KR20230035165A - Smart safety helmet and operating method thereof - Google Patents

Abstract

The present invention comprises: an input module for receiving a user's voice command; a photographing module for capturing an image in front of the user; a communication module for communicating with a user terminal; an output module for visually outputting information; and a processor which transmits a voice command input through the input module to the user terminal through the communication module, receives a control signal generated from the user terminal through the communication module in response to the voice command being a voice command corresponding to a photographing command, captures an image in front of the user through the photographing module when the control signal is received, and outputs the photographed image through the output module.

Description

Smart safety helmet and its operation method {SMART SAFETY HELMET AND OPERATING METHOD THEREOF}

The present invention relates to a smart helmet and an operating method thereof, and more particularly, to a smart helmet capable of protecting workers working at a work site of a power facility from safety accidents and an operating method thereof.

In accordance with the recent 'Act on the Punishment of Serious Accidents, Etc. (enforced from January 22)', when a safety accident occurs at a workplace, the business manager, including the business owner, is subject to criminal punishment, and the company is liable for punitive damages. The importance of prevention and prevention measures is increasing.

In general, insulation breakdown, short circuit, short circuit, Arcs and explosions may occur due to incorrect wiring, but unless a separate measuring device is used, it is not easy for the operator to immediately check whether or not there is an error in the power facility. Human casualties are constantly occurring due to risks such as fire.

In addition, to protect workers from electric shock or fire that may occur while working on power facilities, it is specified in safety work standards that safety helmets with face shields and insulated protective equipment (insulated gloves, insulated boots, etc.) are worn when working on power facilities However, recently, in order to use photos of the work site as supporting data for work, site specifics, reasons for work impossibility, etc., remove insulating protective equipment (for example, insulated gloves) near power facilities and take off the camera. The case of manipulating smart phones is increasing, and as a result, electric shock or burn accidents caused by power facilities are also increasing.

The background art of the present invention is disclosed in 'Safety Helmet' of Republic of Korea Patent Publication No. 10-2016-0017410 (February 16, 2016).

The present invention was invented to solve the above-mentioned problems, and an object according to one aspect of the present invention is to provide a smart helmet and its operation method that can protect workers working at the work site of power facilities from safety accidents. .

A smart helmet according to an aspect of the present invention includes an input module that receives a user's voice command; a photographing module for photographing an image in front of the user; A communication module that communicates with a user terminal; an output module that visually outputs information; and transmitting a voice command input through the input module to the user terminal through the communication module, and transmitting a control signal generated from the user terminal in response to the voice command corresponding to a photographing command to the communication module. and a processor for capturing an image in front of the user through the capturing module when the control signal is received, and outputting the captured image through the output module.

In the present invention, the processor is characterized in that the image captured by the photographing module is transmitted to the user terminal through the communication module.

In the present invention, a positioning module for measuring positional information of the photographing module further includes, and the processor transmits the positional information measured through the positional measurement module together with an image captured through the photographing module. to be characterized

In the present invention, the processor receives, through the communication module, a warning signal generated from the user terminal according to whether or not the power equipment included in the image is abnormal, and when the warning signal is received, a warning through the output module. It is characterized by outputting.

In the present invention, the photographing module includes an infrared camera for measuring radiant heat emitted from an object, and the warning signal is generated when the radiant heat emitted from power facilities included in the image is greater than a preset reference intensity. do.

In the present invention, the processor extracts a text area included in an image captured through the photographing module, identifies text information included in the extracted text area, and transmits the identified text information through the output module. characterized by output.

In the present invention, the processor is characterized in that it receives the work procedure information and safety rule information of the power facility from the user terminal, and outputs the received work procedure information and safety rule information through the output module.

In the present invention, the output module is a head-up display, and the processor outputs the information to the protective surface provided in the smart helmet through the output module.

A method of operating a smart helmet according to an aspect of the present invention includes receiving, by a processor, a user's voice command through an input module; Transmitting, by the processor, the input voice command to a user terminal through a communication module; receiving, by the processor, a control signal generated from the user terminal in response to the voice command corresponding to a photographing command through the communication module; photographing, by the processor, an image in front of the user through a photographing module when the control signal is received; and outputting, by the processor, the photographed image through an output module.

