CN110935974B - Efficient wire winding soldering tin machine - Google Patents

Abstract

The invention discloses a high-efficiency wire-winding soldering machine which is used for wire-winding operation and soldering fixation of a three-leg inductance magnetic core and comprises a material arranging mechanism, a wire-winding mechanism, a soldering mechanism, a material feeding and taking mechanism and a control device, wherein the material arranging mechanism, the wire-winding mechanism, the soldering mechanism and the material feeding and taking mechanism are connected with the control device, and the material feeding and taking mechanism comprises a first clamping fixture assembly and a second clamping fixture assembly; the material arranging mechanism comprises a vibrating disc, a blanking guide rail and a feeding assembly; the winding mechanism comprises a main shaft device, a residual wire clamp device and a winding device; the soldering tin mechanism comprises a lifting moving device, a distance shrinking clamp, a soldering flux box, a tin furnace, a recycling and conveying device and a receiving box. According to the winding soldering machine, feeding, arranging and feeding operations are automatically completed through the vibrating disc, the blanking guide rail and the feeding assembly, and the whole processes of feeding, winding, soldering and discharging are fully automatic, so that the technical problems of time and labor waste caused by single operation in the prior art are solved, and the production efficiency is high and the production cost is low.

Description

Efficient wire winding soldering tin machine

Technical Field

The invention relates to the technical field of soldering equipment, in particular to a wire-winding soldering machine with high efficiency.

Background

The inductor is a common electronic element in a circuit, mainly plays roles in filtering, oscillating, delaying, trapping and the like in the circuit, and also plays roles in screening signals, filtering noise, stabilizing current, inhibiting electromagnetic wave interference and the like, so that the inductor has wider application range. The i-inductor is mainly a two-leg i-inductor or a three-leg i-inductor, and an induction coil of the i-inductor is usually wound on a magnetic core. The traditional three-leg I-shaped inductor adopts artifical material loading, the in-process of soldering tin, artifical soldering tin, and current winding equipment can only carry out semi-automatic wire winding to three-leg I-shaped inductor, can only accomplish two feet wire winding operations, need the manual work to continue winding after the unloading, intensity of labour is big, work efficiency is low, is not suitable for the scale production of enterprise, and wire winding effect is not guaranteed, still need the material loading to carry out soldering tin again after accomplishing the wire winding, the processing procedure is complicated, the step is many, production cycle is long, it is time consuming and laborious, finally lead to manufacturing cost to be high, be unfavorable for the long-term development of enterprise.

Therefore, how to solve the above technical problems is a technical problem to be solved in the industry.

Disclosure of Invention

The invention mainly aims to provide a wire-winding soldering machine with high efficiency, and aims to realize the wire-winding soldering machine with high automation degree, low labor intensity, high wire-winding efficiency, good soldering effect and low production cost.

The invention provides a high-efficiency wire-winding soldering machine which is used for wire-winding operation and soldering fixation of a three-leg inductance magnetic core and comprises a material arranging mechanism, a wire winding mechanism, a soldering mechanism, a material feeding and taking mechanism and a control device, wherein the material arranging mechanism, the wire winding mechanism, the soldering mechanism and the material feeding and taking mechanism are connected with the control device, and the material feeding and taking mechanism comprises a workbench, a transverse guide rail arranged on the workbench, a first clamp assembly arranged on the transverse guide rail through a first sliding block and a second clamp assembly arranged on the transverse guide rail through a second sliding block; the material placing mechanism comprises a bracket, a vibrating disc, a blanking guide rail, a support and a material loading assembly arranged on the support; the winding mechanism comprises a frame, a wire frame, a main shaft device, a residual wire clamp device and a winding device, wherein the main shaft device, the residual wire clamp device and the winding device are arranged on the frame; the soldering tin mechanism comprises a base, an outer cover arranged on the base, a lifting moving device arranged on the base, a distance shrinking clamp arranged on the lifting moving device, a soldering flux box arranged on the base, a tin furnace, a recycling and conveying device and a receiving box.

