CN113183103A

CN113183103A - Computer processing assembly quality

Info

Publication number: CN113183103A
Application number: CN202110464154.6A
Authority: CN
Inventors: 洪世勇
Original assignee: Individual
Current assignee: Beijing Shenzhou Digital Cloud Information Technology Co ltd; Shenzhou Kuntai Xiamen Information Technology Co ltd
Priority date: 2021-04-28
Filing date: 2021-04-28
Publication date: 2021-07-30
Anticipated expiration: 2041-04-28
Also published as: CN113183103B

Abstract

The utility model provides a computer processing assembly quality, includes drive arrangement, positioner, rotating device, operation panel, and drive arrangement includes actuating lever, connecting rod, slider, gyro wheel, extension spring, and positioner includes location cap, pin, spring, and rotating device includes positioner, hopper, operation panel, swivel stand, the inner chamber has in the middle of the operation panel, has the pivot hole in the middle of the inner chamber, and the operation panel left side has the spout, and the operation panel lower part has four supporting legs, and two supporting leg lower parts in the rear side have the axle of connecting two supporting legs, and rear side supporting leg lower part has the spring axle, has the locating surface in the middle of two supporting legs in the left side.

Description

Computer processing assembly quality

Technical Field

The invention relates to the field of computers, in particular to a computer processing and assembling device.

Background

At computer processing, assembly, in the testing process, often need rotate the product to satisfy the work demand of different stations, traditional way needs to stop work in hand, then the manual work is stirred, wastes time, difficultly, influences work efficiency.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a computer processing and assembling device.

The purpose of the invention is realized by the following technical scheme:

a computer processing assembly device comprises a driving device, a positioning device, a rotating device and an operating platform, wherein the driving device comprises a driving rod, a connecting rod, a sliding block, a roller and a tension spring, the positioning device comprises a positioning cap, a pin and a spring, the rotating device comprises a positioning device, a hopper, an operating surface and a rotating platform, an inner cavity is arranged in the middle of the operating platform, a rotating shaft hole is formed in the middle of the inner cavity, a sliding groove is formed in the left side of the operating platform, four supporting legs are arranged at the lower part of the operating platform, shafts for connecting the two supporting legs are arranged at the lower parts of the two supporting legs at the rear side, a spring shaft is arranged at the lower part of the supporting leg at the rear side, and a positioning surface is arranged in the middle of the two supporting legs at the left side; the front part of the driving rod is provided with a pedal, the rear side of the pedal is provided with a shaft hole, the rear side of the shaft hole is provided with a pin shaft, the upper part of the driving rod is provided with a connecting rod hole, the front part of the sliding block is provided with a sliding block groove, two sides of the sliding block groove are provided with roller holes, the rear side of the sliding block is provided with a connecting hole, and the middle of the roller is provided with a roller; the connecting shaft is rotated in the shaft hole, the shaft hole rotates around the shaft, the upper side of the tension spring is fixedly connected with the pin shaft, the lower side of the tension spring is fixedly connected with the spring shaft, the lower part of the connecting rod is hinged with the rod hole, the upper part of the connecting rod is hinged with the connecting hole, the roller is clamped in the middle of the sliding block groove, the roller is rotatably connected with the roller hole, the roller rotates in the roller hole, the sliding block is slidably connected with the sliding groove, and the sliding block slides in the sliding groove; the middle of the positioning cap is provided with a pin hole, the upper part of the pin is provided with a boss, the lower part of the pin is provided with a conical head, the pin is connected with the pin hole in a sliding mode, a spring is placed in the middle of the pin hole, the upper part of the spring abuts against the upper part of the pin hole, and the lower part of the spring abuts against the upper part of the boss.

The utility model discloses a computer, including hopper, locating pin hole, swivel mount head, pivot hole, locating pin hole rear side, the inner chamber has in the middle of the hopper, the hexagonal hole has in the middle of the inner chamber, the hole has in the middle of the operation panel, the hole has in the middle of the hole, the hole rear side has the locating pin hole, four spherical recess of swivel mount head terminal surface equipartition, it is protruding to have the hexagonal in the middle of the swivel mount head, the swivel mount head lower part has the pivot, the pivot is rotated and is connected the pivot hole, the pivot rotates in the pivot hole, locating pin hole fixed connection position cap, when the swivel mount head is static, conical head and spherical recess contact, and the contact of gyro wheel excircle and the upper left corner rear side of swivel mount head, operation panel lower part fixed connection operation panel upper portion, the hexagonal is protruding to pass the hole, the hopper is placed on operation panel upper portion, hexagonal hole fixed connection hexagonal is protruding, the inside computer work piece of placing of inner chamber.

