CN219296830U - Full-automatic tin wire rolling equipment - Google Patents

Abstract

The utility model discloses full-automatic tin wire winding equipment, wherein a driving motor is arranged on an installation base, a winding component and a wiring component are arranged on an assembly base, and the assembly base is fixedly arranged on the installation base in a detachable manner; in the winding assembly, a sleeve joint shaft is mounted on the assembly machine base and is connected with the driving motor, a winding barrel is inserted on the sleeve joint shaft, and the winding barrel is locked and fixed by the self-locking assembly; in the wiring assembly, a guide chute is fixedly connected to an assembly machine seat, a reciprocating screw rod is arranged in the guide chute, a sliding seat is arranged in the guide chute and matched with the reciprocating screw rod, a guide wheel set is arranged on the sliding seat and used for arranging soldering tin wires, and a sleeve joint shaft is linked with the reciprocating screw rod through a speed distribution assembly. The utility model realizes the rapid feeding and discharging operation of the winding cylinder, can effectively reduce the labor cost while improving the winding and packaging efficiency of the soldering tin wire, liberates the labor force and can improve the winding and packaging quality of the soldering tin wire.

Description

Full-automatic tin wire rolling equipment

Technical Field

The utility model relates to the technical field of winding and packaging of soldering tin wires, in particular to full-automatic soldering tin wire winding equipment.

Background

In the wiring operation of circuits and electronic components, the solder wires are important materials for improving auxiliary heat conduction and removing oxidation in the welding process, reducing the surface tension of the welded material, removing oil stains on the surface of the welded material and increasing the welding area. After the production of the soldering tin wire is finished, the soldering tin wire after the production is finished and the cooling is often wound and rolled onto a special winding drum for convenient packaging, retail and practical operation and use of users, so that the winding and packaging are required by means of a rolling device.

Traditional tin wire rolling equipment is in the use, needs the manual work to assemble a rolling section of thick bamboo to rolling equipment on, waits to roll up the equipment with the tin wire on rolling section of thick bamboo, still needs the manual work to take off the new rolling section of thick bamboo of assembly with a rolling section of thick bamboo, when manual operation, is difficult to guarantee the last unloading speed of a rolling section of thick bamboo, and then leads to the rolling packing speed of tin wire limited. In addition, in use, the traditional tin wire winding equipment is different in package size, different winding drums are required to be selected, and at least two groups of power equipment related to the winding equipment are required (the winding drums are driven to rotate and the tin wire is driven to reciprocate in the range of the winding drums), so that manual debugging is required, uncertainty caused by manual intervention is increased, and the winding and packaging quality of the tin wire is difficult to guarantee.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model aims to provide the full-automatic tin wire winding equipment, which can realize the rapid feeding and discharging operation of the winding cylinder, effectively reduce the labor cost while improving the tin wire winding packaging efficiency, liberate the labor force and improve the tin wire winding packaging quality.

The technical scheme adopted by the utility model for achieving the purpose is as follows: the full-automatic tin wire winding device comprises an installation base, a driving motor, an assembly base, a winding component and a wiring component, wherein the driving motor is fixedly installed on the installation base, the winding component and the wiring component are installed on the assembly base in a matched mode, and the assembly base is fixedly installed on the installation base in a detachable mode.

The winding assembly comprises a sleeve joint shaft and a self-locking assembly, the sleeve joint shaft is rotatably mounted on the assembly machine base, the sleeve joint shaft is in power connection with a rotating shaft of the driving motor through a coupler, a winding barrel for winding tin wires is connected to the sleeve joint shaft in a sliding inserting mode, and the self-locking assembly is mounted on the sleeve joint shaft in a matched mode and locks and fixes the winding barrel.

The wiring assembly comprises a guide chute, a sliding seat, a reciprocating screw and a guide wheel set, wherein the guide chute is fixedly connected to the assembly machine base, the reciprocating screw is rotatably installed in the guide chute, the sliding seat is slidably installed in the guide chute and is screwed with the reciprocating screw in a matched mode, the guide wheel set is installed on the sliding seat in a matched mode and is used for distributing soldering tin wires, and the sleeve joint shaft is linked with the reciprocating screw through a speed distribution assembly.

