CN219284878U - Sample loading and magnetic field detection device - Google Patents

Abstract

The utility model relates to a sample loading and magnetic field detecting device which comprises a base, and a stretching unit, a bending unit and a detecting unit which are arranged on the base. Wherein the stretching unit and the bending unit can apply a stretching load and a bending load to the sample respectively or simultaneously, so that the sample is subjected to stretching deformation and bending deformation. The detection unit comprises a displacement sensor which is arranged on the stretching unit and can detect the deformation quantity of the sample, and a magnetic field sensor which can monitor the magnetic field of the surface of the sample.

Description

Sample loading and magnetic field detection device

Technical Field

The present utility model relates to a sample loading and magnetic field detecting device.

Background

In the industrial production process, operators need to detect the mechanical properties or the surface magnetic fields of samples of different materials. In the detection process, an operator generally needs to stretch or bend a sample to detect the mechanical properties of the sample, and in this process, the surface magnetic field of the sample is detected at the same time to obtain a magnetic field change curve.

The existing detection equipment is difficult to stretch and bend the sample in the detection process at the same time, so that the detection steps are complicated. Meanwhile, the existing equipment is difficult to accurately control the distance between the magnetic field detection equipment and the sample in the magnetic field detection process, so that the lift-off value is difficult to control, and the error of surface magnetic field detection is larger.

Disclosure of Invention

The present utility model is directed to a sample loading and magnetic field detecting device. The sample loading and magnetic field detecting device can effectively simplify the detecting steps and improve the detecting precision.

According to the utility model, a device for loading and detecting a magnetic field by a sample is provided, which comprises a base, and a stretching unit, a bending unit and a detecting unit which are arranged on the base.

Wherein the stretching unit and the bending unit can apply a stretching load and a bending load to the sample respectively or simultaneously, so that the sample is subjected to stretching deformation and bending deformation. The detection unit comprises a displacement sensor which is arranged on the stretching unit and can detect the deformation quantity of the sample, and a magnetic field sensor which can monitor the magnetic field of the surface of the sample.

In a preferred embodiment, the stretching unit comprises a front plate body and a rear plate body which are separated and oppositely arranged, clamping jaws capable of forming fixed connection with the end parts of the two axial ends of the sample are arranged on the front plate body and the rear plate body, and a first power piece capable of driving the clamping jaws to move to stretch the sample is arranged on the front plate body and/or the rear plate body.

In a preferred embodiment, first through holes are respectively arranged on the side walls of the front plate body and the rear plate body, and the first ends of the clamping jaws can penetrate through the first through holes and are connected with the first power piece.

The second end of the clamping jaw is provided with a clamping groove allowing the end to be inserted, and the sample is connected with the clamping jaw through the clamping groove.

In a preferred embodiment, a first fixing pin is also provided on the clamping jaw, which is arranged to be able to penetrate the clamping groove and the end of the sample at the same time, by means of which the clamping jaw and the sample form a fixed connection.

In a preferred embodiment, a second fixing pin penetrating the front plate body and the rear plate body along the radial direction of the first through hole is further arranged on the front plate body and the rear plate body respectively, and a second through hole is further arranged on the clamping jaw and is arranged to penetrate through the second through hole so as to realize connection between the clamping jaw and the front plate body and the rear plate body.

The second through hole is provided in an elongated shape such that the second fixing pin can move within the second through hole.

In a preferred embodiment, a tightening nut is further provided between the first power member and the clamping jaw.

In a preferred embodiment, the bending unit comprises a movable part and a first power part connected to the movable part, wherein the movable part can be connected with the axial middle part of the sample and can move along the radial direction of the sample to a direction approaching to the sample under the driving of the first power part.

In a preferred embodiment, the moveable member is configured in a generally "I" shape that includes a first plate proximal to the sample and a second plate distal to the sample, and a linkage connected between the first plate and the second plate.

In a preferred embodiment, a fixing plate is further disposed at one end, far away from the first plate, of the second plate, and a plurality of fixing rods are disposed on the fixing plate and can be respectively abutted to side walls on two sides of the second plate, so that the second plate can be clamped.

