CN114698258A - Printed board mends brilliant device of reprocessing - Google Patents

Abstract

The invention belongs to the technical field of semiconductor processing equipment, and particularly relates to a printed board crystal repairing device, which comprises a frame and further comprises: the laser module is arranged on the rack; the film module is used for moving the blue film chip disc on which the chip is placed; the pin module is positioned below the blue film chip disc and used for impacting a chip placed on the blue film chip disc; the dispensing module is used for coating solder paste on the position of the printed board where the chip needs to be compensated; the suction nozzle module is used for sucking the chip on the blue film chip disc and placing the chip on the welding disc coated with the solder paste on the printed board; the pressing module is used for fixing the chip to be welded on the printed board; and the transfer module is used for moving the printed board to the station where the dispensing module, the suction nozzle module, the pressing module and the laser module are located. Compared with the prior art, the chip repairing and repairing device integrates chip repairing and welding processes to be completed on one device, so that the production flow is effectively reduced, the operation efficiency and the product yield are improved, and the occupied area is reduced.

Description

Printed board mends brilliant device of reprocessing

Technical Field

The invention relates to the technical field of semiconductor processing equipment, in particular to equipment for supplementing a chip to a vacancy on a printed board.

Background

In the production process of the circuit board, the phenomena of crystal leakage and crystal damage are inevitable, namely, a chip is not placed at a position on the printed board where the chip is required to be placed. At present, in order to solve the problem, a plurality of independent devices are generally needed to complete the process, so that the production flow is increased, the processes are more, the product yield and the efficiency are low, more space is needed for installing processing devices, and the cost is greatly increased.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention aims to provide a printed board crystal repairing device, which aims to solve the problems in the prior art.

In order to achieve the purpose, the invention adopts the technical scheme that: the utility model provides a printed circuit board benefit brilliant device of reprocessing, includes the frame, still includes:

the laser module is arranged on the rack;

the film module is arranged on the rack and used for moving the blue film chip tray on which the chip is placed;

the pin module is arranged on the rack, is positioned below the blue film chip disc and is used for impacting a chip placed on the blue film chip disc;

the dispensing module is arranged on the frame and used for coating solder paste on the position of the printed board where the chip needs to be compensated;

the suction nozzle module is arranged on the rack and used for sucking the chip on the blue film chip disc and placing the chip on a bonding pad coated with solder paste on the printed board;

the pressing module is arranged on the rack and used for fixing the chip to be welded on the printed board;

and the transfer module is arranged on the rack and used for moving the printed board to the station where the dispensing module, the suction nozzle module, the pressing module and the laser module are located, and finally, welding of the chip on the printed board is completed.

Preferably, the rack comprises a bearing platform and a gantry support, and the gantry support is fixedly arranged on the upper surface of the bearing platform; the laser module, the suction nozzle module, the dispensing module and the pressing module are fixedly arranged on the gantry support; the film module, the needle module and the transfer module are fixedly arranged on the upper surface of the bearing platform.

Preferably, a film module positioning camera assembly and a printed board positioning camera assembly which are positioned above the film module and the transfer module are respectively arranged on the gantry support; a coring sheet confirmation camera assembly positioned between the membrane module and the transfer module is arranged on the upper surface of the bearing platform; the film module positioning camera assembly comprises an XZ manual sliding table fixedly arranged on the upper surface of the gantry support, a first mounting support arranged on the XZ manual sliding table, a lens arranged on the first mounting support, a camera arranged at the upper end of the lens, and a light source arranged on a light source support arranged on the gantry support and positioned below the side of the lens; the printed board positioning camera assembly comprises an XY manual sliding table fixedly arranged on the upper surface of the gantry support, a Z-direction motor fixedly arranged on the upper surface of the XY manual sliding table, a Z-direction sliding rail arranged on one vertical surface of the Z-direction motor, a Z-direction fixed plate movably connected with the Z-direction sliding rail, a second mounting support fixedly connected with the Z-direction fixed plate, a lens arranged on the second mounting support, a camera arranged at the upper end of the lens, and a light source arranged on the second mounting support and positioned below the lens; the camera assembly for confirming the core plate comprises an XZ manual sliding table fixedly arranged on the upper surface of the bearing platform, a third mounting bracket arranged on the XZ manual sliding table, a lens arranged on the third mounting bracket, a camera arranged at the lower end of the lens, and a light source arranged on the third mounting bracket and positioned above the lens.

Preferably, the membrane module comprises an X-direction moving assembly arranged on the upper surface of the bearing platform, a Y-direction moving assembly movably arranged on the X-direction moving assembly, and a rotating assembly movably arranged on the Y-direction moving assembly.

Preferably, the X-direction moving assembly includes an X-direction base plate, an X-direction linear motor stator disposed on an upper surface of the X-direction base plate, two X-direction guide rails parallel to each other, an X-direction slider disposed on the two X-direction guide rails, an X-direction linear motor mover movably connected to the X-direction linear motor stator, and a Y-direction base plate fixedly disposed on the X-direction linear motor mover and having a bottom surface fixedly connected to the X-direction slider; the Y-direction moving assembly comprises two Y-direction side plates which are parallel to each other and the bottom surfaces of which are fixedly connected with the upper surface of the Y-direction bottom plate, Y-direction rear vertical plates, Y-direction linear motor stators, two Y-direction guide rails, Y-direction sliding blocks, Y-direction linear motor rotors and an R-direction rotating bottom plate, wherein the two ends of the Y-direction rear vertical plates are fixedly connected with the rear surfaces of the two Y-direction side plates respectively; the rotating assembly comprises a support, a rotating group fixing plate, a rotating group base, a bearing outer ring cover, a bearing inner ring, a crossed roller bearing, a driven belt pulley, a rotating group ring seat, a blue film chip disc, a R-direction motor, a driving belt pulley and an R-direction synchronous belt, wherein the R-direction support is composed of two R-direction vertical plates which are parallel to each other and fixedly arranged on the front surface of a R-direction rotating base plate, the R-direction rotating group fixing plate is arranged on the upper surface of the support, the rotating group base is fixedly arranged on the rotating group fixing plate, the bearing outer ring cover is fixedly arranged in the bearing inner ring cover, the crossed roller bearing is arranged between the bearing inner ring and the bearing outer ring cover in the radial direction, the driven belt pulley is sleeved on the crossed roller bearing, the rotating group ring seat is fixedly arranged on the upper surface of the driven belt pulley, the blue film chip disc is arranged on the rotating group ring seat, the R-direction motor is arranged below the rotating group fixing plate, and the driving belt pulley is arranged at the upper end of an output shaft of the R-direction motor and is used for connecting the driving belt pulley and the driven belt pulley.

