CN115385139A - Intelligent electronic device production equipment and production method based on Internet of things - Google Patents

Abstract

The invention provides an electronic device intelligent production device based on the Internet of things, which comprises: a support; the transposition shaft is rotatably connected to the middle part of the upper end of the bracket through a bearing; the station disc is fixed at the end part of the indexing shaft; the driving sleeve rod is connected to the station disc in an equidistant rotating mode through a bearing and used for being sleeved with a winding core for winding the residual heat dissipation film; the winding device is fixed on the outer wall of the driving sleeve rod and used for driving the driving sleeve rod to rotate to complete the winding work of the residual heat dissipation film; the switching device is arranged on the bracket; the invention can complete the replacement work of the winding core while the whole equipment does not stop to perform the winding work, saves the time of shutdown operation compared with the traditional equipment which manually performs the feeding and discharging work of the winding shaft after stopping, thereby improving the production efficiency of the heat dissipation film, and has simple steps of dismounting and mounting the winding core, saving manpower and being convenient for operation.

Description

Intelligent electronic device production equipment and production method based on Internet of things

Technical Field

The invention relates to the technical field of electronic device production equipment, in particular to electronic device intelligent production equipment and a production method based on the Internet of things.

Background

The common products of the protective functional devices comprise a lens protective film, a camera protective film, a battery cover heat-conducting film, a screen explosion-proof film and the like, wherein the battery cover heat-conducting film is usually a graphene heat-radiating film, the production of the battery cover heat-radiating film is in a required shape by die-cutting of a heat-radiating film stuck on plastic paper through die-cutting equipment, then the residual heat-radiating film is uncovered, the residual heat-radiating film is wound along with the plastic paper, the die-cutting equipment, the unwinding equipment, the finished product winding equipment and the residual heat-radiating film winding equipment are usually involved in the die-cutting work, and along with the technical development of the internet of things, the existing related die-cutting equipment for producing the heat-radiating film carries out the internet of things, so that the working conditions of all the equipment can be checked in real time through a client terminal;

but there is certain problem when remaining heat dissipation membrane rolling equipment based on thing networking in the current graphite alkene heat dissipation membrane cross cutting working process uses: the rolling work of remaining radiating film is carried out to setting up a wind-up roll to current usually, need shut down the operation after this wind-up roll is fully loaded with, takes off through the manual work and changes empty wind-up roll this wind-up roll, and then the manual work will treat the remaining radiating film of rolling to paste on new wind-up roll again, and then just can continue to carry out rolling work, and the very big manpower of having wasted of this kind of operation, and reduced efficiency.

Therefore, there is a need to provide a new electronic device intelligent production apparatus and a production method based on the internet of things to solve the above technical problems.

Disclosure of Invention

In order to solve the technical problems, the invention provides electronic device intelligent production equipment and a production method based on the Internet of things.

The invention provides an electronic device intelligent production device based on the Internet of things, which comprises:

a support;

the transposition shaft is rotatably connected to the middle part of the upper end of the bracket through a bearing;

the station disc is fixed at the end part of the indexing shaft;

the driving sleeve rod is connected to the station disc in an equidistance rotating mode through a bearing and used for being sleeved with a rolling core for rolling the residual heat dissipation film;

the winding device is fixed on the outer wall of the driving sleeve rod and used for driving the driving sleeve rod to rotate to complete the winding work of the residual heat dissipation film;

the switching device is arranged on the support, and consists of a switching component, an auxiliary component and a follow-up positioning component, wherein the switching component is arranged on the support and used for driving the station disc to rotate so as to switch stations, the auxiliary component is arranged on the support and used for cutting off the residual heat dissipation film and pressing and pasting the cut residual heat dissipation film to be wound on the winding core, the follow-up positioning component is used for positioning the winding core and removing the positioning work in the conversion working process, and the switching component, the auxiliary component and the follow-up positioning component are linked.

Preferably, the winding device comprises:

the driven gear is fixed at the end part of the driving sleeve rod;

the first motors are fixed on the surface of the station disc, and the number of the first motors is the same as that of the driving sleeve rods;

the driving gear is fixed at the output end of the first motor and is in meshed connection with the driven gear.

Preferably, the switching assembly includes:

the second motor is fixed on the surface of the support, and the output end of the second motor is rotatably connected with the support through a bearing;

the driving wheel is fixed at the output end of the second motor;

the grooved wheel is fixed at one end of the turning shaft, which is far away from the station disc, and the grooved wheel is matched with the driving wheel.

