Multi-axis force sensor calibration method and calibration device

文档序号:1707112 发布日期:2019-12-13 浏览:21次 中文

阅读说明:本技术 一种多轴力传感器校准方法及校准装置 (Multi-axis force sensor calibration method and calibration device ) 是由 刘春风 刘训华 文帅 刘家骅 王金印 于 2019-07-31 设计创作,主要内容包括:本发明涉及一种多轴力传感器校准方法及校准装置,通过加载板实现力和力矩的分解,最终实现多轴力传感器的六分量载荷高精度协同加载,提高传感器校准的精度。本发明仅使用7个激光位移传感器即可获得多轴力传感器的全部位置姿态,装置便捷有效。能够在每次新传感器安装时,快速将新安装的多轴力传感器调整至指定基准,且能够保证所有安装的传感器安装位置一致,保证了校准基准一致性,大大提高不同批次传感器的一致性。应用本发明将传感器安装完毕后,可以在校准过程中实时监测传感器在不同载荷作用下的变形量,作为传感器的技术参数提供给使用者,该参数的获得方法,相比于有限元理论估算这一传统手段,更为真实,也更为精确。(The invention relates to a multi-axis force sensor calibration method and a multi-axis force sensor calibration device, which realize the decomposition of force and moment through a loading plate, finally realize the high-precision cooperative loading of six-component load of a multi-axis force sensor and improve the calibration precision of the sensor. According to the invention, all position postures of the multi-axis force sensor can be obtained only by using 7 laser displacement sensors, and the device is convenient and effective. The multi-axis force sensor can be quickly adjusted to an appointed reference when a new sensor is installed at every time, the installation positions of all installed sensors can be guaranteed to be consistent, the consistency of calibration references is guaranteed, and the consistency of sensors in different batches is greatly improved. After the sensor is installed, the deformation of the sensor under different loads can be monitored in real time in the calibration process and provided to a user as the technical parameter of the sensor.)

1. A multi-axis force sensor precision mounting method is characterized by comprising the following steps:

(1) mounting the multi-axis force sensor and a loading plate to the supporting device, wherein the loading plate is used for transferring the calibration load to the multi-axis force sensor; respectively installing a first target plate and a second target plate along the directions of a first horizontal shaft X and a second horizontal shaft Y of the loading plate; the first target plate comprises a horizontal plane and a vertical plane which are vertical to each other; a third target plate is arranged in a direction perpendicular to the first horizontal shaft X;

(2) the first laser displacement sensor and the second laser displacement sensor are arranged along the length direction of the first target plate at intervals, and emit laser, and the laser is reflected by the horizontal plane of the first target plate and then the distance between the first laser displacement sensor and the first target plate in the vertical direction is measured;

arranging third and fourth laser displacement sensors at intervals along the length direction of the first target plate, wherein the third and fourth laser displacement sensors emit laser, reflect the laser through the vertical surface of the first target plate and then measure the distance between the laser and the first target plate along the y direction of a first horizontal shaft;

Fifth and sixth laser displacement sensors are arranged along the length direction of the second target plate at intervals, and emit laser and measure the distance from the second target plate in the vertical direction after being reflected along the second target plate;

The seventh laser displacement sensor emits laser and measures the distance between the laser and the third target plate along the X direction of the first horizontal shaft after the laser is reflected along the third target plate;

(3) recording the readings of the first to seventh laser displacement sensors;

(4) and replacing the next multi-axis force sensor to be calibrated, adjusting the supporting device to enable the readings of the first to seventh laser displacement sensors to be consistent with the recorded values, completing installation and starting calibration.

2. The method for precision mounting of a multi-axis force transducer of claim 1 wherein the step (4) is repeated to complete the calibration of the same type of transducer.

3. the precision mounting method of the multi-axis force sensor as claimed in claim 1 or 2, wherein the first to seventh laser displacement sensors are fixedly mounted by a sensor bracket, and the sensor bracket is independent from the loading plate and the supporting device.

