CN210901565U - Wearable check out test set - Google Patents

Abstract

The application relates to wearable check out test set, including safety helmet, outer temperature sensor, discharge and detect sensor, integrated treater, intelligent lens, battery, wireless communication equipment and alarm. The infrared temperature measurement sensor is used for detecting the temperature of an area to be detected in the power system, and the discharge detection sensor is used for detecting the discharge condition of the area to be detected. The integrated processor is used for receiving detection signals output by the infrared temperature measurement sensor and the discharge detection sensor and generating a processing result according to the detection signals. And the intelligent lens is used for displaying the processing result and the alarm information. The wireless communication equipment is used for sending the processing result to external equipment. The alarm is used for alarming. The wearable detection equipment provided by the application can solve the problems that the traditional scheme is large in workload, large in detection result error and untimely in information feedback when the operation condition of the power system is detected.

Description

Wearable check out test set

Technical Field

The application relates to the field of power equipment monitoring, in particular to a wearable detection device.

Background

With the vigorous development of the economic society, the demand of electric energy is continuously increased, and the requirement on the quality of the electric energy is higher and higher, so that higher requirements are provided for the safety and the stability of a power system. As an important link for guaranteeing the safety and stability of an electric power system, power routing inspection is increasingly paid more attention by people.

At present, manual inspection is the main mode of power inspection in most provinces and cities in China. The manual inspection is mainly to observe at a distance through a telescope and judge whether the operation of a power system is stable or not through an observation result. However, the manual inspection mode not only brings heavy workload to power workers, but also results of manual inspection are often too large in error and not timely in problem feedback, and therefore people are not facilitated to find operation problems of the power system in time.

Therefore, the traditional scheme has the problems of large workload, large detection result error and untimely information feedback when detecting the operation condition of the power system.

SUMMERY OF THE UTILITY MODEL

Based on this, it is necessary to provide a wearable detection device for solving the problems of large workload, large detection result error and untimely information feedback in the conventional scheme of detecting the operation status of the power system.

A wearable sensing device for sensing power system operating conditions, comprising:

a safety helmet;

the infrared temperature measurement sensor is arranged on the safety helmet and used for detecting the temperature of an area to be detected in the power system;

the discharge detection sensor is arranged on the safety helmet and used for detecting the discharge condition of the area to be detected;

the integrated processor is arranged on the safety helmet, is electrically connected with the infrared temperature measuring sensor and the discharge detection sensor and is in signal connection with the infrared temperature measuring sensor and the discharge detection sensor so as to receive detection signals output by the infrared temperature measuring sensor and the discharge detection sensor and generate a processing result according to the detection signals, wherein the processing result is used for indicating the running state of the area to be detected, and the integrated processor is also used for storing the processing result;

the intelligent lens is arranged on the safety helmet, is electrically connected with the integrated processor and is in signal connection with the integrated processor, and is used for displaying the processing result and displaying alarm information;

the wireless communication equipment is arranged on the safety helmet, is electrically connected and in signal connection with the integrated processor, and is used for sending the processing result to external equipment;

and the alarm is arranged on the safety helmet, is electrically connected with the integrated processor and is in signal connection with the integrated processor, and is used for carrying out alarm operation according to the control of the integrated processor.

The battery is installed on the safety helmet, is electrically connected with the integrated processor and is in signal connection with the infrared temperature measuring sensor, the discharge detection sensor, the integrated processor, the intelligent lens, the wireless communication equipment and the alarm provide electric energy.

The application provides a wearable check out test set for detect electric power system operation status, wearable check out test set includes safety helmet, infrared temperature sensor, discharges and detects sensor, integrated treater, intelligent lens, battery, wireless communication equipment and alarm. The infrared temperature measurement sensor is used for detecting the temperature of an area to be detected in the power system, and the discharge detection sensor is used for detecting the discharge condition of the area to be detected. The integrated processor is electrically connected and in signal connection with the infrared temperature measurement sensor and the discharge detection sensor, and is used for receiving detection signals output by the infrared temperature measurement sensor and the discharge detection sensor and generating a processing result according to the detection signals, wherein the processing result is used for indicating the operation condition of the area to be detected. The intelligent lens is used for displaying the processing result and the alarm information so that a worker can obtain the running condition of the area to be detected in real time.

