CN211277659U - Cutter passivation and measurement integrated device - Google Patents

Abstract

The utility model provides a cutter passivation measures integrative device, its lathe frame bottom is provided with step motor, the step motor output shaft passes through the shaft coupling and is connected with ball screw mechanism, ball screw mechanism fixedly connected with support frame, the support frame top is provided with first servo motor and second servo motor, the support frame below is provided with the revolution carousel, the revolution carousel passes through N link gear and N rotation carousel connection, each rotation carousel below all is connected with corresponding cutter clamping mechanism, there are a plurality of guide posts at ball screw mechanism bilateral symmetry equipartition, every guide post cover is equipped with corresponding guide pin bushing, guide post and lathe frame fixed connection, guide pin bushing and support frame fixed connection, the guide post runs through the guide pin bushing, and can the relative slip. The device realizes that the cutter can be accurately positioned and accurately measured after being clamped once in the passivation process; meanwhile, the accurate measurement of the target passivation value is realized, the requirement of the passivation precision value is ensured, and the error caused by multiple times of clamping and multiple times of measurement is reduced.

Description

Cutter passivation and measurement integrated device

Technical Field

The utility model belongs to the technical field of the cutter processing equipment, concretely relates to cutter passivation measures integrative device.

Background

The main machining method of machining is machining, and a tool is hardware indispensable for machining. The cutter formed by grinding through the knife grinder and the grinding wheel is observed through a high power magnifying glass, and a large number of microscopic notches with the width of 10-50 mu m exist on the cutting edge of the cutter. The micro notches not only reduce the surface quality and strength of the cutter, but also expand and extend the micro notches on the surface of the cutter under the action of multiple factors such as force, heat, vibration and the like in cutting machining, so that the quick abrasion and damage failure of the cutter are caused, the service life of the cutter is greatly reduced, the machining quality of a workpiece is difficult to guarantee, and how to reduce or reduce the grinding damage at the cutting edge of the cutter is important for improving the cutting performance of the cutter.

The emerging tool passivation technology is an effective measure for prolonging the service life of the tool and reducing the tool abrasion. The cutter passivation not only eliminates the microscopic defects of the cutting edge of the cutter, but also obtains the appropriate microscopic geometric parameters of the cutting edge and the smooth surface of the cutting edge, and simultaneously eliminates the residual tensile stress generated by grinding the surface of the cutting edge, thereby effectively improving the strength of the cutting edge and the stability of the cutting process and prolonging the service life of the cutter. Through a large number of cutting tests and cutting edge passivation practices, it can be realized that: the good cutting edge type and the blade passivation quality are also the precondition of how fast, and how economical the tool can carry out cutting processing.

With the development of modern manufacturing techniques, the tool cutting edge geometry may be adjusted according to the tool material and the workpiece material, and the specific cutting edge is designed according to different cutting processes. The cutter passivation machine tool realizes scientific passivation treatment of the cutting edge of the cutter, so that the cutting edge is improved into a smooth and regular straight line or curve, and the average service life of the cutter can be prolonged by 1.5-3 times. In the passivation production process of the cutter, a dragging type passivation method is commonly used, the cutter is generally clamped on a cutter passivation machine to passivate the cutter, disordered friction is generated between a workpiece and a grinding material in the passivation process, then the cutter is taken to a measuring device to measure the passivation result, the obtained data is used for representing the geometry of a cutting edge, in order to achieve a better passivation effect, a large amount of reciprocating operation is needed, the cumulative error of measurement is increased, the production cost of the cutter is also increased, and the production efficiency of the cutter is reduced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that the prior cutter passivation processing precision is difficult to guarantee and the measurement accumulated error is large, and provides a cutter passivation and measurement integrated device, which realizes the purpose of completing passivation and measurement by single equipment; meanwhile, the accurate measurement of the target passivation value is realized, the requirement of the passivation precision value is ensured, and the error caused by multiple times of clamping and multiple times of measurement is reduced. The revolution turntable is connected with N linkage mechanisms to realize one-time passivation of multiple cutters. The rotation turntable is directly connected with the cutter clamping mechanism to realize accurate control of cutter rotation.

