CN221101883U - Silica gel cap cover capacitor machine - Google Patents

Abstract

The utility model discloses a silica gel cap sleeve capacitor machine which comprises a rack, and a feeding mechanism, a turntable, a feeding mechanism, a dispensing mechanism, a vibrating disc, a silica gel cap assembling mechanism, a pressure maintaining mechanism and a discharging mechanism which are respectively connected with the rack; the turntable is provided with a clamp; the feeding mechanism is used for automatically providing a capacitor, the feeding mechanism is arranged on one side of the feeding mechanism and used for transferring the capacitor on the feeding mechanism to the clamp, and the vibration disc is used for automatically providing a silica gel cap; the glue dispensing mechanism is used for automatically dripping glue to the top surface of the capacitor on the clamp, the silica gel cap assembling mechanism is used for automatically taking out the silica gel cap from the vibration disc and sleeving the silica gel cap on the capacitor, and the pressure maintaining mechanism is used for applying pressure to the top surface of the capacitor sleeved with the silica gel cap; the utility model mainly solves the technical problem of how to automatically cover the capacitor with the silica gel cap.

Description

Silica gel cap cover capacitor machine

Technical Field

The utility model relates to the field of capacitor production and manufacturing, in particular to a silica gel cap sleeve capacitor machine.

Background

As shown in fig. 1, a portion of the capacitor 80 in the prior art needs to be sleeved into a silicone cap 90, and the silicone cap 90 is used for protecting the capacitor from being damaged by the external environment. For example, the silicone cap 90 can prevent the capacitor 80 from being oxidized and corroded, and can also prevent the capacitor 80 from being damaged by impact or friction. At present, the operation of sleeving the silica gel cap 90 is still mostly completed by manual operation, wherein glue is firstly dripped on the surface of the capacitor 80 or the inner wall of the silica gel cap 90 by manual operation, then the silica gel cap 90 is sleeved on the outer wall of the capacitor 80, and after the glue is solidified, the assembly operation is completed. The manual operation has the defect of lower efficiency, and the quality difference of assembly is larger, so that the production requirement of the capacitor on high efficiency and high quality can not be met.

Disclosure of utility model

The utility model aims to provide a silica gel cap sleeve capacitor machine, which mainly solves the technical problem of how to automatically sleeve a silica gel cap on a capacitor.

To achieve the purpose, the utility model adopts the following technical scheme:

a silica gel cap sleeve capacitor machine comprises a frame, and a feeding mechanism, a turntable, a feeding mechanism, a dispensing mechanism, a vibrating disc, a silica gel cap assembly mechanism, a pressure maintaining mechanism and a discharging mechanism which are respectively connected with the frame;

the turntable can rotate relative to the rack, a clamp for clamping the capacitor is arranged on the turntable, and the clamp is driven to rotate relative to the rack when the turntable rotates;

The feeding mechanism is used for automatically providing a capacitor, the feeding mechanism is arranged on one side of the feeding mechanism and used for transferring the capacitor on the feeding mechanism to a clamp of the turntable, and the vibration disk is used for automatically providing the silica gel cap;

The device comprises a rotating disc, a silica gel cap assembly mechanism, a pressure maintaining mechanism, a discharging mechanism, a dispensing mechanism and a vibration disc, wherein the dispensing mechanism, the silica gel cap assembly mechanism, the pressure maintaining mechanism and the discharging mechanism are sequentially arranged on one side of the rotating disc along the rotating direction of the rotating disc, the dispensing mechanism is used for automatically dripping glue on the top surface of a capacitor on the clamp, the silica gel cap assembly mechanism is used for automatically taking out a silica gel cap from the vibration disc and sleeving the silica gel cap on the capacitor on the clamp, the pressure maintaining mechanism is used for applying pressure to the top surface of the capacitor sleeved with the silica gel cap, and the discharging mechanism is used for discharging the capacitor on the clamp to a preset position outwards.