In the actual use process, a worker can wear the wearable detection equipment and learn the operation state of the area to be detected in the power system through the wearable detection equipment. The operating conditions are analyzed and known by the infrared temperature measuring sensor, the discharge detecting sensor and the integrated processor on the wearable detecting device. And the working personnel can timely know the processing result through the intelligent lens so as to know the operating condition of the area to be detected. The wireless communication equipment is used for sending the processing result to external equipment, and the external equipment can be a mobile phone or a computer of a worker. Therefore, the working personnel can know the operating condition of the area to be detected in real time through the wireless communication equipment. The alarm is used for carrying out alarm operation according to the control of the integrated processor, so that a worker can timely obtain alarm information. Therefore, the wearable detection equipment provided by the application can solve the problems that the traditional scheme has large workload, large detection result error and untimely information feedback when the power system is checked.

In one embodiment, the integrated processor comprises:

the analog-to-digital converter is electrically connected and in signal connection with the infrared temperature measuring sensor and the discharge detection sensor, and is used for receiving the detection signal and converting the detection signal into a digital signal;

the central processing unit is electrically connected and in signal connection with the analog-to-digital converter and is used for analyzing the digital signal and then generating a processing result;

and the memory is electrically connected and in signal connection with the central processing unit and is used for storing the operation memory of the central processing unit and the processing result.

In one embodiment, an earphone is detachably mounted on the safety helmet, and the infrared temperature measuring sensor, the discharge detection sensor, the integrated processor, the battery, the wireless communication device and the alarm are all arranged in the earphone;

the intelligent lens is detachably mounted on the earphone.

In one embodiment, the smart lens is mounted on the headset via a hinge.

In one embodiment, the method further comprises:

the change-over switch is electrically connected with the infrared temperature measurement sensor and the discharge detection sensor and is used for controlling the infrared temperature measurement sensor to work or controlling the discharge detection sensor to work;

and the zooming switch is electrically connected with the intelligent lens and is used for controlling the intelligent lens to zoom.

In one embodiment, the switch includes:

the first change-over switch is electrically connected with the infrared temperature measurement sensor and is used for controlling the infrared temperature measurement sensor to be turned on or turned off;

and the second change-over switch is electrically connected with the discharge detection sensor and is used for controlling the discharge detection sensor to be switched on or switched off.

In one embodiment, the alarm is an audible alarm and is arranged in the earphone.

In one embodiment, the memory is a solid state disk.

In one embodiment, the discharge detection sensor is an ultraviolet electric field detector.

Drawings

Fig. 1 is a schematic structural diagram of a wearable detection device according to an embodiment of the present application.

Fig. 2 is a schematic structural diagram of an earphone according to an embodiment of the present application.

Fig. 3 is a schematic diagram of an integrated processor provided in an embodiment of the present application.

Description of the reference numerals

Wearable check out test set 10

Protective helmet 100

Earphone 110

Infrared temperature measurement sensor 200

Discharge detection sensor 300

Integrated processor 400

Analog-to-digital converter 410

Central processing unit 420

Memory 430

Intelligent lens 500

Hinge 510

Battery 600

Wireless communication device 700

Alarm 800

Change-over switch 20

First switch 21

Second changeover switch 22

Zoom switch 30

Detailed Description

The traditional scheme has that work load is big, the testing result error is big and information feedback is untimely when detecting electric power system's operation conditions, and based on this, this application provides a wearable check out test set.

In order to make the aforementioned objects, features and advantages of the present application more comprehensible, embodiments accompanying the present application are described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application. This application is capable of embodiments in many different forms than those described herein and those skilled in the art will be able to make similar modifications without departing from the spirit of the application and it is therefore not intended to be limited to the embodiments disclosed below.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1, the present application provides a wearable detection device 10 for detecting an operating condition of an electrical power system. The wearable detection device 10 includes a hard hat 100, an infrared temperature measurement sensor 200, a discharge detection sensor 300, an integrated processor 400, a smart lens 500, a battery 600, a wireless communication device 700, and an alarm 800.

The shape, material and model of the safety helmet 100 can be selected according to actual needs, and the application is not limited. It will be appreciated that the headgear 100 may alternatively be other wearable items, such as a worker's clothing, or gloves.

The infrared temperature measuring sensor 200 is mounted on the safety helmet 100 and used for detecting the temperature of an area to be detected in an electric power system. The mounting position of the infrared temperature measuring sensor 200 on the safety helmet 100 can be selected according to actual needs, and the application is not limited. The infrared temperature measurement sensor 200 may be detachably mounted on the safety helmet 100, or may be fixedly mounted on the safety helmet 100, and may be specifically selected according to actual needs, which is not limited in this application. The specific model of the infrared temperature measurement sensor 200 can be selected according to actual needs, and the application is not limited. In the actual use process, the infrared temperature measurement sensor 200 is used for detecting the temperature of the area to be detected in the power system. The worker can wear the safety helmet 100 and move the safety helmet 100 in the moving process of the worker, so that the region to be detected is changed, and temperature measurement is carried out on different regions to be detected.

