CN221415280U - Multi-station soldering machine - Google Patents

Abstract

The utility model discloses a multi-station soldering machine, which comprises: frame, scaling powder atomizer, soldering tin spraying device, first actuating mechanism and second actuating mechanism, the top of frame is provided with scaling powder atomizer's scaling powder shower nozzle, and the internally mounted of frame has drive assembly, and soldering tin spraying device fixed mounting is in the inside of frame, and the top of frame has been seted up and has been used for tin liquid spun hole, and first actuating mechanism sets up in the top of scaling powder shower nozzle, and second actuating mechanism sets up in the top of soldering tin spraying shower nozzle. According to the utility model, the linear module, the first driving mechanism and the second driving mechanism are matched with the scaling powder spraying device and the tin spraying and soldering device, so that the scaling powder spraying operation and the tin spraying and soldering operation are not mutually interfered, and further the scaling powder spraying and the tin soldering operation can be synchronously carried out on the circuit board, and the processing efficiency is effectively improved.

Description

Multi-station soldering machine

Technical Field

The utility model relates to the technical field of soldering machines, in particular to a multi-station soldering machine.

Background

Selective wave soldering, also known as selective soldering, is a technique for soldering through holes in a PCB board insert. When the selective wave soldering is used for soldering, the soldering parameters of each soldering point can be precisely controlled, so that the method is commonly used for soldering multilayer PCB through holes with high soldering requirements and complex process, such as military electronics, spaceship electronics, automobile electronics, digital cameras, printers and the like.

However, the existing soldering machine cannot realize synchronous operation of spraying soldering flux and tin spraying soldering tin, and seriously reduces production efficiency.

Disclosure of utility model

The utility model aims to provide a multi-station soldering machine which can synchronously spray soldering flux and solder a circuit board, thereby effectively improving the processing efficiency and saving the energy consumption.

In order to achieve the above purpose, the main technical scheme adopted by the utility model comprises the following steps:

A multi-station solder machine, comprising:

the top of the rack is provided with a plurality of holes for spraying molten tin to realize soldering flux spraying or tin soldering tin spraying;

The soldering flux spraying device is provided with a soldering flux nozzle of the soldering flux spraying device on the frame and can spray soldering flux;

And the frame is provided with a tin spraying nozzle of the tin spraying device and can realize tin spraying flux.

Further, the frame is provided with a driving component for driving the soldering flux spraying device or the tin spraying device to move up and down, left and right and/or back and forth.

Still further, the drive assembly further comprises:

The first driving mechanism is used for driving the circuit board to move up and down, left and right and/or back and forth;

The second driving mechanism is used for driving the circuit board sprayed with the soldering flux to move up and down, left and right and/or back and forth;

And the circuit board clamp is respectively corresponding to the first driving mechanism and the second driving mechanism, and is arranged on the first driving mechanism or the second driving mechanism to clamp the circuit board.

Still further, the method further comprises:

The first driving mechanism is arranged above the soldering flux spray head, and the soldering flux spray head extends out of one hole for spraying tin liquid to spray soldering flux;

the second driving mechanism is arranged above the tin spraying and soldering spray head, and the tin spraying and soldering spray head stretches out from one hole for spraying tin liquid to spray tin.

Still further, the method further comprises:

The driving assembly comprises a linear module corresponding to the soldering flux spraying device or the tin spraying device, and the linear module is used for driving the soldering flux spraying device or the tin spraying device to move for spraying or soldering.

Still further, the circuit board fixture is located above the soldering flux spray head, and the linear module is used for driving the soldering flux spraying device to move up and down, left and right and/or back and forth to spray the fixed circuit board.

Still further, first actuating mechanism and second actuating mechanism are including the lifting unit who is used for the up-and-down motion respectively, lifting unit includes the riser, riser fixed mounting is in the inside of frame, sliding fit has the movable plate on the riser, the top fixed mounting of movable plate has the diaphragm, the bottom fixed mounting of riser has linear electric motor, thereby slip table on the linear electric motor with one side fixed connection drive movable plate of movable plate realizes going up and down.

