Electronic component processing apparatus and method
The transmission mechanism drives the cooling mechanism to cool and flush the drive motor and grinding head or drill bit, which solves the problems of equipment wear and uneven processing caused by high temperature, extends equipment life and improves processing quality, and realizes the recycling of water resources.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Filing Date
- 2026-06-01
- Publication Date
- 2026-07-14
Smart Images

Figure CN122378552A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the technical field of electronic components, and more particularly to an electronic component processing and manufacturing apparatus and method. Background Technology
[0002] Electronic components are the building blocks of electronic parts and small machines and instruments. Electronic components include: resistors, capacitors, inductors, potentiometers, electron tubes, heat sinks, electromechanical components, connectors, discrete semiconductor devices, electroacoustic devices, laser devices, electronic display devices, optoelectronic devices, sensors, power supplies, switches, micromotors, electronic transformers, relays, printed circuit boards, integrated circuits, various circuits, piezoelectric materials, crystals, quartz, ceramic magnetic materials, substrates for printed circuit boards, special materials for electronic functional processes, electronic adhesive (tape) products, electronic chemical materials and components, etc. Manufacturing equipment is used in the processing of electronic components. This equipment typically consists of a worktable, a clamping mechanism, a drive motor, and a grinding mechanism to manufacture electronic components. Current electronic component manufacturing equipment requires a drive motor to power a grinding head or drill bit to manufacture electronic components. During manufacturing, the drive motor generates heat due to continuous operation. Prolonged exposure to a hot working environment increases wear and tear on the motor itself. Furthermore, the grinding head or drill bit itself generates heat during manufacturing. Prolonged exposure to high heat can lead to deformation and damage of the grinding head or drill bit, and in severe cases, thermal damage to the workpiece surface. Manufacturing efficiency is also reduced due to high temperatures. This not only affects manufacturing speed but may also result in uneven processing and a shortened service life. Summary of the Invention
[0003] The purpose of this section is to outline some aspects of embodiments of the present invention and to briefly describe some preferred embodiments. Simplifications or omissions may be made in this section, as well as in the abstract and title of this application, to avoid obscuring the purpose of these documents; however, such simplifications or omissions should not be construed as limiting the scope of the invention.
[0004] In view of the problems existing in the current electronic component processing and manufacturing apparatus, the present invention is proposed.
[0005] Therefore, the purpose of this invention is to provide an electronic component processing and manufacturing apparatus, the purpose of which is to cool down the drill bit and to flush away impurities remaining on the grinding head or drill bit.
[0006] To solve the above-mentioned technical problems, the present invention provides the following technical solution: a manufacturing mechanism, comprising a worktable, a fixed plate fixedly installed on the top of the front side of the worktable, a drive motor fixedly installed on the bottom of the fixed plate, an electric telescopic rod fixedly installed on the output end of the drive motor, a chuck fixedly installed on the bottom of the electric telescopic rod, the bottom of the chuck being able to easily engage a grinding head or a drill bit, a processing groove being formed on the top of the worktable, and hydraulic push rods being provided on both sides of the top of the worktable, the output end of the hydraulic push rods being fixedly installed with clamping components; and... A cooling mechanism is located on top of the manufacturing mechanism. The cooling mechanism includes a water tank with a sealing cover connected to the rear side of the top left side of the water tank. A recovery port is located on the right side of the top of the water tank, and a water level line is located on the front of the water tank. A heat dissipation component is fixedly installed on the left side of the bottom inside the water tank. A transmission mechanism is provided at the output end of the drive motor. The transmission mechanism includes a first sprocket, which is fixedly installed at the output end of the drive motor. A second sprocket is connected to the surface of the first sprocket via a chain drive. A transmission rod is fixedly installed inside the second sprocket. A drive assembly is fixedly installed at the top of the transmission rod, and a fixing member is movably installed at the bottom of the transmission rod. The other end of the fixing member is fixedly installed to the worktable. An adjustment mechanism is provided on the front side of the top of the manufacturing mechanism.
[0007] In a preferred embodiment of the electronic component processing and manufacturing apparatus of the present invention, the heat dissipation component includes a water storage tank, which is fixedly installed on the left side inside the water storage tank. A water inlet is provided at the bottom of the surface of the water storage tank, and several water inlets are provided at equal intervals. A positive impeller is provided at the bottom inside the water storage tank. A water outlet pipe is connected to the top of the water storage tank, and the other end of the water outlet pipe is connected to a heat dissipation coil. The heat dissipation coil is wound around the surface of the drive motor, and the other end of the heat dissipation coil is connected to a water spray component.
[0008] In a preferred embodiment of the electronic component processing and manufacturing apparatus of the present invention, the water spraying component includes a water spraying pipe connected to the other end of the heat sink coil, a mounting bracket is movably mounted on the left side of the clamping head surface, a telescopic pipe is connected to the other end of the water spraying pipe, the telescopic pipe is fixedly installed inside the mounting bracket, and a water spray head is connected to the other end of the telescopic pipe.
