An automatic production apparatus for a fuse tube clamp assembly
By designing automated production equipment, the automated production of fuse clamp assemblies has been realized, solving the problem of low production efficiency in existing technologies, improving production efficiency and product qualification rate, and adapting to the production needs of different sizes and specifications.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DOGE ELECTRIC CO LTD
- Filing Date
- 2025-08-20
- Publication Date
- 2026-07-14
AI Technical Summary
The production efficiency of existing fuse clamp assemblies is low, relying on manual operation and difficult to scale up production.
An automated production equipment was designed, including a support base, turntable, fixed tray, multiple workstations and pipeline control box. The automated production of pipe clamp components is achieved through components such as mechanical grippers, cylinders, and camera recognition sensors, including the automatic assembly of wiring frames, spigot supports, pressure frames and snap rings.
It significantly reduces labor costs, improves production efficiency and product qualification rate, adapts to different sizes and specifications, and is suitable for mass production.
Smart Images

Figure CN224501828U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of automated production equipment application technology, and in particular to an automated production equipment for fuse clamp assemblies. Background Technology
[0002] A fuse is a widely used circuit protection device, found in homes, industrial and commercial applications, and automobiles. It melts when the current exceeds a set value, preventing damage or even fires caused by overload or short circuits. Inside the fuse, the clamp assembly is a crucial wiring connection component. This assembly consists of a clamping frame, a wiring frame, and a spigot base, all assembled together. Currently, conventional technology typically employs manual or semi-automatic production methods for this assembly, requiring manual adjustments. This results in low production efficiency and reliance on manual labor and operator skill, hindering large-scale, widespread production. Utility Model Content
[0003] The technical solution of this utility model: An automatic production equipment for fuse clamp assemblies, characterized in that it includes: a support base 1 and a clamp assembly 12. A turntable 11 is provided in the middle of the support base 1. A plurality of fixed trays 1101 are evenly distributed around the outer periphery of the turntable. The fixed trays 1101 are provided with a receiving cavity 1102 for holding the clamp assembly 12. A wiring frame loading station 3, a spigot support loading station 4, a first assembly station 5, and a second assembly station 8 are respectively arranged clockwise on the outer side of the fixed trays 1101. A further arrangement is provided between the first assembly station 5 and the second assembly station 8. There is an auxiliary station 6 and a pressing frame feeding station 7. The second assembly station 8 is also equipped with a screening station 9 and a snap ring installation station in the clockwise rotation direction. A pipeline control box 2 is provided on one side of the bearing base 1. The pipeline control box 2 is used to connect and control the air and electrical circuits of the above stations. The pipe clamp assembly 12 includes a wiring frame 1201, a pressing frame 1202 and a fork support 1203. Snap ring grooves 1205 are provided at both ends of the upper outer side of the fork support 1203. Snap rings 1204 are engaged in the snap ring grooves 1205. All the above stations are connected and combined with the pipeline control box 2 to realize the automated production of the pipe clamp assembly 12.
[0004] Optionally, a wire frame feeding tray 301 is connected to one end of the wire frame feeding station 3. The wire frame feeding station 3 also includes a wire frame feeding base 302. A first horizontal slide groove 304 is provided on the wire frame feeding base 302. A first horizontal moving cylinder 303 is provided on the first horizontal slide groove 304. A first vertical moving cylinder 307 is provided below the first horizontal moving cylinder 303. A first mechanical gripper 3071 for gripping the wire frame 1201 is provided below the first vertical moving cylinder 307. A wire frame conveyor 308 is also connected between the wire frame feeding base 302 and the wire frame feeding tray 301.
[0005] Optionally, one side of the forklift support loading station 4 is connected to the forklift support screening frame 401 via a forklift support conveyor 402. A forklift picking cylinder 403 is provided on the upper part of one side of the forklift support conveyor 402, and a second mechanical gripper 404 is provided on the lower part of the forklift picking cylinder 403. A first camera recognition sensor 406 and a second camera recognition sensor 407 are respectively provided around the side of the forklift support conveyor 402 away from the forklift support screening frame 401. A camera display 408 is suspended at the upper middle part of the forklift support conveyor 402. A camera controller 4081 is provided on one side of the camera display 408. According to the forklift supports 1203 of different sizes and specifications, the corresponding shooting sensitivity, exposure and shooting speed and other related parameters are adjusted to meet the shooting and recognition needs under different production conditions. A waste receiving frame 409 is provided on one side of the first camera recognition sensor 406.
