CN211669390U - Component type drilling strain gauge complete machine detection platform controlled by six degrees of freedom - Google Patents

Abstract

The utility model provides a component formula drilling strain gauge complete machine testing platform of six degree of freedom control for test component formula drilling strain gauge is respectively at the ascending performance parameter of each measuring element side, include: the device comprises a hydraulic system, a loading frame, a probe three-dimensional adjusting platform and a laser displacement sensor three-dimensional adjusting platform, wherein the hydraulic system is used for providing a load which can be accurately and quantitatively controlled for the loading frame, the loading frame converts the load into displacement through a plurality of elastic components, the probe three-dimensional adjusting platform is used for fixing a probe and adjusting a pitch angle, a rolling angle and a deflection angle of the probe in an XZ plane, a rolling angle and an XY plane in a YZ plane, and the laser displacement sensor three-dimensional adjusting platform is used for fixing a laser displacement sensor and adjusting the relative positions of the laser displacement sensor and the probe in X, Y and Z directions. The utility model discloses can control component formula drilling strain gauge's probe when the test degree of freedom in six directions in space, reduce the influence of probe gesture to the test result, can effectively improve the repeatability and the stability of test result.

Description

Component type drilling strain gauge complete machine detection platform controlled by six degrees of freedom

Technical Field

The utility model relates to a displacement testing platform especially relates to a complete machine performance parameter (including sensitivity, linearity and range) testing platform of weight formula drilling strain gauge who uses in earthquake precursor observation.

Background

The component borehole strain gauge is a seismic precursor observation instrument used for recording the change of the formation level strain. The probe part of the instrument comprises a stainless steel long cylinder and four internal measuring elements, wherein the four measuring elements are positioned in a plane perpendicular to the axis of the stainless steel long cylinder and distributed in a shape of a Chinese character 'mi' at 45-degree intervals. The two ends of each measuring element are connected with the stainless steel long cylinder in a welding or threaded fastening mode, when the probe deforms, the two ends of the measuring element also change in the radial direction, and the change can be recorded through a capacitance sensor in the measuring element.

Patent document 1 (publication No. CN206523143U, publication No. 2017-09-26) discloses a borehole strain gauge sensitivity testing system, which can be used for testing the sensitivity of a borehole strain gauge, and includes: the device comprises a manual hydraulic pump, a laser displacement sensor, a support, an upper pressure head and a lower pressure head, wherein the outer cylinder of the drilling strain gauge probe is stressed in the radial measurement direction in a centralized manner through the manual hydraulic pump, the deformation of the outer cylinder of the drilling strain gauge probe in the stressed position is measured through the high-precision laser displacement sensor, the readings of the laser displacement sensor and a differential capacitance sensor installed in the probe are recorded, and the parameters of the instrument such as sensitivity, linearity and the like can be calculated. The sensitivity testing system for the drilling strain gauge not only can provide large and stable calibration force (5000N), but also has high calibration precision.

The component type borehole strain gauge has extremely high measurement precision and measurement resolution of 10^-10The strain magnitude is that if the measuring element in the probe and the external laser displacement sensor cannot be strictly kept in the measuring direction during the test of the component type borehole strain gaugeAs a result, the test results (e.g., sensitivity and linearity) are affected. The external laser displacement sensor is generally fixed after being adjusted, and the measuring direction of the measuring element in the probe can be adjusted by changing the fixed posture of the probe (the position of the probe relative to the laser displacement sensor in the direction X, Y, Z, and the pitch angle, the roll angle and the yaw angle of the probe). The probe is adjusted to the same fixed posture during each test, so that the repeatability (consistency among obtained results in a short-time continuous multiple measurements under the same measurement condition) and the stability (consistency among obtained results in a specified longer time interval under the same measurement condition) of the test result can be greatly improved, but the related technology of probe fixed posture and posture adjustment is not involved in the prior art.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the fixed problem of probe of above-mentioned weight formula drilling strain gauge when the whole machine in laboratory is examined, provided a weight formula drilling strain gauge complete machine testing platform of six degree of freedom control, the test result can have higher repeatability and stability.

The utility model discloses a component formula drilling strain gauge complete machine testing platform of six degree of freedom control for test component formula drilling strain gauge is at the ascending performance parameter of each measuring element side, include: a hydraulic system, a loading frame, a probe three-dimensional adjusting platform and a laser displacement sensor three-dimensional adjusting platform,

the hydraulic system is used for providing accurately and quantitatively controllable loads for the loading frame;

the loading frame is used for applying load to a probe of the component borehole strain gauge to enable the probe to generate radial deformation;

the probe three-dimensional adjusting platform is used for fixing the probe and adjusting the posture of the probe in each direction; and

the three-dimensional adjusting table of the laser displacement sensor is used for fixing the laser displacement sensor and adjusting the relative positions of the laser displacement sensor and the probe in the X, Y and Z directions.

