CN220265909U - Electroplating tool for manufacturing ceramic carrier plate - Google Patents

Abstract

The utility model relates to an electroplating tool for manufacturing a ceramic carrier plate, which relates to the technical field of ceramic carrier plate electroplating and comprises a frame, wherein a group of guide rods are fixedly arranged on the frame, an upper guide sleeve and a lower guide sleeve are sleeved on the guide rods, the upper guide sleeve is positioned above the lower guide sleeve, a cover plate is fixedly arranged between the upper guide sleeves, an electroplating pool is fixedly arranged between the lower guide sleeves, the cover plate is positioned above the electroplating pool, a storage rack is arranged at the bottom of the cover plate, an upper lifting assembly is arranged between the cover plate and the frame, the upper lifting assembly is used for driving the cover plate to lift, a lower lifting assembly is arranged between the electroplating pool and the frame, the lower lifting assembly is used for driving the electroplating pool to lift, and a driving motor is fixedly arranged on the frame and used for driving the upper lifting assembly and the lower lifting assembly. The application has the effects of improving the electroplating efficiency of the ceramic carrier plate and shortening the electroplating period of the ceramic carrier plate.

Description

Electroplating tool for manufacturing ceramic carrier plate

Technical Field

The utility model relates to the technical field of ceramic carrier plate electroplating, in particular to an electroplating tool for manufacturing a ceramic carrier plate.

Background

The ceramic carrier is an ideal heat dissipation packaging material for a new generation of large-scale integrated circuits, semiconductor module circuits and high-power devices, and is applied to the fields of high-power semiconductor modules, semiconductor refrigerators, electronic heaters, power control circuits, automobile electronics, solar panel assemblies, lasers and the like, and the surface of the ceramic carrier often needs electroplating treatment.

The China patent with the authorized bulletin number of CN213295540U in the related art provides a ceramic substrate electroplating device, which comprises a supporting frame, wherein an electroplating bath is arranged below the supporting frame, a cover plate is arranged on the electroplating bath and used for covering the electroplating bath, a telescopic device is arranged between the supporting frame and the cover plate and used for driving the cover plate to move, a storage rack is fixedly arranged at the bottom of the cover plate, a motor is arranged at the top of the cover plate, and an output shaft of the motor penetrates through the cover plate and is fixedly connected with the storage rack. The plating solution is injected into the plating bath, the ceramic carrier plate to be plated is arranged on the storage rack, then the telescopic device drives the cover plate to descend, after the cover plate is tightly covered with the plating bath, the plating solution in the ceramic carrier plate to be plated and the plating bath is electrified to start plating, in the plating process, the motor is started to drive the storage rack to rotate, on one hand, the storage rack rotates to stir the plating solution, so that the concentration of the plating solution in the plating bath is uniform and consistent, and on the other hand, the storage rack drives the ceramic carrier plate to slowly rotate, and the ceramic substrate is convenient to uniformly plate.

In carrying out the present application, the inventors have found that at least the following problems exist in this technology: before electroplating, the telescopic device drives the cover plate to move downwards, after the cover plate is tightly covered with the electroplating tank, electroplating is started to electrify electroplating liquid in the electroplating tank, after electroplating is completed, the telescopic device drives the cover plate to move upwards, when the cover plate is a certain distance away from the top of the electroplating tank, the ceramic carrier plate is separated from the electroplating liquid, and then the ceramic carrier plate is taken out from the storage rack by a worker.

Disclosure of Invention

In order to improve ceramic carrier plate electroplating efficiency and shorten the ceramic carrier plate electroplating period, the application provides an electroplating tool for manufacturing a ceramic carrier plate.

The application provides a ceramic support plate makes with electroplating frock adopts following technical scheme:

the utility model provides a pottery carrier plate makes with electroplating frock, includes the frame, fixed a set of guide bar that sets up in the frame, cover on the guide bar is established uide bushing and lower uide bushing, go up uide bushing and be located down uide bushing top, go up fixedly between the uide bushing and set up the apron, fixed electroplating pool that sets up between the uide bushing down, the apron is located electroplating pool top, the apron bottom sets up the supporter, set up lifting unit between apron and the frame, lifting unit is used for driving the apron and goes up and down, set up lifting unit down between electroplating pool and the frame, lifting unit is used for driving electroplating pool and goes up and down, fixed driving motor that sets up in the frame, driving motor is used for driving lifting unit and lifting unit down.