Preferably, the auxiliary assembly comprises:

the two groups of supporting rods are symmetrically fixed on one side, close to the second motor, of the surface of the bracket;

the lifting frame is connected to the outer walls of the four supporting rods in a sliding mode through the sliding holes;

the first spring is sleeved on the outer side of the supporting rod, the upper end of the first spring is in extrusion contact with the bottom of the lifting frame, and the bottom of the first spring is in extrusion contact with the surface of the support;

the cam is fixed at the output end of the second motor and is in extrusion contact with the outer wall of the lifting frame;

the connecting sleeve is fixed on the surface of the lifting frame and is positioned right above one driving sleeve rod positioned above the lifting frame;

the second spring is fixed on the inner wall of the connecting sleeve;

the contraction block is connected to the inner wall of the connecting sleeve in a sliding mode, and the bottom of the second spring is fixed to the surface of the contraction block;

the arc-shaped pressing strip is fixed at the bottom of the contraction block and is opposite to the upper coiling core;

the cutting connecting frame is fixed at the upper end of the lifting frame;

the electric heating wire is fixed at the lower end of the cutting connecting frame;

the axial directions of the electric heating wire, the arc-shaped pressing strip and the winding core are the same.

Preferably, the cambered surface of the lower end of the cambered pressing strip is matched with the cambered surface of the outer side of the winding core in shape.

Preferably, the following positioning component comprises:

the opening is arranged in the middle of the outer wall of the driving loop bar and penetrates through the side wall of the driving loop bar;

the abutting block is connected to the inner side of the opening in a sliding mode, and an anti-skid pad is fixed at one end, far away from the inner side of the driving sleeve rod, of the abutting block;

the third springs are symmetrically fixed on the outer wall of the abutting block, and one ends of the third springs, far away from the abutting block, are fixed with the inner wall of the driving loop bar;

the driving inclined block is arranged on the inner side of the driving sleeve rod in a sliding mode, and the inclined surface of the driving inclined block is in extrusion contact with the surface of the abutting block;

the fourth spring is fixed at the end part of the driving inclined block, and one end of the fourth spring, which is far away from the driving inclined block, is fixed with the inner wall of the driving sleeve rod;

the sliding rod is connected to the inner wall of the driving sleeve rod in a sliding mode, and one end of the sliding rod is fixed to the outer wall of the driving inclined block;

the universal roller is fixed at the end part of the sliding rod;

the driving guide rail is fixed on the outer wall of the support, and the universal roller is in contact with the outer wall of the driving guide rail.

Preferably, the outer side of the non-slip mat is arranged in an arc shape.

Preferably, the first motor and the second motor are both speed reduction motors.

Preferably, one side of the lower end of the abutting block, which is in contact with the inclined plane of the driving inclined block, is provided with a fillet.

The invention also provides a production method, which adopts any intelligent electronic device production equipment based on the Internet of things for production.

Compared with the related art, the intelligent electronic device production equipment and the intelligent electronic device production method based on the Internet of things have the following beneficial effects:

1. the invention can complete the replacement work of the winding core while the whole equipment does not stop to perform the winding work, and saves the time of shutdown operation compared with the traditional equipment which manually performs the feeding and discharging work of the winding shaft after stopping, thereby improving the production efficiency of the heat dissipation film;

2. according to the invention, by arranging the switching device, the transposition work of the winding core, the cutting work of the heat dissipation film, the work of pressing the heat dissipation film to be wound on the surface of a newly-in-place winding core after cutting, the positioning work of the winding core at a newly-in-place winding station and the unlocking work of the winding core with the fully-loaded heat dissipation film separated from the winding station can be completed in a linkage manner, namely, a plurality of works can be completed in sequence in a linkage manner by driving of a second motor without the cooperation of a plurality of motors, so that the whole equipment is more stable and reliable in operation;

3. according to the invention, the positioning and the positioning relieving work of the winding cores on different stations can be simultaneously completed by the arranged follow-up positioning assembly after the transposition is completed, so that the empty winding core is inserted into the outer side of the driving sleeve rod after the winding shaft is manually replaced, the complex disassembly and assembly work is not required to be manually performed, the labor is further saved, and the use is convenient.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic structural view of a winding device according to the present invention;

FIG. 3 is a schematic structural diagram of a switching assembly according to the present invention;

FIG. 4 is a schematic structural diagram of an auxiliary assembly according to the present invention;

FIG. 5 is a second schematic view of the auxiliary assembly of the present invention;

FIG. 6 is a third schematic view of an auxiliary assembly according to the present invention;

FIG. 7 is a schematic structural diagram of a servo positioning assembly according to the present invention;

FIG. 8 is a second schematic structural view of a servo positioning assembly of the present invention;

FIG. 9 is an enlarged view of the invention at A;

FIG. 10 is a third structural illustration of the follower positioning assembly of the present invention;

fig. 11 is a fourth structural schematic of the follow-up positioning assembly of the present invention.

