High-precision Y-axis module

By introducing moving and lifting components into the Y-axis module, multi-directional adjustment of the slider and machining machinery is achieved, solving the problem of single-directional adjustment in the prior art and improving the adjustment range and stability.

CN224411283UActive Publication Date: 2026-06-26BAIMA EMBROIDERY MACHINERY (DONGGUAN) CO LTD +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
BAIMA EMBROIDERY MACHINERY (DONGGUAN) CO LTD
Filing Date
2025-07-23
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

The existing Y-axis module can only be moved and adjusted in one direction, which cannot meet the needs of multi-directional adjustment and has poor practicality.

Method used

A high-precision Y-axis module was designed, comprising a moving component and a lifting component. The longitudinal movement adjustment is achieved by a motor driving a lead screw, a drive wheel, and a connecting belt, while the lifting adjustment is achieved by a bidirectional screw and a lifting component. The support component improves the stability of the movement.

Benefits of technology

This technology enables multi-directional movement adjustment of the slider and the machining machinery mounted on it, improving the adjustment range and the practicality of the device.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224411283U_ABST
    Figure CN224411283U_ABST
Patent Text Reader

Abstract

The utility model discloses a high accuracy Y axle module belongs to automation equipment technical field, including the base plate, the base plate upper end is fixed with dovetail block, and the both sides fixed bearing block of dovetail block upper end, and one side bearing block one end is installed with motor no.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model belongs to the field of automation equipment technology, specifically relating to a high-precision Y-axis module. Background Technology

[0002] Automated equipment refers to equipment systems that integrate mechanical, electrical, computer, and sensor technologies to achieve unmanned or intelligent operation of tasks such as production, inspection, and material handling. They are widely used in industrial manufacturing, logistics, medical, agricultural, and service industries, and are a core component of modern intelligent manufacturing. High-precision Y-axis modules are mechanical transmission systems used to achieve precise linear motion, and are widely used in semiconductor equipment, laser processing, precision measurement, 3C electronics manufacturing, medical equipment, embroidery machines, and other fields.

[0003] The existing Y-axis module can only be adjusted in one direction, and the adjustment range of the machining machinery mounted on the slider is limited. It cannot be adjusted in multiple directions for the machining machinery mounted on the slider, and the device has poor practicality. Utility Model Content

[0004] To address the problems mentioned in the background art, this utility model provides a high-precision Y-axis module, which has the characteristic of being able to adjust the movement of machining machinery mounted on a slider in multiple directions.

[0005] To achieve the above objectives, the present invention provides the following technical solution: a high-precision Y-axis module, comprising a base plate, a dovetail block fixed at the upper end of the base plate, bearing seats fixed on both sides of the upper end of the dovetail block, a motor 1 installed at one end of one bearing seat, a lead screw provided at the output end of the motor 1, a slider threadedly connected to the surface of the lead screw, a plurality of mounting holes provided at the upper end of the slider, and a moving component provided at the lower end of the base plate.

[0006] The moving component includes a strip box. The strip box is disposed on the lower side of the base plate. A second motor is installed on one side of the front end of the strip box. A drive wheel is disposed on the output end of the second motor. A driven wheel is rotatably connected inside the strip box on the side away from the drive wheel. A connecting belt is disposed between the driven wheel and the drive wheel. I-shaped blocks are fixed on both sides of the upper end of the connecting belt. A sliding groove corresponding to the I-shaped block is opened at the upper end of the strip box. A lifting component is disposed at the lower end of the strip box. A support component is disposed between the base plate and the strip box.

[0007] Preferably, the support assembly includes side plates, two side plates are fixed at both ends of the strip box, a fixing rod is fixed between the two side plates, a slide block is slidably connected to the fixing rod, a connecting frame is fixed between the slide block and the base plate, and a support column is fixed between the upper end of the slide block and the base plate.

[0008] Preferably, the I-shaped block and the base plate, as well as the side plate and the strip box, are all spot welded together, and the drive wheel and the driven wheel are all rotatably connected to the strip box.

