CN113263304A - Assembling equipment with anti-deviation structure for computer power supply machining - Google Patents

Abstract

The invention relates to an assembly device with an anti-offset structure for computer power supply processing, which comprises a device shell and a clamping block, wherein a first motor is installed at the lower end of the device shell, a first belt conveyor and a second belt conveyor are arranged at the front end of the inner lower wall of the device shell from left to right, a third belt conveyor and a workbench are sequentially arranged in the middle of the inner lower wall of the device shell from left to right, a computer power supply body is placed on the outer side of the upper end of the workbench, a first multi-section hydraulic cylinder is arranged on the inner side of the upper end of the workbench, and a second motor is installed on the periphery of the lower wall of the workbench: this computer power processing is with equipment that has anti skew structure promotes the board of polishing through the spring and makes polishing board and screwdriver contact, rotates to the screwdriver and causes the resistance to make the screwdriver can screw up the screw, the screwdriver can appear skidding when the torsion of screwdriver surpasss the resistance simultaneously, thereby prevents the too big screw that damages of torsion of screwdriver.

Description

Assembling equipment with anti-deviation structure for computer power supply machining

Technical Field

The invention relates to the technical field of computer power supply processing, in particular to assembling equipment with an anti-offset structure for computer power supply processing.

Background

The computer power supply is a computer component which is installed in the computer and is responsible for converting the common commercial power into the voltage which can be used by the computer, the computer power supply is a switch circuit and converts the common alternating current into the voltage which can be used by the computerDirect currentThen the voltage is controlled by chopping wave to supply different electricityThe voltages are respectively output to computer components such as a mainboard, a hard disk, an optical drive and the like, and the computer power supply needs to be assembled together by using an assembling device in the machining process.

The screw that current equipment was on to the computer power makes the dynamics of rotating too big easily when fastening, leads to the screw to slide when the fastening, makes the screw can't dismantle, leads to the problem that the computer power appears damaging.

Disclosure of Invention

The invention aims to provide an assembling device with an anti-offset structure for computer power supply processing, which solves the problem that the conventional assembling device provided in the background art easily causes overlarge rotating force when fastening a screw on a computer power supply, so that the screw slides during fastening, the screw cannot be detached, and the computer power supply is damaged.

In order to achieve the purpose, the invention provides the following technical scheme: an assembling device with an anti-deviation structure for computer power supply processing comprises a device shell and a clamping block, wherein a first motor is installed at the lower end of the device shell, a first belt conveyor and a second belt conveyor are arranged at the front end of the inner lower wall of the device shell from left to right, a third belt conveyor and a workbench are sequentially arranged in the middle of the inner lower wall of the device shell from left to right, a computer power supply body is placed on the outer side of the upper end of the workbench, a first multi-section hydraulic cylinder is arranged on the inner side of the upper end of the workbench, a second motor is installed on the periphery of the lower wall of the workbench, one side of the second motor is connected with a first threaded rod through a chain, a fixed block is connected to the outer portion of the first threaded rod, a sliding rod is fixed to one side of the fixed block, the clamping block is located on the outer portion of the sliding rod, and a full-automatic screw arranging machine is installed on one side of the inner portion of the device shell, and the inside upper wall anticlockwise of equipment casing has set gradually first electronic slide rail, the electronic slide rail of second and tight silk mechanism, the electronic slide rail of third is installed to the lower extreme of first electronic slide rail, and the lower extreme of the electronic slide rail of third is provided with centre gripping adjustment mechanism, the electronic slide rail of fourth is installed to the lower extreme of the electronic slide rail of second, and the lower extreme of the electronic slide rail of fourth is provided with arranges silk mechanism.

Preferably, threaded connection is adopted between the clamping block and the first threaded rod, the clamping block forms a sliding structure through the sliding rod and the fixed block, and the sliding rod and the fixed block are welded.