Reference numbers in the figures: 1. a support; 100. winding the core; 2. a displacement shaft; 3. a station disc; 4. driving the loop bar; 5. a winding device; 51. a driven gear; 52. a first motor; 53. a driving gear; 6. a switching device; 61. a switching component; 611. a second motor; 612. a drive wheel; 613. a grooved wheel; 62. an auxiliary component; 621. a strut; 622. a lifting frame; 623. a first spring; 624. a cam; 625. connecting sleeves; 626. a second spring; 627. a contraction block; 628. an arc-shaped layering; 629. cutting off the connecting frame; 6210. an electric heating wire; 63. a follow-up positioning component; 631. an opening; 632. a propping block; 632a, a non-slip mat; 633. a third spring; 634. driving the swash block; 635. a fourth spring; 636. a slide bar; 637. a universal roller; 638. the guide rail is driven.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Specific implementations of the present invention are described in detail below with reference to specific embodiments.

Referring to fig. 1 to 11, an electronic device intelligent production apparatus based on the internet of things according to an embodiment of the present invention includes a support 1, an indexing shaft 2, a station disc 3, a driving loop bar 4, a winding device 5 and a switching device 6,

the device comprises a position-changing shaft 2, a position disc 3, a driving sleeve rod 4, a switching device 6, an auxiliary assembly 62 and a follow-up positioning assembly 63, wherein the position-changing shaft 2 is rotationally connected to the middle of the upper end of a support 1 through a bearing, the position disc 3 is fixed at the end part of the position-changing shaft 2, the driving sleeve rod 4 is rotationally connected to the position disc 3 at equal intervals through the bearing and is used for sleeving a winding core 100 for winding a residual heat-radiating film, the winding device 5 is fixed on the outer wall of the driving sleeve rod 4 and is used for driving the driving sleeve rod 4 to rotate to complete the winding work of the residual heat-radiating film, the switching device 6 is arranged on the support 1 and consists of a switching assembly 61, a position-changing assembly 61, a follow-up positioning assembly 63 and a follow-up positioning assembly 63, wherein the switching assembly 61 is arranged on the support 1 and is used for driving the position disc 3 to rotate to carry out the position-changing work, the residual heat-radiating film to be cut off and wound is tightly pressed and adhered to the winding core 100 and is adhered to the winding core 100 in the conversion work process, and the switching assembly 61, and the follow-up positioning assembly 63 is linked with the follow-up positioning assembly 63;

according to the winding core 100 automatic turning device, a winding core 100 can be automatically turned away from a winding station after being wound to a certain amount of residual heat dissipation films, meanwhile, an empty winding core 100 can be automatically turned to the winding station, the residual heat dissipation films can be quickly cut off after being turned in place, the residual heat dissipation films to be wound can be pressed and stuck on the newly-turned winding core 100 before being cut off, the positioning and the positioning releasing work of the winding core 100 can be automatically completed while being turned, the whole operation can be continuously carried out without stopping the device, and after the transposition work of the full-load winding core 100 is completed, people can directly need to change the full-load winding core 100 to the empty winding core 100 without stopping the device to carry out loading and unloading work, so that the production efficiency is greatly improved, the manual replacement operation is convenient, and the manpower is greatly saved;

it is emphasized that the whole device is required to be ensured to be in a horizontal state during operation;

the winding device 5 comprises a driven gear 51, a first motor 52 and driving gears 53, wherein the driven gear 51 is fixed at the end part of the driving sleeve rod 4, the first motors 52 are fixed on the surface of the station disc 3, the number of the first motors is the same as that of the driving sleeve rod 4, the driving gears 53 are fixed at the output end of the first motors 52, and the driving gears 53 are meshed with the driven gear 51.