An operation method of a computer machining assembly device is characterized by comprising the following steps: step 1, treading a pedal, rotating a driving rod around a shaft, driving a connecting rod to move towards the inner side by a connecting rod hole, drawing a tension spring under stress, driving a sliding block to slide forwards along a sliding groove by the connecting rod, step 2, driving a roller to push the upper left corner of a rotating device by the sliding block, starting to rotate a rotating platform until the rear side surface of the rotating platform is contacted with the left side surface of the sliding block, rotating the rotating platform just over approximately 90 degrees at the moment, driving a computer workpiece to rotate by the rotating platform, and the cone head just at the edge of the next spherical groove, step 3, loosening the pedal, driving the driving rod to rotate backwards under the action of the tension spring, driving the connecting rod to pull the connecting rod to move outwards, driving the sliding block to slide outwards and backwards along the sliding groove by the connecting rod, stopping when the driving rod is contacted with the lower surface of a positioning surface, and then the roller is separated from the rear side of the rotating platform and has a certain gap, step 4, after the roller is separated from the rear side edge of the rotating platform, the rotating platform loses support, the conical head is just positioned at the edge of the spherical groove, the spring presses the conical head to move downwards after the rotating table loses support, the conical head is pressed into the spherical groove, the rotating table rotates under the pressing of the conical head until the conical head and the spherical groove are completely contacted and positioned, at the moment, the upper left corner of the rotating table is contacted with the outer circle of the roller, step 5, when the pedal is treaded next time, the sliding block drives the rotating table to rotate, the rotating table rotates by approximately 90 degrees after the pedal is treaded once, and the computer workpiece rotates by one station.

Has the advantages that:

the positioning surface adopts an inclined surface structure, the contact area of the positioning surface and the driving rod is increased, when the driving rod is prevented from rebounding, the impact force is too large to damage the driving rod, the sliding block and the sliding groove are of a rectangular structure, the guide area is large, the sliding block can slide stably in the front and back direction and cannot be inclined or stuck, the roller can be guaranteed to smoothly push the rotating table, when the rotating table is pushed, the roller structure is adopted, the torque required by the rotation of the rotating table is realized, the rotating table and the roller are prevented from being mutually stuck, meanwhile, the friction between the roller and the rotating table is reduced, the positioning device is positioned at the lower part of the operating surface, the spherical groove is positioned at the upper part of the rotating table, when the roller is separated from the left side edge of the rotating table, the conical head can press the left side edge of the spherical groove and slide along the spherical groove, the spherical groove is completely contacted with the conical head, and the contact between the roller and the left upper corner of the rotating table is guaranteed.

Drawings

Fig. 1 is a schematic view of the overall structure of the computer processing assembling device of the present invention.

Fig. 2 is a schematic diagram of an explosive structure of the computer processing assembly device according to the present invention.

Fig. 3 is a schematic structural diagram of a driving device according to the present invention.

Fig. 4 is a schematic diagram of an explosive structure of the driving device according to the present invention.

Fig. 5 is a schematic view of a connection structure of the driving device according to the present invention.

Fig. 6 is a schematic structural diagram of a positioning device according to the present invention.

Fig. 7 is a schematic structural diagram of a rotating device according to the present invention.

Fig. 8 is a schematic cross-sectional front structural view of the computer-machining assembling device according to the present invention.

Fig. 9 is a schematic cross-sectional three-dimensional structure diagram of the computer processing assembling device according to the present invention.

FIG. 10 is a schematic top view of the computer-based assembly apparatus of the present invention.

Fig. 11 is a schematic structural diagram of the operation table according to the present invention.

Fig. 12 is a schematic view of the bottom structure of the console according to the present invention.

Fig. 13 is a schematic top view of the turntable according to the present invention.

Fig. 14 is a schematic view of the bottom structure of the turntable according to the present invention.

Fig. 15 is a schematic structural diagram of a rotating table according to the present invention.