Preferably, the needle module comprises a needle module base fixedly arranged on the upper surface of the bearing platform, a Z-direction manual sliding table arranged on the needle module base, an XY-direction manual sliding table arranged on the Z-direction manual sliding table, a voice coil motor and a Z-direction support arranged on the XY-direction manual sliding table, a Z-direction support frame connected with an output shaft of the voice coil motor and movably connected with the Z-direction support frame along the Z direction, a needle clamping column with the lower end connected with the Z-direction support frame, a thimble arranged at the upper end of the needle clamping column, a ball bush guide assembly sleeved outside the needle clamping column along the axial direction of the needle clamping column, a needle slide rail base arranged above the Z-direction support and sleeved outside the ball bush guide assembly along the axial direction of the needle clamping column, a needle clamping cap sleeved outside the thimble and fixedly connected with the upper end of the needle clamping column, and a vacuum cover sleeved outside the needle clamping cap; a vacuum seat located above and sleeved outside the needle slide rail seat; the vacuum cover is covered outside the opening at the upper end of the vacuum seat, and the lower end of the needle clamping cap is arranged in the opening at the upper end of the vacuum seat; and axial holes for the upper ends of the ejector pins to extend upwards along the axial direction of the ejector pins are formed in the ejector pin clamping cap and the vacuum cover.

Preferably, the upper surface of the bottom disc of the needle slide rail seat is provided with an inner sealing ring, and the inner sealing ring is in contact with the bottom surface of the vacuum seat; the Z-direction support frame consists of a Z-direction vertical plate and a Z-direction flat plate which are perpendicular to each other, and the back of the Z-direction vertical plate is connected with a support vertical plate on the Z-direction support frame through a crossed roller slide rail; the Z-direction flat plate is connected with an output shaft of the voice coil motor.

Preferably, the dispensing module comprises a dispensing mounting base, a dispensing assembly disposed thereon, and a dispensing disc assembly for mounting solder.

Preferably, the glue dispensing mounting seat comprises a glue dispensing mounting plate and a mounting vertical plate hinged with one side surface of the glue dispensing mounting plate; the dispensing disc assembly comprises a Z-direction adjusting plate fixedly arranged on the mounting vertical plate, a Z-direction base which is arranged on the Z-direction adjusting plate and can be adjusted in the Z direction relative to the Z-direction adjusting plate, a dispensing stepping motor and a dispensing disc which are arranged on the Z-direction base, a roller which is arranged below the dispensing stepping motor and is connected with an output shaft of the dispensing stepping motor, and the outer wall of a connecting cylinder on the dispensing disc is contacted with the circumferential surface of the roller; the subassembly is glued to point includes, locate on the installation riser and can be relative its X to the mounting panel of X to the removal, locate X to the surperficial motor installing support of mounting panel, point glue voice coil motor and Z to the guide rail on locating the motor installing support, glue the mounting bracket to the point of being connected with point glue voice coil motor and Z respectively, set firmly the point glue mount on the point glue mounting bracket, locate the step motor who glues the mount upper surface, the shaft coupling that is connected with the step motor output shaft, the main pivot seat that is connected with the shaft coupling, locate in the point glue mount and overlap the main pivot outer deep groove ball bearing of main pivot on the main pivot seat, with main pivot seat swing joint's counter shaft seat, one end and counter shaft seat lower extreme fixed connection's horizontal swing arm, locate perpendicularly the head is glued to the vertical point of the horizontal swing arm other end.

Preferably, the pressing module comprises a pressing mounting vertical seat, a pressing motor mounting plate arranged on the front surface of the pressing mounting vertical seat, a pressing motor arranged on the upper surface of the pressing motor mounting plate, an axial jacking block connected with the lower end of an output shaft of the pressing motor, and a pressing bracket fixedly connected with the axial jacking block and movably connected with the pressing motor mounting plate; the pressing support comprises a pressing support vertical plate, a glass carrier vertically connected with the pressing support vertical plate, and a glass suction plate arranged in the upper surface of the glass carrier; the axial jacking block moves in the Z direction; the back of the pressing support vertical plate is movably connected with the pressing motor mounting plate through a pressing cross roller slide rail.

Preferably, the suction nozzle module comprises a suction X-direction moving assembly, a suction Z-direction moving assembly arranged on the suction X-direction moving assembly, and a suction rotating assembly arranged on the suction Z-direction moving assembly.

Preferably, the X-direction sucking moving assembly comprises a material taking bottom plate, a material taking X-direction linear motor stator, two parallel material taking X-direction slide rails, material taking X-direction slide blocks, a material taking X-direction linear motor rotor and a material taking sliding table, wherein the material taking bottom plate is transversely arranged on the front surface of the gantry support; the suction Z-direction moving assembly comprises a material taking mounting bracket arranged on the material taking sliding table, a material taking voice coil motor and a material taking Z-direction slide rail arranged on the material taking sliding table, and a Z-direction mounting plate which is connected with the lower end of the material taking voice coil motor and movably connected with the material taking Z-direction slide rail; the sucking and rotating assembly comprises a material taking seat fixedly connected with the front surface of the Z-direction mounting plate, a material taking stepping motor arranged at the upper end of the material taking seat, a material taking coupler arranged in the material taking seat and connected with an output shaft of the material taking stepping motor, a material taking shaft bracket connected with the lower end of the material taking coupler, a material taking shaft arranged in the material taking shaft bracket along the axial direction of the material taking shaft bracket, a first guide bushing, a second guide bushing and a round wire spiral spring, a circular mounting hole arranged in a bottom plate at the lower end of the material taking seat, a material taking deep groove ball bearing arranged in the circular mounting hole, a transverse quick-change connector with one end transversely inserted in the material taking shaft bracket and detachably connected with the material taking shaft, a suction nozzle arranged at the lower end of the material taking shaft, and a fixing nut sleeved outside the connecting position of the upper end of the suction nozzle and the material taking shaft; the first guide bushing and the second guide bushing are sequentially sleeved outside the material taking shaft from inside to outside; the lower end of the material taking shaft frame is inserted into the circular mounting hole, the material taking deep groove ball bearing is sleeved outside the lower end of the material taking shaft frame, and the first guide bushing and the second guide bushing are positioned in the lower end of the material taking shaft frame; the round wire spiral spring is positioned above the material taking shaft.

Preferably, the transfer module includes an X-direction transfer component disposed on the upper surface of the carrying platform, and a Y-direction transfer component disposed thereon.

Preferably, the X-direction transfer assembly comprises a transfer support, an X-direction transfer linear motor stator arranged on the upper surface of the transfer support, two parallel X-direction transfer slide rails, an X-direction transfer linear motor rotor movably connected with the X-direction transfer linear motor stator, an X-direction fixed block fixedly connected with the X-direction transfer linear motor rotor, an X-direction transfer slide block arranged on the two X-direction transfer slide rails, and a Y-direction transfer bottom plate fixedly connected with the X-direction fixed block and the X-direction transfer slide block on the bottom surface; the Y-direction shifting assembly comprises a Y-direction shifting linear motor stator arranged on the upper surface of the Y-direction shifting bottom plate, two Y-direction shifting slide rails parallel to each other, a Y-direction shifting linear motor rotor movably connected with the Y-direction shifting linear motor stator, a Y-direction fixed block fixedly connected with the Y-direction shifting linear motor rotor, Y-direction shifting slide blocks arranged on the two Y-direction shifting slide rails, a Y-direction auxiliary slide table, an adsorption table seat arranged on the Y-direction auxiliary slide table, and an adsorption plate arranged on the adsorption table seat.