Preferably, the feeding assembly comprises a guide groove, a locating piece, a pushing device and a flattening cylinder, wherein the guide groove is arranged on the support column and is in an I shape, the locating piece is arranged in the guide groove, the pushing device is used for pushing the three-leg inductance magnetic cores into the first clamping fixture assembly one by one, and the flattening cylinder is used for flattening the three-leg inductance magnetic cores pushed into the first clamping fixture assembly.

Preferably, the feeding and taking mechanism further comprises a belt, a plurality of gears and a driving motor, wherein the belt drives the first sliding block and the second sliding block to move along the transverse guide rail.

Preferably, the first clamp assembly comprises a first bottom plate arranged on the first sliding block, a first longitudinal guide rail arranged on the first bottom plate, a first lifting assembly arranged on the first longitudinal guide rail through the third sliding block, a first driving cylinder for driving the third sliding block to move along the first longitudinal guide rail, and a first clamp seat arranged on the first lifting assembly, wherein a plurality of first clamp tools are distributed on the first clamp seat.

Preferably, the second clamp assembly comprises a second bottom plate arranged on the second sliding block, a second longitudinal guide rail arranged on the second bottom plate, a second clamp jig seat arranged on the second longitudinal guide rail through the fourth sliding block, and a second driving cylinder for driving the fourth sliding block to move along the second longitudinal guide rail, wherein a plurality of second clamp jigs and third driving cylinders are distributed on the second clamp jig seat.

Preferably, the control device comprises a first control panel and a second control panel.

Preferably, the winding device can move along the up-down, left-right and front-back directions of the frame, and the winding device comprises a wire arranging frame.

Preferably, the wire-wound soldering machine further comprises a protective cover arranged on the workbench.

Preferably, the housing is provided with an exhaust assembly.

According to the winding soldering machine, feeding, arranging and loading operations are automatically completed through the vibrating plate, the blanking guide rail and the loading assembly, and the whole processes of feeding, loading, winding, soldering tin and unloading are fully automatically completed, so that the technical problem that the traditional single machine operation is time-consuming and labor-consuming is solved, the winding operation and soldering tin fixation of the three-leg inductance magnetic core are fully automatically completed, the integration level and the automation degree are high, the labor intensity is low, the production efficiency is greatly improved, the production cost is reduced, and the consistency of the yield and the quality of finished products is ensured.

Drawings

FIG. 1 is a schematic perspective view of an embodiment of a high efficiency wire-wound soldering machine according to the present invention;

FIG. 2 is an enlarged schematic view of a swing mechanism in a high-efficiency wire-wound soldering machine according to an embodiment of the present invention, in which the bracket is not shown;

FIG. 3 is a schematic perspective view of a feeding and extracting mechanism in an embodiment of a high-efficiency wire-wound soldering machine according to the present invention, wherein the feeding and extracting mechanism includes a portion A;

FIG. 4 is an enlarged schematic view of the portion A in FIG. 3;

FIG. 5 is a schematic perspective view of a winding mechanism of an embodiment of a high-efficiency wire-wound soldering machine according to the present invention;

FIG. 6 is a schematic perspective view of a soldering mechanism in an embodiment of a high-efficiency wire-wound soldering machine according to the present invention;

fig. 7 is an enlarged schematic view showing a three-dimensional structure of a soldering mechanism in an efficient wire-wound soldering machine according to an embodiment of the present invention, wherein neither the base nor the housing is shown.

The achievement of the objects, functional features and advantages of the present invention will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Referring to fig. 1 to 7, an embodiment of a high-efficiency wire winding soldering machine according to the present invention is provided for winding operation and soldering fixing of a three-leg inductor magnetic core 600, and includes a material placing mechanism 100, a winding mechanism 200, a soldering mechanism 300, a material feeding and taking mechanism, and a control device, where the material placing mechanism 100, the winding mechanism 200, the soldering mechanism 300, and the material feeding and taking mechanism are connected with the control device, and the control device includes a first control panel 501 and a second control panel 502, and a user can set parameters on the first control panel 501 and the second control panel 502.

