RU2695499C1 - Method and device for remote monitoring of compliance with safety regulations by employees - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to electrical engineering for monitoring of compliance with safety regulations by employees. Method for remote monitoring of compliance with safety regulations by employees, involving: detecting effects on the wearable device by the impact sensor by measuring the projection of acceleration, presence of the wear phase of the wearable device, recording temperature, recording humidity, transmitting, by a communication module, values transmitted from data sensors, comparison between the processor and the software of the portable device of the obtained values from an impact sensor, a temperature sensor and a humidity sensor with critical values recorded in the data storage of the wearable device recorded by said sensors, and alerting the operator when an emergency event occurs.EFFECT: wider range of tools for the same purpose.30 cl, 7 dwg

Description

FIELD OF TECHNOLOGY

The invention relates to the field of electrical engineering, as well as to the field of recording, processing and data transfer for various, including special applications, and can be used to create decentralized and centralized, including automated, methods, devices and systems for monitoring devices and device management, as well as to monitor compliance with safety regulations by employees.

BACKGROUND

Currently, the problem of people's safety is quite acute when they perform various works, for example, construction, rescue and other types of work. Generally, protective equipment such as helmets, masks, helmets, etc. Such protective equipment can be equipped with various electronic devices with sensors capable of recording various kinds of effects on a person or received by a person. Such electronic devices can provide for the detection (determination, recording) of various events, data on which can be presented to the user of such protective equipment or to persons monitoring personnel.

The prior art device (see US 20120210498 A1, publ. 08.23.2012), which describes a helmet with distance sensors located inside the helmet, which detect the presence of the helmet on the user's head. Also, the helmet contains at least one impact sensor capable of detecting the impact on the helmet. One of the disadvantages of this solution is the inability to detect user feedback with the operator, in particular, by recording a series of actions performed by the user, as well as the inability to detect various emergency events and their analytics. Another disadvantage is the lack of a sensor for detecting a user’s fall from a height, in particular, implemented by an accelerometer and analytics of data received from such a sensor by a server. Another drawback of the existing solution is the inability to track the movement of the user with the display of his movements on the map. Also, it is not possible for the operator or the server to automatically perform actions in case of emergency events.

Also known from the prior art is a method (see US 7298258 B1, publ. 20.11.2007) for monitoring the activities of workers at a construction site, and the worker wears a helmet and includes an electrical circuit for transmitting information data to a monitoring system, which includes dividing the construction site into multiple sectors, data transmission from the helmets of workers, the data containing the coordinates of the location of the workers and personal information about the worker, processing the data received and generating messages to the worker who went beyond the sector. One of the disadvantages of this method is the need to divide the construction site into sectors. Another disadvantage is the lack of a sensor and the presence of a helmet on the head of the worker. There is also no additional device used to alert the worker. Another drawback of this solution is the inability to detect the user's feedback with the operator, in particular, by recording a series of actions performed by the user, as well as the inability to detect various emergency events and their analytics. Another disadvantage is the lack of a sensor for detecting a user’s fall from a height, in particular, implemented by an accelerometer and analytics of data received from such a sensor by a server. Also, it is not possible for the operator or the server to automatically perform actions in case of emergency events.

ESSENCE

The technical result achieved by the present invention consists in remotely monitoring compliance with safety regulations by employees, notifying the operator controlling the personnel, and increasing the information content of the safety information and operator alerts visualized to the operator.

According to one implementation option, a method for remotely monitoring compliance with safety regulations by employees is proposed, including: detecting by the sensor of the presence associated with the processor of the wearable device, the presence of the wearable device on the user, the absence of the wearable device on the user being an emergency event; recording by the action sensor associated with the processor of the wearable device: effects on the wearable device by measuring the projection of acceleration, the effects being a blow or a series of strokes on the wearable device, the force sensor recording at least one impact; the presence of the fall phase of the wearable device when the wearable device is in a state of free fall in order to establish an emergency event corresponding to a fall from the height of the user of the wearable device; recording a temperature sensor associated with the processor of the wearable device, the temperature around the wearable device; registration by the humidity sensor associated with the processor of the wearable device, the humidity value around the wearable device; transmission by the communication module associated with the processor of the wearable device to at least one base station of the values transmitted from the presence sensor, from the impact sensor, from the temperature sensor, from the humidity sensor, as well as the value of the battery charge level; comparison by the processor and the software of the wearable device of the obtained values from the exposure sensor, temperature sensor and humidity sensor with the critical values recorded for the said sensors stored in the data store of the wearable device; determination by the processor and software of the wearable device of reaching or exceeding critical values for the impact sensor, for the temperature sensor and for the humidity sensor in order to establish at least one fact of an emergency event corresponding to: a strong blow to the wearable device; critical temperature around the wearable device; critical humidity around the wearable device; determination by the processor and software of the wearable device of a series of strokes against the wearable device, which is a request for help by the user of the wearable device and is a fact of an emergency event; determination by the processor and software of the wearable device of the presence of the fall phase of the wearable device, which is a fact of an emergency event; determination by the processor and software of the wearable device of the absence of the wearable device on the user, which is a fact of an emergency event; the transmission by the communication module associated with the processor of the wearable device to at least one base station of the battery level of the wearable device, as well as at least one fact of an emergency event corresponding to: the absence of the wearable device on the user, the presence of a certain series of strikes on the wearable device, reaching or exceeding critical values for the temperature sensor and for the humidity sensor around the wearable device; the presence of the falling phase of the wearable device, the presence of a strong blow to the wearable device, and together with the fact of an emergency event, the communication module transmits to the base station the values of the impact sensor, temperature sensor and humidity sensor at the time the emergency event occurred, as well as the time the emergency event occurred; determining by the base station a signal strength value received from the wearable device; transmission by the base station to the server: signal strength values received from the wearable device; the values transmitted by the communication module of the wearable device to the base station from the presence sensor, from the impact sensor, from the temperature sensor, from the humidity sensor and the battery level value of the wearable device; the fact of an emergency event, values of the action sensor, temperature sensor, humidity sensor and battery level of the wearable device at the time of the occurrence of the emergency event, as well as the time of the occurrence of the emergency event transmitted by the communication module of the wearable device to the base station; notification of the operator monitoring the user of the wearable device by displaying data visualization module, which is part of the server application server, received by the server the signal level values received from the wearable device, values from the presence sensor, from the impact sensor, from the temperature sensor, from the humidity sensor and values of the battery level of the wearable device, the fact of an emergency event and the values of the impact sensor, temperature sensor, humidity sensor and the value of the charge level yes Battery portable device at the time of emergency events, as well as the time of occurrence of an emergency event.

In one of the private embodiments, the data transfer by the communication module of the wearable device to the base station is carried out using data transmission channels with ultra-low power consumption, and / or LoRa, and / or LoRaWAN, and / or LPWAN, and / or 6LoWPAN, and / or Z- wave.

In one of the private embodiments, the base station is a gateway for data transmission with ultra-low power consumption, and / or the Internet, and / or mobile or satellite communications, Bluetooth, and / or Wi-Fi, and / or GSM, and / or 3G, and / or 4G and / or LTE and / or trunking and / or ZigBee and / or LoRa and / or LoRaWAN and / or LPWAN and / or 6 LoWPAN and / or Z-wave.

In one particular embodiment, data is transferred between the wearable device, the base station, and the server using a network server, which is a computing system that controls the process of receiving data from the base station from the wearable device and transmitting data from the base station to the wearable device, as well as the transfer process data by the base station to the server and data transmission by the server to the base station, said network server being part of the base station and / or server.

In one particular embodiment, the presence sensor is an ultrasonic sensor and / or an infrared sensor.

In one particular embodiment, the battery of the wearable device is charged by at least one of the following methods for charging the battery: by means of a power connector located on the wearable device; by at least one solar cell associated with a wearable device; by contactless charging realized by an inductive loop.

In one particular embodiment, the critical values for the impact sensor, for the temperature sensor and for the humidity sensor are transmitted by the server to the base station and transferred from the base station to the wearable device, and stored in the data storage of the wearable device.

In one particular embodiment, the critical values for the impact sensor, for the temperature sensor and for the humidity sensor are recorded in the data storage of the dependent device by the wearable device programmer.

In one of the private embodiments of the processor and software of the wearable device, it is determined that the temperature recorded by the temperature sensor reaches a value close to the critical temperature for a predetermined period of time in order to establish the fact of an emergency event and the communication module transmits at least one the base station and further to the server of such an emergency event and the time of occurrence of such an emergency event.

In one of the private embodiments, the data analytics module, which is part of the server application server, processes the values of the presence sensor, the impact sensor, the temperature sensor, the humidity sensor, and determines at least one fact of the emergency event.

In one particular embodiment, the wearable device comprises a radio frequency identification tag for identifying the wearable device.

In one particular embodiment, the wearable device is mounted on protective equipment or integrated into wearable protective equipment.

In one of the private embodiments, the protective equipment is a helmet, helmet, mask, construction helmet, worker's helmet, protective helmet.

In one of the private embodiments, the communication between the wearable device, the base station and the server is carried out via wireless communication, including the Internet, and / or mobile or satellite communications, Bluetooth, and / or Wi-Fi, and / or GSM, 3G , 4G, LTE, trunking, and / or via ultra-low power consumption data channels forming complex wireless networks with a mesh topology, and / or ZigBee, and / or LoRa, and / or LoRaWAN, and / or LPWAN, and / or 6LoWPAN, and / or Z-wave.

In one particular embodiment, a user’s location is determined by a second device comprising a user’s location tracking module, and the coordinates of the user's location are transmitted to at least one base station by the communication module of the second device and / or to the server, the data visualization module being part of the server’s application server, the operator, controlling the user of the wearable device, displays the location of the user the caller.

In one particular embodiment, the server transmits control commands to the second device, the control commands turning on indicators and / or sound reproducing devices and / or vibration devices that are part of such a second device in order to notify the user of an emergency event.

In one of the private embodiments, the server sends notifications in the form of at least one text or graphic message to the second device to notify the user about an emergency event.

In one of the private embodiments of the server, notifications and / or control commands are transmitted, at least to the base station with their further transmission to the second device.

In one of the private embodiments, the second device is a bracelet, pendant, watch, mobile phone, laptop computer, computer, information board.

