CN114136984A - Multifunctional detection platform for cutter and use method - Google Patents

Abstract

The invention proposes a multifunctional detection platform for cutting tools and a method for using it, comprising: a workbench, a drill pin grabbing device, a detection base, a numerical control module and a visual camera system. The three axes of 、Z move upward to continuously complete the grabbing, installation and recovery of the drill bit; the detection base is provided with a servo rotating seat and a position adjustment device, which can clamp the drill needle and drive the drill bit in the horizontal direction under the drive of the position adjustment device. It moves in two vertical directions, and completes the drill pin clamping, detection and recovery continuously; the servo rotating base can be rotated under the drive of the motor, and cooperates with multiple sets of vision camera systems to comprehensively detect the drill pin's machining accuracy index. The automatic operation of tool detection is realized, the detection efficiency of the tool is greatly improved, and the detection error of the tool is reduced.

Description

Multifunctional detection platform for cutter and use method

Technical Field

The invention belongs to the technical field of cutter detection, and particularly relates to a multifunctional detection platform of a cutter and a using method thereof.

Background

The PCB is an important electronic component, and a PCB cutter is required to be used for cutting, punching and the like on the PCB in the processing process, so that the requirement on the processing precision of the cutter is high, and in order to ensure that the processing precision of the cutter can meet the requirement of a user, whether the cutter is ground to a preset blade angle and geometric shape, the cutter width, ligament width, appearance quality and the like must be detected one by one after the cutter is processed, so that the quality of the cutter is ensured. At present the image that generally adopts perpendicular setting in the cutter trade detects machine (CCD) to the cutter that makes, adopts manual operation's mode, gets one by one and puts cutter and detect to image detection machine department, also puts the not different position with the cutter through manual operation simultaneously and carries out diversified detection, and efficiency is very low, and because it is very big to put the position inaccurate can lead to detecting error.

In view of this, it is important to design and manufacture a fully automated multifunctional tool detection platform that can overcome the above problems, is convenient to operate, and improves the tool detection efficiency.

Disclosure of Invention

In order to solve the problems of low automation degree, low detection efficiency, large error and the like of the existing cutter detection equipment, the application provides a multifunctional detection platform for cutters, so as to solve the defects existing in the prior art.

The invention provides a multifunctional detection platform of a cutter, which is provided with a workbench, wherein the workbench is provided with an L-shaped groove, and the multifunctional detection platform further comprises:

the drill point gripping device comprises a base, a moving platform and at least one group of gripping manipulators, wherein the moving platform is fixedly arranged on the base and comprises a first moving assembly, a second moving assembly and a third moving assembly, the second moving assembly is movably connected with the first moving assembly and moves along the axial direction of the first moving assembly, the third moving assembly is movably connected with the second moving assembly and moves along the axial direction of the second moving assembly, and the gripping manipulators are movably connected with the third moving assembly and move along the axial direction of the third moving assembly; the moving platform is provided with a driving device to control the axial movement of the moving platform; the base is fixedly arranged on the upper part of the workbench;

the detection base comprises a servo rotating base and a position adjusting device, the servo rotating base is provided with a drill point clamping assembly and a motor, a shaft of the motor is connected with the drill point clamping assembly to control the drill point clamping assembly to rotate, and the drill point clamping assembly is provided with a clamping device to fix a drill point to be detected; the position adjusting device is provided with a horizontal sliding assembly and a vertical sliding assembly, and the servo rotating seat is movably connected with the position adjusting device so as to control the horizontal movement or the vertical movement of the servo rotating seat; the detection base is arranged at the lower part of the workbench, and the drill point clamping assembly extends out of the upper part of the workbench and can move along the L-shaped groove;

the numerical control module is electrically connected with the drill point gripping device and the detection base and is used for controlling and integrating actions of the drill point gripping device and the detection base so as to execute detection operation;

the visual camera system is arranged at the upper part of the workbench and comprises at least one optical camera, and the measuring axis of the optical camera is parallel or vertical to the central axis of the drill point to be detected so as to detect the drill point to be detected; the vision camera system is fixedly arranged on the upper part of the workbench.