Through adopting above-mentioned technical scheme, pour into plating solution into in the electroplating bath, wait to plate ceramic carrier plate and install on the supporter, then start driving motor and make driving motor's output shaft corotation, driving motor drives lifting unit and lower lifting unit action, lifting unit makes apron along guide bar downwardly moving, lower lifting unit makes the electrolytic bath upwards move along the guide bar, after apron and the electroplating Chi Gaijin, it begins electroplating to wait to electroplate the plating solution circular telegram in ceramic carrier plate and the electroplating bath, after electroplating is accomplished, make driving motor's output shaft reversal, driving motor drives lifting unit and lower lifting unit action, lifting unit makes apron upwards move along the guide bar, lower lifting unit makes the electrolytic bath follow guide bar downwardly moving, and then make apron drive ceramic carrier plate and electroplating bath separation, when waiting to plate ceramic carrier plate gets into in the plating solution, apron and electroplating bath relative motion, when ceramic carrier plate is taken out by the electroplating solution, apron and electroplating bath back to back, reduce apron and electroplating bath separation and closure time, improve ceramic carrier plate electroplating efficiency, shorten ceramic carrier plate electroplating cycle.

Preferably, the upper lifting assembly comprises an upper sliding seat, an upper sliding block, an upper screw rod and an upper connecting arm, wherein the upper sliding seat is fixedly connected with the frame, an upper sliding groove is formed in the bottom of the upper sliding seat, the upper screw rod is rotationally arranged in the upper sliding groove, the upper sliding block is slidingly arranged in the upper sliding groove, the upper sliding block is in threaded connection with the upper screw rod, one end of the upper connecting arm is rotationally connected with the upper sliding block, and the other end of the upper connecting arm is rotationally connected with the top wall of the cover plate.

Through adopting above-mentioned technical scheme, driving motor forward rotation drives the lead screw and rotates clockwise, go up the lead screw and rotate clockwise and drive the slider and move from being close to driving motor one end to keeping away from driving motor one end along last spout, go up the slider and drive when going up the linking arm and remove, go up the linking arm and take place to rotate with last slider, and then go up linking arm and apron and take place to rotate, and make the apron downwardly moving, driving motor reverse rotation drives the anticlockwise rotation of lead screw, go up the slider and drive and move along last spout by keeping away from driving motor one end to being close to driving motor one end, go up the slider and drive when going up the linking arm and move, go up linking arm and apron take place to rotate, and make the apron upwards move.

Preferably, a group of limiting grooves are formed in the upper sliding groove, the limiting grooves are arranged oppositely, limiting blocks are slidably arranged in the limiting grooves, and the limiting blocks are fixedly connected with the upper sliding block.

Through adopting above-mentioned technical scheme, when last slider removes along last spout, go up the slider and drive the stopper and remove along the spacing groove, because stopper diapire and spacing inslot wall butt each other, and the stopper is connected with last slider, so go up the slide and provide holding power to the slider, and then reduce the effort that goes up the lead screw and receive, be convenient for go up the lead screw rotation, reduce the cracked condition of lead screw.

Preferably, one end of the upper screw rod penetrates through the upper sliding seat, an upper driving wheel is fixedly arranged at one end of the upper screw rod, which is positioned outside the upper sliding seat, an upper driving wheel is sleeved on an output shaft of the driving motor, the upper driving wheel is fixedly connected with an output shaft of the driving motor, and an upper driving belt is sleeved on the upper driving wheel and the upper driving wheel together.

By adopting the technical scheme, the driving motor rotates forward to drive the upper driving wheel to rotate clockwise, the upper driving wheel rotates clockwise to drive the upper driving belt to move clockwise, the upper driving belt moves clockwise to drive the upper driving wheel to rotate clockwise, the upper driving wheel rotates clockwise to drive the upper screw rod to rotate clockwise, the driving motor rotates reversely to drive the upper driving wheel to rotate anticlockwise, the upper driving wheel rotates anticlockwise to drive the upper driving belt to move anticlockwise, and the upper driving belt moves anticlockwise to drive the upper driving wheel to rotate anticlockwise, and the upper driving wheel rotates anticlockwise to drive the upper screw rod to rotate anticlockwise.

Preferably, the lower lifting assembly comprises a left sliding seat, a group of left sliding blocks, a left screw rod and a group of left connecting arms, wherein the left sliding seat is fixedly connected with the frame, a left sliding groove is formed in the top of the left sliding seat, the left screw rod is rotationally arranged in the left sliding groove, the left screw rod comprises a left thread section I and a left thread section II, the left sliding blocks are slidingly arranged in the left sliding groove, one of the left sliding blocks is in threaded connection with the left thread section I, the other of the left sliding blocks is in threaded connection with the left thread section II, one end of the left connecting arm is rotationally connected with one of the left sliding blocks, one end of the left connecting arm is rotationally connected with the other left sliding block, and one end of the left connecting arm, which is far away from the left sliding blocks, is rotationally connected with the side wall of the electroplating pool.