Preferably, the wire tightening mechanism comprises a second multi-section hydraulic cylinder, a third motor, a first gear, a second gear, a bearing, a connecting frame, a fourth motor, a connecting box body, a second threaded rod, a connecting plate, a pressure sensor, a first spring, a friction block, a first guide rod and a screwdriver, the third motor is installed at the lower end of the second multi-section hydraulic cylinder, the first gear is connected to one side of the third motor, the second gear is connected to the lower end of the first gear, the bearing is connected to the outside of the second gear, the connecting frame is connected to the lower end of the second gear, the fourth motor is installed at one side of the connecting frame, the connecting box body is connected to the lower end of the fourth motor, the second threaded rod penetrates through the left side and the right side of the connecting box body, the connecting plate is connected to one side of the second threaded rod close to the central axis of the connecting box body, the pressure sensor and the first guide rod are sequentially arranged at the other side of the connecting plate from the middle to the upper side and the lower side, and the other side of the pressure sensor is connected with a first spring, the other end of the first spring is connected with a friction block, and the other side of the friction block is provided with a screwdriver.

Preferably, the outer surface of the second gear is meshed with the outer surface of the first gear, the second gear and the second multi-section hydraulic cylinder form a rotating structure through a bearing, and the central axis of the second gear is coincident with the central axis of the second multi-section hydraulic cylinder.

Preferably, the friction block forms an elastic telescopic structure with the connecting plate through the first spring and the first guide rod, the connecting plate is movably connected with the second threaded rod, and the second threaded rod is in threaded connection with the connecting box body.

Preferably, the clamping adjusting mechanism comprises a third multi-section hydraulic cylinder, a fifth motor, a rotating frame, a scanner, a fourth multi-section hydraulic cylinder and a clamping block, the fifth motor is installed at the lower end of the third multi-section hydraulic cylinder, the lower end of the fifth motor is connected with the rotating frame, the front end of the rotating frame is connected with the scanner, the fourth multi-section hydraulic cylinder penetrates through the left side and the right side of the rotating frame, and one end of the fourth multi-section hydraulic cylinder is connected with the clamping block.

Preferably, the rotating frame forms a telescopic structure with the third multi-section hydraulic cylinder through the fifth motor, the clamping block forms a lifting structure with the rotating frame through the fourth multi-section hydraulic cylinder, and a welding integrated structure is formed between the rotating frame and the scanner.

Preferably, the wire arranging mechanism comprises a fifth multi-section hydraulic cylinder, a second spring, a second guide rod, an expansion bracket, an electromagnet, a limiting sleeve and a vibrating motor, the second spring and the second guide rod are sequentially arranged from the middle to the left and right sides of the lower end of the fifth multi-section hydraulic cylinder, the lower end of the second spring is connected with the expansion bracket, the electromagnet is installed at the lower end of the expansion bracket, the limiting sleeve is connected to the outer portion of the expansion bracket, and the vibrating motor is installed on one side of the limiting sleeve.

Preferably, the telescopic frame forms an elastic structure with the fifth multi-section hydraulic cylinder through the second spring, forms a sliding structure with the fifth multi-section hydraulic cylinder through the second guide rod, and forms a telescopic structure with the limit sleeve.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the invention, the two clamping blocks can be driven to clamp and position the computer power supply body through the threaded connection between the first threaded rod and the clamping blocks, so that the situation that the subsequent flow of equipment cannot be accurately positioned due to the deviation of the computer power supply body in the machining process is prevented, and meanwhile, the sliding rod can position and support the clamping blocks, so that the situation that the clamping blocks deviate in the moving process to cause the deviation of the clamping position of the equipment is prevented.

2. According to the invention, the friction block can rub the screwdriver to cause resistance to the rotation of the screwdriver, so that the screwdriver can fasten the screw, and the screwdriver and the friction block can directly slip after the screw is tightened, so that the screw is prevented from being screwed and slipped after the torque force of the screwdriver exceeds a certain value, and the installation of the computer power supply body can be protected to prevent damage.

3. The friction force between the friction block and the screwdriver can be adjusted through the threaded connection between the second threaded rod and the connecting box body, so that the screwdriver can bear the maximum torque force and can be screwed down by the screwdriver, and the friction block is tightly contacted with the screwdriver through the friction block and an elastic telescopic structure formed between the first spring and the connecting plate and the first guide rod.