In the present invention, the step of transmitting, by the processor, the image captured through the photographing module to the user terminal through the communication module; characterized in that it further comprises.

In the step of transmitting the photographed image to the user terminal in the present invention, the processor transmits the image captured through the photographing module and location information of the photographing module measured through a position measurement module. to be

In the present invention, after the step of transmitting the captured image to the user terminal, the processor receives a warning signal output from the user terminal according to whether or not the power equipment included in the image is abnormal through the communication module. doing; and outputting, by the processor, a warning through the output module when the warning signal is received.

In the present invention, the photographing module is an infrared camera that measures radiant heat emitted from an object, and the warning signal is generated when the radiant heat emitted from power facilities included in the image is greater than a preset reference intensity. .

Extracting, by the processor, a text area included in an image captured through the photographing module in the present invention; identifying, by the processor, text information included in the extracted text area; and outputting, by the processor, the identified text information through the output module.

In the present invention, the step of receiving, by the processor, work procedure information and safety rule information of a power facility from the user terminal through the communication module; and outputting, by the processor, the received work procedure information and safety rule information through the output module.

In the present invention, the output module is a head-up display, and the processor outputs information to the protective surface provided in the smart helmet through the output module.

According to one aspect of the present invention, a power facility is photographed through an infrared camera provided in a hard hat, and the captured image is output on a protective surface provided in the hard hat so that the operator can easily check the state of the power facility before or during work. can do.

According to another aspect of the present invention, the safety of the worker can be ensured by eliminating the need to attach and detach insulation equipment to take a picture of the work site during power facility work by operating the camera provided in the hard hat through the worker's voice command.

According to another aspect of the present invention, text is extracted from an image of a power facility through a camera provided in a hard hat, and the extracted text is identified and output on a protective surface provided in the hard hat, thereby easily conveying information about the power facility to a worker. there is.

According to another aspect of the present invention, it is possible to improve the efficiency of operation and management of power facilities by transmitting the GPS coordinates of the camera together with the image captured by the camera provided in the hard hat to the user terminal.

According to another aspect of the present invention, by outputting work procedures and safety rules of power facilities on the protective surface provided in the hard hat, the efficiency and accuracy of work can be improved, and stability can be promoted during work of power facilities.

1 is a block diagram for explaining a smart helmet according to an embodiment of the present invention.
2 is an exemplary diagram for explaining a smart hard hat according to an embodiment of the present invention.
3 is an exemplary diagram for explaining an image captured through a smart helmet according to an embodiment of the present invention.
4 to 7 are flowcharts for explaining a method of operating a smart helmet according to an embodiment of the present invention.

Hereinafter, a smart helmet and its operating method according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In this process, the thickness of lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of a user or operator. Therefore, definitions of these terms will have to be made based on the content throughout this specification.

1 is a block configuration diagram for explaining a smart hard hat according to an embodiment of the present invention, Figure 2 is an exemplary view for explaining a smart hard hat according to an embodiment of the present invention, and FIG. It is an exemplary diagram for explaining an image captured through a smart helmet according to an embodiment.

1 and 2, the smart helmet 10 according to an embodiment of the present invention includes an input module 100, a photographing module 200, a communication module 300, an output module 400, and a position measurement module. 500, a power module 600 and a processor 700. According to one embodiment, the smart helmet 10 is connected to a main body 11 that protects the user's head from various impacts, and a protective surface connected to one side of the main body 11 to protect the user's face from foreign substances and flying objects. (12) may be included. The input module 100, the photographing module 200, the communication module 300, the output module 400, the positioning module 500, the power module 600, and the processor 700 are provided in the main body 11, respectively. can

The input module 100 may receive a user's voice command. The input module 100 may receive a voice command spoken by the user and output it to the processor 700 to be described later. According to one embodiment, the input module 100 may be a microphone.

