RU197118U1 - HELMET RADIO MODULE - Google Patents

Abstract

The utility model relates to the field of industrial safety, namely, devices for monitoring the time and zone of the user (employee) and warning the user about the danger and / or entry into the zone of increased danger. The radio module (2) for the helmet (1) contains built-in sensors, accelerometer, gyroscope, compass and barometer, as well as light and sound detectors, a vibration motor, an alarm button, while all elements of the radio module (2) are connected to the controller and to the battery, and the radio module made in the form of a housing with the possibility of mounting on a protective helmet (1). Also, the radio module is configured to determine its location and with the possibility of collecting data from wearable devices / sensors and built-in sensors, as well as transmitting / receiving signals to (a) the beacon (a) and transmitting the received data to a remote server, the module is also capable of monitoring wearing personal protective equipment (PPE) and when removed from the attached PPE, the module is configured to supply a pre-selected light and / or sound and / or vibration warning signal and send a corresponding signal but to the server. The technical result is to increase the safety of the user (employee) when carrying out work or entering one or another area of increased danger. 5 cp f-ly, 1 ill.

Description

The utility model relates to the field of industrial safety, namely, devices for monitoring the time and zone of the user (employee) and warning the user about the danger and / or entry into the zone of increased danger.

Various technical solutions are known in the field of industrial safety.

Known helmet with electronic protection (RF patent No. 2438539, publ. 10.01.2012), which contains a housing having a rigid outer shell, a rigid inner shell attached to the outer shell with the formation of a cavity between them, and shock-absorbing structure located between the inner shell and the user’s head when wearing a helmet, and an integrated electronic system that contains a microphone and a loudspeaker and located in the specified cavity of the subsystem: digital images; audio information; global positioning; mobile communications; a headlamp focused on providing light emission in space in front of the user; power supply battery.

Also known from the prior art is a protective helmet with an automatic operation control device, which is taken as a prototype (patent for PM No. 183600 U1), a protective helmet with an automatic operation control device combines the helmet and the user's head into a single constructive and information space for the purpose of operating control helmets in accordance with established norms and rules during working hours. Monitoring is carried out by using two groups of electronic sensors and an automatic operation control device. The first group of sensors is optoelectronic sensors. As the second group of sensors, an accelerometer is used, which provides identification of the motor activity of a person during the operation of the helmet. In addition, the automatic control device includes a controller board, a processor installed on the controller board, and a set of devices that provide: assessment, memorization and storage of information about when the state of the system “human head - protective helmet” changes; formation of an alarm in case of violation of the rules of operation of a protective helmet; the transfer of information stored during the operation of the helmet on the wireless channel to external devices in order to provide the administrative authorities. The automatic control of the operation of the protective helmet implemented by the device motivates the user to comply with safety regulations.

The disadvantages of the prototype are the lack of determining the presence of the user in a particular area of work, the limited number of objective data obtained about the user (employee), on which it is possible to draw any conclusions and send alerts, the lack of an alarm button, the lack of control of wearing personal protective equipment, etc. .d.

The objective of the proposed solution is to create a radio module that provides increased security for the user (employee) while eliminating the above disadvantages of the prototype.

The technical result is to increase the safety of the user (employee) when carrying out work or entering one or another area of increased danger.

This result is achieved due to the fact that the radio module for the helmet contains built-in sensors, accelerometer, gyroscope, compass and barometer, as well as light and sound detectors, a vibration motor, an alarm button, while all elements of the radio module are connected to the controller and to the battery, and the radio module is made in the form of a housing with the possibility of mounting on a protective helmet. Also, the radio module is configured to determine its location and with the possibility of collecting data from wearable devices / sensors and built-in sensors, as well as transmitting / receiving signals to (a) the beacon (a) and transmitting the received data to a remote server, the module is also configured to receive warning signals and monitoring the wearing of personal protective equipment (PPE), and when removed from the attached PPE, the module is configured to supply a pre-selected light and / or sound and / or vibration warning signal and sending the appropriate signal to the server.