Through adopting above-mentioned technical scheme, driving motor corotation drives left lead screw clockwise rotation, left lead screw clockwise rotation drives left slider and moves from being close to driving motor one end to keeping away from driving motor one end along left spout, left slider drives left linking arm and left slider and takes place to rotate when moving, and then left linking arm and electroplating pool take place to rotate, and make electroplating pool upwards move, driving motor reversal drives left lead screw anticlockwise rotation, left lead screw anticlockwise rotation drives left slider and moves from keeping away from driving motor one end to being close to driving motor one end along left spout, left slider drives left linking arm and left slider and takes place to rotate when moving, and then left linking arm and electroplating pool take place to rotate, and make electroplating pool down move.

Preferably, one end of the left screw rod penetrates through the left sliding seat, a left driving wheel is fixedly arranged at one end of the left screw rod, which is positioned outside the left sliding seat, a left driving wheel is sleeved on an output shaft of the driving motor, the left driving wheel is fixedly connected with an output shaft of the driving motor, and a left driving belt is sleeved on the left driving wheel and the left driving wheel.

Through adopting above-mentioned technical scheme, driving motor forward rotation drives left drive wheel clockwise rotation, and left drive wheel clockwise rotation drives left drive belt clockwise movement, and left drive belt clockwise movement drives left drive wheel clockwise rotation, and left drive wheel clockwise rotation drives left lead screw clockwise rotation, and driving motor reversal drives left drive wheel anticlockwise rotation, and left drive wheel anticlockwise rotation drives left drive belt anticlockwise movement, and left drive belt anticlockwise movement drives left drive wheel anticlockwise rotation, and left drive wheel anticlockwise rotation drives left lead screw anticlockwise rotation.

Preferably, the lower lifting assembly further comprises a right sliding seat, a group of right sliding blocks, a right screw rod and a group of right connecting arms, wherein the right sliding seat is fixedly connected with the frame, a right sliding groove is formed in the top of the right sliding seat, the right screw rod is rotationally arranged in the right sliding groove, the right screw rod comprises a first right thread section and a second right thread section, the right sliding blocks are slidingly arranged in the right sliding groove, one of the right sliding blocks is in threaded connection with the first right thread section, the other of the right sliding blocks is in threaded connection with the second right thread section, one end of each right connecting arm is rotationally connected with one of the right sliding blocks, one end of each right connecting arm is rotationally connected with the other right sliding block, and one end of each right connecting arm, which is far away from the right sliding blocks, is rotationally connected with the side wall of the electroplating pool.

Through adopting above-mentioned technical scheme, driving motor forward rotation drives right lead screw clockwise rotation, right lead screw clockwise rotation drives right slider and moves from being close to driving motor one end to keeping away from driving motor one end along right spout, right slider drives right linking arm and right slider and takes place to rotate when moving, and then right linking arm and electroplating pool take place to rotate, and make electroplating pool upwards move, driving motor reverse rotation drives right lead screw anticlockwise rotation, right lead screw anticlockwise rotation drives right slider and moves from keeping away from driving motor one end to being close to driving motor one end along right spout, right slider drives right linking arm and right slider and takes place to rotate when moving, and then right linking arm and electroplating pool take place to rotate, and make electroplating pool down move.

Preferably, one end of the right screw rod penetrates through the right sliding seat, a right driving wheel is fixedly arranged at one end of the right screw rod, which is positioned outside the right sliding seat, a right driving wheel is sleeved on an output shaft of the driving motor, the right driving wheel is fixedly connected with an output shaft of the driving motor, and a right driving belt is sleeved on the right driving wheel and the right driving wheel.

By adopting the technical scheme, the driving motor rotates forward to drive the right driving wheel to rotate clockwise, the right driving wheel rotates clockwise to drive the right driving belt to move clockwise, the right driving belt moves clockwise to drive the right driving wheel to rotate clockwise, the right driving wheel rotates clockwise to drive the right screw rod to rotate clockwise, the driving motor rotates reversely to drive the right driving wheel to rotate anticlockwise, the right driving wheel rotates anticlockwise to drive the right driving belt to move anticlockwise, and the right driving belt moves anticlockwise to drive the right driving wheel to rotate anticlockwise to drive the right screw rod to rotate anticlockwise.

