CN112332192A

CN112332192A - Rotary wire peeling and soldering equipment and method

Info

Publication number: CN112332192A
Application number: CN202011264088.XA
Authority: CN
Inventors: 阮诗扬; 万睿; 周华平; 叶棣中; 王健
Original assignee: Janohig Electronics Technology Co ltd
Current assignee: Janohig Electronics Technology Co ltd
Priority date: 2020-11-12
Filing date: 2020-11-12
Publication date: 2021-02-05

Abstract

The invention discloses rotary wire peeling and soldering equipment and a rotary wire peeling and soldering method, wherein the rotary wire peeling and soldering equipment comprises a soldering tin rotary table module, a first soldering flux groove module, a first tin furnace module, a wire pulling module and a shearing module; the tin soldering turntable module is provided with a turntable and a first rotary driving device for driving the turntable to vertically rotate around a horizontal axis, a first wire clamping device is arranged on the turntable, and the first wire clamping device controls the first wire clamping device to move up and down along the turntable through a lifting driving device; the wire drawing module is provided with a second wire clamping device and a wire drawing driving device for driving the second wire clamping device to displace so as to draw the wire; the shearing module is provided with a shearing device; and a second wire clamping device of the wire pulling module clamps one end of the wire to pull out the wire by a set length, and a shearing device peels and shears the other end of the wire. So, through the design to the rotary type wire rod soldering tin equipment of skinning, the cooperative operation between each module can accomplish skinning, shearing, the scaling powder of wire rod, a series of operations of soldering tin fast, has effectively promoted machining efficiency.

Description

Rotary wire peeling and soldering equipment and method

Technical Field

The invention relates to the technical field of wire peeling and soldering equipment, in particular to rotary wire peeling and soldering equipment and a rotary wire peeling and soldering method.

Background

The existing transformer generally needs a certain length of insulated wire to wind the secondary winding, and one end of the insulated wire needs to be pasted with soldering oil and soldered. At present, the operation mode of manually shearing the insulated wire and soldering tin is generally adopted, so that the manual operation efficiency is low, the labor cost is high, the stability of the processing quality is poor, and the processing yield is influenced; in addition, manual soldering has certain potential safety hazards.

Later, some automatic wire stripping and welding devices have appeared, which are much improved in terms of production efficiency and consistency of operation quality compared with manual operation. However, the existing automatic wire stripping and welding device has a complex structure and a large occupied space, and meanwhile, the flexibility of soldering tin is affected, and the application range is limited.

Therefore, a new technical solution is needed to solve the above problems.

Disclosure of Invention

In view of the above, the present invention provides a rotary wire peeling and soldering device and method, which can quickly complete a series of operations of peeling, shearing, soldering and flux adhering of the wire by the design of the rotary wire peeling and soldering device and the cooperative operation among modules, thereby effectively improving the processing efficiency.

In order to achieve the purpose, the invention adopts the following technical scheme:

a rotary wire peeling and soldering device comprises a workbench, and a soldering tin turntable module, a first scaling powder groove module, a first tin furnace module, a wire pulling module and a shearing module which are arranged on the workbench; wherein:

the soldering tin turntable module is provided with a turntable and a first rotary driving device for driving the turntable to vertically rotate around a horizontal axis, a first wire clamping device is arranged on the turntable, and the first wire clamping device controls the first wire clamping device to move along the turntable in a lifting manner through a lifting driving device;

the first scaling powder groove module, the first tin furnace module, the pull wire module and the shearing module are respectively arranged on the periphery of the rotary table; the wire drawing module is provided with a second wire clamping device and a wire drawing driving device for driving the second wire clamping device to move so as to draw a wire; the shearing module is provided with a shearing device; and the second wire clamping device of the wire pulling module clamps one end of the wire to pull out the wire by a set length, and the shearing device peels and shears the other end of the wire.

As a preferable scheme, the first soldering flux groove module and the first tin furnace module are arranged on the lower side of the rotary table; the shearing module and the wire drawing module are arranged on the right side of the turntable.