The manipulator is controlled by the moving platform to freely move in three directions of XYZ axes, so that the manipulator can automatically grab the drill point to be tested from the material tray and move to a clamping station; controlling the drill point clamping assembly to move in the XY axis directions through the position adjusting device, and sequentially completing the process steps of drill point installation, drill point detection and drill point recovery between the clamping station and the detection station; the drill point clamping assembly can rotate through the servo rotating seat, and detection operation in each direction is automatically completed; the action between the devices is controlled and integrated by the numerical control module, so that the detection operation of the cutter is more convenient, the detection efficiency of the cutter is improved, and the full-automatic detection of the cutter is realized.

Preferably, the vision camera system further comprises a communication module, and the communication module is communicated with the tool machining equipment so that the tool machining equipment can compensate and correct machining amount according to the detection data. By adding the communication module, the processing equipment is further produced intelligently, and the production quality of products is improved.

Further preferably, the vision camera system comprises a camera with a measuring axis parallel to the central axis of the drill point to be measured, and three cameras with measuring axes perpendicular to the central axis of the drill point to be measured. The detection of the whole key size of the cutter can be completed at one time by the cooperation of a plurality of cameras, so that the detection efficiency is improved.

Preferably, the drill point gripping device is provided with two gripping manipulators which are respectively used for gripping the drill point to be detected to the drill point clamping assembly and gripping the detected drill point to the material tray. The two manipulators respectively complete different instructions, and the working efficiency is improved.

Preferably, the first moving assembly comprises an X-axis slide rail, an X-axis slide block, a press plate and a driving structure, the X-axis slide rail is fixedly arranged on the base, the X-axis slide block is arranged on the inner side of the X-axis slide rail, a slide rail cover plate is further arranged at the upper end of the X-axis slide rail, and the press plate is fixedly connected with the X-axis slide block and is connected to the slide rail cover plate in a nested manner; the driving mechanism comprises a driving motor arranged at one end of the X axial sliding rail, and the driving motor drives the X axial sliding block to axially move along the X axial sliding rail. This structure allows the robot arm to move in the X-axis direction.

Preferably, one end of the second moving assembly is fixedly connected with the pressing plate through a connecting plate arranged on the pressing plate, the other end of the second moving assembly is of a cantilever structure, a Z-axis sliding rail and a Z-axis sliding block are arranged on one side, facing the vision camera system, of the cantilever structure, and a driving motor is arranged at one end, far away from the cantilever, of the second moving assembly to control the Z-axis sliding block to move axially along the Z-axis sliding rail. This structure allows the robot arm to move in the Z-axis direction.

Preferably, the third moving assembly is fixedly connected with the Z-axis sliding block and comprises a connecting base, two Y-axis sliding rails, two Y-axis sliding blocks and two pull rod type cylinders, the Y-axis sliding rails are fixedly arranged on the connecting base, the Y-axis sliding blocks are movably connected with the Y-axis sliding rails, one end of each pull rod type cylinder is fixedly connected to the connecting base, and the other end of each pull rod type cylinder is fixedly connected to the Y-axis sliding block so as to control the Y-axis sliding blocks to move axially along the Y-axis sliding rails; the grabbing manipulator is fixedly arranged on the Y-axis sliding block. This structure allows the robot arm to move in the Y-axis direction.