In one particular embodiment, the operator’s location is displayed to the operator on a site map displayed by the data visualization module, and / or a construction site map, and / or a city map, and / or a district map, and / or a location map.

In one particular embodiment, the action sensor is an accelerometer.

According to another embodiment, a device for remotely monitoring compliance with safety rules by employees is proposed, comprising: a presence sensor coupled to a processor of the wearable device, configured to detect the presence of the wearable device on the user, the absence of the wearable device on the user being an emergency event; an impact sensor associated with the processor of the wearable device, configured to record: effects on the wearable device by measuring the projection of acceleration, and the impact is a blow or a series of strokes on the wearable device, and the impact sensor registers the value of at least one impact; the presence of the fall phase of the wearable device when the wearable device is in a state of free fall in order to establish an emergency event corresponding to a fall from the height of the user of the wearable device; a temperature sensor associated with the processor of the wearable device, configured to record the temperature around the wearable device; a humidity sensor associated with the processor of the wearable device, configured to record the moisture value around the wearable device; data storage associated with the processor of the wearable device, configured to store critical values for recorded temperature and humidity by a temperature sensor and a humidity sensor; a processor of the wearable device, with software installed on it, configured to: compare values from the impact sensor, temperature sensor and humidity sensor with the corresponding critical values recorded by the said sensors stored in the data store of the wearable device; determining if critical values have been reached or exceeded for the exposure sensor, for the temperature sensor and for the humidity sensor in order to establish at least one fact of an emergency event corresponding to: a strong blow to the wearable device; critical temperature around the wearable device; critical humidity around the wearable device; determining a series of strikes on a wearable device, which is a request for help by a user of a wearable device and is a fact of an emergency event; determine the presence of the phase of the fall of the wearable device, which is a fact of an emergency event; determining the absence of a wearable device on the user, which is a fact of an emergency event; a battery of the wearable device associated with the processor, configured to power the wearable device; a communication module associated with the processor of the wearable device, configured to: transmit to the base station the values transmitted from the presence sensor, from the impact sensor, from the temperature sensor, from the humidity sensor, as well as the battery charge level value; transmitting the battery level of the wearable device to the base stations, as well as the facts of emergency events corresponding to: the absence of the wearable device on the user of the wearable device, the presence of a certain series of strokes on the wearable device, reaching or exceeding critical values for the temperature sensor and for the humidity sensor around the wearable device; the presence of the falling phase of the wearable device, the presence of a strong blow to the wearable device, and together with the fact of an emergency event, the communication module transmits to the base station the values of the impact sensor, temperature sensor and humidity sensor at the time the emergency event occurred, as well as the time of the emergency event, where the base event the station determines the value of the signal level received from the wearable device and transmits the base station to the server: Nala received from the portable device; the values transmitted by the communication module of the wearable device to the base station from the presence sensor, from the impact sensor, from the temperature sensor, from the humidity sensor and the battery level value of the wearable device; the fact of the emergency event and the values of the impact sensor, temperature sensor, humidity sensor and the battery level of the wearable device at the time the emergency event occurred, as well as the time of the emergency event transmitted by the communication module of the wearable device to the base station, and on the server, the data visualization module, which is part application server, alerts the operator that controls the user of the wearable device by displaying the received servers rum values of the signal level received from the wearable device, values from the presence sensor, from the impact sensor, from the temperature sensor, from the humidity sensor and the battery value of the wearable device, facts of emergency events and the values of the impact sensor, temperature sensor, humidity sensor and level value the battery charge of the wearable device at the time of the occurrence of an emergency event, as well as the time of occurrence of the emergency event.

In one particular embodiment, the presence sensor is an ultrasonic sensor and / or an infrared sensor.

In one particular embodiment, the battery of the wearable device is charged by at least one of the following methods for charging the battery: by means of a power connector located on the wearable device; by at least one solar cell associated with a wearable device; by contactless charging realized by an inductive loop.

In one particular embodiment, the processor of the wearable device is configured to determine, by using the software installed on the wearable device, to achieve the temperature recorded by the temperature sensor, a value close to the critical temperature, for a predetermined period of time in order to establish the fact of an emergency event, moreover, the processor using software, at least one base is transmitted via the communication module station and further to the server of such an emergency event and the time of occurrence of such an emergency event.

In one particular embodiment, the wearable device comprises a radio frequency identification tag for identifying the wearable device.

In one particular embodiment, the wearable device is mounted on protective equipment or integrated into wearable protective equipment.

In one of the private embodiments, the protective equipment is a helmet, helmet, mask, construction helmet, worker's helmet, protective helmet.

In one of the private embodiments, the communication module of the wearable device is configured to transmit data to the base station using ultra low power data channels, and / or LoRa, and / or LoRaWAN, and / or LPWAN, and / or 6LoWPAN, and / or Z-wave.

In one particular embodiment, the action sensor is an accelerometer.

BRIEF DESCRIPTION OF THE DRAWINGS

Additional objectives, features and advantages of the present invention will be apparent from reading the following description of an embodiment of the invention with reference to the accompanying drawings, in which:

FIG. 1 illustrates an exemplary embodiment of a system that implements the method described in the framework of the present invention.

FIG. 2 illustrates an exemplary embodiment of protective equipment by the example of a protective helmet, for example, a construction helmet, with a wearable device installed in or on it, or associated with it.

FIG. 3 illustrates an example embodiment of an application server.

FIG. 4 illustrates an exemplary map option for tracking the location of wearable devices.

FIG. 5 illustrates an example graphical interface of a data visualization module.

FIG. 6 illustrates a flowchart of an embodiment of the present invention.

FIG. 7 illustrates an example of a general purpose computer system.

DETAILED DESCRIPTION

The objects and features of the present invention, methods for achieving these objects and features will become apparent by reference to exemplary embodiments. However, the present invention is not limited to the exemplary embodiments disclosed below, it can be embodied in various forms. The essence described in the description is nothing more than the specific details provided to assist the specialist in the field of technology in a comprehensive understanding of the invention, and the present invention is defined only in the scope of the attached claims.

Used in the present description of the invention, the terms "component", "element", "system", "module", "part", in particular, "component", and the like are intended (used) to refer to computer entities (entities or objects associated with a computer, computing entities), which can be hardware, equipment (for example, a device, a tool, an apparatus, equipment, an integral part of a device, in particular, a processor, microprocessor, printed circuit board, etc.), software (Eg, executable program code, compile the application, software module, part of the software and / or code, etc.) or firmware (firmware / firmware). So, for example, a component can be a process running (running) on a processor, processor, object, executable file, program, function, method, library, subroutine and / or computing device (for example, a microcomputer or computer) or a combination of software or hardware . As an illustration: as an application running on a server can be a component or module, so the server can be a component or module. At least one component may be located within the process. A component may reside on a single computing device (eg, a computer) and / or may be distributed between two or more computing devices. So, for example, in a particular case, an application (for example, a component) can be represented by a server component (server part) and a client component (client part). In the particular case, the client component is installed on at least one computing device, and the server component is installed on the second computing device, from which, in the particular case, control and / or configuration of the first computing device (and / or its component components ( parts).

A system that implements the method (or at least one part of the method) described in the framework of the present invention, an example of which is shown in FIG. 1, contains at least one wearable device (110A ... 110N). Such wearable devices (110A ... 110N) can be various devices that the user can carry on himself or with himself. It is worth noting that the said wearable device (110A ... 110N) can also be integrated into a person’s garment. So, for example, a wearable device can be integrated, in particular, installed, fixed (in or on), in protective equipment (or devices, in particular devices and / or means of protecting an employee, ensuring the safety of an employee, etc.), for example , in a protective helmet, helmet, mask, etc.

Also, a wearable device (110A ... 110N) can be an independent device that does not require installation (in particular, integration) in other devices, including those worn by a person.

It is worth noting that in the particular case, the person who carries (in particular, carries) a wearable device (110A ... 110N) is a user of such a wearable device and a user of the system described in the framework of the present invention, a particular case of which (depicted in FIG. 1) allows you to implement the method described in the framework of the present invention.

It is also worth noting that wearable devices (110A ... 110N) can be or can be integrated into such devices (in particular, be part of such devices) as electronic devices, computing devices (users), various mobile devices, including, for example , phones, smartphones, tablets, laptops, tablets, personal computers, watches, walkie-talkies, key rings, lights, various sensors, actuating components, for example, engines, mechanisms, etc.

In the particular case, the wearable device (110A ... 110N) is a protective helmet (for example, a helmet of a builder, a helmet of a worker, etc.), an example implementation of which will be described later. A description of the present invention will now be given as an example of such a safety helmet, although it is understood that instead of a safety helmet any other device, equipment, etc. can be used.

System, an exemplary version of which is depicted in FIG. 1 may also include at least one base station (base device) (120A ... 120N). In the particular case, the base station (120A ... 120N) (or several of the mentioned base stations (120A ... 120N) for fault tolerance) is a gateway (for example, a LoRa gateway, LoRaWAN gateway, etc.), in particular, a network gateway and / or Internet gateway, etc. .. The base station (120A ... 120N) receives (receives) data from wearable devices (110A ... 110N) and sends (transfers) data from the base station (120A. ..120N) to at least one wearable device (110A ... 110N), for example, from at least one server 160A ... 160N. Also, the base station (120A ... 120N) transmits data received from wearable devices (110A ... 110N) to at least one server (160A ... 160N), for example, via an Ethernet cable, cellular or using any type (type) of communication. The base station (120A ... 120N) also receives data from the server (160A ... 160N) and transfers it to wearable devices (110A ... 110N).

Data transmission and reception by base stations 120A ... 120N is carried out, in particular, using the LoRaWAN protocol or using any type of communication (connection) that is described in the framework of the present invention. It is worth noting that the base station 120A ... 120N can determine (establish) the signal level of the wearable device 110A ... 110N and transmit such signal level values (signal strength data) to the server 160A ... 160N. The aforementioned transmission of signal level values can be carried out together with the transmission of data received by the base station 120A ... 120N from the wearable device 110A ... 110N, for example, together with sensor data, which are described in more detail below. It should be noted that the base station (120A ... 120N) in a particular case is a router that receives (receives) data, for example, according to the principle of receiving and transmitting data via a Wi-Fi router (Wi-Fi station, Wi-Fi module) and etc.