The feeding and taking mechanism is arranged at the front end of the wire-winding soldering tin machine and comprises a workbench 401, a transverse guide rail 403 arranged on the workbench 401, a first clamp jig assembly arranged on the transverse guide rail 403 through a first sliding block 407, and a second clamp jig assembly arranged on the transverse guide rail 403 through a second sliding block 415. The feeding and taking mechanism further comprises a belt 404, a plurality of gears 405 and a driving motor 406, wherein the belt 404 drives the first sliding block 407 and the second sliding block 415 to move along the transverse guide rail 403, the output end of the driving motor 406 is connected with the gears 405 and drives the gears 405 to rotate, so that the belt 404 is driven to move, and finally the first clamping fixture component and the second clamping fixture component are driven to move along the transverse guide rail 403, and automatic feeding and taking operations are completed.

The first clamping fixture assembly comprises a first bottom plate 408 arranged on the first sliding block 407, a first longitudinal guide rail 409 arranged on the first bottom plate 408, a first lifting assembly 411 arranged on the first longitudinal guide rail 409 through a third sliding block 410, a first driving cylinder 412 for driving the third sliding block 410 to move along the first longitudinal guide rail 409, and a first clamping fixture seat 413 arranged on the first lifting assembly 411, wherein a plurality of first clamping fixtures 414 are distributed on the first clamping fixture seat 413. The first clamping fixture seat 413 moves left and right, up and down and back and forth through the driving motor 406, the first lifting assembly 411 and the first driving cylinder 412, a plurality of first clamping fixtures 414 are distributed on the first clamping fixture seat 413, and the first clamping fixtures 414 are used for clamping the three-leg inductance core 600.

The second clamping fixture assembly comprises a second bottom plate 416 arranged on the second sliding block 415, a second longitudinal guide rail 417 arranged on the second bottom plate 416, a second clamping fixture seat 419 arranged on the second longitudinal guide rail 417 through a fourth sliding block 418, and a second driving cylinder for driving the fourth sliding block 418 to move along the second longitudinal guide rail 417, wherein a plurality of second clamping fixtures 420 and third driving cylinders 421 are distributed on the second clamping fixture seat 419. In operation, the driving motor 406 drives the second chassis to move left and right along the transverse guide rail 403, and the second driving cylinder drives the fourth slider 418 to move back and forth along the second longitudinal guide rail 417, so as to drive the second clamp holder 419 to move back and forth to facilitate material taking and feeding. In this embodiment, the third driving cylinder 421 is used for driving the second clamping tool 420 to perform opening and clamping operations to facilitate clamping and placing the three-leg inductor core 600.

The material placing mechanism 100 is disposed on the left side of the material feeding and taking mechanism, and is used for dividing the three-leg inductance core 600 into directions and pushing the three-leg inductance core into the first clamping tools 414 one by one. The material placing mechanism 100 comprises a bracket, a vibrating disc 101, a blanking guide rail 102, a support column 103 and a feeding assembly arranged on the support column 103, wherein the vibrating disc 101 is controlled by photoelectricity, and the vibrating disc 101 is used for dividing the three-leg inductance core 600 into directions and pushing the three-leg inductance core into the blanking guide rail 102 one by one. The feeding assembly comprises a guide groove 104 which is arranged on the support column 103 and is I-shaped, a pushing device 106 which pushes the three-leg inductance core 600 into the first clamping fixture assembly one by one, and a flattening cylinder 107 which has a flattening effect on the three-leg inductance core 600 pushed into the first clamping fixture assembly. The three-leg inductor magnetic cores 600 move along the blanking guide rail 102 and enter the feeding assembly, namely, the three-leg inductor magnetic cores 600 enter the guide groove 104 from the blanking guide rail 102, the guide groove 104 is vertically arranged, so that the three-leg inductor magnetic cores 600 freely fall down and stay on the pushing device 106, the pushing device 106 moves left and right, the three-leg inductor magnetic cores 600 freely fall into the first clamping tool 414 one by one, and then the three-leg inductor magnetic cores 600 are flattened and compressed by the flattening cylinder 107. According to the invention, feeding, swinging and loading operations are automatically completed through the vibrating plate 101, the blanking guide rail 102 and the loading assembly, and the whole feeding, swinging and loading processes are fully automatically completed, so that the technical problem of high labor intensity caused by traditional manual loading is solved, time and labor are saved, labor is greatly saved, the production efficiency is improved, and the production cost is reduced.

