CN214502359U - Driving mechanism zero setting device using grating ruler to assist measurement - Google Patents

Abstract

The utility model discloses a help measuring actuating mechanism zero-setting device with grating chi, including equipment fixing platform, rotation control mechanism, measuring mechanism, actuating mechanism, measuring mechanism installs in equipment fixing platform's top, and measuring mechanism is used for measuring the actual deviation of actuating mechanism machinery zero-bit, and rotation control mechanism installs on equipment fixing platform, and actuating mechanism's input is connected with rotation control mechanism's output, and rotation control mechanism is used for controlling actuating mechanism rotation and feedback rotation angle. The utility model adopts the rotation measurement method, and the measurement is performed relative to the linear sliding of the main slide block in the measurement movement, so that the influence of longitudinal error caused by incomplete parallel of the plane of the linear guide rail and the working plane can be avoided; in the measurement form, compared with a vertical measurement rotor positioning pin, the inclination measurement reduces the measurement error caused by the photoelectric displacement sensor, and improves the measurement precision of the measurement mechanism.

Description

Driving mechanism zero setting device using grating ruler to assist measurement

Technical Field

The utility model relates to a machinery zero setting field, more specifically the utility model particularly relates to a help measuring actuating mechanism zero setting device with grating chi.

Background

The driving mechanism is provided with two zero marks of a mechanical zero position and an electric zero position. In the production process of the driving mechanism, the deviation between the mechanical zero position and the electrical zero position of the driving mechanism needs to be debugged, so that the deviation between the mechanical zero position and the electrical zero position meets the index requirement.

The electric zero position detection mainly detects the installation position and performance parameters of a zero position sensor installed in the driving mechanism, and utilizes a zero position signal measured by an electric appliance measuring element. In effect, this null is an artificially defined position relative to the mechanical null. The mechanical zero point is a machine reference zero point marked by a scale and other instruments on equipment, the other equipment is installed and operated by taking the point as a reference position, and the mainly used mechanical zero point is generally the initial position for marking the machine in a stop state.

The zero setting method of the driving mechanism comprises the following steps: the measuring element is fixed by measuring the digital '0' of the measuring element corresponding to the mechanical zero position, so that the mechanical zero position and the electrical zero position are at the same position, namely the two positions are coincident. But in reality, the mechanical zero position and the zero position of the measured value of the electrical encoder are difficult to coincide, and the data measured by the measuring element corresponding to the mechanical zero position is a range and has deviation. The offset is generally reduced by two methods, one of which is to improve the performance and mounting position accuracy of the zero sensor in the drive mechanism; and the other is that under the condition that the installation position and the performance of a zero position sensor in the driving mechanism are determined, the actual deviation is measured, and the driving mechanism is mechanically zeroed with high precision.

The current practice of drive mechanism zeroing is generally manual measurement and adjustment, with the main drawbacks:

firstly, the stability of manual measurement is not high, and the measurement accuracy is influenced;

secondly, because the difference value between the mechanical zero position and the electrical zero position is small, manual adjustment is very laborious;

thirdly, the high-precision zero setting of the driving mechanism is difficult to achieve through manual measurement and adjustment;

fourth, the work efficiency of measurement and adjustment is very low.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a solve the problem that current actuating mechanism zero set difficulty, rate of accuracy are not high, work efficiency is low, provided one kind and helped measuring actuating mechanism zero set device with grating chi, can be in actuating mechanism's production process, through the utility model discloses debug actuating mechanism's mechanical zero-bit, make mechanical zero-bit accord with the index requirement.

The utility model discloses a following technical scheme realizes above-mentioned purpose: the utility model provides an assist measuring actuating mechanism zero-setting device with grating chi, includes equipment fixing platform, rotation control mechanism, measuring mechanism, actuating mechanism, measuring mechanism install in the top of equipment fixing platform, measuring mechanism is used for measuring the actual deviation of actuating mechanism mechanical zero position, rotation control mechanism install in the equipment fixing platform above, actuating mechanism's input with rotation control mechanism's output is connected, rotation control mechanism is used for controlling actuating mechanism is rotatory and feedback rotation angle.

The equipment mounting platform comprises a supporting bracket, an adjustable supporting platform, a working platform, a mounting vertical frame and a positioning block.

The supporting bracket is stably erected on a ground plane, the number of the adjustable supporting platforms is three, the adjustable supporting platforms are respectively fixed at three different positions on the supporting bracket in a triangular mode, the working platform is placed on the three adjustable supporting platforms, a square groove is formed in the working platform, the positioning block is placed in the square groove of the working platform, and the number of the installation vertical frames is two and the installation vertical frames are respectively and symmetrically fixed on two sides of a transverse central axis on the working platform; in the working platform leveling process, the adjustable supporting platform is used as a main adjusting supporting point to support the working platform and determine the actual levelness of the working platform.

The rotation control mechanism comprises a first servo motor, a first speed reducer, a main shaft, a brake support, a first angle encoder, an expansion sleeve, an encoder transfer block, a universal joint, a torsion spring, a bottom plate and a first speed reducer support.