The base station may include a network server 198A or 198B installed (deployed) on it, which is a computing system that controls the process of receiving data from wearable devices 110A ... 110N and transmitting data to wearable devices 110A ... 110N. Such a network server (Network server) 198A or 198B allows receiving data by a base station (120A ... 120N) from wearable devices 110A ... 110N or additional devices (second devices), which are described in the framework of the present invention. Said data may be, for example, location data of an additional device user (not shown in FIG. 1) and / or wearable device 110A ... 110N, sensor readings of wearable device 110A ... 110N, etc. Also, the Network server 198A or 198B allows data transmission from base stations 120A ... 120N to wearable devices 110A ... 110N, as described in more detail within the framework of the present invention. The network server 198A or 198B installed on the base station 120A ... 120N also allows the transmission of the data (and other data described in the framework of the present invention) to the server 160A ... 160N. It is worth noting that in the particular case, the network server (Network server) is installed (deployed, located) either on at least one base station (120A ... 120N) or on the server (160A ... 160N). Network server 198A or 198B allows the server 160A ... 160N to receive data from base stations 120A ... 120N. Also, the Network server 198A or 198B allows sending data to the mentioned base stations (120A ... 120N), and also allows sending data to wearable devices 110A ... 110N and additional devices via the API (from the English application programming interface - application programming interface) of applications, systems, and services, which are described in more detail in the framework of the present invention.

As mentioned above, the described system, an exemplary version of which is depicted in FIG. 1 may include at least one server 160A ... 160N.

The server 160A ... 160N may include an application server 195. The application server 195, in a particular case, includes a data analytics module (analytical module, data analysis module) (310, FIG. 3), which, in a particular case, is implemented by a software module (in particular , at least one application), allows you to receive data from base stations (120A ... 120N) and process them, including display in the data visualization module 320, as described in more detail below. Also, the application server 195 may include a data visualization module (320, FIG. 3), processed, in particular, by a data analytics module (310, FIG. 3), and visualize the received data, in particular for the purpose of alerting (informing) the operator, for example, about emergency events. It is worth noting that, in the particular case, the data received by the server 160A ... 160N can be stored in at least one of the data stores (170A ... 170N), for example, in the data store 170D and / or 170B, etc. So, data storage in at least one data warehouse (170A ... 170N) can be carried out by the data storage module (330, FIG. 3). It should be noted that the data visualization module (320, FIG. 3) can receive data from third-party systems, services and devices (for example, by using the API of such systems, services and devices), in order to track and visualize the location of the wearable device (110A ... 110N ), in particular, to monitor and visualize the location of users of wearable devices (110A ... 110N).

It is worth noting that the data analytics module 310 of the server 160A ... 160N and / or the data visualization module can be connected with third-party (in particular, external to the server 160A ... 160N) systems and means for visualizing the location of employees on the map. It is worth noting that such third-party systems and services may include the use of third-party (in particular, additional) devices that provide at least the determination of user location data (for example, through the use of GPS systems and devices, and corresponding services). It is worth noting that additional devices equipped with a communication module, like wearable devices (110A ... 110N), can be electronic devices, computing devices, etc. and can be made in the form of trinkets, bracelets, watches, walkie-talkies, lights, various sensors, actuators, mechanisms, smartphones, phones, computers, etc. It is worth noting that such additional devices (as well as systems and services) can provide data at least to the server 160A ... 160N, and moreover, such data can be processed by the data analytics module 310 and / or displayed through the data visualization module 320, and can also be stored by data storage module 330, for example, in one of the described data stores.

It is also worth noting that the described server 160A ... 160N can be a remote server, virtual machine, cloud server, etc.

In the particular case, the data analytics module 310 can be an external module for the server 160A ... 160N, for example, it can be located on any other server, including those connected by at least one type of connection described in the framework of the present invention. It should be noted that the data analytics module 310 (including the external one) contains an API, in particular, an open interface for interaction between the server 160A ... 160N (in particular, between the server modules 160A ... 160N) and third-party applications and services. Such third-party applications and services through the interaction of their API (the API of such services and applications) and the API of the data analytics module 310 can provide information (data) to the data analytics module 310 with their further display in the data visualization module (module) 320. For example, said third-party (in relation to the system in FIG. 1) applications and services may include the provision of data that allows the display of various maps (maps of a site, for example, a construction site, a map of a city, district, area, etc.). It should be noted that data exchange between the data analytics module 310 (and the data visualization module 320) and third-party services and applications can be carried out using the API of the mentioned modules and / or applications and services.

So, for example, third-party applications and services can provide data, as well as ready-made solutions that can be used by data analytics module 310. Such third-party services and applications can provide data (in particular, data that are maps of the area, site of the area, etc. ) for processing by the data analytics module 310 and / or to display the data (for example, in the form of a map shown in FIG. 4) by means of the data visualization module 320.

It is worth noting that third-party services and applications can communicate with at least one operator with at least one user of the wearable device (110A ... 110N) using data from data analytics module 310 and data visualization module 320. It should be noted that the operator is the person controlling the user of the described wearable device 110A ... 110N. So, for example, the operator can monitor the user and / or wearable (user) device (110A ... 110N), for example, through the data visualization module 320 and at least notify the user of the wearable device (110A ... 110N) through feedback with the user, for example, through an additional device, as described in the framework of the present invention. It is worth noting that the said user control and user notification can be carried out by the operator, for example, using the data visualization module 320 and / or the data analytics module 310, as well as automatically by the server 160A ... 160N, in particular, through software that allows monitoring and / or notification of the user of the wearable device (110A ... 110N).

It should be noted that data from server 160A ... 160N, in particular, from application server 195 (for example, from data visualization module 320, data analytics module 310 and / or data storage module 330) can be transferred to third-party applications and services, in particular using the API of such services and applications. So, for example, when an event, in particular, an emergency event, associated with the user of the wearable device 110A ... 110N or with the wearable device 110A ... 110N itself occurs via the data analytics module 310 (and data visualization module 320), the wearable device 110A ... can be sent to the user 110N messages (alerts) about the corresponding emergency situation). In a particular case, the mentioned emergency event is an emergency, dangerous, potentially dangerous, critical, etc. situation. Such an emergency event may be the excess of the temperature recorded by the temperature sensor, critical (extreme) values, the excess of the permissible exposure recorded by the impact sensor, the presence of a sequence of actions registered by the impact sensor, which is a request for help from the user of the wearable device 110A ... 110N, leaving the user of the wearable device 110A ... 110N of a certain territory, for example, a building plot or area of a building plot, etc. It is worth noting that the sending of such notifications can be carried out not only to the user of the wearable device 110A ... 110N, but also to other users of the said wearable devices, other persons (foremen, site managers, company directors, operators, etc.), services (for example, emergency services, rescue services, control services, security services, etc.). Also, sending these alerts can be carried out to the user of the wearable device 110A ... 110N, both to the described wearable device 110A ... 110N, and to the aforementioned additional device, which may be present (present) at the user. Such additional devices can either send data to the server 160A ... 160N (for example, through the API of external applications and services), in particular, to the data analytics module 310, or receive data from the server 160A ... 160N, for example, from the data analytics module 310 using the mentioned APIs.

It is worth noting that the sent alerts can contain textual information that can be displayed to the user of the wearable device 110A ... 110N, as well as instructions and data that allow the transmission of data and notify the user through visual signals. Such said instructions and data may include commands (in particular control commands) for said additional devices. It is worth noting that these commands can be used, for example, by additional devices or wearable devices (110A ... 110N), to turn on indicators (for example, LED indicators), sound reproducing devices (for example, speakers, etc.), vibration devices etc. It is worth noting that the aforementioned additional device or wearable device can be identified by one of the means, devices and types of identification and identifiers. Such mentioned means, types and devices of identification and identifiers can be RFID tags, Wi-Fi tags, including worn and wearable tags, which, in the particular case, can be additional (identification) devices. Such additional devices may be associated with (may correspond to) a user-defined wearable device 110A ... 110N, in particular, they may be registered with a user-defined wearable device 110A ... 110N or wearable device 110A ... 110N. Mentioned identification (in the particular case, via a label) of the user of the wearable device 110A ... 110N can be used to transmit alerts to the user of the wearable device 110A ... 110N by the server (160A ... 160N). As mentioned above, for example, in case of emergency, the indicators transmitted from at least one wearable device 110A ... 110N through at least one base station 120A ... 120N to at least one server 160A ... 160N can be visualized by data visualization module 320 to alert the operator of such an emergency event.

It is worth noting that the mentioned emergency event, in the particular case, can be registered by at least one sensor of the wearable device 110A ... 110N, the impact of a certain force on the wearable device 110A ... 110N, for example, a strong blow to the wearable device 110A ... 110N, including protective equipment equipped with such a wearable device 110A ... 110N, as well as at least one series of actions (in particular, a sequence, a set, etc.) of such actions, for example, in the form of blows by a user of a wearable device 110A ... 110N , and recorded by at least one impact sensor, etc. Also, as mentioned above, an emergency event is the exceeding of the critical temperature recorded by at least one of the temperature sensors of the wearable device 110A ... 110N.

If the operator (server 160A ... 160N) detects such visualized critical (extreme) data (in a particular case, having critical (extreme) exposure values, etc.), the operator can notify the user of such a portable device 110A ... 110N through third-party services and applications , access to which, in a particular case, is carried out from the data visualization module 320 by using the described APIs of such services and applications. It is worth noting that the notification of the user of the wearable device 110A ... 110N can be carried out by means of an additional device (which may be or contain a (identification) user label), which is located at the user of the said wearable device 110A ... 110N.

It is also worth noting that, in a particular case, the user is a person who uses (in particular, wears) a wearable device (110A ... 110N), for example, a builder at a construction site, the head of a construction site, a fireman, etc.

It is also worth noting that a particular case of the user is at least one administrator (operator, etc.), i.e., in a particular case, a person interested, for example, in operability or in maintaining the operability of devices (equipment) for example, a server 160A ... 160N and / or base station (120A ... 120N), wearable devices (110A ... 110N), data warehouses (170A ... 170N), computer networks (computer, mobile and others).

It should be noted that the devices, modules, etc. described in the present invention. can be an integral part of the described system and / or can be connected to the said system, for example, connected by one or another known at present or invented in the future direct (for example, via terminals and / or wires, soldering, riveting, etc.) or indirectly (through intermediate devices, including various types of converters, in particular converters (converters) of information, including data in analog form, digital form or in any other known form of information) with the said system, for example ery, by means of wired communication, wireless communication, by means of various types of connectors, wires, etc.