Preferably, the position adjusting device further comprises an L-shaped connecting portion, the horizontal sliding assembly is arranged on a horizontal arm of the L-shaped connecting portion, the horizontal sliding assembly comprises a horizontal sliding table pair and a pull rod type cylinder, a sliding rail of the horizontal sliding table pair is fixedly arranged on the lower portion of the workbench, and a sliding block of the horizontal sliding table pair is fixedly arranged on the horizontal arm of the L-shaped connecting portion; one end of the pull rod type cylinder is fixedly connected with the sliding block of the horizontal sliding table pair, and the other end of the pull rod type cylinder is fixedly arranged at the lower part of the workbench so as to control the horizontal movement of the position adjusting device; the vertical sliding assembly is arranged on a vertical arm of the L-shaped connecting part and comprises a first vertical sliding assembly, a second vertical sliding assembly and a driving motor, the first vertical sliding assembly is arranged on the side surface, deviating from the horizontal arm, of the vertical arm, and the second vertical sliding assembly is arranged on the side surface, perpendicular to the horizontal arm, of the vertical arm; the first vertical sliding assembly comprises a vertical sliding table pair, a sliding rail of the vertical sliding table pair is arranged on the side surface deviating from the horizontal arm, and a sliding block of the vertical sliding table pair is movably connected with the sliding rail and the second vertical sliding assembly respectively; an output shaft of the driving motor is connected with a sliding block of the vertical sliding table pair so as to control the vertical movement of the position adjusting device; and the sliding block of the vertical sliding table pair is fixedly connected with the servo rotating seat. The structure enables the servo rotary seat to clamp the drill point to move in the horizontal and vertical directions.

Preferably, the camera with the measuring axis parallel to the central axis of the drill point to be measured is further provided with a vertical lifting device so as to adjust the vertical measuring position of the camera. The camera position is adjustable, is convenient for align measuring tool, makes to measure more accurately.

The invention also provides a using method of the multifunctional detection platform of the cutter, which comprises the following steps:

(1) the drill point is clamped and positioned: adjusting the relative position of the central axis of the drill point detection base and the axis of the camera vision system and the relative position of the drill point detection base and the drill point gripping device, inputting the adjusted X, Y, Z coordinate point and the transverse moving distance of the drill point to a processing limit point to complete setting, returning to a main interface, resetting, and starting detection operation according to starting;

(2) the servo rotating seat moves to a drill point clamping station: the servo rotary seat extends out of the upper surface of the working platform and moves to a drill point clamping station along the transverse position of the L-shaped clamping groove by controlling an X-axis sliding table and a Y-axis sliding table of the detection base;

(3) grabbing and fixing a drill point: the manipulator of the drill point gripping device moves to a material tray to be measured through the moving platform to grip a drill point to be measured, moves to a drill point clamping station, loads the drill point to be measured into the drill point clamping assembly, and fixes the drill point through the clamping device;

(4) detecting a drill point: detecting the drill point through a vision camera system;

(5) and (3) classifying and recycling the detected drill pins: after detection is finished, the servo rotary seat moves to a drill point clamping station, the clamping device loosens the drill point, and the manipulator moves to the position above the drill point to grab the drill point and moves to a corresponding recovery tray.

Compared with the prior art, the beneficial effect of this application lies in:

the drill point gripping device can drive the manipulator to move in X, Y, Z three axial directions respectively, and the gripping, the installation and the recovery of the drill point are continuously completed; the servo rotary seat can clamp the drill point and respectively move in the horizontal direction and the vertical direction under the driving of the position adjusting device, and the clamping, the detection and the recovery of the drill point are continuously completed; the servo rotary seat can rotate under the drive of the motor and is matched with a plurality of groups of vision camera systems to comprehensively detect the machining precision index of the drill point. The automatic operation of cutter detection is realized, the detection efficiency of the cutter is greatly improved, and the detection error of the cutter is reduced.

Drawings

The accompanying drawings are included to provide a further understanding of the embodiments and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments and together with the description serve to explain the principles of the application. Other embodiments and many of the intended advantages of embodiments will be readily appreciated as they become better understood by reference to the following detailed description. The elements of the drawings are not necessarily to scale relative to each other. Like reference numerals designate corresponding similar parts.

FIG. 1 is a schematic view of the overall structure of a multifunctional detection platform for a tool according to an embodiment of the present application;

FIG. 2 is a schematic diagram of the overall structure of a drill point gripping device in the multifunctional detection platform of the tool according to the embodiment of the application;

FIG. 3 is a schematic axial structure diagram of a drill point gripping device of the multifunctional detection platform of the tool according to the embodiment of the application;

FIG. 4 is a schematic structural diagram of a detection base in the multifunctional detection platform for the tool according to the embodiment of the present application;

FIG. 5 is a flow chart of a method for using the multifunctional inspection platform of the tool according to an embodiment of the present application.