Still further, the first driving mechanism and the second driving mechanism respectively comprise a front-back moving assembly, and a circuit board clamp for clamping the circuit board to realize front-back movement is arranged between the two front-back moving assemblies.

Still further, the back-and-forth movement subassembly includes two slide rails and first driving motor, two slide rail parallel arrangement is in the top of frame, two the one end of slide rail all sets up the top surface of diaphragm, two run through between the slide rail has the transfer line, the equal fixedly connected with supporting shoe in both ends of transfer line, the equal fixedly connected with first synchronous pulley in both ends of transfer line, the slide rail is kept away from the one end of first synchronous pulley is rotated through the fixed block and is connected with the second synchronous pulley, is located same first synchronous pulley with be connected through first synchronous belt drive between the second synchronous pulley, the output of first driving motor pass through drive assembly with the transfer line drive is connected, fixedly connected with first splint on the first synchronous belt, the bottom fixedly connected with sliding block of first splint, the sliding block slides and sets up on the slide rail, two fixedly connected with between the sliding block circuit board anchor clamps.

Still further, the transmission assembly includes third synchronous pulley and fourth synchronous pulley, third synchronous pulley fixed connection is in the pivot of first driving motor, the fixed cover of fourth synchronous pulley is established on the transfer line, third synchronous pulley with pass through the transmission of second synchronous belt between the fourth synchronous pulley and be connected.

Still further, the scaling powder spraying device is arranged on the sliding table of the linear module.

Still further, the second actuating mechanism still includes the left and right movement subassembly, the left and right movement subassembly includes second driving motor, fifth synchronous pulley and second splint, second driving motor fixed mounting is in the inside of frame, fifth synchronous pulley rotates and installs one side inner wall of frame, fixed cover is equipped with sixth synchronous pulley in the pivot of second driving motor, sixth synchronous pulley with pass through third synchronous belt drive connection between the fifth synchronous pulley, second splint fixation clamp is in on the third synchronous belt, thereby one side of second splint with riser fixed connection on the second actuating mechanism drives second actuating mechanism and realizes controlling the removal.

Furthermore, two parallel guide rails are fixedly arranged on one side of the frame, the two guide rails are distributed up and down, the upper end and the bottom of one side of the vertical plate on the first driving mechanism are fixedly connected with limit sliding blocks, and the two limit sliding blocks are respectively and slidably limited on the guide rails matched with the limit sliding blocks.

Furthermore, the soldering flux spray head or the tin spraying spray head is in a static state, and the driving assembly drives the circuit board to move on the circuit board clamp to finish the work of spraying soldering flux or tin spraying tin.

Further, the circuit board is fixed on the circuit board clamp and is in a static state, and the soldering flux spray head or the tin spraying soldering spray head is driven by a driving assembly arranged on the frame to finish the soldering flux spraying work.

Still further, the drive assembly still includes multidirectional motion mechanism, multidirectional motion mechanism includes the bottom plate of fixed mounting in the frame inside, the Y axle direction of motion electric slipway of fixed mounting on bottom plate upper portion, and the X axle direction of motion electric slipway of fixed mounting on Y axle direction of motion electric slipway sliding part, Y axle direction of motion electric slipway is used for driving the scaling powder shower nozzle back and forth movement, X axle direction of motion electric slipway is used for driving the scaling powder shower nozzle to control the motion, accomplish the circuit board on the circuit board anchor clamps and spout scaling powder work.