[0009] In a preferred embodiment of the electronic component processing and manufacturing apparatus of the present invention, the driving assembly includes a large gear fixedly mounted on the top of a transmission rod. A small gear meshes with the front of the large gear. Mounting components are movably mounted on the top of the large gear and the bottom of the small gear, respectively, and are fixedly mounted to a worktable and a fixed plate. A driving rod is fixedly mounted on the top of the small gear. A driving wheel is fixedly mounted on the surface of the driving rod. A driven wheel is connected to the surface of the driving wheel via a belt drive. A rotating rod is fixedly mounted inside the driven wheel. A reverse impeller is fixedly mounted through a water tank at the top of the rotating rod. A first pulley is fixedly mounted on the bottom of the rotating rod. A second pulley is connected to the surface of the first pulley via a belt drive. A driven rod is fixedly mounted inside the second pulley. The bottom of the driven rod is movably mounted to the fixed plate. The driven rod is fixedly mounted through the water tank and inside the positive impeller. The other end of the reverse impeller is connected to a recovery component.
[0010] In a preferred embodiment of the electronic component processing and manufacturing apparatus of the present invention, the recycling component includes a recycling bin connected to the top of the recycling port, an anti-reverse impeller located inside the recycling bin, a recycling pipe connected to the top of the recycling bin, a recycling hole for use with the recycling pipe opened inside the workbench, a recycling head connected to the other end of the recycling pipe, a recycling trough connected to the back of the processing trough, the recycling trough being inclined backward, a cleaning trough connected to the bottom of the recycling trough, a cleaning frame slidably installed inside the cleaning trough, and a filter screen fixedly installed on the rear side of the recycling trough.
[0011] In a preferred embodiment of the electronic component processing and manufacturing apparatus of the present invention, the adjusting mechanism includes a connecting plate, which is fixedly installed on the outside of the hydraulic push rod. An adjusting plate is fixedly installed on the front side of the inner side of the connecting plate. A scale is provided on the top of the adjusting plate. A pointer located on the back of the adjusting plate is fixedly installed on the top of the worktable. A rack is fixedly installed on the front of the adjusting plate. An adjusting gear is meshed on the front of the rack. The bottom of the adjusting gear is movably installed on the worktable. An adjusting rod is fixedly installed on the top of the adjusting gear. A worm gear is fixedly installed on the top of the adjusting rod. A worm is meshed on the front of the worm gear. A mounting bracket is movably installed on the surface of the worm. The bottom of the mounting bracket is fixedly installed on the worktable. A knob is fixedly installed on the right end of the worm.
[0012] In a preferred embodiment of the electronic component processing and manufacturing apparatus of the present invention, an L-shaped plate is fixedly installed at the bottom of the adjusting plate, a movable groove for use with the L-shaped plate is connected to the front side of the processing groove, and a processing ring is fixedly installed on the back of the L-shaped plate.
[0013] In a preferred embodiment of the electronic component processing and manufacturing apparatus of the present invention, sliders are fixedly installed on both sides of the front of the adjustment plate, and a sliding groove is provided on the top of the worktable to cooperate with the sliders, and the sliders and the sliding groove are slidably connected.
[0014] The beneficial effects of the present invention are as follows: the transmission mechanism can drive the cooling mechanism to cool the drive motor and the grinding head or drill bit, and to rinse the grinding head or drill bit. Furthermore, the transmission mechanism can synchronously drive the recycling component through the drive assembly to filter, recycle, and reuse the rinsed water.
[0015] In view of the problems existing in the current method for processing and manufacturing electronic components, the present invention is proposed.
[0016] Therefore, the purpose of this invention is to provide a method for processing and manufacturing electronic components, which aims to simultaneously cool down the temperature of the drive motor and the grinding head or drill bit itself during the processing of electronic components, and to rinse away the impurities remaining in the grinding head or drill bit during operation.
[0017] To solve the above-mentioned technical problems, the present invention provides the following technical solution: when the drive motor is working, the output end can drive the transmission mechanism to rotate synchronously, and then the transmission mechanism drives the cooling mechanism to work synchronously, so that the cooling mechanism can cool the drive motor and the grinding head or drill bit, and rinse the grinding head or drill bit, and then the transmission mechanism drives the recycling component to recycle and reuse the rinsed water.
[0018] As a preferred embodiment of the electronic component processing and manufacturing method of the present invention, when the two sides of the grinding head are not completely ground, the electronic component held by the adjustment mechanism can be adjusted left and right arbitrarily so that the grinding device can grind the electronic component more thoroughly.
