CN219435000U - Detection device and detection equipment - Google Patents

Abstract

The utility model discloses a detection device and detection equipment, wherein the detection device is used for detecting a brushless motor, the brushless motor is provided with a cable, the detection device comprises a detection table, a detection assembly and an error detection prevention mechanism, the detection assembly comprises a detection connector and a detection power supply, the detection connector is arranged on the detection table and is connected with the detection power supply, the detection connector is used for being connected with the cable, the error detection prevention mechanism comprises an optical fiber sensor and a control assembly which are electrically connected, the control assembly is respectively and electrically connected with the detection connector and the detection power supply and is used for controlling the on-off of the detection connector and the detection power supply, and the optical fiber sensor is used for detecting the color of the cable. The utility model aims to replace manual inspection of polarity of the power supply of the brushless motor on the basis of carrying out power-on test on the motor by the detection device, thereby avoiding damage of the brushless motor product caused by wrong connection of the anode and the cathode to the electrode, reducing labor intensity and effectively improving detection efficiency.

Description

Detection device and detection equipment

Technical Field

The utility model relates to the technical field of motor testing equipment, in particular to a detection device and detection equipment using the same.

Background

After the assembly of the brushless motor product is completed, the brushless motor product needs to be subjected to an energization test to detect whether the brushless motor product can normally operate. However, in the actual testing process, there is a hidden trouble that the operator connects the direct current power supply with the positive and negative poles of the brushless motor product reversely, when the connection is reversed, the driving board of the brushless motor product may be broken down, the core IC processes low-voltage components such as chips, and even causes the burnout of the brushless motor.

Disclosure of Invention

The utility model mainly aims to provide a detection device and detection equipment, and aims to replace manual inspection of polarity of a power supply connected with a brushless motor on the basis of carrying out power-on test on a motor by the detection device, so that damage of the brushless motor due to wrong connection of positive and negative electrodes is avoided, labor intensity is reduced, and meanwhile, detection efficiency is effectively improved.

To achieve the above object, the present utility model provides a detecting device for detecting a brushless motor having a cable, the detecting device comprising:

a detection table;

the detection assembly comprises a detection connector and a detection power supply, the detection connector is arranged on the detection table and connected with the detection power supply, and the detection connector is used for being connected with the cable; a kind of electronic device with high-pressure air-conditioning system

The error detection prevention mechanism comprises an optical fiber sensor and a control component which are electrically connected, wherein the control component is respectively electrically connected with the detection connector and the detection power supply and is used for controlling the on-off of the detection connector and the detection power supply, and the optical fiber sensor is used for detecting the color of the cable.

In one embodiment, the control assembly is provided with a detection circuit and a control circuit, wherein the detection circuit is electrically connected with the optical fiber sensor and is used for receiving and displaying the detection result of the optical fiber sensor;

the control circuit is respectively and electrically connected with the detection connector and the detection power supply and is used for controlling the on-off of the detection power supply.

In one embodiment, the control assembly includes a signal amplifier and a relay electrically connected, the signal amplifier being electrically connected to the fiber optic sensor and the signal amplifier being electrically connected to the detection power supply to form the detection circuit;

the relay is electrically connected with the detection power supply and the detection connector to form the control circuit;

the signal amplifier is used for receiving the detection result of the optical fiber sensor and controlling the relay to conduct on-off of the detection power supply.

In an embodiment, the signal amplifier and the relay are detachably disposed on the side wall of the detection table, the signal amplifier is disposed adjacent to the optical fiber sensor, and the relay is disposed adjacent to the detection power supply.

In an embodiment, the signal amplifier is provided with a display screen, and the display screen is used for displaying the detection result of the optical fiber sensor.

In an embodiment, the detection table is provided with a detection frame, one end of the detection frame, which is far away from the surface of the detection table, is provided with a detection hole and a clamping groove which are communicated with each other, the optical fiber sensor is provided with a detection head, the detection head stretches into the detection hole and is arranged adjacent to the clamping groove, the clamping groove is used for placing the cable, and the optical fiber sensor is opposite to the cable.

In an embodiment, a clamping portion is disposed at one end of the side wall of the clamping groove away from the detection frame, the clamping portion extends to one side of the detection hole, the cross section of the clamping portion is gradually increased from one end adjacent to the detection hole to the side wall of the clamping groove, and the clamping portion is used for fixing the cable.