4. According to the invention, the rotating structure formed by the fifth motor and the third multi-section hydraulic cylinder can drive the two parts of the computer power supply body to rotate by virtue of the rotating frame, so that the two parts of the computer power supply body can be aligned, the two parts of the computer power supply body can be accurately butted, and equipment can be accurately butted with the computer power supply body.

5. According to the invention, the screw attracted by the electromagnet can be positioned through the limiting sleeve, so that the screw can accurately fall into the hole on the computer power supply body, and the limiting sleeve can be vibrated through the vibrating motor, so that the screw in the limiting sleeve is driven to shake tightly, and the screw can be prevented from being clamped in an inclined manner, and the screw can not fall at a designated position.

Drawings

FIG. 1 is a schematic front view of an assembling apparatus with an anti-shifting structure for computer power processing according to the present invention;

FIG. 2 is an enlarged cross-sectional view of a connection box of an assembling apparatus with an anti-shift structure for computer power processing according to the present invention;

FIG. 3 is an enlarged cross-sectional view of a wire arranging mechanism of an assembling apparatus with an anti-shift structure for computer power processing according to the present invention;

FIG. 4 is an enlarged schematic structural view of a portion A of FIG. 1 of an assembling apparatus for computer power processing with an anti-shifting structure according to the present invention;

FIG. 5 is an enlarged schematic view of the assembly apparatus with an anti-shift structure for computer power processing of the present invention at B of FIG. 1;

FIG. 6 is an enlarged schematic view of the assembly apparatus with an anti-shift structure for computer power processing of the present invention at C in FIG. 1;

FIG. 7 is a schematic diagram of an enlarged top view of a computer power supply of an assembling apparatus with an anti-shifting structure for computer power supply processing according to the present invention.

In the figure: 1. an equipment housing; 2. a first motor; 3. a first belt conveyor; 4. a second belt conveyor; 5. a third belt conveyor; 6. a work table; 7. a computer power supply body; 8. a first multi-section hydraulic cylinder; 9. a second motor; 10. a chain; 11. a first threaded rod; 12. a fixed block; 13. a slide bar; 14. a clamping block; 15. a full-automatic screw arranging machine; 16. a first electric slide rail; 17. a second electric slide rail; 18. a wire tensioning mechanism; 1801. a second multi-section hydraulic cylinder; 1802. a third motor; 1803. a first gear; 1804. a second gear; 1805. a bearing; 1806. a connecting frame; 1807. a fourth motor; 1808. connecting the box body; 1809. a second threaded rod; 1810. a connecting plate; 1811. a pressure sensor; 1812. a first spring; 1813. a friction block; 1814. a first guide bar; 1815. a screwdriver; 19. a third electric slide rail; 20. a clamping adjustment mechanism; 2001. a third multi-section hydraulic cylinder; 2002. a fifth motor; 2003. a rotating frame; 2004. a scanner; 2005. a fourth multi-section hydraulic cylinder; 2006. a clamping block; 21. a fourth electric slide rail; 22. a wire arrangement mechanism; 2201. a fifth multi-section hydraulic cylinder; 2202. a second spring; 2203. a second guide bar; 2204. a telescopic frame; 2205. an electromagnet; 2206. a limiting sleeve; 2207. a vibration motor.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the referred devices or elements must have a specific orientation, be constructed in a specific orientation, and be operated, and thus are not to be construed as limiting the present invention, and furthermore, the terms "first", "second", "third", and the like are only used for descriptive purposes and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; they may be directly connected or indirectly connected through an intermediate, and those skilled in the art will understand the specific meaning of the above terms in the present invention in specific situations.