In a preferred embodiment, a pressure sensor is also provided on the first power member.

In a preferred embodiment, the displacement sensor is provided as a laser displacement sensor comprising a light source capable of emitting a probe beam and a baffle capable of blocking the beam, the baffle being provided on the sample so as to be movable with stretching of the sample.

In a preferred embodiment, a control assembly is further connected to the magnetic field sensor, so that the magnetic field sensor can move along the axial direction of the sample under the drive of the control assembly.

In a preferred embodiment, the control assembly comprises a first slide rail and a slider fixedly connected with the magnetic field sensor and arranged on the first slide rail.

The sliding block is connected with a second power piece so as to move along the first sliding rail under the drive of the second power piece.

In a preferred embodiment, a distance sensor capable of monitoring the lift-off value of the magnetic field sensor is also connected to the magnetic field sensor.

In a preferred embodiment, a second sliding rail perpendicular to the first sliding rail is further arranged on the first sliding rail, and a second power piece is arranged on the second sliding rail, so that the first sliding rail can move along the second sliding rail under the driving of the second power piece.

In a preferred embodiment, the second power member is provided as a stepper motor.

Drawings

The present utility model will be described below with reference to the accompanying drawings.

FIG. 1 shows a schematic diagram of a sample loading and magnetic field detection device according to one embodiment of the utility model.

Fig. 2 is a schematic diagram of a stretching unit of the sample loading and magnetic field detecting device shown in fig. 1.

Fig. 3 is a schematic view of the jaws of the drawing unit shown in fig. 2.

Fig. 4 is a schematic diagram of a bending unit of the sample loading and magnetic field detecting device shown in fig. 1.

Fig. 5 is a schematic diagram of a magnetic field sensor of the sample loading and magnetic field detection device shown in fig. 1.

In this application, all of the figures are schematic drawings which are intended to illustrate the principles of the utility model and are not to scale.

Detailed Description

The utility model is described below with reference to the accompanying drawings. Herein, the term "upper end" or the like means an end near the base; and the term "lower end" or the like means an end remote from the base.

FIG. 1 shows a schematic diagram of a sample loading and magnetic field detection device 100 according to one embodiment of the utility model. As shown in fig. 1, the detection device 100 includes a base 10. A stretching unit 20, a bending unit 30, and a detecting unit 40 are respectively fixed to the base 10.

Wherein the stretching unit 20 and the bending unit 30 can apply a stretching load and a bending load to the sample 1 to be detected separately or simultaneously, thereby causing the sample 1 to undergo stretching deformation and bending deformation. At the same time, the detection unit 40 can detect the deformation amount of the sample 1 and the surface magnetic field change process in the deformation process in real time, so as to obtain the mechanical property and the magnetic field change curve of the sample.

Fig. 2 is a schematic diagram of the stretching unit 20 of the sample loading and magnetic field detection device 100 shown in fig. 1. As shown in fig. 2, the stretching unit 20 includes a front plate body 21 and a rear plate body 22 which are arranged opposite to each other. A gap 23 for accommodating the sample 1 is formed between the front plate body 21 and the rear plate body 22 by being disposed apart from the front plate body 21 and the rear plate body 22.

Clamping jaws 24 are respectively provided at one ends of the front plate body 21 and the rear plate body 22 near the gap 23. Specifically, first through holes 211 are respectively provided on the side walls of the front plate body 21 and the rear plate body 22, and the first ends 241 of the clamping jaws 24 can be connected to the first through holes 211. Meanwhile, the clamping jaw 24 is provided to be movable within the through hole 211 with respect to the through hole 211 such that the first end 241 of the clamping jaw 24 can pass through the first through hole 211.

As shown in fig. 2, the second end 242 of the jaw 24 extending into the gap 23 is arranged to form a fixed connection with the end 11 of the sample 1. Thereby, the clamping jaws 24 on the front plate body 21 and the rear plate body 22 can fix both ends of the sample 1 at the same time, and the clamping jaws 24 and the sample 1 are fixedly connected.