4. The precision mounting method of a multi-axis force sensor according to claim 1 or 2, wherein only the multi-axis force sensor is disassembled when the multi-axis force sensor to be calibrated is replaced in the step (4), and the assembling relationship between the load plate and the first to third target plates is maintained.

5. The multi-axis force transducer precision mounting method of claim 1 or 2, wherein the laser light emitted by the first and second laser displacement sensors in step (2) is perpendicular to the horizontal plane of the first target plate; the laser emitted by the third and fourth laser displacement sensors is vertical to the vertical surface of the first target plate; the laser emitted by the fifth laser displacement sensor and the laser emitted by the sixth laser displacement sensor are vertical to the plane of the second target plate; the laser emitted by the seventh laser displacement sensor is perpendicular to the plane of the third target plate.

6. A multi-axis force sensor precision calibration method is characterized by comprising the following steps:

(1) Mounting the multi-axis force sensor and a loading plate to the supporting device, wherein the loading plate is used for transferring the calibration load to the multi-axis force sensor; respectively installing a first target plate and a second target plate along the directions of a first horizontal shaft X and a second horizontal shaft Y of the loading plate; the first target plate comprises a horizontal plane and a vertical plane which are vertical to each other; a third target plate is arranged in a direction perpendicular to the first horizontal shaft X;

(2) the first laser displacement sensor and the second laser displacement sensor are arranged along the length direction of the first target plate at intervals, and emit laser, and the laser is reflected by the horizontal plane of the first target plate and then the distance between the first laser displacement sensor and the first target plate in the vertical direction is measured;

arranging third and fourth laser displacement sensors at intervals along the length direction of the first target plate, wherein the third and fourth laser displacement sensors emit laser, reflect the laser through the vertical surface of the first target plate and then measure the distance between the laser and the first target plate along the y direction of a first horizontal shaft;

fifth and sixth laser displacement sensors are arranged along the length direction of the second target plate at intervals, and emit laser and measure the distance from the second target plate in the vertical direction after being reflected along the second target plate;

the seventh laser displacement sensor emits laser and measures the distance between the laser and the third target plate along the X direction of the first horizontal shaft after the laser is reflected along the third target plate;

(3) Recording the readings of the first to seventh laser displacement sensors; completing the calibration of the current multi-axis force sensor;

(4) And (4) replacing the next multi-axis force sensor to be calibrated, and adjusting the supporting device to ensure that the readings of the first to seventh laser displacement sensors are consistent with the recorded values, so that the installation is completed, and the calibration is completed.

7. The multi-axis force transducer precision calibration method of claim 6, wherein the calibration method in steps (3) and (4) is as follows:

a. Reading d1 of the first to seventh laser displacement sensors0~d70

b. Applying a downward numerical load to the loading plate, and reading the readings d1 and d2 of the first laser displacement sensor and the second laser displacement sensor and the readings d5 and d6 of the fifth laser displacement sensor and the sixth laser displacement sensor; computing wherein L12 is the distance between the first and second laser displacement sensors, and L56 is the distance between the fifth and sixth laser displacement sensors, which can be measured actually; Δ d1 ═ d1-d10,Δd2=d2-d20,Δd5=d5-d50,Δd6=d6-d60

c. Applying a horizontal load to the loading plate, and reading the readings d3 and d4 of the third laser displacement sensor and the fourth laser displacement sensor; computingL34 is the distance between the third and fourth laser displacement sensors; Δ d3 ═ d3-d30,Δd4=d4-d40

d. and giving alpha, beta and gamma corresponding to the loading load as performance parameters of the multi-axis force sensor.

8. The multi-axis force transducer precision calibration method of claim 6 or 7, wherein the first to seventh laser displacement transducers are mounted and fixed by a transducer holder, and the transducer holder is independent of the load plate and the supporting device.

9. The multi-axis force sensor fine calibration method according to claim 6 or 7, wherein only the multi-axis force sensor is disassembled when the multi-axis force sensor to be calibrated is replaced in the step (4), and the assembly relationship between the loading plate and the first to third target plates is kept still.