In summary, the present application includes at least one of the following beneficial technical effects:

1. by arranging the frame, the guide rod, the upper guide sleeve, the lower guide sleeve, the cover plate, the electroplating pool, the storage rack, the upper lifting assembly, the lower lifting assembly and the driving motor, the separation and closing time of the cover plate and the electroplating pool is reduced, the electroplating efficiency of the ceramic carrier plate is improved, and the electroplating period of the ceramic carrier plate is shortened;

2. the cover plate is driven to lift by arranging an upper sliding seat, an upper sliding block, an upper screw rod, an upper connecting arm and an upper sliding groove;

3. through setting up left slide, right slide, left slider, right slider, left lead screw, right lead screw, left linking arm, right linking arm, left spout and right spout, drive the electroplating tank and go up and down.

Drawings

Fig. 1 is a schematic structural diagram of an electroplating tool for manufacturing a ceramic carrier in an embodiment of the application.

Fig. 2 is a cross-sectional view of an electroplating tool for manufacturing a ceramic carrier in an embodiment of the application.

Fig. 3 is a schematic diagram showing a connection relationship between a driving motor and an upper screw in the embodiment of the present application.

Fig. 4 is a cross-sectional view showing the positional relationship of the limiting groove and the limiting block in the embodiment of the present application.

Fig. 5 is a cross-sectional view showing the positional relationship of the left and right carriages in the embodiment of the present application.

Fig. 6 is a schematic diagram showing a left screw and a right screw in an embodiment of the present application.

Fig. 7 is a schematic diagram showing a connection relationship between a driving motor and a left screw in the embodiment of the present application.

Fig. 8 is a schematic diagram showing a connection relationship between a driving motor and a right screw in the embodiment of the present application.

Reference numerals illustrate: 1. a frame; 11. a guide rod; 2. a cover plate; 21. an upper guide sleeve; 22. a commodity shelf; 3. an electroplating pool; 31. a lower guide sleeve; 4. an upper lifting assembly; 41. an upper slider; 42. an upper slider; 43. feeding a screw rod; 44. an upper connecting arm; 45. an upper chute; 451. a limit groove; 452. a limiting block; 5. a lower lifting assembly; 6. a left chute; 61. a left slide; 62. a left slider; 63. a left screw rod; 631. left thread section one; 632. a left thread section II; 64. a left connecting arm; 7. a right chute; 71. a right slide; 72. a right slider; 73. a right screw rod; 731. right thread section one; 732. a right thread section II; 74. a right connecting arm; 8. a driving motor; 81. an upper driving wheel; 811. an upper driving wheel; 812. an upper drive belt; 82. a left driving wheel; 821. a left driving wheel; 822. a left drive belt; 83. a right driving wheel; 831. a right driving wheel; 832. right drive belt.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-8.

The embodiment of the application discloses an electroplating tool for manufacturing a ceramic carrier plate. Referring to fig. 1, it includes a frame 1, and a set of guide bars 11 are installed on the frame 1 in a height direction. The upper guide sleeve 21 and the lower guide sleeve 31 are sleeved on the guide rod 11, the upper guide sleeve 21 and the lower guide sleeve 31 are both in sliding connection with the guide rod 11, and the upper guide sleeve 21 is positioned above the lower guide sleeve 31. A cover plate 2 is arranged between the upper guide sleeves 21, an electroplating pool 3 is arranged between the lower guide sleeves 31, the cover plate 2 is positioned above the electroplating pool 3, and a storage rack 22 is arranged at the bottom of the cover plate 2. An upper lifting assembly 4 is arranged between the cover plate 2 and the frame 1, and the upper lifting assembly 4 is used for driving the cover plate 2 to lift. A lower lifting component 5 is arranged between the electroplating pool 3 and the frame 1, and the lower lifting component 5 is used for driving the electroplating pool 3 to lift. A driving motor 8 is arranged on the frame 1, and the driving motor 8 is used for driving the upper lifting assembly 4 and the lower lifting assembly 5. Electroplating solution is injected into the electroplating pool 3, and the ceramic carrier plate to be plated is arranged on the commodity shelf 22. Then, the driving motor 8 is started to enable the output shaft of the driving motor 8 to rotate positively, the driving motor 8 drives the upper lifting assembly 4 and the lower lifting assembly 5 to act, the upper lifting assembly 4 enables the cover plate 2 to move downwards along the guide rod 11, and the lower lifting assembly 5 enables the electrolytic cell to move upwards along the guide rod 11. After the cover plate 2 and the electroplating pool 3 are tightly covered, the ceramic carrier plate to be plated and the electroplating liquid in the electroplating pool 3 are electrified to start electroplating. After electroplating is completed, the output shaft of the driving motor 8 is reversed, the driving motor 8 drives the upper lifting assembly 4 and the lower lifting assembly 5 to act, the upper lifting assembly 4 enables the cover plate 2 to move upwards along the guide rod 11, the lower lifting assembly 5 enables the electrolytic cell to move downwards along the guide rod 11, and then the cover plate 2 drives the ceramic carrier plate to be separated from the electroplating cell 3. When the ceramic carrier plate to be plated enters the electroplating liquid, the cover plate 2 and the electroplating pool 3 move relatively, when the ceramic carrier plate is taken out by the electroplating liquid, the cover plate 2 and the electroplating pool 3 move back to back, the separation and closing time of the cover plate 2 and the electroplating pool 3 are reduced, the electroplating efficiency of the ceramic carrier plate is improved, and the electroplating period of the ceramic carrier plate is shortened.

