CN217295970U - Automatic production line for wired micro motor - Google Patents

Abstract

The utility model discloses a wired micromotor automatic production line, the load simulator comprises a complete machine, the complete machine is equipped with host module and switching mechanism, the host module is including preceding doubly fast chain and the doubly fast chain in back, preceding doubly fast chain is installed the front end of doubly fast chain in back is controlled adjacent two the preceding doubly fast chain of host module and the installation of being plugged into each other of doubly fast chain in back, preceding doubly fast chain with the carrier is all installed to doubly fast chain in back, doubly fast chain in back is transmitted from a left side right the carrier, preceding doubly fast chain is from the right side left conveying the carrier, switching mechanism installs both ends about the complete machine, switching mechanism connects preceding doubly fast chain with the installation of doubly fast chain in back, the host module is equipped with the processing subassembly, preceding doubly fast chain with the position that doubly fast chain in back corresponds the processing subassembly is equipped with the location module. The utility model discloses can be used to the wired micromotor of automatic production, overcome the limitation of the dead carrier of carousel station lock.

Description

Automatic production line for wired micro motor

Technical Field

The utility model belongs to the technical field of motor production, especially, relate to an automatic line of producing of wired micromotor.

Background

When a wireless motor is produced traditionally, a dividing machine is usually used for driving a turntable main machine table to be connected with each station, but the method cannot be applied to the production of a wired motor, the wired motor can only be processed in a linear speed chain transmission mode in the production process, and a carrier developed aiming at the wired characteristic of wired motor production is lacked in the prior art, so that the problem of carrier locking is easily caused in the processing process.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a wired micromotor is from line of producing, aims at solving the problem that exists among the background art. For realizing the purpose, the utility model discloses a technical scheme be:

the utility model provides a wired micromotor automatic production line, it is further, includes the complete machine, the complete machine is equipped with host computer module and changeover mechanism, the host computer module includes preceding doubly fast chain and the chain of doubly fast of back, preceding doubly fast chain is installed the front end of the chain of doubly fast of back is controlled adjacent two the preceding doubly fast chain of host computer module and the chain of doubly fast of back are installed of plugging into each other, preceding doubly fast chain with the chain of doubly fast of back all installs the carrier, the chain of doubly fast of back is from the left to the right transmission the carrier, preceding doubly fast chain is from the right side to the left transmission the carrier, changeover mechanism installs both ends about the complete machine, changeover mechanism connect preceding doubly fast chain with the chain installation of doubly fast of back, the host computer module is equipped with the processing subassembly, preceding doubly fast chain with the position that the chain of doubly fast of back corresponds the processing subassembly is equipped with the location module.

Furthermore, the carrier comprises a carrier panel, a product groove is formed in the middle of the upper end of the carrier panel, and a wire clamping clamp is mounted at the upper end of the carrier panel;

the wire clamping clamp comprises a fixed clamping plate and a movable clamping plate, the fixed clamping plate is fixedly mounted on the carrier panel, the movable clamping plate is provided with a clamping position, an upper spring groove is formed in the lower end of the clamping position, a lower spring groove is formed in the upper end of the carrier panel, and a wire clamping spring is connected between the upper spring groove and the lower spring groove. To the processing production of wired micromotor, can press from both sides the line tight through the fastener on the anchor clamps, avoid the line of product to drop etc. the condition to appear in the course of working, solved in traditional production process wired product and caused the problem of the dead carrier of station lock easily.

Furthermore, the positioning module comprises a primary positioning assembly, a material stopping blocking assembly and a fine positioning assembly, the primary positioning assembly and the material stopping blocking assembly are arranged in a left-right arrangement mode, and the fine positioning assembly is installed between the primary positioning assembly and the material stopping blocking assembly;