The photographing module 200 may capture an image in front of the user. The capturing module 200 may capture an image in front of the user under the control of the processor 700 and output the captured image to the processor 700 . According to an embodiment, the photographing module 200 may include an infrared camera that detects radiant heat emitted from an object. That is, the capturing module 200 may capture an infrared image. Also, the photographing module 200 may include a general camera. 3A is an example of an image of a power facility taken through a general camera, and FIG. 3B is an example of an image of a power facility taken through an infrared camera.

The communication module 300 may communicate with the user terminal 20 . The communication module 300 may transmit and receive information by communicating with the user terminal 20 under the control of the processor 700 . According to an embodiment, the communication module 300 may communicate with the user terminal 20 through short-range wireless communication. The communication module 300 may communicate with the user terminal 20 using at least one of Bluetooth, Wi-Fi, Wi-Fi Direct, and Ultra Wide Band (UWB). However, it is not limited to the above-described embodiment, and the communication module 300 may communicate with the user terminal 20 using various well-known wireless communication methods. Meanwhile, the user terminal 20 is a terminal carried by the user and may be a smart phone equipped with a short-range communication function and a voice recognition function. A dedicated application for processing various information transmitted from the smart helmet 10 and performing various functions necessary for transmitting the result to the smart helmet 10 may be pre-installed on the user terminal 20 .

The output module 400 may visually output information. The output module 400 may output information to the protective surface 12 provided in the smart helmet 10 under the control of the processor 700 . According to one embodiment, the output module 400 may be a head-up display. However, it is not limited to the above-described embodiment, and the output module 400 may be a transparent display composed of a panel having transmittance. Meanwhile, the protective surface 12 may be made of a material having light transmission properties. The output module 400 may output an image only on one side of the protective surface 12 to prevent the user's field of view from being blocked by the image output on the protective surface 12 . A polarizing film may be attached to the protective surface 12 to clearly display the image output from the output module 400 .

The location measurement module 500 may measure location information of the photographing module 200 . The location measuring module 500 may measure location information of the photographing module 200 under the control of the processor 700 and output the measured location information to the processor 700 . According to one embodiment, the location measurement module 500 may be a GPS. That is, the location measurement module 500 may use GPS coordinates as location information of the photographing module 200 .

The power module 600 may supply power to each module and processor 700 provided in the smart helmet 10 . The power module 600 may be a rechargeable battery.

The processor 700 may control the input module 100, the photographing module 200, the communication module 300, the output module 400, the location measurement module 500, and the power module 600. According to an embodiment, the processor 700 transmits a voice command input through the input module 100 to the user terminal 20 through the communication module 300, and the voice command is a voice command corresponding to a photographing command. In response to this, a control signal generated from the user terminal 20 is received through the communication module 300, and when the control signal is received, an image in front of the user is photographed through the photographing module 200, and the output module 400 The recorded video can be output through

Hereinafter, a process of operating the photographing module 200 in response to a user's voice command will be described with reference to FIG. 4 .

First, the processor 700 may receive a user's voice command through the input module 100 (step S401). That is, the processor 700 may receive a voice command spoken by the user through the input module 100 . For example, the processor 700 may receive voice commands such as “camera,” “photograph,” and “photograph” from the user.

Subsequently, the processor 700 may transmit the voice command input through the input module 100 to the user terminal 20 through the communication module 300 (step S403). That is, the processor 700 may transmit the voice command input through the input module 100 to the user terminal 20 through short-range wireless communication. The communication module 300 and the user terminal 20 may be previously paired.

Subsequently, the processor 700 may receive a control signal generated from the user terminal 20 in response to the voice command corresponding to the photographing command through the communication module 300 (step S405). That is, the user terminal 20 determines whether the voice command transmitted from the smart helmet 10 is a voice command corresponding to the shooting command, and if it is determined that the voice command is a voice command corresponding to the shooting command, the smart helmet ( A control signal for operating the photographing module 200 provided in 10) may be generated, and the generated control signal may be transmitted to the smart helmet 10 through short-range wireless communication.

When a control signal is received through the communication module 300, the processor 700 may capture an image in front of the user through the photographing module 200 (step S407). That is, the processor 700 may capture an image in front of the user by operating the photographing module 200 in response to receiving a control signal from the user terminal 20 .