The utility model has at least the following beneficial effects:

According to the utility model, the linear module, the first driving mechanism and the second driving mechanism are matched with the scaling powder spraying device and the tin spraying and soldering device, so that the scaling powder spraying operation and the tin spraying and soldering operation are not mutually interfered, and further the scaling powder spraying and the tin soldering operation can be synchronously carried out on the circuit board, and the processing efficiency is effectively improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description serve to explain the application and do not constitute a limitation on the application. In the drawings:

FIG. 1 is a schematic diagram of a multi-station soldering machine in embodiment 1 of the present utility model;

FIG. 2 is a schematic view of a part of a multi-station soldering machine according to embodiment 1 of the present utility model;

FIG. 3 is a schematic diagram of a part of a multi-station soldering machine in embodiment 1 of the present utility model;

fig. 4 is a schematic diagram of a part of a multi-station soldering machine in embodiment 1 of the present utility model;

FIG. 5 is a schematic diagram of a multi-station soldering machine in embodiment 2 of the present utility model;

FIG. 6 is a schematic diagram of a multi-station soldering machine in embodiment 3 of the present utility model;

FIG. 7 is a schematic view showing a partial structure of a multi-station soldering machine in accordance with an embodiment 3 of the present utility model;

Fig. 8 is a schematic diagram showing a partial structure of a multi-station soldering machine in embodiment 3 of the present utility model.

Reference numerals illustrate:

1. A frame; 101. a bar-shaped hole; 102. a hood; 2. a flux head; 3. a tin spraying and soldering nozzle; 4. a first driving mechanism; 401. a linear motor; 402. a vertical plate; 403. a moving plate; 404. a cross plate; 405. a slide rail; 406. a first driving motor; 407. a support block; 408. a transmission rod; 409. a first synchronous pulley; 410. a second synchronous pulley; 411. a first synchronization belt; 412. a first clamping plate; 413. a circuit board clamp; 414. a limit sliding block; 5. a linear module; 6. a second driving mechanism; 7. a guide rail; 8. a second driving motor; 9. a second clamping plate; 10. a third timing belt; 11. a fifth synchronous pulley; 31. a through groove; 32. a multidirectional movement mechanism; 321. a bottom plate; 322. y-axis movement direction electric sliding table; 323. x-axis movement direction electric sliding table.

Detailed Description

The following detailed description of embodiments of the present application will be given with reference to the accompanying drawings and examples, by which the implementation process of how the present application can be applied to solve the technical problems and achieve the technical effects can be fully understood and implemented.

Example 1

Referring to fig. 1 to 4, the present embodiment provides a multi-station soldering machine, which is composed of a frame 1, a soldering flux spraying device, a soldering tin spraying device, a driving assembly, a first driving mechanism 4 and a second driving mechanism 6.

The top of frame 1 has seted up bar hole 101, and scaling powder atomizer's scaling powder shower nozzle 2 stretches out in the bar hole 101 for drive scaling powder atomizer along bar hole 101 length direction reciprocating motion's drive assembly includes sharp module 5, and scaling powder atomizer fixed mounting is on the slip table of sharp module 5, and sharp module 5 fixed mounting is in the inside of frame 1, moves about through the slip table on the control sharp module 5, and then can drive scaling powder atomizer and carry out the side-to-side movement realization scaling powder.

The soldering tin spraying device is fixedly arranged in the frame 1, a hole for spraying tin liquid is formed in the top of the frame 1, so that in order to adapt to the size of most circuit boards on the current world, the soldering tin spraying operation and the soldering flux spraying operation can be simultaneously carried out without mutual interference, the distance between the soldering flux spray head 2 on the soldering flux spraying device and the soldering tin spraying spray head 3 on the soldering tin spraying device is not lower than 450mm, and if the soldering tin spraying device is used for circuit boards with small specification and size, the distance between the soldering flux spray head 2 and the soldering tin spraying spray head 3 can also be adaptively reduced.