In some implementations, in order to ensure stable installation of the driving motor in the installation base and stable installation of the speed matching component in the assembly base, specific angular speed matching operation of the winding component and the wiring component is further realized, and stable installation of the assembly base on the installation base is ensured.

The mounting machine seat is provided with a mounting groove, a mounting cover is fixedly matched with the mounting groove, the driving motor is fixedly mounted in the mounting groove, and a rotating shaft of the driving motor extends out of the mounting cover; the mounting machine seat is fixedly connected with a mounting pad table arranged below the mounting groove, and the mounting machine seat is fixedly mounted on the mounting pad table through bolts; the assembly machine seat is internally provided with an installation cavity, the reciprocating screw rod and the sleeve joint shaft extend into the installation cavity, and the speed matching assembly is arranged in the installation cavity in a matched mode and is connected with the sleeve joint shaft and the reciprocating screw rod in a matched mode.

In some implementations, in order to ensure that the winding drum can be stably inserted onto the sleeve joint shaft, the winding drum is conveniently assembled and disassembled on the sleeve joint shaft, and the winding drum and the sleeve joint shaft are ensured to synchronously rotate when the sleeve joint shaft is driven by the driving motor.

The guide bars distributed in an annular array are uniformly fixedly connected to the sleeve joint shaft, guide grooves for sliding combination of the guide bars are formed in the inner side wall of the winding barrel, and arc-shaped transition surfaces are arranged at the outer side end of the sleeve joint shaft and at the ports at the two ends of the winding barrel.

In one implementation, in order to ensure that the self-locking assembly can lock and fix the winding drum inserted on the sleeve joint shaft, the winding drum is prevented from sliding off the sleeve joint shaft when the equipment is in operation, the self-locking assembly is conveniently controlled to cancel the locking effect on the winding drum, and the winding drum is conveniently disassembled and assembled.

Locking grooves are uniformly formed in the inner side wall of the winding drum, and mounting through grooves are formed in the outer side end of the sleeve joint shaft; the self-locking assembly comprises a locking block, a driving rod, an unlocking footstock, a connecting rod and a reset spring, wherein the locking block, the driving rod, the unlocking footstock, the connecting rod and the reset spring are assembled in an installation through groove, the locking block is rotatably installed in the installation through groove and exposed out of a locking shaft, the locking block is nested and kept in nested fit with the locking groove, the unlocking footstock is exposed out of the outer side of the end part of the locking shaft, the driving rod is fixedly connected with the unlocking footstock, the two ends of the connecting rod are respectively hinged with the locking block and the driving rod, and the reset spring is matched and combined with the driving rod to reset the unlocking footstock.

In some implementations, when the produced and cooled soldering tin wire is wound on the winding drum, the adopted standard winding method is to control the winding drum to rotate at a constant speed and simultaneously control the soldering tin wire which is wound in the winding drum to move in a reciprocating cycle at two ends of the winding drum, so that the soldering tin wire is uniformly distributed and wound on the winding drum, and the speed ratio between the sleeving shaft and the reciprocating screw rod is ensured by the speed matching assembly, so that the following technical scheme related to the speed matching assembly is provided.

The speed matching assembly comprises a first synchronous wheel, a second synchronous wheel and a synchronous belt, wherein the first synchronous wheel is fixedly connected with the sleeve joint shaft, the second synchronous wheel is fixedly connected with the reciprocating screw rod, and the synchronous belt is wound on the first synchronous wheel and the second synchronous wheel and is in a tight state.

In some implementations, in order to ensure that the guide wheel set can stably roll up the solder wire which is produced and cooled to normal temperature onto the winding drum, the solder wire needs to be stably input onto the winding drum by means of the guide wheel set, so that the following technical scheme related to the guide wheel set is provided.