The utility model discloses a cutter passivation measures integrative device, including lathe frame, step motor, shaft coupling, ball screw mechanism, guide post, guide pin bushing, axle fixed sleeve, support frame, first servo motor, second servo motor, revolution carousel, N link gear, N rotation carousel, N cutter clamping mechanism, infrared scanner, optical microscope, abrasive trough and abrasive trough bracket;

the machine tool comprises a machine tool frame, a stepping motor, a ball screw mechanism, a horizontal support frame, a revolving turntable, a cutter clamping mechanism, a first servo motor, a second servo motor, an infrared scanner and an optical microscope, wherein the bottom of the machine tool frame is provided with the stepping motor, an output shaft of the stepping motor is connected with the ball screw mechanism through a coupler, the ball screw mechanism is fixedly connected with the support frame, the support frame is divided into the horizontal support frame and a vertical support frame, the first servo motor and the second servo motor are arranged above the horizontal support frame, the revolving turntable is arranged below the horizontal support frame and is connected with N autorotation turntables through N linkage mechanisms, the lower part of each autorotation turntable is connected with the corresponding cutter clamping mechanism, the first servo motor is connected with the revolving turntable and is used for driving the revolution, the device is used for accurately positioning and measuring the cutting edge of the cutter;

a grinding trough is arranged below the cutter clamping mechanism, and a grinding trough bracket fixed on the machine body frame is arranged below the grinding trough;

the cutter passivation and measurement integrated device is further provided with a plurality of guide posts which are symmetrically and uniformly distributed on two sides of the ball screw mechanism, the upper end and the lower end of each guide post are fixedly connected with a machine tool frame through shaft fixing sleeves, each guide post sleeve is provided with a corresponding guide sleeve, the guide posts are connected with the guide sleeves in a sliding mode, the guide sleeves are fixedly connected with the support frame and move up and down along with the support frame, and the guide posts sleeved in the guide sleeves ensure that the axial position of the support frame is unchanged.

The ball screw mechanism mainly comprises a screw, a nut seat and balls; the screw rod penetrates through the nut, the screw rod is in threaded connection with the nut, a ball is arranged between the screw rod and the nut, a nut seat is arranged on the nut, and a bolt hole is formed in the nut seat;

the output shaft of the stepping motor is connected with a lead screw of the ball screw mechanism through a coupler, a nut of the ball screw mechanism is connected with the support frame through a nut seat, the stepping motor rotates to drive a lead screw of the ball screw mechanism to rotate, the nut arranged on the lead screw vertically moves along the lead screw, and the nut seat connected with the nut drives the support seat to vertically move.

The nut seat of the ball screw mechanism is fixedly connected with the support frame through a bolt.

The N linkage mechanisms are uniformly distributed on the circumference of the revolution turntable, the revolution turntable is provided with a centripetal/centrifugal orbit corresponding to each of the N linkage mechanisms, the revolution turntable rotates to drive the N linkage mechanisms to do centripetal/centrifugal motion along the centripetal/centrifugal orbit on the revolution turntable by taking the axis of the revolution turntable as the center, wherein N is a positive integer larger than or equal to 1, preferably 6, when the revolution turntable is in forward transmission, the N linkage mechanisms do centripetal motion, and when the revolution turntable is in reverse rotation, the N linkage mechanisms do centrifugal motion.

The support frame comprises roof, two relative curb plates and backplate, and the backplate is installed to the roof below, and two relative curb plates are fixed respectively in the backplate both sides to be connected with the roof, the roof is as horizontal support frame, two relative curb plates and backplate are as perpendicular support frame, as preferred, and the machine tool frame side that corresponds on one side of the support frame opening is provided with infrared scanner and optical microscope.

The infrared scanner and the optical microscope are connected with a computer.

The guide post be used for carrying out accurate location to the support frame to guarantee the accurate location of cutter axial.

