CN111716088A - Automatic module for overturning alignment - Google Patents

Abstract

The invention relates to the technical field of transfer equipment, and particularly discloses an automatic module for overturning alignment, which comprises: the suction head assembly is used for sucking a workpiece to be assembled; the driving end of the first rotating motor is connected with the sucker assembly and is used for driving the sucker assembly to rotate around the axis of the sucker assembly; the driving end of the second rotating motor is connected with the sucker assembly and is used for driving the sucker assembly to rotate around a horizontal axis; the horizontal axis is perpendicular to the axis of the sucker head assembly; and the up-down translation assembly is connected with the suction head assembly and is used for driving the suction head to move up and down. The invention provides an automatic module for overturning alignment, which can rotate a workpiece to be assembled so as to improve the flexibility during assembly.

Description

Automatic module for overturning alignment

Technical Field

The invention relates to the technical field of transfer equipment, in particular to an automatic module for overturning alignment.

Background

For example, referring to fig. 1, if it is required to complete the assembly of the body component 101 and the workpiece 102 to be assembled, the body component 101 needs to be fixed, and then the workpiece 102 to be assembled is clamped by the alignment module and the workpiece 102 to be assembled is placed on the body component 101 from top to bottom. Because the existing alignment modules can only perform translation but cannot rotate, when the operation space right above the main body part 101 is insufficient, for example, referring to fig. 2, if other mechanisms 2 are arranged above the main body part 101, the other mechanisms 2 may interfere with the vertical and downward movement path of the workpiece 102 to be assembled, and the existing alignment modules cannot achieve automatic alignment and assembly of the main body part 101 and the workpiece 102 to be assembled.

Therefore, the existing alignment module needs to be improved to solve the problems that the existing alignment module can only translate the workpiece to be assembled and has low flexibility.

Disclosure of Invention

One object of the present invention is to provide an automatic module for flip alignment, which can rotate a workpiece to be assembled to improve the flexibility of assembly.

To achieve the above object, the present invention provides an automatic module for flipping alignment, comprising:

the suction head assembly is used for sucking a workpiece to be assembled;

the driving end of the first rotating motor is connected with the sucker assembly and is used for driving the sucker assembly to rotate around the axis of the sucker assembly;

the driving end of the second rotating motor is connected with the sucker assembly and is used for driving the sucker assembly to rotate around a horizontal axis; the horizontal axis is perpendicular to the axis of the sucker head assembly;

and the up-down translation assembly is connected with the suction head assembly and is used for driving the suction head to move up and down.

Preferably, the method further comprises the following steps:

the main belt wheel is fixedly connected with the driving end of the first rotating motor and is coaxial;

the secondary belt wheel is fixedly connected with the sucker assembly and is coaxial;

and the main belt wheel is in transmission connection with the auxiliary belt wheel through the belt.

Preferably, the method further comprises the following steps:

the first photoelectric sensor is positioned on the side surface of the main belt wheel and is fixedly arranged relative to the shell of the first rotating motor; the first photosensor is electrically connected with the first rotating motor;

the first light barrier is fixed at the edge of the main belt wheel and used for shielding the first photoelectric sensor when rotating along with the main belt wheel so as to enable the first photoelectric sensor to generate an electric signal.

Preferably, the method further comprises the following steps:

and one end of the connecting plate is rotatably connected with the suction head assembly through a bearing, and the other end of the connecting plate is fixedly connected with the shell of the first rotating motor.

Preferably, the method further comprises the following steps:

and one side of the rotating plate is fixedly connected with a driving shaft of the second rotating motor, and the other side of the rotating plate is fixedly connected with the connecting plate.

Preferably, the method further comprises the following steps:

the angle graduated scale is fixedly arranged relative to the shell of the second rotating motor and is coaxial with the rotating plate;

the pointer is opposite to the angle graduated scale, fixedly connected with the rotating plate and used for indicating the rotating angle of the rotating plate on the angle graduated scale.

