CN219718665U - Thin copper processing equipment for depositing raw material insulating holes - Google Patents

Abstract

The utility model provides raw material insulation hole deposition thin copper processing equipment, which relates to the technical field of PCB board processing and comprises a copper deposition tank, wherein a plurality of copper deposition tanks are arranged in the copper deposition tank, one side of the copper deposition tank is provided with a gear through motor rotation, one end of each copper deposition tank is provided with a rack, each copper deposition tank is provided with a filtering mechanism, sundries generated in the copper deposition process can be collected through arranging a filtering box, after copper deposition is finished, the filtering box is taken out to separate the sundries from copper deposition liquid, the time required for cleaning the copper deposition tanks is shortened, the production progress is accelerated, the filtering box can be fixed through arranging a movable rod and a stop block, the installation and the disassembly of the filtering box are facilitated, the movable rod is fixed through arranging a threaded rod, and the stability of the stop block and the filtering box can be improved.

Description

Thin copper processing equipment for depositing raw material insulating holes

Technical Field

The utility model relates to the technical field of PCB processing, in particular to a thin copper processing device for depositing a raw material insulating hole.

Background

The Chinese name printed circuit board, also called printed circuit board, is an important electronic component, is a support body of the electronic component, is a carrier for electrically connecting the electronic component, is called a printed circuit board because the printed circuit board is manufactured by adopting an electronic printing technology, is one of important components in the electronic industry, is not conductive on the wall of a hole after drilling, and needs copper deposition and electroplating in an insulating hole to realize conduction between circuit layers, so that the hole is metalized, copper in the hole can be conducted, the copper deposition is to dip a board into copper deposition liquid to perform chemical reaction, so that a thin chemical copper layer is deposited on the whole printed circuit board, particularly the wall of the hole, and conventionally, a thin copper sheet is formed on the surface layer, and the copper deposition lays a foundation for the subsequent electroplating.

However, the existing copper precipitation tank is not provided with a sundry filtering structure, sundries can be deposited at the bottom of the copper precipitation tank in the copper precipitation process of the printed board, when copper precipitation liquid is replaced, the bottom of the copper precipitation tank needs to be cleaned for a long time, and the production progress is affected, so that improvement is made by the copper precipitation tank, and the thin copper processing equipment for depositing the raw material insulating holes is provided.

Disclosure of Invention

The utility model mainly aims to provide raw material insulation hole deposition thin copper processing equipment, which can effectively solve the problems that sundries are deposited at the bottom of a copper deposition groove in the copper deposition process of a printed board, and when copper deposition liquid is replaced, the bottom of the copper deposition groove needs to be cleaned for a long time, so that the production progress is influenced.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

the utility model provides a thin copper processing equipment of raw materials insulating hole deposit, includes the heavy copper pond, install a plurality of heavy copper grooves in the heavy copper pond, heavy copper pond one side is provided with the gear through motor rotation, every heavy copper groove one end all is provided with the rack, every all be provided with filtering mechanism on the heavy copper groove.

Preferably, a plurality of first limit grooves and second limit grooves are respectively formed in two sides of the copper precipitation tank, and limit rods are fixedly connected in the first limit grooves and the second limit grooves respectively.

Preferably, each copper precipitation groove is fixedly connected with a first limiting block and a second limiting block at two ends respectively, the first limiting block and the second limiting block are respectively in sliding connection with the inner walls of the first limiting groove and the second limiting groove, and the first limiting block and the second limiting block are both sleeved on the limiting rod in a sliding manner.

Preferably, each second limiting block is fixedly connected with the rack, a connecting block is fixedly connected to one side of the copper precipitation tank, and the motor is fixedly installed on one side of the copper precipitation tank.

Preferably, the output end of the motor is fixedly connected with a rotating shaft, one end of the rotating shaft, far away from the motor, is rotationally connected with the connecting block, a plurality of gears are fixedly sleeved on the rotating shaft, and each gear is correspondingly meshed with the rack.

Preferably, each copper precipitation groove is provided with a mounting groove at both ends, each mounting groove is internally and rotatably connected with a movable rod, each movable rod top is fixedly connected with an adjusting block, and each movable rod lower end is fixedly connected with a stop block.