[0006] Optionally, the first assembly station 5 includes a first assembly support 501 and a first assembly motor 502. The lower part of the first assembly motor 502 is connected to a transmission link 5021. The lower end of the transmission link 5021 is coaxially connected to the assembly guide rod 503. The lower part of the assembly guide rod 503 is provided with an integrated assembler 504. The upper end of the integrated assembler 504 is also provided with a bolt conveying pipe 5041. The lower end of the integrated assembler 504 is also provided with a first connection assembly port 5042. The bolt conveying pipe 5041 transports bolts to the lower end of the first connection assembly port 5042 for easy bolt connection. The upper part of the assembly guide rod 503 is provided with a first displacement identifier 505 for identifying and limiting the descent distance of the assembly guide rod 503.
[0007] Optionally, the auxiliary station 6 is provided with a second displacement identifier 601. The lower part of the second displacement identifier 601 is provided with a flattening contact 602 to flatten the upper end of the fixed support plate 1101 that is rotated to the lower part of the flattening contact 602 and the corresponding spigot support 1203, so as to facilitate the operation of subsequent processes.
[0008] Optionally, the pressing frame feeding station 7 is provided with a pressing frame feeding base 702. A pressing frame material frame 701 is connected to one side of the pressing frame feeding base 702 for conveying the pressing frame 1202. The upper end of the pressing frame feeding base 702 is horizontal, and a pressing frame horizontal displacement identifier 703 and a pressing frame feeding horizontal guide rail 704 are respectively provided at both ends. A pressing frame horizontal moving cylinder 705 is provided on the pressing frame feeding horizontal guide rail 704. A rotating moving tooth 706 is provided on one side of the pressing frame horizontal moving cylinder 705. A second mechanical gripper 707 is provided at the lower part of the rotating moving tooth 706 for picking up and placing the pressing frame 1202 and rotating it to an angle suitable for assembly.
[0009] Optionally, the second assembly station 8 is equipped with a second assembly motor 801. A second assembly connection port 802 is connected to the lower part of the second assembly motor 801. A second assembly height identifier 803 is provided on one side of the second assembly connection port 802 to monitor its vertical movement. The second assembly motor 801 has a torque recognition mode. The second assembly connection port 802 tightens the bolts of the wiring frame 1201 according to the calibrated torque. Once the set torque is reached, the second assembly connection port automatically stops tightening the bolts and retracts and rises. The screening station 9 is equipped with a screening lateral displacement identifier 901, a screening longitudinal displacement identifier 902, and a screening transfer cylinder 903. If the second connection assembly port 802 on the corresponding second assembly station 8 detects that the bolt on the wiring frame 1201 is not tightened after reaching the calibrated torque, and the bolt becomes loose, then the corresponding wiring frame 1201 fails to tighten and is determined to be a defective product. The screening transfer cylinder 903 is equipped with a waste box 904 below it. The waste box 904 is picked up and transferred by the gripper below the screening transfer cylinder 903.
[0010] Optionally, the snap ring installation station 10 is provided with a snap ring conveyor 1001. A pusher cylinder 1002 is provided at one end of the snap ring conveyor 1001. A pusher limiting protrusion 1003 is provided in the direction perpendicular to the snap ring conveyor 1001. The pusher limiting protrusion 1003 abuts against the upper end of the snap ring 1204. A pusher cylinder limiting slot 1005 is provided at the far end of the pusher limiting protrusion 1003 along the pushing direction. The pusher cylinder 1002 pushes the pusher limiting protrusion 1003 to the pusher cylinder limiting slot 1005, pushing the snap ring 1204 into the snap ring grooves 1205 on both sides of the fork support 1203. A lateral pressing cylinder 1004 is also provided on one side of the pusher limiting protrusion 1003 for laterally pressing the two sides of the fork support 1203 after installation.