The first driving mechanism 4 and the second driving mechanism 6 comprise a lifting assembly and a front-back moving assembly, the lifting assembly comprises a vertical plate 402, a moving plate 403 is inserted on the vertical plate 402 in a sliding mode, a linear motor 401 is fixedly arranged at the bottom of the vertical plate 402, a sliding table on the linear motor 401 is fixedly connected with one side of the moving plate 403, a transverse plate 404 is fixedly arranged at the top of the moving plate 403, the vertical plate 402 on the first driving mechanism 4 is fixedly arranged in the frame 1, and when the movable plate 403 is driven to move up and down by controlling the sliding table on the linear motor 401.

The front-back moving assembly comprises two sliding rails 405 and a first driving motor 406, the two sliding rails 405 are arranged above the frame 1 in parallel, the tops of the transverse plates 404 are all fixed at one ends of the two sliding rails 405, supporting blocks 407 are fixedly connected to one ends of the two sliding rails 405, a transmission rod 408 is rotatably connected between the two supporting blocks 407, first synchronous pulleys 409 are fixedly connected to two ends of the transmission rod 408, one ends of the sliding rails 405, far away from the first synchronous pulleys 409, are fixedly connected with second synchronous pulleys 410 through fixing blocks, the first synchronous pulleys 409 and the second synchronous pulleys 410 on the same sliding rail 405 are in transmission connection through first synchronous belts 411, the output ends of the first driving motor 406 are in transmission connection with the transmission rods 408 through the transmission assembly, the transmission assembly comprises third synchronous pulleys and fourth synchronous pulleys, the third synchronous pulleys are fixedly connected to the rotating shafts of the first driving motor 406, the fourth synchronous pulleys are fixedly sleeved on the transmission rods 408, the first synchronous pulleys are fixedly connected with first synchronous pulleys 412 through second synchronous belts, the first synchronous pulleys 412 are fixedly connected to the first synchronous pulleys 411 through the fixing blocks, the first synchronous pulleys 412 are connected to the first synchronous pulleys 412 through the first synchronous pulleys, the first synchronous pulleys 412 are in the reverse rotation clamps are connected to the first synchronous pulleys, the first synchronous pulleys are in the reverse rotation shafts or the reverse rotation clamps are connected to the first synchronous pulleys through the first synchronous pulleys 411 through the first synchronous pulleys 413, and the first synchronous pulleys are in the reverse rotation clamps or the reverse rotation shafts are connected to the first synchronous pulleys through the first synchronous pulleys 411 through the first synchronous pulleys and the first synchronous pulleys 411.

The first driving mechanism 4 further comprises a left-right moving assembly, the left-right moving assembly comprises a second driving motor 8, a fifth synchronous pulley 11 and a second clamping plate 9, the second driving motor 8 is fixedly installed inside the frame 1, the fifth synchronous pulley 11 is rotatably installed on the inner wall of one side of the frame 1, a sixth synchronous pulley is fixedly sleeved on the rotating shaft of the second driving motor 8, the sixth synchronous pulley is in transmission connection with the fifth synchronous pulley 11 through a third synchronous belt 10, the second clamping plate 9 is fixedly clamped on the third synchronous belt 10, one side of the second clamping plate 9 is fixedly connected with a vertical plate 402 on the first driving mechanism 4, the second clamping plate 9 can be driven to move left and right through controlling the rotating shaft of the second driving motor 8, a circuit board clamp 413 in the first driving mechanism 4 can be driven to move left and right, two parallel guide rails 7 are fixedly installed on one side of the frame 1 and are distributed up and down, one side of the vertical plate 402 and the bottom 414 of the first driving mechanism 4 are fixedly connected with two guide rails 414 on the upper side of the vertical plate, the two guide rails 414 are fixedly connected with the lower side of the vertical plate 414 and the lower side of the vertical plate are located on the limit slide block 7, and the limit block is arranged on the limit block 402.

Wherein, the top of frame 1 is provided with the aircraft bonnet 102, and one side of aircraft bonnet 102 is provided with the door plant.