Preferably, the filtering mechanism comprises a plurality of filtering boxes, the filtering boxes are respectively arranged at the bottoms of the copper precipitation tanks, each filtering box is fixedly connected with a mounting block at two ends, each mounting block is in sliding connection with the inner wall of each mounting tank, through holes corresponding to the movable rods and the corresponding through holes of the corresponding check blocks are formed in the mounting blocks, the movable rods penetrate through the through holes, and the lower surfaces of the check blocks are propped against the upper surfaces of the mounting blocks.

Preferably, each copper precipitation groove upper surface both ends all fixedly connected with first fixed block and second fixed block, first fixed block and second fixed block are located the mounting groove both sides respectively, run through in first fixed block, movable rod and the second fixed block and be provided with the threaded rod, threaded rod one end fixedly connected with knob.

Compared with the prior art, the utility model has the following beneficial effects:

(1) Through setting up the rose box and can collect the debris that copper in-process produced, after copper precipitation, take out the rose box and can separate debris and copper precipitation liquid, shorten the time that the clearance copper precipitation groove required for production progress.

(2) Through setting up movable rod and dog, can fix the rose box, the installation and the dismantlement of rose box of being convenient for are fixed the movable rod through setting up the screw thread pole, can improve the stability of dog and rose box.

Drawings

FIG. 1 is a perspective view of the overall structure of the present utility model;

FIG. 2 is a schematic top view of the present utility model;

FIG. 3 is a perspective view of the cross-sectional structure of FIG. 2 A-A in accordance with the present utility model;

FIG. 4 is a perspective view of the cross-sectional structure B-B of FIG. 2 in accordance with the present utility model;

FIG. 5 is an enlarged view of the structure of FIG. 3C in accordance with the present utility model;

fig. 6 is an enlarged view of the structure of fig. 3D according to the present utility model.

In the figure: 1. a copper precipitation pool; 101. a first limit groove; 102. the second limit groove; 103. a limit rod; 2. a copper precipitation tank; 201. a first limiting block; 202. a second limiting block; 203. a rack; 204. a movable rod; 205. an adjusting block; 206. a mounting groove; 207. a stop block; 3. a motor; 301. a rotating shaft; 302. a gear; 303. a connecting block; 4. a filtering mechanism; 401. a filter box; 402. a first fixed block; 403. a second fixed block; 404. a knob; 405. a threaded rod; 406. a mounting block; 407. and a through hole.

Detailed Description

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

As shown in fig. 1, the embodiment of the utility model provides a processing device for depositing thin copper in a raw material insulating hole, which comprises a copper deposition tank 1, wherein a plurality of copper deposition tanks 2 are installed in the copper deposition tank 1, one side of the copper deposition tank 1 is rotatably provided with a gear 302 through a motor 3, one end of each copper deposition tank 2 is provided with a rack 203, and each copper deposition tank 2 is provided with a filtering mechanism 4.

As shown in fig. 1-6, in another embodiment of the present utility model, a plurality of first limiting grooves 101 and second limiting grooves 102 are respectively provided at two sides of a copper precipitation tank 1, a limiting rod 103 is fixedly connected in each of the first limiting grooves 101 and the second limiting grooves 102, a first limiting block 201 and a second limiting block 202 are respectively fixedly connected at two ends of each copper precipitation tank 2, the first limiting block 201 and the second limiting block 202 are respectively slidably connected with inner walls of the first limiting grooves 101 and the second limiting grooves 102, the first limiting block 201 and the second limiting block 202 are respectively slidably sleeved on the limiting rod 103, each second limiting block 202 is fixedly connected with a rack 203, a connecting block 303 is fixedly connected at one side of the copper precipitation tank 1, a motor 3 is fixedly mounted at one side of the copper precipitation tank 1, an output end of the motor 3 is fixedly connected with a rotating shaft 301, one end of the rotating shaft 301, which is far away from the motor 3, is rotatably connected with the connecting block 303, a plurality of gears 302 are respectively fixedly sleeved on the rotating shaft 301, each gear 302 is correspondingly meshed with the rack 203, mounting grooves 206 are respectively provided at two ends of each copper tank 2, each mounting groove 206 is rotatably connected with a movable block 204, each movable block 204 is fixedly connected with a top end of each movable block 204, and each movable block 204 is fixedly connected with a movable block 207.