In order to raise and lower the cover plate 2, referring to fig. 1 to 4, the upper raising and lowering assembly 4 includes an upper slider 41, an upper slider 42, an upper screw 43, and an upper connection arm 44. The upper slide 41 is located above the cover plate 2, and the top wall of the upper slide 41 is welded with the frame 1. An upper sliding groove 45 is formed in the bottom of the upper sliding seat 41 along the length direction, one end, away from the driving motor 8, of the upper lead screw 43 is rotationally connected with the inner wall of the upper sliding groove 45, one end, close to the driving motor 8, of the upper lead screw 43 penetrates through the upper sliding seat 41, and the side wall of the upper lead screw 43 is rotationally connected with the upper sliding seat 41 through a bearing. The upper sliding block 42 is in threaded connection with the upper screw rod 43, the upper sliding block 42 is slidably arranged in the upper sliding groove 45, and the outer wall of the upper sliding block 42 is mutually attached to the inner wall of the upper sliding groove 45. A group of limiting grooves 451 are formed in the upper sliding groove 45, the limiting grooves 451 are oppositely arranged, limiting blocks 452 are slidably arranged in the limiting grooves 451, the outer walls of the limiting blocks 452 are mutually attached to the inner walls of the limiting grooves 451, and the limiting blocks 452 are mutually welded with the upper sliding blocks 42. One end of the upper connecting arm 44 is rotatably connected with the upper slider 42, and the other end of the upper connecting arm 44 is rotatably connected with the top wall of the cover plate 2. The driving motor 8 rotates forward to drive the upper screw rod 43 to rotate clockwise, and the upper screw rod 43 rotates clockwise to drive the upper sliding block 42 to move along the upper sliding groove 45 from one end close to the driving motor 8 to one end far away from the driving motor 8. The upper slider 42 drives the upper connecting arm 44 to move, and at the same time, the upper connecting arm 44 and the upper slider 42 rotate, so that the upper connecting arm 44 and the cover plate 2 rotate, and the cover plate 2 moves downwards. The driving motor 8 rotates reversely to drive the upper screw rod 43 to rotate anticlockwise, and the upper screw rod 43 rotates anticlockwise to drive the upper sliding block 42 to move along the upper sliding groove 45 from one end far away from the driving motor 8 to one end close to the driving motor 8. The upper slider 42 drives the upper connecting arm 44 to move, and at the same time, the upper connecting arm 44 and the upper slider 42 rotate, so that the upper connecting arm 44 and the cover plate 2 rotate, and the cover plate 2 moves upwards. When the upper slider 42 moves along the upper chute 45, the upper slider 42 drives the stopper 452 to move along the stopper slot 451. Because stopper 452 diapire and the mutual butt of spacing groove 451 inner wall, and stopper 452 is connected with last slider 42, so go up slide 41 and provide holding power to slider 42, and then reduce the effort that goes up lead screw 43 and receive, be convenient for go up lead screw 43 rotation, reduce the cracked condition of lead screw 43.

In order to drive the upper lift assembly 4 by the drive motor 8, referring to fig. 1 to 3, an upper drive wheel 81 is sleeved on an output shaft of the drive motor 8, and the upper drive wheel 81 and the output shaft of the drive motor 8 are welded to each other. An upper driving wheel 811 is welded on one end of the upper screw 43 outside the upper sliding seat 41, and an upper driving belt 812 is sleeved on the upper driving wheel 81 and the upper driving wheel 811 together. The driving motor 8 rotates forward to drive the upper driving wheel 81 to rotate clockwise, the upper driving wheel 81 rotates clockwise to drive the upper driving belt 812 to move clockwise, the upper driving belt 812 moves clockwise to drive the upper driving wheel 811 to rotate clockwise, and the upper driving wheel 811 rotates clockwise to drive the upper screw 43 to rotate clockwise. The driving motor 8 rotates reversely to drive the upper driving wheel 81 to rotate anticlockwise, the upper driving wheel 81 rotates anticlockwise to drive the upper driving belt 812 to move anticlockwise, the upper driving belt 812 moves anticlockwise to drive the upper driving wheel 811 to rotate anticlockwise, and the upper driving wheel 811 rotates anticlockwise to drive the upper screw rod 43 to rotate anticlockwise.