The first servo motor output end is connected with the input end of the first speed reducer, the first speed reducer is fixedly installed on the side face of the first speed reducer support, the bottom face of the first speed reducer support is installed on the bottom plate, the output end of the first speed reducer is connected with one end of the main shaft, the other end of the main shaft is connected with the universal joint switching block through expansion, the brake is installed on the main shaft, the brake is fixed on one side face of the brake support, the bottom face of the brake support is fixed on the bottom plate, the first angle encoder is installed at one end of the encoder switching block, the first angle encoder is fixed on the other side face of the brake support, one end of the universal joint is connected with the other end of the encoder switching block, the torsion spring is installed on the universal joint, one end of the torsion spring is connected with the input end of the universal joint, the other end of the torsion spring is connected with the output end of the universal joint, and the bottom plate is installed on the working platform; in the zero setting process, the first servo motor provides driving force for rotary motion, the main shaft is driven to rotate and drive the universal joint to rotate through the moment amplified by the first speed reducer and the rotating speed reduced, and the first angle encoder provides the actual rotating angle of the universal joint.

The measuring mechanism comprises a linear motion guiding device, an auxiliary measuring device and a displacement measuring device.

The linear motion guiding device comprises a supporting beam, a linear guide rail, a linear module main body, a linear module supporting frame, a linear module sliding block, a linear module servo motor, a driving lever and a linear guide rail sliding block. The linear module main body is fixed on the two linear module support frames, the side surfaces of the linear module support frames are fixed on one side surface of the support cross beam, the deflector rod is installed on the linear module sliding block, the linear guide rail is fixed on the support cross beam, the linear guide rail sliding block is installed on the linear guide rail, and the linear module servo motor is installed at one end of the linear module main body; in the measuring process, the supporting cross beam is fixed on the two mounting vertical frames; the linear module servo motor provides power for the transverse motion of the measuring mechanism, the linear module sliding block drives the shifting rod to move, and the linear guide rail provides guide for the transverse motion of the measuring mechanism.

The auxiliary measuring device comprises a grating ruler guide rail, a grating ruler slide block and a grating ruler support frame. The grating scale guide rail is arranged on the grating scale support frame, the grating scale sliding block is arranged on the grating scale guide rail, one end of the grating scale sliding block is fixedly connected with one side of the main sliding block, and the grating scale support frame is fixed on the support cross beam; in the measurement engineering, along with the movement of the grating ruler slide block, the working position of the measurement mechanism can be positioned in real time.

The displacement measuring device comprises a main sliding block, a counterweight frame, a counterweight, a second servo motor, a second reducer support, a coupler, a rotating shaft, a linear bearing seat, a second angle encoder support, a second angle encoder, an optical shaft seat, an optical shaft connecting block, an optical shaft counterweight, a photoelectric displacement sensor and a photoelectric displacement sensor mounting plate. The output end of the second servo motor is connected with the input end of the second speed reducer, the second speed reducer is fixed on a second speed reducer support, the second speed reducer support is installed on the main sliding block, the output end of the second speed reducer is connected with one end of the coupler, the other end of the coupler is connected with one end of the rotating shaft, the other end of the rotating shaft penetrates through the linear bearing seat and the second angle encoder to be fixedly connected with the optical axis switching block, the counterweight frame is installed on the main sliding block, the counterweight is placed on the counterweight frame, the linear bearing seat is fixed on the main sliding block, the second angle encoder is fixed on the side surface of the second angle encoder support, the bottom surface of the second angle encoder support is fixed on the main sliding block, and the optical axis counterweight is placed on one side of the optical axis switching block, the optical axis is fixed on the other side of the optical axis switching block, the optical axis is installed on the two optical axis seats, the two optical axis seats are both fixed on one surface of the photoelectric displacement sensor installation plate, and the photoelectric displacement sensor is fixed on the other surface of the photoelectric displacement sensor installation plate; in the measuring process, the driving lever drives the main sliding block to do linear motion, and the photoelectric displacement sensor follows the main sliding block to do linear motion; the second servo motor provides driving force for rotary motion, the torque is amplified and the rotating speed is reduced through the second speed reducer, the rotating shaft is driven to rotate, the photoelectric displacement sensor rotates along with the rotating shaft, and the second angle encoder provides the actual rotating angle of the rotating shaft.

The driving mechanism comprises a driving mechanism rotor and a driving mechanism stator. Two rotor positioning pins are arranged on the driving mechanism rotor, and the driving mechanism stator is arranged on the working platform; in the zero setting process, when the universal joint drives the driving mechanism rotor to rotate, the rotor positioning pin moves along with the driving mechanism rotor.

Furthermore, a torsional spring is installed on the universal joint, one end of the torsional spring is connected with the input end of the universal joint, the other end of the torsional spring is connected with the output end of the universal joint, and the transmission backlash of the input end and the output end of the universal joint is eliminated.

Further, the cross section of the optical axis is in a combination of a semicircular shape and a rectangular shape, and the cross section is used for limiting the longitudinal rotation freedom degree of the optical axis.

Furthermore, a square notch is formed in one side of the main sliding block, and one end of the driving lever is spherical and is arranged in the square notch of the main sliding block. In the measuring process, the driving lever drives the main sliding block to do linear motion, and the spherical end is in point-surface contact with the square notch, so that errors caused by longitudinal jumping from the driving lever to the main sliding block are eliminated.

Furthermore, one end of the driving mechanism rotor is provided with two cylindrical rotor positioning pins symmetrically arranged at the rotation center of the driving mechanism.

