CN218822155U - Testing device using correlation sensor technology - Google Patents

Abstract

The utility model discloses a testing device using correlation sensor technology, which relates to the technical field of testing devices and aims to solve the technical problems that the testing device in the prior art is difficult to rapidly measure the size of an object by utilizing the correlation sensor technology and is difficult to rapidly adjust the position of the fixedly placed object, and the testing device comprises a bearing body and a first movable body and a second movable body which are movably arranged above the bearing body; the right-hand member fixed mounting of second movable body has evenly distributed's infrared distance measuring sensor, and the upper end activity of supporting body is provided with first fly leaf, and the upper end activity of first fly leaf is provided with the second fly leaf, and the upper and lower both ends of second fly leaf run through the standing groove of seting up evenly distributed, and the inner wall activity of standing groove is provided with the installation piece. The size of the object can be rapidly measured by the testing device by utilizing the correlation sensor technology, and the position of the fixedly placed object can be rapidly adjusted.

Description

Testing device using correlation sensor technology

Technical Field

The utility model belongs to the testing arrangement field, concretely relates to use testing arrangement who penetrates sensor technique.

Background

At present when carrying out size measurement to all kinds of work pieces, utilize infrared distance measuring sensor to range for the object usually, place the object is fixed in suitable position, through fixed infrared distance measuring sensor's position, open infrared distance measuring sensor and realize measuring the size of object, but present testing arrangement is difficult to utilize correlation sensor technique to carry out the rapid survey to the size of object usually, is difficult to the position of the fixed object of placing of quick adjustment, remains the improvement of further.

At present, a utility model patent with a patent number of CN202020289778.X discloses a multi-degree-of-freedom photoelectric correlation sensor testing device, which comprises a test board, a multi-dimensional movement mechanism, an angle deflection mechanism and a mounting bracket; the multi-dimensional movement mechanism is arranged on the test board, the angle deflection mechanism is arranged on the multi-dimensional movement mechanism, and the mounting bracket is arranged on the test board, positioned above the angle deflection mechanism and used for mounting the receiver; the angle deflection mechanism is provided with a transmitter and is used for realizing deflection of the transmitter; the multi-dimensional movement mechanism is used for driving the emitter to move in different directions; the angle deflection mechanism comprises an upper base, a lower base, a fan-shaped worm wheel, a worm and a knob, the upper base is connected with the lower base in a sliding manner, and the sliding surface between the upper base and the lower base is arc-shaped; the worm is arranged on the lower base, one end of the worm is connected with the knob, and worm transmission is formed between the other end of the worm and the fan-shaped worm wheel; go up base installation on fan-shaped worm wheel, the device has simple structure, easy and simple to handle and test advantages such as accurate, but present testing arrangement is difficult to utilize correlation sensor technique to carry out the rapid survey to the size of object usually, is difficult to the position of the fixed object of placing of quick adjustment.

Therefore, in order to solve the above-mentioned problem that the conventional testing device is generally difficult to rapidly measure the size of the object by using the correlation sensor technology and to rapidly adjust the position of the fixedly placed object, it is necessary to achieve the capability of rapidly measuring the size of the object by using the correlation sensor technology and rapidly adjusting the position of the fixedly placed object.

SUMMERY OF THE UTILITY MODEL

(1) Technical problem to be solved

An object of the present invention is to provide a test device using correlation sensor technology, which is difficult to quickly measure the size of an object by using correlation sensor technology and to quickly adjust the position of the object.

(2) Technical scheme

In order to solve the above technical problem, the present invention provides a testing device using a correlation sensor technology, which comprises a supporting body, and a first movable body and a second movable body movably disposed above the supporting body; the right end of the second movable body is fixedly provided with uniformly distributed infrared distance measuring sensors, the upper end of the supporting body is movably provided with a first movable plate, the upper end of the first movable plate is movably provided with a second movable plate, the upper end and the lower end of the second movable plate are provided with uniformly distributed placing grooves in a penetrating manner, the inner wall of each placing groove is movably provided with a mounting block, the outer wall fixed mounting of installation piece has evenly distributed's spring, the one end fixed mounting of spring has the extrusion piece, the right-hand member fixed mounting of supporting body has servo motor, infrared distance measuring sensor still fixed mounting is in the left end of first activity body, the fixed first spacing groove of symmetry of seting up in the upper end of supporting body, the fixed second spacing groove of seting up in the upper end of supporting body.