In one of the technical schemes, the silica gel cap sleeve capacitor machine further comprises a pin shearing mechanism connected with the frame, the pin shearing mechanism is located on the moving path of the blanking mechanism, and the pin shearing mechanism is used for cutting pins of the capacitor to a preset length.

In one of the technical schemes, the feeding mechanism comprises a seat body, a braid, a poking motor and a poking wheel;

The base is connected with the frame, a guide groove for allowing the braid to enter and be sent out is formed in the base, a plurality of hole sites are formed in the braid along the length direction, the braid is used for bonding pins of a capacitor, a plurality of protruding blocks are arranged on the radial outer wall of the poking wheel in a protruding mode, the poking motor is respectively connected with the base and the poking wheel and used for driving the poking wheel to rotate, and when the poking wheel rotates, the protruding blocks are embedded into the hole sites of the braid so as to drive the braid to move in the guide groove;

The silica gel cap sleeve capacitor machine further comprises a pin cutting mechanism connected with the frame, wherein the pin cutting mechanism is arranged on one side of the dial wheel and used for cutting off pins of the capacitor, so that the pins of the capacitor can be separated from the braid.

In one of the technical schemes, a middle swivel mount is arranged at the adjacent position of the silica gel cap assembly mechanism, and the silica gel cap assembly mechanism comprises a first driver, a second driver, a rotary clamping cylinder and a clamping jaw cylinder;

The rotary clamping cylinder and the clamping jaw cylinder are connected with the second driver, the second driver is used for driving the rotary clamping cylinder and the clamping jaw cylinder to move along the vertical direction together, the first driver is connected with the frame and the second driver respectively and used for driving the second driver, the rotary clamping cylinder and the clamping jaw cylinder to move along a single shaft or multiple shafts together, the rotary clamping cylinder is used for taking out a silica gel cap from the vibration disc and driving the silica gel cap to rotate to a preset angle, the transfer seat is used for receiving the silica gel cap from the rotary clamping cylinder, and the clamping jaw cylinder is used for clamping the silica gel cap from the transfer seat and is used for sleeving the silica gel cap onto a capacitor of the clamp under the combined driving of the first driver and the second driver.

In one of the technical schemes, a positioning datum plane is arranged on the middle rotary seat, a third driver is fixed on the middle rotary seat, a calibration block is connected to the third driver, the third driver is used for driving the calibration block to be close to or far away from the positioning datum plane, and the positioning datum plane and the calibration block are used for clamping the silica gel cap together so as to calibrate the position of the silica gel cap on the transfer seat.

In one of the technical schemes, the pressure maintaining mechanism comprises a fourth driver, a connecting seat, an elastic piece and a pressing block;

The elastic piece is connected between the connecting seat and the pressing block, the pressing block has a downward movement trend due to the elasticity of the elastic piece, the fourth driver is connected with the connecting seat and used for driving the connecting seat, the elastic piece and the pressing block to move along the vertical direction together, and the pressing block is used for directly applying pressure to the top surface of the capacitor sleeved in the silica gel cap.

In one of the technical schemes, the adjacent positions of the pressure maintaining mechanisms are provided with clamping mechanisms which are connected with the frame and used for clamping the side walls of the capacitor sleeved with the silica gel cap.

In one of the technical schemes, the pin shearing mechanism comprises a fifth driver, a first cutter, a sixth driver, a second cutter, a guide cover and a collecting box;

The fifth driver is connected with the first cutter and is used for driving the first cutter to be close to or far away from the second cutter, the sixth driver is connected with the second cutter and is used for driving the second cutter to be close to or far away from the first cutter, pins for jointly cutting off capacitors are arranged when the first cutter and the second cutter are close to each other, the guide cover is arranged below the first cutter and the second cutter but is positioned above the collecting box, and the guide cover is used for guiding the cut pins to fall into the collecting box.