Subsequently, the processor 700 may output the image captured through the photographing module 200 through the output module 400 (step S409). That is, the processor 700 protects the infrared image in front of the user, which is captured through the photographing module 200, so that the user wearing the smart helmet 10 can check the infrared image of the power facility. It can be projected onto the surface (12).

In the above-described embodiment, it has been described that the processor 700 transmits a voice command input through the input module 100 to the user terminal 20 and receives a control signal from the user terminal 20, but the processor 700 may itself generate a control signal by recognizing a voice command input through the input module 100.

Subsequently, the processor 700 may transmit the image captured through the photographing module 200 to the user terminal 20 through the communication module 300 (step S411). That is, the processor 700 transmits an image captured through the photographing module 200 to the user terminal 20 through the communication module 300 so that the image photographed through the photographing module 200 can be stored in the user terminal 20. ) can be transmitted. When a memory is provided in the smart helmet 10, the processor 700 may store an image captured through the photographing module 200 in the memory. The video transmitted to the user terminal 20 may be retransmitted to the outside (management server, etc.) through a wireless communication network (eg, LTE).

According to an embodiment, when capturing an image in front of the user through the photographing module 200, the processor 700 measures the position (GPS coordinates) of the photographing module 200 through the localization module 500, and captures the image. When the image captured through the module 200 is transmitted to the user terminal 20 through the communication module 300, the image captured through the capture module 200 and the capture module measured through the localization module 500 The location of (200) can be transmitted. That is, the present invention can improve the efficiency of operation and management of power facilities by transmitting the GPS coordinates of the camera together with the image captured through the camera provided in the hard hat to the user terminal 20.

As described above, in the present invention, the operator can easily check the state of the power facility before or during work by photographing the power facility through an infrared camera provided in the helmet and outputting the captured image on the protective surface provided in the helmet. can make it In addition, the present invention protects workers from safety accidents such as electric shock or burns by operating the camera provided in the hard hat through the operator's voice command to eliminate the need to attach and detach the insulation protective equipment for taking pictures of the work site during power facility work. and ensure the safety of workers.

Meanwhile, the processor 700 may receive various voice commands for controlling the user terminal 20 through the input module 100 and transmit the received voice commands to the user terminal 20 through the communication module 300. there is. For example, the processor 700 controls a camera provided in the user terminal 20, operates a keypad provided in the user terminal 20, or receives a call received through the user terminal 20, Voice commands corresponding to the aforementioned operations may be received through the input module 100 and transmitted to the user terminal 20 . In this case, the user terminal 20 may identify a voice command transmitted from the smart helmet 10 and perform an operation corresponding to the identified voice command.

Meanwhile, a touch sensor (not shown) may be provided in the main body 11 of the smart helmet 10, and the processor 700 may control the photographing module 200 based on an input signal through the touch sensor. For example, the processor 700 may drive the photographing module 200 when an input signal is detected through the touch sensor, and then, when the input signal is detected again through the touch sensor, the processor 700 may enable the user through the photographing module 200. You can take pictures of the front. That is, the processor 700 can turn on the power of the camera provided in the smart helmet 10 when a touch is input from the user through the touch sensor, and then the processor 700 can replay the touch from the user through the touch sensor. If input, a picture in front of the user can be taken through the camera. The touch sensor may be a pressure sensitive touch sensor, an ultrasonic touch sensor, or an infrared touch sensor so that the touch sensor can be operated even while wearing insulating protective equipment (eg, insulating gloves).

Hereinafter, with reference to FIG. 5 , a process of outputting a warning according to whether a power facility included in an image captured through the photographing module 200 is abnormal will be described.

First, the processor 700 may capture an image of a power facility located in front of the user through the photographing module 200 (step S501).

Subsequently, the processor 700 may transmit the image captured through the photographing module 200 to the user terminal 20 through the communication module 300 (step S503). That is, the processor 700 may transmit an image captured through the photographing module 200 to the user terminal 20 through short-range wireless communication. The communication module 300 and the user terminal 20 may be previously paired.