The discharge detection sensor 300 is mounted on the helmet 100, and is used for detecting a discharge condition of the area to be detected. The mounting position of the discharge detection sensor 300 on the helmet 100 may be selected according to actual needs, and the application is not limited thereto. The discharge detection sensor 300 may be detachably mounted on the safety helmet 100, or may not be detachably mounted on the safety helmet 100, and may be specifically selected according to actual needs, which is not limited in this application. The discharge detection sensor 300 may be an ultraviolet electric field detector or a partial discharge detector as long as it can detect the discharge condition of the area to be detected. The type of the discharge detection sensor 300 may be selected according to actual needs, and is not limited in this application. In an embodiment, the discharge detection sensor 300 is an ultraviolet electric field detector, and the type of the ultraviolet electric field detector may be selected according to actual needs, which is not limited in this application.

The integrated processor 400 is mounted on the helmet 100, and is electrically connected and signal-connected with the infrared temperature measurement sensor 200 and the discharge detection sensor 300, so as to receive detection signals output by the infrared temperature measurement sensor 200 and the discharge detection sensor 300, and generate a processing result according to the detection signals, where the processing result is used to indicate an operation status of the area to be detected, and the integrated processor 400 is further used to store the processing result. In one embodiment, the integrated processor 400 may be a single chip or a central processing unit. An analog-to-digital conversion circuit may be disposed on the integrated processor 400 to convert the detection signals, i.e., analog signals, output by the infrared temperature measurement sensor 200 and the discharge detection sensor 300 into digital signals. The integrated processor 400 may further have a memory disposed thereon for storing the processing results. The installation position of the integrated processor 400 on the safety helmet 100 can be selected according to actual needs, and the application is not limited. The integrated processor 400 may be detachably mounted on the safety helmet 100, or may be fixedly mounted on the safety helmet 100, which may be specifically selected according to actual needs, and the application is not limited thereto.

The intelligent lens 500 is installed on the helmet 100, and is electrically connected and signal-connected with the integrated processor 400, and the intelligent lens 500 is used for displaying the processing result and displaying alarm information. It should be noted that, the AR augmented reality technology is adopted in the present application, and the staff can observe the real discharge intensity, temperature or alarm information displayed on the to-be-detected region through the intelligent lens 500. In one embodiment, the smart lens 500 may be an AR (Augmented Reality) smart lens. The integrated processor 400 may transmit the processing result and/or the alarm information to the smart lens 500, so that a worker observes the processing result and/or the alarm information through the smart lens 500. In one embodiment, the smart lens 500 may be linked, hinged, riveted, or fastened to the helmet 100, and the specific connection manner may be selected according to actual needs, which is not limited in this application. In the actual use process, the worker can adjust the position of the intelligent lens 500, so as to observe the operation conditions of different areas to be detected. It is understood that the smart lens 500 may also be fixedly mounted on the helmet 100. The installation position of the intelligent lens 500 on the safety helmet 100 can be selected according to actual needs, and the application is not limited.

The wireless communication device 700 is mounted on the helmet 100, and is electrically and signal-connected to the integrated processor 400, for transmitting the processing result to an external device. In one embodiment, the wireless communication device 700 may be a bluetooth device. It is to be understood that the wireless communication device 700 may also be other devices capable of performing wireless communication, which may be specifically selected according to actual needs, and the present application is not limited thereto. The installation position of the wireless communication device 700 on the helmet 100 can be selected according to actual needs, and the present application is not limited thereto. The wireless communication device 700 provided by this embodiment can help the staff to remotely monitor the operation status of the area to be detected, so as to timely know whether the area to be detected operates abnormally, and timely maintain the area to be detected after the abnormal operation is found.

The alarm 800 is mounted on the helmet 100, electrically connected and signal-connected to the integrated processor 400, and configured to perform an alarm operation according to the control of the integrated processor 400.