In an embodiment, the detection platform comprises a placement platform and an operation platform which are connected, a detection groove is formed in the surface of the placement platform, the detection connector is placed in the detection groove, an open operation space is formed between the surface of the operation platform and the side wall of the placement platform, and the optical fiber sensor is arranged in the operation space.

In an embodiment, the detection joint is provided with a first quick socket adjacent to one end of the operation space, and a second quick socket is provided at one end of the cable away from the brushless motor, and the second quick socket is detachably connected with the first quick socket.

The utility model also proposes a detection device comprising:

a main body; and

the detection device as described above, wherein the detection device is electrically connected to the main body.

The detection device is used for detecting the performance of the brushless motor, the brushless motor is provided with an extended cable, the detection device comprises a detection table and a detection assembly, wherein the detection assembly comprises a detection connector used for being connected with the cable and a detection power supply used for providing power supply, and the detection connector is arranged on the detection table so as to facilitate an operator to detect the brushless motor; the detection device is further provided with an error detection prevention mechanism, the error detection prevention mechanism comprises an optical fiber sensor and a control component which are electrically connected, the control component is electrically connected with a detection joint and a detection power supply respectively, the optical fiber sensor is used for detecting the color of a cable so as to identify whether the cable is correctly connected with the detection joint or not, and the detection result can be transmitted to the control component so as to control the on-off between the detection joint and the detection power supply, thereby realizing the protection of the brushless motor, avoiding the damage of the brushless motor caused by the error connection of the cable and the detection joint, effectively replacing the manual work to access the inspection of the polarity of the power supply of the brushless motor, avoiding the damage of the brushless motor product caused by the error connection electrode, and further improving the detection efficiency.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a detecting device according to an embodiment of the utility model;

FIG. 2 is an enlarged schematic view of FIG. 1 at A;

fig. 3 is a schematic structural diagram of another view of the detection device according to an embodiment of the utility model.

Reference numerals illustrate:

the achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that all the directional indicators in the embodiments of the present utility model are only used to explain the relative positional relationship, movement conditions, etc. between the components in a specific posture, and if the specific posture is changed, the directional indicators are correspondingly changed.

Meanwhile, the meaning of "and/or" and/or "appearing throughout the text is to include three schemes, taking" a and/or B "as an example, including a scheme, or B scheme, or a scheme that a and B satisfy simultaneously.

Furthermore, descriptions such as those referred to as "first," "second," and the like, are provided for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implying an order of magnitude of the indicated technical features in the present disclosure. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

After the assembly of the brushless motor product is completed, the brushless motor product needs to be subjected to an energization test to detect whether the brushless motor product can normally operate. However, in the actual testing process, there is a hidden trouble that the operator connects the direct current power supply with the positive and negative poles of the brushless motor product reversely, when the connection is reversed, the driving board of the brushless motor product may be broken down, the core IC processes low-voltage components such as chips, and even causes the burnout of the brushless motor.

Based on the above concepts and problems, the present utility model proposes a detection apparatus 100. The detection device 100 can also replace manual inspection to judge whether the electrode connected with the brushless motor power supply is correct or not through the set error-preventing detection mechanism 3 while carrying out power-on test on the brushless motor product, and damage caused by the fact that the anode and the cathode of the brushless motor product are connected with the error power supply is effectively avoided.

Referring to fig. 1 to 3, in an embodiment of the present utility model, the detecting device 100 is used for detecting a brushless motor, the brushless motor has a cable 4, the detecting device 100 includes a detecting table 1, a detecting component 2 and an anti-error detecting mechanism 3, the detecting component 2 includes a detecting connector 21 and a detecting power source, the detecting connector 21 is disposed on the detecting table 1 and connected with the detecting power source, the detecting connector 21 is used for being connected with the cable 4, the anti-error detecting mechanism 3 includes an optical fiber sensor 31 and a control component 32 which are electrically connected, the control component 32 is electrically connected with the detecting connector 21 and the detecting power source respectively, for controlling the on-off of the detecting connector 21 and the detecting power source, and the optical fiber sensor 31 is used for detecting the color of the cable 4.