The beneficial technical effects are as follows: by adopting the crystal repairing and repairing device, during feeding, the printed board is placed on the platform of the transfer module, and the blue film chip tray for containing a plurality of chips is placed on the film module; the shifting module fixes the printed board on the positioning camera assembly and then moves to the position below the printed board positioning camera assembly, the printed board positioning camera assembly identifies the angle and the coordinate position of the chip bonding pad to be compensated, and the shifting module moves to the dispensing module after the identification is finished; a dispensing head on the dispensing module coats solder paste on the bonding pad and then returns to the initial position; after dispensing is finished, the printed board is moved to a chip station to be compensated by the transferring module platform; the suction nozzle module is moved above the blue film chip tray, after the film module positions the camera to identify the chip, an ejector pin of the needle module jacks up the chip, a suction nozzle of the suction nozzle module descends to suck up the chip, the chip is moved to a position above the coring chip confirmation camera, and if the chip accords with set image parameters (such as angles), the chip is placed on a corresponding position on the printed board; if the set image parameters are not met, the chip can be finely adjusted through a material taking stepping motor on the suction nozzle module within a fine adjustment range, the chip is placed on the corresponding position of the printed board after adjustment, and if the chip is not within the adjustment range, the suction nozzle module can move the chip to a recovery box for recovery; after the chip is placed, the printed board is moved to the lower side of the laser module by the transferring module, the pressing module presses downwards, the chip is attached and fixed on the printed board, and the chip is repaired by laser welding of the laser module. Compared with the prior art, the chip repairing and repairing device integrates chip repairing and welding processes to be completed on one device, reduces production flow, improves operation efficiency, improves product yield and reduces floor area.

Drawings

FIG. 1 is a perspective assembly view of an embodiment of the present invention;

FIG. 2 is another perspective assembly view of the present invention;

FIG. 3 is an exploded view of an embodiment of the present invention;

FIG. 4 is an assembled perspective view of the frame and portions of the mechanism thereon according to an embodiment of the present invention;

FIG. 5 is an exploded view of the housing and portions of the mechanism thereon according to an embodiment of the present invention;

FIG. 5a is a partial enlarged view of FIG. 5;

FIG. 6 is an assembled perspective view of a membrane module according to an embodiment of the present invention;

FIG. 7 is an exploded view of a membrane module according to an embodiment of the present invention;

FIG. 8 is an assembled perspective view of the needle module of the present embodiment;

FIG. 9 is an exploded view of the needle module of the embodiment of the present invention;

FIG. 10 is a cross-sectional view of a portion of a needle module in accordance with an embodiment of the present invention;

FIG. 11 is an assembled perspective view of a dispensing module according to an embodiment of the present invention;

FIG. 12 is an assembled perspective view of another view angle of the dispensing module according to the embodiment of the present invention;

FIG. 13 is an exploded view of a dispensing module according to an embodiment of the present invention;

fig. 14 is an assembled perspective view of the pressing module according to the embodiment of the invention;

FIG. 15 is an assembled perspective view of the pressing module according to another embodiment of the present invention;

FIG. 16 is an exploded view of a compression module according to an embodiment of the present invention;

FIG. 17 is an assembled perspective view of a nozzle module according to an embodiment of the present invention;

FIG. 18 is another perspective view of the nozzle module of the embodiment of the present invention;

FIG. 19 is an exploded view of a nozzle module according to an embodiment of the present invention;

FIG. 20 is a cross-sectional view of a portion of a nozzle module according to an embodiment of the present invention;

FIG. 21 is an assembled perspective view of a transfer module according to an embodiment of the present invention;

fig. 22 is an exploded view of the transfer module according to the embodiment of the present invention.

Detailed Description

In order that those skilled in the art will better understand the technical solution of the present invention, the following detailed description of the present invention is provided in conjunction with the accompanying drawings and embodiments.

As shown in fig. 1 to 3, an embodiment of the present invention provides a printed board repairing device, including a frame 100, further including: the laser module 200 is arranged on the frame; the laser module is a commercially available standard part, namely a laser; a film module 300 disposed on the frame 100 for moving a blue film chip tray on which chips are placed; a pin module 400 disposed on the frame 100 and below the blue film chip tray, for striking a chip placed on the blue film chip tray; the dispensing module 500 is arranged on the frame 100 and used for coating solder paste on a position of the printed board where a chip needs to be compensated; a suction nozzle module 600 disposed on the frame 100, for sucking the chip on the blue-film chip tray and placing the chip on the pad coated with solder paste on the printed board; a press-fit module 700 disposed on the frame 100 and used for fixing a chip to be soldered placed on a printed board; and the transfer module 800 is arranged on the rack 100 and used for moving the printed board to the station where the dispensing module 500, the suction nozzle module 600, the pressing module 700 and the laser module 200 are located, and finally completing the welding of the chip on the printed board.

As shown in fig. 4-5 and 5a, in this embodiment, the rack 100 includes two major parts, namely, a bearing platform 101 and a gantry support 102, the gantry support 102 is fixedly disposed on the upper surface of the bearing platform 101, specifically, the bearing platform 101 includes a bearing support 101a and a bearing flat plate 101b disposed thereon, and the gantry support 102 is disposed on the upper surface of the bearing flat plate 101 b; the gantry 102 is a mechanism commonly used in the equipment and will not be described in detail herein; the laser module 200, the suction nozzle module 600, the dispensing module 500 and the pressing module 700 are fixedly arranged on the gantry support 102; the film module 300, the pin module 400, and the transferring module 800 are fixedly disposed on the upper surface of the supporting platform 101, i.e., on the upper surface of the supporting plate 101 b.

Other attachment mechanisms are arranged on the rack 100 so as to be matched with the modules to work, and specifically, a film module positioning camera assembly 900 and a printed board positioning camera assembly 1000 which are positioned above the film module 300 and the transfer module 800 are respectively arranged on the gantry support 102; the coring sheet confirmation camera module 1100 is disposed between the film module 300 and the transfer module 800 on the upper surface of the support plate 101b of the support platform 101.

Specifically, the film module positioning camera assembly 900 comprises an XZ manual sliding table 901 fixedly arranged on the upper surface of the gantry support 102, a first mounting support 902 arranged on the XZ manual sliding table 901, a lens 1a arranged on the first mounting support, a camera 1b arranged at the upper end of the lens 1a, and a light source 1c arranged on a light source support 903 arranged on the gantry support 102 and positioned below the side of the lens 1 a; the printed board positioning camera assembly 1000 comprises an XY manual sliding table 1001 fixedly arranged on the upper surface of a gantry support 102, a Z-direction motor 1002 fixedly arranged on the upper surface of the XY manual sliding table 1001, a Z-direction slide rail 1003 arranged on one vertical surface of the Z-direction motor, a Z-direction fixing plate 1004 movably connected with the Z-direction slide rail, a second mounting support 1005 fixedly connected with the Z-direction fixing plate, a lens 1a arranged on the second mounting support, a camera 1b arranged at the upper end of the lens, and a light source 1c arranged on the second mounting support and positioned below the lens, wherein the position of the lens 1a can be finely adjusted in the XYZ three directions through the adjustment of the XY manual sliding table 1001 and the Z-direction motor 1002; the camera assembly 1100 for confirming the core slice comprises an XZ manual sliding table 901 fixedly arranged on the upper surface of the bearing platform 101, a third mounting bracket 1102 arranged on the XZ manual sliding table, a lens 1a arranged on the third mounting bracket, a camera 1b arranged at the lower end of the lens, and a light source 1c arranged on the third mounting bracket 1102 and positioned above the lens; here, the XZ manual slide table 901 and the XY manual slide table 1001 are both commercially available standard components, such as manual slide tables produced by mismi corporation, and are used for fine adjustment in XYZ directions. The Z-motor 1002, the Z-slide 1003 and the Z-fixing plate 1004 are all commercially available standard components, and particularly, the three components are integrated when purchased.