The embodiment also provides another implementation manner, and the second driving mechanism 6 of the embodiment is used for driving the circuit board to move up and down, left and right, and back and forth;

The circuit board clamping device is arranged on the second driving mechanism 6, and the second driving mechanism 6 drives the circuit board to move up and down, left and right or back and forth; the first driving mechanism 4 of the present embodiment is used for driving the circuit board sprayed with the soldering flux to move up and down, left and right or back and forth, and the first driving mechanism 4 is disposed above the tin spraying nozzle 3 to spray tin.

The embodiment also provides another implementation manner, and further includes a circuit board fixture, where the circuit board fixture is disposed above the soldering flux spray head 2, the circuit board fixture is fixedly installed on the frame 1, the circuit board is fixed on the circuit board fixture, and the linear module 5 is used to drive the soldering flux spraying device to move up and down, left and right, or back and forth to spray the fixed circuit board.

The embodiment also provides another implementation mode, the linear module of the embodiment can realize front and back, left and right or up and down movement, so that the soldering flux spray head 2 can be driven to realize front and back, left and right or up and down movement according to the requirement, and in this case, the circuit board can be directly fixed on the frame 1 to realize soldering flux spraying operation; likewise, the second driving assembly 6 can also move back and forth, left and right or up and down, so that the circuit board can be driven to move back and forth, left and right or up and down as required, and in this case, the soldering flux spray head 2 can be directly fixed on the frame 1 to realize the soldering flux spraying operation.

In order to facilitate understanding of the above technical solutions of the present utility model, the following describes in detail the working principle or operation manner of the present utility model in the actual process.

Example 2

Referring to fig. 5, the present embodiment provides a multi-station soldering machine, which is different from embodiment 1 in that: the soldering flux spray head 2 is in a fixed state, and the first driving mechanism 4 and the second driving mechanism 6 move towards a single direction to drive the circuit board to move on the circuit board clamp so as to respectively finish the soldering flux spraying and tin soldering tin spraying work.

Example 3

Referring to fig. 6-8, the present embodiment provides a multi-station soldering machine, which is different from embodiment 1 in that: the soldering flux spray head 2 is mounted on the frame 1 by adopting a multidirectional movement mechanism 22, a through groove 21 for the movement of the soldering flux spray head 2 is reserved on the top wall of the frame 1, the soldering flux spray head 2 is positioned in the through groove 21, the multidirectional movement mechanism 22 comprises a bottom plate 221 fixedly mounted in the frame 1, a Y-axis movement direction electric sliding table 222 fixedly mounted on the upper part of the bottom plate 221 and an X-axis movement direction electric sliding table 223 fixedly mounted on the sliding part of the Y-axis movement direction electric sliding table 222, the Y-axis movement direction electric sliding table 222 is used for driving the soldering flux spray head 2 to move back and forth, the X-axis movement direction electric sliding table 223 is used for driving the soldering flux spray head 2 to move left and right, and soldering flux spraying operation on a circuit board clamp is completed.

Working principle: firstly, placing a circuit board into a circuit board clamp 413 on a first driving mechanism 4, controlling the first driving mechanism 4 to drive the circuit board clamp 413 to move forwards and backwards, and simultaneously, driving a soldering flux spraying device to move left and right by a linear module 5, so as to finish soldering flux spraying operation of the circuit board;

And taking the circuit board sprayed with the soldering flux off the circuit board clamp 413 in the first driving mechanism 4, simultaneously placing another circuit board into the circuit board clamp 413 in the first driving mechanism 4 to spray the soldering flux of the next round of circuit board, placing the circuit board sprayed with the soldering flux into the circuit board clamp 413 'on the second driving mechanism 6, controlling the second driving mechanism 6 to drive the circuit board clamp 413' to move back and forth and left and right to finish the tin spraying operation of the circuit board, taking the circuit board sprayed with the tin from the circuit board clamp 413', and placing the circuit board sprayed with the soldering flux on the first driving mechanism 4 into the circuit board clamp 413' on the second driving mechanism 6 to perform the tin spraying operation of the next round, so that the circulation operation is realized.