A zero setting method for a driving mechanism assisting measurement by using a grating ruler specifically comprises the following steps:

the method comprises the following steps: adjusting the adjustable bolts in the three adjustable supporting platforms to enable the working platform to be horizontal;

step two: loosening a screw for fixing the optical axis on the optical axis connecting block to enable the optical axis to move longitudinally; adjusting the height of an optical axis until the photoelectric displacement sensor can measure the upper plane of the working platform; then, a screw used for fixing the optical axis on the optical axis rotating block is screwed down, so that the optical axis cannot move longitudinally;

step three: driving a second servo motor to enable the photoelectric displacement sensor to rotate along with the rotating shaft; the photoelectric displacement sensor measures the distance between the photoelectric displacement sensor and the working plane in the rotation process of the photoelectric displacement sensor, and calculates the rotation angle required by the movement of the photoelectric displacement sensor to the shortest distance from the photoelectric displacement sensor to the working plane by combining angle data fed back by the second angle encoder; continuously driving a second servo motor to enable the position of a light beam of the photoelectric displacement sensor to be vertical to the upper plane of the working platform;

step four: loosening a screw for fixing the optical axis on the optical axis connecting block to enable the optical axis to move longitudinally; adjusting the height of the optical axis until the photoelectric displacement sensor is higher than the top of the driving mechanism;

step five: the driving mechanism is placed on the working platform by depending on a positioning block on the working platform so as to be convenient to install; fixedly connecting a rotor of the driving mechanism with the output end of a universal joint of the rotary control mechanism; fixing the stator of the driving mechanism on the working platform by using screws;

step six: loosening a screw for fixing the optical axis on the optical axis connecting block to enable the optical axis to move longitudinally; adjusting the height of an optical axis until the photoelectric displacement sensor can measure two rotor positioning pins on a rotor of the driving mechanism; then, a screw used for fixing the optical axis on the optical axis rotating block is screwed down, so that the optical axis cannot move longitudinally;

step seven: driving a linear module servo motor to enable a linear module sliding block to drive a main sliding block on a linear guide rail to move; the photoelectric displacement sensor makes linear motion along with a main sliding block on the linear guide rail; meanwhile, recording the positions of the grating ruler slide blocks when the photoelectric displacement sensor detects two mover positioning pins on the mover of the driving mechanism according to the grating ruler guide rails; calculating to obtain the actual central position of the driving mechanism, and enabling the photoelectric displacement sensor to detect that the light spot moves to the central position of the driving mechanism;

step eight: the output end of the second servo motor amplifies the output torque and reduces the output rotating speed through a second speed reducer to drive the rotating shaft to rotate, so that a second angle encoder and the optical axis switching block on the rotating shaft are driven to rotate; the photoelectric displacement sensor rotates along with the rotating shaft, and meanwhile, the second angle encoder feeds back the actual rotating angle in real time; when the photoelectric displacement sensor detects a rotor positioning pin on a rotor of the driving mechanism, immediately stopping the second servo motor and recording the distance between the photoelectric displacement sensor and the rotor positioning pin and the rotation angle fed back by the second angle encoder; the second servo motor is driven reversely, when the photoelectric displacement sensor detects another rotor positioning pin on the rotor of the driving mechanism, the second servo motor is immediately stopped, and the distance between the photoelectric displacement sensor and the rotor positioning pin and the rotation angle fed back by the second angle encoder are recorded;

step nine: driving a second servo motor to enable the photoelectric displacement sensor to detect that the light spot moves to the central position of the driving mechanism;

step ten: calculating to obtain an angle theta required by the rotor to rotate when the driving mechanism is adjusted to zero, driving a first servo motor of the rotation control mechanism, amplifying output torque and reducing output rotating speed by an output end of the first servo motor through a first speed reducer, and driving the main shaft to rotate so as to drive a first angle encoder and a universal joint on the main shaft to rotate; the universal joint drives a rotor of the driving mechanism to rotate, and meanwhile, the first angle encoder feeds back the actual rotating angle of the universal joint in real time; when the rotation angle fed back by the first angle encoder is theta, immediately stopping rotating the first servo motor of the control mechanism;

step eleven: checking whether the mechanical zero position of the driving mechanism meets the requirement, and repeating the steps eight to ten until the mechanical zero position of the driving mechanism meets the requirement;

step twelve: unloading the driving mechanisms which are subjected to mechanical zero setting, and repeating the fifth step to the eleventh step on the driving mechanisms to be subjected to mechanical zero setting until all the driving mechanisms are subjected to mechanical zero setting;

step thirteen: all objects are either zeroed or zeroed.

Further, the method for calculating θ in the step ten is as follows: before the measurement process, the target mechanical zero position of the driving mechanism is that two rotor positioning pins are positioned on the same horizontal line, the rotor positioning pin positioned on the left side is a, the rotor positioning pin positioned on the right side is b, in the measurement process, position data provided by the grating ruler slide block and measurement data of the photoelectric displacement sensor are both related to time, and the absolute positions of the grating ruler slide block on the grating ruler guide rail are respectively X when the photoelectric displacement sensor measures the two rotor positioning pins_a、X_bWhen the photoelectric displacement sensor detects that the light spot moves to the central position of the driving mechanism, the position of the sliding block of the grating ruler is determined as

X_o＝(X_a-X_b) 2; the photoelectric displacement sensor measures and records the distance between two rotor positioning pins on a rotor of the driving mechanism and the photoelectric displacement sensor, and the second angle encoder records that the rotation angle of the photoelectric displacement sensor from the central position of the driving mechanism to the rotor positioning pin a is theta_abThe rotation angle from the rotor positioning pin a to the rotor positioning pin b is theta_abThe angle theta of the photoelectric displacement sensor which needs to rotate when the photoelectric displacement sensor returns to the central position of the driving mechanism can be obtained_bo＝θ_ab-θ_oa(ii) a The distances between the two rotor positioning pins and the photoelectric displacement sensor are respectively d_a、d_b. The angle that the two rotor positioning pins rotate to the horizontal position and the rotor of the driving mechanism needs to rotate can be obtained

When the angle is positive, the rotor of the driving mechanism is rotated clockwise; and when the angle is negative, the rotor of the driving mechanism is rotated anticlockwise.

