plate 4, the left side of the push plate 4 is connected with a pressure spring 5, the pressure spring 5 drives the push plate 4 to extrude the tin rod 3 at any time, and the tin rod 3 keeps in contact with the electric heating tube 1 at any time under the action of push plate thrust.

Further, a material receiving box 7 for receiving stripped and cut insulators and redundant liquid tin in a tin feeding process is arranged on the side surface of the cable clamping tin injection module 13.

The invention has the beneficial effects that: the automatic cable tinning equipment provided by the invention is simple in structure, convenient to use and low in manufacturing cost, can be used for rapidly clamping a cable to finish automatic tinning, replaces the traditional manual operation, and improves the production efficiency.

According to the invention, the second guide rod and the third guide rod are adopted for positioning in the butt joint between the cable clamping tin injection module and the nozzle assembly, so that the deviation generated in butt joint is prevented, the butt joint accuracy is improved, and the defect of the phenomenon of blocking in the butt joint of the traditional sensor is overcome.

According to the invention, the quick partition of the longitudinal partition plate to the tin dissolving cavity is completed in the butt joint process between the cable clamping tin injection module and the nozzle assembly, the nozzle assembly is forced to move downwards in the downward pressing process of the cable clamping tin injection module, the liquid tin is extruded by the extrusion block, and the liquid tin directly flows onto the stripped and cut cable conductor after passing through the connecting side hole, the pipeline inner hole, the countersunk head through hole and the tin injection surface groove, so that the automatic tin feeding is completed.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic side view of the cable clamping tin injection module according to the present invention.

Fig. 3 is a schematic cross-sectional view taken along line a-a in fig. 2.

Fig. 4 is a schematic view of the structure of the nozzle of the present invention.

Fig. 5 is a schematic structural diagram of the cable clamping tin injection module and the nozzle assembly in a butt joint state.

The text labels in the figures are represented as: 1. an electric heating tube; 2. a base; 3. a tin bar; 4. pushing the plate; 5. a pressure spring; 6. a column; 7. a material receiving box; 8. injecting tin into the butt joint nozzle; 9. a cross beam; 10. a longitudinal guide rail; 11. a first cylinder; 12. a saddle; 13. clamping the tin injection module by the cable; 14. a nozzle is connected; 15. a first return spring; 16. extruding the block; 17. a tin dissolving cavity; 18. a longitudinal partition; 19. a shaft body; 20. a second return spring; 21. a circular channel; 22. a second guide bar; 23. a third guide bar; 81. countersunk through holes; 1301. a lower clamping block; 1302. an upper clamping block; 1303. injecting a tin surface groove; 1304. a clamping surface groove; 1305. a second cylinder; 1306. an angled port.

Detailed Description

The following detailed description of the present invention is given for the purpose of better understanding technical solutions of the present invention by those skilled in the art, and the present description is only exemplary and explanatory and should not be construed as limiting the scope of the present invention in any way.

As shown in fig. 1 to 5, the specific structure of the present invention is: the device comprises a base 2, wherein an upright post 6 is arranged at the upper end of the base, a cross beam 9 is arranged at the top of the upright post 6, the bottom of the cross beam 9 is connected with a longitudinal guide rail 10 and a first air cylinder 11, a saddle 12 is arranged on the longitudinal guide rail 10, a cable clamping tin injection module 13 is fixedly connected on the saddle 12, the cable clamping tin injection module 13 is connected with the extending end of the first air cylinder 11, and a tin injection butt joint 8 is arranged at the bottom of the cable clamping tin injection module 13; a lower pressing type tin spraying component is arranged on the base 2 and right below the tin injection butt joint nozzle 8; the downward-pressing type tin spraying assembly comprises a tin dissolving cavity 17 and a nozzle assembly, the nozzle assembly comprises a nozzle 14 and an extrusion block 16 connected to the bottom of the nozzle 14, and the tin injection butt joint nozzle 8 can be in matched butt joint with the nozzle assembly; after the tin injection butt joint nozzle 8 is in matched butt joint with the nozzle assembly, the first air cylinder 11 drives the tin injection butt joint nozzle 8 to press down the nozzle assembly, the extrusion block 16 extrudes liquid tin in the tin dissolving cavity 17, the liquid tin is sprayed on a tin feeding position of the cable through the nozzle assembly and the tin injection butt joint nozzle 8, a second guide rod 22 and a third guide rod 23 are arranged at the bottom of the cable clamping tin injection module 13, and guide holes matched with the second guide rod 22 and the third guide rod 23 are formed in the base 2.