Preferably, the hydraulic system comprises a pressure calibrator, a high-pressure hose and a hydraulic cylinder.

Preferably, the loading frame comprises a loading head, an upper loader, a lower loader, a positioning piston, a positioning cylinder, an outer frame, a preload adjustment spring, and a stiffness adjustment spring.

Preferably, the loading frame includes 4 pairs of the positioning pistons and the positioning cylinders, the positioning pistons being mounted to the upper loader, and the positioning cylinders being mounted to the lower loader so that two opposite loading surfaces of the upper loader and the lower loader are maintained in parallel.

Preferably, the stiffness adjusting spring is installed between the loading head and the upper loader, for adjusting an equivalent stiffness of the loading frame.

Preferably, the preload adjustment spring is installed between the positioning piston and the positioning cylinder for adjusting the preload between the upper loader and the lower loader.

Preferably, the probe three-dimensional adjusting table comprises a dividing head, a tailstock, a probe X horizontal adjusting table, a probe Y horizontal adjusting table and a probe Z vertical adjusting table.

Preferably, the probe three-dimensional adjusting platform adjusts the posture of the probe in each direction by adjusting the pitch angle of the probe in an XZ plane, the roll angle of the probe in a YZ plane and the yaw angle of the probe in an XY plane.

Preferably, the three-dimensional adjusting table of the laser displacement sensor comprises a laser displacement sensor, a connecting frame, a sensor X horizontal adjusting table, a sensor Y horizontal adjusting table and a sensor Z vertical adjusting table.

The utility model has the advantages that:

according to the utility model discloses a structure, the probe that can control component formula drilling strain gauge when the test reduces the influence of probe gesture to the test result in the degree of freedom of six directions in space, can effectively improve the repeatability and the stability of test result.

Drawings

Fig. 1 is the front structural schematic diagram of the component type drilling strain gauge complete machine detection platform controlled by six degrees of freedom of the utility model.

Fig. 2 is the side structure schematic diagram of the component type drilling strain gauge complete machine detection platform controlled by six degrees of freedom of the utility model.

Detailed Description

The present invention is further illustrated by the following examples, which are intended only for better understanding of the contents of the present invention and are not intended to limit the scope of the present invention.

The utility model discloses a component formula drilling strain gauge complete machine testing platform of six degree of freedom control for test component formula drilling strain gauge is at the ascending performance parameter of each measuring element side. The probe of the component borehole strain gauge comprises a stainless steel long cylinder and four measuring elements inside the stainless steel long cylinder. Performance parameters include sensitivity, linearity, and range. The present invention will be explained below by taking sensitivity as an example.

The utility model discloses a complete machine testing platform includes: the device comprises a hydraulic system, a loading frame, a probe three-dimensional adjusting table and a laser displacement sensor three-dimensional adjusting table. The hydraulic system is used for providing accurately and quantitatively controllable loads for the loading frame; the loading frame is used for applying load to a probe of the component borehole strain gauge to enable the probe to generate radial deformation; the probe three-dimensional adjusting platform is used for fixing the probe and adjusting the posture of the probe in each direction; and the three-dimensional adjusting table of the laser displacement sensor is used for fixing the laser displacement sensor and adjusting the relative positions of the laser displacement sensor and the probe in the directions X, Y and Z.

Fig. 1 is a front structural schematic diagram of the complete machine detection platform of the six-degree-of-freedom controlled component type drilling strain gauge of the present invention. Fig. 2 is the side structure schematic diagram of the component type drilling strain gauge complete machine detection platform controlled by six degrees of freedom of the utility model. The structure of the present invention will be described in detail with reference to fig. 1 to 2.

As shown in figure 1, the hydraulic system of the whole machine detection platform of the utility model comprises a pressure calibrator 1, a high-pressure rubber tube 2 and a hydraulic cylinder 3. The loading frame comprises a loading head 6, an upper loader 7, a lower loader 9, a positioning piston 10, a positioning cylinder 11, an outer frame 5, a preload adjusting spring 12 and a stiffness adjusting spring 8. The probe three-dimensional adjusting table comprises a dividing head 18, a tailstock 20, a probe X horizontal adjusting table 15, a probe Y horizontal adjusting table 16 and a probe Z vertical adjusting table 17.