In this embodiment, the brushless motor has a cable 4, the detecting device 100 includes a detecting table 1 and a detecting assembly 2, the detecting assembly 2 includes a detecting connector 21 connected with the cable 4 and a detecting power source for providing power for the brushless motor product, and the detecting connector 21 is disposed on the detecting table 1, and the detecting connector 21 is also connected with the detecting power source.

It will be appreciated that the detecting device 100 is used for detecting whether the brushless motor product can be operated or whether the performance of the brushless motor product meets the standard, and before the operator detects the brushless motor product, the operator needs to connect the cable 4 with the detecting connector 21, typically, two cables 4 of the brushless motor are provided, that is, one connecting to the positive pole of the brushless motor product and one connecting to the negative pole of the brushless motor product; meanwhile, two detection joints 21 are also arranged, one is connected with the brushless motor product positive cable 4, and the other is connected with the brushless motor product negative cable 4; the detection connector 21 connected to the brushless motor product is also connected to the detection power supply, but the brushless motor product is not energized at this time, and the connection between the detection connector 21 and the detection power supply is merely a general interconnection.

It will be appreciated that the test bench 1 is used to house the test connectors 21, and that two test connectors 21 are typically spaced adjacent to the test bench 1 with the end of the test bench that is connected to the cable 4 facing the operator for ease of operation and use by the operator.

In this embodiment, the detection device 100 further includes a false detection preventing mechanism 3, where the false detection preventing mechanism 3 includes an optical fiber sensor 31 and a control component 32 that are electrically connected, and the control component 32 is electrically connected to the detection joint 21 and the detection power supply, respectively.

It can be understood that the optical fiber sensor 31 in the error detection prevention mechanism 3 is used for detecting the color of the cable 4, two cables 4 connected with the anode and the cathode of the brushless motor product are usually different colors, and the corresponding detection connectors 21 also have the colors of the two cables 4, so that an operator can conveniently judge the connection condition of the anode and the cathode of the brushless motor and the anode and the cathode of the detection power supply directly through the colors; specifically, the detecting connector 21 is set to be black and red, the black is connected with the negative electrode of the detecting power supply, the red is connected with the positive electrode of the detecting power supply, meanwhile, the positive cable 4 of the brushless motor product is set to be red, the negative cable 4 of the brushless motor product is black, an operator only needs to connect the red with the red, the black is connected with the black, the positive electrode and the negative electrode of the brushless motor product can be guaranteed not to be reversely connected with the positive electrode and the negative electrode of the detecting power supply, and the brushless motor product can not be damaged due to wrong connection. However, when the operator detects a plurality of brushless motor products repeatedly in a large number, there is a probability of a certain error connection, and the error connection is affected by ambient light and misoperation, so that the black of the brushless motor products is inevitably connected to the red of the detection power supply, and the brushless motor products are damaged due to the error connection.

To above problem, this application detects the cable 4 of brushless motor product through setting up optical fiber sensor 31 to confirm whether operating personnel will detect the positive negative pole of brushless motor product and correspond to the positive negative pole of power, later optical fiber sensor 31 will detect the result and transmit control assembly 32 in, control assembly 32 is connected with detection joint 21 and detection power electricity respectively, make control assembly 32 can be according to the circuit break-make of optical fiber sensor 31's detection result control detection power and detection joint 21, thereby realize the circuit break-make of detection power and brushless motor product. Specifically, the positive electrode of the detection joint 21 is located at the side of the detection table 1 closer to the operator, and the positive electrode of the detection joint 21 is red, when the operator connects the positive and negative cables 4 of the brushless motor product with the detection joint 21 correspondingly, the operator needs to put the cable 4 close to the operator side into the optical fiber sensor 31 to detect the color of the cable 4, if the placed color is detected to be red, the optical fiber sensor 31 informs the control component 32 that the connection is correct, the detection is passed, the control component 32 controls the detection power supply to be communicated with the detection joint 21, and performance detection of the brushless motor product is started; if the color is detected as black, the control component 32 keeps the detection power supply disconnected from the detection connector 21, so that the brushless motor product is effectively protected, and the labor intensity of operators is reduced.

In one embodiment, the control component 32 has a detection circuit and a control circuit, where the detection circuit is electrically connected to the optical fiber sensor 31 and is used for receiving and displaying the detection result of the optical fiber sensor 31; the control circuit is electrically connected with the detection joint 21 and the detection power supply respectively and is used for controlling the on-off of the detection power supply.