10. The multi-axis force sensor precision calibration method of claim 6 or 7, wherein the laser light emitted by the first and second laser displacement sensors in step (2) is perpendicular to the horizontal plane of the first target plate; the laser emitted by the third and fourth laser displacement sensors is vertical to the vertical surface of the first target plate; the laser emitted by the fifth laser displacement sensor and the laser emitted by the sixth laser displacement sensor are vertical to the plane of the second target plate; the laser emitted by the seventh laser displacement sensor is perpendicular to the plane of the third target plate.

11. A calibration device used in the method for precisely calibrating a multi-axis force sensor according to any one of claims 6 to 10, comprising a loading plate having a rectangular shape; the loading plate is attached to the upper mounting surface of the multi-axis force sensor;

Setting a horizontal loading point at the center of one edge;

two symmetrical horizontal loading points are arranged on the opposite side of the edge;

The centers of two adjacent sides of the side are provided with horizontal loading points, and four angular points are respectively provided with vertical downward loading points;

The horizontal load points are used to apply outward forces in the horizontal direction and the vertically downward load points are used to apply vertically downward forces.

12. The calibration device of claim 11, wherein the symmetrical horizontal load points and the four vertically downward load points effect loading of the corresponding directional moment by applying an unbalanced force.

13. The calibration device according to claim 11, wherein the vertical downward loading point uses the weight to realize loading; the horizontal loading point converts the loading direction into vertical downward direction through the pulley, and the weight dead weight is utilized to realize loading.

Technical Field

The invention relates to a multi-axis force sensor calibration method and a multi-axis force sensor calibration device, which are used for avoiding calibration errors caused by different mounting states of different batches of sensors and belong to the field of force sensor application.

background

The multiaxial force sensor has great structural form difference according to different application occasions, for example, the common rod type structures of wind tunnel balances applied to wind tunnel tests are more, and the common hub type structures applied to the field of industrial robots are more. However, no matter what kind of field the multi-axis force sensor is applied to, calibration is required before the multi-axis force sensor is manufactured and put into practical use, and the corresponding relations between the three force components and the three moment components and the output signals are obtained.

the calibration of the force sensor comprises the core steps of mounting the sensor on a calibration table and applying various loads according to a certain loading method. The high-precision calibration result is the premise of high-precision grade of the sensor, and the high-precision installation method of the sensor during calibration is the premise of high-precision calibration of the sensor. Compared with a single-axis force sensor, the multi-axis force sensor has the advantages that the requirement on installation accuracy is much higher in the calibration process, especially, the installation error of an angle around an axis can cause one load component to generate interference on the other load component during loading, the loading accuracy of calibration is directly limited, and the accuracy grade of the multi-axis force sensor is reduced.

At present, in order to suppress the installation errors at home and abroad, a common method is to separately establish a calibration coordinate system for each calibration and adjust all loading devices to be consistent with the coordinate system. At present, a high-precision and quick mounting method is not available, which becomes a technical bottleneck restricting the batch precision calibration of the multi-axis force sensor.

Disclosure of Invention

The invention provides a multi-axis force sensor calibration method and a multi-axis force sensor calibration device aiming at the installation problem of the multi-axis force sensor when the multi-axis force sensor is precisely calibrated currently.

The purpose of the invention is realized by the following technical scheme:

Provided is a multi-axis force sensor precision mounting method, which comprises the following steps:

(1) Mounting the multi-axis force sensor and a loading plate to the supporting device, wherein the loading plate is used for transferring the calibration load to the multi-axis force sensor; respectively installing a first target plate and a second target plate along the directions of a first horizontal shaft X and a second horizontal shaft Y of the loading plate; the first target plate comprises a horizontal plane and a vertical plane which are vertical to each other; a third target plate is arranged in a direction perpendicular to the first horizontal shaft X;