The meaning of each number in the figure: the device comprises a workbench 1, a drill point gripping device 2, a detection base 3, a vision camera system 4, an L-shaped groove 5, a material tray 6, a moving platform 20, a first moving component 21, a second moving component 22, a third moving component 23, a gripping manipulator 24, a base 25, a servo rotating base 31, a position adjusting device 32, a drill point clamping component 311, a motor 312, a clamping device 313, a horizontal sliding component 321, a vertical sliding component 322, a parallel axis camera 41, a vertical axis camera (42,43,44), a camera lifting device 45, an X axial slide rail 212, an X axial slide block 213, an X axial slide rail cover plate 214, a pressing plate 215, a Z axial slide rail 221, a Z axial slide block 222, a driving motor 223, a connecting base 231, a Y axial slide rail 232, a Y axial slide block 233, a pull rod type air cylinder 234, an L-shaped connecting part 323, a driving motor 325, a pull rod type air cylinder 326 and a slide rail 0 of a horizontal sliding table pair 321321321, A sliding block 3211 of the horizontal sliding table pair, a first vertical sliding assembly 3220, a second vertical sliding assembly 3221, a sliding rail 3222 of the vertical sliding table pair, and a sliding block 3223 of the vertical sliding table pair.

Detailed Description

In the following detailed description, reference is made to the accompanying drawings, which form a part hereof, and in which is shown by way of illustration specific embodiments in which the application may be practiced. In this regard, directional terminology, such as "top," "bottom," "left," "right," "up," "down," etc., is used with reference to the orientation of the figures being described. Because components of embodiments can be positioned in a number of different orientations, the directional terminology is used for purposes of illustration and is in no way limiting. It is to be understood that other embodiments may be utilized and logical changes may be made without departing from the scope of the present application. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present application is defined by the appended claims.

The application provides a multi-functional detection platform of cutter, as shown in fig. 1, this multi-functional detection platform is equipped with the cabinet body of vertical setting, and the cabinet body adopts the aluminium alloy to form for the preparation of main material, and the four corners of cabinet body bottom all is provided with the support foot post. The upper surface of the cabinet body is a workbench 1, the workbench 1 divides the interior of the cabinet body into an upper layer and a lower layer, the power distribution equipment is installed on the layer located at the bottom, and the working mechanism is installed on one side located above the power distribution equipment.

Referring to fig. 1-3, an L-shaped groove 5 is provided on the table 1, and the table 1 is further provided with:

the drill point gripping device 2 comprises a base 25, a moving platform 20 and at least one group of gripping manipulators 24, wherein the moving platform 20 is fixedly arranged on the base 25, the moving platform 20 comprises a first moving assembly 21, a second moving assembly 22 and a third moving assembly 23, the second moving assembly 22 is movably connected with the first moving assembly 21 and moves along the axial direction of the first moving assembly 21, the third moving assembly 23 is movably connected with the second moving assembly 22 and moves along the axial direction of the second moving assembly 22, and the gripping manipulators 24 are movably connected with the third moving assembly 23 and move along the axial direction of the third moving assembly 23; the moving platform 20 is provided with a driving device to control the axial movement of the moving platform; the base 25 is fixedly arranged on the upper part of the workbench 1;

the detection base 3 comprises a servo rotating base 31 and a position adjusting device 32, the servo rotating base 31 is provided with a drill point clamping component 311 and a motor 312, a shaft of the motor 312 is connected with the drill point clamping component 311 so as to control the drill point clamping component 311 to rotate, and the drill point clamping component 311 is provided with a clamping device 313 so as to fix a drill point to be detected; the position adjusting device 32 is provided with a horizontal sliding component 321 and a vertical sliding component 322, and the servo rotary seat 31 is movably connected with the position adjusting device 32 to control the horizontal movement or the vertical movement of the servo rotary seat 31; the detection base 3 is arranged at the lower part of the workbench 1, and the drill point clamping component 311 extends out of the upper part of the workbench and can move along the L-shaped groove 5;

the numerical control module is electrically connected with the drill point gripping device 2 and the detection base 3 and is used for controlling and integrating actions of the drill point gripping device 2 and the detection base 3 so as to execute detection operation;

the vision camera system 4 is arranged at the upper part of the workbench 1 and comprises at least one optical camera, and the measuring axis of the optical camera is parallel to or vertical to the central axis of the drill point to be detected so as to detect the drill point to be detected; the vision camera system 4 is fixedly arranged on the upper part of the workbench 1.