The alarm 800 is mounted on the helmet 100, electrically connected and signal-connected to the integrated processor 400, and configured to perform an alarm operation according to the control of the integrated processor 400. After analyzing the processing result, the integrated processor 400 may further determine the temperature and the discharge condition of the region to be measured. If the temperature or the discharge intensity of the area to be measured exceeds the normal range, the integrated processor 400 sends an alarm signal to the alarm 800, and the alarm 800 performs an alarm operation after receiving the alarm signal. In one embodiment, the alarm 800 is an audible alarm. The type of the audible alarm can be selected according to actual needs, and the audible alarm is not limited in the application. In addition, the intelligent lens 500 may also display the alarm information, which may include text and image contents. The alarm 800 can help the worker to know the abnormal operation phenomenon of the area to be detected in time, so that the loss of the power system is reduced. The installation position of the alarm 800 on the helmet 100 can be selected according to actual needs, and the application is not limited. The alarm 800 may be detachably mounted on the safety helmet 100, or may be fixedly mounted on the safety helmet 100, which may be specifically selected according to actual needs, and the present application is not limited thereto.

The battery 600 is mounted on the helmet 100, electrically connected and signal-connected to the integrated processor 400, and is used to provide electric energy for the infrared temperature measuring sensor 200, the discharge detection sensor 300, the integrated processor 400, the smart lens 500, the wireless communication device 700, and the alarm 800. The battery 600 may be a lithium battery, a storage battery, or a graphene battery, or other batteries, as long as the battery can provide electric energy for the infrared temperature measuring sensor 200, the discharge detection sensor 300, the integrated processor 400, the smart lens 500, the wireless communication device 700, and the alarm 800. The type of the battery 500 may be selected according to actual needs, and is not limited in this application.

The present embodiment provides a wearable detection device 10 for detecting the operating condition of an electrical power system, where the wearable detection device 10 includes the safety helmet 100, the infrared temperature measurement sensor 200, the discharge detection sensor 300, the integrated processor 400, the smart lens 500, the battery 600, the wireless communication device 700, and the alarm 800. The infrared temperature measuring sensor 200 is used for detecting the temperature of an area to be detected in the power system, and the discharge detecting sensor 300 is used for detecting the discharge condition of the area to be detected. The integrated processor 400 is electrically connected and in signal connection with the infrared temperature measurement sensor 200 and the discharge detection sensor 200, and is configured to receive detection signals output by the infrared temperature measurement sensor 200 and the discharge detection sensor 300, and generate a processing result according to the detection signals, where the processing result is used to indicate an operation status of the area to be detected. The intelligent lens 500 is used for displaying the processing result and the alarm information so that a worker can obtain the operation condition of the area to be detected in real time.

In an actual use process, a worker can wear the wearable detection device 10 and obtain the operation status of the to-be-detected area in the power system through the wearable detection device 10. The operating conditions are analyzed by the infrared temperature measurement sensor 200, the discharge detection sensor 300, and the integrated processor 400 on the wearable detection device 10. The staff can timely know the processing result through the intelligent lens 500, and timely know the operation status of the area to be detected. The wireless communication device 700 is configured to send the processing result to an external device, where the external device may be a mobile phone or a computer of a worker. Therefore, the operator can know the operation status of the area to be detected in real time through the wireless communication device 700. The alarm 800 is configured to perform an alarm operation according to the control of the integrated processor 400, so that a worker can obtain alarm information in time. Therefore, the wearable detection device 10 provided by the application can solve the problems that the workload is large, the detection result error is large and the information feedback is not timely when the electric power system is checked in the conventional scheme.

Referring to fig. 1 to 3, in an embodiment of the present application, the integrated processor 400 includes an analog-to-digital converter 410, a central processor 420 and a memory 430.

The analog-to-digital converter 410 is electrically connected and in signal connection with the infrared temperature measurement sensor 200 and the discharge detection sensor 300, and is configured to receive the detection signal and convert the detection signal into a digital signal. The type of the analog-to-digital converter 410 can be selected according to actual needs, and is not limited in this application. It is understood that the analog-to-digital converter 410 may be replaced by an analog-to-digital conversion circuit, one end of the analog-to-digital conversion circuit is electrically and signal-connected to the infrared temperature measurement sensor 200 and the discharge detection sensor 300, respectively, and the other end of the analog-to-digital conversion circuit is connected to the digital signal processing unit in the integrated processor 400. It is understood that the analog-to-digital converter 410 can also convert analog signals into digital signals, which can be selected according to actual needs, and the application is not limited thereto.