[0019] The beneficial effects of the present invention are as follows: the transmission mechanism can drive the cooling mechanism to cool the drive motor and the grinding head or drill bit, and to rinse the grinding head or drill bit. Furthermore, the transmission mechanism can synchronously drive the recycling component through the drive assembly to filter, recycle, and reuse the rinsed water. Attached Figure Description
[0020] To more clearly illustrate the technical solutions of the embodiments of the present invention, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort. Wherein: Figure 1 This is a schematic diagram of the overall structure of the present invention.
[0021] Figure 2 This is an overall three-dimensional schematic diagram from another perspective for the present invention.
[0022] Figure 3 A schematic diagram of the upper part of the worktable provided by the present invention.
[0023] Figure 4 This is a schematic diagram of the lower half of the workbench provided by the present invention.
[0024] Figure 5 This is a three-dimensional schematic diagram of the rear side provided by the present invention.
[0025] Figure 6 This is a three-dimensional schematic diagram of the front side of the present invention. Detailed Implementation
[0026] To make the above-mentioned objects, features and advantages of the present invention more apparent and understandable, the specific embodiments of the present invention will be described in detail below with reference to the accompanying drawings.
[0027] Many specific details are set forth in the following description in order to provide a full understanding of the invention. However, the invention may also be practiced in other ways different from those described herein, and those skilled in the art can make similar extensions without departing from the spirit of the invention. Therefore, the invention is not limited to the specific embodiments disclosed below.
[0028] Secondly, the term "one embodiment" or "embodiment" as used herein refers to a specific feature, structure, or characteristic that may be included in at least one implementation of the present invention. The phrase "in one embodiment" appearing in different places in this specification does not necessarily refer to the same embodiment, nor is it a single or selective embodiment that is mutually exclusive with other embodiments.
[0029] Secondly, the present invention is described in detail with reference to the schematic diagrams. When detailing the embodiments of the present invention, for ease of explanation, the cross-sectional views illustrating the device structure may be partially enlarged, not according to the usual scale. Furthermore, the schematic diagrams are merely examples and should not limit the scope of protection of the present invention. In addition, actual fabrication should include the three-dimensional spatial dimensions of length, width, and depth.
[0030] Example 1
[0031] Reference Figures 1-6This is the first embodiment of the present invention, providing a method for manufacturing electronic components. Through a manufacturing apparatus, when the drive motor 103 is working, its output end can drive the transmission mechanism 300 to rotate synchronously. The transmission mechanism 300 then drives the cooling mechanism 200 to work synchronously, enabling the cooling mechanism 200 to cool the drive motor 103 and the grinding head or drill bit, as well as to rinse the grinding head or drill bit. The transmission mechanism 300 then drives the recycling component 305l to recycle and reuse the rinsed water. Furthermore, when the sides of the grinding head are not completely ground, the adjusting mechanism 400 can adjust the clamped electronic components left and right, allowing the grinding device to grind the electronic components more thoroughly. When the output end of the drive motor 103 drives the electric telescopic rod 104 and the grinding head or drill bit to manufacture the electronic components, the output end of the drive motor 103 can synchronously drive the first sprocket 301 to rotate, causing the first sprocket 301... The chain 302 drives the second sprocket 303 to rotate, which in turn drives the large gear 305a to rotate via the transmission rod 304. The large gear 305a then drives the small gear 305b to rotate at an accelerated speed. The small gear 305b rotates synchronously via the drive wheel 305e, driven wheel 305f, first pulley 305i, second pulley 305j, positive impeller 204c, and negative impeller 305h, causing the positive impeller 204c to rotate in the forward direction. The thrust is transmitted through the water storage tank 204a to the water outlet pipe 204d and the cooling coil 204f, which cools the drive motor 103. The water spray component 204g cools and washes the grinding head or drill bit. Meanwhile, the reverse impeller 305h rotates in the opposite direction, which transmits the suction through the recovery tank 305l-1 to the recovery pipe 305l-2 and the recovery head 305l-4, allowing the recovery head 305l-4 to recycle the water.
[0032] Example 2
[0033] Reference Figures 1-6 In the second embodiment of the present invention, a transmission mechanism 300 and a cooling mechanism 200 are provided. Through the transmission mechanism 300 and the cooling mechanism 200, the driving motor 103 and the grinding head or drill bit are cooled by the power of the driving motor 103, and the grinding head or drill bit is rinsed and the rinsing water is filtered and recycled.
[0034] Cooling mechanism 200 is located on top of manufacturing mechanism 100. Cooling mechanism 200 includes water storage tank 201. A sealing cover is connected to the rear side of the top left side of water storage tank 201. A recycling port 202 is opened on the right side of the top of water storage tank 201. A water level line 203 is opened on the front of water storage tank 201. A heat dissipation component 204 is fixedly installed on the left side of the bottom inside water storage tank 201.
[0035] A transmission mechanism 300 is located at the output end of the drive motor 103. The transmission mechanism 300 includes a first sprocket 301, which is fixedly installed at the output end of the drive motor 103. A second sprocket 303 is connected to the surface of the first sprocket 301 via a chain 302. A transmission rod 304 is fixedly installed inside the second sprocket 303. A drive assembly 305 is fixedly installed on the top of the transmission rod 304. A fixing member 306 is movably installed on the bottom of the transmission rod 304. The other end of the fixing member 306 is fixedly installed to the worktable 101.