It can be understood that in the utility model, the first limiting groove 101, the second limiting groove 102 and the limiting rod 103 are used for limiting the first limiting block 201 and the second limiting block 202, so that the copper precipitation groove 2 is prevented from shaking in the working process, when the copper precipitation liquid is replaced, the rotating shaft 301 is driven to rotate by the starting motor 3, the gears 302 are driven to rotate by the rotating shaft 301, the gears 302 are in one-to-one correspondence with the racks 203, and the copper precipitation groove 2 is driven to move upwards by the meshed connection between the gears 302 and the racks 203, so that the copper precipitation groove 2 is conveniently taken out of the copper precipitation tank 1, and the copper precipitation liquid is conveniently replaced and the copper precipitation groove 2 is conveniently cleaned.

As shown in fig. 2-6, in another embodiment of the present utility model, the filtering mechanism 4 includes a plurality of filtering boxes 401, the plurality of filtering boxes 401 are respectively disposed at the bottom of the copper precipitation tank 2, two ends of each filtering box 401 are fixedly connected with a mounting block 406, the mounting block 406 is slidably connected with the inner wall of the mounting tank 206, a through hole 407 corresponding to the size of the movable rod 204 and the size of the stop block 207 is formed in the mounting block 406, the movable rod 204 penetrates through the through hole 407, the lower surface of the stop block 207 abuts against the upper surface of the mounting block 406, two ends of the upper surface of each copper precipitation tank 2 are fixedly connected with a first fixing block 402 and a second fixing block 403, the first fixing block 402 and the second fixing block 403 are respectively disposed at two sides of the mounting tank 206, threaded rods 405 are penetrated in the first fixing block 402, the movable rod 204 and the second fixing block 403, and one end of the threaded rods 405 is fixedly connected with a knob 404.

In this embodiment, through setting up rose box 401 and can collect the debris that copper in-process produced, after copper precipitation, take out rose box 401 and can separate debris and copper precipitation liquid, shorten the time that clearance copper precipitation tank 2 required for the production progress.

It should be noted that, before installing the filter box 401, the threaded rod 405 is in threaded connection with the second fixed block 403, the movable rod 204 is rotated to make the positions of the adjusting block 205 and the stop block 207 correspond to the positions of the through holes 407, so that the installation block 406 is conveniently sleeved on the movable rod 204, when the installation block 406 drives the filter box 401 to move to the bottom of the copper precipitation tank 2, the movable rod 204 is rotated to make the positions of the stop block 207 and the through holes 407 staggered, so that the lower surface of the stop block 207 abuts against the installation block 406, thereby fixing the filter box 401, improving the stability of the filter box 401, and finally, the threaded rod 405 penetrates through the first fixed block 402 and the movable rod 204 and then is in threaded connection with the second fixed block 403, so that the position of the stop block 207 is fixed.

The working principle of the raw material insulation hole deposition thin copper processing equipment is as follows:

when the filter box 401 is installed, the movable rod 204 is rotated to enable the adjusting block 205 and the check block 207 to correspond to the through holes 407, the installing block 406 is sleeved on the movable rod 204, when the installing block 406 drives the filter box 401 to move to the bottom of the copper precipitation tank 2, the movable rod 204 is rotated to enable the positions of the check block 207 and the through holes 407 to be staggered, the lower surface of the check block 207 abuts against the installing block 406 to enable the filter box 401 to be fixed, then the threaded rod 405 penetrates through the first fixed block 402 and the movable rod 204 and is in threaded connection with the second fixed block 403, the position of the check block 207 is fixed, sundries generated in the copper precipitation process are placed in the filter box 401, after copper precipitation is finished, the filter box 401 is taken out to separate sundries from copper precipitation liquid, the time required for cleaning the copper precipitation tank 2 is shortened, the production progress is accelerated, when the copper precipitation tank is replaced, the motor 3 is started to drive the rotating shaft 301 to rotate, the gears 302 are driven to rotate through the rotating shaft 301, and the copper precipitation tank 2 is driven to move upwards through the meshing connection between the gears 302 and the racks 203, so that the copper precipitation tank 2 is convenient to take out of the copper precipitation tank 1 from the copper precipitation tank and clean the copper precipitation tank 2.