The beneficial effects of the utility model reside in that:

1) the utility model adds three adjustable supporting platforms between the working platform and the supporting bracket, and adjusts the adjustable bolts of the adjustable supporting platforms to adjust the levelness of the working platform, so that the working platform is in the horizontal state;

2) the utility model adopts the holding connection at the connection part of the optical axis and the optical axis switching block, realizes the tightness by the locking mode of the screw, and ensures that the measuring height of the measuring mechanism can be freely adjusted;

3) the utility model adopts the linear module to control the main slide block to do transverse motion and the second servo motor to control the photoelectric displacement sensor to do rotary motion, thereby improving the automation level of the measuring process;

4) the utility model adopts the first servo motor of the rotation control mechanism to control the rotation motion of the driving mechanism, thereby improving the automation level of the zeroing process;

5) the utility model adopts the contact mode that the spherical end of the deflector rod on the linear module slider is in point-surface contact with the square notch of the main slider, compared with the mode that the linear module slider is directly and rigidly connected with the main slider, the error generated by the longitudinal displacement of the main slider due to jumping during the motion of the linear module slider is eliminated, and the measurement precision of the measuring mechanism is improved;

6) the utility model adopts the main slider to be added with the counterweight bracket, and the counterweight bracket is added with the counterweight to increase the pretightening force, thereby improving the stability of the main slider in the moving process and ensuring the measuring precision of the measuring mechanism;

7) the utility model adds the first angle encoder on the main shaft to feed back the actual rotation angle of the main shaft, thereby realizing closed-loop control; and a torsion spring is added on the universal joint to eliminate the rotation gap of the universal joint; when the first servo motor of the rotation control mechanism stops driving, the rotation of the main shaft is stopped in time by the brake. The rotation control mechanism can realize the high-precision control of the rotation angle of the universal joint;

8) the utility model discloses a grating ruler carries out absolute positioning to the main slide block when doing the transverse motion process, in the measuring process, because the positional data that the grating ruler provided and photoelectric displacement sensor's measured data all are relevant with the time, can confirm photoelectric displacement sensor absolute position on grating ruler when measuring two active cell locating pins indirectly, thereby confirmed the actual central point of actuating mechanism and put, guaranteed photoelectric displacement sensor operating position's accuracy;

9) the utility model adds the second angle encoder on the rotating shaft to feed back the actual rotating angle of the rotating shaft, thus realizing the high-precision control of the rotating shaft rotating angle by the measuring mechanism;

10) the utility model adds a counter weight on one side of the optical axis switching block, which improves the rotation stability of the rotating shaft;

11) the utility model adopts the rotation measurement method, and the measurement is performed relative to the linear sliding of the main slide block in the measurement movement, so that the influence of longitudinal error caused by incomplete parallel of the plane of the linear guide rail and the working plane can be avoided; in the measurement form, compared with a vertical measurement rotor positioning pin, the inclination measurement reduces the measurement error caused by the photoelectric displacement sensor, and improves the measurement precision of the measurement mechanism.

Drawings

Fig. 1 is a schematic diagram of the whole structure of the driving mechanism zero setting device using the grating ruler to assist the measurement.

Fig. 2 is a schematic structural diagram of the equipment mounting platform of the present invention.

Fig. 3 is a schematic structural diagram of the rotation control mechanism of the present invention.

Fig. 4 is a schematic structural diagram of the measuring mechanism of the present invention.

Fig. 5 is a schematic structural view of the linear motion guide device of the present invention.

Fig. 6 is a schematic structural diagram of the auxiliary measuring device of the present invention.

Fig. 7 is a schematic structural diagram of the displacement measuring device of the present invention.

Fig. 8 is a schematic structural diagram of the driving mechanism of the present invention.

In the figure: 1-equipment mounting platform; 11-a support bracket; 12-an adjustable support table; 13-a working platform; 14-installing a vertical frame; 15-positioning blocks; 2-a rotation control mechanism; 21-a first servo motor; 22-a first reducer; 23-a main shaft; 24-a brake; 25-a brake carrier; 26-a first angle encoder; 27-expanding the sleeve; 28-encoder switching block; 29-universal joint; 210-torsion spring; 211-a base plate; 212-first reducer carrier; 3-a measuring mechanism; 31-linear motion guide means; 311-a support beam; 312-linear guide rail; 313-a linear module body; 314-linear module support; 315-linear module slider; 316-linear module servo motor; 317-a deflector rod; 318-linear guide slider; 32-auxiliary measuring means; 321-grating ruler guide rails; 322-grating ruler slide block; 323-grating ruler support frame; 33-displacement measuring means; 331-linear bearing seats; 332-a second retarder carrier; 333-a second servo motor; 334-a second reducer; 335-a coupling; 336-a rotating shaft; 337-counterweight frame; 338-a counterweight; 339-optical axis; 3310-optical axis counterweight; 3311-optical axis junction block; 3312-optical axis seat; 3313-photoelectric displacement sensor mounting plate; 3314-photoelectric displacement sensor; 3315-a second angular encoder; 3316-second angular encoder mount; 3317-main slide; 4-a drive mechanism; 41-a drive mechanism mover; 410-rotor positioning pins; 42-drive mechanism stator.