The central processor 420 is electrically connected and in signal connection with the analog-to-digital converter 410, and is configured to analyze the digital signal and generate the processing result. The specific model of the central processor 420 may be selected according to actual needs, and is not limited in this application. The central processor 420 may process the digital signal input by the analog-to-digital converter 410 to generate the processing result, where the processing result may include an image, a number, or a word. In one embodiment, the central processor 420 is further electrically and signally connected to a digital-to-analog conversion circuit, which is further electrically and signally connected to the smart lens 500. It will be appreciated that the digital to analog conversion circuit may be replaced by a digital to analog converter, or other device that converts a digital signal to an analog signal. The digital-to-analog conversion circuit may convert the processing result into an analog signal, and the intelligent lens 500 displays the processing result converted into the analog signal.

The memory 430 is electrically and signally connected to the central processing unit 420, and is configured to store the operation memory of the central processing unit 420 and the processing result. The memory 430 may be a memory strip or a memory card, and may be specifically selected according to actual needs, which is not limited in this application. In one embodiment, the memory 430 is a solid state disk comprising a random access memory capacity of 3GB (GByte, gigabyte), and the maximum storage capacity of the solid state disk is 64 GB.

The integrated processor 400 provided by this embodiment includes the analog-to-digital converter 410, the central processor 420 and the memory 430. The analog-to-digital converter 410 may convert the detection signals output by the infrared temperature measurement sensor 200 and the discharge detection sensor 300 into the digital signals, and the central processing unit 420 may process the digital signals to generate the processing result. The memory 430 is used for storing the operation memory of the central processing unit 420 and the processing result. The central processor 420 transmits the processing result of the converted analog signal to the intelligent lens 500 through the digital-to-analog conversion circuit, and the intelligent lens 500 displays the processing result of the converted analog signal. The application provides integrated processor 400 can accurate and rapid reachs judge regional operating condition to reduce staff's work load.

In an embodiment of the present application, the helmet 100 has a detachable earphone 110, and the infrared temperature sensor 200, the discharge detection sensor 300, the integrated processor 400, the battery 600, the wireless communication device 700, and the alarm 800 are all built in the earphone 110. The infrared temperature measuring sensor 200, the discharge detection sensor 300, the integrated processor 400, the battery 600, the wireless communication device 700, and the alarm 800 may be installed at positions on the earphone 110 that may be selected according to actual needs, which is not limited in this application. In one embodiment, a cavity is formed in the earphone 110, and the infrared temperature measuring sensor 200, the discharge detection sensor 300, the integrated processor 400, the battery 600, the wireless communication device 700, and the alarm 800 are all mounted in the cavity. The earphone 110 may be detachably mounted on the safety helmet 100, or may be fixedly mounted on the safety helmet 100, which may be specifically selected according to actual needs, and the present application is not limited thereto. In one embodiment, the ear set 110 is mounted to the helmet 100 by a snap fit.

The smart lens 500 is detachably mounted on the earphone 110. The smart lens 500 may be fastened, riveted or screwed to the earphone 110, and the specific installation manner may be selected according to actual needs, which is not limited in the present application. In one embodiment, the smart lens 500 is mounted to the earpiece 110 by a hinge 510. The specific specification and model of the hinge 510 can be selected according to actual needs, and the present application is not limited. In the actual use process, the staff can regulate and control the angle of the intelligent lens 500 at will, so as to obtain information more clearly.

In one embodiment of the present application, the wearable detection device 10 further includes a switch 20 and a zoom switch 30.

The switch 20 is electrically connected to the infrared temperature measurement sensor 200 and the discharge detection sensor 300, and is configured to control the infrared temperature measurement sensor 200 to operate, and/or is configured to control the discharge detection sensor 300 to operate. In one embodiment, the switch 20 includes a first switch 21 and a second switch 22. The first switch 21 is electrically connected to the infrared temperature sensor 200 and is used for controlling the infrared temperature sensor 200 to be turned on or off. The second switch 22 is electrically connected to the discharge detection sensor 300, and is used for controlling the discharge detection sensor 300 to be turned on or off. The switch 20 may be installed at any position on the earphone body 100.

The zoom switch 30 is installed on the earphone body 100, and is electrically connected to the intelligent lens 500, so as to control the intelligent lens 500 to zoom. The installation position of the zoom switch 30 on the earphone body 100 can be selected according to actual needs, and the present application is not limited. In one embodiment, the smart lens 500 is mounted on the earphone body 100 through a hinge 510, and the switch 20 and the zoom switch 30 are both mounted on a side close to the hinge 510. The specific installation sequence of the first switch 21, the second switch 22 and the zoom switch 30 may be selected according to actual needs, and the present application is not limited thereto. The change-over switch 20 and the zoom switch 30 can help a worker to flexibly switch the function of the detection earphone 10 when the detection earphone 10 is used, and the simultaneous detection of the temperature and the discharge intensity of the area to be detected is realized, or only the temperature of the area to be detected is detected, or only the discharge intensity of the area to be detected is detected. Therefore, the switch 20 and the zoom switch 30 can increase the flexibility and the utility of the detection earphone 10.

