CN214079660U - Tin soldering device for inductance tin soldering machine - Google Patents

Abstract

A soldering tin device for inductance soldering tin machine, it includes: the three-axis movement mechanism base is positioned on the right side of the tin bath mounting base; the tin dipping column fixing plate is vertically arranged and extends forwards and backwards, and can be translationally arranged on the base of the three-axis movement mechanism through the three-axis movement mechanism; the tin dipping columns are vertically fixed on the tin dipping column fixing plate at intervals from front to back; the tin bath is characterized by comprising a tin bath, wherein tin bath protection plates are fixedly arranged on the periphery of the tin bath, the tin bath protection plates and the tin bath are fixed at the upper end of a tin bath bottom plate, the tin bath bottom plate is fixed at the upper end of a connecting plate through a plurality of tin bath seat plate supporting upright columns, the connecting plate is fixed at the upper end of a tin bath mounting base, the tin bath is fixedly connected to the tin bath at the upper end of the tin bath seat plate supporting upright columns, and the tin bath is horizontally arranged and extends forwards and backwards; and the first barrel type electric heater is fixedly arranged in the inner wall of the bottom side of the tin bath.

Description

Tin soldering device for inductance tin soldering machine

Technical Field

The utility model relates to an inductance production technical field, concretely relates to soldering tin device for inductance soldering tin machine.

Background

Solder is an integral part of inductor manufacture and is aimed at soldering a layer of tin to the inductor leads to wet the molten metal solder with the heated metal surface to form a new alloy layer for subsequent better connection to the PCB board. Among them, wave soldering and reflow soldering are the two most common soldering methods. When soldering an inductor, the soldering operation is generally performed manually or semi-automatically, and the soldering efficiency is low. One idea is that under the intermittent feeding action of a linear feeding device, an inductor coated with soldering flux in advance is sequentially heated to a preset temperature through four stations of preheating, soldering, drying and cooling, the soldering flux on the inductor is dried and then cooled.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide a soldering tin device for inductance soldering tin machine, make it can carry out automatic some tin to the inductance.

The utility model provides a technical scheme that technical problem adopted is: a soldering tin device for inductance soldering tin machine, it includes:

the three-axis movement mechanism base is positioned on the right side of the tin bath mounting base;

the tin dipping column fixing plate is vertically arranged and extends forwards and backwards, and can be translationally arranged on the base of the three-axis movement mechanism through the three-axis movement mechanism;

the tin dipping columns are vertically fixed on the tin dipping column fixing plate at intervals from front to back;

the tin bath is characterized by comprising a tin bath, wherein tin bath protection plates are fixedly arranged around the tin bath, the tin bath protection plates and the tin bath are fixed at the upper end of a tin bath bottom plate, the tin bath bottom plate is fixed at the upper end of a connecting plate through a plurality of tin bath seat plate supporting upright columns, the connecting plate is fixed at the upper end of a tin bath mounting base, the tin bath is fixedly connected at the upper ends of the tin bath seat plate supporting upright columns, and the tin bath is horizontally arranged and extends forwards and backwards;

and the first cylinder type electric heater is fixedly arranged in the inner wall of the bottom side of the tin bath.

Preferably, a plurality of vertical tin dipping column jacks are formed in the tin dipping column fixing plate at intervals, the upper end of each tin dipping column is expanded to form an anti-falling cap, and the lower end of each tin dipping column penetrates through the tin dipping column fixing plate downwards; it sets up one and dips in tin post side direction clamp plate to dip in on the tin post fixed plate with sliding around can, dip in and form a plurality of on the tin post side direction clamp plate towards one side back to press in the face of supporting of anticreep cap, dip in tin post side direction clamp plate through a plurality of screw locking in dip in on the tin post fixed plate.

The utility model discloses a soldering tin device for inductance soldering tin machine, it can conveniently dip in from the molten tin bath and get soldering tin and point on the inductance that preheats, and it once can operate a plurality of inductances, and degree of automation and efficiency are higher.