The guide wheel group comprises a connecting frame plate and longitudinal guide wheels, transverse guide wheels and drop guide wheels which are rotatably arranged on the connecting frame plate, the connecting frame plate is fixedly arranged on the sliding seat, the transverse guide wheels comprise two groups which are arranged in a clinging mode, soldering tin wires pass through the two groups of transverse guide wheels, the longitudinal guide wheels comprise two groups which are arranged in a clinging mode and are arranged at the downstream end of the transverse guide wheels, the longitudinal guide wheels are higher than the transverse guide wheels, the soldering tin wires pass through the two groups of longitudinal guide wheels and extend to the winding cylinder, the drop guide wheels comprise two groups which are arranged at different heights, the drop guide wheels are arranged between the transverse guide wheels and the longitudinal guide wheels, and the soldering tin wires bypass the two groups of drop guide wheels sequentially.

The utility model has the beneficial effects that: utilize the automatic tin wire rolling equipment that this application provided, can use with the arm is supporting, under the cooperation operation of cup jointing axle and auto-lock subassembly, can lock a rolling section of thick bamboo to cup jointing epaxially voluntarily, can also cancel the locking effect to a rolling section of thick bamboo simultaneously fast through the unblock footstock, realize the quick unloading operation of going up to a rolling section of thick bamboo, when improving tin wire rolling packaging efficiency, can effectively reduce the cost of labor, make the labour can liberate. The speed matching assembly is utilized to realize the matching operation between the winding assembly and the wiring assembly, so that the problem of uneven winding of the soldering tin wire caused by manual intervention is solved, and the winding and packaging quality of the soldering tin wire is improved.

Drawings

FIG. 1 is a schematic view of the present utility model;

FIG. 2 is a schematic diagram of the structure of the mounting frame and the disassembled driving motor;

FIG. 3 is a schematic view of an assembled housing and its associated components;

FIG. 4 is a schematic view of the structure of FIG. 3 from another view;

FIG. 5 is a schematic view of the structure of the matched combination of the winding assembly, the wiring assembly and the speed matching assembly;

FIG. 6 is a schematic diagram of a matched combination of a guide wheel set and a solder wire;

FIG. 7 is a schematic view of the structure of the reciprocating screw and its associated components;

FIG. 8 is a schematic structural view of a take-up drum;

FIG. 9 is a schematic view of the socket shaft (partially cut away) and its associated components;

FIG. 10 is an enlarged detailed schematic view of portion A of FIG. 9;

fig. 11 is a schematic structural view of the self-locking assembly (with part of the locking block, connecting rod removed).

In the figure: 1 installation frame, 11 mounting groove, 12 installation cover, 13 installation pad platform, 2 driving motor, 3 assembly frame, 4 rolling component, 41 sleeve joint axle, 411 guide bar, 412 installation through groove, 413 spline groove, 414 coupling, 421 lock block, 422 actuating lever, 423 unblock footstock, 424 connecting rod, 425 reset spring, 426 spline shaft, 427 backing ring, 5 wiring component, 51 guide chute, 52 slide, 53 reciprocating screw, 541 connection frame plate, 542 longitudinal guide wheel, 543 transverse guide wheel, 544 drop guide wheel, 61 first synchronous wheel, 62 second synchronous wheel, 63 synchronous belt, 7 winding drum, 71 guide groove, 72 lock groove, 73 draw-in groove, 8 soldering tin wire.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-11, a full-automatic tin wire winding device comprises a mounting base 1, a driving motor 2, an assembling base 3, a winding component 4 and a wiring component 5, wherein the driving motor 2 is fixedly installed on the mounting base 1, the winding component 4 and the wiring component 5 are installed on the assembling base 3 in a matching manner, and the assembling base 3 is fixedly installed on the mounting base 1 in a detachable manner.

The winding component 4 comprises a sleeve joint shaft 41 and a self-locking component, the sleeve joint shaft 41 is rotatably mounted on the assembly machine base 3, the sleeve joint shaft 41 is in power connection with a rotating shaft of the driving motor 2 through a coupler 414, the sleeve joint shaft 41 is in sliding connection with a winding cylinder 7 for winding tin wires, and the self-locking component is mounted on the sleeve joint shaft 41 in a matched manner and locks and fixes the winding cylinder 7.