Preferably, the method further comprises the following steps:

the second photoelectric sensor is positioned on the side surface of the rotating plate and is fixedly arranged relative to the shell of the second rotating motor; the second photoelectric sensor is electrically connected with the second rotating motor;

the second light blocking sheet is fixed at the edge position of the rotating plate and used for blocking the second photoelectric sensor when rotating along with the rotating plate so as to enable the second photoelectric sensor to generate an electric signal.

Preferably, the up-down translation assembly includes:

the bottom plate is vertically arranged;

the Z-axis screw rod extends along the vertical Z-axis direction;

the Z-axis sliding plate is connected with the bottom plate in a sliding mode along the Z-axis direction, and the middle of the Z-axis screw rod is in threaded connection with the Z-axis sliding plate;

and the shell of the Z-axis motor is fixedly connected with the bottom plate, and the driving end of the Z-axis motor is fixedly connected with one end of the Z-axis screw rod.

Preferably, still be equipped with the left and right sides translation subassembly between upper and lower translation subassembly and the suction head subassembly, the left and right sides translation subassembly includes:

the X-axis screw rod extends along the horizontal X-axis direction;

the X-axis sliding plate is connected with the Z-axis sliding plate in a sliding mode along the X-axis direction, and the middle of the X-axis screw rod is in threaded connection with the X-axis sliding plate;

and the shell of the X-axis motor is fixedly connected with the Z-axis sliding plate, and the driving end of the X-axis motor is fixedly connected with one end of the X-axis screw rod.

Preferably, still be equipped with the front and back translation subassembly between left and right translation subassembly and the suction head subassembly, the front and back translation subassembly includes:

the Y-axis screw rod extends along the horizontal Y-axis direction, and the X-axis direction is vertical to the Y-axis direction;

the Y-axis sliding plate is connected with the X-axis sliding plate in a sliding mode along the Y-axis direction, and the middle of the Y-axis screw rod is in threaded connection with the Y-axis sliding plate; the second rotating motor is fixedly connected with the Y-axis sliding plate;

and a shell of the Y-axis motor is fixedly connected with the X-axis sliding plate, and a driving end of the Y-axis motor is fixedly connected with one end of the Y-axis screw rod.

The invention has the beneficial effects that: the utility model provides an automatic module for upset counterpoint, after the suction head subassembly is inhaled and is waited to assemble the work piece, when the translation subassembly drives suction head subassembly down motion from top to bottom, if wait to assemble the work piece and meet the blockking of other mechanisms, first rotation motor and second rotation motor work just can change waiting to assemble the self gesture and the position etc. of work piece to accomplish the counterpoint equipment between main part and the work piece of waiting to assemble under the circumstances of not moving other mechanisms, thereby reduce the requirement to operating space when counterpointing the equipment.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a schematic diagram illustrating alignment and assembly of a main body component and a workpiece to be assembled according to the background art;

FIG. 2 is a schematic diagram of a position of a workpiece to be assembled, which is provided by the background art and blocked by other mechanisms;

FIG. 3 is a schematic diagram illustrating an exemplary embodiment of an automated assembly for flip alignment;

fig. 4 is a schematic structural view of a first rotating electric machine and a second rotating electric machine according to an embodiment;

FIG. 5 is a schematic diagram illustrating a position of a workpiece to be assembled blocked by a slit according to an embodiment;

FIG. 6 is a schematic view of a workpiece to be assembled rotated by 90 degrees in the forward direction by a first rotating motor according to an embodiment;

FIG. 7 is a schematic view illustrating a workpiece to be assembled rotated forward by a certain angle by a second rotating motor according to an embodiment;

FIG. 8 is a schematic structural diagram of a first light barrier according to an embodiment;

FIG. 9 is a schematic structural diagram of an up-down translation assembly according to an exemplary embodiment;

FIG. 10 is a schematic structural diagram of a left-right translation assembly and a front-back translation assembly according to an embodiment.