As a preferred scheme, the first tin furnace module, the first soldering flux groove module and the shearing module are sequentially arranged from left to right.

As a preferred scheme, a mounting plate is vertically arranged on the workbench; wherein:

the first soldering flux groove module and the first tin furnace module are arranged on the workbench, and the soldering tin rotary table module, the stay wire module and the shearing module are arranged on the mounting plate.

As a preferable scheme, the first tin furnace module, the first soldering flux groove module, the first wire clamping device, the second wire clamping device and the shearing device are all located on the front side of the mounting plate, and the first rotary driving device and the lifting driving device are arranged on the rear side of the mounting plate.

As a preferable scheme, the shearing device is connected with a second rotary driving device, and the second rotary driving device drives the shearing device to vertically rotate around a horizontal axis; the shearing device is connected with a shearing translation driving device for driving the shearing device to displace and adjust along the pulling direction of the wire rod; the shearing device is provided with a shearing clamping assembly, a second scaling powder groove module and a second tin furnace module are arranged below the shearing device, the shearing clamping assembly clamps the other end of the wire to rotate, and the other end of the wire is subjected to tin soldering.

As a preferred scheme, the shearing device is located on the right side of the soldering tin turntable module, and the first tin furnace module, the first soldering flux groove module, the second soldering flux groove module and the second tin furnace module are sequentially arranged from left to right.

As a preferred scheme, a wire passing seat is arranged on the turntable or the first wire clamping device, and a plurality of wire passing holes arranged side by side at intervals are arranged in the wire passing seat.

A wire peeling and soldering method comprises the following steps:

s1: the wire enters the equipment, and one end of the wire is clamped by the first wire clamping device;

s2: rotating the first wire clamping device to enable one end of the wire to be screwed to the soldering flux groove to adhere the soldering flux;

s3: rotating the first wire clamping device to enable one end of the wire to rotate to a tin furnace for tin soldering;

s4: the first wire clamping device rotates to enable one end of the wire to be screwed to the wire pulling side;

s5: clamping one end of the wire by using a wire drawing module to draw the wire out by a set length;

s6: peeling and cutting the wire material by the cutting module to obtain a finished wire material with one end soldered, and peeling one end of the wire material to be processed, as a next cycle, performing steps S2 to S6.

Preferably, in step S6, peeling off the other end of the soldered wire rod, so as to obtain a wire rod with one end soldered and one end peeled;

alternatively, in step S6, the other end of the soldered wire material product is also peeled; for the cut wire rod product, the process proceeds to step S7: the cutting clamping assembly of the cutting module clamps the other end of the wire rod to rotate, the other end of the wire rod is soldered, and meanwhile, the wire rod to be processed with one peeled end is subjected to steps S2 to S6 as the next cycle; thus, a finished product of the wire rod with the double-end soldering tin is obtained.

Compared with the prior art, the rotary wire peeling and soldering device has obvious advantages and beneficial effects, and particularly, according to the technical scheme, a series of operations of peeling, shearing, soldering flux adhering and soldering of the wire can be rapidly completed through the design of the rotary wire peeling and soldering device and the cooperative operation among modules, so that the processing efficiency is effectively improved, meanwhile, the stability of wire soldering is enhanced, and the quality risk of products such as transformers and the like is reduced; particularly, due to the rotary design, the arrangement among the modules is ingenious, a large operation space is saved, the structure of the whole equipment is more compact, the operation is more flexible, the automatic wire stripping and welding device can be widely combined and applied to various nonstandard automatic equipment, the application range is wide, and the problem that the application range of the automatic wire stripping and welding device in the traditional technology is limited is solved.

Secondly, through set up second scaling powder groove module, second tin stove module at shearing module place side, the other end rotation of wire rod is cliied to the shearing centre gripping subassembly, carries out soldering tin to the other end of wire rod, so, realizes the processing of bi-polar soldering tin wire rod.

