CN116358814A - Motor vibration testing mechanism - Google Patents

Abstract

The invention belongs to the technical field of motor production equipment, and discloses a motor vibration testing mechanism, which comprises a bearing table assembly, a clamping assembly and a detection assembly, wherein the bearing table assembly comprises a sponge used for supporting a motor; the clamping assembly is arranged on one side of the bearing table assembly and used for clamping and pushing the plug assembly to be close to the bearing table assembly so that the conductive terminal of the plug assembly is inserted into the motor; the detection assembly is arranged on one side of the bearing table assembly and comprises a first driving piece, an accelerometer and a profiling piece, the accelerometer is arranged at the output end of the first driving piece, the profiling piece is arranged on the accelerometer, the first driving piece is used for driving the profiling piece to be attached to the outer wall of the motor, and the accelerometer is used for detecting the vibration of the motor. The motor vibration testing mechanism can improve the motor vibration testing efficiency and the reliability of the testing result.

Description

Motor vibration testing mechanism

Technical Field

The invention relates to the technical field of motor production equipment, in particular to a motor vibration testing mechanism.

Background

The motor needs to be inserted into the motor in the production process, so that the conductive terminals in the plug and the motor are electrified to run so as to test the vibration condition, when the motor vibrates poorly, the motor is reworked, the existing test mode adopts manual test, the test efficiency is low, and the reliability of the test result is poor.

Therefore, there is a need for a motor vibration testing mechanism that improves motor vibration testing efficiency and reliability of test results.

Disclosure of Invention

One object of the present invention is to: the motor vibration testing mechanism is provided, the motor vibration testing efficiency is improved, and the reliability of the testing result is improved.

To achieve the purpose, the invention adopts the following technical scheme:

motor vibration testing mechanism includes:

the bearing table assembly comprises a sponge, wherein the sponge is used for supporting a motor;

the clamping assembly is arranged on one side of the bearing table assembly and used for clamping and pushing the plug assembly to be close to the bearing table assembly so that the conductive terminal of the plug assembly can be inserted into the motor;

the detection assembly is arranged on one side of the bearing table assembly and comprises a first driving piece, an accelerometer and a profiling piece, the accelerometer is arranged at the output end of the first driving piece, the profiling piece is arranged at the accelerometer, the first driving piece is used for driving the profiling piece to be attached to the outer wall of the motor, and the accelerometer is used for detecting vibration of the motor.

As an optional technical scheme, the detection assembly further comprises a connecting plate and a connecting rope, the connecting plate is mounted at the output end of the first driving piece, the first driving piece drives the connecting plate to be close to the sponge along the vertical direction, one end of the connecting rope is connected with the connecting plate, the other end of the connecting rope is connected with the accelerometer, and the accelerometer is hung above the sponge.

As an optional technical scheme, the detection assembly further comprises a second driving piece and a first clamping jaw, the second driving piece is installed at the output end of the first driving piece, the first clamping jaw is installed at the output end of the second driving piece, and the second driving piece is used for driving the first clamping jaw to clamp and fix the accelerometer.

As an optional technical scheme, the top of sponge is provided with spacing recess, spacing recess is used for holding the motor.

As an optional technical scheme, the plummer assembly further comprises a third driving piece and a top, the third driving piece is arranged on one side, away from the clamping assembly, of the sponge, the top is installed at the output end of the third driving piece, and the third driving piece is used for driving the top to prop up tightly the motor.

As an optional technical scheme, the plummer assembly further comprises a fourth driving piece and a second clamping jaw, the second clamping jaw is installed at the output end of the fourth driving piece, and the fourth driving piece is used for driving the second clamping jaw to clamp two side walls of the motor.

As an optional technical scheme, the second clamping jaw is arranged into two groups, wherein one group of the second clamping jaw is arranged at one end of the sponge, which is close to the clamping assembly, and the other group of the second clamping jaw is arranged at one end of the sponge, which is far away from the clamping assembly.