[0036] The heat dissipation assembly 204 includes a water storage tank 204a, which is fixedly installed on the left side inside the water storage tank 201. A water inlet 204b is provided at the bottom of the surface of the water storage tank 204a. Several water inlets 204b are provided and are evenly distributed. A positive impeller 204c is provided at the bottom inside the water storage tank 204a. A water outlet pipe 204d is connected to the top of the water storage tank 204a. The other end of the water outlet pipe 204d is connected to a heat dissipation coil 204f. The heat dissipation coil 204f is wound around the surface of the drive motor 103. The other end of the heat dissipation coil 204f is connected to a water spray component 204g.
[0037] The water spray component 204g includes a water spray pipe 204g-1, which is connected to the other end of the heat sink 204f. A mounting bracket 204g-2 is movably mounted on the left side of the clip 105. The other end of the water spray pipe 204g-1 is connected to a telescopic pipe 204g-3, which is fixedly installed inside the mounting bracket 204g-2. The other end of the telescopic pipe 204g-3 is connected to a water spray head 204g-4.
[0038] The drive assembly 305 includes a large gear 305a, which is fixedly mounted on the top of the transmission rod 304. A small gear 305b meshes with the front of the large gear 305a. Mounting parts 305c are movably mounted on the top of the large gear 305a and the bottom of the small gear 305b, respectively. The mounting parts 305c are fixedly mounted to the worktable 101 and the fixed plate 102. A drive rod 305d is fixedly mounted on the top of the small gear 305b. A drive wheel 305e is fixedly mounted on the surface of the drive rod 305d. A driven wheel 305f is connected to the surface of the drive wheel 305e via a belt drive. A rotating rod 305g is fixedly installed inside. The top of the rotating rod 305g passes through the water storage tank 201 and is fixedly installed with a reverse impeller 305h. A first pulley 305i is fixedly installed on the bottom of the surface of the rotating rod 305g. A second pulley 305j is connected to the surface of the first pulley 305i via belt drive. A driven rod 305k is fixedly installed inside the second pulley 305j. The bottom of the driven rod 305k is movably installed with the fixed plate 102. The driven rod 305k passes through the water storage tank 201 and is fixedly installed inside the positive impeller 204c. The other end of the reverse impeller 305h is connected to a recovery component 305l.
[0039] The recycling component 305l includes a recycling bin 305l-1, which is connected to the top of the recycling port 202. The reverse impeller 305h is located inside the recycling bin 305l-1. The top of the recycling bin 305l-1 is connected to a recycling pipe 305l-2. The inside of the workbench 101 is provided with a recycling hole for use with the recycling pipe 305l-2. The other end of the recycling pipe 305l-2 is connected to a recycling head 305l-4. The back of the processing tank 106 is connected to a recycling tank 305l-3, which is opened at a rearward angle. The bottom of the recycling tank 305l-3 is connected to a cleaning tank 305l-5. A cleaning frame 305l-6 is slidably installed inside the cleaning tank 305l-5. A filter screen 305l-7 located behind the cleaning tank 305l-5 is fixedly installed inside the rear side of the recycling tank 305l-3.
[0040] Specifically, when the drive motor 103 is working, it drives the transmission mechanism 300 to work synchronously, so that the transmission mechanism 300 drives the cooling mechanism 200 to dissipate heat from the drive motor 103 and to cool and clean the grinding head or drill bit.