In one embodiment of the present application, the alarm 800 is an audible alarm, built into the headset 110. It will be appreciated that the acoustic alarm may be provided in the cavity of the earphone body 100. The type of the audible alarm can be selected according to actual needs, and the audible alarm is not limited in the application.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the claims. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A wearable check out test set for checking electrical power system behavior, comprising:

a safety helmet (100);

the infrared temperature measurement sensor (200) is arranged on the safety helmet (100) and used for detecting the temperature of an area to be detected in the power system;

the discharge detection sensor (300) is arranged on the safety helmet (100) and is used for detecting the discharge condition of the area to be detected;

the integrated processor (400) is installed on the safety helmet (100), is electrically connected with the infrared temperature measurement sensor (200) and the discharge detection sensor (300) and is in signal connection with the infrared temperature measurement sensor and the discharge detection sensor so as to receive detection signals output by the infrared temperature measurement sensor (200) and the discharge detection sensor (300) and generate a processing result according to the detection signals, the processing result is used for indicating the operation condition of the area to be detected, and the integrated processor (400) is also used for storing the processing result;

the intelligent lens (500) is arranged on the safety helmet (100) and is electrically and signal-connected with the integrated processor (400), and the intelligent lens (500) is used for displaying the processing result and displaying alarm information;

a wireless communication device (700) mounted on the helmet (100) and electrically and signal-connected with the integrated processor (400) for transmitting the processing result to an external device;

the alarm (800) is arranged on the safety helmet (100), is electrically and signally connected with the integrated processor (400), and is used for carrying out alarm operation according to the control of the integrated processor (400);

the battery (600) is installed on the safety helmet (100), is electrically connected with the integrated processor (400) in a signal connection mode, and is used for providing electric energy for the infrared temperature measuring sensor (200), the discharge detection sensor (300), the integrated processor (400), the intelligent lens (500), the wireless communication device (700) and the alarm (800).

2. The wearable detection device according to claim 1, wherein the integrated processor (400) comprises:

the analog-to-digital converter (410) is electrically connected and in signal connection with the infrared temperature measurement sensor (200) and the discharge detection sensor (300) and is used for receiving the detection signal and converting the detection signal into a digital signal;

a central processor (420) electrically and signally connected to the analog-to-digital converter (410) for analyzing the digital signal and generating the processing result;

and the storage (430) is electrically connected and in signal connection with the central processing unit (420) and is used for storing the operation memory of the central processing unit (420) and the processing result.

3. The wearable detection device according to claim 1, wherein an ear piece (110) is removably mounted to the hard hat (100), and the infrared thermometry sensor (200), the discharge detection sensor (300), the integrated processor (400), the battery (600), the wireless communication device (700), and the alarm (800) are all built into the ear piece (110);

the intelligent lens (500) is detachably mounted on the earphone (110).

4. The wearable detection device of claim 3, wherein the smart lens (500) is mounted to the headset (110) via a hinge (510).

5. The wearable detection device of claim 1, further comprising:

the switch (20) is electrically connected with the infrared temperature measurement sensor (200) and the discharge detection sensor (300) and is used for controlling the infrared temperature measurement sensor (200) to work or controlling the discharge detection sensor (300) to work;

the zooming switch (30) is electrically connected with the intelligent lens (500) and is used for controlling the intelligent lens (500) to zoom.

6. The wearable detection device according to claim 5, characterized in that the changeover switch (20) comprises:

the first change-over switch (21) is electrically connected with the infrared temperature measurement sensor (200) and is used for controlling the infrared temperature measurement sensor (200) to be turned on or turned off;

and the second change-over switch (22) is electrically connected with the discharge detection sensor (300) and is used for controlling the discharge detection sensor (300) to be switched on or switched off.

7. The wearable detection device according to claim 3, characterized in that the alarm (800) is an acoustic alarm, built into the headset (110).

8. The wearable detection device of claim 2, wherein the memory (430) is a solid state disk.

9. The wearable detection device according to claim 1, wherein the discharge detection sensor (300) is an ultraviolet electric field detector.

10. The wearable sensing device of claim 1, wherein the integrated processor (400) is a single chip or a central processor.

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