[0009] Preferably, the side of the I-shaped block is in close contact with the inner wall of the slide groove, the slide seat has a sliding hole corresponding to the fixed rod, and the connecting frame and the slide seat are welded as a whole.

[0010] Preferably, the lifting assembly includes a lifting component, a base box is provided on the lower side of the strip box, a motor is installed on the lower side of one end of the base box, a bidirectional screw is provided at the output end of the motor, a movable seat is threaded on both sides of the surface of the bidirectional screw, the movable seat is connected to the strip box through a rotating rod, a rectangular groove corresponding to the rotating rod is opened at the upper end of the base box, and guide rods are fixed on both sides of the lower end of the strip box.

[0011] Preferably, the upper end of the base box has sliding holes on both sides corresponding to the guide rod, and the rear end of the base box is fixed with a maintenance plate by bolts.

[0012] Preferably, the rotating rod and the strip box, as well as the rotating rod and the movable seat, are rotatably connected by a pivot pin, and the two movable seats are threaded to the bidirectional screw in opposite directions.

[0013] Compared with the prior art, the beneficial effects of this utility model are:

[0014] 1. This utility model, by setting a moving component, turns on the motor to drive the drive wheel to rotate, which in turn drives the connecting belt to rotate. The driven wheel rotates in the strip box, and the rotating connecting belt drives the I-shaped block to move in the slide groove at the upper end of the strip box. The movement of the I-shaped block drives the base plate to move, thereby achieving the effect of longitudinal movement adjustment of the slider and the processing machinery. By setting the moving component, the slider and the processing machinery mounted on the slider can be longitudinally moved and adjusted, thus improving the adjustment range.

[0015] 2. This utility model, by setting up a lifting component, activates a three-drive bidirectional screw motor to rotate. The rotation of the bidirectional screw drives two moving seats to move towards each other in the base box. The movement of the two moving seats pushes the strip box to rise and fall through a rotating rod. The rotating rod slides in a rectangular groove at the upper end of the base box, while the guide rod slides on both sides at the upper end of the base box. The rise and fall of the strip box pushes the base plate to rise and fall. By setting up the lifting component, the processing machinery installed on the slider can be raised and lowered according to the needs, improving the practicality of the device. Attached Figure Description

[0016] Figure 1 This is a perspective view of the present utility model;

[0017] Figure 2 This is a bottom-view perspective view of the present invention;

[0018] Figure 3 This is a sectional perspective view of the strip box of this utility model;

[0019] Figure 4 This is a sectional perspective view of the base box of this utility model;

[0020] In the diagram: 1. Base plate; 2. Moving component; 21. Strip box; 22. Motor II; 23. Drive wheel; 24. Driven wheel; 25. Connecting belt; 26. I-shaped block; 27. Slide groove; 28. Support component; 281. Side plate; 282. Fixed rod; 283. Slide seat; 284. Connecting frame; 285. Support column; 3. Lifting component; 31. Base box; 32. Motor III; 33. Guide rod; 34. Rotating rod; 35. Bidirectional screw; 36. Moving seat; 37. Rectangular groove; 4. Dovetail block; 5. Bearing seat; 6. Slider; 7. Mounting hole; 8. Lead screw; 9. Motor I. Detailed Implementation

[0021] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0022] Example 1

[0023] Please see Figure 1-4 The present invention provides the following technical solution: a high-precision Y-axis module, including a base plate 1, a dovetail block 4 fixed on the upper end of the base plate 1, bearing seats 5 fixed on both sides of the upper end of the dovetail block 4, a motor 9 installed on one end of one bearing seat 5, a lead screw 8 provided at the output end of the motor 9, a slider 6 threadedly connected to the surface of the lead screw 8, a plurality of mounting holes 7 opened on the upper end of the slider 6, and a moving component 2 provided at the lower end of the base plate 1.