Specifically, the position of the lens in the camera assembly 900 is finely adjusted by an XZ manual sliding table 901 in the camera assembly; the position of a lens in the printed board positioning camera assembly 1000 is adjusted through the XY manual sliding table 1001 and the Z-direction motor 1002; the position of a lens in the camera assembly is finely adjusted by confirming the XZ manual sliding table 901 in the camera assembly 1100 through the coring sheet, so that the use requirement is better met.

A recovery box 1103 is provided on the third mounting bracket 1102, and a recovery box tube 1104 is provided on the recovery box 1103.

As shown in fig. 6-7, in the present embodiment, the film module 300 includes an X-direction moving assembly disposed on the upper surface of the supporting platform 101, a Y-direction moving assembly movably disposed on the X-direction moving assembly, and a rotating assembly movably disposed on the Y-direction moving assembly.

Specifically, the X-direction moving assembly includes an X-direction base plate 301, an X-direction linear motor stator 302 disposed on an upper surface of the X-direction base plate, two X-direction guide rails 303 parallel to each other, and two X-direction sliders 304 disposed on the two X-direction guide rails, where the number of the X-direction sliders 304 disposed on each X-direction guide rail is two, an X-direction linear motor mover 305 movably connected to the X-direction linear motor stator 302, and a Y-direction base plate 306 fixedly disposed on the X-direction linear motor mover 305 and having a bottom surface fixedly connected to the X-direction slider 304; the Y-direction moving assembly comprises two Y-direction side plates 307 which are parallel to each other and the bottom surfaces of which are fixedly connected with the upper surface of a Y-direction bottom plate 306, Y-direction rear vertical plates 308 of which the two ends are respectively fixedly connected with the rear surfaces of the two Y-direction side plates 307, a Y-direction linear motor stator 309 arranged on the front surfaces of the Y-direction rear vertical plates 308, two Y-direction guide rails 310 which are parallel to each other, and Y-direction sliding blocks 311 arranged on the two Y-direction guide rails, wherein the number of the Y-direction sliding blocks 311 arranged on each Y-direction guide rail is two; a Y-direction linear motor mover 312 movably connected to the Y-direction linear motor stator 309, an R-direction rotary base plate 313 fixedly disposed on the Y-direction linear motor mover 312 and having a bottom surface fixedly connected to the Y-direction slider 311; the rotating assembly comprises an R-direction bracket 314 consisting of two R-direction vertical plates which are parallel to each other and fixedly arranged on the front surface of an R-direction rotating bottom plate 313, a rotating group fixing plate 315 arranged on the upper surface of the R-direction bracket 314, a rotating group base 316 fixedly arranged on the rotating group fixing plate 315, a bearing outer ring cover 317 fixedly arranged on the rotating group base, a bearing inner ring 318 arranged in the bearing outer ring cover, a cross roller bearing 319 arranged between the bearing inner ring 318 and the bearing outer ring cover 317 in the radial direction, a driven belt pulley 320 sleeved on the cross roller bearing 319, a rotating group ring seat 321 fixedly arranged on the upper surface of the driven belt pulley, a blue film chip disc 322 arranged on the rotating group ring seat, an R-direction motor 323 arranged below the rotating group fixing plate 315, a driving belt pulley 324 arranged on an output shaft of the R-direction motor, and an R-direction synchronous belt 325 used for connecting the upper ends of the driving belt pulley 324 and the driven belt pulley 320; a first grating scale 326 is arranged on the bottom plate of the X-direction bottom plate 301, and a first grating scale head 327 positioned at the side of the first grating scale 326 is arranged on the side surface of the Y-direction bottom plate 306.

In the module, when the module is in operation, the X-direction linear motor stator 302 and the X-direction linear motor rotor 305 of the X-direction moving assembly drive the Y-direction base plate 306 and the components mounted thereon to reciprocate along the X direction, the Y-direction linear motor stator 309 and the Y-direction linear motor rotor 312 in the Y-direction moving assembly drive the R-direction rotating base plate 313 and the components mounted thereon to reciprocate in the Y direction, the R-direction motor 323 drives the driven pulley 320 to rotate through the driving pulley 324 and the R-direction synchronous belt 325, the rotating ring seat 321 connected with the driven pulley 320 is driven to rotate, and the blue film chip disc 322 arranged on the rotating ring seat rotates along with the rotating ring seat, so that the film module has XY-direction movement and can rotate.

As shown in fig. 8-10, the needle module 400 includes a needle module base 401 fixed on the upper surface of the supporting platform 101, a Z-direction manual sliding table 402 disposed on the needle module base, an XY-direction manual sliding table 403 disposed on the Z-direction manual sliding table, a voice coil motor 404 mounted on the XY-direction manual sliding table, and a Z-direction support 405, a Z-direction supporting frame 406 connected with the output shaft of the voice coil motor and movably connected with the Z-direction support 405 along the Z direction, a needle clamping column 407 with the lower end connected with the Z-direction supporting frame 406, a thimble 408 arranged at the upper end of the needle clamping column 407, a ball bush guiding assembly 409 sleeved outside the needle clamping column 407 along the axial direction of the needle clamping column, a needle slide rail seat 410 arranged above the Z-direction support 405 and sleeved outside the Z-direction support along the axial direction of the ball bush guiding assembly, a needle clamping cap 411 sleeved outside the thimble 408 along the axial direction and fixedly connected with the upper end of the needle clamping column 407, and a vacuum cover 412 sleeved outside the needle clamping cap; a vacuum seat 413 disposed above and sleeved on the needle rail seat 410; the vacuum cover 412 is covered outside the opening at the upper end of the vacuum seat 413, and the lower end of the needle clamping cap 411 is arranged in the opening at the upper end of the vacuum seat 413; the needle clamping cap 411 and the vacuum cover 412 are provided with axial holes for the upper ends of the needles 408 to extend upwards along the axial direction of the needles. And the Z-direction manual sliding table and the XY-direction manual sliding table are commercially available standard parts.