(2) The first laser displacement sensor and the second laser displacement sensor are arranged along the length direction of the first target plate at intervals, and emit laser, and the laser is reflected by the horizontal plane of the first target plate and then the distance between the first laser displacement sensor and the first target plate in the vertical direction is measured;

arranging third and fourth laser displacement sensors at intervals along the length direction of the first target plate, wherein the third and fourth laser displacement sensors emit laser, reflect the laser through the vertical surface of the first target plate and then measure the distance between the laser and the first target plate along the y direction of a first horizontal shaft;

fifth and sixth laser displacement sensors are arranged along the length direction of the second target plate at intervals, and emit laser and measure the distance from the second target plate in the vertical direction after being reflected along the second target plate;

the seventh laser displacement sensor emits laser and measures the distance between the laser and the third target plate along the X direction of the first horizontal shaft after the laser is reflected along the third target plate;

(3) recording the readings of the first to seventh laser displacement sensors;

(4) And replacing the next multi-axis force sensor to be calibrated, adjusting the supporting device to enable the readings of the first to seventh laser displacement sensors to be consistent with the recorded values, completing installation and starting calibration.

Preferably, the step (4) is repeated to complete the calibration of the same type of sensor.

Preferably, the first to seventh laser displacement sensors are fixedly mounted through a sensor bracket, and the sensor bracket is independent of the loading plate and the supporting device.

Preferably, only the multi-axis force sensor is disassembled when the multi-axis force sensor to be calibrated is replaced in the step (4), and the assembling relation between the loading plate and the first target plate to the third target plate is kept still.

Preferably, the laser emitted by the first and second laser displacement sensors in step (2) is perpendicular to the horizontal plane of the first target plate; the laser emitted by the third and fourth laser displacement sensors is vertical to the vertical surface of the first target plate; the laser emitted by the fifth laser displacement sensor and the laser emitted by the sixth laser displacement sensor are vertical to the plane of the second target plate; the laser emitted by the seventh laser displacement sensor is perpendicular to the plane of the third target plate.

Meanwhile, a multi-axis force sensor precision calibration method is provided, which comprises the following steps:

(1) mounting the multi-axis force sensor and a loading plate to the supporting device, wherein the loading plate is used for transferring the calibration load to the multi-axis force sensor; respectively installing a first target plate and a second target plate along the directions of a first horizontal shaft X and a second horizontal shaft Y of the loading plate; the first target plate comprises a horizontal plane and a vertical plane which are vertical to each other; a third target plate is arranged in a direction perpendicular to the first horizontal shaft X;

(2) The first laser displacement sensor and the second laser displacement sensor are arranged along the length direction of the first target plate at intervals, and emit laser, and the laser is reflected by the horizontal plane of the first target plate and then the distance between the first laser displacement sensor and the first target plate in the vertical direction is measured;

Arranging third and fourth laser displacement sensors at intervals along the length direction of the first target plate, wherein the third and fourth laser displacement sensors emit laser, reflect the laser through the vertical surface of the first target plate and then measure the distance between the laser and the first target plate along the y direction of a first horizontal shaft;

fifth and sixth laser displacement sensors are arranged along the length direction of the second target plate at intervals, and emit laser and measure the distance from the second target plate in the vertical direction after being reflected along the second target plate;

the seventh laser displacement sensor emits laser and measures the distance between the laser and the third target plate along the X direction of the first horizontal shaft after the laser is reflected along the third target plate;

(3) Recording the readings of the first to seventh laser displacement sensors; completing the calibration of the current multi-axis force sensor;

(4) and (4) replacing the next multi-axis force sensor to be calibrated, and adjusting the supporting device to ensure that the readings of the first to seventh laser displacement sensors are consistent with the recorded values, so that the installation is completed, and the calibration is completed.