When using this technical scheme's testing arrangement, the object that will await measuring is placed between two extrusion pieces, makes the spring keep certain compression state, can place the both ends stably between two extrusion pieces around the object that awaits measuring, opens infrared distance measuring sensor on the first movable body and the infrared distance measuring sensor on the second movable body and can carry out the rapid test to the surface of the object that awaits measuring, can seek out unevenness's place fast, realizes carrying out the rapid survey to the size of object.

Further, the front end fixed mounting of first activity body has first instruction piece, the front end fixed mounting of second activity body has the second instruction piece, the front end fixed mounting of supporting body is provided with the scale mark, and first instruction piece and second instruction piece all indicate on the scale mark, conveniently confirm the relative distance between first activity body and the second activity body.

Further, servo motor's output shaft left end runs through supporting body right-hand member fixed mounting and has the lead screw body, the outer wall movable mounting of lead screw body has screw-nut, screw-nut's outer wall fixed mounting has the fifth stopper, the upper end of fifth stopper is connected with the lower extreme of first movable body, the left end and the left end inner wall run through formula fixed mounting of supporting body have the bearing, the inner wall of bearing is laminated mutually with the left end outer wall of lead screw body, opens servo motor and makes the lead screw body rotate, and screw-nut moves along the outer wall of lead screw body, can make the fifth stopper remove about on the horizontal direction, realizes removing first movable body.

Further, the lower extreme fixed mounting of first activity body has the first stopper of symmetry, both ends laminate mutually with the front and back both ends inner wall in first spacing groove around the first stopper, and first stopper moves along the front and back both ends inner wall in first spacing groove, does benefit to the steady removal of first activity body.

Further, the lower extreme fixed mounting of the second activity body has the second stopper of symmetry, both ends laminate mutually with first spacing groove both ends inner wall around both ends around the second stopper, the lower extreme fixed mounting of first fly leaf has the fourth stopper of symmetry, both ends and first spacing groove both ends inner wall laminate around the fourth stopper around, and the second stopper removes along first spacing groove both ends inner wall around, does benefit to the stable removal of second activity body, and the fourth stopper removes along first spacing groove both ends inner wall around, does benefit to the stable removal of first fly leaf.

Further, the upper end fixed mounting of first fly leaf has the fixed block of symmetry, the fixed third spacing groove of having seted up of both ends inner wall around the fixed block, the equal fixed mounting in both ends has the third stopper around the second fly leaf, third stopper and third spacing groove looks adaptation place the inner wall department at the third spacing groove with the third stopper, can place the second fly leaf fast and stable in the upper end of first fly leaf.

Further, both ends are run through and are seted up evenly distributed's first thread groove about the second fly leaf, both ends are run through and are seted up the second thread groove about the installation piece, the screw thread post is installed to the inner wall screw thread of first thread groove, the screw thread post passes first thread groove screw thread and installs in the inner wall of second thread groove, passes first thread groove screw thread with the screw thread post and installs in the inner wall of second thread groove, can fix the installation piece in the standing groove fast.

(3) Advantageous effects

Compared with the prior art, the beneficial effects of the utility model reside in that: the utility model discloses a testing arrangement is through setting up first movable body and second movable body, all be provided with evenly distributed's infrared distance measuring sensor on first movable body and the second movable body, the object that will await measuring is placed between two extrusion pieces, make the spring keep certain compression state, can stably place the front and back both ends of the object that awaits measuring between two extrusion pieces, open the infrared distance measuring sensor on the first movable body and the infrared distance measuring sensor on the second movable body and can test the surface of the object that awaits measuring fast, uneven place can be found out fast, realize measuring the size of object fast, through setting up servo motor, lead screw body and screw-nut, it makes the lead screw body rotate to open servo motor, screw-nut removes along the outer wall of lead screw body, can make the fifth stopper remove on the horizontal direction, realize removing first movable body, through setting up first fly leaf and second fly leaf, and a plurality of standing grooves's setting, can conveniently fix the object that awaits measuring the measuring fast in the right position of second fly leaf, realized that the device can adjust the ability of the fixed position of placing the object that places fast.

Drawings

FIG. 1 is a schematic perspective view of a specific embodiment of the testing device of the present invention;

fig. 2 is a schematic perspective view of a first movable plate of a testing device according to an embodiment of the present invention;

FIG. 3 is a schematic perspective view of an installation block of a specific embodiment of the testing device of the present invention;

fig. 4 is a cross-sectional view of a carrier according to one embodiment of the testing device of the present invention.