Also, the described system may contain at least one data storage 170A ... 170N, which in a particular case can be a temporary data storage device (for example, Random Access Memory (RAM)), a permanent data storage (for example, (Programmable) Permanent Storage Device (ROM / ROM)), including those sold by at least one microcircuit and / or a set of microcircuits, etc.

Components (devices, modules, components, etc.) of the described system that implements the method described in the framework of the present invention, shown in FIG. 1, can be interconnected (and any other modules, devices, and servers capable of receiving information from the constituent parts of the described system and / or transmitting data to the described constituent parts of the system) via a local area network (LAN), the Internet (140), (by means of) mobile and / or satellite communications and / or by any other type (method) of wired communication (for example, via a USB interface, an RS-232 / COM port interface, etc.) and / or wireless communication, e.g. bluetooth, wifi, mobile cellular (GSM), including 3G, 4G, LTE, in particular, in the 850/900/1800/1900 MHz bands, satellite communications, trunked communications and data transmission channels with ultra-low power consumption, forming complex wireless networks with a mesh topology (ZigBee) , LoRa, LoRaWAN (Long Range wide-area networks), LPWAN (Low-Power Wide-Area Network), 6LoWPAN (IPv6 over Low power Wireless Personal Area Networks) Z-wave, etc.

It is worth noting that at least one part of the method described in the framework of the present invention (or the whole method) can be performed on the server 160A ... 160N and / or on the wearable device (110A ... 110N), and / or on / in the base stations (120A ... 120N), including, after establishing the connection of such devices (or any other module of the described system) with the server 160A ... 160N, and / or between such devices, in particular, through at least one protocol data transmission, including network protocol, for example, TCP / IP, HTTP / HTTPs (English Hyper Text Transfer Protocol, protocol hypertext transfer), FTP (File Transfer Protocol, file transfer protocol), etc., including protocols regulated by IEEE 802.15.4 standards, including existing add-ons, for example, specifications of top-level network protocols, in particular the level of the APS applications (from the English application support sublayer), and the network layer (NWK), which use, in particular, the services of the lower layers, the level of medium access control (MAC) and the physical layer (PHY), as well as those mentioned above, etc. .d.

The above server 160A ... 160N may comprise a web server. The aforementioned server 160A ... 160N can be implemented by a specialized computing device (in particular, a computer) and / or specialized equipment for executing service software on it (including servers and services for certain tasks).

The data warehouse (170A ... 170N) in FIG. 1 (which, in a particular case, can be an integral part of at least one module or device of the described system) is a device for storing information (data) and can be implemented by at least one hard disk drive (HDD) HDD, English hard (magnetic) disk drive), solid state drive (SSD, English solid-state drive), hybrid hard disk (SSHD, English solid-state hybrid drive), flash memory (flash drive), network data storage (SHAN / SAN, the English Storage Area Network), a network storage system / network storage (NAS, English Network Att ached Storage) and / or any other device that allows at least writing to the device, reading from the device and / or storing data on the device. Data in data warehouses (170A ... 170N) can be stored in any known format, for example, in a database (DB), for example, in the form of at least one table or a set of related or unrelated database tables. It should be noted that at least one of the mentioned databases can be hierarchical, object, object-oriented, object-relational, relational, network and / or functional database, each of which can be centralized, concentrated, distributed, heterogeneous, homogeneous, fragmented / partitioned, replicated, spatial, temporal, spatio-temporal, cyclic, super-large database, etc., moreover, for the management, creation and use of databases can be used use various database management systems (DBMS).

Also, data in data storages (170A ... 170N) can be stored in at least one file, in particular, in the form of a text file, or data can be stored in any at least one other format currently known storing data / information or in a data format invented later.

In the particular case, at least one part of the described method and system may be software or part of an application. So, in the particular case, the application can be used for monitoring and / or control (including tracking parameters, control, data transfer, etc., including their constituent elements or modules) of at least one described module of the system.

Also, at least one part of the described method and system may be at least one service implemented, for example, by program code, script / scripts, and also be executable components of various systems (in particular, computer systems) and subsystems (for example , subsystems, input, output subsystems (in particular, the graphics subsystem), storage (in particular, the disk subsystem), data transfer, etc.). Such software, services and / or other methods, in particular, implemented in software or hardware, as well as any combination of them, or any part thereof, are capable of controlling, monitoring, informing, managing, including through data transmission, etc. . at least one module / device of the described system or other software, services, hardware and / or modules (software or hardware).

It is worth noting that the above means of software components, devices and / or modules may include the execution (execution) of program code, executable application code, machine code, etc., in particular, in compiled and / or non-compiled form, for example, in the form of javascript (java-scripts), as well as in the form of one of the intermediate languages (programming), for example, the intermediate language CIL, from English. Common Intermediate Language.

Also, the described devices, as well as their components (elements), modules, etc. can be implemented as two or more devices (modules, elements, etc.), and one device or module, etc. Also, in the particular case, at least one element of the described system (in particular, a module), or at least one component thereof can be implemented by at least one executable file. Moreover, in the particular case, a module (in particular, a software module) can be implemented (be) one executable file, which in turn can be associated with at least one software library, for example, implemented as a dll file, which is a compiled form of a dynamic link library (from the English Dynamic Link Library), and also with at least one file, for example, containing application service data, application metadata, data necessary for the application to function, and / or a service (local and / or remote, for example, a web service / web service), including applications and services built on a service-oriented architecture (from the English service-oriented architecture / SOA), including, but not limited to, REST technologies (from the English Representational State Transfer - “transferring the state of a presentation”), remote procedure call (from the English. Remote Procedure Call, RPC) and others.

In FIG. 2 shows an exemplary embodiment of protective equipment 200 by the example of a protective helmet (for example, a construction helmet) with a wearable device (110A ... 110N) installed in or on it, or associated with it. It is worth noting that the wearable device (110A ... 110N) can be placed in any part of the protective equipment 200, for example, as shown in FIG. 2 (including in positions 210A ... 210N). In the particular case, the described method, system and (wearable) device allow you to control (including, in real time), the fact that the wearable device (110A ... 110N) is present when the user, on the user or next to the user ( in particular, in the immediate vicinity of the user). So, in the particular case when the wearable device (110A ... 110N) is a helmet (helmet, etc.), the described method, system and / or device allow using at least one presence sensor 230 to detect the fact that the helmet (in the particular case, the wearable device (110A ... 110N)) is worn on the user's head (in particular, the wearable device is located at least on one part of the user or connected to it), i.e., in the private case, the user's head is present in the helmet. Such a sensor for the presence of the wearable device 110A ... 110N on the user (or at least on one part of the user's body, for example, on the head) can be an ultrasonic sensor (for example, an ultrasonic rangefinder, in particular, the HC-SR04 ultrasonic rangefinder) and / or infrared sensor (e.g. KP3216 p3c with F3c). Such a presence detector 230 may be part of a wearable device (110A ... 110N) or may be mounted on protective equipment 200 and connected with at least one of the types (types) of communication described above with a wearable device (110A ... 110N) .

It is worth noting that in the present invention, at least one impact sensor 240 allows you to record (determine) and track the effects, in particular, of shocks, on a wearable device (110A ... 110N) and on protective equipment, and such effects may be shocks wearable device 110A ... 110N (or a protective device equipped with such a wearable device). It is also worth noting that the impact sensor allows you to measure the projection of acceleration (in particular, the apparent acceleration, which is the difference between the true acceleration of the object and gravitational acceleration). So, for example, the impact on the impact sensor (in the particular case, which is an accelerometer) equal to more than two (2G), three (3G), etc. G (the values of the acceleration of gravity (on the Earth's surface)) can be an extreme (strong) impact on the wearable device 110A ... 110N (and means are protected), and, accordingly, on the user of such a wearable device. It is worth noting that the wearable device (110A ... 110N) allows you to register (track) the presence of the falling phase of the wearable device (110A ... 110N), and the user of such a wearable device (and wearable protective equipment), using an exposure sensor 240. It is worth noting that the mentioned phase of falling is when the user of the wearable device (110A ... 110N) is in a free fall state, in particular, when the exposure sensor 240 registers a value G equal to zero (or close to zero), for example, for a predefined time wearable device (110A ... 110N), for example, within a few tenths of a second or seconds. It is worth noting that the phase of the fall of the wearable device (110A ... 110N) can occur (and be registered), in particular, if the user fell (fell) from a scaffold, crane, etc. As mentioned above, the implementation and determination of effects on the wearable device (110A ... 110N) can be carried out by at least one impact sensor 240, and such a sensor can be a shock sensor and / or a weightlessness sensor (for example, Lis2dh) with a wearable device (110A ... 110N) or mounted in or on protective equipment 200, and the impact sensor is associated with a wearable device (110A ... 110N) one of the types or types of communication described above.

It is worth noting that the data (information) recorded by the exposure sensor 240 of the wearable device (110A ... 110N), in particular, data on the presence of shock or blows on the wearable device (110A ... 110N), as well as data on the presence of the fact of free fall wearable device (110A ... 110N), as well as data from the presence sensor 230 that the protective equipment is worn by the user, can be transmitted to at least one base station (120A ... 120N) and (hereinafter) to the server 160A ... 160N.

It is worth noting that the impact sensor 240 can detect various forms of exposure to a wearable device (110A ... 110N) and / or protective equipment with which the wearable device (110A ... 110N) is associated. So, for example, the impact sensor 240 can record the impact by the user of a wearable device (110A ... 110N) on a wearable device (110A ... 110N) and / or protective equipment 200. So, for example, such a user action can be performed by the user through a series (set, sequences, etc.) of impacts on a wearable device (110A ... 110N) and / or protective equipment 200, for example, through a series (set, sequence, etc.) of blows on a wearable device (110A ... 110N) and / or protective equipment 200. So, for example Example, the impact on the wearable device (110A ... 110N) and / or protective equipment 200 may be one, two, three or more effects (in particular, impacts) on the wearable device (110A ... 110N) and / or protective equipment 200, and data such influences can be transmitted by at least one wearable device (110A ... 110N) and / or protective equipment 200 to at least one base station (120A ... 120N) and (further) to the server 160A ... 160N. Such a user interaction may be carried out by at least one part of the user on the wearable device (110A ... 110N), or by striking the user with a wearable device (110A ... 110N) (or any part of the user's body with a wearable device mounted on it (110A ... 110N)) about any object surrounding the user, for example, a building structure, equipment, etc., or about another wearable device (110A ... 110N) or an additional (wearable) device, which is described in more detail below. It is worth noting that such an impact can be carried out by the user by moving the wearable device (110A ... 110N) in space (in particular, at least with respect to one part of the user's body or the user himself) with at least one hit. So, for example, a user of a wearable device (110A ... 110N) can knock (or shake) one of the parts of the body (on which is attached (which is worn) or in which the mentioned wearable device is located), for example, with his hand, head, leg, torso etc. for the transmission of a signal (in particular) for assistance that will be registered by the exposure sensor 240.