Detailed Description

The present invention will be further explained with reference to the accompanying drawings:

as shown in fig. 1 to 8, a device for high-precision measurement and zero adjustment of a driving mechanism includes an equipment mounting platform 1, a rotation control mechanism 2, a measurement mechanism 3, and a driving mechanism 4, wherein the measurement mechanism 3 is mounted above the equipment mounting platform 1, the measurement mechanism 3 is used for measuring an actual zero offset of a mechanical zero position of the driving mechanism 4, the rotation control mechanism 2 is mounted on the equipment mounting platform 1, an input end of the driving mechanism 4 is connected with an output end of the rotation control mechanism 2, and the rotation control mechanism 2 is used for controlling the driving mechanism 4 to rotate and feeding back a rotation angle.

The equipment mounting platform 1 comprises a support bracket 11, an adjustable support platform 12, a working platform 13, a mounting stand 14 and a positioning block 15.

The supporting bracket 11 is stably erected on the ground plane, the number of the adjustable supporting platforms 12 is three, the adjustable supporting platforms are respectively fixed at three different positions on the supporting bracket 11 in a triangular mode, the working platform 13 is placed on the three adjustable supporting platforms 12, a square groove is formed in the working platform 13, the positioning block 15 is placed in the square groove of the working platform 13, and the number of the installation vertical frames 14 is two, and the two installation vertical frames are respectively and symmetrically fixed on two sides of the transverse central axis on the working platform 13; in the leveling process of the working platform 13, the adjustable supporting platform 12 serves as a main adjusting supporting point to support the working platform 13 and determine the actual levelness of the working platform 13.

The rotation control mechanism 2 includes a first servo motor 21, a first speed reducer 22, a spindle 23, a brake 24, a brake bracket 25, a first angle encoder 26, an expansion sleeve 27, an encoder transfer block 28, a universal joint 29, a torsion spring 210, a base plate 211, and a first speed reducer bracket 212.

The output end of the first servo motor 21 is connected with the input end of the first speed reducer 22, the first speed reducer 22 is fixedly installed on the side surface of the first speed reducer support 212, the bottom surface of the first speed reducer support 212 is installed on the bottom plate 211, the output end of the first speed reducer 22 is connected with one end of the main shaft 23, the other end of the main shaft 23 is connected with the universal joint 29 transfer block through the expansion sleeve 27, the brake 24 is installed on the main shaft 23, the brake 24 is fixed on one side surface of the brake support 25, the bottom surface of the brake support 25 is fixed on the bottom plate 211, the first angle encoder 26 is installed at one end of the encoder transfer block 28, the first angle encoder 26 is fixed on the other side surface of the brake support 25, one end of the universal joint 29 is connected with the other end of the encoder transfer block 28, the torsion spring 210 is installed on the universal joint 29, one end of the torsion spring 210 is connected with the input end of the universal joint 29, the other end of the torsion spring 210 is connected with the output end of the universal joint 29, and the bottom plate 211 is installed on the working platform 13; during the zero setting process, the first servo motor 21 provides a driving force for a rotational motion, the first speed reducer 22 amplifies the moment and reduces the rotational speed, the spindle 23 is driven to rotate and drives the universal joint 29 to rotate, and the first angle encoder 26 provides an actual rotating angle of the universal joint 29.

The measuring mechanism 3 includes a linear motion guide device 31, an auxiliary measuring device 32, and a displacement measuring device 33.

The linear motion guide device 31 includes a support beam 311, a linear guide 312, a linear module main body 313, a linear module support frame 314, a linear module slider 315, a linear module servo motor 316, a shift lever 317, and a linear guide slider 318. The linear module main body 313 is fixed on the two linear module support frames 314, the side surfaces of the linear module support frames 314 are fixed on one side surface of the support beam 311, the shift lever 317 is installed on the linear module slider 315, the linear guide rail 312 is fixed on the support beam 311, the linear guide rail slider 318 is installed on the linear guide rail 312, and the linear module servo motor 316 is installed at one end of the linear module main body 313; during the measurement, the supporting beam 311 is fixed on the two mounting stands 14; the linear module servo motor 316 provides power for the lateral movement of the measuring mechanism 3, the linear module sliding block 315 drives the shift lever 317 to move, and the linear guide rail 312 provides guidance for the lateral movement of the measuring mechanism 3.

The auxiliary measuring device 32 comprises a grating ruler guide rail 321, a grating ruler slide block 322 and a grating ruler support frame 323. The grating scale guide rail 321 is mounted on the grating scale support frame 323, the grating scale slide block 322 is mounted on the grating scale guide rail 321, one end of the grating scale slide block 322 is fixedly connected with one side of the main slide block 3317, and the grating scale support frame 323 is fixed on the support beam 311; in the measurement process, along with the movement of the grating ruler slide block 322, the working position of the measuring mechanism 3 can be positioned in real time.