Furthermore, in the tool passivation and measurement integrated device, a stepping motor fixing seat and a lead screw fixing seat are arranged on a machine tool frame close to one side of the back plate, the stepping motor is fixedly arranged on the stepping motor fixing seat, and a lead screw of the ball screw mechanism is connected with the lead screw fixing seat;

the step motor fixing seat can be arranged below the grinding material groove bracket, the step motor is fixedly arranged on the step motor fixing seat, and an output shaft of the step motor penetrates through the grinding material groove bracket and is connected with a lead screw of the ball screw mechanism through a coupler.

The use method of the cutter passivation and measurement integrated device comprises the following steps:

(1) clamping a tool to be passivated and measured on a tool clamping mechanism;

(2) turning on a stepping motor, driving a ball screw mechanism to convert rotary motion into linear motion by the stepping motor, taking a support frame connected with the ball screw mechanism as a driven workpiece, driving the support frame to move downwards by the ball screw mechanism, and moving a cutter to be passivated and measured along with the support frame so that the passivated part of the cutter is completely immersed in the grinding material contained in a grinding material groove;

(3) starting a first servo motor and a second servo motor, wherein the first servo motor drives the revolution turntable to rotate and simultaneously drives the N linkage mechanisms to perform centripetal/centrifugal motion along a centripetal/centrifugal track arranged along the revolution turntable by taking the axis of the revolution turntable as the center, and the second servo motor drives the rotation turntable to rotate to drive the cutter on the cutter clamping mechanism to rotate;

(4) after passivation processing, a stepping motor drives a ball screw mechanism to rotate, the ball screw mechanism drives a support frame to move upwards, so that a cutter moves upwards, meanwhile, a first servo motor drives a revolution turntable to rotate reversely, and simultaneously drives N linkage mechanisms to move centrifugally along a centripetal/centrifugal track arranged on the revolution turntable by taking the axis of the revolution turntable as the center, so that the cutter is arranged at a position where an infrared scanner and an optical microscope are arranged, the infrared scanner and the optical microscope arranged on the side surface of a machine tool frame are started, a lens of the optical microscope stretches to the edge of the cutter, the distance between the infrared scanner and the optical microscope is 10mm +/-1 mm, and a passivation value of the cutter edge is measured by adopting a 3D imaging technology;

(5) and (4) judging the measured passivation value of the cutting edge of the cutter, if the passivation requirement is met, not continuing, and if the passivation requirement is not met, repeating the steps (2) - (4) until the passivation requirement is met.

In the step (4), the infrared scanner accurately positions the cutter to ensure that the optical microscope can accurately stretch to the edge position of the cutter edge and measure the passivation value of the cutter edge.

The utility model discloses a cutter passivation measures integrative device, its beneficial effect is: the utility model discloses a real-time measurement in the cutter passivation process has reduced the measuring number of times of clamping repeatedly, has reduced the measuring error because of the clamping causes repeatedly. The first servo motor is adopted to drive the revolution turntable, so that the revolution of the cutter is realized, and meanwhile, the first servo motor drives the linkage mechanism to move centripetally/centrifugally, so that the centripetally/centrifugally move of the cutter is realized. And the second servo motor is adopted to drive the rotation turntable independently, so that the rotation of the cutter is realized. And the precise control of the passivation value of the cutter is realized by adopting the measurement of an optical microscope.

Drawings

Fig. 1 is a schematic front view of an integrated device for passivation and measurement of a cutting tool in an embodiment of the present invention;

fig. 2 is a schematic right-view structural diagram of an integrated device for passivation and measurement of a cutting tool in an embodiment of the present invention;

fig. 3 is a schematic view of a connection structure of a ball screw mechanism in an integrated device for passivation and measurement of a cutting tool in an embodiment of the present invention;

fig. 4 is a schematic view of a connection structure of a guide post in the tool passivation measurement integrated device in the embodiment of the present invention;

fig. 5 is a schematic view of centripetal/centrifugal movement of a tool in the integrated device for passivation and measurement of the tool in the embodiment of the present invention;