Drawings

Fig. 1 is a perspective view of an inductance soldering machine according to a preferred embodiment of the present invention;

fig. 2 is a perspective view of a linear feeder according to a preferred embodiment of the present invention;

fig. 3 is a top view of the linear feeder according to a preferred embodiment of the present invention;

fig. 4 is a right side view of a linear feeder according to a preferred embodiment of the present invention;

fig. 5 is a perspective view of a feeding jig according to a preferred embodiment of the present invention;

fig. 6 is a top view of the feed fixture in accordance with a preferred embodiment of the present invention;

fig. 7 is a bottom view of the feed fixture in accordance with a preferred embodiment of the present invention;

fig. 8 is a perspective view of a preheating device according to a preferred embodiment of the present invention;

fig. 9 is a plan view of a preheating device according to a preferred embodiment of the present invention;

fig. 10 is a perspective view of a soldering device according to a preferred embodiment of the present invention;

fig. 11 is a perspective view of a part of the structure of the drying device according to a preferred embodiment of the present invention;

fig. 12 is a left side view of a drying apparatus according to a preferred embodiment of the present invention;

fig. 13 is a perspective view of the drying apparatus according to another preferred embodiment of the present invention;

fig. 14 is a perspective view of a cooling device according to a preferred embodiment of the present invention;

fig. 15 is a left side view of a cooling device according to a preferred embodiment of the present invention;

description of reference numerals: 01. a frame; 02. installing a panel; 1. an inductance feeding clamp; 10. An inductance; 101. a long slider with a T-shaped section; 102. a horizontal plate; 103. cutting; 104. a first positioning jack; 105. a second positioning jack; 106. a transverse clamping groove; 107. inserting a strip block; 2. A linear feeding device; 201. a horizontal seat plate; 202. a working panel; 203. fixing the sliding block; 204. A longitudinal feed cylinder; 205. a longitudinal guide bar; 206. a horizontal sliding plate; 207. a longitudinal guide rail; 208. a transverse guide rail; 209. a side bar connecting block; 210. the cylinder is transversely abutted tightly; 211. a longitudinal connecting strip; 212. a side bar movable groove; 213. side pressing strips; 214. a feeding platen; 215. A feeding cylinder; 216. a vertical plectrum; 217. a second vertical cylinder; 218. a first vertical cylinder; 219. positioning a stop block; 220. positioning a bolt fixing block; 221. connecting blocks; 222. a horizontal material guide chute; 3. a preheating device; 301. a base; 302. a vertical plate; 303. a hot air pipe fixing seat; 304. a hot air pipe; 305. a flat-head air nozzle; 306. a first thermocouple; 307. an L-shaped connector; 308. a small hot air generator; 310. a hot air generator support column; 311. a pipe joint; 312. fixing the connecting plate; 313. a yielding groove; 314. a vertical base plate; 4. a soldering device; 401. a tin bath mounting base; 402. a connecting plate; 403. a tin bath soleplate; 404. a tin bath; 405. a first cartridge electric heater; 406. the tin bath seat plate supports the upright post; 407. a tin bath guard plate; 408. dipping tin columns; 409. fixing plates for dipping tin columns; 410. a lateral pressing plate of the tin dipping column; 411. A three-axis motion mechanism base; 412. a three-axis motion mechanism; 5. a drying device; 501. a baking oven base; 502. a drying oven transverse moving cylinder fixing seat; 503. a transverse cylinder of the oven; 504. a sliding bottom plate of the oven; 505. a T-shaped block; 506. a U-shaped connecting block; 507. a shield connecting post; 508. A thermocouple fixing seat; 509. a second thermocouple; 510. feeding a mould strip; 511. discharging the die strip; 512. A lateral heat insulation plate; 513. an inductive baking cavity; 515. transversely moving the sliding block; 516. transversely moving the guide rail; 517. a U-shaped shield; 518. a lateral abdication notch; 519. a total baking chamber; 520. a second cartridge electric heater; 6. a cooling device; 601. a cooling device base plate; 602. a support pillar; 603. a horizontal connecting plate; 604. cooling the air pipe; 605. a spray pipe rotary joint; 606. an air inlet joint; 607. An inclined heat conducting plate; 608. cooling the air pipe fixing end seat; 609. a abdication notch; 610. a horizontal support plate;

Detailed Description

The technical solution of the present invention will be clearly and completely described with reference to the accompanying drawings. In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The present invention will be further explained with reference to the accompanying drawings.

Please refer to fig. 1 to fig. 15.

The utility model discloses an inductance soldering tin machine, it includes frame 01, installation panel 02, sharp material feeding unit 2, preheating device 3, soldering tin device 4, drying device 5 and cooling device 6. Wherein, the mounting panel 02 is fixed on the top of the frame 01.