Preferably, the calibration method in steps (3) and (4) is as follows:

a. reading d1 of the first to seventh laser displacement sensors0~d70

b. Applying a downward numerical load to the loading plate, and reading the readings d1 and d2 of the first laser displacement sensor and the second laser displacement sensor and the readings d5 and d6 of the fifth laser displacement sensor and the sixth laser displacement sensor; computing Wherein L12 is the distance between the first and second laser displacement sensors, and L56 is the distance between the fifth and sixth laser displacement sensors, which can be measured actually; Δ d1 ═ d1-d10,Δd2=d2-d20,Δd5=d5-d50,Δd6=d6-d60

c. Applying a horizontal load to the loading plate, and reading the readings d3 and d4 of the third laser displacement sensor and the fourth laser displacement sensor; computingl34 is the distance between the third and fourth laser displacement sensors; Δ d3 ═ d3-d30,Δd4=d4-d40

d. and giving alpha, beta and gamma corresponding to the loading load as performance parameters of the multi-axis force sensor.

Preferably, the first to seventh laser displacement sensors are fixedly mounted through a sensor bracket, and the sensor bracket is independent of the loading plate and the supporting device.

Preferably, only the multi-axis force sensor is disassembled when the multi-axis force sensor to be calibrated is replaced in the step (4), and the assembling relation between the loading plate and the first target plate to the third target plate is kept still.

Preferably, the laser emitted by the first and second laser displacement sensors in step (2) is perpendicular to the horizontal plane of the first target plate; the laser emitted by the third and fourth laser displacement sensors is vertical to the vertical surface of the first target plate; the laser emitted by the fifth laser displacement sensor and the laser emitted by the sixth laser displacement sensor are vertical to the plane of the second target plate; the laser emitted by the seventh laser displacement sensor is perpendicular to the plane of the third target plate.

Providing a calibration device used in the multi-axis force sensor precision calibration method, wherein the calibration device comprises a loading plate in a rectangular shape; the loading plate is attached to the upper mounting surface of the multi-axis force sensor;

setting a horizontal loading point at the center of one edge;

two symmetrical horizontal loading points are arranged on the opposite side of the edge;

the centers of two adjacent sides of the side are provided with horizontal loading points, and four angular points are respectively provided with vertical downward loading points;

the horizontal load points are used to apply outward forces in the horizontal direction and the vertically downward load points are used to apply vertically downward forces.

Preferably, the symmetrical horizontal loading points and the four vertically downward loading points realize loading of the moment in the corresponding direction by applying unbalanced force.

Preferably, the loading is realized by the dead weight of the weight at a vertical downward loading point; the horizontal loading point converts the loading direction into vertical downward direction through the pulley, and the weight dead weight is utilized to realize loading.

compared with the prior art, the invention has the following advantages:

(1) according to the mounting and positioning method for the precision calibration of the multi-axis force sensor, the newly mounted multi-axis force sensor can be quickly adjusted to the specified reference when the new sensor is mounted each time, the mounting positions of all mounted sensors can be ensured to be consistent, the consistency of calibration references is ensured, and the consistency of sensors in different batches is greatly improved.

(2) after the sensor is installed, the deformation of the sensor under different loads can be monitored in real time in the calibration process and provided to a user as the technical parameter of the sensor.

(3) according to the mounting and positioning method, only the supporting device for supporting the multi-axis force sensor needs to be adjusted in the actual calibration process, and the load reversing devices such as the pulleys on the periphery do not need to be adjusted, so that the adjustment workload of calibration is greatly reduced, the calibration efficiency of the sensor is improved, and the calibration is favorably realized in batch production.

(4) According to the invention, all position postures of the multi-axis force sensor can be obtained only by using 7 laser displacement sensors through a unique layout mode, and the device is convenient and effective.

(5) according to the invention, the decomposition of force and moment is realized through the loading plate, and finally, the six-component load high-precision cooperative loading of the multi-axis force sensor is realized, so that the calibration precision of the sensor is improved.

Drawings

FIG. 1 is a schematic view of a multi-axis force sensor of the present invention installed in a calibration station;

FIG. 2 is a layout diagram of the installation of 7 laser displacement sensors;

fig. 3 is a schematic diagram illustrating a monitoring principle of an angle change of a multi-axis force sensor during a calibration process.