It will be appreciated that, as shown in fig. 1 to 3, the control assembly 32 has a detection circuit and a control circuit electrically connected to each other, the detection circuit being electrically connected to the optical fiber sensor 31 for detecting and displaying the detection result of the optical fiber sensor 31; after the detection circuit detects the detection result of the optical fiber sensor 31, the detection result is transmitted to the control circuit, the control circuit is electrically connected with the detection connector 21 and the detection power supply, and the control circuit controls the on/off of the detection power supply and the detection connector 21 through the received detection result, so that the on/off of the detection power supply and the brushless motor product is controlled.

In one embodiment, the control assembly 32 includes a signal amplifier 321 and a relay 322 electrically connected, the signal amplifier 321 is electrically connected to the fiber optic sensor 31, and the signal amplifier 321 is electrically connected to a detection power source to form a detection circuit; the relay 322 is electrically connected to the detection power supply and the detection joint 21 to form a control circuit; the signal amplifier 321 is configured to receive a detection result of the optical fiber sensor 31, and control the relay 322 to switch on or off the detection power supply.

It will be appreciated that, as shown in fig. 3, the relay 322 is electrically connected to the detection power supply and the detection connector 21 to form a control circuit, and at the same time, the relay 322 is electrically connected to the signal amplifier 321 for receiving the detection result sent by the signal amplifier 321; the relay 322 can control the on-off of the detection power supply and the detection connector 21 according to the signal sent by the signal amplifier 321, thereby realizing the control of the on-off of the detection power supply and the brushless motor product.

It will be appreciated that the control assembly 32 includes an electrically connected signal amplifier 321, the signal amplifier 321 being electrically connected to the optical fiber sensor 31 and also being electrically connected to a detection power source to form a detection circuit; the signal amplifier 321 is electrically connected with the detection power supply, so that the detection power supply can supply power to the signal amplifier 321 and the optical fiber sensor 31 to ensure normal and continuous operation, and when the optical fiber sensor 31 detects the color of the cable 4, the detection result is transmitted to the signal amplifier 321, and the signal amplifier 321 displays the detection result and transmits the detection result to the relay 322.

Specifically, the detection principle of the optical fiber sensor 31 and the signal amplifier 321 is that the refractive indexes of light for different colors are utilized to collect optical wave signals and amplify the optical wave signals, the standard value of the optical fiber sensor 31 is 2728, when the optical fiber sensor 31 senses red, the signal value output by the optical fiber sensor 31 in the signal amplifier 321 is 3959, namely, when the signal value 3959 is higher than 2728, the optical fiber sensor 31 determines that the detected cable 4 is red, and at the moment, the signal amplifier 321 and the relay 322 are triggered to output signals; when the red line is removed or the black line is placed, the signal value of the optical fiber will be lower than 2728 because the black light has a lower refractive index and absorbs more light, and the signal amplifier 321 outputs no signal, i.e. the relay 322 keeps the detection joint 21 and the detection power supply disconnected. The positive and negative wiring of the brushless motor product is effectively replaced by manual inspection, the risk of motor damage is reduced, and the labor efficiency is improved.

In one embodiment, the signal amplifier 321 and the relay 322 are detachably disposed on the side wall of the detection stage 1, and the signal amplifier 321 is disposed adjacent to the optical fiber sensor 31, and the relay 322 is disposed adjacent to the detection power source.

It will be appreciated that, as shown in fig. 3, the signal amplifier 321 and the relay 322 are detachably disposed on the side wall of the detection platform 1 or the surface of the detection platform 1, which is not limited herein, for convenience of use, reducing the use of wires and simplifying the overall structure, the signal amplifier 321 is typically disposed near the optical fiber sensor 31, and the relay 322 is disposed near the detection power source, and also near the end of the detection joint 21 far from the connection with the cable 4.

In one embodiment, the signal amplifier 321 is provided with a display screen, and the display screen is used for displaying the detection result of the optical fiber sensor 31. It will be appreciated that the signal amplifier 321 is provided with a display screen for displaying the detection result of the optical fiber sensor 31, that is, the optical wave signal value collected by the optical fiber sensor 31, such as 3959 displayed by red light, or standard value 2728, or other values lower than the standard value. The setting of display screen, the effectual operating personnel that makes things convenient for carries out the secondary inspection, through looking over the numerical value on the display screen, can know the cable 4 colour of test this moment to can judge whether this cable 4 and detection joint 21 overlap joint are correct.