It will be readily appreciated that, when the clamping jaw 24 is fixedly connected to the sample 1, the distance between the two clamping jaws 24 on the front plate body 21 and the rear plate body 22 increases as the clamping jaw 24 moves away from the gap 23 relative to the through hole 211, so that the function of stretching the sample 1 can be achieved.

As shown in fig. 1, a first power member 221 is further provided on the front plate body 21 and the rear plate body 22, respectively. The first power member 221 may be, for example, a hydraulic cylinder. The first end 241 of the jaw 24 is configured to form a fixed connection with the first power member 221. Thus, the first power member 221 can provide power for stretching the sample 1, thereby realizing biaxial stretching of the sample 1.

In the present utility model, the first power member 221 may be provided only on the front plate body 21 or the rear plate body 22, and the tensile deformation of the sample 1 may be similarly achieved by unidirectional stretching of one first power member 221.

In a preferred embodiment, as shown in fig. 2, a tightening nut 222 is also provided between the first power member 221 and the jaw 24. Thus, before stretching the sample 1, the operator can move the clamping jaw 24 by an appropriate displacement in a direction away from the gap 23 by rotating the tightening nut 222 until the clamping jaw 24 stretches the sample 1 to a tight state. With this arrangement, the initial dimension of the specimen 1 before stretching is obtained more accurately, and further, it is advantageous to more accurately detect the deformation amount of the specimen 1 after stretching.

The structure and principle of the screwing nut 222 are well known to those skilled in the art, and a detailed description thereof will be omitted herein.

Fig. 3 is a schematic view of the jaws 24 of the drawing unit 20 shown in fig. 2. As shown in fig. 2 and 3, in one particular embodiment, the jaws 24 are configured in a rod-like shape. An internal thread (not shown) is provided at the first end 241 of the clamping jaw 24, by means of which internal thread the first end 241 of the clamping jaw 24 is fixedly connected to the first power member 221.

Meanwhile, a clamping groove 243 is formed on the second end 242 of the clamping jaw 24. Thus, the end of the sample 1 can be inserted into the clamping groove 243 and connected to the clamping jaw 24. Further, pin holes 246 allowing the pin shaft to pass through are provided on the side walls of both ends of the clamping groove 243. The clamping jaw 24 and the sample 1 can be fixedly connected by a first fixing pin 244 which simultaneously penetrates the pin hole 246 and the sample 1.

Similarly, second fixing pins 225 are also provided on the front and rear plate bodies 21 and 22, respectively. The two second fixing pins 225 penetrate the front plate body 21 and the rear plate body 22 along the radial direction of the first through hole 211, respectively. At the same time, a second through hole 245 allowing the second fixing pin 225 to pass through is also provided on the clamping jaw 24. Thus, after the clamping jaw 24 extends into the first through hole 211, the second fixing pin 225 can penetrate through the first through hole 211 and the second through hole 245 at the same time, so that the clamping jaw 24 is connected with the front plate body 21 and the rear plate body 22 respectively.

It is easy to understand that by the fixed connection of the second fixing pin 225, the clamping jaw 24 can be prevented from rotating circumferentially relative to the first through hole 211 during the stretching process of the sample 1, and further, the rotation of the sample or kinking caused by the asynchronous rotation of both ends can be prevented, thereby ensuring that the sample 1 is always kept stationary in the circumferential direction.

The second through hole 245 is necessarily provided in an elongated shape so that the second fixing pin 225 can move in the axial direction within the second through hole 245. With this arrangement, the second fixing pin 225 can be prevented from obstructing the movement of the holding jaw 24 in the first through hole 211, and thus the second fixing pin 225 can be prevented from obstructing the normal stretching of the sample 1.

Fig. 4 is a schematic diagram of the bending unit 30 of the sample loading and magnetic field detecting device 100 shown in fig. 1. As shown in fig. 4, the bending unit 30 includes a movable member 31, and a first power member 221 is also connected to the movable member 31. The movable member 31 may be connected to the axial middle portion of the sample 1, and may be driven by the first power member 221 to move along the radial direction (i.e., perpendicular to the stretching direction) of the sample 1 in a direction approaching the sample 1.