the primary positioning assembly comprises a primary positioning air cylinder, and a primary positioning plate is mounted at the driving end of the primary positioning air cylinder; the material stopping and blocking assembly comprises a material stopping and blocking cylinder, a material stopping and blocking plate is mounted at the driving end of the material stopping and blocking cylinder, and material blocking grooves are formed in the left end and the right end of the carrier panel; the width of the material stopping blocking cylinder is equal to that of the material stopping blocking plate, and the width of the primary positioning plate is larger than that of the material stopping blocking plate; the fine positioning assembly comprises a fine positioning cylinder, a fine positioning bearing plate is mounted at the upper end of the fine positioning cylinder, a fine positioning guide pillar is mounted on the fine positioning bearing plate, a fine positioning hole is formed in the carrier panel, and the fine positioning guide pillar can penetrate through the fine positioning hole; the initial positioning plate is lifted to prevent the carrier to be processed from flowing to the next station, the material stopping baffle plate is lifted to stop the coming material of the carrier behind, the fine positioning guide post penetrates through the fine positioning hole to be lifted, the positioning module is used for further accurately positioning the carrier, and if the fine positioning step is completed, the carrier is processed through the processing assembly.

Further, switching mechanism includes switching guide rail, switching slip table, slip table driver, pushes away the material cylinder and keeps off the material cylinder, the switching slip table is installed the upper end of switching guide rail, the slip table driver is installed the side of switching guide rail, the slip table driver is connected the installation of switching slip table, it installs to push away the material cylinder the outside end of switching guide rail, it installs to keep off the material cylinder the medial extremity of switching guide rail, and processing sequence has preceding doubly fast chain to process the material from the right side left side, treats when the carrier transmits the leftmost end to preceding doubly fast chain, shifts the carrier from preceding doubly fast chain to back doubly fast chain through switching mechanism, and back doubly fast chain transports the carrier from a left side to the right.

Furthermore, the whole machine further comprises a feeding mechanism, the host module comprises a first host, a second host, a third host and a fourth host, the first host, the second host, the third host and the fourth host are sequentially arranged from right to left, the feeding mechanism is installed at the right end of the first host, the feeding mechanism comprises a casing riveting assembly, a casing three-blade assembly and a casing guide rail, and the casing riveting assembly and the casing three-blade assembly are installed at the front end of the casing guide rail;

the first host comprises a first front speed multiplication chain, a first rear speed multiplication chain, a wired cable protection shell assembly module, a shaping assembly and a discharge guide rail, the wired cable protection shell assembly module is installed at the front end of the first front speed multiplication chain, the shaping assembly and the discharge guide rail are installed at the rear end of the first rear speed multiplication chain, and the shaping assembly is installed at the left end of the discharge guide rail;

the second main machine comprises a second front speed multiplication chain, a second rear speed multiplication chain, a cover plate assembly, an electrode plate assembly, a force output shaft assembly and a shaft sleeve assembly, the cover plate assembly and the electrode plate assembly are mounted at the front end of the second front speed multiplication chain, the cover plate assembly is mounted at the right end of the electrode plate assembly, the force output shaft assembly and the shaft sleeve assembly are mounted at the rear end of the second rear speed multiplication chain, and the force output shaft assembly is mounted at the left end of the shaft sleeve assembly;

the third main machine comprises a third front speed multiplying chain, a third rear speed multiplying chain, a rotor assembly, a CCD detection assembly and a three-tooth oiling assembly, the rotor assembly is mounted at the front end of the third front speed multiplying chain, the CCD detection assembly and the three-tooth oiling assembly are mounted at the rear end of the third rear speed multiplying chain, and the CCD detection assembly is mounted at the left end of the three-tooth oiling assembly;

the fourth main machine comprises a fourth front speed-multiplying chain, a fourth rear speed-multiplying chain, a first switching mechanism, a gear plate assembly component, a first gear assembly component, a second gear assembly component and a third gear assembly component, the first switching mechanism is installed at the left ends of the fourth front speed-multiplying chain and the fourth rear speed-multiplying chain, the gear plate assembly component and the first gear assembly component are installed at the front end of the fourth front speed-multiplying chain, the first gear assembly component is installed at the left end of the gear plate assembly component, the second gear assembly component and the third gear assembly component are installed at the rear end of the fourth rear speed-multiplying chain, and the second gear assembly component is installed at the left end of the third gear assembly component; the left end of the shell guide rail is arranged corresponding to the position of the first rear speed multiplying chain, a shell clamping jaw assembly is arranged on the right side between the first front speed multiplying chain and the first rear speed multiplying chain, and a second switching mechanism is arranged on the right ends of the first front speed multiplying chain and the first rear speed multiplying chain. Through designing the feeding mechanism, the first host, the second host, the third host and the fourth host, the product can be assembled in a plurality of processes in sequence.