In order to drive the plating tank 3 to rise and fall, referring to fig. 5 and 6, the lower elevation assembly 5 includes a left slider 61, a set of left sliders 62, a left screw 63, a set of left connecting arms 64, a right slider 71, a set of right sliders 72, a right screw 73, and a set of right connecting arms 74, the left screw 63 includes a left thread section one 631 and a left thread section two 632, and the right screw 73 includes a right thread section one 731 and a right thread section two 732. The left slide seat 61 and the right slide seat 71 are all positioned below the electroplating pool 3, the bottom wall of the left slide seat 61 and the bottom wall of the right slide seat 71 are all welded with the frame 1, the left slide groove 6 is formed in the top of the left slide seat 61, and the right slide groove 7 is formed in the top of the right slide seat 71. The left screw rod 63 is rotatably arranged in the left sliding groove 6, the left sliding block 62 is slidably arranged in the left sliding groove 6, one left sliding block 62 is in threaded connection with the first left threaded section 631, and the other left sliding block 62 is in threaded connection with the second left threaded section 632. One end of one left connecting arm 64 is rotatably connected with one left sliding block 62, one end of the other left connecting arm 64 is rotatably connected with the other left sliding block 62, and one end of the left connecting arm 64 far away from the left sliding block 62 is rotatably connected with the side wall of the electroplating pool 3. The right screw rod 73 is rotatably arranged in the right sliding groove 7, the right sliding block 72 is slidably arranged in the right sliding groove 7, one right sliding block 72 is in threaded connection with the first right threaded section 731, and the other right sliding block 72 is in threaded connection with the second right threaded section 732. One end of one right connecting arm 74 is rotatably connected with one right slider 72, one end of the other right connecting arm 74 is rotatably connected with the other right slider 72, and one end of the right connecting arm 74 far away from the right slider 72 is rotatably connected with the side wall of the electroplating pool 3. The driving motor 8 rotates forward to drive the left screw 63 and the right screw 73 to rotate clockwise, the left screw 63 rotates clockwise to drive the left sliding block 62 to move along the left sliding groove 6 from one end close to the driving motor 8 to one end far away from the driving motor 8, and the right screw 73 rotates clockwise to drive the right sliding block 72 to move along the right sliding groove 7 from one end close to the driving motor 8 to one end far away from the driving motor 8. The left slider 62 drives the left connecting arm 64 to move, and simultaneously, the left connecting arm 64 and the left slider 62 rotate, so that the left connecting arm 64 and the electroplating pool 3 rotate, and the right slider 72 drives the right connecting arm 74 to move, and simultaneously, the right connecting arm 74 and the right slider 72 rotate, so that the right connecting arm 74 and the electroplating pool 3 rotate, and further, the electroplating pool 3 moves upwards. The driving motor 8 rotates reversely to drive the left screw rod 63 and the right screw rod 73 to rotate anticlockwise, the left screw rod 63 rotates anticlockwise to drive the left sliding block 62 to move along the left sliding groove 6 from one end far away from the driving motor 8 to one end close to the driving motor 8, and the right screw rod 73 rotates anticlockwise to drive the right sliding block 72 to move along the right sliding groove 7 from one end far away from the driving motor 8 to one end close to the driving motor 8. The left slider 62 drives the left connecting arm 64 to move, and simultaneously, the left connecting arm 64 and the left slider 62 rotate, so that the left connecting arm 64 and the electroplating pool 3 rotate, and the right slider 72 drives the right connecting arm 74 to move, and simultaneously, the right connecting arm 74 and the right slider 72 rotate, so that the right connecting arm 74 and the electroplating pool 3 rotate, and further, the electroplating pool 3 moves downwards.