As the movable member 31 moves, it can press the specimen 1, thereby causing bending deformation of the specimen 1.

As shown in fig. 4, in the present utility model, the movable member 31 is constructed in a substantially "i" shape including a first plate 311 close to the sample 1 and a second plate 312 far from the sample, and a link 313 connected between the first plate 311 and the second plate 312.

It is easy to understand that the contact area between the movable member 31 and the sample 1 can be increased by the first plate 311 during the process of pressing the sample 1 by the movable member 31, so that the pressure concentration caused by the too small contact area can be prevented, and the risk of breaking the sample 1 can be reduced.

As shown in fig. 2 and 4, in the present utility model, a side plate 226 is further provided between the front plate 21 and the rear plate 22, and a slot 227 communicating with the gap 23 is provided in the side plate 226, so that the first plate 311 can extend into the gap 23 through the slot 227, thereby being able to be connected to the sample 1.

A fixing plate 314 is further disposed at an end of the second plate 312 away from the first plate 311. The fixing plate is provided with a plurality of fixing rods 315, and the fixing rods 315 are provided to extend in a direction approaching the second plate 312 so as to be connected to the side plate 226. Meanwhile, an end of the fixing rod 315 near the side plate 226 is configured as a connection male 229, and a threaded hole (not shown) corresponding to the connection male 229 is provided on the side plate 226. Thus, when the fixing rod 315 is connected to the side plate 226, it can be fixedly connected to the side plate 226 through the connection male 229, thereby achieving a fixed connection between the stretching unit 20 and the bending unit 30.

In a preferred embodiment, the plurality of fixing rods 315 can be simultaneously connected to the side walls 316 at both sides of the second plate 312, respectively. Thus, the second plate 312 can be held by the plurality of fixing rods 315, and the second plate 312 is prevented from rotating relative to the fixing plate 314.

Through this kind of setting, the operation personnel can be through fixing fixed plate 314 and then fixed moving part 31 prevents moving part 31 because the rotation that factors such as atress inequality or vibration lead to, thereby prevent first plate 311 extrudees sample 1's in-process for sample 1 rotation, leads to sample 1 to take place to rotate.

As shown in fig. 4, in a preferred embodiment, a pressure sensor 32 is also provided on the first power member 31. The pressure sensor 32 may be connected to the connecting rod 313, for example. The pressure sensor 32 can measure the pressure applied to the connecting rod 313 and thus the pressure applied to the sample 1 in real time.

As shown in fig. 1, the detection unit 40 includes a displacement sensor 42 provided on the stretching unit 20 and capable of detecting the deformation amount of the sample, and a magnetic field sensor 44 capable of monitoring the magnetic field of the surface of the sample 1.

As shown in fig. 1, the displacement sensor 42 is provided as a laser displacement sensor 43. The laser displacement sensor 43 includes a light source 431 capable of emitting a probe beam and a shutter 432 capable of blocking the beam.

Specifically, the number of the light sources 431 is two, and the two light sources 431 are respectively disposed on the front plate body 21 and the rear plate body 22 and are capable of emitting light beams in a direction approaching the gap 23. The baffle 432 is provided to be connected at the end portions of both ends of the sample 1 and is provided to extend upward so as to block the light beam emitted from the light source 431.

The laser displacement sensor 43 is capable of reading the distance between the light source 431 and the shutter 432 in real time. When the sample 1 is stretched and elongated, the barrier 432 located on the sample 1 near the front plate 21 is moved in a direction toward the front plate 21, so that the distance between the barrier 432 and the light source 431 on the front plate 21 is reduced, the reduction value of which is denoted as L1. Similarly, as the sample 1 is elongated, the shutter 432 positioned on the sample 1 near the rear plate 22 is moved in a direction toward the rear plate 22, so that the distance between the shutter 432 and the light source 431 on the front plate 22 is reduced, and the reduced value is denoted as L2.

Thus, the elongation Δl=l1+l2 of the sample 1 can be obtained.

As described above, the laser displacement sensor 43 can accurately and in real time obtain the deformation amount of the sample 1.