The wiring assembly 5 comprises a guide chute 51, a sliding seat 52, a reciprocating screw 53 and a guide wheel set, wherein the guide chute 51 is fixedly connected to the assembly machine base 3, the reciprocating screw 53 is rotatably installed in the guide chute 51, the sliding seat 52 is slidably installed in the guide chute 51 and is in screwed connection with the reciprocating screw 53 in a matched mode, the guide wheel set is installed on the sliding seat 52 in a matched mode and is used for arranging solder wires 8, and the sleeving shaft 41 is linked with the reciprocating screw 53 through the speed matching assembly.

The guide chute 51 is provided with a slide rail arranged along the extending direction of the guide chute 51, and the side wall of the slide base 52 is provided with a chute which is matched with the slide rail and keeps sliding combination, so that the slide base 52 stably slides along the guide chute 51.

The reciprocating screw 53 is common equipment on the market, unlike the conventional screw, the reciprocating screw 53 is provided with two twisted thread grooves along opposite directions, the head ends and the tail ends of the two thread grooves are in smooth transition connection, when the reciprocating screw 53 rotates, the corresponding sliding seat 52 can be driven to slide reciprocally in the range of the thread grooves, namely, the reciprocating screw 53 which rotates unidirectionally can drive the sliding seat 52 to slide reciprocally bidirectionally.

Utilize the automatic tin silk rolling equipment that this application provided, can use with the arm is supporting, under the cooperation operation of cup jointing axle 41 and auto-lock subassembly, can lock a rolling section of thick bamboo 7 to cup jointing epaxially 41 voluntarily, can also cancel the locking effect to a rolling section of thick bamboo 7 simultaneously through unblock footstock 423 fast, realize the quick unloading operation of going up to a rolling section of thick bamboo 7, when improving 8 rolling packaging efficiency of tin silk, can effectively reduce the cost of labor, make the labour liberated. The matching operation between the winding component 4 and the wiring component 5 is realized by utilizing the speed matching component, the problem of uneven winding of the soldering tin wire 8 caused by manual intervention is solved, and the winding and packaging quality of the soldering tin wire 8 is improved.

In order to ensure that the driving motor 2 is stably installed in the installation base 1, the speed matching component is stably installed in the assembly base 3, and further the specific angular speed matching operation of the winding component 4 and the wiring component 5 is realized, and the stable installation of the assembly base 3 on the installation base 1 is ensured, the following technical scheme is provided.

The mounting machine seat 1 is provided with a mounting groove 11, a mounting cover 12 is fixedly matched with the mounting groove 11, the driving motor 2 is fixedly mounted in the mounting groove 11, and a rotating shaft of the driving motor 2 extends out of the mounting cover 12; the mounting machine base 1 is fixedly connected with a mounting pad table 13 arranged below the mounting groove 11, and the mounting machine base 3 is fixedly mounted on the mounting pad table 13 through bolts; the assembly machine base 3 is provided with an installation cavity, the reciprocating screw rod 53 and the sleeve joint shaft 41 extend into the installation cavity, and the speed matching component is installed in the installation cavity in a matched mode and is connected with the sleeve joint shaft 41 and the reciprocating screw rod 53 in a matched mode.

The mounting groove 11 can guarantee that driving motor 2 is installed wherein stably, and the stability of driving motor 2 at the inside operation of installation frame 1 is guaranteed to assembly installation lid 12, installs the installation pad platform 13 additional and can guarantee that assembly frame 3 is installed wherein stably, the installation cavity of seting up in assembly frame 3, can guarantee to join in marriage fast subassembly and install wherein stably, avoids receiving external environment to interfere the fast precision of joining in marriage, guarantees that soldering tin 8 is reciprocal stable winding on a rolling section of thick bamboo 7.