In this embodiment, the positioning sheet 105 is disposed in the guide slot 104, the three-leg inductor cores 600 falling into the guide slot 104 are uniformly separated on the left side of the positioning sheet 105 under the positioning action of the positioning sheet 105, and the remaining two short legs are located on the right side of the positioning sheet 105, so that the direction is accurately separated, the structure is simple, the positioning effect is good, the material separating accuracy is high, and the practicability is strong.

The winding mechanism 200 comprises a frame 201, a wire frame 202 arranged at the rear end of the frame 201, a main shaft device 203, a residual wire clamp device 204 and a winding device 205 which are arranged on the frame 201. In this embodiment, the wire rack 202 is used for supplying wires to the wire winding device 205. The main shaft device 203 is arranged on the frame 201, the residual wire clamp device 204 is arranged on the main shaft device 203, the winding device 205 is arranged on the residual wire clamp device 204, the winding device 205 can move along the up-down, left-right and front-back directions of the frame 201, and the winding device 205 comprises a wire arrangement frame 206. The control device controls the main shaft device 203, the residual wire clamp device 204 and the winding device 205 to cooperate to act, wire arrangement is automatic, high-speed winding is performed, and the winding device is orderly placed, so that defective products such as uneven winding turns, uneven winding packages, fingernails, irregular operation and the like caused by manual manufacturing can be effectively avoided, the quality of products is improved, the consistency of the quality is ensured, parameters are set on the first control panel 501, intelligent software in the control device automatically works according to the set requirements of the products after programming, the operation is convenient, the unattended operation is not needed, the automation degree is effectively improved, the manpower is further saved, the winding efficiency is high, and the winding quality is good.

The wire winding soldering machine of the invention also comprises a soldering mechanism 300, wherein the soldering mechanism 300 is arranged on the right side of the wire winding mechanism 200. The soldering mechanism 300 comprises a base 301, a housing 302 arranged on the base 301, a lifting moving device 303 arranged on the base 301, a distance shrinking clamp 304 arranged on the lifting moving device 303, a soldering flux box 305 arranged on the base 301, a soldering furnace 306, a recycling and conveying device 307 and a receiving box. The distance shrinking clamp 304 moves up and down and back and forth under the auxiliary action of the lifting moving device 303, so that the three-leg inductor magnetic core 600 is clamped from the second clamp tool 420, the three-leg inductor magnetic core 600 is sent to the soldering flux box 305 for soldering flux dipping, the three-leg inductor magnetic core 600 is sent to the tin furnace 306 for tin dipping soldering, finally, after the tin soldering is finished, the three-leg inductor magnetic core 600 is sent to the recycling and conveying device 307, the recycling and conveying device 307 sends a finished product to the receiving box, the tin soldering and blanking are automatically finished, the tin soldering efficiency is high, and the product quality is stable.

In this embodiment, the wire-wound soldering machine further includes a shield 402 disposed on the workbench 401.

In this embodiment, the housing 302 is provided with an exhaust assembly 308.

When the wire-winding soldering machine works, the vibration disc 101 is used for distributing, the three-leg inductance magnetic cores 600 are distributed in a good direction and are pushed to the blanking guide rail 102 one by one, the guide groove 104 and the pushing device 106 are matched for working, the three-leg inductance magnetic cores 600 are dropped into the first clamping fixture 414 one by one, and then the three-leg inductance magnetic cores are flattened and pressed by the flattening cylinder 107; after the feeding is completed, the driving motor 406 drives the belt 404 to move, and the first clamping fixture assembly moves to the winding mechanism 200 along the transverse guide rail 403, and the first lifting assembly 411 and the first driving cylinder 412 move up and down and back and forth, so that the first clamping fixture seat 413 conveys the three-leg inductor magnetic core 600 clamped in the first clamping fixture 414 to the main shaft device 203, and the main shaft device 203, the residual wire clamp device 204 and the winding device 205 cooperate to act, and wire arrangement and winding are automatically performed; after winding, the second clamp assembly moves and clamps the three-pin inductor core 600 on the spindle device 203, the three-pin inductor core 600 is conveyed to the soldering tin mechanism 300, the three-pin inductor core 600 is clamped by the distance shrinking clamp 304, tin dipping operation is automatically completed, finally, the materials are discharged to the recycling and conveying device 307, the finished products are conveyed to the receiving box by the recycling and conveying device 307, the first clamp assembly and the second clamp assembly work synchronously, and the winding soldering tin machine works continuously in a circulating way.