[0011] Optionally, a first pipeline control console 201 and a second pipeline control console 202 are respectively provided on one side of the pipeline control box 2, corresponding to the connection and opening / closing control of the gas circuit and the electrical circuit.
[0012] Optionally, the fork support 1203 is integrally formed by metal stamping.
[0013] Compared with the prior art, this application includes at least one of the following beneficial technical effects:
[0014] In this invention, the clamping assembly consists of four parts: a wiring frame, a pressure frame, a fork support, and a snap ring. This requires three main steps: connecting the wiring frame to the fork support, fixing the wiring frame to the pressure frame, and installing the snap ring. Through innovative design, this production equipment can achieve these connection and assembly steps. Multiple identification and screening steps are incorporated into the process, significantly reducing labor costs and ensuring a stable product qualification rate. The overall structure of this production equipment is compact and can be adjusted for different product sizes and specifications, further enhancing the product's adaptability and making it suitable for mass production. Attached Figure Description
[0015] Figure 1 This is a three-dimensional schematic diagram of an embodiment of the present utility model;
[0016] Figure 2 for Figure 1 Overall top-down view;
[0017] Figure 3 for Figure 2 A magnified view of the local area in direction A;
[0018] Figure 4 This is a structural illustration of the pipe clamp assembly in this utility model example;
[0019] Figure 5 This is an overall view of the wiring frame loading station;
[0020] Figure 6 Overall view of the fork support loading station;
[0021] Figure 7 This is an overall view of the first assembly station;
[0022] Figure 8 for Figure 7 Main view view diagram;
[0023] Figure 9 An overall view of the auxiliary workstations;
[0024] Figure 10 This is an overall view of the frame pressing and loading station;
[0025] Figure 11 This is an overall view of the second assembly station;
[0026] Figure 12 An overall view of the workstations for screening;
[0027] Figure 13 An overall view of the snap ring installation station;
[0028] Figure 14 for Figure 13 A magnified view of the area along direction B;
[0029] Reference numerals: 1-Bearing base; 2-Pipeline control box; 201-First pipeline control console; 202-Second pipeline control console; 3-Wiring frame loading station; 301-Wiring frame feed tray; 302-Wiring frame loading base; 303-First horizontal moving cylinder; 304-First horizontal chute; 305-Horizontal displacement detector; 306-Vertical displacement detector; 307-First vertical moving cylinder; 3071-First mechanical gripper; 308-Wiring frame conveyor; 4-Forklift support loading station; 401-Forklift support screening box; 402-Forklift support conveyor; 403-Forklift picking cylinder; 404-Second mechanical gripper; 406-First camera recognition sensor; 407-Second camera recognition sensor; 408-Camera display; 4081-Camera controller; 409-Scrap receiving box; 5-First assembly station; 501-First assembly support; 502-First assembly motor; 5021-Transmission connecting rod; 503-Assembly guide rod; 504-Integrated assembler; 5041-Bolt delivery pipe; 5042-First connection assembly port; 505-First displacement identifier; 6-Auxiliary station; 601-Second displacement identifier; 602-Flattening contact; 7-Frame pressing and feeding station; 701-Frame pressing material box; 702-Frame pressing and feeding base; 703-Frame pressing horizontal displacement identifier; 704-Frame pressing horizontal guide rail; 705-Frame pressing horizontal movement cylinder; 706-Rotary movement gear; 707-Second mechanical gripper; 8-Second assembly station; 801-Second assembly motor; 802-Second connection assembly port; 803-Second assembly height identifier; 9-Screening station; 901-Screening lateral displacement identifier; 902-Screening longitudinal displacement identifier; 903-Screening material transfer cylinder; 904-Waste box; 10-Snap ring installation station; 1001-Snap ring conveyor; 1002-Pushing cylinder; 1003-Pushing limit protrusion; 1004-Side pressing cylinder; 1005-Pushing cylinder limit bayonet; 11-Turntable; 1101-Fixed support plate; 1102-Receiving cavity; 12-Pipe clamp assembly; 1201-Wiring frame; 1202-Pressure frame; 1203-Spider support; 1204-Snap ring; 1205-Snap ring groove; Detailed Implementation
[0030] The technical solution of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are some embodiments of this utility model, but not all embodiments.