Referring to fig. 1-7, the present invention provides a technical solution: an assembly device with an anti-deviation structure for computer power supply processing comprises a device shell 1 and a clamping block 14, wherein a first motor 2 is installed at the lower end of the device shell 1, a first belt conveyor 3 and a second belt conveyor 4 are arranged at the front end of the inner lower wall of the device shell 1 from left to right, a third belt conveyor 5 and a workbench 6 are sequentially arranged in the middle of the inner lower wall of the device shell 1 from left to right, a computer power supply body 7 is placed on the outer side of the upper end of the workbench 6, a first multi-section hydraulic cylinder 8 is arranged on the inner side of the upper end of the workbench 6, a second motor 9 is installed on the periphery of the lower wall of the workbench 6, one side of the second motor 9 is connected with a first threaded rod 11 through a chain 10, a fixed block 12 is connected to the outside of the first threaded rod 11, a sliding rod 13 is fixed on one side of the fixed block 12, the clamping block 14 is located on the outside of the sliding rod 13, and the clamping block 14 is in threaded connection with the first threaded rod 11, and the clamping block 14 passes through and constitutes sliding structure between slide bar 13 and the fixed block 12, and be the welding between slide bar 13 and the fixed block 12, threaded connection between first threaded rod 11 and the clamping block 14 can drive two clamping blocks 14 and carry out the centre gripping location to computer power supply body 7, thereby prevent that computer power supply body 7 from appearing the skew in the course of working and leading to the unable accurate location that carries out of follow-up flow of equipment, slide bar 13 can carry out the location support to clamping block 14 simultaneously, thereby prevent clamping block 14 at the in-process offset of removal, lead to with the skew of equipment centre gripping position.

A full-automatic screw arranging machine 15 is installed on one side inside the equipment casing 1, a first electric slide rail 16, a second electric slide rail 17 and a wire tightening mechanism 18 are sequentially arranged on the upper wall inside the equipment casing 1 in a counterclockwise direction, the wire tightening mechanism 18 comprises a second multi-section hydraulic cylinder 1801, a third motor 1802, a first gear 1803, a second gear 1804, a bearing 1805, a connecting frame 1806, a fourth motor 1807, a connecting box 1808, a second threaded rod 1809, a connecting plate 1810, a pressure sensor 1811, a first spring 1812, a friction block 1813, a first guide rod 1814 and a screwdriver 1815, the third motor 1802 is installed at the lower end of the second multi-section hydraulic cylinder 1801, the first gear 1803 is connected to one side of the third motor 1802, the second gear 1803 is connected to the lower end of the first gear 1803, the bearing 1805 is connected to the outside of the second gear 1804, the connecting frame 1806 is connected to the lower end of the second gear 1804, the fourth motor 1807 is installed on one side of the connecting frame 1806, and the lower end of the fourth motor 1807 is connected with a connection box 1808, the left and right sides of the connection box 1808 are penetrated with a second threaded rod 1809, and one side of the second threaded rod 1809 close to the central axis of the connection box 1808 is connected with a connection plate 1810, the other side of the connection plate 1810 is provided with a pressure sensor 1811 and a first guide rod 1814 in sequence from the middle to the upper and lower sides, and the other side of the pressure sensor 1811 is connected with a first spring 1812, the other end of the first spring 1812 is connected with a friction block 1813, and the other side of the friction block 1813 is provided with a screwdriver 1815, the screwdriver 1815 can be rubbed by the friction block 1813, resistance is provided to the rotation of the screwdriver 1815, thereby enabling the screwdriver 1815 to tighten the screw, while the screwdriver 1815 and the friction block 1813 directly slip when the screw is tightened, thereby preventing the screw from being screwed and sliding after the torque force of the screwdriver 1815 exceeds a certain value, and protecting the installation of the computer power supply body 7 from being damaged.

The outer surface of the second gear 1804 is engaged with the outer surface of the first gear 1803, and the second gear 1804 forms a rotating structure with the second multi-section hydraulic cylinder 1801 through the bearing 1805, and the central axis of the second gear 1804 coincides with the central axis of the second multi-section hydraulic cylinder 1801, the friction block 1813 forms an elastic telescopic structure with the connecting plate 1810 through the first spring 1812 and the first guide rod 1814, and the connecting plate 1810 is movably connected with the second threaded rod 1809, and the second threaded rod 1809 is in threaded connection with the connection box body 1808, the friction force between the friction block 1813 and the screwdriver 1815 can be adjusted through the threaded connection between the second threaded rod 1809 and the connection box body 1808, thereby adjusting the maximum torque that the driver 1815 can bear to enable the driver 1815 to tighten the screw, and the friction block 1813 is brought into close contact with the driver 1815 by means of the friction block 1813 through the first spring 1812 and the elastic expansion structure formed between the first guide 1814 and the connecting plate 1810.