While the foregoing description illustrates and describes the preferred embodiments of the present utility model, it is to be understood that the utility model is not limited to the forms disclosed herein, but is not to be construed as limited to other embodiments, and is capable of numerous other combinations, modifications and environments and is capable of changes or modifications within the scope of the inventive concept, either as a result of the foregoing teachings or as a result of the knowledge or skills of the relevant art. And that modifications and variations which do not depart from the spirit and scope of the utility model are intended to be within the scope of the appended claims.

Claims (16)

1. A multi-station solder machine, comprising:

The device comprises a frame (1), wherein a plurality of holes for spraying tin liquor are formed in the top of the frame (1) to realize soldering flux spraying or tin soldering tin spraying;

The soldering flux spraying device is characterized in that a soldering flux nozzle (2) of the soldering flux spraying device is arranged on the frame (1) and can spray soldering flux;

The tin spraying device is characterized in that a tin spraying nozzle (3) of the tin spraying device is arranged on the frame (1) and can realize tin spraying flux.

2. A multi-station solder machine according to claim 1, wherein: further comprises:

The frame (1) is provided with a driving component for driving the soldering flux spraying device or the tin spraying and soldering device to move up and down, left and right and/or back and forth.

3. A multi-station solder machine according to claim 2, wherein: the drive assembly further includes:

The first driving mechanism (4) is used for driving the circuit board to move up and down, left and right and/or back and forth;

the second driving mechanism (6), the second driving mechanism (6) is used for driving the circuit board sprayed with the scaling powder to move up and down, left and right and/or back and forth;

And the circuit board clamps respectively correspond to the first driving mechanism (4) and the second driving mechanism (6), and are arranged on the first driving mechanism (4) or the second driving mechanism (6) to clamp the circuit board.

4. A multi-station solder machine according to claim 3, wherein: further comprises:

The first driving mechanism (4) is arranged above the soldering flux spray head (2), and the soldering flux spray head (2) stretches out from one hole for spraying tin liquid to spray soldering flux;

The second driving mechanism (6) is arranged above the tin spraying and soldering spray head (3), and the tin spraying and soldering spray head (3) stretches out from one hole for spraying tin liquid to spray tin.

5. The multi-station soldering machine according to claim 4, wherein: further comprises:

the driving assembly comprises a linear module (5) corresponding to the soldering flux spraying device or the tin spraying device, and the linear module (5) is used for driving the soldering flux spraying device or the tin spraying device to move for spraying or soldering.

6. The multi-station soldering machine according to claim 5, wherein: the circuit board fixture is located above the soldering flux spray head (2), and the linear module (5) is used for driving the soldering flux spraying device to move up and down, left and right and/or back and forth to spray the fixed circuit board.

7. The multi-station soldering machine according to claim 6, wherein: the lifting mechanism comprises a lifting assembly used for moving up and down, the lifting assembly comprises a vertical plate (402), the vertical plate (402) is fixedly installed inside the frame (1), a movable plate (403) is slidably matched with the vertical plate (402), a transverse plate (404) is fixedly installed at the top of the movable plate (403), a linear motor (401) is fixedly installed at the bottom of the vertical plate (402), and a sliding table on the linear motor (401) is fixedly connected with one side of the movable plate (403) to drive the movable plate (403) to achieve lifting.

8. The multi-station soldering machine according to claim 7, wherein: the first driving mechanism (4) and the second driving mechanism (6) both comprise a front-back moving assembly, and a circuit board clamp (413) for clamping a circuit board to realize front-back movement is arranged between the two front-back moving assemblies.