[0041] Furthermore, when the output end of the drive motor 103 drives the electric telescopic rod 104 and the grinding head or drill bit to rotate, the output end can synchronously drive the first sprocket 301 to rotate, so that the first sprocket 301 drives the second sprocket 303 to rotate through the chain 302. The second sprocket 303 drives the transmission rod 304 to rotate, and the transmission rod 304 drives the large gear 305a to rotate. When the large gear 305a and the transmission rod 304 rotate, the fixing part 306 and the mounting part 305c can limit the large gear 305a and the transmission rod 304, ensuring the stability of the rotation of the large gear 305a and the transmission rod 304. Then, the large gear 305a drives the small gear 305b to accelerate its rotation, ensuring the rotation speed, so that the small gear 305b... b drives the rotating rod 305g to rotate, which in turn drives the drive wheel 305e to rotate. The drive wheel 305e drives the driven wheel 305f to rotate, which in turn drives the drive rod 305d to rotate. The drive rod 305d drives the first pulley 305i to rotate, which in turn drives the second pulley 305j to rotate via a belt. This causes the second pulley 305j to drive the driven rod 305k to rotate, and the driven rod 305k and the drive rod 305d to synchronously drive the positive impeller 204c and the negative impeller 305h to rotate. The positive impeller 204c then transports water entering the water tank 201 through the water inlet 204b via the water storage tank 204a. The water storage tank 204a is connected to... Water is discharged through outlet pipe 204d and then transported to cooling coil 204f. Cooling coil 204f uses the cold water to remove heat generated on the surface of drive motor 103, thus cooling the drive motor 103. Cooling coil 204f then transmits water to spray pipe 204g-1, which in turn transmits the water to telescopic pipe 204g-3, allowing the telescopic pipe 204g-3 to move with the position of chuck 105. Spray head 204g-4 then sprays water to cool and rinse the grinding head or drill bit, preventing residual debris from affecting subsequent grinding. The rinsed water flows to processing tank 106 and recovery tank 305l-3, with recovery tank 305l-3... The backward tilting design guides the water flow, ensuring a stable backward flow. This flow also carries grinding debris backward, allowing it to fall into the cleaning frame 305l-6 inside the cleaning tank 305l-5 for collection. The cleaning frame 305l-6 is slidably installed with the cleaning tank 305l-5. When the tank is nearly full, the cleaning frame 305l-6 can be removed to process the debris. After processing, the cleaning frame 305l-6 can be reset. The filter screen 305l-7 then filters the water, preventing debris from being collected along with it. The drive rod 305d rotates the reverse impeller 305h, causing it to create suction through the collection tank 305l-1 onto the collection pipe 305l-2.The recovery pipe 305l-2 recycles the water filtered by the recovery tank 305l-3 through the recovery head 305l-4. The water level line 203 eliminates the need for the user to observe the water level inside the storage tank 201; when the water level is too low, it can be added promptly by opening the sealed cover, ensuring stable cooling.
[0042] It should be noted that the 204g-4 spray head is a pressurized spray head, which increases the rinsing force and ensures the stability of the rinsing.
[0043] Example 3
[0044] Reference Figures 1-6 In the third embodiment of the present invention, an adjustment mechanism 400 is provided. The adjustment mechanism 400 is used to adjust the clamping position of the clamping device, thereby ensuring the thoroughness of the grinding.
[0045] The adjustment mechanism 400 includes a connecting plate 401, which is fixedly installed on the outside of the hydraulic push rod 107. An adjustment plate 402 is fixedly installed on the front side of the inner side of the connecting plate 401. A scale 403 is provided on the top of the adjustment plate 402. A pointer 404 located on the back of the adjustment plate 402 is fixedly installed on the top of the worktable 101. A rack 405 is fixedly installed on the front of the adjustment plate 402. An adjustment gear 406 is meshed on the front of the rack 405. The bottom of the adjustment gear 406 is movably installed on the worktable 101. An adjustment rod 407 is fixedly installed on the top of the adjustment gear 406. A worm gear 408 is fixedly installed on the top of the adjustment rod 407. A worm 409 is meshed on the front of the worm gear 408. A mounting bracket 204g-2 is movably installed on the surface of the worm 409. The bottom of the mounting bracket 204g-2 is fixedly installed on the worktable 101. A knob 410 is fixedly installed on the right end of the worm 409.
[0046] An L-shaped plate 402a is fixedly installed at the bottom of the adjusting plate 402. A movable groove 402b for use with the L-shaped plate 402a is connected to the front side inside the processing groove 106. A processing ring 402c is fixedly installed on the back of the L-shaped plate 402a.
[0047] Slider 402d is fixedly installed on both sides of the front of the adjustment plate 402. The top of the worktable 101 is provided with a slide groove 402e that is used in conjunction with the slider 402d. The slider 402d and the slide groove 402e are slidably connected.
[0048] Specifically, the adjusting plate 402 drives the hydraulic push rod 107 to adjust its position via the connecting plate 401, and then the hydraulic push rod 107 drives the overall clamping component 108 to adjust its position, thus ensuring the thoroughness of the grinding.
[0049] Furthermore, by rotating the knob 410, the worm gear 409 can be rotated, which in turn rotates the worm wheel 408. The worm wheel 408 then rotates the adjusting rod 407, which in turn rotates the adjusting gear 406. The adjusting gear 406, through the rack 405, drives the adjusting plate 402 to adjust its position. During adjustment, the machining ring 402c can move synchronously with the adjusting plate 402 via the moving groove 402b and the L-shaped plate 402a. The adjusting plate 402, through the connecting plate 401, drives the hydraulic push rod 107 and the clamping component 108 to adjust their positions. To ensure the accuracy of the position adjustment, precise adjustment can be made by observing the pointer 404 and the scale 403. The worm gear 409 and the worm wheel 408 have a self-locking effect, which ensures the accuracy of the adjustment.
[0050] It should be noted that the machining ring 402c is hollow, which enables the machining ring 402c to position and limit electronic components, thereby improving the convenience of manufacturing.
[0051] The remaining structure is the same as that in Example 2.