The displacement measuring device 33 includes a main slide block 3317, a weight holder 337, a weight 338, a second servo motor 333, a second reducer 334, a second reducer holder 332, a coupling 335, a rotating shaft 336, a linear bearing base 331, a second angle encoder holder 3316, a second angle encoder 3315, an optical axis 339, an optical axis holder 3312, an optical axis adapter 3311, an optical axis weight 3310, a photoelectric displacement sensor 3314, and a photoelectric displacement sensor mounting plate 3313. The output end of the second servo motor 333 is connected to the input end of the second speed reducer 334, the second speed reducer 334 is fixed to a second speed reducer support 332, the second speed reducer support 332 is mounted on the main slide block 3317, the output end of the second speed reducer 334 is connected to one end of the coupling 335, the other end of the coupling 335 is connected to one end of the rotating shaft 336, the other end of the rotating shaft 336 passes through the linear bearing seat 331 and the second angle encoder 3315 to be fixedly connected to the optical axis adapter block 3311, the weight holder 337 is mounted on the main slide block 3317, the weight 338 is placed on the weight holder 337, the linear bearing seat 331 is fixed on the main slide block 3317, the second angle encoder 3315 is fixed on the side surface of the second angle encoder support 3316, and the bottom surface of the second angle encoder support 3316 is fixed on the main slide block 3317, the optical axis counterweight 3310 is disposed on one side of the optical axis adapting block 3311, the optical axis 339 is fixed on the other side of the optical axis adapting block 3311, the optical axis 339 is installed on the two optical axis bases 3312, the two optical axis bases 3312 are both fixed on one surface of the photoelectric displacement sensor mounting plate 3313, and the photoelectric displacement sensor 3314 is fixed on the other surface of the photoelectric displacement sensor mounting plate 3313; in the measuring process, the shift lever 317 drives the main slide block 3317 to make a linear motion, and the photoelectric displacement sensor 3314 makes a linear motion along with the main slide block 3317; the second servo motor 333 provides a driving force for a rotational motion, amplifies a moment and reduces a rotational speed through the second reducer 334 to drive the rotation shaft 336 to rotate, the photoelectric displacement sensor 3314 performs a rotational motion with the rotation shaft 336, and the second angle encoder 3315 provides an actual rotational angle of the rotation shaft 336.

The drive mechanism 4 includes a drive mechanism mover 41 and a drive mechanism stator 42. Two rotor positioning pins 410 are arranged on the driving mechanism rotor 41, and the driving mechanism stator 42 is installed on the working platform 13; in the zero setting process, when the universal joint 29 drives the driving mechanism rotor 41 to rotate, the rotor positioning pin 410 moves along with the driving mechanism rotor 41.

Furthermore, a torsion spring 210 is installed on the universal joint 29, one end of the torsion spring 210 is connected with the input end of the universal joint 29, the other end of the torsion spring 210 is connected with the output end of the universal joint 29, and the transmission backlash of the input end and the output end of the universal joint 29 is eliminated.

Further, the cross-sectional shape of the optical axis 339 is a combination of a semicircular shape and a rectangular shape, and is used for limiting the longitudinal rotation freedom of the optical axis 339.

Further, a square notch is formed in one side of the main slider 3317, and one end of the shift lever 317 is spherical and is disposed in the square notch of the main slider 3317. In the measuring process, the shift lever 317 drives the main slide block 3317 to make a linear motion, and the spherical end makes point-surface contact with the square notch, so that the error caused by the longitudinal jump from the shift lever 317 to the main slide block 3317 is eliminated.

Further, one end of the driving mechanism mover 41 is provided with two cylindrical mover positioning pins 410 symmetrically to the rotation center of the driving mechanism 4.

A measuring method for measuring mechanical zero error of a driving mechanism 4 and performing mechanical zero fading specifically comprises the following steps:

the method comprises the following steps: adjusting the adjustable bolts in the three adjustable support tables 12 to enable the working platform 13 to be horizontal;

step two: loosening a screw for fixing the optical axis 339 on the optical axis connecting block 3311 to allow the optical axis 339 to move longitudinally; adjusting the height of the optical axis 339 until the photoelectric displacement sensor 3314 can measure the upper plane of the working platform 13; then, the screw for fixing the optical axis 339 on the optical axis adapting block 3311 is tightened, so that the optical axis 339 cannot move longitudinally;

step three: driving the second servo motor 333 to rotate the photoelectric displacement sensor 3314 with the rotary shaft 336; the photoelectric displacement sensor 3314 measures the distance between the photoelectric displacement sensor 3314 and the working plane during rotation, and calculates the rotation angle required for the photoelectric displacement sensor 3314 to move to the shortest distance from the working plane in combination with the angle data fed back by the second angle encoder 3315; continuing to drive the second servo motor 333 to make the beam position of the photoelectric displacement sensor 3314 vertical to the upper plane of the working platform 13;

step four: loosening a screw for fixing the optical axis 339 on the optical axis connecting block 3311 to allow the optical axis 339 to move longitudinally; adjusting the height of the optical axis 339 until the photoelectric displacement sensor 3314 is higher than the top of the driving mechanism 4;

step five: the driving mechanism 4 is placed on the working platform 13 by relying on a positioning block 15 on the working platform 13 so as to be convenient to install; fixedly connecting a driving mechanism rotor 41 with the output end of a universal joint 29 of the rotary control mechanism 2; fixing the driving mechanism stator 42 on the working platform 13 by using screws;

step six: loosening a screw for fixing the optical axis 339 on the optical axis connecting block 3311 to allow the optical axis 339 to move longitudinally; adjusting the height of the optical axis 339 until the photoelectric displacement sensor 3314 can measure two mover positioning pins 410 on the driving mechanism mover 41; then, the screw for fixing the optical axis 339 on the optical axis adapting block 3311 is tightened, so that the optical axis 339 cannot move longitudinally;

step seven: driving the linear module servo motor 316 to make the linear module slider 315 drive the main slider 3317 on the linear guide rail 312 to move; the photoelectric displacement sensor 3314 moves linearly along with the main slide block 3317 on the linear guide rail 312; meanwhile, the positions of the grating ruler slide block 322 when the photoelectric displacement sensor 3314 detects two mover positioning pins 410 on the driving mechanism mover 41 are recorded according to the grating ruler guide rail 321; calculating to obtain the actual central position of the driving mechanism 4, and moving the light spot detected by the photoelectric displacement sensor 3314 to the central position of the driving mechanism 4;