Subsequently, the processor 700 may receive a warning signal generated from the user terminal 20 through the communication module 300 according to whether the power equipment included in the image is abnormal (step S505). That is, the user terminal 20 analyzes the infrared image transmitted from the smart safety helmet 10 to determine whether an abnormality has occurred in the power facility, and generates a warning signal when it is determined that an abnormality in the power facility has occurred. , The generated warning signal can be transmitted to the smart helmet 10. According to an embodiment, the warning signal may be generated when radiant heat having a predetermined reference intensity or more is detected in at least one area among each area of the power facility included in the image. That is, the user terminal 20 may determine that an abnormality has occurred in the power facility and generate a warning signal when radiant heat having a reference intensity or more is detected in at least one area among each area of the power facility included in the image.

When a warning signal is received through the communication module 300, the processor 700 may output a warning through the output module 400 (step S507). That is, the processor 700 may output a warning to the protective surface 12 provided in the smart helmet 10 so that the user wearing the smart helmet 10 can recognize the occurrence of an abnormal power facility. For example, the processor 700 may blink a screen output through the output module 400 or output a preset warning phrase or picture through the output module 400 . Meanwhile, the output module 400 may further include a speaker, and when a warning signal is received through the communication module 300, the processor 700 outputs a warning sound of a certain decibel (eg, 85dB) or more through the speaker. may be

As described above, the image of the power facility is analyzed to determine whether the power facility is abnormal, a warning signal generated from the user terminal is received according to the abnormality of the power facility, and when the warning signal is received, the protective surface is displayed. By outputting a warning, it is possible to prevent an accident caused by an abnormal power facility.

Hereinafter, a process of outputting text information included in an image captured through the photographing module 200 will be described with reference to FIG. 6 .

First, the processor 700 may capture an image of a power facility located in front of the user through the photographing module 200 (step S601).

Subsequently, the processor 700 may extract a text area included in an image captured through the photographing module 200 (step S603). That is, the processor 700 may extract a text area, which is an area including text information, from images captured through the photographing module 200 . Here, the text area may refer to an area in which text information about the type of power equipment, manufacturer, model number, manufacturing number, or manufacturing year is described.

Subsequently, the processor 700 may identify text information included in the extracted text area (step S605). According to an embodiment, the processor 700 may extract a text area from an image using Optical Character Recognition (OCR) technology and identify text information included in the extracted text area.

Subsequently, the processor 700 may output the identified text information through the output module 400 (step S607). That is, in order to deliver information about power facilities to the user, the processor 700 may identify text information included in the image and output it to the protective surface 12 provided in the smart helmet 10.

Meanwhile, when the processor 700 transmits an image captured through the photographing module 200 to the user terminal 20 through the communication module 300, the image captured through the photographing module 200 and the identified text information can also be transmitted.

In addition, the processor 700 extracts a QR code or barcode included in an image captured through the photographing module 200, identifies information included in the extracted QR code or barcode, and outputs the identified information to the module 400. ) can also be output.

In the above-described embodiment, it has been described that the processor 700 extracts a text area from an image by itself and identifies text included in the text area, but the user terminal 20 receives the image from the processor 700 and identifies the text area. It is also possible to extract, identify text included in the text area, and transmit the identified text to the smart helmet 10.

Hereinafter, with reference to FIG. 7, a process of outputting work procedure information and safety rule information of a power facility will be described.

First, the processor 700 may receive work procedure information and/or safety rule information of a power facility from the user terminal 20 (step S701). Here, the work procedure information may refer to text, pictures, photos, or videos for explaining a series of work orders or methods for inspecting or repairing the power equipment, and safety rule information may refer to when inspecting or repairing the power equipment. It can mean text, pictures, photos or videos to explain what needs to be observed.

According to an embodiment, the processor 700 transmits the image of the power facility to the user terminal 20 through the communication module 300, and transmits the image from the user terminal 20 to the power facility included in the image. Corresponding work procedure information and/or safety rule information may be received. That is, the user terminal 20 analyzes the image transmitted from the smart safety helmet 10 to identify the type of power facility included in the image, and performs a task corresponding to the identified power facility among pre-stored work procedure information and safety rule information. Procedure information and/or safety rule information may be detected, and the detected work procedure information and/or safety rule information may be transmitted to the smart helmet 10 .