It should be understood that the foregoing examples of the present utility model are merely illustrative of the present utility model and not limiting of the embodiments of the present utility model, and that various other changes and modifications can be made by those skilled in the art based on the above description, and it is not intended to be exhaustive of all of the embodiments, and all obvious changes and modifications that come within the scope of the utility model are defined by the following claims.

Claims (8)

1. The utility model provides a raw materials insulating hole deposit thin copper processing equipment, includes heavy copper pond (1), its characterized in that: install a plurality of copper sink grooves (2) in heavy copper pool (1), heavy copper pool (1) one side is provided with gear (302) through motor (3) rotation, every copper sink groove (2) one end all is provided with rack (203), every all be provided with filtering mechanism (4) on heavy copper pool (2).

2. A raw material insulating hole deposition thin copper processing apparatus according to claim 1, wherein: a plurality of first limit grooves (101) and second limit grooves (102) are respectively formed in two sides of the copper precipitation tank (1), and limit rods (103) are fixedly connected in the first limit grooves (101) and the second limit grooves (102) respectively.

3. A raw material insulating hole deposition thin copper processing apparatus according to claim 2, wherein: each copper precipitation groove (2) both ends are fixedly connected with first stopper (201) and second stopper (202) respectively, first stopper (201) and second stopper (202) respectively with first spacing groove (101) and second spacing groove (102) inner wall sliding connection, first stopper (201) and second stopper (202) all slip cap are established on gag lever post (103).

4. A raw material insulating hole deposition thin copper processing apparatus according to claim 3, wherein: each second limiting block (202) is fixedly connected with a rack (203), a connecting block (303) is fixedly connected to one side of the copper precipitation tank (1), and the motor (3) is fixedly installed on one side of the copper precipitation tank (1).

5. A raw material insulating hole deposition thin copper processing apparatus as claimed in claim 4, wherein: the output end fixedly connected with pivot (301) of motor (3), the one end that motor (3) was kept away from to pivot (301) is rotated with connecting block (303) and is connected, a plurality of gear (302) are all fixed the cover and are established on pivot (301), every gear (302) all correspond with rack (203) meshing.

6. A raw material insulating hole deposition thin copper processing apparatus as claimed in claim 5, wherein: every copper sink groove (2) both ends have all been seted up mounting groove (206), every all rotate in mounting groove (206) and be connected with movable rod (204), every all fixedly connected with regulating block (205) on movable rod (204) top, every all fixedly connected with dog (207) of movable rod (204) lower extreme.

7. The apparatus for processing a thin copper deposited in a raw material insulating hole according to claim 6, wherein: the filtering mechanism (4) comprises a plurality of filtering boxes (401), wherein the filtering boxes (401) are respectively arranged at the bottoms of the copper precipitation grooves (2), each filtering box (401) is fixedly connected with a mounting block (406) at two ends, each mounting block (406) is slidably connected with the inner wall of each mounting groove (206), through holes (407) corresponding to the movable rods (204) and the corresponding through holes (407) in the sizes of the corresponding check blocks (207) are formed in the corresponding mounting blocks (406), the movable rods (204) penetrate through the through holes (407), and the lower surfaces of the corresponding check blocks (207) are propped against the upper surfaces of the corresponding mounting blocks (406).

8. The apparatus for processing a thin copper deposited in a raw material insulating hole according to claim 7, wherein: every copper sink (2) upper surface both ends all fixedly connected with first fixed block (402) and second fixed block (403), first fixed block (402) and second fixed block (403) are located mounting groove (206) both sides respectively, run through in first fixed block (402), movable rod (204) and second fixed block (403) and be provided with threaded rod (405), threaded rod (405) one end fixedly connected with knob (404).