The manipulator 24 can be driven by the drill point gripping device 2 to move in X, Y, Z three axial directions respectively, so that the gripping, the installation and the recovery of the drill point can be continuously completed; the servo rotary seat 31 can clamp the drill point and move in the horizontal direction and the vertical direction under the driving of the position adjusting device 32, and the clamping, the detection and the recovery of the drill point are continuously completed; the servo rotary seat 31 can rotate under the driving of the motor 312, and is matched with the multiple groups of vision camera systems 4 to comprehensively detect the machining precision index of the drill point. The whole operation process is controlled and integrated through the numerical control module, so that automatic detection is realized, the detection efficiency of the cutter is improved, and detection errors caused by manual operation are avoided.

In an embodiment of the present invention, the vision camera system 4 further includes a communication module (not shown in the figure) which communicates with the tool machining apparatus to make the tool machining apparatus compensate and correct the machining amount according to the detected data. By adding the communication module, the processing equipment and the detection equipment are intelligently networked, and the production quality of products is further improved.

In one embodiment of the invention, the vision camera system comprises one camera 41 with a measurement axis parallel to the central axis of the drill bit under test, and three cameras (42,43,44) with measurement axes perpendicular to the central axis of the drill bit under test. The detection of the whole key size of the cutter can be completed at one time by the cooperation of a plurality of cameras, so that the detection efficiency is improved.

In an embodiment of the present invention, the drill point gripping device 2 is provided with two gripping manipulators 24, which are respectively used for gripping the drill point to be tested on the drill point clamping assembly 31 and gripping the tested drill point on the material tray 7. The two manipulators respectively complete different instructions, and the working efficiency is improved.

In an embodiment of the present invention, the first moving assembly 21 includes an X-axis sliding rail 212, an X-axis sliding block 213, a pressing plate 215, and a driving structure, the X-axis sliding rail 212 is fixedly disposed on the base 25, the X-axis sliding block 213 is disposed inside the X-axis sliding rail 212, a sliding rail cover plate 214 is further disposed at an upper end of the X-axis sliding rail 212, and the pressing plate 215 and the X-axis sliding block 213 are fixedly connected and nested on the sliding rail cover plate 214; the driving mechanism includes a driving motor (not shown in the figure) disposed at one end of the X-axis sliding rail 212, and the driving motor drives the X-axis sliding block 213 to move axially along the X-axis sliding rail.

The slide block 213 is driven by the rotation of the motor, so as to drive the pressing plate 215 to realize the X-axis movement.

In an embodiment of the present invention, one end of the second moving assembly 22 is fixedly connected to the pressing plate 215 through a connecting plate 216 disposed on the pressing plate 215, the other end is a cantilever structure, a Z-axis sliding rail 221 and a Z-axis sliding block 222 are disposed on a side of the cantilever structure facing the vision camera system, and a driving motor 223 is disposed at an end of the second moving assembly 22 away from the cantilever to control the Z-axis sliding block 222 to move axially along the Z-axis sliding rail 221.

The driving motor 223 drives the slider 222 to move along the slide rail 221, so as to realize the Z-axis movement of the mobile platform.

In an embodiment of the present invention, the third moving assembly 23 is fixedly connected to the Z-axis sliding block 222, and includes a connecting base 231, two Y-axis sliding rails 232, two Y-axis sliding blocks 233 and two pull rod type cylinders 234, the Y-axis sliding rails 232 are fixedly disposed on the connecting base 231, the Y-axis sliding blocks 232 are movably connected to the Y-axis sliding rails 232, one end of each pull rod type cylinder 234 is fixedly connected to the connecting base 231, and the other end of each pull rod type cylinder 234 is fixedly connected to the Y-axis sliding block 233, so as to control the Y-axis sliding blocks 233 to move axially along the Y-axis sliding rails 232; the gripping robot 24 is fixedly connected to the Y-axis slider 233.