In the figure:

101. a main body member; 102. a workpiece to be assembled;

2. other mechanisms; 201. a long and narrow through slot;

3. a suction head assembly;

401. a first rotating electric machine; 402. a primary pulley; 403. a secondary pulley; 404. a belt; 405. a first photosensor; 406. a first light-blocking sheet;

501. a second rotating electric machine; 502. a connecting plate; 503. a rotating plate; 504. an angle scale; 505. a pointer; 506. a second photosensor; 507. a second light blocking sheet;

6. an up-down translation assembly; 601. a base plate; 602. a Z-axis lead screw; 603. a Z-axis slide plate; 604. a Z-axis motor;

7. a left-right translation assembly; 701. an X-axis lead screw; 702. an X-axis slide plate; 703. an X-axis motor;

8. a front-to-back translation assembly; 801. a Y-axis lead screw; 802. a Y-axis slide plate; 803. and a Y-axis motor.

Detailed Description

In order to make the objects, features and advantages of the present invention more obvious and understandable, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the embodiments described below are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that 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. When a component is referred to as being "disposed on" another component, it can be directly on the other component or intervening components may also be present.

Furthermore, the terms "long", "short", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of describing the present invention, but do not indicate or imply that the referred devices or elements must have the specific orientations, be configured to operate in the specific orientations, and thus are not to be construed as limitations of the present invention.

The technical scheme of the invention is further explained by the specific implementation mode in combination with the attached drawings.

Referring to fig. 3 to 4, the present embodiment provides an automatic module for flipping and aligning, which includes a suction head assembly 3, a first rotating motor 401, a second rotating motor 501, and an up-down translation assembly 6. The suction head assembly 3 is used for sucking a workpiece 102 to be assembled. The driving end of the first rotating motor 401 is connected to the tip assembly 3 for driving the tip assembly 3 to rotate about the axis of the tip assembly 3. The driving end of the second rotating motor 501 is connected with the suction head assembly 3 and is used for driving the suction head assembly 3 to rotate around a horizontal axis; the horizontal axis is perpendicular to the axis of the tip assembly 3. The up-down translation assembly 6 is connected with the suction head assembly 3 and used for driving the suction head to move up and down.

Preferably, the horizontal axis is the axis of the drive shaft of the second rotating motor 501.

It can be understood that the first rotating motor 401 can drive the workpiece 102 to be assembled to rotate around its own axis, so as to change its own posture, which is beneficial for passing through some narrow places. For example, referring to fig. 5, initially, the workpiece 102 to be assembled is too long to pass through the long and narrow through slot 201 of the other mechanism 2, referring to fig. 6, the first rotating motor 401 drives the workpiece 102 to be assembled to rotate by 90 ° in the forward direction, the long side and the short side of the workpiece 102 to be assembled are subjected to position conversion, the up-down translation assembly 6 continues to push the suction head assembly 3 downward, the workpiece 102 to be assembled can pass through the long and narrow through slot 201, after the workpiece 102 to be assembled passes through the long and narrow through slot 201, the first rotating motor 401 drives the workpiece 102 to be assembled to rotate by 90 ° in the reverse direction, the long side and the short side of the workpiece 102 to be assembled are subjected to position conversion again, and the up-down translation assembly 6 continues to push the suction head assembly 3.

Further, the second rotating motor 501 can drive the workpiece 102 to be assembled to rotate around the horizontal axis, so as to change the position of the workpiece, and thus, the workpiece can be beneficial to bypassing obstacles. For example, referring to fig. 5, initially, the workpiece 102 to be assembled is oversized and cannot reach above the body member 101 bypassing the other mechanism 2; referring to fig. 7, the second rotating motor 501 drives the workpiece 102 to be assembled to rotate forward by a certain angle, the workpiece 102 to be assembled rotates to the side of another mechanism 2, and the up-down translation assembly 6 continues to push the suction head assembly 3 downward; then the second rotating motor 501 drives the workpiece 102 to be assembled to rotate reversely by a certain angle, the workpiece 102 to be assembled can reach the upper part of the main body part 101 by bypassing other mechanisms 2, and the up-down translation assembly 6 continues to push the suction head assembly 3 downwards, so that the main body part 101 and the workpiece 102 to be assembled can be aligned and assembled.