Detailed Description

The invention is explained in more detail below with reference to the figures and examples:

a computer processing assembly device comprises a driving device 100, a positioning device 200, a rotating device 300 and an operating platform 410, wherein the driving device 100 comprises a driving rod 110, a connecting rod 120, a sliding block 130, a roller 140 and a tension spring 150, the positioning device 200 comprises a positioning cap 210, a pin 220 and a spring 230, the rotating device 300 comprises a positioning device 200, a hopper 310, an operating surface 320 and a rotating platform 330, an inner cavity 411 is arranged in the middle of the operating platform 410, a rotating shaft hole 412 is arranged in the middle of the inner cavity 411, a sliding groove 413 is arranged on the left side of the operating platform 410, four supporting legs 417 are arranged on the lower portion of the operating platform 410, shafts 414 connecting two supporting legs 417 are arranged on the lower portion of two supporting legs 417 on the rear side, a spring shaft 416 is arranged on the lower portion of the supporting leg 417 on the rear side, and a supporting leg 415 on the positioning surface is arranged in the middle of two supporting legs 417 on the left side.

The front of the driving rod 110 is provided with a pedal 111, the rear side of the pedal 111 is provided with a shaft hole 112, the rear side of the shaft hole 112 is provided with a pin 113, the upper part of the driving rod 110 is provided with a connecting rod hole 114, the front of the slider 130 is provided with a slider groove 131, two sides of the slider groove 131 are provided with roller holes 132, the rear side of the slider 130 is provided with a connecting hole 133, and the middle of the roller 140 is provided with a roller 141.

The shaft hole 112 rotates to connect the shaft 414, the upper side of the tension spring 150 is fixedly connected with the pin shaft 113, the lower side of the tension spring 150 is fixedly connected with the spring shaft 416, the lower part of the connecting rod 120 is hinged to the rod hole 114, the upper part of the connecting rod 120 is hinged to the connecting hole 133, the roller 140 is clamped in the middle of the sliding block groove 131, the roller 141 rotates to connect the roller hole 132, the roller 141 rotates in the roller hole 132, the sliding block 130 is slidably connected with the sliding groove 413, and the sliding block 130 slides in the sliding groove 413.

The positioning cap 210 has a pin hole 211 in the middle, the upper part of the pin 220 has a boss, the lower part of the pin 220 has a conical head 222, the pin 220 is slidably connected with the pin hole 211, a spring 230 is placed in the middle of the pin hole 211, the upper part of the spring 230 is abutted against the upper part of the pin hole 211, and the lower part of the spring 230 is abutted against the upper part of the boss.

The middle of the hopper 310 is provided with an inner cavity 311, the middle of the inner cavity 311 is provided with a hexagonal hole 312, the middle of the operation surface 320 is provided with an inner hole 321, the rear side of the inner hole 321 is provided with a positioning pin hole 322, four spherical grooves 332 are uniformly distributed on the end surface of the rotating table 330, the middle of the rotating table 330 is provided with a hexagonal bulge 331, the lower part of the rotating table 330 is provided with a rotating shaft 333, the rotating shaft 333 is rotatably connected with the rotating shaft hole 412, the rotating shaft 333 rotates in the rotating shaft hole 412, the positioning pin hole 322 is fixedly connected with the positioning cap 210, when the rotating table 330 is static, a conical head is contacted with the spherical grooves 332, the outer circle of the roller 140 is contacted with the rear side of the upper left corner of the rotating table 330, the lower part of the operation surface 320 is fixedly connected with the upper part of the operation table 410, the hexagonal bulge 331 penetrates through the inner hole 321, the hopper 310 is placed on the upper part of the operation surface 320, the hexagonal hole 312 is fixedly connected with the hexagonal bulge 331, and the computer workpiece 340 is placed in the inner cavity 311.