Compared with the prior art, the silica gel cap sleeve capacitor machine provided by the utility model has the following beneficial effects:

During operation, the feeding mechanism automatically provides the capacitor, the feeding mechanism takes out the capacitor from the feeding mechanism and places the capacitor on the clamp, then the turntable drives the clamp to rotate, the clamp sequentially passes through the glue dispensing mechanism, the silica gel cap assembling mechanism, the pressure maintaining mechanism and the adjacent position of the discharging mechanism, wherein the glue dispensing mechanism automatically drops glue to the top surface of the capacitor on the clamp, the silica gel cap assembling mechanism automatically takes out the silica gel cap from the vibrating disc and sleeves the silica gel cap on the capacitor positioned on the clamp, the pressure maintaining mechanism applies pressure to the top surface of the capacitor sleeved on the silica gel cap, the silica gel cap is adhered with the capacitor into a whole more reliably, and finally the discharging mechanism outwards feeds the capacitor positioned on the clamp to a preset position, so that the function of automatically sleeving the silica gel cap on the capacitor is realized.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained from these drawings without inventive faculty for a person skilled in the art.

Fig. 1 is an assembled structural view of a capacitor and a silicone cap provided in the prior art;

Fig. 2 is a schematic structural diagram of a silicone cap capacitor machine according to an embodiment of the present application;

FIG. 3 is a schematic view of the silicone cap capacitive machine of FIG. 2 at another angle;

FIG. 4 is a schematic diagram of a turntable and a plurality of jigs according to an embodiment of the present application;

FIG. 5 is a schematic diagram of a structure of an embodiment of the present application in which a plurality of capacitors are bonded by a braid;

fig. 6 is a schematic structural diagram of a feeding mechanism according to an embodiment of the present application;

FIG. 7 is an enlarged view of a portion of FIG. 6 at A;

Fig. 8 is a schematic structural view of a silica gel cap assembly mechanism according to an embodiment of the present application;

FIG. 9 is a partial enlarged view at B in FIG. 8;

FIG. 10 is a schematic structural view of a pressure maintaining mechanism according to an embodiment of the present application;

fig. 11 is a schematic structural diagram of a leg cutting mechanism according to an embodiment of the present application.

Wherein, each reference sign in the figure:

1. A frame; 2. a feeding mechanism; 21. a base; 211. a guide groove; 22. the motor is stirred; 23. a thumb wheel; 231. a bump; 24. braiding; 241. hole sites; 3. a pin cutting mechanism; 31. a blade; 4. a turntable; 41. a clamp; 5. a feeding mechanism; 6. a dispensing mechanism; 7. a vibration plate;

8. A silica gel cap assembly mechanism; 81. a first driver; 82. a second driver; 83. a rotary clamping cylinder; 84. a clamping jaw cylinder; 85. a fifth driver; 86. a calibration block;

9. A pressure maintaining mechanism; 91. a fourth driver; 92. a connecting seat; 93. an elastic member; 94. briquetting;

10. A pin cutting mechanism; 101. a fifth driver; 102. a first cutter; 103. a sixth driver; 104. a second cutter; 105. a guide cover; 106. a collection box;

11. A blanking mechanism; 12. middle rotating seat; 121. positioning a reference surface; 13. a clamping mechanism; 80. a capacitor; 90. a silica gel cap.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the application.

It will be understood that when an element is referred to as being "mounted" or "disposed" on another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It is to be understood that the terms "upper," "lower," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship based on that shown in the drawings, merely to facilitate describing the present application and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present application.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present application, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent.

Referring to fig. 2 to 4, the present embodiment provides a silicone cap capacitor machine, which includes a frame 1, a feeding mechanism 2, a pin cutting mechanism 3, a turntable 4, a feeding mechanism 5, a dispensing mechanism 6, a vibration disc 7, a silicone cap assembling mechanism 8, a pressure maintaining mechanism 9, a pin cutting mechanism 10 and a discharging mechanism 11. Wherein, carousel 4 is by motor drive for carousel 4 can rotate for frame 1, is provided with anchor clamps 41 on the carousel 4, and foretell feed mechanism 5, dispensing mechanism 6, silica gel cap equipment mechanism 8, pressurize mechanism 9 and unloading mechanism 11 are arranged in proper order in the one side of carousel 4 along the direction of rotation of carousel 4 respectively.