The symbols in the drawings are: 1. a carrier; 2. a first movable body; 3. a second movable body; 4. an infrared ranging sensor; 5. a first indication block; 6. a second indication block; 7. scale lines; 8. a first movable plate; 9. a servo motor; 10. a first limit groove; 11. a first stopper; 12. a second limit groove; 13. a second limiting block; 14. a fixed block; 15. a third limiting groove; 16. a second movable plate; 17. a third limiting block; 18. a placement groove; 19. mounting blocks; 20. a spring; 21. extruding the block; 22. a first screw groove; 23. a threaded post; 24. a fourth limiting block; 25. a second screw groove; 26. a screw rod body; 27. a feed screw nut; 28. a fifth limiting block; 29. and a bearing.

Detailed Description

The present embodiment is a testing device using a correlation sensor technology, a schematic three-dimensional structure thereof is shown in fig. 1, a schematic three-dimensional structure of a first movable plate 8 thereof is shown in fig. 2, the testing device includes a supporting body 1, and a first movable body 2 and a second movable body 3 movably disposed above the supporting body 1; the infrared distance measuring sensor 4 with uniform distribution is fixedly installed at the right end of the second movable body 3, a first movable plate 8 is movably arranged at the upper end of the supporting body 1, a second movable plate 16 is movably arranged at the upper end of the first movable plate 8, a standing groove 18 with uniform distribution is formed in the upper end and the lower end of the second movable plate 16 in a penetrating mode, an installation block 19 is movably arranged at the inner wall of the standing groove 18, a spring 20 with uniform distribution is fixedly installed on the outer wall of the installation block 19, an extrusion block 21 is fixedly installed at one end of the spring 20, a servo motor 9 is fixedly installed at the right end of the supporting body 1, the infrared distance measuring sensor 4 is further fixedly installed at the left end of the first movable body 2, a first symmetrical limiting groove 10 is fixedly installed at the upper end of the supporting body 1, a second limiting groove 12 is fixedly installed at the upper end of the supporting body 1, a second limiting block 13 with symmetry is fixedly installed at the lower end of the second movable body 3, a front end and a rear end of the second limiting block 13 are attached to front and rear end inner walls at front and rear ends of the first limiting groove 10, a lower end of the first movable body 8 is fixedly installed with a symmetrical fourth limiting block 24, a front and rear end of the fourth limiting block 24 and a front end of the fourth limiting groove is attached to inner wall of the front and a rear end of the first limiting groove 10, a rear limiting block 17, a front and a rear limiting block is installed at both ends of the fixed block 14, a front and a third limiting groove 17 fixed block with a rear end fixed block 15, and a rear end of a third limiting groove 17, and a third limiting groove 17 fixed block 15 fixed block are installed at both ends of the third limiting groove 17, and a rear end of the fixed block.

In order to measure the position between the first movable body 2 and the second movable body 3 conveniently, a first indicating block 5 is fixedly installed at the front end of the first movable body 2, a second indicating block 6 is fixedly installed at the front end of the second movable body 3, scale marks 7 are fixedly arranged at the front end of the bearing body 1, and the position between the first movable body 2 and the second movable body 3 can be measured quickly through the first indicating block 5 and the second indicating block 6.

In order to conveniently adjust the position of the first movable body 2, the left end of the output shaft of the servo motor 9 penetrates through the right end of the bearing body 1 and is fixedly provided with a screw rod body 26, the outer wall of the screw rod body 26 is movably provided with a screw rod nut 27, the outer wall of the screw rod nut 27 is fixedly provided with a fifth limiting block 28, the upper end of the fifth limiting block 28 is connected with the lower end of the first movable body 2, the left end and the left end inner wall of the bearing body 1 are fixedly provided with a bearing 29 in a penetrating manner, the inner wall of the bearing 29 is attached to the left end outer wall of the screw rod body 26, the servo motor 9 is opened to enable the screw rod body 26 to rotate, the screw rod nut 27 rotates along the outer wall of the screw rod body 26, the fifth limiting block 28 can be moved, and the position of the first movable body 2 can be conveniently adjusted.

In order to realize the stable removal of the first movable body 2, the lower end fixed mounting of the first movable body 2 has the first stopper 11 of symmetry, and both ends and the front and back both ends inner wall of the first spacing groove 10 are laminated around the first stopper 11, and when the first movable body 2 is removed, the inner wall of the front and back both ends of the first stopper 11 along the first spacing groove 10 is removed, and the stable removal of the first movable body 2 can be realized.

In order to realize the quick fixation of the mounting block 19 on the second movable plate 16, the left and right ends of the second movable plate 16 are penetrated and provided with the first screw grooves 22 which are uniformly distributed, the left and right ends of the mounting block 19 are penetrated and provided with the second screw grooves 25, the inner wall of the first screw groove 22 is threaded with the threaded post 23, the threaded post 23 is threaded through the first screw groove 22 and is mounted on the inner wall of the second screw groove 25, and the mounting block 19 can be quickly fixed on the second movable plate 16.