step eight: the second servo motor 333 is driven, and the output end of the second servo motor 333 amplifies the output torque and reduces the output rotation speed through the second reducer 334 to drive the rotation shaft 336 to rotate, thereby driving the second angle encoder 3315 and the optical axis adapter 3311 on the rotation shaft 336 to rotate; the photoelectric displacement sensor 3314 rotates along with the rotating shaft 336, and the second angle encoder 3315 feeds back the actual rotating angle in real time; when the photoelectric displacement sensor 3314 detects one mover positioning pin 410 on the mover 41 of the driving mechanism, immediately stopping the second servo motor 333 and recording the distance between the photoelectric displacement sensor 3314 and the mover positioning pin 410 and the rotation angle fed back by the second angle encoder 3315; the second servo motor 333 is driven reversely, when the photoelectric displacement sensor 3314 detects another mover positioning pin 410 on the driving mechanism mover 41, the second servo motor 333 is immediately stopped and the distance between the photoelectric displacement sensor 3314 and the mover positioning pin 410 and the rotation angle fed back by the second angle encoder 3315 are recorded;

step nine: the second servo motor 333 is driven to move the light spot detected by the photoelectric displacement sensor 3314 to the center position of the driving mechanism 4;

step ten: calculating to obtain an angle theta of the rotor required to rotate when the driving mechanism 4 is zeroed, driving a first servo motor 21 of the rotation control mechanism 2, amplifying output torque and reducing output rotating speed of an output end of the first servo motor 21 through a first speed reducer 22, and driving a main shaft 23 to rotate so as to drive a first angle encoder 26 and a universal joint 29 on the main shaft 23 to rotate; the universal joint 29 drives the driving mechanism rotor 41 to rotate, and meanwhile, the first angle encoder 26 feeds back the actual rotating angle of the universal joint 29 in real time; when the rotation angle fed back by the first angle encoder 26 is θ, immediately stopping the first servo motor 21 of the rotation control mechanism 2;

step eleven: checking whether the mechanical zero position of the driving mechanism 4 meets the requirement, and repeating the steps eight to ten until the mechanical zero position of the driving mechanism 4 meets the requirement;

step twelve: unloading the driving mechanisms 4 which are mechanically zeroed, and repeating the fifth step to the eleventh step on the driving mechanisms 4 to be mechanically zeroed until all the driving mechanisms 4 are mechanically zeroed;

step thirteen: all objects are either zeroed or zeroed.

Before the measurement process, the target mechanical zero position of the driving mechanism 4 is that the two mover positioning pins 410 are in the same horizontal line. For convenience of explanation and calculation, a is set as the mover positioning pin 410 located on the left side, and b is set as the mover positioning pin 410 located on the right side. In the measurement process, because the position data provided by the linear scale slider 322 and the measurement data of the photoelectric displacement sensor 3314 are both related to time, it can be indirectly determined that the absolute positions of the linear scale slider 322 on the linear scale guide rail 321 are X respectively when the photoelectric displacement sensor 3314 measures the two mover positioning pins 410_a、X_bWhen the photoelectric displacement sensor 3314 detects that the light spot moves to the center of the driving mechanism 4, the position of the grating ruler slide block 322 is determined to be X_o＝(X_a-X_b)/2. Photoelectric displacement sensor 3314The distance between the two mover positioning pins 410 of the mover 41 of the driving mechanism and the photoelectric displacement sensor 3314 is measured and recorded, and the rotation angle θ of the photoelectric displacement sensor 3314 from the center position of the driving mechanism 4 to the mover positioning pin a is recorded as the second angle encoder 3315_oaThe rotation angle from the rotor positioning pin a to the rotor positioning pin b is theta_abThe angle theta of the photoelectric displacement sensor 3314 required to rotate when returning to the center of the driving mechanism 4 can be obtained_bo＝θ_ab-θ_oa. Let the distances between the two mover positioning pins 410 and the photoelectric displacement sensor 3314 be d_a、d_b. The angle that the two rotor positioning pins 410 rotate to the horizontal position and the rotor 41 of the driving mechanism needs to rotate can be obtained

When the angle is positive, the driving mechanism mover 41 is rotated clockwise; when the angle is negative, the driving mechanism mover 41 is rotated counterclockwise.

The above-mentioned embodiment is only the preferred embodiment of the present invention, and is not to the limitation of the technical solution of the present invention, as long as the technical solution can be realized on the basis of the above-mentioned embodiment without creative work, all should be regarded as falling into the protection scope of the right of the present invention.

Claims (4)

1. A drive mechanism zero setting device using a grating ruler to assist measurement is characterized in that: the device comprises an equipment mounting platform, a rotation control mechanism, a measuring mechanism and a driving mechanism, wherein the measuring mechanism is mounted above the equipment mounting platform and used for measuring the actual deviation of the mechanical zero position of the driving mechanism;

the equipment mounting platform comprises a support bracket, an adjustable support platform, a working platform, a mounting vertical frame and a positioning block;

the supporting bracket is stably erected on a ground plane, the number of the adjustable supporting platforms is three, the adjustable supporting platforms are respectively fixed at three different positions on the supporting bracket in a triangular mode, the working platform is placed on the three adjustable supporting platforms, a square groove is formed in the working platform, the positioning block is placed in the square groove of the working platform, and the number of the installation vertical frames is two and the installation vertical frames are respectively and symmetrically fixed on two sides of a transverse central axis on the working platform; in the working platform leveling process, the adjustable supporting platform is used as a main adjusting supporting point to support the working platform and determine the actual levelness of the working platform;