Specifically, referring to fig. 5, the feeding mechanism 2 automatically feeds the capacitor 80 by using the braid 24, wherein the braid 24 is used for bonding pins of a plurality of capacitors 80, and the capacitors 80 can be driven to a desired position only by driving the braid 24 to move. The pin cutting mechanism 3 is used for cutting off two pins on the capacitor 80, so that the capacitor 80 and the braid 24 can be separated from each other, the capacitor 80 separated from the braid 24 is placed on the clamp 41 under the driving of the feeding mechanism 5, and the turntable 4 drives the clamp 41 to rotate, so that the clamp 41 is sequentially driven to adjacent positions of the dispensing mechanism 6, the silicone cap assembling mechanism 8, the pressure maintaining mechanism 9 and the blanking mechanism 11. The dispensing mechanism 6 is used for automatically dripping glue to the top surface of the capacitor 80 on the clamp 41, the vibration disc 7 is used for automatically providing the silica gel cap 90, the silica gel cap assembling mechanism 8 is used for automatically taking out the silica gel cap 90 from the vibration disc 7 and sleeving the silica gel cap 90 on the capacitor 80 positioned on the clamp 41, the pressure maintaining mechanism 9 is used for applying pressure to the top surface of the capacitor 80 sleeved with the silica gel cap 90, so that the silica gel cap 90 is more reliably adhered with the capacitor 80 into a whole, the pin shearing mechanism 10 is positioned on the moving path of the blanking mechanism 11, the blanking mechanism 11 is used for blanking the capacitor 80 positioned on the clamp 41 onto the pin shearing mechanism 10 firstly and then outwards blanking the capacitor 80 on the pin shearing mechanism 10 to a preset position, and the pin shearing mechanism 10 is used for shearing two pins on the capacitor 80 to a preset length.

The respective mechanisms described above are described in detail below with reference to the drawings.

Referring to fig. 5 to 7, the feeding mechanism 2 includes a base 21, a dial motor 22, a dial wheel 23 and a braid 24, wherein the base 21 is fixed on the frame 1, a guide slot 211 is provided on the base 21, the guide slot 211 is used for feeding the braid 24 in and out, the extending direction of the guide slot 211 is preferably U-shaped, so that the direction of the braid 24 entering the guide slot 211 is opposite to the direction of the braid 24 leaving the guide slot 211, the braid 24 is provided with a plurality of holes 241 along the length direction thereof, the dial motor 22 is fixed on the base 21, the dial wheel 23 and the output shaft of the dial motor 22 are connected, a plurality of protrusions 231 are protruding from the outer wall of the dial wheel 23 along the radial direction, and when the dial wheel 23 is driven by the dial motor 22 to do rotary motion, the protrusions 231 of the dial wheel 23 are embedded into the holes 241 of the braid 24 to drive the braid 24 to move along the extending direction of the guide slot 211. The pin cutting mechanism 3 cuts off two pins of the capacitor 80 in a manner of transversely moving the driving blade 31, so that the capacitor 80 and the braid 24 are separated from each other, and the feeding mechanism 5 can easily take the capacitor 80 from the braid 24. In fact, the pins of capacitor 80 that have been cut will not drop downward, and the pins of capacitor 80 that have been cut will remain on braid 24 and be fed out as braid 24 is fed out along guide slot 211.

The feeding mechanism 5 is an existing two-axis or three-axis material taking manipulator, so that the specific structure of the feeding mechanism 5 is not described here. The dispensing mechanism 6 is also in the prior art, and the dispensing mechanism 6 is a structural design of the existing two-axis or three-axis manipulator matched with the dispensing head, so that the specific structure of the dispensing mechanism 6 is not described here again.