It should be noted that when one driving loop bar 4 located above needs to rotate to perform winding work, the first motor 52 is driven to rotate to drive the driving gear 53 to rotate, the driven gear 51 is poked to rotate, and then the driving loop bar 4 is driven to rotate, so that the winding core 100 can be driven to rotate to perform winding work of the residual heat dissipation film;

the switching assembly 61 comprises a second motor 611, a driving wheel 612 and a grooved wheel 613, the second motor 611 is fixed on the surface of the support 1, the output end of the second motor 611 is rotatably connected with the support 1 through a bearing, the driving wheel 612 is fixed on the output end of the second motor 611, the grooved wheel 613 is fixed on one end of the indexing shaft 2 far away from the station disc 3, and the grooved wheel 613 is matched with the driving wheel 612.

After a certain amount of residual heat dissipation film is wound on one winding core 100 positioned above, the second motor 611 is driven to rotate to drive the driving wheel 612 to rotate for a circle, and the grooved pulley 613 is driven to rotate for 90 degrees, so that the station disc 3 rotates for 90 degrees, a full winding core 100 rotates to leave the winding station, and an empty winding core 100 rotates to the winding station to perform winding work;

the auxiliary component 62 comprises a support 621, a lifting frame 622, a first spring 623, a cam 624, a connecting sleeve 625, a second spring 626, a shrinking block 627, an arc-shaped pressing strip 628, a cutting connecting frame 629 and heating wires 6210, wherein the support 621 is provided with two groups, the two groups of support 621 are symmetrically fixed on one side of the surface of the support 1 close to the second motor 611, the lifting frame 622 is connected on the outer walls of the four support 621 in a sliding way through a sliding hole, the first spring 623 is sleeved on the outer side of the support 621, the upper end of the first spring 623 is in pressing contact with the bottom of the lifting frame 622, the bottom of the first spring 623 is in pressing contact with the surface of the support 1, the cam 624 is fixed at the output end of the second motor 611, the cam 624 is in pressing contact with the outer wall of the lifting frame 622, the connecting sleeve 625 is fixed on the surface of the lifting frame 622, the connecting sleeve 625 is positioned right above one driving sleeve rod 4 positioned above the arc-shaped shrinking block, the second spring 626 is fixed on the inner wall of the connecting sleeve 625, the shrinking block 627 which is connected on the inner wall of the connecting sleeve 625 in a sliding way, the bottom of the second spring 626 is fixed on the surface of the shrinking block 628 fixed on the surface of the shrinking block 628, the heat-shaped heat-releasing strip 628, the heat-releasing block 628, the heat-releasing strip 628, the heat-releasing core 628 which is positioned above the arc-shaped winding core 100 positioned above the arc-shaped winding core 628, and can be tightly pressed on the arc-shaped heat-shaped winding core 100 of the arc-shaped winding core 628, and is pressed on the arc-shaped heat-shaped winding core 100 of the arc-shaped winding core 628,

the cutting connecting frame 629 is fixed at the upper end of the lifting frame 622, the heating wire 6210 is fixed at the lower end of the cutting connecting frame 629, and the axial directions of the heating wire 6210, the arc-shaped pressing bar 628 and the reeling core 100 are the same;

at the beginning of the transposition operation, the first half of the rotation of the second motor 611 is completed, and the second half of the rotation of the second motor 611 drives the cam 624 to rotate, the lifting frame 622 is pushed by the cam 624 to move downwards, finally the arc-shaped pressing strip 628 presses the heat dissipation film on the outer wall of the winding core 100 newly arriving at the winding station, so that the heat dissipation film is attached to the outer wall of the winding core 100 at the upper winding station, the heating wire 6210 continuously descends to contact with the heat dissipation film after the pressing, the heating wire 6210 is quickly electrified at the beginning of the descending, the heat dissipation film is burned off by the heating wire 6210, the second motor 611 finishes one-circle rotation, the pressing and cutting-off operations are completed, the lifting frame 622 pushes upwards to reset under the action of the resilience force of the first spring 623, the first motor 52 at the upper winding station after the resetting rapidly drives to rotate to drive the winding core 100 to rotate for winding operation,

the follow-up positioning assembly 63 comprises an opening 631, a resisting block 632, a third spring 633, a driving inclined block 634, a fourth spring 635, a sliding rod 636, a universal roller 637 and a driving guide rail 638, wherein the opening 631 is disposed in the middle of the outer wall of the driving sleeve 4, the opening 631 penetrates through the side wall of the driving sleeve 4, the resisting block 632 is slidably connected to the inner side of the opening 631, a non-slip mat 632a is fixed at one end of the resisting block 632, which is far away from the inner side of the driving sleeve 4, the outer side of the non-slip mat 632a is arc-shaped, so that the outer wall of the non-slip mat 632a can be completely attached to the inner wall of the winding core 100,