[0031] The components of the present invention embodiments described and shown in the accompanying drawings can typically be arranged and designed in a variety of different configurations. Therefore, the following detailed description of the embodiments of the present invention provided in the drawings is not intended to limit the scope of the claimed invention, but merely to illustrate selected embodiments of the invention.
[0032] Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this utility model.
[0033] In the description of this utility model, it should be noted that the terms "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," and "outer," etc., indicating the orientation or positional relationship, are based on the orientation or positional relationship shown in the accompanying drawings and are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and should not be construed as indicating or implying relative importance.
[0034] In the description of this utility model, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "joining" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the specific circumstances.
[0035] This embodiment proposes an automated production equipment for fuse clamp assemblies, such as... Figures 1 to 14As shown, the assembly includes a support base 1 and a pipe clamp assembly 12. A turntable 11 is located in the center of the support base 1. Multiple fixed support plates 1101 are evenly distributed around the outer perimeter of the turntable. Each fixed support plate 1101 has a receiving cavity 1102 for holding the pipe clamp assembly 12. Clockwise from the outer perimeter of the fixed support plates 1101, there are a wiring frame loading station 3, a fork support loading station 4, a first assembly station 5, and a second assembly station 8. An auxiliary station 6 and a pressure frame loading station 7 are also provided between the first assembly station 5 and the second assembly station 8. The second assembly station 8 is also equipped with a screening station 9 and a snap ring installation station in a clockwise rotation direction. A pipeline control box 2 is provided on one side of the bearing base 1. The pipeline control box 2 is used to connect and control the air and electrical circuits of the above stations. The pipe clamp assembly 12 includes a wiring frame 1201, a pressure frame 1202 and a fork support 1203. Snap ring grooves 1205 are provided at both ends of the upper outer side of the fork support 1203. Snap rings 1204 are engaged in the snap ring grooves 1205. All the above stations are connected and combined with the pipeline control box 2 to realize the automated production of the pipe clamp assembly 12.
[0036] One end of the wiring frame loading station 3 is connected to a wiring frame feeding tray 301. The wiring frame loading station 3 also includes a wiring frame loading base 302. The wiring frame loading base 302 is provided with a first horizontal slide groove 304. A first horizontal moving cylinder 303 is provided on the first horizontal slide groove 304. A first vertical moving cylinder 307 is provided below the first horizontal moving cylinder 303. A first mechanical gripper 3071 for gripping the wiring frame 1201 is provided below the first vertical moving cylinder 307. A wiring frame conveyor 308 is also connected between the wiring frame loading base 302 and the wiring frame feeding tray 301.
[0037] Through the above scheme, the wiring frame 1201 can be smoothly and orderly placed into the receiving cavity 1102 of the fixed tray 1101 by the first mechanical gripper 3071 according to the rotation speed of the turntable 11.
[0038] One side of the forklift support loading station 4 is connected to the forklift support screening frame 401 via a forklift support conveyor 402. A forklift picking cylinder 403 is provided on the upper part of one side of the forklift support conveyor 402, and a second mechanical gripper 404 is provided on the lower part of the forklift picking cylinder 403. A first camera recognition sensor 406 and a second camera recognition sensor 407 are respectively provided around the side of the forklift support conveyor 402 away from the forklift support screening frame 401. A camera display 408 is suspended at the upper middle part of the forklift support conveyor 402. A camera controller 4081 is provided on one side of the camera display 408. According to the forklift support 1203 of different sizes and specifications, the corresponding shooting sensitivity, exposure and shooting speed and other related parameters are adjusted to meet the shooting and recognition needs under different production conditions. A waste receiving frame 409 is provided on one side of the first camera recognition sensor 406.