And each module is arranged by utilizing the workbench and the mounting plate, so that the structure is simple, the assembly is convenient, the realization is easy, and meanwhile, the advantages of low manufacturing cost, suitability for popularization and use and the like are realized.

To more clearly illustrate the structural features and effects of the present invention, the present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.

Drawings

FIG. 1 is an assembled perspective view of a first embodiment of the present invention;

FIG. 2 is a partially exploded view of a first embodiment of the present invention;

FIG. 3 is an enlarged partial view at A of FIG. 2;

FIG. 4 is a partially enlarged view at B of FIG. 2;

FIG. 5 is a partially exploded view from another perspective of one embodiment of the present invention;

FIG. 6 is a front view of a first embodiment of the present invention;

FIG. 7 is a partial top view of a first embodiment of the present invention;

fig. 8 is a front view of a second embodiment of the present invention.

The attached drawings indicate the following:

100. workbench 101 and mounting plate

10. Roll shaft module 20 and soldering tin turntable module

21. Turntable 22 and first wire clamping device

23. Wire passing seat 30 and first soldering flux groove module

31. First flux groove 32 and second flux groove module

40. First tin furnace module 41 and first tin furnace

42. Second tin furnace module 50 and wire drawing module

51. Second wire clamping device 60 and shearing module

61. Shearing mechanism 70, first tin scraping surface module

71. And the second tin scraping surface module.

Detailed Description

Referring to fig. 1 to 8, specific structures of the embodiments of the present invention are shown.

A rotary wire peeling and soldering device comprises a workbench 100, a roll shaft module 10, a soldering tin turntable module 20, a first scaling powder groove module 30, a first tin furnace module 40, a wire drawing module 50 and a shearing module 60, wherein the roll shaft module 10, the soldering tin turntable module 20, the first scaling powder groove module 30, the first tin furnace module 40 and the wire drawing module 50 are arranged on the workbench 100; wherein:

the roll shaft module 10 is used for smoothly feeding the wire rods into equipment, so that the soldering effect of the wire rods and the appearance quality of the wire rods can be improved;

the soldering tin turntable module 20 is provided with a turntable 21 and a first rotary driving device for driving the turntable 21 to vertically rotate around a horizontal axis, the turntable 21 is provided with a first wire clamping device 22 capable of automatically opening and closing, and the first wire clamping device 22 is controlled by a lifting driving device to be capable of lifting and displacing along the radial direction of the turntable 21; here, it can be detailed that: usually, the turntable 21 is provided with a gear ring (preferably, the gear ring is arranged at the rear side of the turntable 21, and the gear ring may be integrally formed with the turntable 21 or separately installed), the first rotary driving device may be a motor, and the motor is connected to the gear ring through a conveyor belt so as to drive the gear ring to rotate; the first wire clamping device 22 may be a first clamping cylinder and a first clamping member disposed on the first clamping cylinder, the first clamping cylinder is connected to the rotary table 21 through a first sliding block, and of course, a first sliding rail matched with the first sliding block is disposed on the rotary table 21; and the lifting driving device for driving the first clamping cylinder to reciprocate on the guide rail can be arranged on the turntable 21 or arranged at other positions by other driving modes (such as screw transmission);

the wire passing seat 23 is arranged on the rotary table 21 or the first wire clamping device 22, a plurality of wire passing holes arranged side by side at intervals are formed in the wire passing seat 23, and through the arrangement of the wire passing seat 23, the equipment can realize simultaneous operation on a plurality of wires.