Referring to fig. 4, a plurality of jigs 41 are fixed on the turntable 4, so that the feeding mechanism 5, the dispensing mechanism 6, the silicone cap assembling mechanism 8, the pressure maintaining mechanism 9 and the discharging mechanism 11 can operate simultaneously, thereby improving the working efficiency of the device.

Referring to fig. 8 and 9 together, the silica gel cap assembly mechanism 8 includes a first driver 81, a second driver 82, a rotary clamping cylinder 83 and a clamping jaw cylinder 84, the rotary clamping cylinder 83 and the clamping jaw cylinder 84 are connected to the second driver 82, the second driver 82 is used for driving the rotary clamping cylinder 83 and the clamping jaw cylinder 84 to move together along a vertical direction, the first driver 81 is mounted on the frame 1 and connected to the second driver 82, the first driver 81 is used for driving the second driver 82, the rotary clamping cylinder 83 and the clamping jaw cylinder 84 to move together in a single shaft or multiple shafts, the rotary clamping cylinder 83 has the clamping and rotating functions, and the clamping jaw cylinder 84 has the clamping function. During operation, through the linkage of the first driver 81 and the second driver 82, the rotary clamping cylinder 83 takes out the silica gel cap 90 from the discharging position of the vibration disc 7, rotates the silica gel cap 90 to a preset posture, and then places the silica gel cap 90 on the transfer seat 12, and at the same time, the existing silica gel cap 90 on the transfer seat 12 is taken out by the clamping jaw cylinder 84 and sleeves the silica gel cap 90 on the capacitor 80 clamped by the clamp 41. By providing the rotary clamping cylinder 83 and the jaw cylinder 84 at the same time, the assembly efficiency of the silicone cap 90 can be improved.

Referring to fig. 8 and 9 again, a positioning reference surface 121 is disposed on the transfer seat 12, a third driver 85 is fixed on the transfer seat 12, a calibration block 86 is connected to the third driver 85, and the third driver 85 is used for driving the calibration block 86 to approach or separate from the positioning reference surface 121. During operation, the calibration block 86 is in a state away from the positioning reference surface 121, after the silica gel cap 90 is placed on the transfer seat 12 by the rotary clamping cylinder 83, the third driver 85 drives the calibration block 86 to be close to the positioning reference surface 121, and the calibration block 86 and the positioning reference surface 121 jointly clamp the silica gel cap 90 so as to calibrate the position of the silica gel cap 90 on the middle rotary seat 12, so that the clamping jaw cylinder 84 can accurately clamp the silica gel cap 90 from the middle rotary seat 12 and accurately sleeve the silica gel cap 90 into the outer wall of the capacitor 80.

Referring to fig. 10, the pressure maintaining mechanism 9 includes a fourth driver 91, a connection seat 92, an elastic member 93 and a pressing block 94, wherein the fourth driver 91 is an air cylinder, the elastic member 93 is a spring, the elastic member 93 is connected between the connection seat 92 and the pressing block 94, the elastic member 93 elastically stretches in a direction pointing to a vertical direction, the pressing block 94 is subject to the elastic force of the elastic member 93 to have a downward moving trend, the fourth driver 91 is connected with the connection seat 92, and the fourth driver 91 is used for driving the connection seat 92, the elastic member 93 and the pressing block 94 to move together along the vertical direction. During operation, the fourth driver 91 drives the connecting seat 92 to descend to a preset height, at this time, the pressing block 94 applies pressure to the top of the capacitor 80 through the silica gel cap 90 under the elasticity of the elastic member 93, after a specified time, the glue between the silica gel cap 90 and the capacitor 80 is cured, so that the silica gel cap 90 and the capacitor 80 are reliably adhered into a whole, and finally the fourth driver 91 drives the connecting seat 92 to move upwards to a reset position, at this time, the pressing block 94 is reset upwards.