A method of operating a computer-machined assembly apparatus, comprising the steps of: step 1, the pedal 111 is stepped on, the driving rod 110 rotates around the shaft 414, the connecting rod hole 114 drives the connecting rod 120 to move towards the inner side, the tension spring 150 is stressed and stretched, the connecting rod 120 drives the sliding block 130 to slide forwards along the sliding groove 413, step 2, the sliding block 130 drives the roller 140 to push the upper left corner of the rotating device 300 to prevent dislocation, the rotating table 330 starts to rotate until the rear side surface of the rotating table 330 contacts with the left side surface of the sliding block 130, at the moment, the rotating table 330 just rotates for approximately 90 degrees, the rotating table 330 drives the computer workpiece 340 to rotate for one station, at the moment, the conical head is just positioned at the edge of the next spherical groove 332, step 3, the pedal 111 is released, the driving rod 110 rotates backwards under the elastic force of the tension spring 150, the driving rod 110 pulls the connecting rod 120 to move towards the outer side, the connecting rod 120 drives the sliding block 130 to move outwards and backwards along the sliding groove 413, the driving rod 110 stops when contacting with the positioning surface 415, at the roller 140 breaks away from the rear side of the rotating table 330 and has a certain gap, step 4, after the roller 140 is separated from the rear side edge of the rotating table 330, the rotating table 330 loses support, the conical head is just positioned at the edge of the spherical groove 332, the spring 230 presses the conical head to move downwards after the rotating table 330 loses support, the conical head is pressed into the spherical groove 332, the rotating table 330 rotates under the pressing of the conical head until the conical head and the spherical groove 332 are completely contacted and positioned, the upper left corner of the rotating table 330 is contacted with the excircle of the roller 140 at the moment, and step 5, when the pedal 111 is stepped next time, the sliding block 130 drives the rotating table 330 to rotate, and when the pedal 111 is stepped once, the rotating table 330 rotates by approximately 90 degrees, and the computer workpiece 340 rotates by one station. The accuracy and the processing and assembling success rate of drilling processing and assembling are improved.

The corner of the sliding block 130 is arc-shaped, and the sliding block 130, the positioning surface 415, the spring 230, the conical head 222, the spherical groove 332 and the driving rod 110 are matched together, so that the rotating table 330 is accurately positioned, stably rotates, smoothly runs in a matched manner and is prevented from being stuck, and the computer workpiece 340 is accurately drilled, machined and assembled to be high in power and high in assembly efficiency;

under slider 130 and the cooperation of revolving stage 330, realized that revolving stage 330 is steady to be decided to rotate at cavity 411 and operation panel 320 internal water, the space that cavity 411 and operation panel 320 formed has guaranteed that revolving stage 330 level rotates steadily, prevents to rotate the in-process revolving stage and takes place to vibrate and cause hopper 310 to rock, influences the accuracy of computer work piece 340 drilling processing assembly and has reduced the processing assembly success rate.

The positioning surface 415 adopts an inclined surface structure, which increases the contact area between the positioning surface 415 and the driving rod 110, prevents the driving rod 110 from rebounding, and damages the driving rod 110 due to excessive impact force, the sliding block 130 and the sliding groove 413 are rectangular structures, and have large guide area, thereby preventing the dislocation of the rotating table, enabling the sliding block 130 to slide stably in the front and back direction, without skewing, without affecting the accuracy of drilling, processing and assembling of the computer workpiece 340, ensuring that the roller 140 can smoothly push the rotating table 330, and when the rotating table 330 is pushed, adopting a roller structure, which not only realizes the torque required by the rotation of the rotating table 330, but also prevents the rotating table 330 and the roller 140 from being mutually clamped, preventing the dislocation of the rotating table, and simultaneously reducing the friction between the roller 140 and the rotating table 330, the positioning device 200 is positioned at the lower part of the operating surface 320, the spherical groove 332 is positioned at the upper part of the rotating table 330, and ensuring that when the roller 140 is separated from the left side edge of the rotating table 330, the conical head can press the left side edge of the spherical groove 332 and slide along the surface of the spherical groove 332, and the rotating table 330 is pushed to rotate by a certain angle until the spherical groove 332 is completely contacted with the conical head, so that the contact between the roller 140 and the upper left corner of the rotating table 330 is ensured, and the operation is smooth. The invention realizes that the computer workpiece 340 is accurately drilled, processed and assembled with high power and high assembly efficiency.