The assembly machine base 3 and the winding component 4 and the wiring component 5 arranged on the assembly machine base exist as a whole, the winding barrels 7 matched with the assembly machine base also meet the corresponding specification and size, when the winding barrels 7 with different specifications are used for winding the soldering tin wires 8, the corresponding assembly machine base 3 and the winding component 4 and the wiring component 5 matched with the assembly machine base are adopted, and the winding component 4 and the wiring component 5 are ensured to meet the specific running speed ratio under the association action of the corresponding speed matching component.

In order to ensure that the winding drum 7 can be stably inserted onto the sleeve joint shaft 41, the winding drum 7 is conveniently assembled and disassembled on the sleeve joint shaft 41, and the winding drum 7 and the sleeve joint shaft 41 are ensured to synchronously rotate when the sleeve joint shaft 41 is driven to rotate by the driving motor 2, the following technical scheme is provided.

Guide strips 411 distributed in an annular array are uniformly fixedly connected to the sleeve joint shaft 41, guide grooves 71 formed by sliding and combining the guide strips 411 are formed in the inner side wall of the winding drum 7, and arc-shaped transition surfaces are arranged at the outer side end of the sleeve joint shaft 41 and at the ports at the two ends of the winding drum 7.

The combination of the guide strip 411 and the guide groove 71 can ensure that the winding drum 7 is inserted onto the sleeve joint shaft 41 from the outer side end of the sleeve joint shaft 41 and synchronously rotates with the sleeve joint shaft 41, and the ports at the two ends of the winding drum 7 and the arc transition surface at the outer side end of the sleeve joint shaft 41 can be conveniently matched and combined, so that the winding drum 7 is convenient to assemble and disassemble on the sleeve joint shaft 41.

In order to ensure that the self-locking assembly can lock and fix the winding drum 7 inserted onto the sleeve joint shaft 41, the winding drum 7 is prevented from sliding off the sleeve joint shaft 41 during equipment operation, the self-locking assembly is conveniently controlled to cancel the locking effect on the winding drum 7, and the winding drum 7 is conveniently disassembled and assembled, the following technical scheme is provided.

The inner side wall of the winding drum 7 is uniformly provided with locking grooves 72, and the outer side end of the sleeve joint shaft 41 is provided with a mounting through groove 412; the self-locking assembly comprises a locking block 421, a driving rod 422, an unlocking top seat 423, a connecting rod 424 and a return spring 425, wherein the locking block 421 is assembled in an installation through groove 412 and exposed out of a locking shaft, the locking block 421 and the locking groove 72 are nested and kept in nested fit, the unlocking top seat 423 is exposed out of the outer end part of the locking shaft, the driving rod 422 is fixedly connected with the unlocking top seat 423, two ends of the connecting rod 424 are respectively hinged with the locking block 421 and the driving rod 422, and the return spring 425 is matched and combined with the driving rod 422 to reset the unlocking top seat 423.

The locking grooves 72 are formed at two ends of the inner wall of the winding drum 7 so as to cancel the directivity of the winding drum 7, and no matter which end of the winding drum 7 is inserted into the sleeve shaft 41, the locking block 421 and the locking groove 72 can be nested and combined to realize the locking effect. Since the locking grooves 72 at the two ends are in a symmetrical design state, in the process of inserting the winding drum 7 into the sleeve joint shaft 41, the locking grooves 72 which enter first cannot realize the locking effect due to the opposite arrangement with the locking blocks 421, so that the locking grooves 72 which enter later are ensured to normally act with the locking blocks 421 and are locked.

The part of the locking piece 421 exposed to the outer side of the sleeve joint shaft 41 is provided with an action inclined plane, so that the locking groove 72 in the winding drum 7 can be ensured to be marked on the locking piece 421, and the locking combination of the locking piece 421 and the locking piece can be realized.

The reset spring 425 is used for driving the driving rod 422 and the unlocking top seat 423 to move outwards, so that the locking block 421 is ejected outwards through the connecting rod 424, and the locking block 421 and the locking groove 72 are locked stably.