Further, the first soldering flux groove module 30, the first tin furnace module 40, the wire drawing module 50 and the shearing module 60 are respectively arranged on the periphery of the turntable 21; the wire drawing module 50 is provided with a second wire clamping device 51 capable of automatically opening and closing and a wire drawing driving device for driving the second wire clamping device 51 to move so as to draw the wire to a set length (the length of the wire is designed according to production requirements); the shearing module 60 has a shearing device 61; the second wire clamping device 51 of the wire drawing module 50 clamps one end of the wire to draw the wire out by a set length, and the cutting device 61 peels and cuts the other end of the wire. Here, the first flux groove module 30 includes a first flux groove 31, and a device for replenishing flux may be connected to the first flux groove 31; the first tin furnace module 40 comprises a first tin furnace 41, and the first tin furnace 41 can be connected with a device for supplementing tin (or tin liquid); the second wire clamping device 51 may be composed of a second clamping cylinder and a second clamping component arranged on the second clamping cylinder; the shearing device 61 comprises a shearing cylinder, a peeling part and a shearing part, wherein the peeling part and the shearing part are arranged on the shearing cylinder; it should be emphasized that the peeling member and the cutting member may be the same member having two functions of peeling and cutting, or may be the same member having three functions of peeling, cutting and clamping, and the design of such member is conventional for those skilled in the art, and therefore, will not be described in detail herein.

Specifically, the method comprises the following steps:

the first soldering flux groove 31 and the first tin furnace 41 are arranged on the lower side of the turntable 21; the shearing device 61 and the second wire clamping device 51 are arranged at the right side of the rotary table 21. Moreover, the first tin furnace 41, the first scaling powder groove 31, the shearing device 61 and the second wire clamping device 51 are sequentially arranged from left to right; in this embodiment, the roller module 10 includes a roller and is disposed on the left side of the turntable 21, and in practical applications, the roller may be disposed in other directions of the turntable 21. (e.g., upper) preferably, the flux channels of the first flux channel module 30 are higher than the first solder pot 41 of the first solder pot module 40; therefore, the distance for the lifting driving device to drive the first wire clamping device 22 to reciprocate on the guide rail can be shortened, and the working efficiency of the equipment is directly improved. Preferably, the shearing device 61, the second wire clamping device 51 and the roller shaft are all higher than the first flux groove 31.

Preferably, the first tin furnace module 40 is provided with a first tin scraping surface module 70; in the present embodiment, the first tin scraping surface module 70 is preferably disposed right below the turntable 21 and on the left side of the first tin furnace 41.

First tin scraping surface module 70 is including the tin scraping translation drive arrangement of tin scraping plate, the left and right translation of drive tin scraping plate and the tin scraping lift drive arrangement of drive tin scraping plate lift, the upside of tin scraping plate has the tin scraping surface towards the first tin stove device oblique downwardly extending to and, the downside of tin scraping plate has the tin dross portion of scraping. Specifically, the solder dross scraping portion is formed by extending downward from the right end of the solder dross scraping surface, and has the function of preventing the solder dross from escaping from the solder pot. The tin scraping surface can be contacted with a soldering tin position after the wire is soldered, and redundant tin is removed; the dross scraping section scrapes dross floating on the liquid surface of the first tin furnace 41 by reciprocating in the first tin furnace 41.

When in use, the workbench 100 is provided with a vertically arranged mounting plate 101; wherein: first scaling powder groove 31, first tin stove 41 equipartition are arranged in on workstation 100, on mounting panel 101 was arranged in to roller, carousel 21, second trapping mechanism 51, shearing mechanism 61 equipartition, simultaneously, all kinds of drive arrangement can arrange in mounting panel 101 as required.

Preferably, the roller, the first tin furnace 41, the first soldering flux groove 31, the first wire clamping device 22, the second wire clamping device 51 and the shearing device 61 are all positioned on the front side of the mounting plate 101; the first rotation driving device, the lifting driving device and the wire pulling driving device are arranged on the rear side of the mounting plate 101. Generally, a protective cover is provided on the rear side of the mounting plate 101 to protect the devices, and an electric control box is provided above the protective cover.