In this embodiment, as shown in fig. 2 to fig. 3, preferably, the cable clamping tin injection module 13 includes an upper clamping block 1302 and a lower clamping block 1301, a second cylinder 1305 is connected between the upper clamping block 1302 and the lower clamping block 1301, and a clamping surface groove 1304 and a tin injection surface groove 1303 are provided between the upper clamping block 1302 and the lower clamping block 1301; when the second cylinder 1305 drives the lower clamping block 1301 and the upper clamping block 1302 to cover, the clamping surface groove 1304 and the tin injection surface groove 1303 are both in a round hole shape, and the diameter of the tin injection surface groove 1303 is larger than that of the clamping surface groove 1304.

In the present embodiment, as shown in fig. 2-3, it is preferable that the upper and

lower clamping blocks

1302 and 1301 are provided with an inclined opening 1306 for placing cables near the clamping surface groove 1304 and the tin injection surface groove 1303.

In the present embodiment, as shown in fig. 2-3, it is preferable that the tin injection butt joint nozzle 8 is provided with a countersunk through hole 81 in the axial direction.

In the present embodiment, as shown in fig. 1, it is preferable that the electric heating tube 1 for maintaining the molten state of tin is provided in the tin dissolving chamber 17.

In this embodiment, as shown in fig. 4, preferably, the nozzle 14 includes a pipe 1403, a stud 1405 is provided at the bottom of the pipe 1403, the stud 1405 is connected to a circular hole at the top of the extrusion block 16 through a screw thread, a flange 1402 is provided at the upper end of the pipe 1403, a pipe butt-joint section 1401 is provided at the top of the flange 1402, and a side hole 1404 is provided at one end of the pipe 1403, which is located near the extrusion block 16; the bottom of the flange 1402 is connected to a first return spring 15.

In the present embodiment, as shown in fig. 5, preferably, the volume V1 of the extrusion block 16 is the sum of the volume V2 of the side hole 1404, the volume V3 of the inner hole of the pipe 1403, the volume V4 of the countersunk head through hole 81, and the volume V5 of the tin injection surface groove.

In the present embodiment, as shown in fig. 1, preferably, the base 2 is provided with a valve assembly for longitudinally blocking the molten tin chamber 17, and the valve assembly is arranged right below the third guide rod 23; the valve component comprises a longitudinal partition plate 18, a plurality of shaft bodies 19 connected to the bottom of the longitudinal partition plate 18 and a second return spring 20 connected to the bottom of the shaft bodies 19; the top of base 2 is provided with the square groove that runs through tin dissolving cavity 17, and the bottom in square groove is equipped with the round hole, and longitudinal baffle 18 matches in square inslot, and second reset spring 20 locates in the round hole of square inslot bottom.

Preferentially, in this embodiment, as shown in fig. 1, preferably, a circular channel 21 is provided on a side surface of the tin dissolving cavity 17, the circular channel 21 and the tin dissolving cavity 17 are communicated with each other, a tin rod 3 is provided in the circular channel 21, a diameter of the tin rod 3 is matched with the circular channel 21, a push plate 4 is provided on a left side of the tin rod 3, a pressure spring 5 is connected to a left side of the push plate 4, the pressure spring 5 constantly drives the push plate 4 to extrude the tin rod 3, and the tin rod 3 constantly keeps in contact with the electric heating tube 1 under the action of push plate thrust.

In the present embodiment, as shown in fig. 1, it is preferable that a material receiving box 7 for receiving the stripped and cut insulator and the excess liquid tin in the tin applying process is provided on the side surface of the cable clamping tin injection module 13.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The principles and embodiments of the present invention are explained herein using specific examples, which are presented only to assist in understanding the method and its core concepts of the present invention. The foregoing is only a preferred embodiment of the present invention, and it should be noted that there are objectively infinite specific structures due to the limited character expressions, and it will be apparent to those skilled in the art that a plurality of modifications, decorations or changes may be made without departing from the principle of the present invention, and the technical features described above may be combined in a suitable manner; such modifications, variations, combinations, or adaptations of the invention using its spirit and scope, as defined by the claims, may be directed to other uses and embodiments.