Claims

1. A computer processing assembly device is characterized by comprising a driving device, a positioning device, a rotating device and an operating platform, wherein the driving device comprises a driving rod, a connecting rod, a sliding block, a roller and a tension spring, the positioning device comprises a positioning cap, a pin and a spring, the rotating device comprises a positioning device, a hopper, an operating surface and a rotating platform, an inner cavity is arranged in the middle of the operating platform, a rotating shaft hole is formed in the middle of the inner cavity, a sliding groove is formed in the left side of the operating platform, four supporting legs are arranged at the lower part of the operating platform, shafts for connecting the two supporting legs are arranged at the lower parts of the two supporting legs at the rear side, a spring shaft is arranged at; the front part of the driving rod is provided with a pedal, the rear side of the pedal is provided with a shaft hole, the rear side of the shaft hole is provided with a pin shaft, the upper part of the driving rod is provided with a connecting rod hole, the front part of the sliding block is provided with a sliding block groove, two sides of the sliding block groove are provided with roller holes, the rear side of the sliding block is provided with a connecting hole, and the middle of the roller is provided with a roller; the connecting shaft is rotated in the shaft hole, the shaft hole rotates around the shaft, the upper side of the tension spring is fixedly connected with the pin shaft, the lower side of the tension spring is fixedly connected with the spring shaft, the lower part of the connecting rod is hinged with the rod hole, the upper part of the connecting rod is hinged with the connecting hole, the roller is clamped in the middle of the sliding block groove, the roller is rotatably connected with the roller hole, the roller rotates in the roller hole, the sliding block is slidably connected with the sliding groove, and the sliding block slides in the sliding groove; the middle of the positioning cap is provided with a pin hole, the upper part of the pin is provided with a boss, the lower part of the pin is provided with a conical head, the pin is connected with the pin hole in a sliding mode, a spring is placed in the middle of the pin hole, the upper part of the spring abuts against the upper part of the pin hole, and the lower part of the spring abuts against the upper part.

2. The computer processing and assembling device of claim 1, wherein the hopper has an inner cavity therein, the inner cavity has a hexagonal hole therein, the operating surface has an inner hole therein, the rear side of the inner hole has a positioning pin hole, four spherical recesses are uniformly distributed on the end surface of the turntable, a hexagonal protrusion is provided in the middle of the turntable, the lower portion of the turntable has a rotating shaft rotatably connected to the rotating shaft hole, the rotating shaft rotates in the rotating shaft hole, the positioning pin hole is fixedly connected to the positioning cap, the rotating table is stationary, the conical head is contacted to the spherical recess, the outer circle of the roller is contacted to the rear side of the upper left corner of the turntable, the lower portion of the operating surface is fixedly connected to the upper portion of the turntable, the hexagonal protrusion passes through the inner hole, the hopper is placed on the upper portion of the operating surface, the hexagonal hole is fixedly connected to the hexagonal protrusion, and a computer workpiece is placed in the inner cavity.

3. The method of claim 1, further comprising the steps of: step 1, a pedal is stepped on, a driving rod rotates around a shaft, a connecting rod hole drives a connecting rod to move towards the inner side, a tension spring is stressed and stretched, and the connecting rod drives a sliding block to slide forwards along a sliding groove; step 2, the slide block drives the roller to push the upper left corner of the rotating device, the rotating table starts to rotate until the rear side face of the rotating table is contacted with the left side face of the slide block, the rotating table just rotates for approximately 90 degrees at the moment, the rotating table drives a computer workpiece to rotate for one station, and the conical head just locates at the edge of the next spherical groove at the moment; step 3, the pedal is loosened, the driving rod rotates under the action of the elasticity of the tension spring, the driving rod pulls the connecting rod to move towards the outer side, the connecting rod drives the sliding block to slide towards the outer rear side along the sliding groove, the driving rod stops when contacting the lower surface of the positioning surface, and at the moment, the idler wheel is separated from the rear side of the rotating table and has a certain gap; step 4, after the roller wheel is separated from the rear side edge of the rotating table, the rotating table loses support, the conical head is just positioned at the edge of the spherical groove, the spring presses the conical head to move downwards after the rotating table loses support, the conical head is pressed into the spherical groove, the rotating table rotates under the pressing of the conical head until the conical head and the spherical groove are completely contacted and positioned, and at the moment, the upper left corner of the rotating table is contacted with the outer circle of the roller wheel; and 5, when the pedal is treaded next time, the sliding block drives the rotating platform to rotate, the rotating platform rotates by approximately 90 degrees every time the pedal is treaded, and the computer workpiece rotates by one station.