The connecting base 231 is fixedly connected with the Z-axis slider 222.

The pull rod type cylinder 234 drives the Y-axis sliding block 233 to move along the sliding rail 232, so as to drive the manipulator to realize Y-axis movement.

In an embodiment of the present invention, the position adjusting device 32 further includes an L-shaped connecting portion 323, the horizontal sliding assembly 321 is disposed on a horizontal arm of the L-shaped connecting portion 323, the horizontal sliding assembly includes a horizontal sliding table pair and a pull rod type cylinder 326, a sliding rail 3210 of the horizontal sliding table pair is fixedly disposed at a lower portion of the workbench, and a sliding block 3211 of the horizontal sliding table pair is fixedly disposed on the horizontal arm of the L-shaped connecting portion 323; one end of the pull rod type cylinder 326 is fixedly connected with the sliding block 3211 of the horizontal sliding table pair, and the other end is fixedly arranged at the lower part of the workbench 1 so as to control the horizontal movement of the position adjusting device 32; the vertical sliding component 322 is arranged on the vertical arm of the L-shaped connecting part, and comprises a first vertical sliding component 3220, a second vertical sliding component 3221 and a driving motor 325, wherein the first vertical sliding component 3220 is arranged on the side surface of the vertical arm, which faces away from the horizontal arm, and the second vertical sliding component 3221 is arranged on the side surface of the vertical arm, which is perpendicular to the horizontal arm; the first vertical sliding assembly comprises a vertical sliding table pair, a sliding rail 3222 of the vertical sliding table pair is arranged on the side surface deviating from the horizontal arm, and a sliding block 3223 of the vertical sliding table pair is movably connected with the sliding rail 3222 and the second vertical sliding assembly 3221 respectively; an output shaft of the driving motor 325 is connected with a sliding block 3223 of the vertical sliding table pair to control the vertical movement of the position adjusting device 32; the sliding block 3223 of the vertical sliding table pair is fixedly connected to the servo rotary seat 31. The structure enables the servo rotary seat to clamp the drill point to move in the horizontal and vertical directions.

The horizontal sliding table pair is preferably two sliding table pairs arranged in parallel, a connecting block is arranged between the two horizontal sliding table pairs, and the connecting block is fixedly connected with one end of the pull rod type air cylinder 326 and can simultaneously drive the two horizontal sliding table pairs to move simultaneously, so that the stability during horizontal movement is improved.

In an embodiment of the invention, the camera 41 with the measuring axis parallel to the central axis of the drill point to be measured is further provided with a vertical lifting device 45 for adjusting the up-and-down measuring position of the camera. The camera position is adjustable, is convenient for align measuring tool, makes to measure more accurately.

The application also discloses a using method of the multifunctional detection platform of the cutter, which specifically comprises the following steps as shown in fig. 5:

(1) the drill point is clamped and positioned: adjusting the relative position of the central axis of the drill point detection base and the axis of the camera vision system and the relative position of the drill point detection base and the drill point gripping device, inputting the adjusted X, Y, Z coordinate point and the transverse moving distance of the drill point to a processing limit point to complete setting, returning to a main interface, resetting, and starting detection operation according to starting;

(2) the servo rotating seat moves to a drill point clamping station: the servo rotary seat extends out of the upper surface of the working platform and moves to a drill point clamping station along the transverse position of the L-shaped clamping groove by controlling an X-axis sliding table and a Y-axis sliding table of the detection base;

(3) grabbing and fixing a drill point: the manipulator of the drill point gripping device moves to a material tray to be measured through the moving platform to grip a drill point to be measured, moves to a drill point clamping station, loads the drill point to be measured into the drill point clamping assembly, and fixes the drill point through the clamping device;

(4) detecting a drill point: detecting the drill point through a vision camera system;

(5) and (3) classifying and recycling the detected drill pins: after detection is finished, the servo rotary seat moves to a drill point clamping station, the clamping device loosens the drill point, and the manipulator moves to the position above the drill point to grab the drill point and moves to a corresponding recovery tray.