In summary, the wire winding soldering machine of the invention automatically completes feeding, swinging and loading operations through the vibration disc 101, the blanking guide rail 102 and the loading assembly, and the whole processes of feeding, loading, winding, soldering and unloading are fully automatically completed, so that the technical problem that the traditional single machine operation is time-consuming and labor-consuming is solved, the wire winding operation and soldering fixation of the three-pin inductance magnetic core 600 are fully automatically completed, the automation degree is high, the labor intensity is low, the wire winding efficiency is high, the soldering effect is good, the production efficiency is greatly improved, the production cost is reduced, the consistency of the yield and quality of finished products is ensured, and the large-scale production of enterprises is facilitated.

The foregoing description is only of the preferred embodiments of the present invention and is not intended to limit the scope of the invention, and all equivalent structural changes made by the present invention and the accompanying drawings, or direct or indirect application in other related technical fields, are included in the scope of the present invention.

Claims (5)

1. The winding and soldering machine is characterized by comprising a material arranging mechanism, a winding mechanism, a soldering mechanism, a material feeding and taking mechanism and a control device, wherein the material arranging mechanism, the winding mechanism, the soldering mechanism and the material feeding and taking mechanism are connected with the control device, and the material feeding and taking mechanism comprises a workbench, a transverse guide rail arranged on the workbench, a first clamp assembly arranged on the transverse guide rail through a first sliding block and a second clamp assembly arranged on the transverse guide rail through a second sliding block; the material placing mechanism comprises a bracket, a vibrating disc, a blanking guide rail, a support and a material loading assembly arranged on the support; the winding mechanism comprises a frame, a wire frame, a main shaft device, a residual wire clamp device and a winding device, wherein the main shaft device, the residual wire clamp device and the winding device are arranged on the frame; the soldering tin mechanism comprises a base, an outer cover arranged on the base, a lifting moving device arranged on the base, a distance shrinking clamp arranged on the lifting moving device, a soldering flux box arranged on the base, a tin furnace, a recycling and conveying device and a receiving box; the feeding assembly comprises a guide groove which is arranged on the support column and is I-shaped, a positioning sheet which is arranged in the guide groove, a pushing device which pushes three-leg inductance magnetic cores into the first clamping fixture assembly one by one, and a flattening cylinder which has flattening effect on the three-leg inductance magnetic cores pushed into the first clamping fixture assembly; the feeding and taking mechanism further comprises a belt, a plurality of gears and a driving motor, wherein the belt drives the first sliding block and the second sliding block to move along the transverse guide rail; the first clamping jig assembly comprises a first bottom plate arranged on the first sliding block, a first longitudinal guide rail arranged on the first bottom plate, a first lifting assembly arranged on the first longitudinal guide rail through the third sliding block, a first driving cylinder for driving the third sliding block to move along the first longitudinal guide rail, and a first clamping jig seat arranged on the first lifting assembly, wherein a plurality of first clamping jigs are distributed on the first clamping jig seat; the second clamp jig assembly comprises a second bottom plate arranged on the second sliding block, a second longitudinal guide rail arranged on the second bottom plate, a second clamp jig seat arranged on the second longitudinal guide rail through the fourth sliding block, and a second driving cylinder for driving the fourth sliding block to move along the second longitudinal guide rail, wherein a plurality of second clamp jigs and third driving cylinders are distributed on the second clamp jig seat.

2. The wire-wound soldering machine according to claim 1, wherein the control device comprises a first control panel and a second control panel.

3. The wire-wound soldering machine according to claim 2, wherein the wire winding device moves in up and down, left and right, and front and rear directions of the frame, and the wire winding device comprises a wire arrangement frame.

4. A wire-wound soldering machine according to claim 3, further comprising a shield disposed on the table.

5. The wire-wound soldering machine of claim 4, wherein the housing is provided with a vent assembly.