in the figure: 1. the grinding machine comprises a machine tool frame, 2, a stepping motor, 3, a coupler, 4, a shaft fixing sleeve, 5, a ball screw mechanism, 501, a screw, 502, a nut, 503, a nut seat, 504, a screw fixing seat, 6, a supporting frame, 601, a top plate, 602, a side plate, 603, a back plate, 7, a first servo motor, 8, a second servo motor, 9, a revolution turntable, 10, a linkage mechanism, 11, a rotation turntable, 12, a tool clamping mechanism, 13, an infrared scanner, 14, an optical microscope, 15, an abrasive groove, 16, an abrasive groove bracket, 17, a guide column, 18 and a guide sleeve.

Detailed Description

The present invention will be described in further detail with reference to examples.

Example 1

A cutter passivation measurement integrated device is shown in a front view structural schematic diagram of fig. 1, and is shown in a right view structural schematic diagram of fig. 2, and comprises a machine tool frame 1, a stepping motor 2, a coupler 3, a ball screw mechanism 5, a guide column 17, a guide sleeve 18, a shaft fixing sleeve 4, a support frame 6, a first servo motor 7, a second servo motor 8, a revolution turntable 9, N linkage mechanisms 10, N rotation turntables 11, N cutter clamping mechanisms 12, an infrared scanner 13, an optical microscope 14, an abrasive groove 15 and an abrasive groove bracket 16;

the ball screw mechanism 5 mainly comprises a screw 501, a nut 502, a nut seat 503 and balls; the screw 501 penetrates through the nut 502, the screw 501 is in threaded connection with the nut 502, a ball is arranged between the screw 501 and the nut 502, the nut 502 is provided with a nut seat 503, and the nut seat 503 is provided with a bolt hole;

the bottom of the machine tool frame 1 is provided with a stepping motor 2, an output shaft of the stepping motor 2 is connected with a screw 501 of a ball screw mechanism 5 through a coupler 3, a nut 502 of the ball screw mechanism 5 is connected with a support frame 6 through a nut seat 503 by a bolt, the stepping motor 2 rotates to drive the screw 501 of the ball screw mechanism 5 to rotate, the nut 502 arranged on the screw 501 moves up and down along the screw 501, and the nut seat 503 connected with the nut 502 drives the support seat 6 to move up and down.

The support frame 6 is composed of a top plate 601, two opposite side plates 602 and a back plate 603, the back plate 603 is installed below the top plate 601, the two opposite side plates 602 are respectively fixed at two sides of the back plate 603 and connected with the top plate 601, the top plate 601 is used as a horizontal support frame, the two opposite side plates 602 and the back plate 603 are used as vertical support frames, a first servo motor 7 and a second servo motor 8 are arranged above the horizontal support frame, a revolution turntable 9 is arranged below the horizontal support frame, the revolution turntable 9 is connected with N rotation turntables 11 through N linkage mechanisms 10, a corresponding tool clamping mechanism 12 is connected below each rotation turntable 11, the first servo motor 7 is connected with the revolution turntable 9 and is used for driving the revolution turntable 9 to rotate and simultaneously driving the linkage mechanisms to do centripetal/centrifugal motion, the second servo motor 8 is connected with the N rotation turntables 11 and is used for driving the rotation turntables 11, an infrared scanner 13 and an optical microscope 14 are arranged on the side wall of the machine tool frame 1 at the tool detection position and used for accurately positioning and measuring the tool cutting edge;

a grinding material groove 15 is arranged below the cutter clamping mechanism, and a grinding material groove bracket 16 fixed on the machine body frame 1 is arranged below the grinding material groove 15;

the cutter passivation and measurement integrated device is further provided with two guide columns 17 which are symmetrically and uniformly distributed on two sides of the ball screw mechanism 5, the upper end and the lower end of each guide column 17 are fixedly connected with the machine tool frame 1 through a shaft fixing sleeve 4, each guide column 17 is sleeved with a corresponding guide sleeve 18, the guide columns 17 can slide relative to the guide sleeves 18, the guide sleeves 18 are fixedly connected with the support frame 6 and move up and down along with the support frame 6, and the guide columns 17 sleeved in the guide sleeves 18 ensure that the axial position of the support frame 6 is unchanged.