As an optional technical scheme, motor vibration testing mechanism includes first bottom plate, plummer subassembly with clamping subassembly all install in first bottom plate, plummer subassembly still includes second bottom plate and adjusting screw, the sponge set up in on the second bottom plate, adjusting screw passes the second bottom plate and butt first bottom plate, adjusting screw is used for adjusting the horizontal height of second bottom plate.

As an optional technical scheme, the plummer subassembly includes plummer and shockproof rubber pad, shockproof rubber pad install in the second bottom plate, the plummer install in shockproof rubber pad, the sponge install in the inside of plummer, the fourth driving piece install in the second bottom plate.

As an optional technical scheme, the clamping assembly comprises a fifth driving piece, a sixth driving piece and a third clamping jaw, wherein the sixth driving piece and the detection assembly are both installed at the output end of the fifth driving piece, the fifth driving piece is used for driving the sixth driving piece and the detection assembly to be close to the bearing table assembly, the third clamping jaw is installed at the output end of the sixth driving piece, and the sixth driving piece is used for driving the third clamping jaw to clamp the plug assembly.

The invention has the beneficial effects that:

the invention provides a motor vibration testing mechanism, which comprises a bearing table assembly, a clamping assembly and a detection assembly, wherein the motor is flexibly supported by a sponge, the motor is horizontally arranged on the sponge, vibration generated during operation of the motor is basically not interfered by the limitation of the sponge, and vibration data acquired by an accelerometer are reliable and real; the profile modeling piece is adapted with the outer wall of motor, and the profile modeling piece can be stably attached in the outer wall of motor, and the vibration that produces when the motor operation is transmitted accelerometer through the profile modeling piece to improve vibration's transmission efficiency and reliability. When the motor vibration testing mechanism is used, the motor is firstly placed in the sponge, the clamping assembly pushes the plug assembly to be close to the bearing table assembly, so that the conductive terminal of the plug assembly is inserted into the motor, then the first driving piece drives the profiling sheet to be attached to the outer wall of the motor, the plug assembly is electrified to start the motor, vibration is generated after the motor starts to run, the vibration generated by the motor is transmitted to the accelerometer through the profiling sheet, and the accelerometer acquires vibration data of the motor, so that the purpose of testing the motor vibration is achieved. The motor vibration testing mechanism has high testing efficiency and reliable testing result.

Drawings

The invention is described in further detail below with reference to the drawings and examples;

fig. 1 is a schematic structural diagram of a motor vibration testing mechanism according to an embodiment;

FIG. 2 is a left side view of a motor vibration testing mechanism according to an embodiment;

FIG. 3 is a front view of a motor vibration testing mechanism (third drive and plug not shown) according to an embodiment;

fig. 4 is a schematic view of a part of a motor vibration testing mechanism according to an embodiment.

In the figure:

100. a plug assembly;

1. a carrier assembly; 11. a sponge; 111. a limit groove; 12. a third driving member; 13. a plug; 14. a fourth driving member; 15. a second jaw; 16. a second base plate; 17. adjusting a screw; 18. a bearing seat; 19. a shockproof rubber pad;

2. clamping the assembly; 21. a fifth driving member; 22. a sixth driving member; 23. a third jaw; 24. a hydraulic buffer;

3. a detection assembly; 31. a first driving member; 32. an accelerometer; 33. profiling sheets; 34. a connecting plate; 35. a connecting rope; 36. a second driving member; 37. a first jaw;

4. a first base plate;

5. a photoelectric sensor.

Detailed Description

In order to make the technical problems solved by the present invention, the technical solutions adopted and the technical effects achieved more clear, the technical solutions of the embodiments of the present invention will be described in further detail below with reference to the accompanying drawings, and it is obvious that the described embodiments are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to fall within the scope of the invention.

In the description of the present invention, unless explicitly stated and limited otherwise, the terms "connected," "connected," and "fixed" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

In the present invention, unless expressly stated or limited otherwise, a first feature "above" or "below" a second feature may include both the first and second features being in direct contact, as well as the first and second features not being in direct contact but being in contact with each other through additional features therebetween. Moreover, a first feature being "above," "over" and "on" a second feature includes the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly under and obliquely below the second feature, or simply means that the first feature is less level than the second feature.