In order to ensure the stability of sliding operation of the driving rod 422 and the unlocking top seat 423 in the installation through groove 412, and simultaneously ensure the matching connection of the reset spring 425 and the driving rod 422, a spline shaft 426 is fixedly connected to the inner side end of the driving rod 422, a backing ring 427 is fixedly connected to the joint of the driving rod 422 and the spline shaft 426, a spline groove 413 matched and combined with the spline shaft 426 is formed in the inner side of the installation through groove 412, and the spline shaft 426 and the spline groove 413 are matched and arranged to ensure the stability of operation of the driving rod 422 and the unlocking top seat 423. The reset spring 425 is wound on the periphery of the spline shaft 426, and two ends of the reset spring 425 are respectively abutted against the backing ring 427 and the inner wall of the mounting through groove 412, so that the reset spring 425 can realize the self design function.

The winding component 4 designed above can be suitable for feeding and discharging with the aid of a manipulator, labor can be reduced to form a pump, the winding and packaging efficiency of the solder wires 8 is improved, and the winding component is embodied as the following embodiment.

The mechanical arm that adopts is supporting to have anchor clamps and flexible cylinder, evenly has offered the draw-in groove 73 that can form a complete set with anchor clamps at winding drum 7 both ends, in clamping groove 73 is got to the clamp when the mechanical arm presss from both sides and gets winding drum 7, guarantees the stability of centre gripping winding drum 7, later utilizes the mechanical arm to move in the degree of freedom of design, will receive winding drum 7 and insert on cup joint axle 41, and the setting of auto-lock subassembly can guarantee to receive winding drum 7 and cup joint axle 41's automatic locking after inserting completely and realize receiving winding drum 7.

When the mechanical arm is adopted to detach the winding drum 7 on the sleeve joint shaft 41, the end part of the winding drum 7 is fixed through the clamp, then the telescopic cylinder is controlled to retract to trigger the unlocking footstock 423 to move towards the inner side of the sleeve joint shaft 41, at the moment, the locking block 421 is driven to retract through the driving rod 422 and the connecting rod 424, the locking effect of the sleeve joint shaft 41 on the winding drum 7 is canceled, and the winding drum 7 can be quickly taken down.

When the produced and cooled soldering tin wire 8 is wound on the winding drum 7, the adopted standard winding method is to control the winding drum 7 to rotate at a constant speed and simultaneously control the soldering tin wire 8 which is wound in the winding drum to move reciprocally at two ends of the winding drum, so as to ensure that the soldering tin wire 8 is uniformly distributed and wound on the winding drum, and the speed ratio between the sleeving shaft 41 and the reciprocating screw 53 is ensured by means of the speed matching component, so that the following technical scheme related to the speed matching component is provided.

The speed matching assembly comprises a first synchronous wheel 61, a second synchronous wheel 62 and a synchronous belt 63, wherein the first synchronous wheel 61 is fixedly connected with the sleeve joint shaft 41, the second synchronous wheel 62 is fixedly connected with the reciprocating screw 53, and the synchronous belt 63 is wound on the first synchronous wheel 61 and the second synchronous wheel 62 and is in a tight state.

When the driving motor 2 works and drives the sleeve joint shaft 41 to rotate through the coupler 414, the reciprocating screw 53 can be driven to stably rotate through the combination of the first synchronous wheel 61, the second synchronous wheel 62 and the synchronous belt 63, and the angular speed ratio of the sleeve joint shaft 41 to the reciprocating screw 53 can be adjusted by adjusting the gear ratio of the first synchronous wheel 61 and the second synchronous wheel 62, so that the speed ratio of the rotating speed of the sleeve joint shaft 41 to the sliding speed of the sliding seat 52 sliding on the guide sliding groove 51 is determined.

The travel range of the sliding seat 52 on the guide sliding groove 51 is matched with the effective length of the matched winding drum 7 for winding the soldering tin wire 8, so that the soldering tin wire 8 guided out by the wiring assembly 5 is ensured to be wound in a reciprocating manner within the effective length range of the winding drum 7.