[0052] Example 4
[0053] Reference Figures 1-6 This is the fourth embodiment of the present invention, which differs from the third embodiment in that: this embodiment provides an electronic component processing and manufacturing apparatus.
[0054] When grinding or drilling is required, the electronic components are positioned inside the processing ring 402c. Then, the hydraulic push rods 107 on both sides are activated, and the output end of the hydraulic push rods 107 drives the clamping component 108 to stably clamp the electronic components. After clamping, if drilling is required, the drill bit is installed, and if grinding is required, the grinding head is replaced. When manufacturing is required, by changing the grinding head or drill bit, and starting the drive motor 103, the output end of the drive motor 103 drives the electric telescopic rod 104 and the grinding head or drill bit to rotate. The electric telescopic rod 104 then adjusts the position of the grinding head or drill bit, enabling it to stably manufacture the clamped electronic components. During grinding, the output end of the drive motor 103 synchronously drives the first sprocket 301 to rotate, which in turn drives the second sprocket 303 via the chain 302. The second sprocket 303 drives the transmission rod 304 to rotate, which in turn drives the large gear 305a to rotate. The fixing part 306 and the mounting part 305c can engage the transmission rod 304 and the large gear 305a with the small gear. Wheel 305b is positioned to limit the rotation of transmission rod 304 and the large gear 305a and small gear 305b, ensuring the stability of their rotation. This allows the large gear 305a to drive the small gear 305b to rotate, which in turn drives the drive rod 305d to rotate. The drive rod 305d then drives the drive wheel 305e to rotate, which in turn drives the driven wheel 305f via a belt. The driven wheel 305f then drives the rotating rod 305g to rotate, which in turn drives the first pulley 305i and the impeller 305h to rotate. The first pulley 305i drives the second pulley 305j via a belt, which in turn drives the driven rod 305k to rotate. 05k synchronously drives the positive impeller 204c to rotate, so that the blades of the positive impeller 204c face upwards. The rotation generates thrust, which transmits water through the water storage tank 204a to the outlet pipe 204d. The outlet pipe 204d then transmits the water to the cooling coil 204f, which first cools the drive motor 103. The cooling coil 204f then transmits the water to the spray pipe 204g-1, which in turn transmits it to the telescopic pipe 204g-3. The mounting bracket 204g-2 secures the telescopic pipe 204g-3. When the clamp 105 moves, the mounting bracket 204g-2 drives the telescopic pipe 204g-3 to extend or retract, ensuring a stable water supply to the spray head 204g-4. The water spray head 204g-4 sprays water to cool and rinse the grinding heads and drill bits used in manufacturing. The rinse water then falls onto the worktable 101, processing tank 106, and recovery tank 305l-3. The backward-sloping recovery tank 305l-3 guides the water, allowing it to flow backward and carry impurities with it. The filter screen 305l-7 filters the water, and the front of the filter screen 305l-7 has a cleaning groove 305l-5. A cleaning frame 305l-6 is slidably installed inside the cleaning groove 305l-5. Due to gravity, the impurities filtered by the filter screen 305l-7 fall into the cleaning frame 305l-6, thus collecting the impurities.The drive rod 305d then synchronously drives the impeller 305h to rotate, so that the blades of the impeller face downwards. The rotation generates suction, which is transmitted through the recovery tank 305l-1 to the recovery pipe 305l-2. The recovery pipe 305l-2 is installed through the recovery hole, and then transmits the suction to the recovery head 305l-4. The recovery head 305l-4 extracts the filtered water and transmits it back to the recovery tank 305l-1 through the recovery pipe 305l-2. The recovery tank 305l-1 then transmits the water through the recovery port 202 to the inside of the water storage tank 201 for recycling. The water level line 203 allows the user to easily observe the water level inside the water storage tank 201. When the water level is low, it can be easily added by opening the sealed cover. When incomplete grinding or workpiece clamping deviations require adjustment, the knob 410 can be rotated to drive the worm gear 409, which in turn drives the worm wheel 408. The mounting bracket 204g-2 limits the movement of the worm gear 409, causing the worm wheel 408 to drive the adjusting gear 406 via the adjusting rod 407. The adjusting gear 406 then drives the adjusting plate 402 via the rack 405 for position adjustment. Finally, the adjusting plate 402 drives the hydraulic push rod 107 via the connecting plate 401. The clamping component 108 is position-adjusted, and during adjustment, the adjusting plate 402 drives the machining ring 402c to adjust its position synchronously through the L-shaped plate 402a. The adjustment value can be observed through the scale 403 and pointer 404 during adjustment, ensuring the accuracy of position adjustment. When the adjusting plate 402 moves, the slider 402d and the slide groove 402e can assist the adjusting plate 402 in sliding, ensuring the stability during adjustment. In addition, the worm gear 408 and worm 409 have a self-locking effect to prevent accidental activation of the adjusting plate 402 and the movement of the whole.