The schematic perspective structure of the test device mounting block 19 is shown in fig. 3, and the cross-sectional view of the carrier 1 is shown in fig. 4.

When the testing device of the technical scheme is used, the mounting block 19 is placed on the inner wall of the placing groove 18 at a proper position, the threaded column 23 penetrates through the first thread groove 22 to be mounted on the inner wall of the second thread groove 25 in a threaded manner, the mounting block 19 can be quickly fixed on the second movable plate 16, an object to be tested is placed between the two extrusion blocks 21, the spring 20 is enabled to keep a certain compression state, the front end and the rear end of the object to be tested can be stably placed between the two extrusion blocks 21, the infrared distance measuring sensor 4 on the first movable body 2 and the infrared distance measuring sensor 4 on the second movable body 3 are opened to quickly test the surface of the object to be tested, an uneven place can be quickly found, the size of the object can be quickly measured, the servo motor 9 is started to enable the screw rod body 26 to rotate, the screw rod nut 27 rotates along the outer wall of the screw rod body 26, the movement of the fifth limiting block 28 can be realized, the position of the first movable body 2 can be conveniently adjusted, and the size of the object to be measured can be quickly measured.

Claims (7)

1. A testing device using a correlation sensor technology comprises a bearing body, a first movable body and a second movable body, wherein the first movable body and the second movable body are movably arranged above the bearing body; the infrared distance measuring device is characterized in that the right end of the second movable body is fixedly provided with uniformly distributed infrared distance measuring sensors, a first movable plate is movably arranged at the upper end of the supporting body, a second movable plate is movably arranged at the upper end of the first movable plate, uniformly distributed placing grooves are formed in the upper end and the lower end of the second movable plate in a penetrating mode, an installing block is movably arranged on the inner wall of each placing groove, uniformly distributed springs are fixedly arranged on the outer wall of the installing block, an extrusion block is fixedly arranged at one end of each spring, a servo motor is fixedly arranged at the right end of the supporting body, the infrared distance measuring sensors are fixedly arranged at the left end of the first movable body, symmetrical first limiting grooves are fixedly formed in the upper end of the supporting body, and a second limiting groove is fixedly formed in the upper end of the supporting body.

2. The testing device using the correlation sensor technology as claimed in claim 1, wherein a first indicating block is fixedly installed at a front end of the first movable body, a second indicating block is fixedly installed at a front end of the second movable body, and a scale mark is fixedly arranged at a front end of the supporting body.

3. The testing device using the correlation sensor technology as claimed in claim 1, wherein a lead screw body is fixedly mounted at the left end of the output shaft of the servo motor in a penetrating manner through the right end of the bearing body, a lead screw nut is movably mounted on the outer wall of the lead screw body, a fifth limiting block is fixedly mounted on the outer wall of the lead screw nut, the upper end of the fifth limiting block is connected with the lower end of the first movable body, a bearing is fixedly mounted at the left end of the bearing body and the inner wall of the left end in a penetrating manner, and the inner wall of the bearing is attached to the outer wall of the left end of the lead screw body.

4. The testing device using the correlation sensor technology as claimed in claim 1, wherein symmetrical first limit blocks are fixedly mounted at the lower end of the first movable body, and the front end and the rear end of each first limit block are attached to the inner walls of the front end and the rear end of each first limit groove.

5. The testing device using the correlation sensor technology as claimed in claim 1, wherein a symmetrical second limiting block is fixedly mounted at the lower end of the second movable body, inner walls of the front and rear ends of the first limiting groove and the front and rear ends of the second limiting block are attached to each other, a symmetrical fourth limiting block is fixedly mounted at the lower end of the first movable plate, and inner walls of the front and rear ends of the first limiting groove and the front and rear ends of the fourth limiting block are attached to each other.

6. The testing device using the correlation sensor technology as claimed in claim 1, wherein the upper end of the first movable plate is fixedly provided with symmetrical fixing blocks, inner walls of the front and rear ends of the fixing blocks are fixedly provided with third limiting grooves, the front and rear ends of the second movable plate are fixedly provided with third limiting blocks, and the third limiting blocks are matched with the third limiting grooves.

7. The testing device using the correlation sensor technology as claimed in claim 1, wherein first screw grooves are formed at left and right ends of the second movable plate, and first screw grooves are uniformly distributed, second screw grooves are formed at left and right ends of the mounting block, screw threads are installed on inner walls of the first screw grooves, and the screw threads are installed on inner walls of the second screw grooves through the first screw grooves.

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