Detailed Description

the invention mainly aims at the problem of insufficient mounting and positioning precision in the current multi-axis force sensor calibration process, and provides a mounting method for adjusting the posture, which can keep the mounting states of different sensors consistent, thereby eliminating the error of the sensors caused by the difference of the mounting states and improving the calibration precision of the sensors. The following is a more detailed description of embodiments of the invention, taken in conjunction with the accompanying drawings.

A schematic diagram of a multi-axis force sensor mounted on a calibration table is shown in figure 1, and main components comprise a supporting mechanism 1, a multi-axis force sensor 2, a loading plate 3, a steel wire 4 for connecting the loading plate 3 and a weight 6, and a pulley 5 for realizing load reversing.

In this example, referring to fig. 1, a rectangular load plate 3 is attached to the upper mounting surface of the multi-axis force sensor 2. The center of one edge of the loading plate 3 is provided with a horizontal loading point, the opposite edge of the edge is provided with two symmetrical horizontal loading points, the centers of two adjacent edges of the edge are provided with horizontal loading points, and four angular points are respectively provided with vertical downward loading points. The horizontal load points of load plate 3 are used to apply outward forces in the horizontal direction and the vertically downward load points are used to apply vertically downward forces. The symmetrical horizontal loading points and the four vertical downward loading points realize the loading of the moment in the corresponding direction by applying unbalanced force. Loading is realized by using the dead weight of a weight 6 at a vertical downward loading point; the horizontal loading point converts the loading direction to vertical direction through the pulley 5, and the weight 6 is used for realizing loading. The support mechanism 1 is used to support the multi-axis force sensor 2.

In this example, referring to fig. 2, the key structures are a laser displacement sensor mounted around the loading plate and a target plate for receiving a laser signal of the displacement sensor. The laser displacement sensors comprise a displacement sensor 1 701, a displacement sensor 2 702, a displacement sensor 3 703, a displacement sensor 4 704, a displacement sensor 5 705, a displacement sensor 6 706 and a displacement sensor 7, and 707.7 laser displacement sensors are mounted on a single displacement sensor bracket and are not in contact with the loading plate 3. The laser displacement gage target plate includes a number 1 flat plate 801, a number 2 flat plate 802, and a gusset plate 803. The target plate is arranged and positioned on the loading plate 3 through screws and pins and is used for receiving laser signals of the laser displacement sensor 7.

When the calibration table calibrates the multi-axis force sensor 2 for the first time, a calibration coordinate system can be established independently, and the peripheral load reversing device is adjusted to be consistent with the calibration coordinate system.

And after the calibration table is installed for the first time, installing the target plate of the laser displacement meter. Preferably, plate No. 1, 801, is mounted on the upper plane of load plate 3 parallel to the y-axis, plate No. 2, 802, is mounted on the front end face of load plate 3 parallel to the y-axis, and gussets 803 are mounted on the upper plane of load plate 3 parallel to the x-axis. After the displacement meter target plate is installed, the displacement meter target plate is not detached any more when other multi-axis force sensors are calibrated subsequently.

And after the calibration table is mounted for the first time, mounting the laser displacement sensor. Preferably, as shown in fig. 2, the displacement sensor No. 1 701 and the displacement sensor No. 2 702 are arranged along the x-axis, and the laser displacement sensor is completely fixed, and the laser is vertically projected downwards to one plane of the angle plate 803; the 3 # displacement sensor 703 and the 4 # displacement sensor 704 are arranged along the x-axis, and the laser displacement sensor is completely fixed, and laser is horizontally projected to the other plane of the angle plate 803; the No. 5 displacement sensor 705 and the No. 6 displacement sensor 706 are arranged along the y axis, the laser displacement sensors are completely fixed, and laser is vertically downwards hit on the No. 1 flat plate 801; a laser displacement sensor number 7 707 is disposed at the foremost side of the load plate 3, and horizontally strikes the number 2 flat plate 802.