According to the automatic module provided by the embodiment, after the suction head assembly 3 sucks the workpiece 102 to be assembled, when the up-down translation assembly 6 drives the suction head assembly 3 to move downwards, if the workpiece 102 to be assembled is blocked by other mechanisms 2, the first rotating motor 401 and the second rotating motor 501 work, the posture, the position and the like of the workpiece 102 to be assembled can be changed, so that the alignment assembly between the main body component 101 and the workpiece 102 to be assembled can be conveniently completed without moving other mechanisms 2, the flexibility in assembly is improved, and the requirement on an operation space in the alignment assembly is reduced.

Referring to fig. 8, the automated module for reverse registration further includes a primary pulley 402, a secondary pulley 403, and a belt 404. The primary pulley 402 is fixed to and coaxial with the drive end of the first rotating motor 401. The secondary pulley 403 is fixed to and coaxial with the nozzle assembly 3. The primary pulley 402 is in driving connection with the secondary pulley 403 via the belt 404.

In this embodiment, when the first rotating motor 401 is started, the suction head assembly 3 is driven to rotate around its own axis by the primary pulley 402, the belt 404 and the secondary pulley 403 in sequence. In some other embodiments, the first rotating motor 401 can drive the suction head assembly 3 to rotate through a gear set or other transmission mechanism such as a sprocket.

Further, the automation module for flip alignment further includes a first photo sensor 405 and a first light barrier 406. The first photoelectric sensor 405 is located on the side of the primary pulley 402 and is fixed to the housing of the first rotating motor 401; the first photosensor 405 is electrically connected to the first rotating motor 401. The first light blocking piece 406 is fixed at an edge position of the primary pulley 402, and is used for blocking the first photosensor 405 when rotating with the primary pulley 402 to cause the first photosensor 405 to generate an electrical signal.

It can be understood that, when the first rotating motor 401 drives the main pulley 402 to rotate, the first light blocking sheet 406 rotates along with the main pulley 402, and if the first light blocking sheet 406 rotates to a position capable of blocking the light beam emitted by the first photoelectric sensor 405, the position is determined as the initial position of the main pulley 402, so that the initial position of the suction head assembly 3 when rotating around the axis of the suction head assembly is determined, and it is beneficial for the following first rotating motor 401 to determine the rotation angle of the suction head assembly 3 around the axis of the suction head assembly through the number of rotations of the driving end. Thus, the first photosensor 405 and the first flag 406 are primarily used to effect repositioning of the tip assembly 3 about its axis.

Preferably, the automation module further comprises a connection plate 502 and a rotation plate 503. One end of the connecting plate 502 is rotatably connected to the suction head assembly 3 through a bearing, and the other end is fixedly connected to the housing of the first rotating motor 401. One side of the rotating plate 503 is fixedly connected to a driving shaft of the second rotating motor 501, and the other side is fixedly connected to the connecting plate 502.

It will be appreciated that when the second rotary motor 501 is activated, the rotary plate 503 is rotated about the horizontal rotary shaft, so that the nozzle assembly 3 mounted on the connecting plate 502 is rotated about the horizontal rotary shaft, thereby achieving the position adjustment of the workpiece 102 to be assembled.

The automation module also includes an angle scale 504 and a pointer 505. The angle scale 504 is fixed to the housing of the second rotating motor 501 and is coaxial with the rotating plate 503. The pointer 505 is opposite to the angle scale 504 and is fixedly connected to the rotating plate 503, and is used for indicating the rotation angle of the rotating plate 503 on the angle scale 504.

Specifically, when the rotation plate 503 is rotated, the pointer 505 rotates with the rotation plate 503, thereby indicating the angle by which the rotation plate 503 is rotated on the angle scale 504.

Further, the automation module further includes a second photosensor 506 and a second light barrier 507. The second photoelectric sensor 506 is located on the side of the rotating plate 503 and is fixed to the housing of the second rotating motor 501; the second photosensor 506 is electrically connected to the second rotating electric machine 501. The second light blocking sheet 507 is fixed at an edge of the rotating plate 503 and is configured to block the second photosensor 506 when the rotating plate 503 rotates, so as to enable the second photosensor 506 to generate an electrical signal.