The N linkage mechanisms are uniformly distributed on the circumference of the revolution turntable, the revolution turntable is provided with a centripetal/centrifugal orbit (shown in fig. 3) corresponding to each of the N linkage mechanisms, the revolution turntable rotates to drive the N linkage mechanisms to do centripetal/centrifugal motion along the centripetal/centrifugal orbit on the revolution turntable by taking the axis of the revolution turntable as the center, wherein the number of N is 6 in the embodiment, when the revolution turntable is in forward transmission, the N linkage mechanisms do centripetal motion, and when the revolution turntable is in reverse rotation, the N linkage mechanisms do centrifugal motion.

The infrared scanner and the optical microscope are connected with a computer.

The guide post be used for carrying out accurate location to the support frame to guarantee the accurate location of cutter axial.

In the tool passivation and measurement integrated device, a stepping motor fixing seat and a lead screw fixing seat 504 are arranged on a machine tool frame 1 close to one side of a back plate 603, a stepping motor 2 is fixedly arranged on the stepping motor fixing seat, and a lead screw 501 of a ball screw mechanism 5 is connected with the lead screw fixing seat 504.

A use method of the tool passivation measurement integrated device comprises the following steps:

the first step is as follows: clamping the tool to the tool clamping mechanism 12;

the second step is that: starting a stepping motor, driving a ball screw mechanism to convert rotary motion into linear motion by the stepping motor, taking a support frame connected with the ball screw mechanism as a driven workpiece, driving the support frame to move downwards by the ball screw mechanism, and moving a cutter to be passivated and measured along with the movement of the support frame so that a passivated part of the cutter is completely immersed in the grinding material contained in a grinding material groove;

the third step: starting a first servo motor and a second servo motor, wherein the first servo motor drives the revolution turntable to rotate and simultaneously drives the N linkage mechanisms to perform centripetal/centrifugal motion along a centripetal/centrifugal track arranged along the revolution turntable by taking the axis of the revolution turntable as the center, and the second servo motor drives the rotation turntable to rotate to drive the cutter on the cutter clamping mechanism to rotate;

the fourth step: the stepping motor drives the ball screw mechanism to do rotary motion, the ball screw mechanism drives the support frame to move upwards, so that the cutter moves upwards, meanwhile, the first servo motor drives the revolution turntable to rotate reversely, and simultaneously drives the N linkage mechanisms to do centrifugal motion along a centripetal/centrifugal track arranged on the revolution turntable by taking the axis of the revolution turntable as a center, so that the cutter is arranged at a position where an infrared scanner and an optical microscope are arranged, the infrared scanner and the optical microscope arranged on the side surface of a machine tool frame are started, the cutter is accurately positioned through the infrared scanner, so that a lens of the optical microscope stretches to the edge of the cutter, the distance between the infrared scanner and the optical microscope is 10mm, and the passivation value of the cutter edge is measured by adopting a 3D imaging technology;

the fifth step: and judging the measured passivation value of the cutting edge of the cutter, if the passivation requirement is met, not continuing, and if the passivation requirement is not met, repeating the second step to the fourth step until the passivation requirement is met.

Example 2

The utility model provides an integrative device is measured in cutter passivation, includes lathe frame 1, step motor 2, shaft coupling 3, axle fixed cover 4, ball screw mechanism 5, guide pin bushing 18, guide post 17, support frame 6, first servo motor 7, second servo motor 8, revolution carousel 9, link gear 10, rotation carousel 11, cutter clamping mechanism 12, infrared scanner 13, optical microscope 14, abrasive material groove 15, abrasive material groove bracket 16.