The utility model has the advantages that:

the utility model discloses to the processing production of wired micromotor, the double-layered fastener has been designed on the carrier, can firmly fix the electric wire of micromotor, the electric wire of micromotor is avoided scattering in process of production, the problem of causing the dead carrier of carousel station lock easily in the traditional wired micromotor production process has been solved, and the position to each processing subassembly is doubly fast chain in the front and is set up the location module with the lower extreme of doubly fast chain in back, make the carrier carry out accurate location to carrier and product earlier when a station is changeed to, improve the accuracy nature of processing, improve the quality of processing.

Drawings

Fig. 1 is a schematic overall top view of an automatic production line for wired micro-motors according to an embodiment of the present invention;

fig. 2 is a schematic view of a speed-multiplying chain structure of an automatic production line of a wired micro-motor according to an embodiment of the present invention;

fig. 3 is a schematic structural view of a carrier and a positioning module of an automatic production line of a wired micro-motor according to an embodiment of the present invention;

fig. 4 is a schematic structural view of a carrier of an automatic production line of wired micro-motors according to an embodiment of the present invention;

fig. 5 is a schematic view of an explosion structure of a wire clamp of the automatic wire clamp of the wired micro-motor according to an embodiment of the present invention.

Fig. 6 is a schematic structural view of a carrier transferring mechanism of an automatic production line of a wired micro-motor according to an embodiment of the present invention.

Fig. 7 is a schematic view of a distribution structure of a wired micro-motor automatic production line according to an embodiment of the present invention.

Fig. 8 is a schematic structural view of a feeding mechanism of an automatic production line of a wired micro-motor according to an embodiment of the present invention.

Fig. 9 is a schematic structural view of a first host of an automatic production line for a wired micro-motor according to an embodiment of the present invention.

Fig. 10 is a schematic structural view of a second host of an automatic production line for wired micro-motors according to an embodiment of the present invention.

Fig. 11 is a schematic structural view of a third host of an automatic production line for a wired micro-motor according to an embodiment of the present invention.

Fig. 12 is a schematic structural view of a fourth host of the wired micro-motor automatic production line according to an embodiment of the present invention.

Wherein, in the figures, the respective reference numerals:

1. a whole machine; 11. a feeding mechanism; 111. a casing riveting component; 112. the machine shell is provided with a three-blade assembly; 113. a housing guide rail; 2. a transfer mechanism; 21. transferring the guide rail; 22. transferring a sliding table; 23. a slide table driver; 24. a material pushing cylinder; 25. a material blocking cylinder; 3. a front double speed chain; 4. a rear speed multiplication chain; 5. a carrier; 51. a carrier panel; 511. a product tank; 512. a lower spring groove; 513. a material blocking groove; 514. fine positioning holes; 52. a wire clamping clip; 521. fixing the clamping plate; 522. a movable splint; 523. pressing a clamping position; 524. an upper spring groove; 53. a wire clamping spring; 6. a positioning module; 61. a primary positioning component; 611. initially positioning a cylinder; 612. a primary positioning plate; 62. a material stopping blocking component; 621. a material stopping blocking cylinder; 622. a material stopping baffle plate; 63. a fine positioning assembly; 631. a fine positioning cylinder; 632. fine positioning guide post; 633. finely positioning a bearing plate; 7. a host module; 71. a first host; 711. a first front double speed chain; 712. a first rear double speed chain; 713. a wired cable guard housing assembly module; 714. a shaping component; 715, a discharge guide rail; 716. a second changeover mechanism; 717. a housing jaw assembly; 72. a second host; 721 second front multiple speed chain; 722. a second rear double speed chain; 723. a cover plate assembly; 724. assembling the electrode plate; a power shaft assembly; 726. assembling the assembly by the shaft sleeve; 73. a third host; 731. a third front double speed chain; a third rear double speed chain; 733. a rotor assembly; 734. a CCD detection assembly; 735. a three-tooth oiling component; 74. a fourth host; 741. a fourth front double speed chain; 742. a fourth rear double speed chain; 743. a first changeover mechanism; 744. a gear plate assembly component; 745. a first gear assembly component; 746. a second gear assembly component; 747. a third gear assembly component; 8. and (6) processing the assembly.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. In contrast, when an element is referred to as being "directly on" another element, there are no intervening elements present. As used herein, the terms "vertical," "horizontal," "left," "right," and the like are for illustrative purposes only and do not represent the only embodiments, and as used herein, the terms "upper," "lower," "left," "right," "front," "rear," and the like are used in a positional relationship with reference to the drawings.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The technical solution of the present patent will be described in further detail with reference to the following embodiments.

