A wire trough continuous punching and cutting integrated equipment
By designing an integrated continuous punching and cutting equipment for wire troughs, and utilizing a transverse drive component and a position-adjustable cutting component, the problem of the difficulty in flexibly adjusting the punching and cutting positions of existing equipment has been solved, thus achieving efficient and flexible wire trough processing.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUBEI HANLIANG ELECTRIC TECHNOLOGY CO LTD
- Filing Date
- 2025-06-20
- Publication Date
- 2026-06-19
AI Technical Summary
Existing wire trough processing equipment is difficult to adjust the number and size of punches flexibly, and the cutting position is inaccurate, resulting in low processing efficiency and cumbersome procedures.
An integrated continuous punching and cutting device for wire troughs was designed, comprising a transverse drive assembly and a position-adjustable cutting assembly. The device uses a servo motor to drive a threaded rod to move a T-shaped extension plate, achieving continuous and efficient punching and cutting. The device also uses a cylinder to control the precise positioning of the detachable punching section and the cutting position.
It enables flexible punching and precise cutting according to different needs, reduces process changeover time, greatly improves processing efficiency, and enhances the practicality and flexibility of the equipment.
Smart Images

Figure CN224372555U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of wire trough processing technology, and in particular to an integrated device for continuous punching and cutting of wire troughs. Background Technology
[0002] Wire trough punching involves using punching equipment to create regular holes at specific locations within the wire trough according to design requirements. These holes are used to guide wires or install fasteners. The shape and size of the holes are customized according to actual needs, such as round holes or square holes, allowing for flexible layout and connection of the wiring within the trough. Wire trough cutting involves creating openings on the edge or side of the trough using cutting tools. This is typically used for branching, corner connections, or special installation scenarios. The shape and angle of the cut need to be determined based on the trough's direction and connection method to meet the requirements for wire branching or turning.
[0003] In the existing wire trough processing, the punching section of traditional equipment is difficult to adjust flexibly according to the number or size of punches, and the cutting position cannot be precisely adjusted, making it difficult to meet different processing needs. Punching and cutting are usually performed separately, and the switching between punching and cutting processes is cumbersome, resulting in low processing efficiency and certain drawbacks in the process.
[0004] In view of the above, this utility model is hereby proposed. Utility Model Content
[0005] To overcome the technical defects of the existing technology, this utility model provides an integrated equipment for continuous punching and cutting of wire troughs. It can adapt to different punching needs, accurately position the cutting position, meet diverse processing requirements, and achieve continuous and efficient processing, reducing process changeover time and significantly improving processing efficiency.
[0006] The technical solution adopted by this utility model is as follows: it includes a fixed base and an L-shaped connecting frame. The L-shaped connecting frame is installed on the top of the fixed base. A horizontal mounting strip is fixedly installed at one end of the L-shaped connecting frame. A limiting groove is opened at the bottom of the horizontal mounting strip. The horizontal movement drive assembly is installed in the limiting groove. A T-shaped extension plate is installed on the horizontal movement drive assembly. A first vertical cylinder and a second vertical cylinder are fixedly installed at one end of the T-shaped extension plate. A detachable punched part is fixedly installed at the telescopic end of the first vertical cylinder. A horizontal connecting strip is fixedly installed at the telescopic end of the second vertical cylinder. A connecting groove is opened at the bottom of the horizontal connecting strip. A position-adjustable cutting assembly is installed in the connecting groove. A pointer is installed on the position-adjustable cutting assembly. One end of the pointer corresponds to the indicator scale opened on the outer wall of the horizontal connecting strip.
[0007] Preferably, in order to enable the drive threaded rod to rotate in the limiting slide groove via the first rotary joint by controlling the servo motor to turn on, the transverse drive assembly includes the servo motor and the drive threaded rod. The servo motor is fixed on the inner wall of one end of the limiting slide groove, and the drive threaded rod is rotatably mounted on the inner wall of the other end of the limiting slide groove via the first rotary joint. One end of the drive threaded rod is fixedly connected to the output shaft of the servo motor.
[0008] Preferably, in order to control the rotation of the drive threaded rod so that the threaded slider can slide in the limiting groove, thereby driving the T-shaped extension plate to move, the threaded slider is mounted on the drive threaded rod, the threaded slider is slidably engaged in the limiting groove, and the T-shaped extension plate is fixed on the threaded slider.