the third springs 633 are symmetrically fixed on the outer wall of the abutting block 632, one end of each third spring 633, which is far away from the abutting block 632, is fixed with the inner wall of the driving sleeve rod 4, the driving inclined block 634 is slidably disposed on the inner side of the driving sleeve rod 4, the inclined plane of the driving inclined block 634 is in pressing contact with the surface of the abutting block 632, a rounded corner is formed on one side of the lower end of the abutting block 632, which is in contact with the inclined plane of the driving inclined block 634, so that the abutting block 632 can be smoothly pushed by the driving inclined block 634,

the fourth spring 635 is fixed at the end of the driving bevel block 634, one end of the fourth spring 635, which is far away from the driving bevel block 634, is fixed with the inner wall of the driving loop bar 4, the sliding bar 636 is slidably connected with the inner wall of the driving loop bar 4, one end of the sliding bar 636 is fixed with the outer wall of the driving bevel block 634, the universal roller 637 is fixed at the end of the sliding bar 636, the driving guide rail 638 is fixed on the outer wall of the bracket 1, and the universal roller 637 is in contact with the outer wall of the driving guide rail 638;

when the indexing work is carried out, the driving sleeve rod 4 originally positioned at the upper winding station rotates to one side to leave the winding station, the universal roller 637 covering the end part of the driving sleeve rod 4 slides to a flat part on the driving guide rail 638 from a convex part on the driving guide rail 638 in the rotating process of the driving sleeve rod, and then the abutting block 632 slides to the inner side of the driving sleeve rod 4 under the action of the resilience force of the third spring 633 due to the loss of the pushing of the driving inclined block 634, so that the anti-skid pad 632a contracts to the inner side of the opening 631, thereby the positioning work of the winding core 100 is relieved, and after the cutting and pressing work is finished, a worker directly takes off the full-load winding core 100 from the driving sleeve rod 4, and then the winding core 100 which is empty on the sleeve can be used;

meanwhile, when the indexing operation is performed, the empty winding core 100 on the other side rotates to the winding station above, and is pushed by the protruding part on the driving guide rail 638, so that the sliding rod 636 on the inner side of the driving sleeve rod 4 pushes the driving inclined block 634 to move in a sliding manner, and then the driving inclined block 634 pushes the abutting block 632 to slide towards the outer side of the driving sleeve rod 4, so that the anti-skid pad 632a is pressed on the inner wall of the winding core 100, and the winding core 100 can be simultaneously positioned on the driving sleeve rod 4 after the empty winding core 100 is in place;

the first motor 52 and the second motor 611 are both speed reducing motors, so that the switching of the whole equipment and the winding station can be stably carried out.

The invention also provides a production method, which adopts any one of the intelligent electronic device production equipment based on the Internet of things for production.

The circuits and controls involved in the present invention are prior art and will not be described in detail herein.

The above description is only an embodiment of the present invention, and is not intended to limit the scope of the present invention, and all equivalent structures or equivalent processes performed by the present invention or directly or indirectly applied to other related technical fields are included in the scope of the present invention.

Claims (10)

1. The utility model provides an electron device intelligence production facility based on thing networking which characterized in that includes:

a support (1);

the transposition shaft (2) is rotatably connected to the middle of the upper end of the bracket (1) through a bearing;

the station disc (3) is fixed at the end part of the indexing shaft (2);

the driving sleeve rod (4) is connected to the station disc (3) in an equidistance rotating mode through a bearing and used for being sleeved with a rolling core (100) for rolling the residual heat dissipation film;

the winding device (5) is fixed on the outer wall of the driving sleeve rod (4) and used for driving the driving sleeve rod (4) to rotate to complete the winding work of the residual heat dissipation film;

switching device (6), the setting is in on support (1), by setting up being used for on support (1) drive station dish (3) rotate carry out station switching work's switching component (61), set up be used for cutting off remaining radiating film and will cut off treat that the remaining radiating film that carries out the rolling compresses tightly auxiliary assembly (62) of pasting on winding core (100) and follow-up locating component (63) that are used for fixing a position and remove locating work to winding core (100) in the conversion work process and constitute, switching component (61), auxiliary assembly (62) and follow-up locating component (63) linkage.

2. The intelligent production equipment of electronic devices based on the Internet of things as claimed in claim 1, wherein the rolling device (5) comprises:

a driven gear (51) fixed to an end of the driving lever (4);

the first motors (52) are fixed on the surface of the station disc (3), and the number of the first motors is the same as that of the driving sleeve rods (4);

and the driving gear (53) is fixed at the output end of the first motor (52), and the driving gear (53) is meshed with the driven gear (51).