As shown in fig. 1-12, the embodiment of the utility model provides a wired micromotor automatic production line, including complete machine 1, complete machine 1 is equipped with host module 7 and changeover mechanism 2, host module 7 is including preceding doubly fast chain 3 and the doubly fast chain 4 in back, preceding doubly fast chain 3 is installed at the front end of doubly fast chain 4 in back, control the installation of plugging into each other of the preceding doubly fast chain 3 of two adjacent host module 7 and doubly fast chain 4 in back, carrier 5 is all installed with doubly fast chain 4 in preceding doubly fast chain 3, doubly fast chain 4 from a left side right side transmission carrier 5 in back, preceding doubly fast chain 3 is from the right side left side transmission carrier 5, changeover mechanism 2 installs both ends about complete machine 1, doubly fast chain 3 and the doubly fast chain 4 installation in back before changeover mechanism 2 connects, host module 7 is equipped with processing subassembly 8, preceding doubly fast chain 3 is equipped with location module 6 with the position that doubly fast chain 4 in back corresponds processing subassembly 8.

In the present embodiment, the carrier 5 includes a carrier panel 51, a product slot 511 is formed in the middle of the upper end of the carrier panel 51, and a clip 52 is mounted on the upper end of the carrier panel 51.

In the present embodiment, the wire clamping clip 52 includes a fixed clip plate 521 and a movable clip plate 522, the fixed clip plate 521 is fixedly mounted on the carrier panel 51, the movable clip plate 522 has a pressing position 523, a lower end of the pressing position 523 is provided with an upper spring slot 524, an upper end of the carrier panel 51 is provided with a lower spring slot 512, and a wire clamping spring 53 is connected between the upper spring slot 524 and the lower spring slot 512.

In this embodiment, the positioning module 6 includes the initial positioning component 61, the material stopping blocking component 62 and the fine positioning component 63, the initial positioning component 61 and the material stopping blocking component 62 are arranged in a left-right direction, and the fine positioning component 63 is installed between the initial positioning component 61 and the material stopping blocking component 62.

In this embodiment, the primary positioning assembly 61 includes a primary positioning cylinder 611, and a primary positioning plate 612 is installed at a driving end of the primary positioning cylinder 611; stop material and block subassembly 62 and block cylinder 621 including ending the material, end the material and block that the drive end of cylinder 621 installs and end material barrier plate 622, and both ends are equipped with and keep off silo 513 about carrier panel 51.

In this embodiment, the width of the material stop blocking cylinder 621 is equal to the width of the material stop blocking plate 622, and the width of the initial positioning plate 612 is greater than the width of the material stop blocking plate 622.

In this embodiment, the fine positioning assembly 63 includes a fine positioning cylinder 631, a fine positioning bearing plate 633 is mounted at an upper end of the fine positioning cylinder 631, a fine positioning guide post 632 is mounted on the fine positioning bearing plate 633, the carrier panel 51 has a fine positioning hole 514, and the fine positioning guide post 632 can penetrate through the fine positioning hole 514.