In order to ensure that the guide wheel set can stably roll the solder wire 8 which is produced and cooled to normal temperature onto the winding drum 7, the solder wire 8 needs to be stably input onto the winding drum 7 by means of the guide wheel set, and the following technical scheme about the guide wheel set is provided.

The guide wheel group comprises a connecting frame plate 541 and longitudinal guide wheels 542, transverse guide wheels 543 and drop guide wheels 544 which are rotatably arranged on the connecting frame plate 541, the connecting frame plate 541 is fixedly arranged on the sliding seat 52, the transverse guide wheels 543 comprise two groups which are tightly arranged, the solder wires 8 pass through the two groups of transverse guide wheels 543, the longitudinal guide wheels 542 comprise two groups which are tightly arranged and are arranged at the downstream end of the transverse guide wheels 543, the longitudinal guide wheels 542 are higher than the transverse guide wheels 543, the solder wires 8 pass through the two groups of longitudinal guide wheels 542 and extend to the winding drum 7, the drop guide wheels 544 comprise two groups which are arranged at different heights, the drop guide wheels 544 are arranged between the transverse guide wheels 543 and the longitudinal guide wheels 542, and the solder wires 8 sequentially bypass the two groups of drop guide wheels 544.

Because the sliding seat 52 can reciprocate in the travel range of the guide chute 51, the arrangement of the two groups of transverse guide wheels 543 can ensure that the solder wire 8 is always conveyed to the winding drum 7 in a transverse stable posture; in the process that the solder wire 8 is gradually wound on the winding drum 7, the thickness is increased to cause the drop change of the solder wire 8 which is conveyed to the winding drum 7, and the two groups of longitudinal guide wheels 542 can ensure that the solder wire 8 is always conveyed to the winding drum 7 in a longitudinal stable posture. The arrangement of the two sets of drop guide wheels 544 can ensure that the solder wires 8 output by the transverse guide wheels 543 are stably transferred to the longitudinal guide wheels 542, and the height difference between the two sets of drop guide wheels can be prevented from influencing the conveying stability of the solder wires 8.

When utilizing the full-automatic tin wire rolling equipment that this application disclosed to carry out the rolling packing of tin wire 8, still need with the help of guide component, cutting component cooperation operation, the guide component that this relates to, cutting component is the same with the function, the structure of the relevant part that common tin wire rolling equipment used in market, not be described in detail here, guide component can lead in the winding drum 7 with the tin wire 8 of wiring subassembly 5 output and carry out the winding under the initial condition, fix the tin wire 8 head on the winding drum 7, after the winding work is accomplished, cutting component can cut off the tin wire 8 from the winding drum 7, accomplish the rolling task of this group of winding drum 7, prepare the winding work of next group of winding drum 7 simultaneously, guarantee that the tin wire winding work is continuous high-efficient.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (6)

1. Full-automatic tin wire rolling equipment, its characterized in that: the automatic winding machine comprises an installation machine seat (1), a driving motor (2), an assembly machine seat (3), a winding assembly (4) and a wiring assembly (5), wherein the driving motor (2) is fixedly installed on the installation machine seat (1), the winding assembly (4) and the wiring assembly (5) are installed on the assembly machine seat (3) in a matched mode, and the assembly machine seat (3) is fixedly installed on the installation machine seat (1) in a detachable mode; the winding component (4) comprises a sleeve joint shaft (41) and a self-locking component, wherein the sleeve joint shaft (41) is rotatably installed on the assembly machine base (3), the sleeve joint shaft (41) is in power connection with a rotating shaft of the driving motor (2) through a coupler (414), a winding drum (7) for winding tin wires is connected to the sleeve joint shaft (41) in a sliding and inserting mode, and the self-locking component is installed on the sleeve joint shaft (41) in a matched mode and locks and fixes the winding drum (7); the wiring assembly (5) comprises a guide chute (51), a sliding seat (52), a reciprocating screw (53) and a guide wheel set, wherein the guide chute (51) is fixedly connected to the assembly machine base (3), the reciprocating screw (53) is rotatably installed in the guide chute (51), the sliding seat (52) is slidably installed in the guide chute (51) and is rotatably connected with the reciprocating screw (53) in a matched mode, the guide wheel set is installed on the sliding seat (52) in a matched mode and is used for arranging soldering wires (8), and the sleeve joint shaft (41) is linked with the reciprocating screw (53) through a speed matching assembly.