The upper surface of the bottom disk of the needle slide rail seat 410 is internally provided with a sealing ring 415, and the sealing ring 415 is contacted with the bottom surface of the vacuum seat 413; the Z-direction supporting frame 406 is composed of a Z-direction vertical plate 406a and a Z-direction flat plate 406b which are perpendicular to each other, and the back of the Z-direction vertical plate 406a is connected with a bracket vertical plate 405a on the Z-direction bracket 405 through a crossed roller sliding rail 414; the Z-direction plate 406b is connected to an output shaft of the voice coil motor 404, so that the Z-direction support 406 is driven by the voice coil motor 404 to be lifted and lowered with respect to the Z-direction holder 405.

The pin module 400 is located on the film module 300 and located below the blue film chip tray 322, fine adjustment in the XYZ direction can be achieved by the module through the XY direction to the manual sliding table 403 and the Z direction to the manual sliding table 402, the module is used for adjusting the positions of the voice coil motor 404 and the ejector pin 408, and when the module works, the voice coil motor 404 is started to sequentially drive the Z direction support frame 406, the needle clamping column 407, the ejector pin 408 and the needle clamping cap 411 to reciprocate in the Z direction to jack up the chip on the blue film chip tray 322.

As shown in fig. 11-13, the dispensing module 500 includes a dispensing mounting base, a dispensing assembly disposed thereon, and a dispensing disc assembly for mounting solder thereon.

Specifically, the dispensing mounting base comprises a dispensing mounting plate 501 vertically arranged, and a mounting vertical plate 502 hinged with one side of the dispensing mounting plate 501, that is, the mounting vertical plate 502 can rotate relative to the dispensing mounting plate 501; the dispensing disc component comprises a Z-direction adjusting plate 503 fixedly arranged on the mounting vertical plate 502, a Z-direction base 504 which is arranged on the Z-direction adjusting plate and can be adjusted in the Z direction relative to the Z-direction adjusting plate, a dispensing stepping motor 505 and a dispensing disc 506 which are arranged on the Z-direction base 504, a roller 507 which is arranged below the dispensing stepping motor 505 and is connected with an output shaft of the dispensing stepping motor, wherein the outer wall of a connecting cylinder 506a on the dispensing disc 506 is contacted with the circumferential surface of the roller 507; here, the connecting cylinder 506a is connected with a disk body 506b on the dispensing disk 506, and the connecting cylinder 506a is in frictional contact with the roller 507, and when the connecting cylinder 506a rotates along with the roller 507, the disk body 506b rotates; the glue dispensing assembly comprises an X-direction mounting plate 508 which is arranged on the mounting vertical plate 502 and can move in the X direction relative to the mounting vertical plate, a motor mounting bracket 509 arranged on the surface of the X-direction mounting plate, a glue dispensing voice coil motor 510 and a Z-direction guide rail 511 arranged on the motor mounting bracket, a glue dispensing mounting bracket 512 respectively connected with the glue dispensing voice coil motor 510 and the Z-direction guide rail 511 in the direction, a glue dispensing fixing frame 513 fixedly arranged on the glue dispensing mounting bracket 512, a stepping motor 514 arranged on the upper surface of the glue dispensing fixing frame, a coupling 515 connected with the output shaft of the stepping motor 514, a main rotating shaft seat 516 connected with the coupling 515, a deep groove ball bearing 517 arranged in the dispensing fixing frame 513 and sleeved outside a main rotating shaft 516a on the main rotating shaft seat 516, an auxiliary rotating shaft seat 518 movably connected with the main rotating shaft seat 516, a transverse swing arm 519 with one end fixedly connected with the lower end of the auxiliary rotating shaft seat, and a vertical dispensing head 520 vertically arranged at the other end of the transverse swing arm. Here, the motor mounting bracket 509, the dispensing voice coil motor 510, the Z-guide 511, and the dispensing mounting bracket 512 are all commercially available standard components, and particularly, they are integrated when purchased.

Here, a transverse adjusting bolt 521 is arranged on the outer side surface of the mounting vertical plate 502 and connected with the X-direction mounting plate 508, and when the adjusting bolt 521 rotates, the X-direction mounting plate 508 can be driven to move on the mounting vertical plate 502 along the X direction; a vertical adjusting bolt 521 is arranged on the upper surface of the Z-direction adjusting plate 503 and connected with the Z-direction base 504, and when the adjusting bolt 521 rotates, the Z-direction base 504 can be driven to move on the Z-direction adjusting plate 503 along the Z direction; the X-direction mounting plate 508 and the mounting vertical plate 502, and the Z-direction base 504 and the Z-direction adjusting plate 503 are connected through a sliding groove and a sliding block.

The back of the auxiliary rotating shaft seat 518 is movably connected with the front surface of the main rotating shaft seat 516 through a buffer crossed roller slide rail 522, the back of the upper end of the auxiliary rotating shaft seat 518 is provided with a transverse connecting block 518a, a longitudinal runway hole 516b is arranged in the main rotating shaft seat 516, the transverse connecting block 518a extends into the longitudinal runway hole 516b, and the transverse connecting block 518a is connected with the main rotating shaft seat 516 through an extension spring 523.

In the module, the mounting vertical plate 502 can rotate a certain angle relative to the dispensing mounting plate 501, and the components on the mounting vertical plate 502 rotate along with the rotation; the dispensing disc 506 is arranged on the Z-direction base 504, the height of the Z-direction base 504 can be adjusted through a vertical adjusting bolt 521, the height of the dispensing disc 506 is synchronously adjusted, a connecting cylinder 506a on the dispensing disc 506 is connected with a disc body 506b on the dispensing disc 506, the connecting cylinder 506a is in friction contact with the roller 507, and when the connecting cylinder 506a rotates along with the roller 507, the disc body 506b rotates along with the roller 507; when the adjusting bolt 521 rotates, the X-direction mounting plate 508 can be driven to move on the mounting vertical plate 502 along the X direction, and components mounted on the X-direction mounting plate 508 are synchronously adjusted; the dispensing voice coil motor 510 drives the dispensing mounting frame 512 and the dispensing mounting frame 513 to move in the Z direction, and drives the stepping motor 514, the horizontal swing arm 519 and the vertical dispensing head 520 to move in the Z direction, and meanwhile, the stepping motor 514 rotates to drive the horizontal swing arm 519 to rotate.

As shown in fig. 17-20, the nozzle module 600 includes an X-direction sucking moving component, a Z-direction sucking moving component disposed thereon, and a Z-direction sucking rotating component disposed on the Z-direction sucking moving component.