The radio module determines its location using the GNSS signal receiver installed in the radio module housing, which is connected to the controller and to the battery. The radio module transmits / receives signals from beacons (BLE-bicons) using the BLE radio interface available in the radio module, while wearing PPE is also performed using the BLE radio interface when the PPE is previously associated with the radio module, data can also be transmitted to the server and received notifications through the application connected to the radio module using the BLE radio interface of the mobile device. The radio module transmits / receives signals from beacons (UWB anchors) using the UWB radio interface available in the radio module. In addition, the radio module transmits data to a remote server, as well as information about the battery charge level, the fact of presence / absence of movement from the accelerometer, spatial orientation and data from connected sensors via the BLE radio interface using the LoRaWAN radio interface available in the radio module. The light detector of the radio module is made of an LED located on the module housing in such a way that when located on the module helmet, the LED is in the peripheral area of view of the user.

The radio module is an autonomous RF device of small size and weight, equipped either with a helmet mount element integrated in the housing or an adapter with a helmet mount. The housing of the radio module may have a translucent button with an indicator. The design of the case and adapter allows you to use the radio module simultaneously with other accessories for protective helmets, for example, passive and active headsets, protective screens and visors, as well as connect additional personal protective equipment, namely shoes, gloves, smart bracelets with a heart rate monitor, safety belt, body biometry, MRO mobile terminal (maintenance and repair), portable gas analyzer, etc. On the personal protective equipment (PPE), the BLE micro-beacon is fixed and the module detects the “removal from PPE” situation when it is removed from the attached PPE, a signal is sent to the module, and an appropriate notification is sent to the system server. The list of PPE required for wearing can be formed for the task / zone. These signals ensure the safety of personnel and remind them of the use of personal protective equipment in a particular area / task, and remote monitoring of the employee is also provided.

Brief description of the drawing.

figure 1 is a General view of the helmet (1) with a side mounted radio module (2), as well as anti-noise headphones (3) and with a protective screen (4).

The radio module operates as follows.

The operation of the radio module (2) in the UWB mode is determined by the internal software, as well as by the beacon teams (anchors - UWB). Being outside the working area of any anchor, the radio module carries out an active search for communication - sends broadcast requests to the air and reports on the time of its readiness to receive commands. Each such request carries information about the status of the label, in particular about the battery charge level. Once in the working area of the anchor, the radio module periodically receives a command from the reader to take measurements. After receiving such a command, the radio module exchanges short messages with the reader. During the exchange, the reader determines the propagation time of the radio signal from the tag to the reader and in the opposite direction, and based on these measurements calculates the distance from the tag to the reader (Time of Flight - ToF method).

Being in the working area of several anchors, the radio module receives commands from each anchor and conducts distance measurement sessions with each of them. To determine the 2D position, the radio module must be in the working area of at least 3 anchors, for 3D - at least 4. Through the use of localization, this technology improves user safety.

If there are no anchors in the visibility zone and the signal satellites are visible (one of the global GPS, Glonass or BeiDou positioning systems), the radio module switches to GNSS positioning mode and transfers data via LoRaWAN to the server. Information about the position is periodically transmitted to the server via the LoRaWAN network. Also, information on the charge level of the battery (battery), the presence / absence of movement, spatial orientation and data from the connected sensors via Bluetooth, if available, is transmitted via the LoRaWAN network.

Through the BLE radio interface, the radio module can periodically listen to the broadcast and receive a signal from nearby BLE beacons. The radio module periodically transmits information about the identifiers of the beacons and the power of their signal to the server via the LoRaWAN network. The server solves the positioning problem and, thus, localizes the radio module. In case of triggering events of entering the danger zone, fixing atypical behavior according to the data of the built-in accelerometer (shock, fall, prolonged immobility) or by pressing the alarm button, information is transmitted to the server without waiting for its turn. Thanks to what the safety of the user is provided.