It can be understood that, when the second rotating motor 501 drives the rotating plate 503 to rotate, the second light blocking sheet 507 rotates along with the rotating plate 503, and if the second light blocking sheet 507 rotates to a position where it can block the light beam emitted by the second photoelectric sensor 506, it is determined as the initial position of the rotating plate 503, so as to determine the initial position of the suction head assembly 3 when rotating around the horizontal axis, which is beneficial for the subsequent second rotating motor 501 to determine the rotation angle of the suction head assembly 3 around the horizontal axis through the number of rotations of the driving end. Therefore, the second photoelectric sensor 506 and the second light blocking sheet 507 are mainly used for resetting the suction head assembly 3 relative to the horizontal rotating shaft.

Referring to fig. 9, the up-down translation assembly 6 includes a base plate 601, a Z-axis lead screw 602, a Z-axis slide 603, and a Z-axis motor 604. The bottom plate 601 is vertically disposed. The Z-axis wire 602 extends in a vertical Z-axis direction. The Z-axis sliding plate 603 is slidably connected to the base plate 601 along the Z-axis direction, and the middle of the Z-axis lead screw 602 is in threaded connection with the Z-axis sliding plate 603. The shell of the Z-axis motor 604 is fixedly connected to the bottom plate 601, and the driving end is fixedly connected to one end of the Z-axis screw 602.

It will be appreciated that when the Z-axis motor 604 is activated, the Z-axis lead screw 602 rotates, thereby moving the Z-axis slide 603 up and down, and thus moving the suction head assembly 3 up and down with the workpiece 102 to be assembled.

Referring to fig. 10, a left-right translation assembly 7 is further disposed between the up-down translation assembly 6 and the suction head assembly 3, and the left-right translation assembly 7 includes an X-axis lead screw 701, an X-axis sliding plate 702, and an X-axis motor 703. The X-axis wire 701 extends in the horizontal X-axis direction. The X-axis sliding plate 702 is connected with the Z-axis sliding plate 603 in a sliding manner along the X-axis direction, and the middle part of the X-axis lead screw 701 is connected with the X-axis sliding plate 702 in a threaded manner. The shell of the X-axis motor 703 is fixedly connected with the Z-axis slide plate 603, and the driving end is fixedly connected with one end of the X-axis lead screw 701.

It can be understood that when the X-axis motor 703 is started, the X-axis lead screw 701 rotates, so that the X-axis sliding plate 702 moves left and right, and the suction head assembly 3 drives the workpiece 102 to be assembled to move left and right.

And a front-rear translation assembly 8 is further arranged between the left-right translation assembly 7 and the suction head assembly 3, and the front-rear translation assembly 8 comprises a Y-axis lead screw 801, a Y-axis sliding plate 802 and a Y-axis motor 803. The Y-axis wire rods 801 extend in a horizontal Y-axis direction, and the X-axis direction is perpendicular to the Y-axis direction. The Y-axis sliding plate 802 is connected with the X-axis sliding plate 702 in a sliding manner along the Y-axis direction, and the middle part of the Y-axis lead screw 801 is connected with the Y-axis sliding plate 802 in a threaded manner; the second rotating motor 501 is fixedly connected with the Y-axis sliding plate 802. The shell of the Y-axis motor 803 is fixedly connected to the X-axis sliding plate 702, and the driving end is fixedly connected to one end of the Y-axis screw 801.

It will be appreciated that when the Y-axis motor 803 is activated, the Y-axis lead screw 801 rotates, thereby moving the Y-axis slide 802 back and forth, and thus the suction head assembly 3, which in turn moves the workpiece 102 to be assembled back and forth. Particularly, the position adjusting range of the suction head assembly 3 can be further enlarged by arranging the left and right translation assembly 7 and the front and rear translation assembly 8, and the adjusting capacity of the automatic module is enhanced.

The automatic alignment module that this embodiment provided has advantages such as positioning accuracy height and motion flexibility, is suitable for the adjustment counterpoint process of the narrow product spare part in complex construction or station space.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (10)

1. An automated assembly for flip alignment, comprising:

the suction head assembly is used for sucking a workpiece to be assembled;

the driving end of the first rotating motor is connected with the sucker assembly and is used for driving the sucker assembly to rotate around the axis of the sucker assembly;

the driving end of the second rotating motor is connected with the sucker assembly and is used for driving the sucker assembly to rotate around a horizontal axis; the horizontal axis is perpendicular to the axis of the sucker head assembly;

and the up-down translation assembly is connected with the suction head assembly and is used for driving the suction head to move up and down.