A third electric slide rail 19 is installed at the lower end of the first electric slide rail 16, a clamping adjusting mechanism 20 is arranged at the lower end of the third electric slide rail 19, the clamping adjusting mechanism 20 comprises a third multi-section hydraulic cylinder 2001, a fifth motor 2002, a rotating frame 2003, a scanner 2004, a fourth multi-section hydraulic cylinder 2005 and a clamping block 2006, the fifth motor 2002 is installed at the lower end of the third multi-section hydraulic cylinder 2001, the rotating frame 2003 is connected to the lower end of the fifth motor 2002, the scanner 2004 is connected to the front end of the rotating frame 2003, the fourth multi-section hydraulic cylinder 2005 penetrates through the left side and the right side of the rotating frame 2003, the clamping block 2006 is connected to one end of the fourth multi-section hydraulic cylinder 2005, the rotating frame 2003 forms a telescopic structure through the fifth motor 2002 and the third multi-section hydraulic cylinder 2001, the clamping block 2006 forms a lifting structure through the fourth multi-section hydraulic cylinder 2005 and the rotating frame 2003, and the rotating frame 2003 form a welding integrated structure, the rotating structure formed by the rotating frame 2003 through the fifth motor 2002 and the third multi-section hydraulic cylinder 2001 can drive the two parts of the computer power supply body 7 to rotate, so that the two parts of the computer power supply body 7 can be aligned, the two parts of the computer power supply body 7 can be accurately butted, and the equipment can be accurately butted with the computer power supply body 7.

A fourth electric slide rail 21 is mounted at the lower end of the second electric slide rail 17, a wire arranging mechanism 22 is arranged at the lower end of the fourth electric slide rail 21, the wire arranging mechanism 22 comprises a fifth multi-section hydraulic cylinder 2201, a second spring 2202, a second guide rod 2203, an expansion bracket 2204, an electromagnet 2205, a limit sleeve 2206 and a vibration motor 2207, the second spring 2202 and the second guide rod 2203 are sequentially arranged at the lower end of the fifth multi-section hydraulic cylinder 2201 from the middle to the left and right sides, the expansion bracket 2204 is connected at the lower end of the second spring 2202, the electromagnet 2205 is mounted at the lower end of the expansion bracket 2204, the limit sleeve 2206 is connected outside the expansion bracket 2204, the vibration motor 2207 is mounted at one side of the limit sleeve 2206, the expansion bracket 2204 forms an elastic structure with the fifth multi-section hydraulic cylinder 2201 through the second spring 2202, the expansion bracket 2204 forms a sliding structure with the fifth multi-section hydraulic cylinder 2201 through the second guide rod 2203, and forms an expansion structure with the limit sleeve 2206, the screw that can hold electro-magnet 2205 through stop collar 2206 fixes a position, makes the screw can be accurate drop to the hole on computer power supply body 7, can shake stop collar 2206 through vibrating motor 2207 to drive the inside screw of stop collar 2206 nervous and rock, and then can prevent that the screw slope from blocking, lead to the assigned position that the screw can't drop.