[0024] The moving component 2 includes a strip box 21. The strip box 21 is disposed on the lower side of the base plate 1. A second motor 22 is installed on one side of the front end of the strip box 21. A drive wheel 23 is disposed at the output end of the second motor 22. A driven wheel 24 is rotatably connected inside the strip box 21 on the side away from the drive wheel 23. A connecting belt 25 is disposed between the driven wheel 24 and the drive wheel 23. I-shaped blocks 26 are fixed on both sides of the upper end of the connecting belt 25. A sliding groove 27 corresponding to the I-shaped block 26 is opened at the upper end of the strip box 21. A lifting component 3 is disposed at the lower end of the strip box 21. A support component 28 is disposed between the base plate 1 and the strip box 21.

[0025] Specifically, the support assembly 28 includes side plates 281. Two side plates 281 are fixed at both ends of the strip box 21. A fixing rod 282 is fixed between the two side plates 281. A slide block 283 is slidably connected to the fixing rod 282. A connecting frame 284 is fixed between the slide block 283 and the base plate 1. A support column 285 is fixed between the upper end of the slide block 283 and the base plate 1.

[0026] By adopting the above technical solution, when the substrate 1 moves, the slide 283 at one end of the connecting frame 284 on both sides of the lower end of the substrate 1 slides on the fixed rod 282. At the same time, a support column 285 is set between the slide 283 and the substrate 1 to make the substrate 1 and the slide 283 more stable. By setting the support component 28, the movement of the substrate 1 can be supported, thereby improving the stability of the movement of the substrate 1.

[0027] Specifically, the I-shaped block 26 is spot-welded to the base plate 1, and the side plate 281 is spot-welded to the strip box 21. The drive wheel 23 and the driven wheel 24 are rotatably connected to the strip box 21.

[0028] By adopting the above technical solution, spot welding makes the I-shaped block 26 and the base plate 1, as well as the side plate 281 and the strip box 21, more secure, and both the drive wheel 23 and the driven wheel 24 can rotate in the strip box 21.

[0029] Specifically, the side of the I-shaped block 26 is in close contact with the inner wall of the slide groove 27, and the slide seat 283 has a sliding hole corresponding to the fixed rod 282. The connecting frame 284 and the slide seat 283 are welded as one piece.

[0030] By adopting the above technical solution, the I-shaped block 26 slides more stably in the slide groove 27, the slide seat 283 can slide on the fixed rod 282, and the connecting frame 284 and the slide seat 283 are welded as one piece, making them more robust and durable.

[0031] In this embodiment, when using the high-precision Y-axis module, the device is installed in a suitable position. The machining mechanism is mounted and fixed onto the slider 6 through the mounting holes 7. Motor 9 is turned on to drive the lead screw 8 to rotate. The rotation of the lead screw 8 moves the slider 6, allowing for lateral movement adjustment of the machining mechanism on the slider 6. Motor 22 is turned on to drive the drive wheel 23 to rotate, which in turn drives the connecting belt 25 to rotate. The driven wheel 24 rotates in the strip box 21. The rotation of the connecting belt 25 drives the I-shaped block 26 to move in the groove 27 at the upper end of the strip box 21. The movement of the I-shaped block 26 moves the base plate 1, thereby... The effect of longitudinal movement adjustment of slider 6 and processing machinery is achieved by setting the moving component 2. The longitudinal movement adjustment of slider 6 and processing machinery installed on slider 6 can be achieved by setting the moving component 28, thereby improving the adjustment range. When the base plate 1 moves, the slide 283 at one end of the connecting frame 284 on both sides of the lower end of the base plate 1 slides on the fixed rod 282. At the same time, the support column 285 is set between the slide 283 and the base plate 1 to make the base plate 1 and the slide 283 more stable. The support component 28 can support the movement of the base plate 1 and improve the stability of the movement of the base plate 1.

[0032] Example 2

[0033] The difference between this embodiment and embodiment 1 is that: the lifting assembly 3 includes a lifting assembly 3, a base box 31 is provided on the lower side of the strip box 21, a motor 32 is installed on the lower side of one end of the base box 31, a bidirectional screw 35 is provided at the output end of the motor 32, a movable seat 36 is threaded on both sides of the surface of the bidirectional screw 35, the movable seat 36 is connected to the strip box 21 through a rotating rod 34, a rectangular groove 37 corresponding to the rotating rod 34 is opened at the upper end of the base box 31, and guide rods 33 are fixed on both sides of the lower end of the strip box 21.