For example, assuming that the power facility is an watt-hour meter, the user terminal 20 may transmit work procedure information and/or safety rule information for installing, inspecting, or replacing the watt-hour meter to the smart helmet 10, and the power facility may transmit AMI Assuming that it is a communication modem, the user terminal 20 may transmit work procedure information and/or safety rule information for installation, inspection, or replacement of the AMI communication model to the smart helmet 10.

Subsequently, the processor 700 may output the work procedure information and/or safety rule information received through the output module 400 (step S703). That is, in order to improve work efficiency and accuracy and promote stability during power facility work, the processor 700 transmits work procedure information and/or safety rule information to the protective face 12 provided in the smart helmet 10. can be printed out.

Meanwhile, the processor 700 receives a voice command related to the output of work procedure information and/or safety rule information through the input module 100, and transmits the received voice command to the user terminal 20 through the communication module 300. By transmitting to, it is possible to control the output of work procedure information and/or safety rule information.

For example, assuming that the work procedure information and/or safety rule information is a video, the processor 700 performs playback and playback of the video, such as play, pause, rewind, fast forward, or repeat playback, through the input module 100. A related voice command may be received from the user, and the received voice command may be transmitted to the user terminal 20 through the communication module 300 . In this case, the user terminal 20 may identify a voice command transmitted from the smart helmet 10 and control data transmitted to the smart helmet 10 according to the identified voice command.

For another example, assuming that the work procedure information and/or the safety rule information are a plurality of pictures, photos, or text, the processor 700 may input a previous screen, a next screen, enlargement or reduction through the input module 100, and the like. A voice command may be received from the user, and the received voice command may be transmitted to the user terminal 20 through the communication module 300 . In this case, the user terminal 20 may identify a voice command transmitted from the smart helmet 10 and control data transmitted to the smart helmet 10 according to the identified voice command.

Meanwhile, in the above-described embodiment, it has been described that the output of work procedure information and/or safety rule information is controlled through the user terminal 20, but the processor 700 itself has a voice command input through the input module 100. may be recognized and the output of work procedure information and/or safety rule information through the output module 400 may be controlled.

As described above, the smart helmet and its operating method according to an embodiment of the present invention photograph power facilities through an infrared camera installed in the helmet and output the captured image to the protective surface provided in the helmet before work or Workers can easily check the status of power facilities during work. In addition, the present invention can secure the safety of the worker by eliminating the need to attach and detach the insulating equipment to take a picture of the work site during power facility work by operating the camera provided in the hard hat through the operator's voice command. In addition, the present invention extracts text from the image of the power facility through a camera provided in the hard hat, identifies the extracted text, and outputs the text on the protective surface provided in the hard hat, thereby easily conveying information about the power facility to the operator. In addition, the present invention can improve the efficiency of operation and management of power facilities by transmitting the GPS coordinates of the camera together with the image captured through the camera provided in the hard hat to the user terminal 20. In addition, the present invention can improve the efficiency and accuracy of work and promote safety during power facility work by outputting work procedures and safety rules of power facilities on the protective surface provided in the hard hat.

The term “module” used in this specification may include a unit implemented in hardware, software, or firmware, and may be used interchangeably with terms such as, for example, logic, logic block, component, or circuit. A module may be an integrally constructed component or a minimal unit of components or a portion thereof that performs one or more functions. For example, according to one embodiment, the module may be implemented in the form of an Application-Specific Integrated Circuit (ASIC).

Implementations described herein may be embodied in, for example, a method or process, an apparatus, a software program, a data stream, or a signal. Even if discussed only in the context of a single form of implementation (eg, discussed only as a method), the implementation of features discussed may also be implemented in other forms (eg, an apparatus or program). The device may be implemented in suitable hardware, software and firmware. The method may be implemented in an apparatus such as a processor, which is generally referred to as a processing device including, for example, a computer, microprocessor, integrated circuit or programmable logic device or the like. Processors also include communication devices such as computers, cell phones, personal digital assistants ("PDAs") and other devices that facilitate communication of information between end-users.