The nut seat of the ball screw mechanism 5 is fixed with the support frame 6 through bolts, and the structural schematic diagram is shown in fig. 4; the guide post 17 is connected with the support frame 6 through a guide sleeve 18, and the guide post 17 is sleeved in the guide sleeve 18 and can slide relatively; the guide post 17 is fixed with the machine tool frame 1 through a shaft fixing sleeve 4, the structural schematic diagram of the guide post is shown in fig. 5, the stepping motor 2 is connected with the ball screw mechanism 5 through the coupler 3, and the stepping motor 2 rotates to drive a screw 501 in the ball screw mechanism to rotate so as to drive the support frame 6 to move up and down.

The upper end of the support frame 6 is fixed with two servo motors, namely a first servo motor 7 and a second servo motor 8 through bolts, the lower end of the support frame 6 is connected with a revolution turntable 9, the bottom of the revolution turntable 9 is connected with N linkage mechanisms 10, each linkage mechanism 10 is connected with an autorotation turntable 11, a cutter clamping mechanism 12 is fixed on the autorotation turntable 11, the first servo motor 7 is connected with the revolution turntable 9, and the second servo motor 8 is connected with the autorotation turntable 11.

The infrared scanner 13 and the optical microscope 14 are fixed on the side of the machine frame 1 and connected to the control computer.

The grinding trough 15 is fixed on the grinding trough bracket 16, and the grinding trough bracket 16 is fixedly connected with the machine tool frame 1 through bolts.

The stepping motor 2 drives the ball screw mechanism 5, and the ball screw mechanism 5 drives the support frame 6 to move up and down; the first servo motor 7 drives the revolution turntable 9 and realizes the revolution and centripetal/centrifugal movement of the cutter through the linkage mechanism 10; the second servo motor 8 drives the autorotation turntable 11 to drive the cutter clamping mechanism 12 so as to realize the rotation of the cutter; the infrared scanner 13 and the optical microscope 14 realize the accurate positioning and measurement of the tool.

The specific implementation steps of the cutter passivation and measurement integrated device of the embodiment comprise:

the first step is as follows: clamping the tool to the tool clamping mechanism 12;

the second step is that: the stepping motor 2 drives a lead screw 501 of the ball screw mechanism 5 to rotate, the lead screw 501 drives a nut 502 to rotate upwards and downwards on the lead screw 501, the nut 502 drives a nut seat 503 connected with the nut 502 to move downwards, the nut seat 503 drives a supporting seat 6 connected with the nut seat to move downwards, and the supporting seat 6 drives a cutter arranged on the cutter clamping mechanism 12 to move downwards until a cutter passivation part is completely immersed in the abrasive material;

the third step: the first servo motor 7 drives the revolution turntable 9 to rotate and simultaneously drives the linkage mechanism 10 to do centripetal/centrifugal motion on the revolution turntable 9; the second servo motor 8 drives the autorotation turntable 11 to rotate so as to achieve autorotation of the cutter;

the fourth step: after the passivation processing is carried out for a certain time, the stepping motor 2 drives the cutter to move upwards, and meanwhile, the first servo motor drives the revolution turntable to rotate, so that the cutter is in centrifugal motion and is close to the position of the microscope lens, the microscope lens stretches to the position where the edge of the cutter is 10mm away from the lens, and the passivation value of the cutter edge is measured by adopting a 3D imaging technology;

the fifth step: judging the measured passivation value of the cutting edge of the cutter, and directly taking out the cutter without passivation treatment when the design requirement is met; and when the passivation requirement value is not met, repeating the second step to the fourth step until the passivation requirement is met.

Claims (9)

1. A cutter passivation and measurement integrated device is characterized by comprising a machine tool frame, a stepping motor, a coupler, a ball screw mechanism, a guide post, a guide sleeve, a shaft fixing sleeve, a supporting frame, a first servo motor, a second servo motor, a revolution turntable, N linkage mechanisms, N autorotation turntables, N cutter clamping mechanisms, an infrared scanner, an optical microscope, a grinding trough and a grinding trough bracket;