Specifically, an oil outlet of the pressure calibrator 1 is connected with a hydraulic cylinder 3 through a high-pressure rubber tube 2, and a piston 4 in the hydraulic cylinder 3 can move along the axial direction of the hydraulic cylinder 3 under the action of oil pressure. The hydraulic cylinder 3 is fixed on the upper top plate of the outer frame 5, and the piston 4 moves downwards for a certain distance to be in contact with the loading head 6 and apply load.

The loading head 6 and the upper loader 7 are slidably fitted through a shaft and a hole, and a stiffness adjusting spring 8 is installed therebetween for adjusting the equivalent stiffness of the entire loading frame. 4 pairs of positioning pistons 10 and positioning cylinders 11 are arranged between the upper loader 7 and the lower loader 9 of the loading frame, the positioning pistons 10 are arranged on the upper loader 7, and the positioning cylinders 11 are arranged on the lower loader 9, so that two opposite loading surfaces of the upper loader 7 and the lower loader 9 can keep parallel movement. Between each 1 pair of the positioning piston 10 and the positioning cylinder 11, a preload adjusting spring 12 is installed for adjusting the preload between the upper loader 7 and the lower loader 9. The loading frame may convert the load into displacement by the plurality of elastic members. The probe 13 of the component borehole strain gauge is mounted between the upper loader 7 and the lower loader 9 and radially deforms under load. The lower loader 9 is fixed to the lower floor of the outer frame 5. The level 14 is placed on the probe 13 in the direction of the probe axis.

In the probe three-dimensional adjusting table, a probe X horizontal adjusting table 15, a probe Z vertical adjusting table 16, a probe Y horizontal adjusting table 17 and a dividing head 18 are fixedly connected into a whole in sequence from bottom to top. The index head 18 locks one end of the probe 13 by three jaws 19 and the tailstock 20 locks the other end of the probe 13. The probe three-dimensional adjusting platform adjusts the posture of the probe in each direction by adjusting the pitch angle of the probe 13 in an XZ plane, the roll angle in a YZ plane and the yaw angle in an XY plane.

As shown in fig. 2, the utility model discloses a three-dimensional regulation platform of complete machine testing platform's laser displacement sensor includes laser displacement sensor 25, link 24, sensor X horizontal adjustment platform 21, sensor Y horizontal adjustment platform 22 and the perpendicular regulation platform 23 of sensor Z. The sensor Y horizontal adjusting platform 21, the sensor X horizontal adjusting platform 22 and the sensor Z vertical adjusting platform 23 are fixedly connected into a whole from bottom to top in sequence. The connecting frame 24 is Y-shaped, one end of the connecting frame is fixed on the sensor Z vertical adjusting platform 23, and the other end of the connecting frame is respectively connected with 2 laser displacement sensors 25. The 2 laser displacement sensors 25 are respectively positioned at the upper side and the lower side of the probe 13 and are consistent with a measuring element 26 in the probe 13 in the vertical direction, and the measuring ends of the 2 laser displacement sensors 25 respectively correspond to the upper surface and the lower surface to be measured of the probe 13 and keep a certain distance.

The working process of the six-degree-of-freedom controlled component type drilling strain gauge complete machine detection platform for testing the sensitivity of the probe of the drilling strain gauge is described in detail below.

The probe 13 of the drilling strain gauge is arranged between the upper loader 7 and the lower loader 9 of the complete machine detection platform, and one end of the probe is fixed by a claw 19 of the dividing head 18. The probe 13 is moved by the probe X leveling stage 15 so that the measuring element 26 to be measured is located at the center position of the loading frame in the X direction. The roll angle of the probe 13 is adjusted by the index head 18, and the probe 13 is rotated in the YZ plane until the measuring element 26 is in a vertical state in the YZ plane. The pitch angle of the probe 13 is adjusted by the probe Z vertical adjustment stage 16, rotating the probe 13 in the XZ plane until the level 14 reads zero. The deflection angle of the probe 13 is adjusted by the probe Y horizontal adjusting platform 17, so that the probe 13 rotates in the XY plane until 2 chock blocks 27 can simultaneously and smoothly pass through two gaps between the probe 13 and the positioning cylinder 11 in the Y direction. The above steps are repeated until the axis of the probe 13 is parallel to the X-axis and the measuring element 26 is parallel to the Z-axis, and then the other end of the probe 13 is locked by the tailstock 20.

The sensor Z is adjusted to be perpendicular to the adjustment stage 23 so that the 2 laser displacement sensors 25 are all within an effective working range in the Z direction. The sensor Y horizontal adjusting platform 21 and the sensor X horizontal adjusting platform 22 are adjusted in sequence, so that the measuring light spots of the 2 laser displacement sensors 25 respectively correspond to the center positions of two ends of the measuring element 26.