In the description herein, it should be understood that the terms "upper," "lower," "left," "right," and the like are based on the orientation or positional relationship shown in the drawings, and are merely for convenience of description and to simplify the operation, rather than to indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the invention. Furthermore, the terms "first," "second," and the like, are used merely for distinguishing between descriptions and not for providing a special meaning.

In the description herein, reference to the term "one embodiment," "an example," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples.

The technical scheme of the invention is further described below by the specific embodiments with reference to the accompanying drawings.

As shown in fig. 1 to 4, the present embodiment provides a motor vibration testing mechanism, which includes a bearing table assembly 1, a clamping assembly 2 and a detecting assembly 3, wherein the bearing table assembly 1 includes a sponge 11, and the sponge 11 is used for supporting a motor; the clamping assembly 2 is arranged on one side of the bearing table assembly 1, and the clamping assembly 2 is used for clamping and pushing the plug assembly 100 to be close to the bearing table assembly 1 so that the conductive terminal of the plug assembly 100 can be inserted into the motor; the detection component 3 is arranged on one side of the bearing table component 1, the detection component 3 comprises a first driving piece 31, an accelerometer 32 and a profiling piece 33, the accelerometer 32 is arranged at the output end of the first driving piece 31, the profiling piece 33 is arranged at the accelerometer 32, the first driving piece 31 is used for driving the profiling piece 33 to be attached to the outer wall of the motor, and the accelerometer 32 is used for detecting the vibration of the motor.

Specifically, in the embodiment, the sponge 11 is adopted to flexibly support the motor, the motor is horizontally arranged on the sponge 11, vibration generated during operation of the motor is basically not limited or interfered by the sponge 11, and vibration data acquired by the accelerometer 32 are reliable and real; the profile modeling piece 33 and the outer wall adaptation of motor, profile modeling piece 33 can be stably attached to the outer wall of motor, and the vibration that the motor produced when running transmits accelerometer 32 through profile modeling piece 33 to improve vibration's transmission efficiency and reliability. When the motor vibration testing mechanism of the embodiment is used, a motor is firstly placed in a sponge 11, the plug assembly 100 is installed in the output of the clamping assembly 2, the motor vibration testing mechanism is started to operate, the clamping assembly 2 firstly pushes the plug assembly 100 to be close to the bearing table assembly 1, so that the conductive terminal of the plug assembly 100 is inserted into the motor, then the first driving piece 31 drives the profiling piece 33 to be attached to the outer wall of the motor, the clamping assembly 2 releases the plug assembly 100, the plug assembly 100 is electrified to start the motor, vibration is generated after the motor starts to operate, the vibration generated by the motor is transmitted to the accelerometer 32 through the profiling piece 33, and the accelerometer 32 acquires vibration data of the motor, so that the purpose of testing the motor vibration is achieved. The motor vibration testing mechanism of the embodiment has high testing efficiency and reliable testing result.

Optionally, the detecting assembly 3 further includes a connecting plate 34 and a connecting rope 35, the connecting plate 34 is mounted at an output end of the first driving member 31, the first driving member 31 drives the connecting plate 34 to be close to the sponge 11 along a vertical direction, one end of the connecting rope 35 is connected with the connecting plate 34, the other end of the connecting rope 35 is connected with the accelerometer 32, and the accelerometer 32 is suspended above the sponge 11.

Alternatively, the first driving member 31 is a cylinder or a linear driving member, and in this embodiment, the first driving member 31 is a cylinder.