In this embodiment, the adapting mechanism 2 includes an adapting guide rail 21, an adapting slide table 22, a slide table driver 23, a pushing cylinder 24, and a material blocking cylinder 25, the adapting slide table 22 is mounted at the upper end of the adapting guide rail 21, the slide table driver 23 is mounted at the side end of the adapting guide rail 21, the slide table driver 23 is connected to the adapting slide table 22, the pushing cylinder 24 is mounted at the outer side end of the adapting guide rail 21, and the material blocking cylinder 25 is mounted at the inner side end of the adapting guide rail 21.

In this embodiment, the whole machine 1 further includes a feeding mechanism 11, the host module 7 includes a first host 71, a second host 72, a third host 73 and a fourth host 74, the first host 71, the second host 72, the third host 73 and the fourth host 74 are sequentially arranged from right to left, the feeding mechanism 11 is installed at the right end of the first host 71, the feeding mechanism 11 includes a casing riveting assembly 111, a casing three-blade assembly 112 and a casing guide rail 113, the casing riveting assembly 111 and the casing three-blade assembly 112 are installed at the front end of the casing guide rail 113;

the first main machine 71 comprises a first front double-speed chain 711, a first rear double-speed chain 712, a wired cable sheath assembly module 713, a shaping assembly 714 and a discharging guide rail 715, wherein the wired cable sheath assembly module 713 is installed at the front end of the first front double-speed chain 711, the shaping assembly 714 and the discharging guide rail 715 are installed at the rear end of the first rear double-speed chain 712, and the shaping assembly 714 is installed at the left end of the discharging guide rail 715;

the second main machine 72 comprises a second front speed multiplication chain 721, a second rear speed multiplication chain 722, a cover plate assembly 723, a pole plate assembly 724, a thrust shaft assembly 725 and a shaft sleeve assembly 726, wherein the cover plate assembly 723 and the pole plate assembly 724 are mounted at the front end of the second front speed multiplication chain 721, the cover plate assembly 723 is mounted at the right end of the pole plate assembly 724, the thrust shaft assembly 725 and the shaft sleeve assembly 726 are mounted at the rear end of the second rear speed multiplication chain 722, and the thrust shaft assembly 725 is mounted at the left end of the shaft sleeve assembly 726;

the third main machine 73 comprises a third front speed multiplication chain 731, a third rear speed multiplication chain 732, a rotor assembly 733, a CCD detection assembly 734 and a three-tooth oil pumping assembly 735, the rotor assembly 733 is mounted at the front end of the third front speed multiplication chain 731, the CCD detection assembly 734 and the three-tooth oil pumping assembly 735 are mounted at the rear end of the third rear speed multiplication chain 732, and the CCD detection assembly 734 is mounted at the left end of the three-tooth oil pumping assembly 735;

the fourth main unit 74 includes a fourth front speed doubling chain 741, a fourth rear speed doubling chain 742, a first switch 743, a gear plate assembly 744, a first gear assembly 745, a second gear assembly 746, and a third gear assembly 747, the first switch 743 is installed at the left end of the fourth front speed doubling chain 741 and the fourth rear speed doubling chain 742, the gear plate assembly 744 and the first gear assembly 745 are installed at the front end of the fourth front speed doubling chain 741, the first gear assembly 745 is installed at the left end of the gear plate assembly 744, the second gear assembly 746 and the third gear assembly 747 are installed at the rear end of the fourth rear speed doubling chain 742, and the second gear assembly 746 is installed at the left end of the third gear assembly 747.

In this embodiment, the left end of the cabinet guide rail 113 is installed corresponding to the position of the first rear speed-multiplying chain 712, the right side of the middle between the first front speed-multiplying chain 711 and the first rear speed-multiplying chain 712 is installed with a cabinet clamping jaw assembly 717, and the right ends of the first front speed-multiplying chain 711 and the first rear speed-multiplying chain 712 are installed with a second switching mechanism 716.