The pressure calibrator 1 is operated to discharge oil, the piston 4 is driven to move downwards to load through the high-pressure rubber tube 2 and the hydraulic cylinder 3, and the probe 13 deforms under the action of the load. The sum of the reading changes of the 2 laser displacement sensors 25 is the radial deformation of the probe 13 in the direction of the measuring element 26, and the voltage or capacitance reading change of the measuring element 26 is recorded, and the ratio of the radial deformation to the voltage or capacitance reading change represents the response degree of the component type borehole strain gauge to the unit deformation of the probe 13 in the direction of the measuring element 26, namely the sensitivity of the component type borehole strain gauge in the direction of the measuring element 26.

And adjusting the probe X horizontal adjusting table 15, moving the probe 13 in the X direction, moving the next measuring element to be measured to the central position of the loading frame, and repeating the sensitivity measuring steps, so that the sensitivities of the component type drilling strain gauge in all four measuring element directions can be respectively measured.

According to the above structure of the utility model, the probe that can control component formula drilling strain gauge when the test reduces the influence of probe stationary gesture to the test result in the degree of freedom of six directions in space, can effectively improve the repeatability and the stability of test result.

It is obvious to those skilled in the art that the above embodiments are only used for illustrating the present invention and are not used as limitations of the present invention, and that changes and modifications to the above embodiments are within the scope of the appended claims as long as they are within the true spirit of the present invention.

Claims (9)

1. The utility model provides a component formula drilling strain gauge complete machine testing platform of six degrees of freedom control for test component formula drilling strain gauge is at the performance parameter of each measuring element orientation, its characterized in that includes: a hydraulic system, a loading frame, a probe three-dimensional adjusting platform and a laser displacement sensor three-dimensional adjusting platform,

the hydraulic system is used for providing accurately and quantitatively controllable loads for the loading frame;

the loading frame is used for applying load to a probe of the component borehole strain gauge to enable the probe to generate radial deformation;

the probe three-dimensional adjusting platform is used for fixing the probe and adjusting the posture of the probe in each direction; and

the three-dimensional adjusting table of the laser displacement sensor is used for fixing the laser displacement sensor and adjusting the relative positions of the laser displacement sensor and the probe in the X, Y and Z directions.

2. The complete detection platform for the component type drilling strain gauge controlled by six degrees of freedom according to claim 1, wherein the hydraulic system comprises a pressure calibrator, a high-pressure rubber pipe and a hydraulic cylinder.

3. The complete machine detection platform for the six-degree-of-freedom controlled component type drilling strain gauge according to claim 1, wherein the loading frame comprises a loading head, an upper loader, a lower loader, a positioning piston, a positioning cylinder, an outer frame, a preload adjustment spring and a stiffness adjustment spring.

4. The six-degree-of-freedom controlled component type borehole strain gauge complete machine detection platform according to claim 3, wherein the loading frame comprises 4 pairs of the positioning piston and the positioning cylinder, the positioning piston is mounted on the upper loader, and the positioning cylinder is mounted on the lower loader, so that two opposite loading surfaces of the upper loader and the lower loader are kept parallel.

5. The six-degree-of-freedom controlled component type complete drilling strain gauge detection platform according to claim 3, wherein the stiffness adjustment spring is installed between the loading head and the upper loader and used for adjusting the equivalent stiffness of the loading frame.

6. The six-degree-of-freedom controlled component type drilling strain gauge complete machine detection platform according to claim 3, wherein the preload adjusting spring is installed between the positioning piston and the positioning cylinder and used for adjusting preload between the upper loader and the lower loader.

7. The complete machine detection platform for the six-degree-of-freedom controlled component type drilling strain gauge as claimed in claim 1, wherein the probe three-dimensional adjusting table comprises a dividing head, a tailstock, a probe X horizontal adjusting table, a probe Y horizontal adjusting table and a probe Z vertical adjusting table.

8. The six-degree-of-freedom controlled component type complete drilling strain gauge detection platform according to claim 7, wherein the probe three-dimensional adjustment platform adjusts the posture of the probe in each direction by adjusting the pitch angle of the probe in an XZ plane, the roll angle of the probe in a YZ plane and the yaw angle of the probe in an XY plane.

9. The six-degree-of-freedom controlled component type complete detection platform for drilling strain gauges as claimed in claim 1, wherein the laser displacement sensor three-dimensional adjusting platform comprises a laser displacement sensor, a connecting frame, a sensor X horizontal adjusting platform, a sensor Y horizontal adjusting platform and a sensor Z vertical adjusting platform.

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