9. The multi-station soldering machine according to claim 8, wherein: the back-and-forth movement assembly comprises two sliding rails (405) and a first driving motor (406), wherein the two sliding rails (405) are arranged in parallel above the frame (1), one ends of the two sliding rails (405) are all arranged on the top surface of the transverse plate (404), a transmission rod (408) penetrates through the two sliding rails, two ends of the transmission rod (408) are fixedly connected with supporting blocks (407), two ends of the transmission rod (408) are fixedly connected with first synchronous pulleys (409), one ends of the sliding rails (405) far away from the first synchronous pulleys (409) are rotatably connected with second synchronous pulleys (410) through fixing blocks, the first synchronous pulleys (409) and the second synchronous pulleys (410) which are arranged on the same sliding rail (405) are in transmission connection through first synchronous belts (411), output ends of the first driving motor (406) are in transmission connection with the transmission rod (408) through the transmission assembly, the first synchronous belts (411) are fixedly connected with first clamping plates (412), and the first clamping plates (412) are fixedly connected with the bottom of the sliding blocks (413) through the fixing blocks, and the sliding blocks are fixedly connected with the sliding blocks (413).

10. A multi-station solder machine according to claim 9, wherein: the transmission assembly comprises a third synchronous pulley and a fourth synchronous pulley, the third synchronous pulley is fixedly connected to a rotating shaft of the first driving motor (406), the fourth synchronous pulley is fixedly sleeved on the transmission rod (408), and the third synchronous pulley and the fourth synchronous pulley are in transmission connection through a second synchronous belt.

11. A multi-station solder machine according to claim 10, wherein: the soldering flux spraying device is arranged on the sliding table of the linear module (5).

12. A multi-station solder machine according to claim 11, wherein: the second driving mechanism (6) further comprises a left-right moving assembly, the left-right moving assembly comprises a second driving motor (8), a fifth synchronous pulley (11) and a second clamping plate (9), the second driving motor (8) is fixedly installed inside the frame (1), the fifth synchronous pulley (11) is rotatably installed on one side inner wall of the frame (1), a sixth synchronous pulley is fixedly sleeved on a rotating shaft of the second driving motor (8), the sixth synchronous pulley is in transmission connection with the fifth synchronous pulley (11) through a third synchronous belt (10), the second clamping plate (9) is fixedly clamped on the third synchronous belt (10), and one side of the second clamping plate (9) is fixedly connected with a vertical plate (402) on the second driving mechanism (6) so as to drive the second driving mechanism (6) to move left and right.

13. A multi-station solder machine according to claim 12, wherein: two parallel arrangement's guide rail (7) are fixed mounting in one side of frame (1), two guide rail (7) are upper and lower distribution, on second actuating mechanism (6) riser (402) one side upper end and bottom all fixedly connected with spacing slider (414), two spacing slider (414) slip respectively are restricted rather than matched with guide rail (7).

14. A multi-station solder machine according to claim 13, wherein: the soldering flux spray head (2) or the tin spraying and soldering spray head (3) is in a static state, and the driving assembly drives the circuit board to move on the circuit board clamp to finish the work of spraying soldering flux or tin spraying and soldering.

15. A multi-station solder machine according to claim 14, wherein: the circuit board is fixed on the circuit board clamp and is in a static state, and the soldering flux spray head (2) or the tin spraying and soldering spray head (3) is driven by a driving assembly arranged on the frame (1) to finish the soldering flux spraying work.

16. A multi-station solder machine according to claim 15, wherein: the driving assembly further comprises a multidirectional movement mechanism (22), the multidirectional movement mechanism (22) comprises a bottom plate (221) fixedly installed inside the frame (1), an electric Y-axis movement direction sliding table (222) fixedly installed on the upper portion of the bottom plate (221), and an electric X-axis movement direction sliding table (223) fixedly installed on the sliding part of the electric Y-axis movement direction sliding table (222), the electric Y-axis movement direction sliding table (222) is used for driving the soldering flux spray head (2) to move back and forth, the electric X-axis movement direction sliding table (223) is used for driving the soldering flux spray head (2) to move left and right, and soldering flux spraying operation on a circuit board on the circuit board clamp is completed.