The working mode is as follows:

during the processing, the first front speed-doubling chain 711, the second front speed-doubling chain 721, the third front speed-doubling chain 731 and the fourth front speed-doubling chain 741 are mutually connected to form a whole of a front speed-doubling chain 3, the first rear speed-doubling chain 712, the second rear speed-doubling chain 722, the third rear speed-doubling chain 732 and the fourth rear speed-doubling chain 742 are mutually connected to form a whole of a rear speed-doubling chain 4, the carrier 5 is transmitted from right to left by the front speed-doubling chain 3, the carrier 5 is transmitted from left to right by the rear speed-doubling chain 4, the whole machine 1 consists of a first main machine 71, a second main machine 72, a third main machine 73, a fourth main machine 74 and a feeding mechanism 11, a plurality of station assemblies are arranged at the front end of the front speed-doubling chain 3 and the rear end of the rear speed-doubling chain 4 of the whole machine 1, and the processing action of the whole machine 1 is completed through the station assemblies; corresponding to the position of each processing assembly 8, the lower ends of the front speed-multiplying chain 3 and the rear speed-multiplying chain 4 are provided with a positioning module 6, when the carrier 5 flows to the upper end of the positioning module 6, the primary positioning cylinder 611 drives the primary positioning plate 612 to rise, the primary positioning plate 612 blocks the carrier 5 so that the carrier cannot move forward continuously, the material stopping blocking cylinder 621 drives the material stopping blocking plate 622 to rise, the material stopping blocking plate 622 stops the carrier 5 of the subsequent incoming material, the material stopping blocking plate 622 penetrates out of the material stopping groove 513, finally, the fine positioning cylinder 631 drives the fine positioning guide posts 632 arranged side by side left and right to perform accurate positioning, the fine positioning guide posts 632 can penetrate through the fine positioning holes 514 to complete fine positioning, and the fine positioning processing assembly 8 processes products on the carrier 5; the complete machine 1 is provided with the switching mechanism 2 at the right end of the first main machine 71 and the left end of the fourth main machine 74, so that the carrier 5 can realize circular motion on the front speed multiplying chain 3 and the rear speed multiplying chain 4.

After the feeding mechanism 11 completes the process of installing riveting pins and three blades in the casing through the casing riveting component 111 and the casing three-blade assembly 112, the casing is transferred to the left end of the casing guide rail 113 through the casing guide rail 113, the left end of the casing guide rail 113 is installed corresponding to the position of the first rear speed-multiplying chain 712, the casing clamping component of the first host 71 clamps the casing on the casing guide rail 113 to the carrier 5 at the right end of the first rear speed-multiplying chain 712, the second switching mechanism 716 forwards transfers the carrier 5 with the casing to the rear material pushing cylinder 24 at the right end of the first front speed-multiplying chain 711, and the carrier 5 is pushed into the first front speed-multiplying chain 711;

the first front double-speed chain 711 transmits the carrier 5 to the wired cable protection shell assembly module 713, the wired cable protection shell assembly module 713 completes assembly of the cable protection shell manually, and clamps and fixes the wires of the cable protection shell by the wire clamping clamp 52; the first front speed multiplying chain 711 transmits the carrier 5 to the second front speed multiplying chain 721, the carrier 5 sequentially passes through the cover plate assembly 723 and the plate assembly 724, the cover plate assembly 723 mounts a cover plate on a product on the carrier 5, and the plate assembly 724 mounts a plate on the product on the carrier 5;

the second front speed multiplication chain 721 transfers the carrier 5 to the third front speed multiplication chain 731, the third front speed multiplication chain 731 transfers the carrier 5 to the rotor assembly 733, and the product completes the installation of the rotor;

the third front speed multiplication chain 731 transfers the carrier 5 to the fourth front speed multiplication chain 741, the fourth front speed multiplication chain 741 sequentially passes the carrier 5 through the gear plate assembly 744 and the first gear assembly 745, the product completes the installation of the gear plate on the gear plate assembly 744, completes the installation of the first gear on the first gear assembly 745, the carrier 5 reaches the first transfer mechanism 743, and the first transfer mechanism 743 transfers the carrier 5 from the fourth front speed multiplication chain 741 to the fourth rear speed multiplication chain 742;

the fourth rear double-speed chain 742 sequentially transfers the carriers 5 to the second gear assembly 746 and the third gear assembly 747, the second gear assembly 746 assembles a second gear for the product, and the third gear assembly 747 assembles a third gear for the product;