In one embodiment, the inspection bench 1 is provided with an inspection rack 11, one end of the inspection rack 11 far away from the surface of the inspection bench 1 is provided with an inspection hole 111 and a clamping groove 112 which are communicated, the optical fiber sensor 31 is provided with an inspection head, the inspection head extends into the inspection hole 111 and is arranged adjacent to the clamping groove 112, the clamping groove 112 is used for placing the cable 4, and the optical fiber sensor 31 is arranged opposite to the cable 4.

In the present embodiment, as shown in fig. 1 to 3, a detection frame 11 is provided on a side of the detection stage 1 adjacent to the operator, one end of the detection frame 11 away from the surface of the detection stage 1 is provided with a detection hole 111 and a holding groove 112 which are communicated, and the axis of the detection hole 111 and the axis of the holding groove 112 are disposed at an angle. And the optical fiber sensor 31 has a detection head that can be inserted into the detection hole 111 and disposed toward the holding groove 112.

It will be appreciated that the detection hole 111 is used for placing the optical fiber sensor 31, and the detection head provided at the end of the optical fiber sensor 31 may extend into the detection hole 111 and be disposed opposite to the holding groove 112. The clamping groove 112 is used for placing the cable 4, that is, the cable 4 is disposed along a direction perpendicular to the axis of the detection hole 111, so that the detection head can detect the skin color of the cable 4, and thus the detection result is transmitted to the control assembly 32. In addition, the detection head is arranged in the detection hole 111 and keeps a certain distance from the clamping groove 112, so that the detection head is ensured to be in a darker environment and cannot cause detection errors due to abrupt change of ambient light. The design of the clamping groove 112 is convenient for an operator to fix the cable 4 near the optical fiber sensor 31, and can fix the position of the cable 4, so that the error of detection results caused by the abnormal movement of the cable 4 is avoided.

In an embodiment, a clamping portion 1121 is disposed at an end of the side wall of the clamping groove 112 away from the detection frame 11, the clamping portion 1121 extends toward the detection hole 111, the clamping portion 1121 gradually increases in cross section from an end adjacent to the detection hole 111 to the side wall of the clamping groove 112, and the clamping portion 1121 is used for fixing the cable 4.

As can be understood, as shown in fig. 1 to 3, a clamping portion 1121 is provided on a side wall of the clamping groove 112 opposite to the side of the detection hole 111, and the clamping portion 1121 is provided at an end of the side wall of the clamping groove 112 away from the detection frame 11, the clamping portion 1121 also extends toward the side of the detection hole 111, and gradually increases in cross section from an end adjacent to the detection hole 111 to the side wall of the clamping groove 112, such that a narrow channel is formed between the clamping portion 1121 and the detection hole 111, so as to facilitate the placement of the cable 4 into the clamping groove 112 and the fixation of the cable 4; meanwhile, an arc-shaped placement area is formed between the clamping part 1121 and the bottom wall of the clamping groove 112, so that the cable 4 is positioned at a correct detection position, namely, is arranged opposite to the optical fiber sensor 31.

In an embodiment, the detection platform 1 includes a placement platform 12 and an operation platform 13 connected to each other, a detection groove 121 is formed on the surface of the placement platform 12, a detection joint 21 is placed in the detection groove 121, an open operation space 14 is formed on the surface of the operation platform 13 and the side wall of the placement platform 12, and an optical fiber sensor 31 is disposed in the operation space 14.

It will be understood that, as shown in fig. 1 and 3, the placement table 12 is provided with a detection groove 121, and the detection groove 121 is provided toward the operation table 13 side, and the detection joint 21 is provided in the detection groove 121 so that the detection joint 21 is fixed in position; the height of the operation table 13 along the vertical direction is smaller than the height of the placement table 12, so that an open operation space 14 is formed between the side wall of the placement table 12 facing the operation table 13 and the surface of the operation table 13, the operation of an operator is facilitated, the optical fiber sensor 31 is arranged in the operation space 14, and meanwhile, the signal amplifier 321 is also arranged adjacent to the operation space 14, so that the operator can conveniently read the light wave value.