[0039] Using the above method, the bottom and sides of the fork support 1203 were photographed and analyzed. The bottom was photographed to check whether the bottom of the fork support was accidentally scratched or deformed during transportation, resulting in unevenness and preventing the bottom of the fork support from being smoothly inserted into the wiring frame 1201. The sides of the fork support 1203 were photographed and analyzed mainly because the fork support 1203 is a stamped one-piece molded unit, and the two sides of the fork support 1203 itself have a certain degree of elasticity. The analysis was to check whether the distance between the two sides was too large or too small, which would affect the subsequent snap ring installation process and prevent the snap ring from being smoothly engaged in the snap ring groove 1205.
[0040] The first assembly station 5 includes a first assembly support 501 and a first assembly motor 502. The lower part of the first assembly motor 502 is connected to a transmission link 5021. The lower end of the transmission link 5021 is coaxially connected to an assembly guide rod 503. An integrated assembler 504 is provided at the lower part of the assembly guide rod 503. A bolt delivery pipe 5041 is also provided at the upper end of the integrated assembler 504. A first connection assembly port 5042 is also provided at the lower end of the integrated assembler 504. The bolt delivery pipe 5041 transports bolts to the lower end of the first connection assembly port 5042 for easy bolt connection. A first displacement identifier 505 is provided at the upper part of the assembly guide rod 503 for identifying and limiting the descent distance of the assembly guide rod 503.
[0041] Based on the above solution, considering that in order for the subsequent clamping frame 1202 to be assembled and snapped with the wiring frame 1201, it is necessary to first insert the bottom of the fork support 1203 into the wiring frame 1201. At the same time, the wiring frame 1201 is moved downward a certain distance by tightening the bolt in the vertical direction. Since the upper circular through hole of the clamping frame 1201 needs to be fastened to the upper end of the bolt, and the vertical height of the clamping frame 1202 is fixed, in order to ensure that the bottom horizontal end of the clamping frame 1201 is inserted into the wiring frame 1201, the downward stroke of the first connection assembly port 5042 is limited by precise positioning measurement to ensure the above-mentioned subsequent processes.
[0042] The auxiliary workstation 6 is equipped with a second displacement identifier 601. The lower part of the second displacement identifier 601 is equipped with a flattening contact 602 to flatten the upper end of the fixed support plate 1101 that is rotated to the lower part of the flattening contact 602 and the corresponding spigot support 1203, so as to facilitate the operation of subsequent processes.
[0043] The pressing frame feeding station 7 is equipped with a pressing frame feeding base 702. A pressing frame material frame 701 is connected to one side of the pressing frame feeding base 702 for conveying the pressing frame 1202. The upper end of the pressing frame feeding base 702 is horizontal, and both ends are respectively equipped with a pressing frame horizontal displacement identifier 703 and a pressing frame feeding horizontal guide rail 704. A pressing frame horizontal movement cylinder 705 is installed on the pressing frame feeding horizontal guide rail 704. A rotating moving tooth 706 is provided on one end of the pressing frame horizontal movement cylinder 705, and a second mechanical gripper 707 is provided at the lower part of the rotating moving tooth 706 for picking up and placing the pressing frame 1202 and rotating it to an angle suitable for assembly. The upper circular hole of the pressing frame 1202 is fastened to the upper part of the bolt on the wiring frame 1201, and the lower part of the pressing frame 1202 is inserted into the interior of the wiring frame 1201.
[0044] The second assembly station 8 is equipped with a second assembly motor 801. A second assembly connection port 802 is connected to the lower part of the second assembly motor 801. A second assembly height detector 803 is installed on one side of the second assembly connection port 802 to monitor its vertical movement. The second assembly motor 801 has a torque recognition mode. The second assembly connection port 802 tightens the bolts of the wiring frame 1201 according to the calibrated torque. Once the set torque is reached, the second assembly connection port automatically stops tightening the bolts and retracts and rises a short distance. The screening station 9 is equipped with a screening lateral displacement identifier 901, a screening longitudinal displacement identifier 902, and a screening transfer cylinder 903. If the second connection assembly port 802 on the corresponding second assembly station 8 detects that the bolt on the wiring frame 1201 is not tightened after reaching the calibrated torque, and the bolt is loosened by turning, then the corresponding wiring frame 1201 fails to tighten and is determined to be a defective product. The screening transfer cylinder 903 is equipped with a waste box 904 below it. The waste box 904 is picked up and transferred by the gripper below the screening transfer cylinder 903.