In order to drive the lower lift assembly 5 by the driving motor 8, referring to fig. 6 to 8, one end of the left screw 63 near the driving motor 8 penetrates the left slider 61, and one end of the right screw 73 near the driving motor 8 penetrates the right slider 71. The left screw rod 63 is provided with a left driving wheel 821 at the outer end of the left sliding seat 61, and the right screw rod 73 is provided with a right driving wheel 831 at the outer end of the right sliding seat 71. The left driving wheel 82 and the right driving wheel 83 are sleeved on the output shaft of the driving motor 8, and the left driving wheel 82 and the right driving wheel 83 are welded with the output shaft of the driving motor 8. A left driving belt 822 is sleeved on the left driving wheel 82 and the left driving wheel 821 together, and a right driving belt 832 is sleeved on the right driving wheel 83 and the right driving wheel 831 together. The driving motor 8 rotates forward to drive the left driving wheel 82 and the right driving wheel 83 to rotate clockwise, the left driving wheel 82 rotates clockwise to drive the left driving belt 822 to move clockwise, and the right driving wheel 83 rotates clockwise to drive the right driving belt 832 to move clockwise. The clockwise movement of the left drive belt 822 drives the left drive wheel 821 to rotate clockwise, and the clockwise movement of the right drive belt 832 drives the right drive wheel 831 to rotate clockwise. The left driving wheel 821 rotates clockwise to drive the left screw 63 to rotate clockwise, and the right driving wheel 831 rotates clockwise to drive the right screw 73 to rotate clockwise. The driving motor 8 rotates reversely to drive the left driving wheel 82 and the right driving wheel 83 to rotate anticlockwise, the left driving wheel 82 rotates anticlockwise to drive the left driving belt 822 to move anticlockwise, and the right driving wheel 83 rotates anticlockwise to drive the right driving belt 832 to move anticlockwise. The left drive belt 822 moves counterclockwise to drive the left drive wheel 821 to rotate counterclockwise, and the right drive belt 832 moves counterclockwise to drive the right drive wheel 831 to rotate counterclockwise. The left driving wheel 821 rotates counterclockwise to drive the left screw 63 to rotate counterclockwise, and the right driving wheel 831 rotates counterclockwise to drive the right screw 73 to rotate counterclockwise.

The implementation principle of the electroplating tool for manufacturing the ceramic carrier plate is as follows: electroplating solution is injected into the electroplating pool 3, and the ceramic carrier plate to be plated is arranged on the commodity shelf 22. Then, the driving motor 8 is started to enable the output shaft of the driving motor 8 to rotate positively, the driving motor 8 drives the upper lifting assembly 4 and the lower lifting assembly 5 to act, the upper lifting assembly 4 enables the cover plate 2 to move downwards along the guide rod 11, and the lower lifting assembly 5 enables the electrolytic cell to move upwards along the guide rod 11. After the cover plate 2 and the electroplating pool 3 are tightly covered, the ceramic carrier plate to be plated and the electroplating liquid in the electroplating pool 3 are electrified to start electroplating. After electroplating is completed, the output shaft of the driving motor 8 is reversed, the driving motor 8 drives the upper lifting assembly 4 and the lower lifting assembly 5 to act, the upper lifting assembly 4 enables the cover plate 2 to move upwards along the guide rod 11, the lower lifting assembly 5 enables the electrolytic cell to move downwards along the guide rod 11, and then the cover plate 2 drives the ceramic carrier plate to be separated from the electroplating cell 3. When the ceramic carrier plate to be plated enters the electroplating liquid, the cover plate 2 and the electroplating pool 3 move relatively, when the ceramic carrier plate is taken out by the electroplating liquid, the cover plate 2 and the electroplating pool 3 move back to back, the separation and closing time of the cover plate 2 and the electroplating pool 3 are reduced, the electroplating efficiency of the ceramic carrier plate is improved, and the electroplating period of the ceramic carrier plate is shortened.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. The utility model provides a ceramic support plate makes with electroplating frock, includes frame (1), its characterized in that: the electroplating device comprises a rack (1), wherein a group of guide rods (11) are fixedly arranged on the rack (1), an upper guide sleeve (21) and a lower guide sleeve (31) are sleeved on the guide rods (11), the upper guide sleeve (21) is located above the lower guide sleeve (31), a cover plate (2) is fixedly arranged between the upper guide sleeve (21), an electroplating pool (3) is fixedly arranged between the lower guide sleeve (31), the cover plate (2) is located above the electroplating pool (3), a storage rack (22) is arranged at the bottom of the cover plate (2), an upper lifting assembly (4) is arranged between the cover plate (2) and the rack (1), the upper lifting assembly (4) is used for driving the cover plate (2) to lift, a lower lifting assembly (5) is arranged between the electroplating pool (3) and the rack (1), a driving motor (8) is fixedly arranged on the rack (1), and the driving motor (8) is used for driving the upper lifting assembly (4) and the lower lifting assembly (5).