Specifically, the suction X-direction moving assembly comprises a material taking bottom plate 601 transversely arranged on the front surface of the gantry support 102, material taking X-direction linear motor stators (not shown) arranged on the surface of the material taking bottom plate, two material taking X-direction slide rails 602 parallel to each other, material taking X-direction slide blocks 603 arranged on the two material taking X-direction slide rails 602, two material taking X-direction slide blocks 603 arranged on each material taking X-direction slide rail 602, material taking X-direction linear motor rotors 604 movably connected with the material taking X-direction linear motor stators, and material taking sliding tables 605 fixedly connected with the material taking X-direction linear motor rotors 604 and the material taking X-direction slide blocks 603 on the back surface; the suction Z-direction moving assembly comprises a material taking mounting bracket 606 arranged on the material taking sliding table 605, a material taking voice coil motor 607 and a material taking Z-direction sliding rail 608 which are arranged on the material taking sliding table, and a Z-direction mounting plate 609 connected with the lower end of the material taking voice coil motor and movably connected with the material taking Z-direction sliding rail 608; the suction rotating assembly comprises a material taking seat 610 fixedly connected with the front surface of the Z-direction mounting plate 609, a material taking stepping motor 611 arranged at the upper end of the material taking seat, a material taking coupler 612 arranged in the material taking seat 610 and connected with an output shaft of the material taking stepping motor, a material taking shaft bracket 613 connected with the lower end of the material taking coupler, a material taking shaft 614, a first guide bush 615, a second guide bush 616 and a round wire spiral spring 617 which are arranged in the material taking shaft bracket along the axial direction of the material taking shaft bracket, a round mounting hole 610b arranged in a bottom plate 610a at the lower end of the material taking seat 610, a material taking deep groove ball bearing 618 arranged in the round mounting hole, a transverse quick-change connector 619, a suction nozzle 620 arranged at the lower end of the material taking shaft, and a fixing nut 621 sleeved outside the position where the upper end of the suction nozzle 620 is connected with the material taking shaft 614; the first guide bushing 615 and the second guide bushing 616 are sequentially sleeved outside the material taking shaft 614 from inside to outside; the lower end of the material taking shaft frame 613 is inserted into the circular mounting hole 610b, the material taking deep groove ball bearing 618 is sleeved outside the lower end of the material taking shaft frame 613, and the first guide bushing 615 and the second guide bushing 616 are located in the lower end of the material taking shaft frame 613; a round wire coil spring 617 is located above the take-up shaft 614.

The upper surface of the material taking sliding table 605 is provided with a third optical reading head 622.

The deep groove ball bearings adopted in the embodiment are all commercially available standard parts and are composed of two single-row deep groove ball bearings and a spacing ring arranged between the two single-row deep groove ball bearings.

The linear motor stator and the linear motor rotor adopted in the embodiment form the linear motor, and are used in different modules, and different numbers are given for the convenience of distinguishing.

As shown in fig. 14-16, the pressing module 700 includes a pressing mounting seat 701, a pressing motor mounting plate 702 disposed on a front surface of the pressing mounting seat, a pressing motor 703 disposed on an upper surface of the pressing motor mounting plate, an axial top block 704 connected to a lower end of an output shaft of the pressing motor, and a pressing bracket 705 fixedly connected to the axial top block 704 and movably connected to the pressing motor mounting plate 702; the pressing support 705 comprises a pressing support vertical plate 705a, a glass carrier 705b vertically connected with the pressing support vertical plate, and a glass suction plate 705c arranged in the upper surface of the glass carrier; the axial top block 704 moves in the Z direction; the back of the pressing bracket vertical plate 705a is movably connected with the pressing motor mounting plate 702 through a pressing cross roller slide rail 706.

The pressing motor 703 used here is a standard component that can convert rotational motion into linear motion, and drive the axial top block 704 to move up and down in the Z direction, and has a function similar to that of an air cylinder, but can be precisely controlled.

As shown in fig. 21 to 22, the transfer module 800 includes an X-direction transfer unit disposed on the upper surface of the carrier platform 101, and a Y-direction transfer unit disposed thereon.

Specifically, the X-direction transfer assembly includes a transfer support 801, an X-direction transfer linear motor stator 802 disposed on an upper surface of the transfer support, two X-direction transfer slide rails 803 parallel to each other, an X-direction transfer linear motor mover 804 movably connected to the X-direction transfer linear motor stator, an X-direction fixed block 805 fixedly connected to the X-direction transfer linear motor mover, and X-direction transfer sliders 806 disposed on the two X-direction transfer slide rails 803, where there are two X-direction transfer sliders 806 disposed on each X-direction transfer slide rail 803, and a Y-direction transfer base plate 807 whose bottom surface is fixedly connected to the X-direction fixed block 805 and the X-direction transfer sliders 806; the Y-direction transfer assembly includes a Y-direction transfer linear motor stator 808 provided on the upper surface of the Y-direction transfer base plate 807, two Y-direction transfer slide rails 809 parallel to each other, a Y-direction transfer linear motor mover 810 movably connected to the Y-direction transfer linear motor stator 808, a Y-direction fixed block 811 fixedly connected to the Y-direction transfer linear motor mover, Y-direction transfer sliders 812 provided on the two Y-direction transfer slide rails, where there are two Y-direction transfer sliders 812 provided on each Y-direction transfer slide rail 809, Y-direction sub-slides 813 having bottom surfaces fixedly connected to the Y-direction fixed block 811 and the Y-direction transfer sliders 812, an adsorption base 814 provided on the Y-direction sub-slides 813, and an adsorption plate 815 provided on the adsorption base.

A first optical head 816 is provided on the end surface of the Y-direction transfer base plate 807, and a second optical head 817 is provided on the side surface of the Y-direction sub slide table 813.

During feeding, the printed board is placed on the adsorption plate 815 of the transfer module 800, and the blue-film chip tray 322 containing a plurality of chips is placed on the film module 300; the shifting module 800 fixes the printed board on the printed board and then moves to the position below the lens 1a of the printed board positioning camera assembly 1000, the angle and the coordinate position of the chip bonding pad needing to be compensated can be known through the identification of the printed board positioning camera assembly, and the shifting module moves to the dispensing module 500 after the identification is completed; the vertical dispensing head 520 on the dispensing module 500 coats the solder paste on the pad and then returns to the initial position; after dispensing is completed, the transferring module 800 moves the printed board to a chip station to be compensated; after the suction nozzle module 600 moves above the blue film chip tray 322, and the film module positioning camera assembly 900 recognizes the chip, the ejector pins 408 of the pin module 400 lift up the chip, and the suction nozzle 620 of the suction nozzle module 600 descends to suck up the chip, wherein the suction nozzle sucks up the chip through vacuum negative pressure, and the transverse quick-change connector 619 is a vacuum pipe connector; moving the chip to a position above the coring bit confirmation camera assembly 1100, and if the image parameters (such as angles) are met, placing the chip at a corresponding position on the printed board; if the set image parameters are not met, the chip can be finely adjusted through the material taking stepping motor 611 on the suction nozzle module within the fine adjustment range, the chip is placed on the corresponding position of the printed board after adjustment, and if the chip is not within the adjustment range, the suction nozzle module 600 moves the chip to the recovery box 1103 for recovery; after the chip is placed, the transferring module 800 transfers the printed board to the lower side of the laser module 200, the pressing module 700 presses downwards, the chip is attached and fixed on the printed board, and the chip supplementing process is completed through laser welding of the laser module 200. Compared with the prior art, the chip repairing and repairing device integrates chip repairing and welding processes to be completed on one device, so that the production flow is effectively reduced, the operation efficiency and the product yield are improved, and the occupied area is reduced.