It is also worth noting that the aforementioned impact on the wearable device (110A ... 110N) of one (first) user can be carried out by another (second) user (who, in a particular case, can be equipped with another wearable device (110A ... 110N) or not to be equipped with such another wearable device), at least one of the methods described above.

In the particular case, the wearable device (110A ... 110N) and / or protective equipment 200 can be performed single (in particular, single) or multiple (for example, more than two) exposure, as described above. Data on such influences, as well as their type, strength, duration and frequency, measured by at least one sensor of the portable device 110A ... 110N, can be transmitted to the base station 120A ... 120N, including for the purpose of further transmission to the server 160A ... 160N, for example, for the purpose of alerting the operator, in particular, through visualization by the data visualization module 320 (FIG. 3) and / or with the aim of processing such data through the data analytics module 310, including the data storage module 330, etc. .

Also, the described method, system and device allow you to register and monitor the temperature change inside the wearable device (110A ... 110N). So, for example, a wearable device (110A ... 110N) may include at least one temperature sensor 250 (for example, HLGA-6L_L2mm_W2mm_H0.9mm), which monitors the temperature inside the wearable device (110A ... 110N) or inside the protective equipment 200. It is worth noting that the temperature recorded by the temperature sensor 250, as well as the fact that the temperature inside the wearable device (110A ... 110N) or the protective equipment 200 is exceeded, is critical or the temperature inside such a wearable device (110A ... 110N) is close to critical at a given (predefined) time period, it can be transmitted (from a portable device (110A ... 110N)) to at least one base station (120A ... 120N) and then to a server 160A ... 160N. It is worth noting that the critical temperature value can be set (predefined) on the server 160A ... 160N (for example, by the operator of the server 160A ... 160N, in particular the operator of the data visualization module 320) or can be set by programming the wearable device 110A ... 110N. So, the critical temperature value of the wearable device 110A ... 110N may be a value equal to 70 degrees Celsius, 80 degrees Celsius, etc. or equal to minus 20 degrees Celsius, minus 50 degrees Celsius, etc. Thus, the critical temperature of the device may have a lower critical temperature and an upper critical temperature. It is worth noting that the value (s) of the critical temperature can be predefined depending on the environment in which the wearable device 110A ... 110N is used, for example, in countries with hot climates, rooms with high temperatures inside them, and areas with low ambient temperatures etc.

It is worth noting that the wearable device (110A ... 110N) may include a humidity sensor that allows you to measure humidity inside the protective equipment in which the wearable device 110A ... 110N is installed, or around such protective equipment. So, for example, a humidity sensor can detect humidity in the room in which the user of the wearable device 110A ... 110N is located, and such humidity values can be transmitted by the wearable device 110A ... 110N to the base station 120A ... 120N and further to the server 160A ... 160N for the purpose of processing them a data analytics module 310 and a data visualization module 320 display.

It should be noted that on the server 160A ... 160N and / or base station (120A ... 120N) the transmitted information (data) from the temperature sensor 250 by the wearable device (110A ... 110N) is the temperature of the wearable device 110A ... 110N, as well as data (about impact on a wearable device (110A ... 110N) or protective equipment) registered by the impact sensor (shock sensor and / or weightlessness sensor) 240, as well as from the presence sensor 230 can be analyzed by data analytics module 310 (FIG. 3), which is part server 160A ... 160N, and the results of this analysis are m Gut be used to perform various actions, such as beginning and / or coordinating a rescue user operation, with portable devices which have been transmitted corresponding to data (information).

Also, the wearable device (110A ... 110N) includes a communication module 260, in particular, which is a transceiver or containing at least one transceiver. Communication module 260 transmits data, including from a presence sensor 230, an exposure sensor 240, a temperature sensor 250 and other sensors, a wearable device (110A ... 110N), in particular, to at least one base station 120A ... 120N and beyond at least one server 160A ... 160N. In the particular case, the communication module 260 transmits via wireless modes of communication, which are described in more detail above, including with support for the LoRaWAN or WiFi protocol.

Also, a wearable device (110A ... 110N) can include a power source (for example, 550mAh 3.7 Li-Po), in particular a battery (battery, rechargeable battery), such a wearable device and a charge level control sensor (for example, WSON-12 ) of such a power source.

In the particular case, the power source of the wearable device (110A ... 110N) can be charged (recharged) by at least one of the following methods for charging the power source:

- through the power connector located on the wearable device (110A ... 110N);

- by means of at least one solar battery connected to a wearable device (110A ... 110N) and, in a particular case, placed on protective equipment, for example, on the surface of a wearable equipment;

- by means of contactless charging (inductive loop).

In the particular case, at least one of the described sensors and / or modules of the wearable device (110A ... 110N) can be located on or connected to a (universal) computing device, in the particular case a single-board computer, in the particular case implemented (mother) computer circuit board (printed circuit board, in particular, which is a software and hardware tool for creating systems (for example, automation and robotics), the basis for constructing a wearable device (110A ... 110N)). Such a (universal) computing device can be, for example, ODroid-C2, Intel Galileo, Raspberry Pi, Arduino (including AT-Mega328), Microsoft .NET Gadgeteer, ProtoSnap and others, in particular, including at least one processor (or microprocessor). Also, a computing device can be any known programmable microcomputers, computers, computers, personal computers, personal computers, mobile computing devices (such as smartphones, tablets, mobile phones, etc.) and other computing devices. It is worth noting that such a (universal) computing device can include microcontrollers, processors and / or microprocessors that can process data received from the described sensors of the wearable device 110A ... 110N and send (transmit) data via the communication module 260 of the wearable device 110A ... 110N at least one base station 120A ... 120N. Said data processing may include comparing the current readings of the described sensors with critical values corresponding to emergency (critical) events, for example, exceeding critical values, stored in the data storage of the wearable device 110A ... 110N (or with received wearable devices 110A ... 110N from the server 160A ... 160N) temperature, the presence of strong impacts (in particular, shock), weightlessness, overload.

As mentioned above, the wearable device (110A ... 110N) may include an identifier, for example, an RFID tag, or may be associated with such an identifier located on security equipment 200 or another device, in particular, an additional RFID device (Radio Frequency) IDentification, radio frequency identification) is a method of identifying objects (for example, wearable devices (110A ... 110N) or protective equipment 200) in which data stored in transponders or RFID tags are read or written by radio signals. In the particular case of the use of wearable devices (110A ... 110N) and / or the aforementioned additional devices together with the identifiers mentioned (user or one of the devices, including wearable, protective equipment, etc.), in particular, with RFID- tags operating via a Wi-Fi network or any other type of communication described in the framework of the present invention, tracking the location of the user of the wearable device (110A ... 110N) can be carried out. It should be noted that tracking the user's location, in particular on a map (for example, a country, city, construction site or any other part of the territory) can be carried out in real time, for example, by transmitting data from an additional device and / or from a wearable device 110A ... 110N, in particular, using third-party services, applications and systems. In the particular case, the operator can send to the additional device and / or wearable device 110A ... 110N, in the particular case, equipped with an identifier (for example, a label), an alert in any of the known formats, for example, text, visual, etc. moreover, alerts can include operational instructions (in particular, control commands, operational instructions, control instructions) for a user of a wearable device (110A ... 110N) and / or an additional device. Mentioned operational commands (in particular, control commands) can be transmitted from the server 160A ... 160N through at least one base station 120A ... 120N, including using third-party services (services), applications, systems, etc. using the API of such third-party services, applications, systems, and using the API provided by the server 160A ... 160N, including the data visualization module 320 and / or data analytics module 310.

In FIG. Figure 3 shows an exemplary version of application server 195. As described above, server 160A ... 160N can include various modules, the combination of which or part of which can be implemented by an application server (application server - a software platform (framework) designed for efficient execution of procedures (programs, scripts, etc.) 195, and the application server 195 functions (works) as a set of components (in particular, modules) available to the software developer through the API defined by the platform itself. 195 may include a data analytics module 310, which, in a particular case, may be implemented by at least one hardware (in particular at least one computer) and / or software device or module (in particular, at least , one application or service.) Application server 195 allows you to receive data from base stations (120A ... 120N) transmitted by wearable devices (110A ... 110N), or from other devices (in particular, additional devices, for example, equipped with user identifiers or such additional stroystv) and modules (e.g., third-party services, applications, systems, etc.) described in the present invention. Application server 195 can process the received data and convert it, in particular, to the format of at least one other application server module 195, for example, to the format of the data visualization module 320, data storage module 330, data analytics module 310, and to the format of third-party services, applications, systems, etc. It is worth noting that the server 160A ... 160N, in particular, the application server 195 can send data (for example, described alerts) to at least one wearable device 110A ... 110N and / or an additional device (including one with an identifier, for example , a tag, in particular, an RFID tag) through base stations (in particular, base stations (120A ... 120N)) and / or third-party services, applications, systems, etc. through appropriate APIs, as described in the framework of the present invention. Sending said data to the described wearable devices and / or additional devices can be done automatically by the server or by the operator. So, for example, when recording, for example, a data analytics module 310 emergency events (critical, in particular, extreme temperatures, impacts, falls, help signals, for example, recorded by the described exposure sensor, etc.) server 160A ... 160N (in particular, the application server 195) can send alerts to the user of the wearable device 110A ... 110N or additional device, as well as sending control commands to the wearable device 110A ... 110N or additional device, as described above, for example Through the use of third-party API services, applications and systems, etc. or its own data transmission module, for example, through a network server (Network server) 198A or 198B.