It is apparent that various modifications and variations can be made to the embodiments of the present application by those skilled in the art without departing from the spirit and scope of the application. In this way, if these modifications and changes are within the scope of the claims of the present application and their equivalents, the present application is also intended to cover these modifications and changes. The word "comprising" does not exclude the presence of other elements or steps than those listed in a claim. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage. Any reference signs in the claims shall not be construed as limiting the scope.

Claims (10)

1. the multifunctional detection platform of a tool is provided with a workbench, and it is characterized in that, the workbench is provided with an L-shaped groove, and the multifunctional detection platform also comprises: The drill needle grabbing device includes a base, a moving platform and at least one group of grabbing manipulators, the moving platform is fixedly arranged on the base, and the moving platform includes a first moving component, a second moving component and a third moving component. The second moving component is movably connected with the first moving component and moves along the axial direction of the first moving component, and the third moving component is movably connected with the second moving component and moves along the second moving component The grasping manipulator is movably connected with the third moving assembly and moves along the axial direction of the third moving assembly; the moving platform is provided with a driving device to control the axis of the moving platform to move; the base is fixedly arranged on the upper part of the workbench; The detection base includes a servo rotating base and a position adjusting device, the servo rotating base is provided with a drill pin clamping assembly and a motor, and the shaft of the motor is connected with the drill pin clamping assembly to control the drill pin clamping For the rotation of the assembly, the drill pin clamping component is provided with a clamping device to fix the drill pin to be tested; the position adjustment device is provided with a horizontal sliding component and a vertical sliding component, and the servo rotating seat is connected to the position adjustment device. Actively connected to control the horizontal movement or vertical movement of the servo rotating base; the detection base is arranged on the lower part of the workbench, and the drill pin clamping assembly protrudes from the upper part of the workbench and can move along the L-shaped groove ; a numerical control module, the numerical control module is electrically connected with the drill pin grabbing device and the detection base, and is used for controlling and integrating the actions of the drill pin grabbing device and the detection base to perform the inspection operation; A vision camera system, arranged on the upper part of the workbench, includes at least one optical camera, the measurement axis of the optical camera is parallel or perpendicular to the central axis of the drill to be tested, so as to detect the drill to be tested; the visual camera system It is fixedly arranged on the upper part of the workbench. 2 . The multifunctional detection platform for cutting tools according to claim 1 , wherein the visual camera system further comprises a communication module, and the communication module communicates with the cutting tool processing equipment, so that the cutting tool processing equipment can The detection data compensates and corrects the machining amount. 3. The multifunctional inspection platform for cutting tools according to claim 2, wherein the visual camera system comprises a camera whose measurement axis is parallel to the central axis of the drill to be measured, and three measurement axes are parallel to the center axis of the drill to be measured. The center axis of the stylus is vertical to the camera. 4 . The multifunctional detection platform for cutting tools according to claim 1 , wherein the drill pin grabbing device is provided with two grabbing manipulators, which are respectively used to grab the drill pin to be tested to the On the drill pin holding assembly, and grab the drill pin after the inspection to the material tray. 5 . The multifunctional detection platform for cutting tools according to claim 1 , wherein the first moving component comprises an X-axis slide rail, an X-axis slide rail, a pressure plate and a driving structure, and the X-axis The sliding rail is fixedly arranged on the base, the X-axis sliding block is arranged on the inner side of the X-axis sliding rail, the upper end of the X-axis sliding rail is also provided with a sliding rail cover, and the pressing plate It is fixedly connected with the X-axis slider and nested on the slide rail cover; the drive mechanism includes a drive motor arranged at one end of the X-axis slide rail, and the drive motor drives the X-axis The sliding block moves axially along the X-axis slide rail. 6 . The multifunctional detection platform for cutting tools according to claim 1 , wherein one end of the second moving component is fixedly connected to the pressing plate through a connecting plate arranged on the pressing plate, and the other end is fixedly connected to the pressing plate. 