2. The fully automatic tin wire winding device according to claim 1, wherein: the mounting machine comprises a mounting machine base (1), a mounting groove (11) is formed in the mounting machine base (1), a mounting cover (12) is fixedly arranged on the mounting groove (11) in a matching mode, the driving motor (2) is fixedly arranged in the mounting groove (11), and a rotating shaft of the driving motor (2) extends out of the mounting cover (12); the mounting machine seat (1) is fixedly connected with a mounting pad table (13) arranged below the mounting groove (11), and the assembly machine seat (3) is fixedly arranged on the mounting pad table (13) through bolts; the assembly machine seat (3) is internally provided with an installation cavity, the reciprocating screw rod (53) and the sleeving shaft (41) are both extended into the installation cavity, and the speed matching component is arranged in the installation cavity in a matched mode and is connected with the sleeving shaft (41) and the reciprocating screw rod (53) in a matched mode.

3. The fully automatic tin wire winding device according to claim 1, wherein: guide strips (411) distributed in an annular array are uniformly fixedly connected to the sleeve joint shaft (41), guide grooves (71) formed by sliding and combining the guide strips (411) are formed in the inner side wall of the winding barrel (7), and arc-shaped transition surfaces are arranged at the outer side end of the sleeve joint shaft (41) and at the ports at the two ends of the winding barrel (7).

4. The fully automatic tin wire winding device according to claim 1, wherein: the inner side wall of the winding drum (7) is uniformly provided with locking grooves (72), and the outer side end of the sleeve joint shaft (41) is provided with a mounting through groove (412); the self-locking assembly comprises a locking piece (421) assembled in an installation through groove (412), a driving rod (422), an unlocking footstock (423), a connecting rod (424) and a return spring (425), wherein the locking piece (421) is rotatably installed in the installation through groove (412) and exposed out of a locking shaft, the locking piece (421) is nested and kept nested and anastomotic with the locking groove (72), the unlocking footstock (423) is exposed out of the outer side of the end part of the locking shaft, the driving rod (422) is fixedly connected with the unlocking footstock (423), two ends of the connecting rod (424) are respectively hinged with the locking piece (421) and the driving rod (422), and the return spring (425) is matched and combined with the driving rod (422) to reset the unlocking footstock (423).

5. A fully automatic tin wire winding device as claimed in claim 2, wherein: the speed matching assembly comprises a first synchronous wheel (61), a second synchronous wheel (62) and a synchronous belt (63), wherein the first synchronous wheel (61) is fixedly connected with the sleeve joint shaft (41), the second synchronous wheel (62) is fixedly connected with the reciprocating screw rod (53), and the synchronous belt (63) is wound on the first synchronous wheel (61) and the second synchronous wheel (62) and is in a tight state.

6. The fully automatic tin wire winding device according to claim 1, wherein: the guide wheel group comprises a connecting frame plate (541) and longitudinal guide wheels (542), transverse guide wheels (543) and drop guide wheels (544) which are rotatably mounted on the connecting frame plate (541), the connecting frame plate (541) is fixedly mounted on the sliding seat (52), the transverse guide wheels (543) comprise two groups which are tightly arranged, a solder wire (8) passes through the two groups of transverse guide wheels (543), the longitudinal guide wheels (542) comprise two groups which are tightly arranged and are arranged at the downstream end of the transverse guide wheels (543), the longitudinal guide wheels (542) are higher than the transverse guide wheels (543), the solder wire (8) passes through the two groups of longitudinal guide wheels (542) and extends to the winding drum (7), the drop guide wheels (544) comprise two groups which are arranged at different heights, the drop guide wheels (544) are arranged between the transverse guide wheels (543) and the longitudinal guide wheels (542), and the solder wire (8) sequentially bypasses the two groups of drop guide wheels (544).

Images