In conclusion, when the assembling device with the anti-deviation structure for the computer power supply processing is used, the first belt conveyor 3 and the second belt conveyor 4 are used for conveying two parts of the computer power supply body 7 respectively, the first electric slide rail 16 and the third electric slide rail 19 are used for driving the clamping adjusting mechanism 20 to move, the scanner 2004 is used for scanning the two parts of the computer power supply body 7 to determine the inclination angle of the computer power supply body 7, the fifth motor 2002 is started to drive the rotating frame 2003 to rotate, the fourth multi-section hydraulic cylinder 2005 is used for driving the clamping block 2006 to clamp the computer power supply body 7 and then is placed on the workbench 6 in a rotating mode, the second motor 9 is started to drive the first threaded rod 11 to rotate through the chain 10, the clamping block 14 is made to move to clamp and position the computer power supply body 7 to prevent deviation, the workbench 6 is driven to rotate by the first motor 2 for 90 degrees, the second electric slide rail 17 and the fourth electric slide rail 21 are used for driving the wire arranging mechanism 22 to move, the electromagnet 2205 is close to the full-automatic screw arranging machine 15 to magnetically clamp the screws, the electromagnet 2205 can contact the full-automatic screw arranging machine 15 through an elastic telescopic structure formed by a telescopic frame 2204, a second guide rod 2203, a second spring 2202 and a fifth hydraulic cylinder 2201 to facilitate clamping of the screws, the screws are positioned through a limiting sleeve 2206, the limiting sleeve 2206 is vibrated through a vibration motor 2207 to prevent the screws from being clamped in an inclined mode, the position of a connecting plate 1810 is adjusted by rotating a second threaded rod 1809, the elastic force of a first spring 1812 is observed through a pressure sensor 1811 to determine the pressure between a friction block 1813 and a screwdriver 1815, the friction force between the screwdriver 1815 and the friction block 1813 is detected, the maximum torsion force capable of rotating the screwdriver 1815 is adjusted, the screwdriver 1815 is driven to descend to be aligned with the screws through the second hydraulic cylinder 1801, and then the fourth motor 1807 is opened to drive a connecting box 1808 to rotate, thereby driving the screwdriver 1815 to rotate to fasten the screw, turning on the third motor 1802 to drive the second gear 1804 to rotate through the first gear 1803, so that the screwdriver 1815 fastens the next screw, then the workbench 6 continues to rotate by 90 degrees, and the processed computer power supply body 7 is pushed to the third belt conveyor 5 through the first multi-section hydraulic cylinder 8 to be conveyed.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (9)

1. The utility model provides an equipment that computer power supply processing was with preventing skew structure, includes equipment casing (1) and grip block (14), its characterized in that: a first motor (2) is installed at the lower end of the equipment shell (1), a first belt conveyor (3) and a second belt conveyor (4) are arranged at the front end of the inner lower wall of the equipment shell (1) from left to right, a third belt conveyor (5) and a workbench (6) are sequentially arranged in the middle of the inner lower wall of the equipment shell (1) from left to right, a computer power supply body (7) is placed on the outer side of the upper end of the workbench (6), a first multi-section hydraulic cylinder (8) is arranged on the inner side of the upper end of the workbench (6), a second motor (9) is installed on the periphery of the lower wall of the workbench (6), one side of the second motor (9) is connected with a first threaded rod (11) through a chain (10), a fixing block (12) is connected to the outer portion of the first threaded rod (11), and a sliding rod (13) is fixed to one side of the fixing block (12), the utility model discloses a screw thread tightening mechanism, including centre gripping piece (14), equipment casing (1), first electronic slide rail (16), second electronic slide rail (17) and tight silk mechanism (18) have been set gradually to the inside upper wall anticlockwise of equipment casing (1), third electronic slide rail (19) are installed to the lower extreme of first electronic slide rail (16), and the lower extreme of third electronic slide rail (19) is provided with centre gripping adjustment mechanism (20), fourth electronic slide rail (21) are installed to the lower extreme of second electronic slide rail (17), and the lower extreme of fourth electronic slide rail (21) is provided with arranges silk mechanism (22).

2. The assembling device with anti-shifting structure for computer power supply processing according to claim 1, wherein: the clamping block (14) is in threaded connection with the first threaded rod (11), the clamping block (14) forms a sliding structure through the sliding rod (13) and the fixed block (12), and the sliding rod (13) and the fixed block (12) are welded.