7 . A cantilever structure, the side of the cantilever structure facing the visual camera system is provided with a Z-axis slide rail and a Z-axis slider, and the end of the second moving component away from the cantilever is provided with a drive motor to control the The Z-axis slider moves axially along the Z-axis slide rail. 7 . The multifunctional detection platform for a tool according to claim 1 , wherein the third moving component is fixedly connected to the Z-axis slider, comprising a connection base and two Y-axis slide rails. 8 . , two Y-axis sliding blocks and two tie rod-type cylinders, the Y-axis sliding rails are fixedly arranged on the connecting base, and the Y-axis sliding blocks are movably connected with the Y-axis sliding rails, so One end of the tie rod type cylinder is fixedly connected to the connection base, and the other end is fixedly connected to the Y-axis slide block, so as to control the Y-axis slide block to move axially along the Y-axis slide rail; The grasping manipulator is fixedly arranged on the Y-axis sliding block. 8 . The multifunctional detection platform for a tool according to claim 1 , wherein the position adjusting device further comprises an L-shaped connecting portion, and the horizontal sliding assembly is arranged on the horizontal arm of the L-shaped connecting portion, 8 . The horizontal sliding assembly includes a horizontal sliding table pair and a tie rod type cylinder, the sliding rail of the horizontal sliding table pair is fixedly arranged at the lower part of the worktable, and the sliding block of the horizontal sliding table pair is fixedly arranged at the bottom of the L-shaped connecting part. on the horizontal arm; one end of the tie rod type cylinder is fixedly connected with the slider of the horizontal sliding table pair, and the other end is fixedly arranged at the lower part of the worktable to control the horizontal movement of the position adjusting device; the vertical sliding assembly It is arranged on the vertical arm of the L-shaped connecting part and includes a first vertical sliding component, a second vertical sliding component and a driving motor. The first vertical sliding component is arranged on the side of the vertical arm away from the horizontal arm, so The second vertical sliding assembly is arranged on the side of the vertical arm that is perpendicular to the horizontal arm; the first vertical sliding assembly includes a vertical sliding table pair, and the sliding rail of the vertical sliding table pair is arranged on the side away from the horizontal On the side of the arm, the sliding block of the vertical sliding table pair is respectively movably connected with the sliding rail and the second vertical sliding assembly; the output shaft of the driving motor is connected with the sliding block of the vertical sliding table pair to The vertical movement of the position adjusting device is controlled; the sliding block of the vertical sliding table pair is fixedly connected with the servo rotating seat. 9 . The multifunctional detection platform for a tool according to claim 3 , wherein the camera whose measurement axis is parallel to the central axis of the drill to be measured is also provided with a vertical lifting device to adjust the up and down measurement of the camera. 10 . Location. 10. The method for using a multifunctional detection platform for a tool according to any one of claims 1-9, wherein the method comprises the following steps: (1) Drill pin clamping and positioning setting: adjust the relative position of the central axis of the drill pin detection base and the axis of the camera vision system and the relative position of the drill pin grabbing device, and adjust the adjusted X, Y, The Z coordinate point and the horizontal movement distance of the drill needle are entered at the processing limit point to complete the setting, return to the main interface, press reset, and then press start to start the detection operation; (2) The servo rotating seat is moved to the drill pin clamping station: by controlling the X-axis slide table and the Y-axis slide table of the detection base, the servo rotating seat is protruded from the upper surface of the working platform and along the L-shaped slot. Move to the drill pin clamping station from the lateral position; (3) Drill pin grabbing and fixing: the manipulator of the drill pin grabbing device moves to the material tray to be tested through the moving platform to grab the drill pin to be tested, and moves to the drill pin clamping station, where the The drill pin to be tested is loaded into the drill pin clamping assembly, and the drill pin is fixed by the clamping device; (4) Drill needle detection: The drill needle is detected by a visual camera system; (5) Sorting and recycling of drill pins after detection: After the detection is completed, the servo rotating base moves to the drill pin clamping station, the clamping device releases the drill pins, and the manipulator moves above the drill pins to grab drill and move it to the corresponding recycling tray.

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