Application server 195 may include a data visualization module 320, for example, obtained and processed by data analytics module 310. In the particular case, data visualization module 320 is a user interface and may be a web interface. The data visualization module 320 may visualize (display) the received data via a graphical user interface, an example of which is shown in FIG. 5, using a monitor (display). Also, the data visualization module 320 allows you to visualize the received data (from the data analytics module 310 and / or from wearable devices (110A ... 110N), and / or base stations (120A ... 120N), etc.) on the map, as shown in FIG. 4. It is worth noting that the data visualization module 320 notifies the operator by presenting (displaying, visualizing) data received from the base station, in particular, notifying the operator by displaying messages about the facts of emergency events, as well as information related to emergency events in particular, the values of the sensors of the wearable device (110A ... 110N).

Also, the application server 195 may include a data storage module 330, which, in the particular case, stores at least one of the data stores (170A ... 170N) transferred to the server 160A ... 160N (in the particular case, at least , into one of the server modules 160A ... 160N) of the data, including data processed by the data analytics module 310.

In FIG. 4 shows an exemplary version of a map that allows you to track the location of wearable devices (110A ... 110N). In the shown in FIG. On the map (410), at least wearable devices (110A ... 110N), base stations (120A ... 120N) and other devices, in particular the additional devices mentioned above, can be displayed. In the particular case, the coordinates of the geographic location (location) of the wearable device (110A ... 110N) are determined by determining the location of the user of the wearable device (110A ... 110N) by using an additional device equipped with tracking modules for the user's location (for example, GPS modules), as described above, and allowing you to track the user's location and send (transmit) the coordinates of the user's location servers 160A ... 160N, etc. It is also worth noting that the location of the wearable device (110A ... 110N) can be used to determine the absence on the user of a wearable device (110A ... 110N), in particular, if the user is equipped with another (additional) device. Such an additional device may be a bracelet, mobile (cell) phone, walkie-talkie, etc. In the particular case, by determining the location (including the geographic location of the user of the wearable device (110A ... 110N) and one of the additional devices), in particular by determining the distance between the location of the wearable device (110A ... 110N) and the location of the additional device, the fact that the wearable device (110A ... 110N) is not present on the user or in the immediate vicinity of the user. It should be noted that the additional device can be equipped with communication tools, means for determining the user's location (including GPS), and also have a set of modules and functionality (including partial) of a wearable device (110A ... 110N), for example, include, at least one communication module 260 (FIG. 2).

In FIG. 5 shows an exemplary graphical interface of a data visualization module. In the particular case presented in FIG. 5, the graphical interface of the data visualization module 320 is a graphical user interface (in particular, a implemented web interface), i.e. in this case, the operator. So, the operator is a special case of the user and can monitor (track) events that occur with the wearable device (110A ... 110N). Data visualization module 320 informs (in particular, notifies) the operator of the values recorded by sensors of wearable devices (110A ... 110N), including emergency events, and transmitted in the form of data by base stations (120A ... 120N) and wearable device (110A ... 110N) by means of a communication module 260 from sensors (for example, a presence sensor 230, an exposure sensor 240, a temperature sensor 250, etc.) to a server 160A ... 160N, in particular to a data analytics module 310 and / or a data visualization module 320, and / or data stored in at least one of the repositories OF DATA (170A ... 170N) storage module 330, or any other means, units, devices, services (services), etc.

So, in the graphical operator interface shown in FIG. 5, data such as:

- data (520) recorded by the temperature sensor 250;

- data recorded by the impact sensor 240;

- data recorded by the presence sensor 230;

- data (530) about the signal level of the wearable device (110A ... 110N);

- data (510) about the battery level of the wearable device (110A ... 110N);

- data on whether the user is equipped with a wearable device (110A ... 110N), for example, the protective equipment equipped with a wearable device is removed or dressed by the user, whether the wearable device (110A ... 110N) is fastened to a belt, protective equipment, etc .;

- events (540), in particular, emergency events (for example, exceeding the critical temperature of a wearable device, severe impact, requesting user assistance for a wearable device, etc.)

and other data, in particular, recorded by any other sensors and devices, as well as services, applications and systems, and transmitted to the server 160A ... 160N, in particular, to the data visualization module 320 and / or data analytics module 310, and / or the module data storage 330.

Also, in the graphical interface of the data visualization module 320 (in particular, in the graphical operator interface) shown in FIG. 5, personal data of at least one user of the wearable device (110A ... 110N) may be displayed by the data visualization module 320, for example, the last name, first name and / or middle name (550) of the user of the wearable device (110A ... 110N).

As mentioned above, in the graphical interface of the data visualization module 320 (in particular, in the graphical operator interface) shown in FIG. 5, data on the charge level of the power source of the wearable device (110A ... 110N) can be displayed by the data visualization module 320.

Also, in the graphical interface of the data visualization module 320 (in particular, in the graphical operator interface) shown in FIG. 5, map 410 may be displayed by data visualization module 320.

As mentioned above, in the graphical interface of the data visualization module 320 (in particular, in the graphical operator interface) shown in FIG. 5, the data visualization module 320 can display data on the signal level received from the wearable device (110A ... 110N) by the base station (120A ... 120N) and transmitted by the base station (120A ... 120N) to the server 160A ... 160N by the base station (120A ... 120N) at least in one of the server modules 160A ... 160N, for example, in the data analytics module 310. In the particular case, the signal level can be an indicator of the level of the received signal (RSSI, from the English received signal strength indicator), which is (complete ) the power received by the base station (120A ... 120N) of the signal from the wearable device va (110A ... 110N), which in the particular case is measured by the base station (120A ... 120N) on a logarithmic scale in dBm (dBm, decibels relative to 1 milliwatt). It is also worth noting that the graphical operator interface shown in FIG. 5 can be displayed by the data visualization module 320 signal level data, in particular, signal-to-noise ratio data (SNR, from the English signal-to-noise ratio, abbreviated SNR, which is a dimensionless quantity equal to the ratio of the useful signal power to the noise power) determined (recorded) by at least one base station (120A ... 120N) by analyzing signals from a wearable device (110A ... 110N).

Also, in the particular case, in the graphical interface of the data visualization module 320 (in particular, in the graphical operator interface) shown in FIG. 5, the data visualization module 320 may display information about a user requesting a wearable device (110A ... 110N) for help, in particular from an operator monitoring (monitoring) the state of users of wearable devices 110A ... 110N). In particular, a request for feedback, for example, a request for help, a request for the operator to contact the user of the wearable device (110A ... 110N) and / or for the user of the wearable device (110A ... 110N) to contact the operator, etc., can be implemented by performing the described effects on a wearable device (110A ... 110N) and / or protective equipment 200.

Also, in the particular case, in the graphical interface of the data visualization module 320 (in particular, in the graphical operator interface) shown in FIG. 5, graphical elements 560A ... 560N can be displayed by the data visualization module 320 for the operator to take actions, depending on events (in particular emergency events), as well as to notify users of the wearable device (110A ... 110N), operator, rescue services, etc. .d.

In FIG. 6 is a flowchart of an embodiment of the present invention. In step 610, the sensors register at least one wearable device (110A ... 110N) of the data. In step 610, the presence sensor 230 associated with the processor of the wearable device (110A ... 110N), registers the presence of the wearable device (110A ... 110N) on the user, and the absence of the wearable device (110A ... 110N) on the user is an emergency event. Also, in step 610, an impact sensor 240 associated with the processor of the wearable device (110A ... 110N) records the effects on the wearable device (110A ... 110N) by measuring the projection of the acceleration, the effects being a blow or a series of strokes on a wearable device (110A ... 110N), moreover, the impact sensor 240 registers the value of the force of at least one impact. An impact sensor 240 also detects the presence of the fall phase of the wearable device (110A ... 110N) when the wearable device (110A ... 110N) is in a free fall state in order to establish an emergency event corresponding to a fall from the user's height of the wearable device (110A ... 110N). Also in step 610, the temperature sensor 250 associated with the processor of the wearable device (110A ... 110N), records the temperature around the wearable device (110A ... 110N). Also, in step 610, a humidity sensor associated with the processor of the wearable device (110A ... 110N) records the humidity around the wearable device (110A ... 110N).

In step 620, the communication module 260 associated with the processor of the wearable device (110A ... 110N) transmits to at least one base station 120A ... 120N the values transmitted from the presence detector 230, from the action sensor 240, from the temperature sensor 250, with a humidity sensor, as well as the value of the battery level of the wearable device (110A ... 110N). It is worth noting that the data from the sensors can be transmitted online (in particular, by a continuous stream of data or data packets), as well as with a certain frequency (in particular, determined by the software of the wearable device (110A ... 110N) and the executable processor (or microprocessor) of such a wearable device, and the value of the frequency of data transfer can be stored in the data storage of the wearable device (110A ... 110N) and can be set ("set", "programmed") by the user of such a device, the operator m programmer performing the creation and maintenance of a wearable device (110A ... 110N), etc.). It is also worth noting that the wearable device (110A ... 110N) can send (transmit) data only in emergency cases, for example, when critical values of sensors, help signals, etc. are reached. In this case, the wearable device (110A ... 110N), in particular, in step 610, processes the data recorded by the described sensors (in particular, the presence sensor 230, the impact sensor 240, the temperature sensor 250), and detects such emergency events (in in particular, by means of a program (or microprogram) executed by a processor (or microprocessor) of a wearable device (110A ... 110N)), after which it sends data on emergency events with the corresponding sensor values (readings) corresponding to such critical events. So, the processor and software of the wearable device (110A ... 110N), in particular, in step 610, compares the obtained values from the exposure sensor 240, temperature sensor 250 and humidity sensor with the corresponding critical values recorded by the said sensors stored in the wearable data storage devices (110A ... 110N). Also, the processor and software of the wearable device (110A ... 110N) determine the achievement or excess of critical values for the impact sensor 240, for the temperature sensor 250 and for the humidity sensor in order to establish at least one fact of an emergency event corresponding to a strong impact on wearable device, critical temperature around the wearable device, critical humidity around the wearable device (110A ... 110N). The processor and software of the wearable device (110A ... 110N) also determines the series of hits on the wearable device (110A ... 110N), which is a request for help from the user of the wearable device (110A ... 110N) and is an emergency event. The processor and software of the wearable device (110A ... 110N) also determines the presence of the falling phase of the wearable device (110A ... 110N), which is a fact of an emergency event. The processor and software of the wearable device (110A ... 110N) also determines the absence of the wearable device on the user, which is a fact of an emergency event. Thus, the communication module 260 transmits at least one base station 120A ... 120N of the battery level of the wearable device (110A ... 110N), as well as at least one fact of an emergency event corresponding to the absence of the wearable device ( 110A ... 110N) on the user, the presence of a certain series of strokes on the wearable device (110A ... 110N), the achievement or exceeding of critical values for the temperature sensor 250 and for the humidity sensor around the wearable device, the presence of the falling phase of the wearable device (110A ... 110N), the presence of strong about hitting a wearable device (110A ... 110N). It is worth noting that, together with the fact of an emergency event, the communication module 260 transmits to the base station 120A ... 120N the values of the said sensors at the time of the occurrence of the emergency event, as well as the time (and in the particular case, date) of the occurrence of the emergency event. It should be noted that the processor and software of the wearable device 110A ... 110N can determine the achievement of the temperature detected by the temperature sensor 250, a value close to the critical temperature, for a predetermined period (in particular, on the wearable device 110A ... 110N) of a time period in order to establish the fact an emergency event, and such an emergency event is transmitted by the communication module 260 to at least one base station 120A ... 120N and then to the server 160A ... 160N of such an emergency event and time Meni (and in the particular case, the date) the occurrence of the emergency event.