The linear feeding device 2 is used for horizontally and intermittently feeding materials from front to back. The linear feeding device 2 is arranged on the left side of the upper end of the installation panel 02. The linear feeder 2 has a horizontal chute 222 for sliding the induction feeding jig 1 back and forth. A plurality of inductors 10 to be soldered are arranged on the inductor feeding clamp 1 at intervals. The inductor 10 protrudes right on the inductor feed fixture 1. Four preheating, soldering, drying and cooling stations are arranged on the right side of the horizontal guide chute 222 at equal intervals.

The preheating device 3, the soldering device 4, the drying device 5 and the cooling device 6 are all arranged on the mounting panel 02 and are sequentially arranged at four stations on the right side of the horizontal guide chute 222 from front to back at intervals.

The utility model discloses an inductance soldering tin machine, it makes the inductance load on bar anchor clamps, from preceding back motion intermittently under sharp material feeding unit's effect, at stop motion's clearance, the inductance on preheating device on horizontal baffle box right side, the anchor clamps preheats in proper order on four workers, soldering tin, stoving and cooling operation. The utility model discloses an inductance soldering tin machine, it can carry out automatic soldering tin and cooling to the inductance that scribbles the scaling powder, and its degree of automation and production efficiency are higher.

The inductance feed jig 1 includes a long slider 101 having a T-shaped cross section extending in the front-rear direction. The horizontal guide chute 222 is a T-shaped chute. The upper end of the long slide block 101 with the T-shaped section is fixed with a horizontal plate 102. The horizontal plate 102 has a plurality of transverse slots 106 spaced apart from one another. A plurality of insertion bar blocks 107 are detachably provided in each lateral card slot 106. The right end of the insertion strip block 107 extends out of the transverse clamping groove 106 and protrudes towards the right to form a horizontal insertion strip 103. An inductor 10 is inserted on each cutting 103. The long slide block 101 with the T-shaped section is provided with a first positioning insertion hole 104 and a second positioning insertion hole 105 which are spaced from each other in the front-back direction.

The utility model discloses a sharp material feeding unit 2 includes still that work panel 202, horizontal bedplate 201, horizontal slide 206, location dial material subassembly, horizontal side pressure subassembly, material loading platen 214 and material loading cylinder 215 except including above-mentioned horizontal baffle box 222.

Wherein, the working panel 202 and the horizontal seat plate 201 are opposite and fixed up and down. The horizontal seat plate 201 is fixed to the mounting panel 02. A horizontal slide plate 206 is slidably disposed on the work panel 202 back and forth. The positioning and material shifting assembly is fixed on the right side of the lower end of the working panel 202 and is used for shifting the whole inductance feeding clamp 1 backwards by a certain distance (the distance between two adjacent stations). The feeding deck 214 is communicated with the horizontal material guide chute 222 in the left direction. The cylinder body is fixed to a feeding cylinder 215 at the front end of the horizontal material guide chute 222. The piston rod of the feeding cylinder 215 extends backward and is fixed with a vertical dial 216 for dialing the inductance feeding clamp 1 backward.

A longitudinally extending rail 207 is fixed to the upper end of the work panel 202. The horizontal sliding plate 206 is slidably disposed on the longitudinal rail 207. The right side of the working panel 202 is fixed and provided with a fixed slide block 203. The body of a longitudinal feed cylinder 204 is secured to the longitudinal feed cylinder 204. The piston rod of the longitudinal feed cylinder 204 extends rearward and is fixed to the connecting block 221. The connecting block 221 is fixedly connected with the horizontal sliding plate 206. Two longitudinal guide rods 205 are fixed on the connecting block 221 and spaced left and right. The longitudinal guide rod 205 is slidably inserted through the fixed slider 203.