In automated production facilities, most drives have a fixed stroke, and the drive can only drive the target a fixed distance. Therefore, in order to expand the application range of the motor vibration testing mechanism, under the condition that the driving stroke of the first driving piece 31 is not regulated, vibration testing can be carried out on motors with various specifications, the connecting rope 35 is utilized to connect the profiling piece 33 and the accelerometer 32, the gravity of the profiling piece 33 and the accelerometer 32 straightens the connecting rope 35, when the specifications of the tested motors are different, the positions of the accelerometer 32 and the profiling piece 33 can be regulated through the connecting rope 35, the motor with larger diameter is placed on the sponge 11, the distance that the first driving piece 31 drives the connecting plate 34 to move downwards along the vertical direction is unchanged, and as the accelerometer 32 is connected through the connecting rope 35, the accelerometer 32 and the profiling piece 33 can be prevented from being directly driven by the first driving piece 31 to impact the outer wall of the motor, the situation that the accelerometer 32 is crushed is avoided, and whether the connecting rope 35 stretches the accelerometer 32 and the profiling piece 33 does not need manual regulation, and the motor can be tested after being placed on the sponge 11. In other embodiments, the detecting component 3 further includes a spring, one end of the spring is connected with the output end of the first driving piece 31, the other end of the spring is connected with the accelerometer 32, and the accelerometer 32 is connected with the spring to perform vibration test on motors with different specifications, but the spring can apply elastic thrust to the motors with different specifications, so that a certain influence is generated on the detection result.

Optionally, the detecting assembly 3 further includes a second driving member 36 and a first clamping jaw 37, the second driving member 36 is mounted at an output end of the first driving member 31, the first clamping jaw 37 is mounted at an output end of the second driving member 36, and the second driving member 36 is used for driving the first clamping jaw 37 to clamp the accelerometer 32. After the profiling sheet 33 is abutted against the top outer wall of the motor, the connecting rope 35 is loosened, if the motor is directly started at this time, vibration generated by the motor can enable the profiling sheet 33 to deviate from the top outer wall of the motor, or the profiling sheet 33 and the accelerometer 32 completely follow the motor to vibrate, so that the accelerometer 32 cannot accurately acquire vibration information of the motor.

Alternatively, the second driving member 36 is a cylinder.

Optionally, the top of sponge 11 is provided with spacing recess 111, and spacing recess 111 is used for holding the motor, avoids the motor to produce on sponge 11 and slides.

Optionally, the bearing platform assembly 1 further includes a third driving member 12 and a plug 13, the third driving member 12 is disposed on one side of the sponge 11 away from the clamping assembly 2, the plug 13 is mounted at an output end of the third driving member 12, and the third driving member 12 is used for driving the plug 13 to tightly prop against the motor. When the clamping assembly 2 inserts the conductive terminal of the plug assembly 100 into the motor, the motor is subjected to axial acting force, and in order to prevent the motor from being separated from the sponge 11, the motor is propped and limited by the third driving piece 12 and the plug 13, so that the motor is ensured to be capable of completing vibration test in the limiting groove 111.

Alternatively, the third driving member 12 is a cylinder or a linear driving member, and in this embodiment, the third driving member 12 is a cylinder.

Optionally, the carrying platform assembly 1 further includes a fourth driving member 14 and a second clamping jaw 15, the second clamping jaw 15 is mounted at an output end of the fourth driving member 14, and the fourth driving member 14 is used for driving the second clamping jaw 15 to clamp two side walls of the motor. When the clamping assembly 2 inserts the conductive terminal of the plug assembly 100 into the motor, the motor is subjected to axial acting force, in order to avoid the motor from being separated from the sponge 11, the motor is clamped by the fourth driving piece 14 and the second clamping jaw 15, and after the conductive terminal of the plug assembly 100 is inserted into the motor, the fourth driving piece 14 drives the second clamping jaw 15 to release the motor, so that the follow-up vibration test of the motor can be smoothly implemented.

Optionally, the fourth driving member 14 is a cylinder.

In this embodiment, the sponge 11 is provided with an avoidance groove along the vertical direction, the fourth driving member 14 is located at the bottom of the sponge 11, and the second clamping jaw 15 is penetrated in the avoidance groove.