[0009] Preferably, in order to facilitate the assembly and disassembly of the punch head via the fixing screw and the threaded sleeve, the detachable punching part includes the mounting top plate and the punch head. The fixing screw is evenly installed on the bottom of the mounting top plate, and the punch head is fixed to the fixing screw by the threaded sleeve.
[0010] Preferably, in order to control the screwing head so that the adjusting screw can rotate in the connecting groove via the second rotary joint, the position-adjustable cutting assembly includes the adjusting screw, which is rotatably mounted on the inner wall of one end of the connecting groove via the second rotary joint, and the screwing head is fixedly mounted on one end of the adjusting screw, with the screwing head located on the outer side of one end of the transverse connecting strip.
[0011] Preferably, in order to enable the adjusting slider to slide in the connecting groove by controlling the rotation of the adjusting screw, the adjusting slider is threaded onto the adjusting screw, and the adjusting slider is slidably engaged in the connecting groove.
[0012] Preferably, in order to precisely control the movement distance of the adjusting slider by means of the pointer, the vertical suspension plate is fixedly installed at the bottom of the adjusting slider, and the pointer is fixed on the vertical suspension plate.
[0013] Preferably, in order to enable the cutting blade to rotate on the vertical suspension plate by controlling the drive motor to turn on, the drive motor is fixedly installed on one side wall of the vertical suspension plate, and the cutting blade is rotatably installed on the other side wall of the vertical suspension plate, with one end of the cutting blade fixedly connected to the output shaft of the drive motor.
[0014] The beneficial effects of this utility model are: by using the transverse drive component to move the detachable punching part and the position-adjustable cutting component, continuous and efficient processing can be achieved; the detachable punching part can be flexibly disassembled and replaced to adapt to different punching needs; the position-adjustable cutting component can precisely adjust the cutting position to meet diverse processing requirements, and can independently control the cylinder to achieve punching or cutting, reducing process switching time, greatly improving processing efficiency, and having higher practicality and flexibility. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0016] Figure 2 This is a schematic diagram of the installation structure of the T-shaped extension plate of this utility model;
[0017] Figure 3 This is a schematic diagram of the transverse drive assembly of this utility model;
[0018] Figure 4 This is a schematic diagram of the detachable punching part of this utility model;
[0019] Figure 5 This is a schematic diagram of the adjustable position cutting component of this utility model.
[0020] Explanation of reference numerals in the attached drawings: 1. Fixed base; 2. L-shaped connecting frame; 3. Horizontal mounting strip; 4. Horizontal drive assembly; 401. Servo motor; 402. Drive threaded rod; 403. First rotary joint; 404. Threaded slider; 5. T-shaped extension plate; 6. First vertical cylinder; 7. Second vertical cylinder; 8. Demountable punching part; 801. Mounting top plate; 802. Punching head; 803. Fixed screw; 804. Threaded sleeve; 9. Horizontal connecting strip; 10. Position adjustable cutting assembly; 1001. Adjusting screw; 1002. Second rotary joint; 1003. Twisting head; 1004. Adjusting slider; 1005. Vertical suspension plate; 1006. Drive motor; 1007. Cutting blade; 11. Pointer. Detailed Implementation
[0021] The present invention will be further described below with reference to the accompanying drawings:
[0022] like Figures 1-5As shown, this embodiment provides an integrated device for continuous punching and cutting of wire troughs, including a fixed base 1 and an L-shaped connecting frame 2. The L-shaped connecting frame 2 is installed on the top of the fixed base 1. A horizontal mounting block 3 is fixedly installed at one end of the L-shaped connecting frame 2. A limiting groove is opened at the bottom of the horizontal mounting block 3. A horizontal movement drive assembly 4 is installed in the limiting groove. A T-shaped extension plate 5 is installed on the horizontal movement drive assembly 4. A first vertical cylinder 6 and a second vertical cylinder 7 are fixedly installed at one end of the T-shaped extension plate 5. A detachable punching part 8 is fixedly installed at the telescopic end of the first vertical cylinder 6. A horizontal connecting strip 9 is fixedly installed at the telescopic end of the second vertical cylinder 7. A connecting groove is opened at the bottom of the horizontal connecting strip 9. A position-adjustable cutting assembly 10 is installed in the connecting groove. A pointer 11 is installed on the position-adjustable cutting assembly 10. One end of the pointer 11 is connected to a pointer on the outer wall of the horizontal connecting strip 9. Corresponding to the scale markings, during use, the detachable punching section 8 and the position-adjustable cutting component 10 are located above the wire groove. Controlling the first vertical cylinder 6 enables the detachable punching section to punch holes in the wire groove, and controlling the second vertical cylinder 7 enables the position-adjustable cutting component 10 to cut the wire groove. Controlling the transverse drive component 4 enables the detachable punching section 8 and the position-adjustable cutting component 10 to move above the wire groove, realizing continuous punching or cutting operations. During use, the detachable punching section 8 can be flexibly disassembled or replaced according to the number or size of punches, and the cutting position of the position-adjustable cutting component 10 can be precisely adjusted relative to the punching position to meet different processing needs. Controlling the first vertical cylinder 6 or the second vertical cylinder 7 alone can realize punching or cutting operations independently, reducing process changeover time and increasing processing efficiency.