Although the present invention has been described with reference to the embodiments shown in the drawings, it should be noted that this is only exemplary and various modifications and equivalent other embodiments are possible from those skilled in the art to which the technology pertains. will understand Therefore, the true technical protection scope of the present invention should be defined by the claims below.

10: smart helmet
11: body
12: protective face
20: user terminal
100: input module
200: shooting module
300: communication module
400: output module
500: position measurement module
600: power module
700: processor

Claims (16)

an input module that receives a user's voice command;
a photographing module for photographing an image in front of the user;
A communication module that communicates with a user terminal;
an output module that visually outputs information; and
A voice command input through the input module is transmitted to the user terminal through the communication module, and a control signal generated from the user terminal is transmitted to the communication module in response to the voice command being a voice command corresponding to a photographing command. A smart helmet comprising: a processor receiving an image in front of the user through the photographing module and outputting the photographed image through the output module when the control signal is received.
According to claim 1,
The processor is a smart helmet, characterized in that for transmitting the image captured through the photographing module to the user terminal through the communication module.
According to claim 2,
It further includes; a location measurement module for measuring location information of the photographing module;
The processor is a smart helmet, characterized in that for transmitting the location information measured through the location measurement module together with the image taken through the photographing module.
According to claim 2,
The processor receives a warning signal generated from the user terminal through the communication module according to whether the power equipment included in the image is abnormal, and outputs a warning through the output module when the warning signal is received. A smart hard hat featuring.
According to claim 4,
The photographing module includes an infrared camera for measuring radiant heat emitted from an object,
The warning signal is a smart helmet, characterized in that generated when the radiant heat emitted from the power equipment included in the image is greater than or equal to a preset reference intensity.
According to claim 1,
The processor extracts a text area included in an image captured through the photographing module, identifies text information included in the extracted text area, and outputs the identified text information through the output module. A smart hard hat made with.
According to claim 1,
The processor receives the work procedure information and safety rule information of the power facility from the user terminal, and outputs the received work procedure information and safety rule information through the output module.
According to claim 1,
The output module is a head-up display,
The processor, characterized in that for outputting the information on the protective surface provided in the smart helmet through the output module.
Receiving, by a processor, a user's voice command through an input module;
Transmitting, by the processor, the input voice command to a user terminal through a communication module;
receiving, by the processor, a control signal generated from the user terminal in response to the voice command corresponding to a photographing command through the communication module;
photographing, by the processor, an image in front of the user through a photographing module when the control signal is received; and
The method of operating a smart hard hat, characterized in that it comprises; outputting, by the processor, the captured image through an output module.
According to claim 9,
Transmitting, by the processor, the image captured through the photographing module to the user terminal through the communication module.
According to claim 10,
In the step of transmitting the captured image to the user terminal, the processor,
A method of operating a smart hard hat, characterized in that for transmitting the location information of the photographing module measured through the position measurement module together with the image photographed through the photographing module.
According to claim 10,
After the step of transmitting the captured image to the user terminal,
Receiving, by the processor, a warning signal output from the user terminal according to whether a power facility included in the image is abnormal through the communication module; and
The smart hard hat operating method further comprising: outputting, by the processor, a warning through the output module when the warning signal is received.
According to claim 12,
The photographing module includes an infrared camera for measuring radiant heat emitted from an object,
The warning signal is generated when the radiant heat emitted from the power equipment included in the image is greater than or equal to a preset reference intensity.
According to claim 9,
extracting, by the processor, a text area included in an image captured through the photographing module;
identifying, by the processor, text information included in the extracted text area; and
The method of operating a smart hard hat, characterized in that it further comprises; outputting, by the processor, the identified text information through the output module.
According to claim 9,
Receiving, by the processor, work procedure information and safety rule information of a power facility from the user terminal through the communication module; and
The method of operating a smart hard hat, characterized in that it further comprises; outputting, by the processor, the received work procedure information and safety rule information through the output module.
According to claim 9,
The output module is a head-up display,
The processor, characterized in that for outputting information to the protective surface provided in the smart hard hat through the output module.

Images