2. The electroplating tool for manufacturing the ceramic carrier plate according to claim 1, wherein: the upper lifting assembly (4) comprises an upper sliding seat (41), an upper sliding block (42), an upper screw rod (43) and an upper connecting arm (44), wherein the upper sliding seat (41) is fixedly connected with the frame (1), an upper sliding groove (45) is formed in the bottom of the upper sliding seat (41), the upper screw rod (43) is rotationally arranged in the upper sliding groove (45), the upper sliding block (42) is slidingly arranged in the upper sliding groove (45), the upper sliding block (42) is in threaded connection with the upper screw rod (43), one end of the upper connecting arm (44) is rotationally connected with the upper sliding block (42), and the other end of the upper connecting arm (44) is rotationally connected with the top wall of the cover plate (2).

3. The electroplating tool for manufacturing the ceramic carrier plate according to claim 2, wherein: a group of limiting grooves (451) are formed in the upper sliding groove (45), the limiting grooves (451) are oppositely arranged, limiting blocks (452) are slidably arranged in the limiting grooves (451), and the limiting blocks (452) are fixedly connected with the upper sliding blocks (42).

4. The electroplating tool for manufacturing the ceramic carrier plate according to claim 2, wherein: the upper screw rod (43) one end runs through the upper sliding seat (41), an upper driving wheel (811) is fixedly arranged at one outer end of the upper screw rod (43), an upper driving wheel (81) is sleeved on an output shaft of the driving motor (8), the upper driving wheel (81) is fixedly connected with an output shaft of the driving motor (8), and an upper driving belt (812) is sleeved on the upper driving wheel (81) and the upper driving wheel (811) together.

5. The electroplating tool for manufacturing the ceramic carrier plate according to claim 1, wherein: the lower lifting assembly (5) comprises a left sliding seat (61), a group of left sliding blocks (62), a left screw rod (63) and a group of left connecting arms (64), wherein the left sliding seat (61) is fixedly connected with a rack (1), the top of the left sliding seat (61) is provided with a left sliding groove (6), the left screw rod (63) is rotationally arranged in the left sliding groove (6), the left screw rod (63) comprises a left threaded section one (631) and a left threaded section two (632), the left sliding blocks (62) are slidingly arranged in the left sliding groove (6), one of the left sliding blocks (62) is in threaded connection with the left threaded section one (631), the other left sliding block (62) is in threaded connection with the left threaded section two (632), one end of the left connecting arm (64) is rotationally connected with one of the left sliding blocks (62), and the other end of the left connecting arm (64) is rotationally connected with the side wall of the electroplating pool (3), and one end of the left sliding block (64) is far away from the left sliding block (62).

6. The electroplating tool for manufacturing the ceramic carrier plate according to claim 5, wherein: left lead screw (63) one end runs through left slide (61), left lead screw (63) are located fixed left drive wheel (821) that sets up on the outer one end of left slide (61), cover on the output shaft of driving motor (8) is established left drive wheel (82), left drive wheel (82) and the output shaft fixed connection of driving motor (8), cover jointly on left drive wheel (82) and left drive wheel (821) and establish left driving belt (822).

7. The electroplating tool for manufacturing the ceramic carrier plate according to claim 5, wherein: the lower lifting assembly (5) further comprises a right sliding seat (71), a group of right sliding blocks (72), a right screw rod (73) and a group of right connecting arms (74), wherein the right sliding seat (71) is fixedly connected with the frame (1), the right sliding groove (7) is formed in the top of the right sliding seat (71), the right screw rod (73) is rotationally arranged in the right sliding groove (7), the right sliding rod (73) comprises a right threaded section I (731) and a right threaded section II (732), the right sliding blocks (72) are slidingly arranged in the right sliding groove (7), one of the right sliding blocks (72) is in threaded connection with the right threaded section I (731), the other right sliding block (72) is in threaded connection with the right threaded section II (732), one end of the right connecting arm (74) is rotationally connected with one of the right sliding blocks (72), and the other end of the right connecting arm (74) is rotationally connected with the side wall of the electroplating pool (3) away from one end of the right sliding block (72).

8. The electroplating tool for manufacturing the ceramic carrier plate according to claim 7, wherein: right lead screw (73) one end runs through right slide (71), right lead screw (73) are located fixed right drive wheel (831) that sets up on the outer one end of right slide (71), right drive wheel (83) are established to the cover on the output shaft of driving motor (8), right drive wheel (83) and the output shaft fixed connection of driving motor (8), right driving belt (832) are established to common cover on right drive wheel (83) and right drive wheel (831).