After the calibration table is installed for the first time and the laser displacement sensors and the target plate are installed, the reading d1 of each displacement sensor is recorded0~d70The reading is used as a baseline value for the multi-axis force sensor installation.

when the multi-axis force sensor is reinstalled on the calibration stand, the support mechanism 1 can be adjusted to restore the readings of the 7 laser displacement sensors to the reference value. Preferably, the z-direction displacement of the support structure 1 can be adjusted first, and the readings of the displacement sensor 701 and the displacement sensor 702 of the number 1 and the number 2 can be restored to the reference values by adjusting the angle of the support structure 1 around the y-axis; secondly, the y-direction displacement and the angle around the z-axis of the supporting structure 1 can be adjusted according to the same principle, so that the readings of the displacement sensor 703 and the displacement sensor 704 of the No. 3 are recovered to the reference value; again, the angle of the support structure 1 about the x-axis can be adjusted to return the displacement sensors No. 5 705 and No. 6 706 to the baseline values; finally, the x-displacement of the support mechanism 1 is adjusted to return the reading of the displacement sensor number 7 707 to the reference value. And finishing the installation, positioning and adjustment of the multi-axis force sensor.

The working principle is as follows:

The 1.1-number displacement sensor 701 and the 2-number displacement sensor 702 are used for measuring and adjusting the displacement in the z-axis direction and the rotation angle around the y-axis; the displacement sensor 703 of No. 3 and the displacement sensor 704 of No. 4 realize the measurement and adjustment of displacement in the y-axis direction and rotation angle around the z-axis; the displacement sensor No. 5 705 and the displacement sensor No. 6 706 realize the measurement and adjustment of the rotation angle around the x axis; the displacement sensor 707 No. 7 is used to realize the measurement and adjustment of the displacement in the x-axis direction.

2. in the calibration process of the multi-axis force sensor, different combined loads are loaded, when the readings of the displacement sensor 701 and the displacement sensor 702 are changed, the reading difference between the two reflects the angle change around the y-axis, and the measurement schematic is shown in fig. 3, where the angle change around the y-axis is:

Similarly, when the number 3 displacement sensor 703 and the number 4 displacement sensor 704 generate reading changes, the reading difference between the two reflects the angle change around the z-axis; when the displacement sensor No. 5 705 and the displacement sensor No. 6 706 generate a reading change, the difference between the readings reflects the angle change around the x-axis.

after the multi-axis force sensor is installed, the multi-axis force sensor is calibrated, and the calibration method comprises the following steps:

a. Reading d1 of the first to seventh laser displacement sensors0~d70

b. Applying a downward numerical load to the loading plate, and reading the readings d1 and d2 of the first laser displacement sensor and the second laser displacement sensor and the readings d5 and d6 of the fifth laser displacement sensor and the sixth laser displacement sensor; computing wherein L12 is the distance between the first and second laser displacement sensors, and L56 is the distance between the fifth and sixth laser displacement sensors, which can be measured actually; Δ d1 ═ d1-d10,Δd2=d2-d20,Δd5=d5-d50,Δd6=d6-d60

c. Applying a horizontal load to the loading plate, and reading the readings d3 and d4 of the third laser displacement sensor and the fourth laser displacement sensor; computingL34 is the distance between the third and fourth laser displacement sensors; Δ d3 ═ d3-d30,Δd4=d4-d40

d. And giving alpha, beta and gamma corresponding to the loading load as performance parameters of the multi-axis force sensor.

In conclusion, the mounting and positioning method for the multi-axis force sensor in the calibration process can be used for quickly mounting the multi-axis force sensor during calibration, and ensures that the mounting states of all the sensors are completely consistent, so that the influence caused by mounting errors during calibration is eliminated, and the calibration accuracy of the multi-axis force sensor is improved by the calibration method. Besides, the deformation of the multi-axis force sensor under different loads is accurately given by an experimental measurement method, and the actual use of the multi-axis force sensor is referred.

The above description is only for the best mode of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are included in the scope of the present invention.

Those skilled in the art will appreciate that the invention may be practiced without these specific details.

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