[0034] By adopting the above technical solution, the motor 32 drives the bidirectional screw 35 to rotate. The rotation of the bidirectional screw 35 drives the two moving seats 36 to move towards each other in the base box 31. The movement of the two moving seats 36 pushes the strip box 21 to rise and fall through the rotating rod 34. The rotating rod 34 slides in the rectangular groove 37 at the upper end of the base box 31. At the same time, the guide rod 33 slides on both sides at the upper end of the base box 31. The rise and fall of the strip box 21 pushes the base plate 1 to rise and fall. By setting the lifting component 3, the processing machinery installed on the slider 6 can be raised and lowered according to the needs, thereby improving the practicality of the device.

[0035] Specifically, the upper sides of the bottom box 31 are provided with sliding holes corresponding to the guide rod 33, and the rear end of the bottom box 31 is fixed with a maintenance plate by bolts.

[0036] By adopting the above technical solution, the guide rod 33 can slide on both sides of the upper end of the base box 31, and the inspection plate can be set to inspect and maintain the components inside the base box 31.

[0037] Specifically, the rotating rod 34 is rotatably connected to the strip box 21 and to the movable seat 36 via a pivot pin, and the two movable seats 36 are threaded to the bidirectional screw 35 in opposite directions.

[0038] By adopting the above technical solution, the rotating rod 34 can rotate between the strip box 21 and the movable seat 36, and the rotation of the bidirectional screw 35 can drive the two movable seats 36 to move towards each other.

[0039] In this embodiment, the motor 32 is turned on to drive the bidirectional screw 35 to rotate. The rotation of the bidirectional screw 35 causes the two movable seats 36 to move towards each other in the base box 31. The movement of the two movable seats 36 pushes the strip box 21 up and down through the rotating rod 34. The rotating rod 34 slides in the rectangular groove 37 at the upper end of the base box 31. At the same time, the guide rod 33 slides on both sides of the upper end of the base box 31. The rise and fall of the strip box 21 pushes the base plate 1 up and down. By setting the lifting component 3, the processing machinery installed on the slider 6 can be raised and lowered according to the needs, improving the practicality of the device.

[0040] In this utility model, the second motor 22 is a previously disclosed technology, and the selected model is 5IK120GN-CF.

[0041] In this utility model, the motor 32 is a previously disclosed technology, and the selected model is Z60-55ZY.

[0042] The structure and working principle of the base plate 1, dovetail block 4, bearing seat 5, slider 6, mounting hole 7, lead screw 8 and motor 9 in this utility model have been disclosed in a Y-axis module bracket that is easy to install, disclosed in Chinese patent application number 2022205712483.

[0043] The working principle and usage process of this utility model: When using the high-precision Y-axis module, the device is installed in a suitable position. The machining machine is installed and fixed onto the slider 6 through the mounting hole 7 on the slider 6. The motor 9 is turned on to drive the lead screw 8 to rotate. The rotation of the lead screw 8 can drive the slider 6 to move and adjust the machining machine on the slider 6 laterally. The motor 22 is turned on to drive the drive wheel 23 to rotate, which in turn drives the connecting belt 25 to rotate. The driven wheel 24 rotates in the strip box 21. The rotation of the connecting belt 25 drives the I-shaped block 26 to move in the slide groove 27 at the upper end of the strip box 21. The movement of the I-shaped block 26 drives the base plate 1 to move, thereby achieving the effect of longitudinal movement adjustment of the slider 6 and the machining machine. By setting the moving component 2, the longitudinal movement adjustment of the slider 6 and the machining machine installed on the slider 6 can be performed, improving the adjustment range. By setting the support component 28... When the substrate 1 moves, the slide 283 at one end of the connecting frame 284 on both sides of the lower end of the substrate 1 slides on the fixed rod 282. At the same time, a support column 285 is set between the slide 283 and the substrate 1 to make the substrate 1 and the slide 283 more stable. By setting the support component 28, the movement of the substrate 1 can be supported, improving the stability of the movement of the substrate 1. The motor 32 is turned on to drive the bidirectional screw 35 to rotate. The rotation of the bidirectional screw 35 drives the two moving seats 36 to move towards each other in the bottom box 31. The movement of the two moving seats 36 pushes the strip box 21 to rise and fall through the rotating rod 34. The rotating rod 34 slides in the rectangular groove 37 at the upper end of the bottom box 31. At the same time, the guide rod 33 slides on both sides at the upper end of the bottom box 31. The rise and fall of the strip box 21 pushes the substrate 1 to rise and fall. By setting the lifting component 3, the processing machinery installed on the slider 6 can be raised and lowered according to the needs, improving the practicality of the device.