the fourth rear speed multiplication chain 742 transmits the carriers 5 to the third rear speed multiplication chain 732, the third rear speed multiplication chain 732 sequentially transmits the carriers 5 to the CCD detection component 734 and the three-tooth oiling component 735, the CCD detection component 734 detects whether the three gears are completely assembled with the product, and the three-tooth oiling component 735 oils the gears installed on the fourth main machine 74;

the third rear speed multiplication chain 732 transmits the carrier 5 to the second rear speed multiplication chain 722, the second rear speed multiplication chain 722 sequentially transmits the carrier 5 to the output shaft assembly 725 and the shaft sleeve assembly 726, the output shaft assembly 725 mounts an output shaft on a product, and the shaft sleeve assembly 726 mounts a shaft sleeve on the output shaft of the product;

the carrier 5 is transmitted to the first rear speed doubling chain 712 by the second rear speed doubling chain 722, the carrier 5 is transmitted to the shaping assembly 714 by the first rear speed doubling chain 712, the product is shaped by the shaping assembly 714, the first rear speed doubling chain 712 after shaping is transmitted to the discharging guide rail 715, the discharging guide rail 715 is provided with a mechanical clamping jaw to take the product off the carrier 5 and place the product on the discharging guide rail 715 to complete discharging, and the carrier 5 after discharging is transmitted to the right end of the first rear speed doubling chain 712 to complete a processing cycle.

The above embodiments are only used for illustrating the present invention, and not for limiting the present invention, and those skilled in the relevant technical field can make various changes and modifications without departing from the spirit and scope of the present invention, so that all equivalent technical solutions also belong to the scope of the present invention, and the protection scope of the present invention should be defined by the claims.

Claims (10)

1. The utility model provides a wired micromotor automatic production line which characterized in that: the rapid speed chain transmission device comprises a complete machine, wherein the complete machine is provided with a host module and a switching mechanism, the host module comprises a front speed-doubling chain and a rear speed-doubling chain, the front speed-doubling chain is installed at the front end of the rear speed-doubling chain, the front speed-doubling chain and the rear speed-doubling chain are adjacent to each other in a left-right mode, the front speed-doubling chain and the rear speed-doubling chain of the host module are installed in a mutual connection mode, carriers are installed on the front speed-doubling chain and the rear speed-doubling chain, the rear speed-doubling chain is transmitted from left to right, the front speed-doubling chain is transmitted from right to left to the carriers, the switching mechanism is installed at the left end and the right end of the complete machine, the switching mechanism is connected with the front speed-doubling chain and the rear speed chain for installation, the host module is provided with a processing assembly, and a positioning module is arranged at the position of the front speed-doubling chain and the rear speed chain corresponding to the processing assembly.

2. The automatic production line of wired micro-motors of claim 1, wherein: the carrier includes the carrier panel, the upper end middle part of carrier panel is equipped with the product groove, the fastener is installed to the upper end of carrier panel.

3. The automatic production line of wired micro-motors of claim 2, wherein: the wire clamping clamp comprises a fixed clamping plate and a movable clamping plate, the fixed clamping plate is fixedly mounted on the carrier panel, the movable clamping plate is provided with a clamping position, an upper spring groove is formed in the lower end of the clamping position, a lower spring groove is formed in the upper end of the carrier panel, and a wire clamping spring is connected between the upper spring groove and the lower spring groove.

4. The wired micro-motor automatic production line according to claim 2, characterized in that: the positioning module comprises a primary positioning assembly, a stopping material blocking assembly and a fine positioning assembly, the primary positioning assembly and the stopping material blocking assembly are arranged in a left-right mode, and the stopping material blocking assembly is installed between the primary positioning assembly and the fine positioning assembly.

5. The automatic production line of wired micro-motors of claim 4, wherein: the primary positioning assembly comprises a primary positioning air cylinder, and a primary positioning plate is mounted at the driving end of the primary positioning air cylinder; stop the material and block the subassembly and block the cylinder including ending the material, end the material and block the drive end of cylinder and install and end the material barrier plate, both ends are equipped with and keep off the silo about the carrier panel.