Further, the shearing device 61 is connected with a shearing translation driving device for driving the shearing device to displace and adjust along the wire material pulling direction; the shearing device 61 has a shearing gripping assembly; of course, the shearing and clamping assembly can be designed into the same component with three functions of peeling, shearing and clamping. Through the design of the shearing translation driving device, the peeling and the shearing of the wire rod are facilitated. Here, it is easy for those skilled in the art to design a mechanism on the device for peeling and cutting the wire, and here, a way for peeling and cutting the wire is provided, but not limiting the scope of the invention; for example: the shearing device 61 can be a shearing cylinder and a peeling (shearing) cutter on the shearing cylinder; firstly, a cutting cylinder cuts a peeling (cutting) cutter into an insulation skin at a wire A1 through closing; secondly, the cutting cylinder draws the peeling (cutting) cutter out of the insulation skin of the wire through opening; thirdly, the shearing translation driving device drives the shearing air cylinder to move, and the moving distance is slightly equal to the distance of the required peeling length (at the moment, the wire is moved to the position A2 of the wire); fourthly, the cutting cylinder cuts a peeling (cutting) cutter into the insulation skin at the position of the wire A2 through closing action; fifthly, the shearing translation driving device drives the shearing air cylinder to move to the position A1, so that the skin layer of the wire rod is pushed to fall off; and sixthly, according to the set length, the cutting translation driving device drives the cutting cylinder to move to a corresponding position, and the cutting cylinder cuts the wire material by utilizing a peeling (cutting) cutter through closing action. Here, it is conceivable that the cutting depth (degree of closing of the cylinder) of the peeling (shearing) tool is controlled to realize the peeling and shearing actions of the peeling (shearing) tool.

As described above, the soldering apparatus in this embodiment can perform the operations of adhering flux and soldering on one end of the wire rod, and peeling and cutting off the other end of the wire rod. In practical application, the following improved design can be carried out on the equipment according to production needs:

referring to fig. 8, the shearing device 61 is connected with a second rotary driving device, and the second rotary driving device drives the shearing device 61 to rotate vertically around a horizontal axis; here, it is to be added that: in practical production, for convenience in production and manufacturing of the device, the design of the second rotary driving device for driving the shearing device 61 to vertically rotate around the horizontal axis may be the same as the design of the first rotary driving device for driving the turntable 21, except for the difference between the first wire clamping device 22 and the shearing device 61.

Further, a second soldering flux groove module 32 and a second tin furnace module 42 are arranged below the shearing device 61, the shearing and clamping assembly clamps the other end of the wire to rotate, and the other end of the wire is soldered; specifically, the method comprises the following steps: the shearing device 61 is located on the right side of the soldering tin turntable module 20, and the first tin furnace module 40, the first soldering flux groove module 30, the second soldering flux groove module 32 and the second tin furnace module 42 are sequentially arranged from left to right. Correspondingly, a second tin scraping surface module 71 can also be arranged. As can be seen in FIG. 8, the first and second

solder pot modules

40, 42, the first and second

flux groove modules

30, 32, and the first and second tin scraping

surface modules

70, 71 on the surface of the work table 100 are all symmetrical about the vertical center plane of the work table 100.

Here, the manner of driving the shearing device 61 to displace along the wire pulling direction by the shearing translation driving device may be implemented in a manner similar to the manner of controlling the first wire clamping device 22 to move up and down along the radial direction of the turntable 21 by the lifting driving device, which is not described herein again.

The embodiment also discloses a wire peeling and soldering method, which comprises the following steps:

s1: the wire enters the equipment through the roller shaft module 10, and one end of the wire is clamped by the first wire clamping device 22;

s2: the first wire clamping device 22 rotates a first angle along with the rotary table 21 to enable one end of the wire to be screwed to the soldering flux groove to adhere the soldering flux;

s3: the first wire clamping device 22 rotates a second angle along with the turntable 21 to rotate one end of the wire to the tin furnace for soldering;

s4: the first wire clamping device 22 rotates a third angle along with the rotary table 21 to rotate one end of the wire to the wire drawing side;

s5: clamping one end of the wire by using the wire pulling module 50 (at the moment, the first wire clamping device 22 is opened) to pull out the wire by a set length;

s6: the wire is peeled and cut by the cutting module 60, the peeled and cut portion of the wire is between the first wire clamping device 22 and the wire drawing module 50, the finished wire having the cut end soldered is discharged, and the one end of the wire to be processed is peeled, and steps S2 to S6 are performed as the next cycle.