Referring to fig. 10 again, the adjacent position of the pressure maintaining mechanism 9 is provided with a clamping mechanism 13, the clamping mechanism 13 is mounted on the frame 1, the clamping mechanism 13 is a clamping jaw cylinder, and the clamping mechanism 13 is used for clamping the side wall of the capacitor 80 sleeved in the silica gel cap 90. During operation, the clamping mechanism 13 clamps the side wall of the capacitor 80 sleeved with the silica gel cap 90, and then the pressure maintaining mechanism 9 begins to press down the top surface of the capacitor 80, so as to ensure that the capacitor 80 can still maintain relatively accurate position accuracy on the clamp 41 when being continuously pressed down by the pressure maintaining mechanism 9.

Referring to fig. 11, the leg cutting mechanism 10 includes a fifth driver 101, a first cutter 102, a sixth driver 103, a second cutter 104, a guiding cover 105 and a collecting box 106, wherein the fifth driver 101 and the sixth driver 103 are all cylinders fixed on the frame 1, the fifth driver 101 is connected with the first cutter 102 and is used for driving the first cutter 102 to be close to or far from the second cutter 104, the sixth driver 103 is connected with the second cutter 104 and is used for driving the second cutter 104 to be close to or far from the first cutter 102, and the guiding cover 105 is arranged below the first cutter 102 and the second cutter 104 but above the collecting box 106. When the device works, the fifth driver 101 drives the first cutter 102 to be close to the second cutter 104, the sixth driver 103 drives the second cutter 104 to be close to the first cutter 102, the first cutter 102 and the second cutter 104 which are close to each other jointly shear two pins of the capacitor 80, and the sheared pins drop into the collecting box 106 downwards along the guide cover 105, so that the sheared pins are prevented from dropping to other positions, and the device can continuously and normally run.

The discharging mechanism 11 is an existing two-axis or three-axis material taking manipulator, so that specific structures of the discharging mechanism 11 are not described here.

To sum up, this technical scheme has both realized to the automatic function of covering the silica gel cap 90 on the electric capacity 80, still has the function of cutting two pins of electric capacity 80 to preset length automatically, and this technical scheme has improved the work efficiency that electric capacity 80 was covered with silica gel cap 90 by a wide margin to improve the production efficiency of electric capacity 80.

The foregoing description of the preferred embodiments of the present utility model has been provided for the purpose of illustrating the general principles of the present utility model and is not to be construed as limiting the scope of the utility model in any way. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the present utility model, and other embodiments of the present utility model as will occur to those skilled in the art without the exercise of inventive faculty, are intended to be included within the scope of the present utility model.

Claims (8)

1. The silica gel cap sleeve capacitor machine is characterized by comprising a machine frame, and a feeding mechanism, a rotary table, a feeding mechanism, a dispensing mechanism, a vibrating disc, a silica gel cap assembling mechanism, a pressure maintaining mechanism and a discharging mechanism which are respectively connected with the machine frame;

the turntable can rotate relative to the rack, a clamp for clamping the capacitor is arranged on the turntable, and the clamp is driven to rotate relative to the rack when the turntable rotates;

The feeding mechanism is used for automatically providing a capacitor, the feeding mechanism is arranged on one side of the feeding mechanism and used for transferring the capacitor on the feeding mechanism to a clamp of the turntable, and the vibration disk is used for automatically providing the silica gel cap;

The device comprises a rotating disc, a silica gel cap assembly mechanism, a pressure maintaining mechanism, a discharging mechanism, a dispensing mechanism and a vibration disc, wherein the dispensing mechanism, the silica gel cap assembly mechanism, the pressure maintaining mechanism and the discharging mechanism are sequentially arranged on one side of the rotating disc along the rotating direction of the rotating disc, the dispensing mechanism is used for automatically dripping glue on the top surface of a capacitor on the clamp, the silica gel cap assembly mechanism is used for automatically taking out a silica gel cap from the vibration disc and sleeving the silica gel cap on the capacitor on the clamp, the pressure maintaining mechanism is used for applying pressure to the top surface of the capacitor sleeved with the silica gel cap, and the discharging mechanism is used for discharging the capacitor on the clamp to a preset position outwards.