[0055] In summary, the drive motor 103 drives the transmission mechanism 300 to transmit power, which in turn drives the cooling mechanism 200 to cool the drive motor 103, the grinding head or drill bit, and to rinse the grinding head or drill bit, as well as to recycle the rinsed water. Finally, the adjustment mechanism 400 can improve the manufacturing quality.
[0056] It is important to note that the constructions and arrangements of this application shown in several different exemplary embodiments are merely illustrative. Although only a few embodiments are described in detail in this disclosure, those who consult this disclosure will readily understand that many modifications are possible without substantially departing from the novelty and advantages of the subject matter described in this application. For example, variations in the size, dimensions, structure, shape, and proportions of various elements, as well as parameter values such as temperature, pressure, etc., installation arrangements, use of materials, color, orientation, etc. For instance, an element shown as integrally formed may be composed of multiple parts or elements, the position of elements may be inverted or otherwise changed, and the nature or number or position of discrete elements may be altered or changed. Therefore, all such modifications are intended to be included within the scope of the invention. The order or sequence of any process or method steps may be changed or rearranged according to alternative embodiments. In the claims, any "device plus function" clause is intended to cover the structure performing the function described herein, and not only structurally equivalent but also equivalent in structure. Other substitutions, modifications, alterations, and omissions may be made in the design, operation, and arrangement of the exemplary embodiments without departing from the scope of the invention. Therefore, the present invention is not limited to the specific embodiments, but extends to various modifications that still fall within the scope of the appended claims. Furthermore, for the purpose of providing a concise description of exemplary embodiments, not all features of the actual embodiments may be omitted, i.e., those features not relevant to the currently considered best mode for carrying out the invention, or those features not relevant to implementing the invention.
[0057] It should be noted that the above embodiments are only used to illustrate the technical solutions of the present invention and are not intended to limit it. Although the present invention has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all such modifications or substitutions should be covered within the scope of the claims of the present invention.
Claims
1. An electronic component processing and manufacturing apparatus, characterized in that: include, A manufacturing mechanism (100) includes a workbench (101), a fixed plate (102) fixedly mounted on the top of the front side of the workbench (101), a drive motor (103) fixedly mounted on the bottom of the fixed plate (102), an electric telescopic rod (104) fixedly mounted on the output end of the drive motor (103), a chuck (105) fixedly mounted on the bottom of the electric telescopic rod (104), the bottom of the chuck (105) being able to easily engage a grinding head or a drill bit, a processing groove (106) being provided on the top of the workbench (101), and hydraulic push rods (107) being provided on both sides of the top of the workbench (101), with a clamping component (108) fixedly mounted on the output end of the hydraulic push rod (107); and, A cooling mechanism (200) is disposed on the top of the manufacturing mechanism (100). The cooling mechanism (200) includes a water storage tank (201). A sealing cover is connected to the rear side of the top left side of the water storage tank (201). A recycling port (202) is opened on the right side of the top of the water storage tank (201). A water level line (203) is opened on the front of the water storage tank (201). A heat dissipation component (204) is fixedly installed on the left side of the bottom inside the water storage tank (201). A transmission mechanism (300) is provided at the output end of the drive motor (103). The transmission mechanism (300) includes a first sprocket (301), which is fixedly installed at the output end of the drive motor (103). A second sprocket (303) is connected to the surface of the first sprocket (301) via a chain (302). A transmission rod (304) is fixedly installed inside the second sprocket (303). A drive assembly (305) is fixedly installed on the top of the transmission rod (304). A fixing member (306) is movably installed on the bottom of the transmission rod (304). The other end of the fixing member (306) is fixedly installed to the worktable (101). An adjustment mechanism (400) is provided on the front side of the top of the manufacturing mechanism (100).
2. The electronic component processing and manufacturing apparatus according to claim 1, characterized in that: The heat dissipation assembly (204) includes a water storage tank (204a), which is fixedly installed on the left side inside the water storage tank (201). A water inlet (204b) is provided at the bottom of the surface of the water storage tank (204a). Several water inlets (204b) are provided and are evenly distributed. A positive impeller (204c) is provided at the bottom inside the water storage tank (204a). A water outlet pipe (204d) is connected to the top of the water storage tank (204a). The other end of the water outlet pipe (204d) is connected to a heat dissipation coil (204f). The heat dissipation coil (204f) is wound around the surface of the drive motor (103). The other end of the heat dissipation coil (204f) is connected to a water spray component (204g).
3. The electronic component processing and manufacturing apparatus according to claim 2, characterized in that: The water spray component (204g) includes a water spray pipe (204g-1), which is connected to the other end of the heat sink coil (204f). A mounting bracket (204g-2) is movably installed on the left side of the clip (105). The other end of the water spray pipe (204g-1) is connected to a telescopic pipe (204g-3), which is fixedly installed inside the mounting bracket (204g-2). The other end of the telescopic pipe (204g-3) is connected to a water spray head (204g-4).