[0045] The snap ring installation station 10 is provided with a snap ring conveyor 1001. A pusher cylinder 1002 is provided at one end of the snap ring conveyor 1001. A pusher limiting protrusion 1003 is provided in the direction perpendicular to the snap ring conveyor 1001. The pusher limiting protrusion 1003 abuts against the upper end of the snap ring 1204. A pusher cylinder limiting slot 1005 is provided at the far end of the pusher limiting protrusion 1003 along the pushing direction. The pusher cylinder 1002 pushes the pusher limiting protrusion 1003 to the pusher cylinder limiting slot 1005, pushing the snap ring 1204 into the snap ring grooves 1205 on both sides of the fork support 1203. A lateral pressing cylinder 1004 is also provided on one side of the pusher limiting protrusion 1003 for laterally pressing the two sides of the fork support 1203 after installation. At this point, the overall installation of the pipe clamp assembly 12 is complete.
[0046] The pipeline control box 2 has a first pipeline control console 201 and a second pipeline control console 202 respectively installed on one side, corresponding to the connection and opening / closing control of the air circuit and the electrical circuit. The spout support 1203 is integrally formed by metal stamping.
[0047] The above specific embodiments are merely several optional embodiments of this utility model. Based on the technical solution of this utility model and the relevant teachings of the above embodiments, those skilled in the art can make various alternative improvements and combinations to the above specific embodiments.
Claims
1. An automated production equipment for fuse clamp assemblies, characterized in that, include: The system comprises a support base and a pipe clamp assembly. A turntable is located in the center of the support base, and multiple fixed trays are evenly distributed around the outer perimeter of the turntable. Each fixed tray has an internal cavity for holding the pipe clamp assembly. Clockwise from the outer perimeter of the fixed trays are a wiring frame loading station, a fork support loading station, a first assembly station, and a second assembly station. An auxiliary station and a pressure frame loading station are located between the first and second assembly stations. Clockwise from the second assembly station, a screening station and a snap ring installation station are also provided. A pipeline control box is located on one side of the support base, used for connecting and controlling the air and electrical circuits of the aforementioned stations. The pipe clamp assembly includes a wiring frame, a pressure frame, and a fork support. Snap ring grooves are located at both ends of the upper outer side of the fork support, and snap rings are engaged in these grooves. All the aforementioned stations and the pipeline control box are connected and combined to achieve automated production of the pipe clamp assembly.
2. The automated production equipment for fuse clamp assemblies according to claim 1, characterized in that: One end of the wiring frame feeding station is connected to a wiring frame feeding tray. The wiring frame feeding station also includes a wiring frame feeding base. The wiring frame feeding base is provided with a first horizontal slide groove. A first horizontal moving cylinder is provided on the first horizontal slide groove. A first vertical moving cylinder is provided below the first horizontal moving cylinder. A first mechanical gripper for gripping the wiring frame is provided below the first vertical moving cylinder. A wiring frame conveyor is also connected between the wiring frame feeding base and the wiring frame feeding tray.
3. An automated production equipment for fuse clamp assemblies according to claim 1, characterized in that: One side of the forklift support loading station is connected to the forklift support screening frame via a forklift support conveyor. A forklift picking cylinder is installed on the upper part of one side of the forklift support conveyor, and a second mechanical gripper is installed below the forklift picking cylinder. A first camera recognition sensor and a second camera recognition sensor are respectively installed around the side of the forklift support conveyor away from the forklift support screening frame. A camera display is suspended at the upper middle part of the forklift support conveyor, and a camera controller is installed on one side of the camera display. According to the forklift support of different sizes and specifications, the corresponding shooting sensitivity, exposure and shooting speed and other related parameters are adjusted to meet the shooting and recognition needs under different production conditions. A waste receiving frame is installed on one side of the first camera recognition sensor.