3. The assembling device with anti-shifting structure for computer power supply processing according to claim 1, wherein: the wire tightening mechanism (18) comprises a second multi-section hydraulic cylinder (1801), a third motor (1802), a first gear (1803), a second gear (1804), a bearing (1805), a connecting frame (1806), a fourth motor (1807), a connecting box body (1808), a second threaded rod (1809), a connecting plate (1810), a pressure sensor (1811), a first spring (1812), a friction block (1813), a first guide rod (1814) and a screwdriver (1815), the third motor (1802) is installed at the lower end of the second multi-section hydraulic cylinder (1801), the first gear (1803) is connected to one side of the third motor (1802), the second gear (1804) is connected to the lower end of the first gear (1803), the bearing (1805) is connected to the outside of the second gear (1804), the connecting frame (1806) is connected to the lower end of the second gear (1804), the fourth motor (1807) is installed at one side of the connecting frame (1806), and the lower extreme of fourth motor (1807) is connected with and connects box (1808), second threaded rod (1809) has been run through to the left and right sides of connecting box (1808), and second threaded rod (1809) are connected with connecting plate (1810) near the one side of connecting box (1808) axis, pressure sensor (1811) and first guide arm (1814) have set gradually to upper and lower both sides from the middle of connecting plate (1810), and the opposite side of pressure sensor (1811) is connected with first spring (1812), the other end of first spring (1812) is connected with clutch blocks (1813), and the opposite side of clutch blocks (1813) is provided with screwdriver (1815).

4. The assembling device with anti-shifting structure for computer power supply processing according to claim 3, wherein: the outer surface of the second gear (1804) is meshed with the outer surface of the first gear (1803), the second gear (1804) forms a rotating structure with the second multi-section hydraulic cylinder (1801) through a bearing (1805), and the central axis of the second gear (1804) is overlapped with the central axis of the second multi-section hydraulic cylinder (1801).

5. The assembling device with anti-shifting structure for computer power supply processing according to claim 3, wherein: the friction block (1813) forms an elastic telescopic structure with the connecting plate (1810) through the first spring (1812) and the first guide rod (1814), the connecting plate (1810) is movably connected with the second threaded rod (1809), and the second threaded rod (1809) is in threaded connection with the connecting box body (1808).

6. The assembling device with anti-shifting structure for computer power supply processing according to claim 1, wherein: the clamping adjusting mechanism (20) comprises a third multi-section hydraulic cylinder (2001), a fifth motor (2002), a rotating frame (2003), a scanner (2004), a fourth multi-section hydraulic cylinder (2005) and a clamping block (2006), the fifth motor (2002) is installed at the lower end of the third multi-section hydraulic cylinder (2001), the lower end of the fifth motor (2002) is connected with the rotating frame (2003), the front end of the rotating frame (2003) is connected with the scanner (2004), the fourth multi-section hydraulic cylinder (2005) penetrates through the left side and the right side of the rotating frame (2003), and one end of the fourth multi-section hydraulic cylinder (2005) is connected with the clamping block (2006).

7. The assembling device with anti-shifting structure for computer power supply processing according to claim 6, wherein: the rotating frame (2003) forms a telescopic structure through a fifth motor (2002) and the third multi-section hydraulic cylinder (2001), the clamping block (2006) forms a lifting structure through a fourth multi-section hydraulic cylinder (2005) and the rotating frame (2003), and a welding integrated structure is formed between the rotating frame (2003) and the scanner (2004).

8. The assembling device with anti-shifting structure for computer power supply processing according to claim 1, wherein: wire arranging mechanism (22) includes fifth multisection pneumatic cylinder (2201), second spring (2202), second guide arm (2203), expansion bracket (2204), electro-magnet (2205), stop collar (2206) and vibrating motor (2207), and the lower extreme of fifth multisection pneumatic cylinder (2201) has set gradually second spring (2202) and second guide arm (2203) from middle to the left and right sides, the lower extreme of second spring (2202) is connected with expansion bracket (2204), and electro-magnet (2205) are installed to the lower extreme of expansion bracket (2204), the external connection of expansion bracket (2204) has stop collar (2206), and vibrating motor (2207) are installed to one side of stop collar (2206).

9. The assembling apparatus with anti-shifting structure for computer power supply processing according to claim 8, wherein: the telescopic frame (2204) and the fifth multi-section hydraulic cylinder (2201) form an elastic structure through a second spring (2202), the telescopic frame (2204) and the fifth multi-section hydraulic cylinder (2201) form a sliding structure through a second guide rod (2203), and the telescopic frame (2204) and the limit sleeve (2206) form a telescopic structure.

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