The operator can adjust the positions of the two baffles 432 according to the detection requirement, thereby detecting the change in the length of the sample 1 between the two baffles 432. It will be readily appreciated that by adjusting the positions of the two baffles 432, a change in the length of any one section of sample 1 can be detected.

Fig. 5 is a schematic diagram of the magnetic field sensor 44 of the sample loading and magnetic field detection device 100 shown in fig. 1. As shown in fig. 5, a control unit 45 is also connected to the magnetic field sensor 44.

As shown in fig. 5, the control assembly 45 includes a first slide rail 451 disposed along the axial direction of the specimen 1, and a slider 452 provided on the first slide rail 451. The magnetic field sensor 44 is fixedly connected with the control assembly 45 and the slider through a bracket 441. Meanwhile, a second power member 453 is further connected to the slider 452, so that the slider 452 can move along the first sliding rail 451 under the driving of the second power member 453, and further drive the magnetic field sensor 44 to move synchronously.

As shown in fig. 1, by controlling the movement of the magnetic field sensor 44, the magnetic field sensor 44 can be made to sweep across the surface of the sample 1, thereby detecting a magnetic field at any position on the surface of the sample 1.

As shown in fig. 5, a second slide rail 455 perpendicular to the first slide rail 451 is further provided on both ends of the first slide rail 451. The second sliding rail 455 is also provided with a second power member 453, so that the first sliding rail 451 can move along the second sliding rail 455 under the driving of the second power member 453.

Since the second sliding rail 455 is perpendicular to the first sliding rail 451, when the first sliding rail 451 moves along the second sliding rail 455, it can change the distance between the magnetic field sensor 44 and the sample 1, so as to adjust the lift-off value of the magnetic field sensor 44, so that the surface magnetic field variation curve under different lift-off values can be measured according to actual needs.

In a preferred embodiment, a distance sensor 442 is also connected to the magnetic field sensor 44. The distance sensor 442 may likewise be configured as a laser displacement sensor. The distance between the laser displacement sensor and the sample 1 can be measured in real time through the laser displacement sensor, so that the change curve of the surface magnetic field of the sample 1 under different lift-off values can be measured.

Moreover, since the sample 1 is often in a bent state during the detection process, the operator can adjust the position of the magnetic field sensor 44 in real time through the second slide rail 455 during the moving process of the magnetic field sensor 44, so that the distance between the magnetic field sensor 44 and the sample 1 is kept constant and is not affected by the shape of the sample 1. Thus, a surface magnetic field change curve at different positions of the sample 1 at a fixed lift-off value can be obtained.

In a preferred embodiment, the second power member 453 is configured as a stepper motor. Such stepper motors can convert the electrical pulse signals into corresponding angular or linear displacements, thereby enabling precise control of the movement of the magnetic field sensor 44.

The operation of the sample loading and magnetic field detecting apparatus 100 according to the present utility model will be briefly described below.

The sample loading and magnetic field detecting apparatus 100 of the present utility model is used to deform a sample 1 and detect the deformation amount and the surface magnetic field during the deformation of the sample 1.

During the test, the operator first needs to mount the sample 1 on the clamping jaw 34 while rotating the tightening nut 222 so that the sample 1 is in a tight state. The deformation of the sample is then controlled by the stretching unit 20 and the bending unit 30, respectively. In this process, the deformation amount and the surface magnetic field of the sample 1 can be detected in real time by the detection unit 40.

Finally, it should be noted that the above description is only of a preferred embodiment of the utility model and is not to be construed as limiting the utility model in any way. Although the utility model has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the techniques described in the foregoing examples, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (16)

1. A sample loading and magnetic field detection device (100), comprising:

a base (10), and,

a stretching unit (20), a bending unit (30) and a detecting unit (40) which are arranged on the base,

wherein the stretching unit and the bending unit can apply a stretching load and a bending load to the sample (1) respectively or simultaneously so that the sample is subjected to stretching deformation and bending deformation,

the detection unit comprises a displacement sensor (42) arranged on the stretching unit and capable of detecting deformation of the sample, and a magnetic field sensor (44) capable of monitoring the magnetic field of the surface of the sample.