Next, in step 630, data is sent (transmitted) from at least one base station 120A ... 120N to at least one server 160A ... 160N, and such data may contain signal strength values received from the wearable device 110A ... 110N the base station 120A ... 120N, values from the presence sensor 230, from the action sensor, from the temperature sensor 250, from the humidity sensor and the battery level of the wearable device 110A ... 110N, as well as at least one fact of the emergency event and the values of the said sensors and the value of the charge level yes Battery portable devices 110A ... 110N, registered, at least at the time of emergency events, as well as the time (in particular, the date of) the occurrence of emergency events.

Next, in step 640, on the server 160A ... 160N, the data analytics module 310 processes the data received by the server 160A ... 160N from the base stations (as well as third-party services, applications and systems) and visualizes such data (including those processed by the data analytics module) 310) data visualization module 320.

Next, in step 650, the server 160A ... 160N checks the received data and the occurrence of an event requiring action (for example, sending messages, notifications, etc. to the user of the wearable device 100A ... 110N, the operator, calling emergency services for assistance to the user, etc.) by the operator or automatically by the server 160A ... 160N, depending on the type of events. If an emergency event was not recorded in step 650 (in particular, determined by the data analytics module 310 on the basis of the received data from the wearable device (110A ... 110N) through the base station 120A ... 120N or on the facts of emergency events transmitted by the wearable devices 110A ... 110N), then returns to step 610, otherwise, step 660 is performed in which the actions described in the framework of the present invention are carried out, depending on the type of event recorded. So, for example, an (registered) event can be an emergency event and / or may require actions in step 660 by an operator, in particular by means of a data visualization module 320, and / or automatically by a server 160A ... 160N, for example, by algorithms (in particular, implemented software, including data analytics module 310). It is worth noting that the aforementioned actions performed by the operator and / or automatically by the server 160A ... 160N may be the transmission of a message to the user of the wearable device 110A ... 110N, for example, to the user's mobile computing device (e.g., smartphone, mobile (cellular) phone, tablet, smart watches, smart bracelets, etc.) equipped with a module for receiving and transmitting signals and messages in various formats to the described additional (including wearable) device, information board, for example, installed on a building plot, etc. Such signals and messages can be reproduced on the mentioned devices as a text message, light indication, sound signals, vibration, etc. It is also worth noting that the mentioned actions are also actions carried out automatically (in particular, by means of server software modules 160A ... 160N, for example, data analytics module 310). It is worth noting that the actions taken may be calling emergency services by the operator or automatically by means of the server 160A ... 160N. Also, in step 660, at least the operator who controls the user of the wearable device 110A ... 110N is notified by displaying the data visualization module 320 received by the server 160A ... 160N of the signal level received from the wearable device 110A ... 110N from the sensors and values of the battery level of the wearable device, the fact of an emergency event and the values of the impact sensor, temperature sensor, humidity sensor and the value of the battery level of the wearable device at the time of occurrence emergency event, as well as the time of occurrence of the emergency event. It is worth noting that the notification of the operator can be accompanied by playing the operator an audio signal, a light signal, transmitting a message to a user device (for example, a wearable device 110A ... 110N, a mobile device, etc.) and any other known means of attracting attention and warning a person.

After step 660, you are returned to step 610.

In FIG. 7 shows an example of a general-purpose computer system that includes a multi-purpose computing device in the form of a computer 20 or a server, or a module of the system described in the present invention, including a processor 21, system memory 22, and system bus 23 that couples various system components, including system memory with 21 processor.

The system bus 23 may be any of various types of bus structures, including a memory bus or memory controller, a peripheral bus, and a local bus using any of a variety of bus architectures. System memory includes read-only memory (ROM) 24 and random access memory (RAM) 25. The ROM 24 stores the basic input / output system 26 (BIOS), consisting of basic routines that help exchange information between elements within the computer 20, for example, at the time of launch.

Computer 20 may also include a hard disk drive 27 for reading from and writing to a hard disk, not shown, a magnetic disk drive 28 for reading from or writing to a removable magnetic disk 29, and an optical disk drive 30 for reading from or recording to a removable optical disc 31 such as a compact disc, a digital video disc, and other optical means. The hard disk drive 27, the magnetic disk drive 28, and the optical disk drive 30 are connected to the system bus 23 by means of the hard disk drive interface 32, the magnetic disk drive interface 33, and the optical drive interface 34, respectively. Storage devices and their respective computer-readable means provide non-volatile storage of computer-readable instructions, data structures, program modules and other data for computer 20.

Although the typical configuration described here uses a hard disk, a removable magnetic disk 29, and a removable optical disk 31, one skilled in the art will appreciate that other types of computer-readable media that can store data that are accessible by a computer may also be used in a typical operating environment. such as magnetic cassettes, flash memory cards, digital video disks, Bernoulli cartridges, random access memory (RAM), read-only memory (ROM), etc.

Various software modules, including operating system 35, may be stored on a hard disk, magnetic disk 29, optical disk 31, ROM 24, or RAM 25. Computer 20 includes a file system 36 associated with or included with the operating system 35 or more software application 37, other program modules 38, and program data 39. A user may enter commands and information into computer 20 using input devices such as a keyboard 40 and pointing device 42. Other input devices (not shown) may include be a microphone, joystick, gamepad, satellite dish, scanner, or any other.

These and other input devices are connected to the processor 21 often through a serial port interface 46 that is connected to the system bus, but can be connected via other interfaces, such as a parallel port, game port, or universal serial bus (USB). A monitor 47 or other type of visual display device is also connected to the system bus 23 via an interface, for example, a video adapter 48. In addition to the monitor 47, personal computers typically include other peripheral output devices (not shown), such as speakers and printers.

Computer 20 may operate in a networked environment through logical connections to one or more remote computers 49. The remote computer (or computers) 49 may be another computer, server, router, network PC, peer to peer device, or other node on a single network, and typically also includes includes most or all of the elements described above with respect to computer 20, although only an information storage device 50 is shown. Logical connections include a local area network (LAN) 51 and a global computer network (GCS) ) 52. Such network environments are usually common in institutions, corporate computer networks, and the Internet.

The computer 20 used in the LAN network environment is connected to the local area network 51 via a network interface or adapter 53. The computer 20 used in the GC network environment typically uses a modem 54 or other means to establish communication with the global computer network 52, such as the Internet.

The modem 54, which may be internal or external, is connected to the system bus 23 via the serial port interface 46. In a networked environment, program modules or parts thereof described with reference to computer 20 may be stored on a remote information storage device. It should be noted that the network connections shown are typical, and other means may be used to establish communication communication between computers.

In conclusion, it should be noted that the information provided in the description are examples that do not limit the scope of the present invention defined by the claims. One skilled in the art will recognize that there may be other embodiments of the present invention consistent with the spirit and scope of the present invention.

Claims (94)