4. An automated production equipment for fuse clamp assemblies according to claim 1, characterized in that: The first assembly station includes a first assembly support and a first assembly motor. A transmission link is connected to the lower part of the first assembly motor. The lower end of the transmission link is coaxially connected to an assembly guide rod. An integrated assembler is provided at the lower part of the assembly guide rod. A bolt delivery pipe is also provided at the upper end of the integrated assembler. A first connection assembly port is also provided at the lower end of the integrated assembler. The bolt delivery pipe transports bolts to the lower end of the first connection assembly port for easy bolt connection. A first displacement identifier is provided at the upper part of the assembly guide rod for identifying and limiting the descent distance of the assembly guide rod.
5. An automated production equipment for fuse clamp assemblies according to claim 1, characterized in that: The auxiliary workstation is equipped with a second displacement identifier. The lower part of the second displacement identifier is equipped with a flattening contact. The fixed support plate that rotates to the lower part of the flattening contact is flattened at the upper end of the corresponding fork support, which facilitates the operation of subsequent processes.
6. An automated production equipment for fuse clamp assemblies according to claim 1, characterized in that: The pressing frame feeding station is equipped with a pressing frame feeding base. A pressing frame material frame is connected to one side of the pressing frame feeding base for conveying the pressing frame. The upper end of the pressing frame feeding base extends horizontally, and a pressing frame horizontal displacement identifier and a pressing frame feeding horizontal guide rail are respectively set at both ends. A pressing frame horizontal moving cylinder is set on the pressing frame feeding horizontal guide rail. A rotating moving tooth is set on one side of the pressing frame horizontal moving cylinder. A second mechanical gripper is set at the lower part of the rotating moving tooth for picking up and placing the pressing frame and rotating it to an angle suitable for assembly.
7. An automated production equipment for fuse clamp assemblies according to claim 1, characterized in that: The second assembly station is equipped with a second assembly motor. The lower part of the second assembly motor is connected to a second connection assembly port. A second assembly height identifier is installed on one side of the second connection assembly port to monitor the vertical movement of the second connection assembly port. The second assembly motor is equipped with a torque recognition mode. The second connection assembly port tightens the bolts of the wiring frame according to the calibrated torque. When the set torque is reached, the second connection assembly port will automatically stop tightening the bolts and retract and rise a certain distance. The screening station is equipped with a screening lateral displacement identifier, a screening longitudinal displacement identifier, and a screening transfer cylinder. If the second connection assembly port on the corresponding second assembly station detects that the bolts on the wiring frame are not tightened after the calibrated torque is reached, and the bolts are loosened by spinning, then the tightening of the corresponding wiring frame has failed, and the wiring frame is determined to be a defective product. A waste box is set below the screening transfer cylinder. The waste box is picked up and transferred by the gripper below the screening transfer cylinder.
8. An automated production equipment for fuse clamp assemblies according to claim 1, characterized in that: The snap ring installation station is equipped with a snap ring conveyor. A pusher cylinder is provided at one end of the snap ring conveyor. A pusher limiting protrusion is provided in the direction perpendicular to the snap ring conveyor. The pusher limiting protrusion abuts against the upper end of the snap ring. A pusher cylinder limiting slot is provided at the far end of the pusher limiting protrusion along the pushing direction. The pusher cylinder pushes the pusher limiting protrusion to the pusher cylinder limiting slot, pushing the snap ring into the snap ring grooves on both sides of the fork support. A lateral pressing cylinder is also provided on one side of the pusher limiting protrusion for laterally pressing the two sides of the fork support after installation.
9. An automated production equipment for fuse clamp assemblies according to claim 1, characterized in that: The pipeline control box has a first pipeline control console and a second pipeline control console installed on one side, which correspond to the connection and opening / closing control of the gas circuit and the electrical circuit, respectively.
10. An automated production equipment for fuse clamp assemblies according to claim 1, characterized in that: The spigot support is manufactured by integral metal stamping.