[0044] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A high-precision Y-axis module, comprising a substrate (1), characterized in that: A dovetail block (4) is fixed at the upper end of the substrate (1), and bearing seats (5) are fixed on both sides of the upper end of the dovetail block (4). A motor (9) is installed at one end of one bearing seat (5), and a lead screw (8) is provided at the output end of the motor (9). A slider (6) is threaded on the surface of the lead screw (8), and several mounting holes (7) are opened at the upper end of the slider (6). A moving component (2) is provided at the lower end of the substrate (1). The moving component (2) includes a strip box (21). The strip box (21) is provided on the lower side of the base plate (1). A second motor (22) is installed on one side of the front end of the strip box (21). A drive wheel (23) is provided at the output end of the second motor (22). A driven wheel (24) is rotatably connected inside the strip box (21) on the side away from the drive wheel (23). A connecting belt (25) is provided between the driven wheel (24) and the drive wheel (23). I-shaped blocks (26) are fixed on both sides of the upper end of the connecting belt (25). A sliding groove (27) corresponding to the I-shaped block (26) is opened at the upper end of the strip box (21). A lifting component (3) is provided at the lower end of the strip box (21). A support component (28) is provided between the base plate (1) and the strip box (21).

2. The high-precision Y-axis module according to claim 1, characterized in that: The support assembly (28) includes a side plate (281). Two side plates (281) are fixed at both ends of the strip box (21). A fixing rod (282) is fixed between the two side plates (281). A slide block (283) is slidably connected to the fixing rod (282). A connecting frame (284) is fixed between the slide block (283) and the base plate (1). A support column (285) is fixed between the upper end of the slide block (283) and the base plate (1).

3. A high-precision Y-axis module according to claim 2, characterized in that: The I-shaped block (26) and the base plate (1) and the side plate (281) and the strip box (21) are all spot welded together, and the drive wheel (23) and the driven wheel (24) are all rotatably connected to the strip box (21).

4. A high-precision Y-axis module according to claim 2, characterized in that: The side of the I-shaped block (26) is in close contact with the inner wall of the slide groove (27), and the slide seat (283) has a sliding hole corresponding to the fixed rod (282). The connecting frame (284) and the slide seat (283) are welded as a whole.

5. A high-precision Y-axis module according to claim 1, characterized in that: The lifting assembly (3) includes a lifting assembly (3), a base box (31) is provided on the lower side of the strip box (21), a motor (32) is installed on the lower side of one end of the base box (31), a bidirectional screw (35) is provided at the output end of the motor (32), a movable seat (36) is threaded on both sides of the surface of the bidirectional screw (35), the movable seat (36) is connected to the strip box (21) through a rotating rod (34), a rectangular groove (37) corresponding to the rotating rod (34) is opened at the upper end of the base box (31), and guide rods (33) are fixed on both sides of the lower end of the strip box (21).

6. A high-precision Y-axis module according to claim 5, characterized in that: The bottom box (31) has sliding holes on both sides of its upper end that correspond to the guide rod (33), and the rear end of the bottom box (31) is fixed with a maintenance plate by bolts.

7. A high-precision Y-axis module according to claim 5, characterized in that: The rotating rod (34) and the strip box (21) are rotatably connected by a pivot pin, and the two moving seats (36) are threaded to the bidirectional screw (35) in opposite directions.