[0023] As a technical optimization solution of this utility model, specifically as follows: Figure 3 As shown, the lateral movement drive assembly 4 includes a servo motor 401 and a drive threaded rod 402. The servo motor 401 is fixed to the inner wall of one end of the limiting slide groove, and the drive threaded rod 402 is rotatably mounted on the inner wall of the other end of the limiting slide groove through a first rotary joint 403. One end of the drive threaded rod 402 is fixedly connected to the output shaft of the servo motor 401. A threaded slider 404 is mounted on the drive threaded rod 402 and is slidably engaged in the limiting slide groove. A T-shaped extension plate 5 is fixed on the threaded slider 404. In use, the servo motor 401 is turned on, and its output shaft drives the drive threaded rod 402 to rotate in cooperation with the first rotary joint 403. As the drive threaded rod 402 rotates, the threaded slider 404 moves along the drive threaded rod 402 under the action of the thread and remains stable due to being slidably engaged in the limiting slide groove. This, in turn, drives the T-shaped extension plate 5 fixed on it to move, realizing the lateral displacement of the punching and cutting components, so that punching and cutting can be performed continuously.
[0024] As a technical optimization solution of this utility model, specifically as follows: Figure 4As shown, the detachable punching unit 8 includes a mounting top plate 801 and a punching head 802. Fixing screws 803 are evenly installed on the bottom of the mounting top plate 801. The punching head 802 is fixed to the fixing screws 803 via threaded sleeves 804. In use, the threaded sleeves 804 of the punching head 802 are aligned with the evenly distributed fixing screws 803 on the bottom of the mounting top plate 801, and then the punching head 802 is rotated to ensure a tight connection and fixation between the threaded sleeves 804 and the fixing screws 803. When it is necessary to replace the punching heads 802 with different specifications or quantities, the punching head 802 is rotated in the opposite direction to remove it, and then a suitable punching head 802 is installed.
[0025] As a technical optimization solution of this utility model, specifically as follows: Figure 5 As shown, the position-adjustable cutting assembly 10 includes an adjusting screw 1001, which is rotatably mounted on the inner wall of one end of the connecting slide groove via a second rotary joint 1002. A screw head 1003 is fixedly mounted on one end of the adjusting screw 1001, located on the outer side of one end of the transverse connecting strip 9. An adjusting slider 1004 is threaded onto the adjusting screw 1001, and the adjusting slider 1004 is slidably engaged in the connecting slide groove. A vertical suspension is fixedly mounted on the bottom of the adjusting slider 1004. The pointer 11 is fixed on the vertical hanging plate 1005. A drive motor 1006 is fixedly installed on one side wall of the vertical hanging plate 1005, and a cutting blade 1007 is rotatably installed on the other side wall of the vertical hanging plate 1005. One end of the cutting blade 1007 is fixedly connected to the output shaft of the drive motor 1006. In use, the screw head 1003 located on the outside of one end of the horizontal connecting bar 9 is turned, which drives the adjusting screw 1001 to rotate in cooperation with the second rotating joint 1002. The adjustment screw 1001 rotates, causing the adjustment slider 1004 connected to the threaded sleeve 804 to move along the connecting groove. The adjustment slider 1004 drives the vertical suspension plate 1005 to move, thereby adjusting the position of the cutting blade 1007. The pointer 11 moves with the vertical suspension plate 1005 and indicates the position on the indicator scale. The position of the punch can be used as a reference to achieve precise adjustment of the cutting position. After adjustment, the second vertical cylinder 7 and the drive motor 1006 are started to drive the cutting blade 1007 to cut the groove.