4. The electronic component processing and manufacturing apparatus according to claim 3, characterized in that: The drive assembly (305) includes a large gear (305a), which is fixedly mounted on the top of the transmission rod (304). A small gear (305b) meshes with the front of the large gear (305a). Mounting components (305c) are movably mounted on the top of the large gear (305a) and the bottom of the small gear (305b). The mounting components (305c) are fixedly mounted to the worktable (101) and the fixed plate (102) respectively. A drive rod (305d) is fixedly mounted on the top of the small gear (305b). A drive wheel (305e) is fixedly mounted on the surface of the drive rod (305d). A driven wheel (305f) is connected to the surface of the drive wheel (305e) via a belt drive. A rotating rod (305g) is fixedly installed inside the water storage tank (201) at the top of the rotating rod (305g). A reverse impeller (305h) is fixedly installed through the water storage tank (201). A first pulley (305i) is fixedly installed at the bottom of the surface of the rotating rod (305g). A second pulley (305j) is connected to the surface of the first pulley (305i) via belt drive. A driven rod (305k) is fixedly installed inside the second pulley (305j). The bottom of the driven rod (305k) is movably installed with the fixed plate (102). The driven rod (305k) is fixedly installed through the water storage tank (201) and the inside of the positive impeller (204c). The other end of the reverse impeller (305h) is connected to a recovery component (305l).
5. The electronic component processing and manufacturing apparatus according to claim 4, characterized in that: The recycling component (305l) includes a recycling bin (305l-1), which is connected to the top of the recycling port (202). The anti-reverse impeller (305h) is located inside the recycling bin (305l-1). A recycling pipe (305l-2) is connected to the top of the recycling bin (305l-1). A recycling hole for use with the recycling pipe (305l-2) is opened inside the workbench (101). The other end of the recycling pipe (305l-2) is connected to a recycling head. (305l-4), the back of the processing tank (106) is connected to a recycling tank (305l-3), the recycling tank (305l-3) is opened at a rearward inclination, the bottom of the recycling tank (305l-3) is connected to a cleaning tank (305l-5), a cleaning frame (305l-6) is slidably installed inside the cleaning tank (305l-5), and a filter screen (305l-7) located behind the cleaning tank (305l-5) is fixedly installed inside the rear side of the recycling tank (305l-3).
6. The electronic component processing and manufacturing apparatus according to claim 5, characterized in that: The adjusting mechanism (400) includes a connecting plate (401), which is fixedly installed on the outside of the hydraulic push rod (107). An adjusting plate (402) is fixedly installed on the front side of the inner side of the connecting plate (401). A scale (403) is provided on the top of the adjusting plate (402). A pointer (404) located on the back of the adjusting plate (402) is fixedly installed on the top of the worktable (101). A rack (405) is fixedly installed on the front side of the adjusting plate (402), and an adjusting gear (405) meshes with the front side of the rack (405). 6) The bottom of the adjusting gear (406) is movably installed on the workbench (101). An adjusting rod (407) is fixedly installed on the top of the adjusting gear (406). A worm gear (408) is fixedly installed on the top of the adjusting rod (407). A worm (409) is meshed on the front of the worm gear (408). A mounting bracket (204g-2) is movably installed on the surface of the worm (409). The bottom of the mounting bracket (204g-2) is fixedly installed on the workbench (101). A knob (410) is fixedly installed on the right end of the worm (409).
7. The electronic component processing and manufacturing apparatus according to claim 6, characterized in that: An L-shaped plate (402a) is fixedly installed at the bottom of the adjusting plate (402), and a moving groove (402b) for use with the L-shaped plate (402a) is connected to the front side inside the processing groove (106). A processing ring (402c) is fixedly installed on the back of the L-shaped plate (402a).
8. The electronic component processing and manufacturing apparatus according to claim 7, characterized in that: The adjustment plate (402) has sliders (402d) fixedly installed on both sides of its front side. The top of the workbench (101) is provided with a slide groove (402e) for use with the sliders (402d). The sliders (402d) and the slide groove (402e) are slidably connected.
9. A method for processing and manufacturing electronic components, characterized in that: Includes an electronic component processing and manufacturing apparatus as described in any one of claims 1 to 8. It also includes, When the drive motor (103) is working, the output end can drive the transmission mechanism (300) to rotate synchronously, and then the transmission mechanism (300) drives the cooling mechanism (200) to work synchronously, so that the cooling mechanism (200) can cool the drive motor (103) and the grinding head or drill bit, and rinse the grinding head or drill bit. Then the transmission mechanism (300) drives the recycling component (305l) to recycle and reuse the rinsed water.
10. The method for processing and manufacturing electronic components according to claim 9, characterized in that: include, When the sides of the grinding head are not completely ground, the electronic components held by the adjustment mechanism (400) can be adjusted left and right at will, so that the grinding device can grind the electronic components more thoroughly.