2. The silicone cap capacitive machine of claim 1 further comprising a pin cutting mechanism coupled to the frame, the pin cutting mechanism being positioned in a path of movement of the blanking mechanism, the pin cutting mechanism being configured to cut pins of the capacitive machine to a predetermined length.

3. The silicone cap capacitive machine of claim 1 wherein the feed mechanism comprises a base, a braid, a toggle motor, and a toggle wheel;

The base is connected with the frame, a guide groove for allowing the braid to enter and be sent out is formed in the base, a plurality of hole sites are formed in the braid along the length direction, the braid is used for bonding pins of a capacitor, a plurality of protruding blocks are arranged on the radial outer wall of the poking wheel in a protruding mode, the poking motor is respectively connected with the base and the poking wheel and used for driving the poking wheel to rotate, and when the poking wheel rotates, the protruding blocks are embedded into the hole sites of the braid so as to drive the braid to move in the guide groove;

The silica gel cap sleeve capacitor machine further comprises a pin cutting mechanism connected with the frame, wherein the pin cutting mechanism is arranged on one side of the dial wheel and used for cutting off pins of the capacitor, so that the pins of the capacitor can be separated from the braid.

4. The silicone cap capacitive machine of claim 1, wherein the silicone cap assembly mechanism comprises a first driver, a second driver, a rotary clamping cylinder and a clamping jaw cylinder, wherein the middle swivel mount is arranged adjacent to the silicone cap assembly mechanism;

The rotary clamping cylinder and the clamping jaw cylinder are connected with the second driver, the second driver is used for driving the rotary clamping cylinder and the clamping jaw cylinder to move along the vertical direction together, the first driver is connected with the frame and the second driver respectively and used for driving the second driver, the rotary clamping cylinder and the clamping jaw cylinder to move along a single shaft or multiple shafts together, the rotary clamping cylinder is used for taking out a silica gel cap from the vibration disc and driving the silica gel cap to rotate to a preset angle, the transfer seat is used for receiving the silica gel cap from the rotary clamping cylinder, and the clamping jaw cylinder is used for clamping the silica gel cap from the transfer seat and is used for sleeving the silica gel cap onto a capacitor of the clamp under the combined driving of the first driver and the second driver.

5. The silicone cap capacitive machine of claim 4, wherein a positioning reference surface is provided on the middle swivel mount, a third driver is fixed on the middle swivel mount, a calibration block is connected to the third driver, the third driver is used for driving the calibration block to be close to or far away from the positioning reference surface, and the positioning reference surface and the calibration block are used for clamping the silicone cap together so as to calibrate the position of the silicone cap on the transit mount.

6. The silicone cap capacitive machine of claim 1 wherein the dwell mechanism comprises a fourth drive, a connecting base, an elastic member, and a press block;

The elastic piece is connected between the connecting seat and the pressing block, the pressing block has a downward movement trend due to the elasticity of the elastic piece, the fourth driver is connected with the connecting seat and used for driving the connecting seat, the elastic piece and the pressing block to move along the vertical direction together, and the pressing block is used for directly applying pressure to the top surface of the capacitor sleeved in the silica gel cap.

7. The silicone cap capacitive machine of claim 6 wherein adjacent locations of the dwell mechanism have clamping mechanisms connected to the frame for clamping the side walls of the capacitor that has been nested into the silicone cap.

8. The silicone cap capacitive machine of claim 2 wherein the pin shearing mechanism comprises a fifth driver, a first cutter, a sixth driver, a second cutter, a guide cover, and a collection box;

The fifth driver is connected with the first cutter and is used for driving the first cutter to be close to or far away from the second cutter, the sixth driver is connected with the second cutter and is used for driving the second cutter to be close to or far away from the first cutter, pins for jointly cutting off capacitors are arranged when the first cutter and the second cutter are close to each other, the guide cover is arranged below the first cutter and the second cutter but is positioned above the collecting box, and the guide cover is used for guiding the cut pins to fall into the collecting box.