Further, in step S6, peeling off the other end of the soldered wire rod finished product, so as to obtain a wire rod finished product with one soldered end and one peeled end; alternatively, in step S6, the other end of the soldered wire material product is also peeled; for the cut wire rod product, the process proceeds to step S7: the cutting clamping assembly of the cutting module 60 clamps the other end of the wire rod to rotate, performs soldering on the other end of the wire rod, and simultaneously performs steps S2 to S6 as the next cycle of the wire rod to be processed, the wire rod of which one end is peeled; thus, a finished product of the wire rod with the double-end soldering tin is obtained.

The design of the invention is characterized in that a series of operations of peeling, shearing, soldering flux adhering and tin soldering of the wire rod can be rapidly completed through the design of the rotary wire rod peeling and tin soldering equipment and the cooperative operation among the modules, so that the processing efficiency is effectively improved, meanwhile, the stability of wire rod tin soldering is enhanced, and the quality risk of products such as transformers and the like is reduced; particularly, due to the rotary design, the arrangement among the modules is ingenious, a large operation space is saved, the structure of the whole equipment is more compact, the operation is more flexible, the automatic wire stripping and welding device can be widely combined and applied to various nonstandard automatic equipment, the application range is wide, and the problem that the application range of the automatic wire stripping and welding device in the traditional technology is limited is solved.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that any minor modifications, equivalent changes and modifications made to the above embodiment according to the technical spirit of the present invention are within the technical scope of the present invention.

Claims

1. The utility model provides a rotation type wire rod soldering tin equipment of skinning which characterized in that: the soldering tin rotary table comprises a workbench, and a soldering tin rotary table module, a first soldering flux groove module, a first tin furnace module, a wire pulling module and a shearing module which are arranged on the workbench; wherein:

2. The rotary wire stripping and soldering apparatus according to claim 1, wherein: the first soldering flux groove module and the first tin furnace module are arranged on the lower side of the rotary table; the shearing module and the wire drawing module are arranged on the right side of the turntable.

3. The rotary wire stripping and soldering apparatus according to claim 2, wherein: the first tin furnace module, the first scaling powder groove module and the shearing module are sequentially arranged from left to right.

4. The rotary wire stripping and soldering apparatus according to claim 1, wherein: a mounting plate is vertically arranged on the workbench; wherein:

5. The rotary wire stripping and soldering apparatus according to claim 4, wherein: the first tin furnace module, the first scaling powder groove module, the first wire clamping device, the second wire clamping device and the shearing device are all located on the front side of the mounting plate, and the first rotary driving device and the lifting driving device are arranged on the rear side of the mounting plate.

6. The rotary wire stripping and soldering apparatus according to claim 1, wherein: the shearing device is connected with a second rotary driving device, and the second rotary driving device drives the shearing device to vertically rotate around a horizontal axis; the shearing device is connected with a shearing translation driving device for driving the shearing device to displace and adjust along the pulling direction of the wire rod; the shearing device is provided with a shearing clamping assembly, a second scaling powder groove module and a second tin furnace module are arranged below the shearing device, the shearing clamping assembly clamps the other end of the wire to rotate, and the other end of the wire is subjected to tin soldering.

7. The rotary wire stripping and soldering apparatus according to claim 6, wherein: the shearing device is positioned on the right side of the soldering tin turntable module, and the first tin furnace module, the first scaling powder groove module, the second scaling powder groove module and the second tin furnace module are sequentially arranged from left to right.

8. The rotary wire stripping and soldering apparatus according to claim 1, wherein: the wire passing seat is arranged on the rotary table or the first wire clamping device, and a plurality of wire passing holes which are arranged side by side at intervals are arranged in the wire passing seat.

9. A wire peeling and soldering method is characterized in that: the method comprises the following steps:

10. The wire peeling and soldering method according to claim 10, wherein: in the step S6, peeling the other end of the soldered wire product, so as to obtain a wire product with one soldered end and one peeled end;