In the above description, it should be noted that the terms "mounted," "connected," and the like are used in a broad sense, and for example, they may be fixedly connected, detachably connected, or integrally connected; the two components can be directly connected or indirectly connected through an intermediate medium, and the two components can be communicated with each other.

It is to be understood that the above-described embodiments are merely illustrative of some, but not restrictive, of the broad invention, and that the appended drawings illustrate preferred embodiments of the invention without limiting its scope. This invention may be embodied in many different forms and, on the contrary, these embodiments are provided so that this disclosure will be thorough and complete. All equivalent structures made by using the contents of the specification and the attached drawings of the invention can be directly or indirectly applied to other related technical fields, and are also within the protection scope of the patent of the invention.

Claims (14)

1. The utility model provides a printed board benefit brilliant device of reprocessing, includes the frame, its characterized in that still includes:

the laser module is arranged on the rack;

the film module is arranged on the rack and used for moving the blue film chip tray on which the chip is placed;

the pin module is arranged on the rack, positioned below the blue film chip disc and used for impacting a chip placed on the blue film chip disc;

the dispensing module is arranged on the rack and used for coating the solder paste on the position of the printed board where the chip needs to be repaired;

the suction nozzle module is arranged on the rack and used for sucking the chip on the blue film chip disc and placing the chip on a bonding pad coated with solder paste on the printed board;

the pressing module is arranged on the rack and used for fixing the chip to be welded on the printed board;

and the shifting module is arranged on the rack and used for moving the printed board to a station where the dispensing module, the suction nozzle module, the pressing module and the laser module are located, and finally, welding of the chip on the printed board is completed.

2. The printed board die repairing device according to claim 1, wherein the frame comprises a bearing platform and a gantry support, and the gantry support is fixedly arranged on the upper surface of the bearing platform; the laser module, the suction nozzle module, the dispensing module and the pressing module are fixedly arranged on the gantry support; the film module, the needle module and the transfer module are fixedly arranged on the upper surface of the bearing platform.

3. The printed board die repairing and reworking apparatus according to claim 2, wherein a film module positioning camera assembly and a printed board positioning camera assembly are respectively provided on the gantry support above the film module and the transfer module; a coring sheet confirmation camera assembly positioned between the membrane module and the transfer module is arranged on the upper surface of the bearing platform; the film module positioning camera assembly comprises an XZ manual sliding table fixedly arranged on the upper surface of the gantry support, a first mounting support arranged on the XZ manual sliding table, a lens arranged on the first mounting support, a camera arranged at the upper end of the lens, and a light source arranged on a light source support arranged on the gantry support and positioned below the side of the lens; the printed board positioning camera assembly comprises an XY manual sliding table fixedly arranged on the upper surface of the gantry support, a Z-direction motor fixedly arranged on the upper surface of the XY manual sliding table, a Z-direction sliding rail arranged on one vertical surface of the Z-direction motor, a Z-direction fixed plate movably connected with the Z-direction sliding rail, a second mounting support fixedly connected with the Z-direction fixed plate, a lens arranged on the second mounting support, a camera arranged at the upper end of the lens, and a light source arranged on the second mounting support and positioned below the lens; the camera assembly for confirming the core plate comprises an XZ manual sliding table fixedly arranged on the upper surface of the bearing platform, a third mounting bracket arranged on the XZ manual sliding table, a lens arranged on the third mounting bracket, a camera arranged at the lower end of the lens, and a light source arranged on the third mounting bracket and positioned above the lens.

4. The printed board die repairing device as claimed in claim 2, wherein the film module comprises an X-direction moving assembly disposed on the upper surface of the carrying platform, a Y-direction moving assembly movably disposed on the X-direction moving assembly, and a rotating assembly movably disposed on the Y-direction moving assembly.

5. The printed board repairing and repairing device according to claim 4, wherein the X-direction moving assembly comprises an X-direction base plate, an X-direction linear motor stator arranged on the upper surface of the X-direction base plate, two X-direction guide rails parallel to each other, an X-direction slider arranged on the two X-direction guide rails, an X-direction linear motor rotor movably connected with the X-direction linear motor stator, and a Y-direction base plate fixedly arranged on the X-direction linear motor rotor and fixedly connected with the X-direction slider at the bottom surface; the Y-direction moving assembly comprises two Y-direction side plates which are parallel to each other and the bottom surfaces of which are fixedly connected with the upper surface of the Y-direction bottom plate, Y-direction rear vertical plates, Y-direction linear motor stators, two Y-direction guide rails, Y-direction sliding blocks, Y-direction linear motor rotors and an R-direction rotating bottom plate, wherein the two ends of the Y-direction rear vertical plates are fixedly connected with the rear surfaces of the two Y-direction side plates respectively; the rotating assembly comprises a support, a rotating group fixing plate, a rotating group base, a bearing outer ring cover, a bearing inner ring, a crossed roller bearing, a driven belt pulley, a rotating group ring seat, a blue film chip disc, a R-direction motor, a driving belt pulley and an R-direction synchronous belt, wherein the R-direction support is composed of two R-direction vertical plates which are parallel to each other and fixedly arranged on the front surface of a R-direction rotating base plate, the R-direction rotating group fixing plate is arranged on the upper surface of the support, the rotating group base is fixedly arranged on the rotating group fixing plate, the bearing outer ring cover is fixedly arranged in the bearing inner ring cover, the crossed roller bearing is arranged between the bearing inner ring and the bearing outer ring cover in the radial direction, the driven belt pulley is sleeved on the crossed roller bearing, the rotating group ring seat is fixedly arranged on the upper surface of the driven belt pulley, the blue film chip disc is arranged on the rotating group ring seat, the R-direction motor is arranged below the rotating group fixing plate, and the driving belt pulley is arranged at the upper end of an output shaft of the R-direction motor and is used for connecting the driving belt pulley and the driven belt pulley.

6. The printed board die repair and rework device of claim 2, wherein the pin module comprises a pin module base fixed on the upper surface of the carrier platform, a Z-direction manual slide table disposed on the pin module base, an XY-direction manual slide table disposed on the Z-direction manual slide table, a voice coil motor and a Z-direction support mounted on the XY-direction manual slide table, the voice coil motor comprises a Z-direction support frame, a needle clamping column, a thimble, a ball bush guide assembly, a needle slide rail seat, a needle clamping cap and a vacuum cover, wherein the Z-direction support frame is connected with an output shaft of the voice coil motor and movably connected with a Z-direction support frame along the Z direction, the lower end of the needle clamping column is connected with the Z-direction support frame, the thimble is arranged at the upper end of the needle clamping column, the ball bush guide assembly is sleeved outside the needle clamping column along the axial direction of the needle clamping column, the needle slide rail seat is arranged above the Z-direction support frame and is sleeved outside the Z-direction support frame along the axial direction of the ball bush guide assembly, the needle clamping cap is sleeved outside the thimble along the axial direction of the thimble and is fixedly connected with the upper end of the needle clamping column, and the vacuum cover is sleeved outside the needle clamping cap; a vacuum seat located above and sleeved outside the needle slide rail seat; the vacuum cover is covered outside the opening at the upper end of the vacuum seat, and the lower end of the needle clamping cap is arranged in the opening at the upper end of the vacuum seat; and axial holes for the upper ends of the ejector pins to extend upwards along the axial direction of the ejector pins are formed in the ejector pin clamping cap and the vacuum cover.