6. The automatic production line of wired micro-motors of claim 5, wherein: the width of the material stopping blocking cylinder is equal to that of the material stopping blocking plate, and the width of the primary positioning plate is larger than that of the material stopping blocking plate.

7. The automatic production line of wired micro-motors of claim 4, wherein: the fine positioning assembly comprises a fine positioning cylinder, a fine positioning bearing plate is mounted at the upper end of the fine positioning cylinder, a fine positioning guide pillar is mounted on the fine positioning bearing plate, a fine positioning hole is formed in the carrier panel, and the fine positioning guide pillar can penetrate through the fine positioning hole.

8. The wired micro-motor automatic production line according to claim 1, wherein: the switching mechanism comprises a switching guide rail, a switching sliding table, a sliding table driver, a material pushing cylinder and a material blocking cylinder, wherein the switching sliding table is installed at the upper end of the switching guide rail, the sliding table driver is installed at the side end of the switching guide rail, the sliding table driver is connected with the switching sliding table, the material pushing cylinder is installed at the outer side end of the switching guide rail, and the material blocking cylinder is installed at the inner side end of the switching guide rail.

9. The automatic production line of wired micro-motors as claimed in any one of claims 1 to 8, wherein: the whole machine further comprises a feeding mechanism, the host machine module comprises a first host machine, a second host machine, a third host machine and a fourth host machine, the first host machine, the second host machine, the third host machine and the fourth host machine are sequentially arranged from right to left, the feeding mechanism is installed at the right end of the first host machine, the feeding mechanism comprises a machine shell riveting assembly, a machine shell three-blade assembly and a machine shell guide rail, and the machine shell riveting assembly and the machine shell three-blade assembly are installed at the front end of the machine shell guide rail;

the first host comprises a first front speed multiplication chain, a first rear speed multiplication chain, a wired cable protection shell assembly module, a shaping assembly and a discharge guide rail, the wired cable protection shell assembly module is installed at the front end of the first front speed multiplication chain, the shaping assembly and the discharge guide rail are installed at the rear end of the first rear speed multiplication chain, and the shaping assembly is installed at the left end of the discharge guide rail;

the second main machine comprises a second front speed multiplication chain, a second rear speed multiplication chain, a cover plate assembly, an electrode plate assembly, a force output shaft assembly and a shaft sleeve assembly, the cover plate assembly and the electrode plate assembly are mounted at the front end of the second front speed multiplication chain, the cover plate assembly is mounted at the right end of the electrode plate assembly, the force output shaft assembly and the shaft sleeve assembly are mounted at the rear end of the second rear speed multiplication chain, and the force output shaft assembly is mounted at the left end of the shaft sleeve assembly;

the third main machine comprises a third front speed multiplying chain, a third rear speed multiplying chain, a rotor assembly, a CCD detection assembly and a three-tooth oiling assembly, the rotor assembly is mounted at the front end of the third front speed multiplying chain, the CCD detection assembly and the three-tooth oiling assembly are mounted at the rear end of the third rear speed multiplying chain, and the CCD detection assembly is mounted at the left end of the three-tooth oiling assembly;

the fourth host comprises a fourth front speed-multiplying chain, a fourth rear speed-multiplying chain, a first switching mechanism, a gear plate assembly component, a first gear assembly component, a second gear assembly component and a third gear assembly component, the first switching mechanism is installed at the left end of the fourth front speed-multiplying chain and the left end of the fourth rear speed-multiplying chain, the gear plate assembly component is installed at the front end of the fourth front speed-multiplying chain with the first gear assembly component, the first gear assembly component is installed at the left end of the gear plate assembly component, the second gear assembly component is installed at the rear end of the fourth rear speed-multiplying chain with the third gear assembly component, and the second gear assembly component is installed at the left end of the third gear assembly component.

10. The automatic production line of wired micro-motors of claim 9, wherein: the left end of the shell guide rail is arranged corresponding to the position of the first rear speed multiplying chain, a shell clamping jaw assembly is arranged on the right side between the first front speed multiplying chain and the first rear speed multiplying chain, and a second switching mechanism is arranged on the right ends of the first front speed multiplying chain and the first rear speed multiplying chain.

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