In this embodiment, the second clamping jaws 15 are arranged in two groups, wherein one group of second clamping jaws 15 is arranged at one end of the sponge 11 close to the clamping assembly 2, and the other group of second clamping jaws 15 is arranged at one end of the sponge 11 far away from the clamping assembly 2, so that the clamping force on the motor is improved, and the motor is prevented from shifting in the limiting groove 111.

Optionally, the motor vibration testing mechanism includes first bottom plate 4, and plummer subassembly 1 and clamping subassembly 2 are all installed in first bottom plate 4, and plummer subassembly 1 still includes second bottom plate 16 and adjusting screw 17, and sponge 11 sets up on second bottom plate 16, and adjusting screw 17 passes second bottom plate 16 and butt first bottom plate 4, and adjusting screw 17 is used for adjusting the horizontal height of second bottom plate 16. When the motor is too large in size and the positions of the accelerometer 32 and the profiling piece 33 cannot be adjusted through the connecting rope 35, the horizontal height of the second bottom plate 16 can be changed through manual operation of the adjusting screw 17, and the adjustment of the basic height is completed.

Alternatively, the bearing table assembly 1 comprises a bearing seat 18 and a shockproof rubber pad 19, the shockproof rubber pad 19 is mounted on the second bottom plate 16, the bearing seat 18 is mounted on the shockproof rubber pad 19, the sponge 11 is mounted inside the bearing seat 18, and the fourth driving piece 14 is mounted on the second bottom plate 16. Specifically, the third driving member 12 is mounted on the second bottom plate 16, and the vibration-proof rubber pad 19 is used to support the bearing seat 18, so that the bearing seat 18 is prevented from being impacted by external vibration, and the installation stability of the sponge 11 in the bearing seat 18 is ensured.

Optionally, the clamping assembly 2 includes a fifth driving member 21, a sixth driving member 22, and a third clamping jaw 23, where the sixth driving member 22 and the detecting assembly 3 are both mounted at an output end of the fifth driving member 21, the fifth driving member 21 is used to drive the sixth driving member 22 and the detecting assembly 3 to approach the plummer assembly 1, the third clamping jaw 23 is mounted at an output end of the sixth driving member 22, and the sixth driving member 22 is used to drive the third clamping jaw 23 to clamp the plug assembly 100.

Specifically, the plug assemblies 100 with different specifications are matched with motors with different specifications, so that the plug assemblies 100 are clamped by the third clamping jaw 23, and the plug assemblies 100 are convenient to replace; the sixth driving member 22 drives the third clamping jaw 23 to release the plug assembly 100 and then starts the motor, so that vibration test of the motor is prevented from being influenced.

Optionally, the clamping assembly 2 further includes a support plate, on which a sliding rail slider and an oil buffer 24 are mounted, and the fifth driving member 21 is mounted on the support plate, and the sixth driving member 22 and the detecting assembly 3 are both disposed on the sliding rail slider, and the oil buffer 24 is used for buffering driving force of the fifth driving member 21 to the sixth driving member 22 and the detecting assembly 3.

Optionally, a photoelectric sensor 5 is installed on the bearing seat 18, and the photoelectric sensor 5 is used for detecting whether the sponge 11 is loaded with a motor.

Furthermore, the foregoing description of the preferred embodiments and the principles of the invention is provided herein. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments described herein, but is capable of various obvious changes, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the invention. Therefore, while the invention has been described in connection with the above embodiments, the invention is not limited to the embodiments, but may be embodied in many other equivalent forms without departing from the spirit or scope of the invention, which is set forth in the following claims.

Claims (10)

1. Motor vibration testing mechanism, its characterized in that includes:

a carrying table assembly (1), wherein the carrying table assembly (1) comprises a sponge (11), and the sponge (11) is used for supporting a motor;

the clamping assembly (2) is arranged on one side of the bearing table assembly (1), and the clamping assembly (2) is used for clamping and pushing the plug assembly (100) to be close to the bearing table assembly (1) so that the conductive terminal of the plug assembly (100) is inserted into the motor;

the detection assembly (3) is arranged on one side of the bearing table assembly (1), the detection assembly (3) comprises a first driving piece (31), an accelerometer (32) and a profiling piece (33), the accelerometer (32) is arranged at the output end of the first driving piece (31), the profiling piece (33) is arranged at the accelerometer (32), the first driving piece (31) is used for driving the profiling piece (33) to be attached to the outer wall of the motor, and the accelerometer (32) is used for detecting vibration of the motor.