7. The printed board die repairing device as claimed in claim 6, wherein the upper surface of the bottom disk of the needle slide rail seat is provided with an inner sealing ring, and the sealing ring is in contact with the bottom surface of the vacuum seat; the Z-direction support frame consists of a Z-direction vertical plate and a Z-direction flat plate which are perpendicular to each other, and the back of the Z-direction vertical plate is connected with a support vertical plate on the Z-direction support frame through a crossed roller slide rail; the Z-direction flat plate is connected with an output shaft of the voice coil motor.

8. The printed circuit board die repairing and repairing device as claimed in claim 2, wherein the dispensing module comprises a dispensing mounting base, a dispensing assembly disposed thereon and a dispensing assembly for mounting solder.

9. The printed board die repairing device as claimed in claim 8, wherein the dispensing mounting base comprises a dispensing mounting plate, a mounting vertical plate hinged to one side surface of the dispensing mounting plate; the dispensing disc assembly comprises a Z-direction adjusting plate fixedly arranged on the mounting vertical plate, a Z-direction base which is arranged on the Z-direction adjusting plate and can be adjusted in the Z direction relative to the Z-direction adjusting plate, a dispensing stepping motor and a dispensing disc which are arranged on the Z-direction base, a roller which is arranged below the dispensing stepping motor and is connected with an output shaft of the dispensing stepping motor, and the outer wall of a connecting cylinder on the dispensing disc is contacted with the circumferential surface of the roller; the subassembly is glued to point includes, locate on the installation riser and can be relative its X to the mounting panel of X to the removal, locate X to the surperficial motor installing support of mounting panel, point glue voice coil motor and Z to the guide rail on locating the motor installing support, glue the mounting bracket to the point of being connected with point glue voice coil motor and Z respectively, set firmly the point glue mount on the point glue mounting bracket, locate the step motor who glues the mount upper surface, the shaft coupling that is connected with the step motor output shaft, the main pivot seat that is connected with the shaft coupling, locate in the point glue mount and overlap the main pivot outer deep groove ball bearing of main pivot on the main pivot seat, with main pivot seat swing joint's counter shaft seat, one end and counter shaft seat lower extreme fixed connection's horizontal swing arm, locate perpendicularly the head is glued to the vertical point of the horizontal swing arm other end.

10. The printed board die repairing device as claimed in claim 2, wherein the press-fit module comprises a press-fit mounting seat, a press-fit motor mounting plate arranged on the front surface of the press-fit mounting seat, a press-fit motor arranged on the upper surface of the press-fit motor mounting plate, an axial top block connected with the lower end of the output shaft of the press-fit motor, and a press-fit bracket fixedly connected with the axial top block and movably connected with the press-fit motor mounting plate; the pressing support comprises a pressing support vertical plate, a glass carrier vertically connected with the pressing support vertical plate, and a glass suction plate arranged in the upper surface of the glass carrier; the axial jacking block moves in the Z direction; the back of the pressing support vertical plate is movably connected with the pressing motor mounting plate through a pressing cross roller slide rail.

11. The printed board die repairing device as claimed in claim 2, wherein the suction nozzle module comprises a suction X-direction moving assembly, a suction Z-direction moving assembly arranged thereon, and a suction rotating assembly arranged on the suction Z-direction moving assembly.

12. The printed board repairing device according to claim 11, wherein the X-direction sucking moving assembly comprises a material taking bottom plate transversely arranged on the front surface of the gantry support, a material taking X-direction linear motor stator and two parallel material taking X-direction slide rails arranged on the surface of the gantry support, a material taking X-direction slider arranged on the two material taking X-direction slide rails, a material taking X-direction linear motor mover movably connected with the material taking X-direction linear motor stator, and a material taking sliding table fixedly connected with the material taking X-direction linear motor mover and the material taking X-direction slider on the back surface of the material taking X-direction linear motor mover; the suction Z-direction moving assembly comprises a material taking mounting bracket arranged on the material taking sliding table, a material taking voice coil motor and a material taking Z-direction slide rail arranged on the material taking mounting bracket, and a Z-direction mounting plate which is connected with the lower end of the material taking voice coil motor and movably connected with the material taking Z-direction slide rail; the sucking and rotating assembly comprises a material taking seat fixedly connected with the front surface of the Z-direction mounting plate, a material taking stepping motor arranged at the upper end of the material taking seat, a material taking coupler arranged in the material taking seat and connected with an output shaft of the material taking stepping motor, a material taking shaft bracket connected with the lower end of the material taking coupler, a material taking shaft arranged in the material taking shaft bracket along the axial direction of the material taking shaft bracket, a first guide bush, a second guide bush and a round wire spiral spring, a round mounting hole arranged in a bottom plate at the lower end of the material taking seat, a material taking deep groove ball bearing arranged in the round mounting hole, a transverse quick-change connector with one end transversely inserted in the material taking shaft bracket and detachably connected with the material taking shaft, a suction nozzle arranged at the lower end of the material taking shaft, and a fixing nut sleeved outside the connecting position of the upper end of the suction nozzle and the material taking shaft; the first guide bushing and the second guide bushing are sequentially sleeved outside the material taking shaft from inside to outside; the lower end of the material taking shaft bracket is inserted into the circular mounting hole, the material taking deep groove ball bearing is sleeved outside the lower end part of the material taking shaft bracket, and the first guide bushing and the second guide bushing are positioned in the lower end part of the material taking shaft bracket; the round wire helical spring is positioned above the material taking shaft.

13. The printed board die repairing and repairing device as claimed in claim 2, wherein the transfer module comprises an X-direction transfer component arranged on the upper surface of the carrying platform, and a Y-direction transfer component arranged thereon.

14. The printed board repairing device according to claim 13, wherein the X-direction transfer assembly comprises a transfer support, an X-direction transfer linear motor stator arranged on the upper surface of the transfer support, two X-direction transfer slide rails parallel to each other, an X-direction transfer linear motor mover movably connected with the X-direction transfer linear motor stator, an X-direction fixed block fixedly connected with the X-direction transfer linear motor mover, an X-direction transfer slide block arranged on the two X-direction transfer slide rails, and a Y-direction transfer base plate fixedly connected with the X-direction fixed block and the X-direction transfer slide block at the bottom surface; the Y-direction shifting assembly comprises a Y-direction shifting linear motor stator arranged on the upper surface of the Y-direction shifting bottom plate, two Y-direction shifting slide rails parallel to each other, a Y-direction shifting linear motor rotor movably connected with the Y-direction shifting linear motor stator, a Y-direction fixed block fixedly connected with the Y-direction shifting linear motor rotor, Y-direction shifting slide blocks arranged on the two Y-direction shifting slide rails, a Y-direction auxiliary slide table, an adsorption table seat arranged on the Y-direction auxiliary slide table, and an adsorption plate arranged on the adsorption table seat.

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