2. The sample loading and magnetic field detecting device according to claim 1, wherein the stretching unit comprises a front plate body (21) and a rear plate body (22) which are separated and oppositely arranged, clamping jaws (24) which can form fixed connection with the end parts of the two axial ends of the sample are arranged on the front plate body and the rear plate body, and a first power piece which can drive the clamping jaws to move so as to stretch the sample is arranged on the front plate body and/or the rear plate body.

3. The sample loading and magnetic field detecting apparatus according to claim 2, wherein first through holes (211) are provided in side walls of the front plate body and the rear plate body, respectively, first ends (241) of the jaws are provided to be capable of passing through the first through holes and being connected to a first power member,

the second end (242) of the jaw is provided with a clamping groove (243) allowing the end to be inserted, through which clamping groove the sample is connected to the jaw.

4. A sample loading and magnetic field detection device according to claim 3, characterized in that a first fixing pin (244) is also provided on the clamping jaw, which is arranged to be able to penetrate the clamping groove simultaneously, and the end (11) of the sample, by means of which the clamping jaw and the sample form a fixed connection.

5. The sample loading and magnetic field detecting apparatus according to claim 4, wherein a second fixing pin (225) penetrating the front plate body and the rear plate body in a radial direction of the first through hole is further provided on the front plate body and the rear plate body, respectively, a second through hole (245) is further provided on the holding jaw, the second fixing pin is provided to be capable of penetrating the second through hole to thereby achieve connection between the holding jaw and the front plate body and the rear plate body,

the second through hole is provided in an elongated shape such that the second fixing pin can move within the second through hole.

6. The sample loading and magnetic field detection device according to any of claims 2-5, wherein a tightening nut (222) is further provided between the first power member and the clamping jaw.

7. The sample loading and magnetic field detecting device according to any one of claims 1 to 5, wherein the bending unit comprises a movable member (31) and a first power member (221) connected to the movable member, and the movable member can be connected to the axial middle part of the sample and can move along the radial direction of the sample to the direction approaching the sample under the drive of the first power member.

8. The sample loading and magnetic field detecting device according to claim 7, wherein the movable member is configured in a substantially "i" shape including a first plate (311) adjacent to the sample and a second plate (312) distant from the sample, and a link (313) connected between the first and second plates.

9. The sample loading and magnetic field detecting apparatus according to claim 8, wherein a fixing plate (314) is further provided at an end of the second plate body away from the first plate body, a plurality of fixing rods (315) are provided on the fixing plate, and the plurality of fixing rods are provided so as to be capable of being respectively abutted against side walls on both sides of the second plate body, thereby being capable of clamping the second plate body.

10. The sample loading and magnetic field detecting device according to claim 9, wherein a pressure sensor (32) is further provided on the first power member.

11. The sample loading and magnetic field detection device according to any one of claims 1 to 5, wherein the displacement sensor is configured as a laser displacement sensor (43),

the laser displacement sensor includes a light source (431) capable of emitting a probe beam and a shutter (432) capable of blocking the beam, the shutter being provided on the sample so as to be movable with stretching of the sample.

12. The sample loading and magnetic field detecting device according to claim 11, wherein a control component (45) is further connected to the magnetic field sensor, so that the magnetic field sensor can move along the axial direction of the sample under the drive of the control component.

13. The sample loading and magnetic field detection device according to claim 12, wherein the control assembly comprises a first slide (451) and a slider (452) fixedly connected to the magnetic field sensor and disposed on the first slide,

the sliding block is connected with a second power piece (453) so as to move along the first sliding rail under the drive of the second power piece.

14. The sample loading and magnetic field detecting apparatus according to claim 13, wherein a distance sensor (442) capable of monitoring a lift-off value of the magnetic field sensor is further connected to the magnetic field sensor.

15. The sample loading and magnetic field detecting device according to claim 14, wherein a second slide rail (455) perpendicular to the first slide rail is further provided on the first slide rail, and a second power member is provided on the second slide rail, so that the first slide rail can move along the second slide rail under the drive of the second power member.

16. The sample loading and magnetic field detection device of claim 15, wherein the second power member is configured as a stepper motor.

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