the machine tool comprises a machine tool frame, a stepping motor, a ball screw mechanism, a horizontal support frame, a revolving turntable, a cutter clamping mechanism, a first servo motor, a second servo motor, an infrared scanner and an optical microscope, wherein the bottom of the machine tool frame is provided with the stepping motor, an output shaft of the stepping motor is connected with the ball screw mechanism through a coupler, the ball screw mechanism is fixedly connected with the support frame, the support frame is divided into the horizontal support frame and a vertical support frame, the first servo motor and the second servo motor are arranged above the horizontal support frame, the revolving turntable is arranged below the horizontal support frame and is connected with N autorotation turntables through N linkage mechanisms, the lower part of each autorotation turntable is connected with the corresponding cutter clamping mechanism, the first servo motor is connected with the revolving turntable and is used for driving the revolution, the device is used for accurately positioning and measuring the cutting edge of the cutter;

a grinding trough is arranged below the cutter clamping mechanism, and a grinding trough bracket fixed on the machine body frame is arranged below the grinding trough;

the cutter passivation and measurement integrated device is further provided with a plurality of guide columns, the guide columns are symmetrically and uniformly distributed on two sides of the ball screw mechanism, the upper end and the lower end of each guide column are fixedly connected with a machine tool frame through shaft fixing sleeves, each guide column sleeve is provided with a corresponding guide sleeve, the guide columns are connected with the guide sleeves in a sliding mode, and the guide sleeves are fixedly connected with the support frame and move up and down along with the support frame.

2. The tool passivation measurement integrated device as claimed in claim 1, wherein the ball screw mechanism mainly comprises a screw, a nut seat and a ball; the screw rod penetrates through the nut, the screw rod is in threaded connection with the nut, a ball is arranged between the screw rod and the nut, a nut seat is arranged on the nut, and a bolt hole is formed in the nut seat;

the output shaft of the stepping motor is connected with a lead screw of the ball screw mechanism through a coupler, a nut of the ball screw mechanism is connected with the support frame through a nut seat, the stepping motor rotates to drive a lead screw of the ball screw mechanism to rotate, the nut arranged on the lead screw vertically moves along the lead screw, and the nut seat connected with the nut drives the support seat to vertically move.

3. The tool passivation measurement integrated device as claimed in claim 2, wherein the nut seat of the ball screw mechanism and the support frame are fixedly connected through a bolt.

4. The integrated tool passivation measuring device according to claim 1, wherein the N linkages are uniformly distributed on the circumference of the revolving turntable, the revolving turntable is provided with a centripetal/centrifugal orbit corresponding to each of the N linkages, the revolving turntable rotates to drive the N linkages to perform centripetal/centrifugal motion along the centripetal/centrifugal orbit on the revolving turntable with the axis of the revolving turntable as the center, wherein N is a positive integer greater than or equal to 1, the N linkages perform centripetal motion when the revolving turntable is in forward rotation, and the N linkages perform centrifugal motion when the revolving turntable is in reverse rotation.

5. The tool passivation measuring integrated device according to claim 1, wherein the infrared scanner and the optical microscope are connected with a computer.

6. The tool passivation and measurement integrated device as claimed in claim 1, wherein the guide posts are used for accurately positioning the support frame to ensure accurate axial positioning of the tool.

7. The integrated tool passivation measuring device according to claim 1, wherein the supporting frame is composed of a top plate, two opposite side plates and a back plate, the back plate is installed below the top plate, the two opposite side plates are respectively fixed on two sides of the back plate and connected with the top plate, the top plate serves as a horizontal supporting frame, and the two opposite side plates and the back plate serve as vertical supporting frames.

8. The integrated tool passivation and measurement device according to claim 7, wherein a stepping motor fixing seat and a lead screw fixing seat are arranged on the machine tool frame on a side close to the back plate, the stepping motor is fixedly arranged on the stepping motor fixing seat, and a lead screw of the ball screw mechanism is connected with the lead screw fixing seat.

9. The integrated tool passivation and measurement device according to claim 8, wherein a stepping motor fixing seat is arranged below the abrasive trough bracket, the stepping motor is fixedly arranged on the stepping motor fixing seat, and an output shaft of the stepping motor penetrates through the abrasive trough bracket and is connected with a lead screw of the ball screw mechanism through a coupling.

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