The positioning and material stirring assembly comprises a second vertical air cylinder 217 and a first vertical air cylinder 218, wherein the cylinder bodies of the second vertical air cylinder 217 and the first vertical air cylinder 218 are fixed on the right side of the lower end of the working panel 202. The piston rod of the first vertical cylinder 218 is fixed upward to a positioning pin fixing block 220. Two positioning bolts spaced back and forth are fixed to the upper end of the positioning bolt fixing block 220. The second vertical cylinder 217 is located behind the first vertical cylinder 218 and its piston rod is fixed upward to a positioning stopper 219. The bottom of the horizontal material guiding groove 222 is provided with a through hole for the positioning bolt and the positioning stopper 219 to pass through upwards. The two positioning pins are arranged in one-to-one correspondence with the first positioning insertion holes 104 and the second positioning insertion holes 105. When the two positioning pins are inserted into the first positioning insertion hole 104 and the second positioning insertion hole 105 in a one-to-one correspondence manner, the positioning stopper 219 just abuts against the inductance feeding jig 1 from the rear side.

In other embodiments, it is preferable that the linear feeder 2 further comprises a lateral pressure assembly for pressing the induction feeding jig 1 toward the right. The lateral side press assembly includes lateral guide rails 208 at corresponding four stations. The cross rail 208 is fixed to the upper end of the horizontal sliding plate 206 so as to extend left and right. Each transverse guide rail 208 is provided with a side bar connecting block 209 in a sliding manner. And a side pressing strip 213 is fixed on the side pressing strip connecting block 209. The side bars 213 are disposed in side bar moving grooves 212 formed in the horizontal sliding plate 206. A longitudinal connecting bar 211 extending forward and backward is fixedly connected to the side bar connecting blocks 209, respectively. A cylinder block which laterally abuts against the cylinder 210 is fixed to the horizontal sliding plate 206. The piston rod of the transverse abutting cylinder 210 is arranged towards the right and fixed on the longitudinal connecting strip 211.

Specifically, the preheating device 3 of the present invention includes a hot-air duct fixing base 303, a first thermocouple 306, two hot-air ducts 304, two small-sized hot-air generators 308, and two sets of flat-head air nozzles 305.

Wherein, the hot-blast main fixing base 303 is arranged vertically. The upper and lower ends of the fixed sliding block 203 are respectively provided with a hot air connecting cavity. The two hot air pipes 304 are opposite to each other vertically and extend forwards and backwards. The left end and the right end of the hot air pipe 304 are communicated with one end of the hot air connecting cavity which corresponds up and down. The two small hot air generators 308 are opposite up and down and extend left and right. One end of the small hot air generator 308 is communicated with the other end of the corresponding hot air connecting cavity.

The other end of the small hot air generator 308 is connected to a first compressed air source via a pipe connection 311. An electric heating element (not shown) is provided within the compact hot wind generator 308. The two sets of flat air nozzles 305 are arranged in mirror image from top to bottom. Each set of the flat-head air nozzles 305 includes a plurality of the flat-head air nozzles 305 arranged in tandem. The upper and lower adjacent ends of the two sets of flat-head air nozzles 305 are provided with air outlets. The other end of each set of flat-head air nozzles 305 is fixed in communication with a corresponding hot air duct 304. The head of the first thermocouple 306 extends horizontally to the left between two sets of flat-head air nozzles 305.

The left end of the hot air pipe fixing base 303 corresponding to the upper and lower middle parts of the two groups of flat air nozzles 305 is provided with a receding groove 313 extending forward and backward. The rear end of the hot air pipe fixing seat 303 is fixed on a vertical plate 302 through a vertical backing plate 314. The vertical plate 302 is fixed on a base 301, and the base 301 is fixed on the mounting panel 02. An L-shaped connector 307 is fixed to the base 301. The first thermocouple 306 is fixed on the L-shaped connecting member 307 and its head penetrates the vertical plate 302 toward the left. The hot air generator supporting column 310 is fixedly connected with the hot air pipe fixing seat 303 through two fixing connection plates 312 which are spaced up and down.

The utility model discloses a soldering tin device 4 also can be called some tin devices, and it specifically includes molten tin bath installation base 401, triaxial moving mechanism base 411, dips in tin post fixed plate 409, molten tin bath 404, first cylinder electric heater 405 and a plurality of tin post 408 that dips in. The tin bath mounting base 401 and the three-axis movement mechanism base 411 are fixedly connected, and the three-axis movement mechanism base 411 is positioned on the right side of the tin bath mounting base 401. The tin bath mounting base 401 is fixed to the upper end of the mounting panel 02. The solder dipping post fixing plate 409 is vertically arranged and extends forwards and backwards. The dip column fixing plate is translatably disposed on the three-axis moving mechanism base 411 by the three-axis moving mechanism 412. The dipping posts 408 are vertically fixed to the dipping post fixing plate 409 at a front-to-back interval. The tin bath 404 is fixedly attached to the upper end of a tin bath base plate support post 406. The tin bath 404 is horizontally disposed and extends forward and rearward. The first barrel electric heater 405 is fixedly disposed in the inner wall of the bottom side of the tin bath 404 to heat the solder in the tin bath.