2. The motor vibration testing mechanism according to claim 1, wherein the detecting assembly (3) further comprises a connecting plate (34) and a connecting rope (35), the connecting plate (34) is mounted at the output end of the first driving member (31), the first driving member (31) drives the connecting plate (34) to be close to the sponge (11) along the vertical direction, one end of the connecting rope (35) is connected with the connecting plate (34), the other end of the connecting rope (35) is connected with the accelerometer (32), and the accelerometer (32) is hung above the sponge (11).

3. The motor vibration testing mechanism according to claim 2, wherein the detecting assembly (3) further comprises a second driving member (36) and a first clamping jaw (37), the second driving member (36) is mounted at the output end of the first driving member (31), the first clamping jaw (37) is mounted at the output end of the second driving member (36), and the second driving member (36) is used for driving the first clamping jaw (37) to clamp and fix the accelerometer (32).

4. Motor vibration testing mechanism according to claim 1, characterized in that the top of the sponge (11) is provided with a limit groove (111), which limit groove (111) is adapted to accommodate the motor.

5. The motor vibration testing mechanism according to claim 1, wherein the bearing table assembly (1) further comprises a third driving member (12) and a plug (13), the third driving member (12) is arranged on one side, far away from the clamping assembly (2), of the sponge (11), the plug (13) is mounted at the output end of the third driving member (12), and the third driving member (12) is used for driving the plug (13) to jack the motor tightly.

6. Motor vibration testing mechanism according to claim 1, characterized in that the carrier assembly (1) further comprises a fourth driving member (14) and a second clamping jaw (15), the second clamping jaw (15) is mounted at the output end of the fourth driving member (14), and the fourth driving member (14) is used for driving the second clamping jaw (15) to clamp two side walls of the motor.

7. The motor vibration testing mechanism according to claim 6, wherein the second clamping jaws (15) are arranged in two groups, one group of the second clamping jaws (15) is arranged at one end of the sponge (11) close to the clamping assembly (2), and the other group of the second clamping jaws (15) is arranged at one end of the sponge (11) far away from the clamping assembly (2).

8. The motor vibration testing mechanism according to claim 6, characterized in that the motor vibration testing mechanism comprises a first bottom plate (4), the bearing table assembly (1) and the clamping assembly (2) are both installed on the first bottom plate (4), the bearing table assembly (1) further comprises a second bottom plate (16) and an adjusting screw (17), the sponge (11) is arranged on the second bottom plate (16), the adjusting screw (17) penetrates through the second bottom plate (16) and abuts against the first bottom plate (4), and the adjusting screw (17) is used for adjusting the horizontal height of the second bottom plate (16).

9. The motor vibration testing mechanism according to claim 8, wherein the bearing table assembly (1) comprises a bearing seat (18) and a shockproof rubber pad (19), the shockproof rubber pad (19) is mounted on the second bottom plate (16), the bearing seat (18) is mounted on the shockproof rubber pad (19), the sponge (11) is mounted inside the bearing seat (18), and the fourth driving member (14) is mounted on the second bottom plate (16).

10. The motor vibration testing mechanism according to claim 8, wherein the clamping assembly (2) comprises a fifth driving member (21), a sixth driving member (22) and a third clamping jaw (23), the sixth driving member (22) and the detecting assembly (3) are both mounted at the output end of the fifth driving member (21), the fifth driving member (21) is used for driving the sixth driving member (22) and the detecting assembly (3) to be close to the carrying table assembly (1), the third clamping jaw (23) is mounted at the output end of the sixth driving member (22), and the sixth driving member (22) is used for driving the third clamping jaw (23) to clamp the plug assembly (100).

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