1. A method for remotely monitoring compliance with safety regulations by employees, including:   registration by the presence sensor associated with the processor of the wearable device, the presence of the wearable device on the user, and the absence of the wearable device on the user is an emergency event registration by an impact sensor associated with the processor of the wearable device: effects on the wearable device by measuring the projection of acceleration, and the impact is a blow or a series of strokes on the wearable device, and the impact sensor registers the value of the force of at least one impact,  the presence of the fall phase of the wearable device when the wearable device is in a state of free fall in order to establish an emergency event corresponding to a fall from the height of the user of the wearable device,   recording a temperature sensor associated with the processor of the wearable device, the temperature around the wearable device,   registration by the humidity sensor associated with the processor of the wearable device, the humidity value around the wearable device,   transmission by the communication module associated with the processor of the wearable device to at least one base station of the values transmitted from the presence sensor, from the impact sensor, from the temperature sensor, from the humidity sensor, as well as the values of the battery charge level,   comparison by the processor with the software of the wearable device of the obtained values from the exposure sensor, temperature sensor and humidity sensor with the critical values recorded for the said sensors stored in the data storage of the wearable device,   determination by the processor with the software of the wearable device of reaching or exceeding critical values for the exposure sensor, for the temperature sensor and for the humidity sensor in order to establish at least one fact of an emergency event corresponding to:   strong impact on the wearable device,   critical temperature around the wearable device,   critical humidity around the wearable device,   determination by the processor with the software of the wearable device of a series of strokes against the wearable device, which is a request for help by the user of the wearable device and is a fact of an emergency event,   determination by the processor with the software of the wearable device of the presence of the phase of the fall of the wearable device, which is a fact of an emergency event,   determination by the processor with the software of the wearable device of the absence of the wearable device on the user, which is a fact of an emergency event,   the transmission by the communication module associated with the processor of the wearable device to at least one base station of the battery level of the wearable device, as well as at least one fact of an emergency event corresponding to:   the lack of a wearable device on the user,   the presence of a certain series of hits on a wearable device,   reaching or exceeding critical values for the temperature sensor and for the humidity sensor around the wearable device,   the presence of the fall phase of the wearable device,   the presence of a strong blow to the wearable device, moreover, together with the fact of an emergency event, the communication module transmits to the base station the values of the impact sensor, temperature sensor and humidity sensor at the time of the occurrence of the emergency event, as well as the time of occurrence of the emergency event,   determination by the base station of a signal level value received from the wearable device,   transmission by the base station to the server:   the value of the signal level received from the wearable device,   the values transmitted by the communication module of the wearable device to the base station from the presence sensor, from the impact sensor, from the temperature sensor, from the humidity sensor and the battery level of the wearable device,   transmitted by the communication module of the wearable device to the base station the fact of an emergency event, the values of the impact sensor, temperature sensor, humidity sensor and battery level of the wearable device at the time of the occurrence of an emergency event, as well as the time of occurrence of an emergency event,   notification of the operator monitoring the user of the wearable device by displaying data visualization module, which is part of the server application server, received by the server the signal level values received from the wearable device, values from the presence sensor, from the impact sensor, from the temperature sensor, from the humidity sensor and values of the battery level of the wearable device, the fact of an emergency event and the values of the impact sensor, temperature sensor, humidity sensor and the value of the charge level yes Battery portable device at the time of emergency events, as well as the time of occurrence of an emergency event. 2. The method according to claim 1, characterized in that the data is transmitted by the communication module of the wearable device to the base station using ultra-low power data channels, and / or LoRa, and / or LoRaWAN, and / or LPWAN, and / or 6LoWPAN , and / or Z wave. 3. The method according to p. 1, characterized in that the base station is a gateway for data transmission with ultra-low power consumption, and / or the Internet, and / or mobile or satellite communications, Bluetooth, and / or Wi Fi, and / or GSM, and / or 3G, and / or 4G, and / or LTE, and / or trunking, and / or ZigBee, and / or LoRa, and / or LoRaWAN, and / or LPWAN, and / or 6LoWPAN, and / or Z wave . 4. The method according to p. 1, characterized in that the data transfer between the wearable device, the base station and the server is carried out using a network server, which is a computing system that controls the process of receiving data from the base station from the wearable device and transmitting data from the base station to the wearable device as well as the process of transmitting data by the base station to the server and transmitting data by the server to the base station, said network server being part of the base station and / or server. 5. The method according to claim 1, characterized in that the presence sensor is an ultrasonic sensor and / or an infrared sensor. 6. The method according to p. 1, characterized in that the battery of the wearable device is charged by at least one of the following methods of charging the battery:   through the power connector located on the wearable device,   through at least one solar cell associated with a wearable device,   by contactless charging realized by an inductive loop. 7. The method according to p. 1, characterized in that the critical values for the impact sensor, for the temperature sensor and for the humidity sensor are transmitted by the server to the base station, and from the base station are transferred to the wearable device, and stored in the data storage of the wearable device. 8. The method according to p. 1, characterized in that the critical values for the impact sensor, for the temperature sensor and for the humidity sensor are recorded in the data warehouse of the wearable device. 9. The method according to p. 1, characterized in that the processor and software of the wearable device is used to determine when the temperature recorded by the temperature sensor reaches a value close to the critical temperature for a predetermined period of time in order to establish the fact of an emergency event and is transmitted by the communication module at least one base station and further to the server of such an emergency event and the time of occurrence of such an emergency event. 10. The method according to p. 1, characterized in that the data analytics module, which is part of the server’s application server, processes the values of the presence sensor, impact sensor, temperature sensor, humidity sensor received by the server and determines at least one fact of the emergency event . 11. The method according to p. 1, characterized in that the wearable device contains a radio frequency identification tag for identifying the wearable device. 12. The method according to p. 1, characterized in that the wearable device is installed on protective equipment or integrated into wearable protective equipment. 13. The method according to p. 12, characterized in that the protective equipment is a helmet, helmet, mask, construction helmet, worker helmet, protective helmet. 14. The method according to claim 1, characterized in that the communication between the wearable device, the base station and the server is carried out via wireless communication, including the Internet, and / or mobile or satellite communications, Bluetooth, and / or Wi Fi, and / or GSM, 3G, 4G, LTE, trunked communications, and / or via ultra-low power consumption data channels forming complex wireless networks with a mesh topology, and / or ZigBee, and / or LoRa, and / or LoRaWAN, and / or LPWAN , and / or 6 LoWPAN, and / or Z wave. 15. The method according to p. 1, characterized in that the location of the user is determined by a second device comprising a user location tracking module, and the coordinates of the user's location are transmitted to at least one base station by the communication module of the second device and / or to the server, moreover, the data visualization module, which is part of the server’s application server, displays to the operator controlling the user of the wearable device the user’s location Vatel. 16. The method according to p. 15, characterized in that the server transmits control commands to the second device, the control commands turning on indicators and / or sound reproducing devices and / or vibration devices that are part of such a second device to notify the user about emergency event. 17. The method according to p. 15, characterized in that the server transmits notifications in the form of at least one text or graphic message to the second device to notify the user about an emergency event. 18. The method according to PP. 16 and 17, characterized in that the server transmits notifications and / or control commands to at least the base station with their further transmission to the second device. 19. The method according to p. 15, characterized in that the second device is a bracelet, pendant, watch, mobile phone, laptop computer, computer, information board. 20. The method according to p. 15, characterized in that the operator’s location of the user is displayed on the site map displayed by the data visualization module and / or the construction site map and / or city map and / or district map and / or location map. 21. The method according to p. 1, characterized in that the exposure sensor is an accelerometer. 22. A device for remote monitoring of compliance with safety regulations by employees, containing:   a presence sensor associated with the processor of the wearable device, configured to detect the presence of the wearable device on the user, and the absence of the wearable device on the user is an emergency event,   an impact sensor associated with the processor of the wearable device, configured to register:   effects on the wearable device by measuring the projection of acceleration, and the impact is a blow or a series of strokes on the wearable device, and the impact sensor registers the value of the force of at least one impact,   the presence of the fall phase of the wearable device when the wearable device is in a state of free fall in order to establish an emergency event corresponding to a fall from the height of the user of the wearable device,   a temperature sensor associated with the processor of the wearable device, configured to record the temperature around the wearable device,   a humidity sensor associated with the processor of the wearable device, configured to record the humidity value around the wearable device,   data storage associated with the processor of the wearable device, configured to store critical values for recorded temperature and humidity by a temperature sensor and a humidity sensor,   a processor of a wearable device with software installed on it, configured to:   comparing the values from the impact sensor, temperature sensor and humidity sensor with the corresponding critical values recorded by said sensors stored in the data warehouse of the wearable device,   determining if critical values have been reached or exceeded for the exposure sensor, for the temperature sensor and for the humidity sensor in order to establish at least one fact of an emergency event corresponding to:   strong impact on the wearable device,   critical temperature around the wearable device,   critical humidity around the wearable device,   determining a series of strikes on a wearable device, which is a request for help by a user of a wearable device and is a fact of an emergency event,   determine the presence of the phase of the fall of the wearable device, which is a fact of an emergency event,   determining the absence of a wearable device on a user that is a fact of an emergency event,   a battery of the wearable device associated with the processor, configured to power the wearable device,   a communication module associated with the processor of the wearable device, configured to:   transmitting to the base station the values transmitted from the presence sensor, from the impact sensor, from the temperature sensor, from the humidity sensor, as well as the values of the battery level,   transmitting the battery level of the wearable device to the base stations, as well as the facts of emergency events corresponding to:   the lack of a wearable device on the user of the wearable device,   the presence of a certain series of hits on a wearable device,   reaching or exceeding critical values for the temperature sensor and for the humidity sensor around the wearable device,   the presence of the fall phase of the wearable device,   the presence of a strong blow to the wearable device, moreover, together with the fact of an emergency event, the communication module transmits to the base station the values of the impact sensor, temperature sensor and humidity sensor at the time of the occurrence of the emergency event, as well as the time of the occurrence of the emergency event, where the base station determines the level of the signal received from the wearable device, and the base station transmits to the server:   the value of the signal level received from the wearable device,   the values transmitted by the communication module of the wearable device to the base station from the presence sensor, from the impact sensor, from the temperature sensor, from the humidity sensor and the battery level of the wearable device,   the fact of the emergency event and the values of the impact sensor, temperature sensor, humidity sensor and the battery level of the wearable device at the time of the emergency event, as well as the time the emergency event occurred, transmitted by the communication module of the wearable device to the base station, moreover, on the server, the data visualization module, which is part of the application server, notifies the operator who controls the user of the wearable device by displaying the server received signal strength values received from the wearable device, values from the presence sensor, from the impact sensor, from the temperature sensor, s humidity sensor and values of the battery level of the wearable device, facts of emergency events and values of the impact sensor, temperature sensor, sensor wet the level and value of the battery level of the wearable device at the time of the occurrence of an emergency event, as well as the time of occurrence of the emergency event. 23. The device according to p. 22, characterized in that the presence sensor is an ultrasonic sensor and / or infrared sensor. 24. The device according to p. 22, characterized in that the battery of the wearable device is charged by at least one of the following methods for charging the battery:   through the power connector located on the wearable device,   through at least one solar cell associated with a wearable device,   by contactless charging realized by an inductive loop. 25. The device according to p. 22, characterized in that the processor of the wearable device is configured to determine, by using software installed on the wearable device, to achieve the temperature recorded by the temperature sensor, a value close to the critical temperature, for a predetermined period of time with the aim of establishing the fact of an emergency event, moreover, the processor using the software through the communication module transfers at least one Azov station and then to the server of the fact of emergency events and the time of occurrence of the emergency event. 26. The device according to p. 22, characterized in that the wearable device contains a radio frequency identification tag for identifying the wearable device. 27. The device according to p. 22, characterized in that the wearable device is installed on protective equipment or integrated into wearable protective equipment. 28. The device according to p. 27, characterized in that the protective equipment is a helmet, helmet, mask, construction helmet, worker's helmet, protective helmet. 29. The device according to p. 22, characterized in that the communication module of the wearable device is configured to transmit data to the base station using data channels with ultra-low power consumption, and / or LoRa, and / or LoRaWAN, and / or LPWAN, and / or 6 LoWPAN, and / or Z wave. 30. The device according to p. 22, characterized in that the exposure sensor is an accelerometer.

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