the rotation control mechanism comprises a first servo motor, a first speed reducer, a main shaft, a brake support, a first angle encoder, an expansion sleeve, an encoder transfer block, a universal joint, a torsion spring, a bottom plate and a first speed reducer support;

the first servo motor output end is connected with the input end of the first speed reducer, the first speed reducer is fixedly installed on the side face of the first speed reducer support, the bottom face of the first speed reducer support is installed on the bottom plate, the output end of the first speed reducer is connected with one end of the main shaft, the other end of the main shaft is connected with the universal joint switching block through expansion, the brake is installed on the main shaft, the brake is fixed on one side face of the brake support, the bottom face of the brake support is fixed on the bottom plate, the first angle encoder is installed at one end of the encoder switching block, the first angle encoder is fixed on the other side face of the brake support, one end of the universal joint is connected with the other end of the encoder switching block, the torsion spring is installed on the universal joint, one end of the torsion spring is connected with the input end of the universal joint, the other end of the torsion spring is connected with the output end of the universal joint, and the bottom plate is installed on the working platform; in the zero setting process, the first servo motor provides driving force for rotary motion, the moment is amplified and the rotating speed is reduced through the first speed reducer, the main shaft is driven to rotate and the universal joint is driven to rotate, and the first angle encoder provides the actual rotating angle of the universal joint;

the measuring mechanism comprises a linear motion guiding device, an auxiliary measuring device and a displacement measuring device;

the linear motion guiding device comprises a supporting beam, a linear guide rail, a linear module main body, a linear module supporting frame, a linear module sliding block, a linear module servo motor, a deflector rod and a linear guide rail sliding block; the linear module main body is fixed on the two linear module support frames, the side surfaces of the linear module support frames are fixed on one side surface of the support cross beam, the deflector rod is installed on the linear module sliding block, the linear guide rail is fixed on the support cross beam, the linear guide rail sliding block is installed on the linear guide rail, and the linear module servo motor is installed at one end of the linear module main body; in the measuring process, the supporting cross beam is fixed on the two mounting vertical frames; the linear module servo motor provides power for the transverse motion of the measuring mechanism, the linear module sliding block drives the shifting rod to move, and the linear guide rail provides guide for the transverse motion of the measuring mechanism;

the auxiliary measuring device comprises a grating ruler guide rail, a grating ruler slide block and a grating ruler support frame; the grating scale guide rail is arranged on the grating scale support frame, the grating scale sliding block is arranged on the grating scale guide rail, one end of the grating scale sliding block is fixedly connected with one side of the main sliding block, and the grating scale support frame is fixed on the support cross beam; in the measurement engineering, along with the movement of the grating ruler slide block, the working position of the measurement mechanism can be positioned in real time;

the displacement measuring device comprises a main sliding block, a counterweight frame, a counterweight, a second servo motor, a second reducer support, a coupling, a rotating shaft, a linear bearing seat, a second angle encoder support, a second angle encoder, an optical shaft seat, an optical shaft connecting block, an optical shaft counterweight, a photoelectric displacement sensor and a photoelectric displacement sensor mounting plate; the output end of the second servo motor is connected with the input end of the second speed reducer, the second speed reducer is fixed on a second speed reducer support, the second speed reducer support is installed on the main sliding block, the output end of the second speed reducer is connected with one end of the coupler, the other end of the coupler is connected with one end of the rotating shaft, the other end of the rotating shaft penetrates through the linear bearing seat and the second angle encoder to be fixedly connected with the optical axis switching block, the counterweight frame is installed on the main sliding block, the counterweight is placed on the counterweight frame, the linear bearing seat is fixed on the main sliding block, the second angle encoder is fixed on the side surface of the second angle encoder support, the bottom surface of the second angle encoder support is fixed on the main sliding block, and the optical axis counterweight is placed on one side of the optical axis switching block, the optical axis is fixed on the other side of the optical axis switching block, the optical axis is installed on the two optical axis seats, the two optical axis seats are both fixed on one surface of the photoelectric displacement sensor installation plate, and the photoelectric displacement sensor is fixed on the other surface of the photoelectric displacement sensor installation plate; in the measuring process, the driving lever drives the main sliding block to do linear motion, and the photoelectric displacement sensor follows the main sliding block to do linear motion; the second servo motor provides driving force for rotary motion, torque is amplified and the rotating speed is reduced through the second speed reducer, the rotary shaft is driven to rotate, the photoelectric displacement sensor rotates along with the rotary shaft, and the second angle encoder provides the actual rotating angle of the rotary shaft;

the driving mechanism comprises a driving mechanism rotor and a driving mechanism stator; two rotor positioning pins are arranged on the driving mechanism rotor, and the driving mechanism stator is arranged on the working platform; in the zero setting process, when the universal joint drives the driving mechanism rotor to rotate, the rotor positioning pin moves along with the driving mechanism rotor.

2. The apparatus of claim 1, wherein the drive mechanism comprises a drive mechanism having a zero setting gauge, and wherein the drive mechanism comprises: the cross section of the optical axis is in a combined shape of a semicircle and a rectangle.

3. The apparatus of claim 1, wherein the drive mechanism comprises a drive mechanism having a zero setting gauge, and wherein the drive mechanism comprises: one side of the main sliding block is provided with a square notch, and one end of the driving lever is spherical and is arranged in the square notch of the main sliding block.

4. The apparatus of claim 1, wherein the drive mechanism comprises a drive mechanism having a zero setting gauge, and wherein the drive mechanism comprises: one end of the driving mechanism rotor is provided with two cylindrical rotor positioning pins symmetrically to the rotation center of the driving mechanism.

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