In one embodiment, the detecting joint 21 is provided with a first quick socket adjacent to one end of the operating space 14, and the end of the cable 4 away from the brushless motor is provided with a second quick socket, and the second quick socket is detachably connected with the first quick socket.

It can be appreciated that the first quick socket and the second quick socket are detachably connected, such as a clamping connection, a plugging connection or a screwing connection, the connection is not limited herein, and the cable 4 connected with the brushless motor product can be quickly connected with the detection connector 21 through the first quick socket and the second quick socket, so that an operator can test a large number of brushless motor products conveniently, the detection efficiency is effectively improved, and the labor intensity is reduced.

The utility model also provides detection equipment, which comprises a main body and the detection device 100, wherein the detection device 100 is electrically connected with the main body. The specific structure of the detection device 100 refers to the foregoing embodiments, and since the detection apparatus adopts all the technical solutions of all the foregoing embodiments, at least the detection device has all the beneficial effects brought by the technical solutions of the foregoing embodiments, which are not described in detail herein.

The foregoing description is only of the optional embodiments of the present utility model, and is not intended to limit the scope of the utility model, and all equivalent structural modifications made by the present description and accompanying drawings or direct/indirect application in other related technical fields are included in the scope of the present utility model.

Claims (10)

1. A detection apparatus for detecting a brushless motor having a cable, the detection apparatus comprising:

a detection table;

the detection assembly comprises a detection connector and a detection power supply, the detection connector is arranged on the detection table and connected with the detection power supply, and the detection connector is used for being connected with the cable; a kind of electronic device with high-pressure air-conditioning system

The error detection prevention mechanism comprises an optical fiber sensor and a control component which are electrically connected, wherein the control component is respectively electrically connected with the detection connector and the detection power supply and is used for controlling the on-off of the detection connector and the detection power supply, and the optical fiber sensor is used for detecting the color of the cable.

2. The detection device of claim 1, wherein the control assembly has a detection circuit and a control circuit, the detection circuit being electrically connected to the fiber sensor for receiving and displaying the fiber sensor detection result;

the control circuit is respectively and electrically connected with the detection connector and the detection power supply and is used for controlling the on-off of the detection power supply.

3. The detection apparatus according to claim 2, wherein the control assembly includes a signal amplifier and a relay electrically connected, the signal amplifier being electrically connected to the fiber optic sensor, and the signal amplifier being electrically connected to the detection power supply to form the detection circuit;

the relay is electrically connected with the detection power supply and the detection connector to form the control circuit;

the signal amplifier is used for receiving the detection result of the optical fiber sensor and controlling the relay to conduct on-off of the detection power supply.

4. A test device according to claim 3, wherein the signal amplifier and the relay are removably mounted to the test bed side wall, and wherein the signal amplifier is disposed adjacent the fiber optic sensor and the relay is disposed adjacent the test power supply.

5. The detecting device according to claim 4, wherein the signal amplifier is provided with a display screen for displaying the detection result of the optical fiber sensor.

6. The device according to claim 1, wherein the inspection table is provided with an inspection frame, an end of the inspection frame away from the surface of the inspection table is provided with an inspection hole and a clamping groove which are communicated, the optical fiber sensor is provided with an inspection head, the inspection head extends into the inspection hole and is arranged adjacent to the clamping groove, the clamping groove is used for placing the cable, and the optical fiber sensor is arranged opposite to the cable.

7. The detecting device according to claim 6, wherein a clamping portion is provided at an end of the side wall of the holding groove away from the detecting rack, and extends toward the detecting hole side, the clamping portion is gradually increased in cross section from an end adjacent to the detecting hole to the side wall of the holding groove, and the clamping portion is used for fixing the cable.

8. The apparatus according to any one of claims 1 to 7, wherein the inspection stage includes a placement stage and an operation stage connected to each other, the placement stage surface is provided with an inspection groove, the inspection joint is placed in the inspection groove, the operation stage surface and the placement stage side wall are formed with an open operation space, and the optical fiber sensor is provided in the operation space.

9. The device of claim 8, wherein the detection joint has a first quick socket adjacent to one end of the operating space, and wherein the cable has a second quick socket at an end remote from the brushless motor, the second quick socket being detachably connected to the first quick socket.

10. A detection apparatus, characterized in that the detection apparatus comprises:

a main body; and

the detection device of any one of claims 1 to 9, the detection device being electrically connected to the body.