Claims

1. The automatic cable tinning equipment is characterized by comprising a base (2), wherein the upper end of the base is provided with an upright post (6), the top of the upright post (6) is provided with a cross beam (9), the bottom of the cross beam (9) is connected with a longitudinal guide rail (10) and a first air cylinder (11), the longitudinal guide rail (10) is provided with a saddle (12), the saddle (12) is fixedly connected with a cable clamping and tin injecting module (13), the cable clamping and tin injecting module (13) is connected with an extending end of the first air cylinder (11), and the bottom of the cable clamping and tin injecting module (13) is provided with a tin injecting butt joint (8); a downward pressing type tin spraying component is arranged on the base (2) and right below the tin injection butt joint nozzle (8); the downward-pressing type tin spraying assembly comprises a tin dissolving cavity (17) and a nozzle assembly, the nozzle assembly comprises a nozzle (14) and an extrusion block (16) connected to the bottom of the nozzle (14), and the tin injection butt joint nozzle (8) can be in matched butt joint with the nozzle assembly; after the tin injection butt joint nozzle (8) is in matched butt joint with the nozzle assembly, the first air cylinder (11) drives the tin injection butt joint nozzle (8) to press down the nozzle assembly, the extrusion block (16) extrudes liquid tin in the tin dissolving cavity (17), so that the liquid tin is sprayed to a tin feeding position of a cable through the nozzle assembly and the tin injection butt joint nozzle (8), a second guide rod (22) and a third guide rod (23) are arranged at the bottom of the cable clamping tin injection module (13), and a guide hole matched with the second guide rod (22) and the third guide rod (23) is formed in the base (2).

2. The automatic cable tinning device according to claim 1, wherein the cable clamping and tinning module (13) comprises an upper clamping block (1302) and a lower clamping block (1301), a second cylinder (1305) is connected between the upper clamping block (1302) and the lower clamping block (1301), and a clamping surface groove (1304) and a tinning surface groove (1303) are arranged between the upper clamping block (1302) and the lower clamping block (1301); when the second cylinder (1305) drives the lower clamping block (1301) and the upper clamping block (1302) to cover, the clamping surface groove (1304) and the tin injection surface groove (1303) are both in a circular hole shape, and the diameter of the tin injection surface groove (1303) is larger than that of the clamping surface groove (1304).

3. The automatic cable tinning device according to claim 2, characterized in that inclined ports (1306) for placing cables are arranged on the upper clamping block (1302) and the lower clamping block (1301) and close to the clamping surface groove (1304) and the tin injection surface groove (1303).

4. The automatic cable tinning equipment according to claim 3, wherein a countersunk through hole (81) is formed in the axial direction of the tin injection butt joint nozzle (8).

5. An automatic cable tinning device according to any one of claims 1 to 4, characterized in that the electric heating tube (1) is arranged in the tin dissolving chamber (17) to maintain the tin in a molten state.

6. The automatic cable tinning equipment according to claim 5, wherein the connecting nozzle (14) comprises a pipeline (1403), a stud (1405) is arranged at the bottom of the pipeline (1403), the stud (1405) is in threaded connection with a round hole in the top of the extrusion block (16), a flange (1402) is arranged at the upper end of the pipeline (1403), a pipeline butt joint section (1401) is arranged at the top of the flange (1402), and a side hole (1404) is formed in one end, close to the extrusion block (16), of the pipeline (1403); the bottom of the flange (1402) is connected with a first return spring (15).

7. The automatic cable tinning equipment according to claim 6, wherein the volume V1 of the extrusion block (16) is the sum of the volume (V2) of the side hole (1404), the volume (V3) of the inner hole of the pipeline (1403), the volume (V4) of the countersunk head through hole (81) and the volume (V5) of the groove of the tin injection surface.

8. The automatic cable tinning equipment of claim 7, wherein a valve component for longitudinally separating the tin dissolving cavity (17) is arranged on the base (2), and the valve component is arranged right below the third guide rod (23); the valve assembly comprises a longitudinal partition plate (18), a plurality of shaft bodies (19) connected to the bottom of the longitudinal partition plate (18), and a second return spring (20) connected to the bottom of the shaft bodies (19); the top of base (2) is provided with the square groove that runs through solution tin chamber (17), and the bottom in square groove is equipped with the round hole, and longitudinal baffle (18) match is in square inslot, and second reset spring (20) are located in the round hole of square inslot bottom.

9. The automatic cable tinning equipment according to claim 8, wherein a circular channel (21) is arranged on the side surface of the tin dissolving cavity (17), the circular channel (21) is communicated with the tin dissolving cavity (17), a tin rod (3) is arranged in the circular channel (21), the diameter of the tin rod (3) is matched with that of the circular channel (21), a push plate (4) is arranged on the left side of the tin rod (3), a pressure spring (5) is connected to the left side of the push plate (4), the pressure spring (5) drives the push plate (4) to extrude the tin rod (3) constantly, and the tin rod (3) keeps in contact with the electric heating pipe (1) constantly under the action of the push plate thrust.

10. The automatic cable tinning device according to claim 9, wherein a material receiving box (7) for receiving stripped insulators and excess liquid tin in a tinning process is arranged on the side surface of the cable clamping and tin injecting module (13).