2. The automated module for flip alignment of claim 1, further comprising:

the main belt wheel is fixedly connected with the driving end of the first rotating motor and is coaxial;

the secondary belt wheel is fixedly connected with the sucker assembly and is coaxial;

and the main belt wheel is in transmission connection with the auxiliary belt wheel through the belt.

3. The automated module for flip alignment of claim 2, further comprising:

the first photoelectric sensor is positioned on the side surface of the main belt wheel and is fixedly arranged relative to the shell of the first rotating motor; the first photosensor is electrically connected with the first rotating motor;

the first light barrier is fixed at the edge of the main belt wheel and used for shielding the first photoelectric sensor when rotating along with the main belt wheel so as to enable the first photoelectric sensor to generate an electric signal.

4. The automated module for flip alignment of claim 1, further comprising:

and one end of the connecting plate is rotatably connected with the suction head assembly through a bearing, and the other end of the connecting plate is fixedly connected with the shell of the first rotating motor.

5. The automated module for flip alignment of claim 4, further comprising:

and one side of the rotating plate is fixedly connected with a driving shaft of the second rotating motor, and the other side of the rotating plate is fixedly connected with the connecting plate.

6. The automated module for flip alignment of claim 5, further comprising:

the angle graduated scale is fixedly arranged relative to the shell of the second rotating motor and is coaxial with the rotating plate;

the pointer is opposite to the angle graduated scale, fixedly connected with the rotating plate and used for indicating the rotating angle of the rotating plate on the angle graduated scale.

7. The automated module for flip alignment of claim 5, further comprising:

the second photoelectric sensor is positioned on the side surface of the rotating plate and is fixedly arranged relative to the shell of the second rotating motor; the second photoelectric sensor is electrically connected with the second rotating motor;

the second light blocking sheet is fixed at the edge position of the rotating plate and used for blocking the second photoelectric sensor when rotating along with the rotating plate so as to enable the second photoelectric sensor to generate an electric signal.

8. The automated module for reverse alignment of claim 1, wherein the up-down translation assembly comprises:

the bottom plate is vertically arranged;

the Z-axis screw rod extends along the vertical Z-axis direction;

the Z-axis sliding plate is connected with the bottom plate in a sliding mode along the Z-axis direction, and the middle of the Z-axis screw rod is in threaded connection with the Z-axis sliding plate;

and the shell of the Z-axis motor is fixedly connected with the bottom plate, and the driving end of the Z-axis motor is fixedly connected with one end of the Z-axis screw rod.

9. The automated module for reverse alignment of claim 8, wherein a left-right translation assembly is further disposed between the up-down translation assembly and the suction head assembly, and the left-right translation assembly comprises:

the X-axis screw rod extends along the horizontal X-axis direction;

the X-axis sliding plate is connected with the Z-axis sliding plate in a sliding mode along the X-axis direction, and the middle of the X-axis screw rod is in threaded connection with the X-axis sliding plate;

and the shell of the X-axis motor is fixedly connected with the Z-axis sliding plate, and the driving end of the X-axis motor is fixedly connected with one end of the X-axis screw rod.

10. The automated module for reverse alignment of claim 9, further comprising a front-to-back translation assembly disposed between the left-to-right translation assembly and the suction head assembly, the front-to-back translation assembly comprising:

the Y-axis screw rod extends along the horizontal Y-axis direction, and the X-axis direction is vertical to the Y-axis direction;

the Y-axis sliding plate is connected with the X-axis sliding plate in a sliding mode along the Y-axis direction, and the middle of the Y-axis screw rod is in threaded connection with the Y-axis sliding plate; the second rotating motor is fixedly connected with the Y-axis sliding plate;

and a shell of the Y-axis motor is fixedly connected with the X-axis sliding plate, and a driving end of the Y-axis motor is fixedly connected with one end of the Y-axis screw rod.

Images