A plurality of vertical tin dipping column insertion holes are arranged on the tin dipping column fixing plate 409 at intervals. The upper end of the dipping tin column 408 is expanded to form a falling-off prevention cap. The lower end of the tin dipping column 408 penetrates through the tin dipping column fixing plate 409 downwards. A dipping column lateral pressing plate 410 is slidably arranged on the dipping column fixing plate 409 back and forth. The lateral pressing plate 410 of the solder dipping pillar is formed with a plurality of pressing surfaces which are pressed against the anti-drop cap towards the front and back sides. The dipping column lateral pressure plate 410 is locked on the dipping column fixing plate 409 through a plurality of screws.

A tin bath guard plate 407 is fixedly arranged around the tin bath 404. The tin bath protection plate 407 and the tin bath 404 are fixed to the upper end of a tin bath bottom plate 403. The tin bath base plate 403 is secured to the upper end of a connecting plate 402 by a plurality of tin bath base plate support posts 406. The connecting plate 402 is fixed to the upper end of the molten tin bath mounting base 401.

Specifically, the utility model discloses a drying device 5 includes oven base 501, oven sliding bottom plate 504, oven (unmarked), goes up mould strip 510, lower mould strip 511 and two second cartridge electric heater 520.

Wherein, the oven base 501 is horizontally arranged and fixed on the upper end of the installation panel 02. The oven sliding bottom plate 504 is arranged at the upper end of the oven base 501 in a manner of moving left and right. The oven is secured to an oven skid plate 504. The oven is formed by splicing and fixing a lateral heat-insulating plate 512, a bottom heat-insulating plate and other heat-insulating plates. A total oven cavity 519 is formed within the oven. The bottom of the bottom heat insulation plate is provided with a plurality of vent holes.

The upper mold strip 510 and the lower mold strip 511 are horizontally fixed and fixed in the oven from front to back, and the upper mold strip and the lower mold strip are vertically and oppositely fixed and spliced to form a plurality of inductance baking chambers 513 spaced from front to back. The back end of the inductive baking chamber 513 communicates with the general baking chamber 519. A lateral heat shield 512 is located to the left of the upper mold strip 510. The lateral heat-insulating plate 512 is provided with a plurality of lateral abdicating notches 518 which are opposite to the left and the right of the plurality of inductive baking chambers 513 one by one.

Two second cartridge heaters 520 are fixed in the upper and lower mold bars 510 and 511 in a one-to-one correspondence, thereby heating the upper and lower mold bars 510 and 511, respectively. The upper mold strip 510 and the lower mold strip 511 are made of a heat conductive material. The second thermocouple 509 is fixed on the oven sliding bottom plate 504, and the head portion thereof penetrates through the oven and then extends between the upper mold strip 510 and the lower mold strip 511.

A traversing guide rail 516 extending left and right is fixed on the oven base 501. A traversing slider 515 is fixed to the oven sliding floor 504. The traverse slide 515 is slidably disposed on the traverse guide 516. An oven transverse moving cylinder fixing seat 502 is fixed on the oven base 501. The body of an oven traversing cylinder 503 is fixed on the oven traversing cylinder fixing base 502. The piston rod of the oven-sliding cylinder 503 is fixed to the oven-sliding bottom plate 504 toward the left. A T-shaped block 505 is fixed on the upper end of the oven sliding bottom plate 504. The upper end of the T-shaped block 505 is fixed and the U-shaped connecting block 506. The U-shaped connecting block 506 is vertically fixed to the oven with both ends facing left.

The head of the second thermocouple 509 is slid horizontally through the U-shaped connection block 506 toward the left. A second thermocouple 509 is secured to the oven slide floor 504 by a thermocouple mount 508. The front and rear ends of the left side of the U-shaped connecting block 506 are fixedly connected with the lower end of a shield connecting column 507. A U-shaped shield 517 covers the oven and is locked with the upper end of the shield connecting column 507 by screws.