[0026] The foregoing has shown and described the basic principles, main features, and advantages of this invention. Those skilled in the art should understand that this invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this invention. Various changes and modifications may be made to this invention without departing from its spirit and scope. All such changes and modifications fall within the scope of this invention as defined by the appended claims and their equivalents.
Claims
1. A wire duct continuous punching and cutting integrated device, comprising a fixed base (1) and an L-shaped connecting frame (2), the L-shaped connecting frame (2) is installed on the top of the fixed base (1), characterized in that: One end of the L-shaped connecting frame (2) is fixedly installed with a horizontal mounting block (3). The bottom of the horizontal mounting block (3) is provided with a limiting groove. A horizontal movement drive assembly (4) is installed in the limiting groove. A T-shaped extension plate (5) is installed on the horizontal movement drive assembly (4). A first vertical cylinder (6) and a second vertical cylinder (7) are fixedly installed on one end of the T-shaped extension plate (5). A detachable punching part (8) is fixedly installed on the telescopic end of the first vertical cylinder (6). A horizontal connecting strip (9) is fixedly installed on the telescopic end of the second vertical cylinder (7). A connecting groove is provided at the bottom of the horizontal connecting strip (9). A position-adjustable cutting assembly (10) is installed in the connecting groove. A pointer (11) is installed on the position-adjustable cutting assembly (10). One end of the pointer (11) corresponds to the indicator scale opened on the outer wall of the horizontal connecting strip (9).
2. The wireway continuous punching and cutout integrated apparatus according to claim 1, wherein: The transverse drive assembly (4) includes a servo motor (401) and a drive threaded rod (402). The servo motor (401) is fixed on the inner wall of one end of the limiting slide groove, and the drive threaded rod (402) is rotatably mounted on the inner wall of the other end of the limiting slide groove through a first rotating joint (403). One end of the drive threaded rod (402) is fixedly connected to the output shaft of the servo motor (401).
3. The wireway continuous punching and slit integrated apparatus according to claim 2, wherein: A threaded slider (404) is installed on the drive threaded rod (402), and the threaded slider (404) is slidably engaged in the limiting groove. The T-shaped extension plate (5) is fixed on the threaded slider (404).
4. The electrical wireway continuous punch and slit integrated apparatus of claim 1, wherein: The detachable punching part (8) includes a mounting top plate (801) and a punching head (802). The bottom of the mounting top plate (801) is uniformly equipped with fixing screws (803), and the punching head (802) is fixed on the fixing screws (803) by a threaded sleeve (804).
5. The integrated equipment for continuous punching and cutting of wire troughs according to claim 1, characterized in that: The position-adjustable cutting assembly (10) includes an adjusting screw (1001), which is rotatably mounted on the inner wall of one end of the connecting slide through a second rotating joint (1002). A screw head (1003) is fixedly mounted on one end of the adjusting screw (1001), and the screw head (1003) is located on the outer side of one end of the transverse connecting strip (9).
6. The integrated equipment for continuous punching and cutting of wire troughs according to claim 5, characterized in that: An adjusting slider (1004) is threaded onto the adjusting screw (1001), and the adjusting slider (1004) is slidably engaged in the connecting groove.
7. The integrated equipment for continuous punching and cutting of wire troughs according to claim 6, characterized in that: The bottom of the adjusting slider (1004) is fixedly installed with a vertical suspension plate (1005), and the pointer (11) is fixed on the vertical suspension plate (1005).
8. The integrated equipment for continuous punching and cutting of wire troughs according to claim 7, characterized in that: A drive motor (1006) is fixedly installed on one side wall of the vertical suspension plate (1005), and a cutting blade (1007) is rotatably installed on the other side wall of the vertical suspension plate (1005). One end of the cutting blade (1007) is fixedly connected to the output shaft of the drive motor (1006).