3. The intelligent production facility of electronic devices based on the internet of things as claimed in claim 2, wherein the switching assembly (61) comprises:

the second motor (611) is fixed on the surface of the bracket (1), and the output end of the second motor (611) is rotatably connected with the bracket (1) through a bearing;

a driving wheel (612) fixed at an output end of the second motor (611);

the grooved wheel (613) is fixed at one end, far away from the station disc (3), of the rotating shaft (2), and the grooved wheel (613) is matched with the driving wheel (612).

4. The intelligent internet-of-things-based electronic device production facility of claim 3, wherein the auxiliary component (62) comprises:

the two groups of supporting rods (621) are symmetrically fixed on one side, close to the second motor (611), of the surface of the support (1);

the lifting frame (622) is connected to the outer walls of the four supporting rods (621) in a sliding mode through sliding holes;

the first spring (623) is sleeved on the outer side of the supporting rod (621), the upper end of the first spring (623) is in extrusion contact with the bottom of the lifting frame (622), and the bottom of the first spring (623) is in extrusion contact with the surface of the support (1);

the cam (624) is fixed at the output end of the second motor (611), and the cam (624) is in pressing contact with the outer wall of the lifting frame (622);

the connecting sleeve (625) is fixed on the surface of the lifting frame (622), and the connecting sleeve (625) is positioned right above one driving sleeve rod (4) positioned above;

the second spring (626) is fixed on the inner wall of the connecting sleeve (625);

the contraction block (627) is connected to the inner wall of the connecting sleeve (625) in a sliding mode, and the bottom of the second spring (626) is fixed to the surface of the contraction block (627);

the arc-shaped pressing strip (628) is fixed at the bottom of the contraction block (627), and the arc-shaped pressing strip (628) is opposite to the upper coiling core (100);

a cut-off connection frame (629) fixed to the upper end of the lifting frame (622);

a heating wire (6210) fixed to a lower end of the cut-off connection frame (629);

the axial directions of the heating wire (6210), the arc-shaped pressing strip (628) and the winding core (100) are the same.

5. The intelligent production equipment of electronic devices based on the Internet of things of claim 4, wherein the arc surface at the lower end of the arc-shaped pressing strip (628) is matched with the arc surface at the outer side of the winding core (100).

6. The intelligent production facility of electronic devices based on the internet of things as claimed in claim 1, wherein the follow-up positioning assembly (63) comprises:

the opening (631) is arranged in the middle of the outer wall of the driving loop bar (4), and the opening (631) penetrates through the side wall of the driving loop bar (4);

the abutting block (632) is connected to the inner side of the opening (631) in a sliding mode, and a non-slip pad (632 a) is fixed to one end, away from the inner side of the driving sleeve rod (4), of the abutting block (632);

the third springs (633) are symmetrically fixed on the outer wall of the abutting block (632), and one ends, far away from the abutting block (632), of the third springs (633) are fixed with the inner wall of the driving sleeve rod (4);

the driving inclined block (634) is arranged on the inner side of the driving sleeve rod (4) in a sliding mode, and the inclined surface of the driving inclined block (634) is in pressing contact with the surface of the abutting block (632);

a fourth spring (635) fixed at the end of the driving inclined block (634), wherein one end of the fourth spring (635) far away from the driving inclined block (634) is fixed with the inner wall of the driving sleeve rod (4);

the sliding rod (636) is connected to the inner wall of the driving sleeve rod (4) in a sliding mode, and one end of the sliding rod (636) is fixed to the outer wall of the driving inclined block (634);

a universal roller (637) fixed at the end of the sliding rod (636);

and the driving guide rail (638) is fixed on the outer wall of the bracket (1), and the universal roller (637) is in contact with the outer wall of the driving guide rail (638).

7. The intelligent production equipment of electronic devices based on Internet of things of claim 6, wherein the outer side of the anti-slip mat (632 a) is arc-shaped.

8. The intelligent production equipment for electronic devices based on the Internet of things as claimed in claim 3, wherein the first motor (52) and the second motor (611) are both speed reduction motors.

9. The intelligent production equipment of electronic devices based on the Internet of things of claim 6, wherein the lower end of the abutting block (632) is chamfered at one side in inclined surface contact with the driving inclined block (634).

10. A production method, which is characterized in that the intelligent electronic device production equipment based on the internet of things is adopted for production according to any one of claims 1 to 9.

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