Specifically, the cooling device 6 of the present invention includes a cooling device seat plate 601, a horizontal support plate 610, two cooling air duct fixing end seats 608 and two cooling air ducts 604. Wherein, the cooling device seat plate 601 is horizontally arranged and fixed on the upper end of the installation panel 02. The horizontal support plate 610 is fixed above the cooling device seat plate 601 by a plurality of support columns 602, and a notch is formed in the middle of the left side of the horizontal support plate.

The two cooling air duct fixing end seats 608 are fixed on the upper sides of the left and right ends of the horizontal support plate 610 in a one-to-one correspondence manner. The cooling air duct fixing end seat 608 has a through cavity therein.

The two cooling air ducts 604 extend horizontally from front to back and are located right above the gap. One of the cooling air ducts 604 is located above the other cooling air duct 604. And is offset to the left from the other cooling air duct 604. A plurality of cold air holes are formed at the upper and lower opposite sides of the two cooling air pipes 604. The front and rear ends of the two cooling air ducts 604 are communicated with one end of the adapter cavity of the cooling air duct fixing end seat 608 on the front and rear corresponding sides. The front and rear ends of the two cooling air ducts 604 are connected to one end of the adapter cavity of the cooling air duct fixing end seat 608 on the front and rear sides through a nozzle rotary joint 605. The other ends of the two cooling air duct fixed end seats 608 are each in communication with a second compressed air source through an air inlet connector 606. The left end of the cooling air duct fixing end seat 608 is provided with a yielding notch 609 which is opposite to the middle of the two cooling air ducts 604 in the front-back direction.

The upper end of the horizontal support plate 610 is fixed to and in surface contact with the lower end of a horizontal connecting plate 603. The left edge of the horizontal connecting plate 603 is obliquely protruded upward to form an oblique heat conducting plate 607. The two cooling air ducts 604 approach the inclined heat-conducting plate 607 from the lower left. A plurality of radiating fins (not shown) are integrally connected to one side of the inclined heat conducting plate 607 away from the cooling air duct 604.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the principle of the present invention, and these improvements and decorations should also be regarded as the protection scope of the present invention.

Other parts not described in detail in the present invention belong to the prior art, and are not described herein again.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (2)

1. The utility model provides a soldering tin device for inductance soldering tin machine which characterized in that includes:

the tin bath mounting base (401) and the three-axis movement mechanism base (411) are fixedly connected, and the three-axis movement mechanism base (411) is positioned on the right side of the tin bath mounting base (401);

the tin dipping column fixing plate (409) is vertically arranged and extends forwards and backwards, and the tin dipping column fixing plate (409) can be translationally arranged on a three-axis movement mechanism base (411) through a three-axis movement mechanism (412);

a plurality of tin dipping columns (408) which are vertically fixed on the tin dipping column fixing plate (409) at intervals from front to back;

the tin bath mounting structure comprises a tin bath (404), wherein tin bath protection plates (407) are fixedly arranged on the periphery of the tin bath (404), the tin bath protection plates (407) and the tin bath (404) are fixed at the upper end of a tin bath base plate (403), the tin bath base plate (403) is fixed at the upper end of a connecting plate (402) through a plurality of tin bath base plate supporting columns (406), the connecting plate (402) is fixed at the upper end of a tin bath mounting base (401), the tin bath (404) is fixedly connected at the upper end of the tin bath base plate supporting columns (406), and the tin bath (404) is horizontally arranged and extends forwards and backwards;

and a first barrel type electric heater (405) fixedly arranged in the inner wall of the bottom side of the tin bath (404).

2. A tin soldering device for an inductance tin soldering machine according to claim 1, characterized in that a plurality of vertical tin dipping column jacks are arranged on the tin dipping column fixing plate (409) at intervals, the upper end of the tin dipping column (408) expands in diameter to form a falling-off prevention cap, and the lower end of the tin dipping column (408) penetrates through the tin dipping column fixing plate (409) downwards; it dips in tin post side direction clamp plate (410) to set up one around can going up on tin post fixed plate (409) with sliding, dip in to form on tin post side direction clamp plate (410) a plurality ofly towards the front and back one side support press in the face of supporting of anticreep cap, dip in tin post side direction clamp plate (410) through a plurality of screw locking in dip in on tin post fixed plate (409).

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