The radio module has the following technical characteristics and functionality:

UWB radio interface: data transmission up to 200 meters. Data rate up to 14 times per second. Positioning with an accuracy of 30 cm. Due to the increased accuracy of determining the location of the module, it is possible to activate the collision and collision avoidance function, for example, if you exit the carriageway or road at the factory or production site (work area) or when receiving location signals from similar devices installed on vehicles and comparing received signals from vehicles and from a module mounted on a helmet, and if these devices are less than 3 this minimum distance, to issue a warning signal to the unit by a preselected light and / or sound and / or vibration alarm signal.

LoRaWAN-radio interface: data transmission over a distance of 15 km; unlicensed frequency range of 868 MHz. The frequency of data transmission up to 1 time in 10 seconds, as well as the transfer of received data to the server.

BLE-5.0-radio interface: positioning with an accuracy of 5 m when reading data from beacons (Beacons); control of wearing personal protective equipment (PPE); the ability to collect data from other wearable devices / sensors and it is also possible to transmit data to the server and receive alerts through an application connected to the radio module using the BLE radio interface of a mobile device (for example, a smartphone or a TOiR mobile terminal) or transfer data to the server and receive LoRaWAN alerts radio interface.

Satellite navigation receiver: positioning on the street with an accuracy of 3.5 m.

There is also an indication on the device about the loss of communication with the system, while a light indication on the radio module is possible, that it is not working or the power source is at a minimum charge, and the radio module sends this signal to the server. The presence of a “panic button” provides the ability to call emergency assistance in the event of an accident or emergency.

According to data from the built-in accelerometer, gyroscope, compass and barometer: the position of the radio module in space is refined, immobility, drops, and shocks are monitored. At the same time, the radio module is able to work offline if there is no possibility of data transfer, with the ability to save the main and key events in the internal memory of the device, with their subsequent transmission when restoring the communication channel.

The radio module contains a rechargeable battery and an induction coil, which allows you to completely abandon the connectors for recharging the module and use wireless charging device, which ensures the absence of external connectors. The cases of the radio module are performed according to IP67, and the battery lasts up to 3 weeks on a single charge when working on UWB, the operating temperature is -40 + 85 ° С.

Thus, the use of this radio module allows you to prevent accidents and to warn users (workers) in advance of danger and in general allows you to increase the safety of users (workers) when carrying out work or entering one or another area of increased danger.

Claims (6)

1. A radio module for a helmet, characterized in that it contains built-in sensors, an accelerometer, a gyroscope, a compass and a barometer, as well as light and sound detectors, a vibration motor, an alarm button, while all the elements of the radio module are connected to the controller and to the battery, and the radio module is made in the form of the housing with the possibility of mounting on a protective helmet, also the radio module is configured to determine its location and with the ability to collect data from wearable devices / sensors and built-in sensors, as well as transmit / receive and signals to (c) beacon (a) and transmitting the received data to a remote server, the module is also configured to receive warning signals and to monitor the wearing of personal protective equipment (PPE), and when removed from the attached PPE, the module is configured to supply a pre-selected light , and / or an audio and / or vibration alert signal and send the corresponding signal to the server. 2. The radio module according to claim 1, characterized in that the location is determined using a satellite signal receiver installed in the radio module housing, which is connected to the controller and to the battery. 3. The radio module according to claim 1 or 2, characterized in that the transmission / reception of signals from beacons (BLE-bicons) is performed using the BLE radio interface available in the radio module, while wearing PPE is also carried out using the BLE radio interface at the preliminary binding PPE to the radio module, it is also possible to transmit data to the server and receive alerts through an application connected to the radio module using the BLE radio interface of the mobile device. 4. The radio module according to any one of the preceding paragraphs, characterized in that the transmission / reception of signals from beacons is performed using the UWB radio interface available in the radio module. 5. The radio module according to any one of the preceding paragraphs, characterized in that the data is transmitted to the remote server, as well as information about the battery charge level, the fact of presence / absence of movement from the accelerometer, spatial orientation and data from the connected sensors via the BLE radio interface are transmitted via LoRaWAN radio interface available in the radio module. 6. The radio module according to any one of the preceding paragraphs, characterized in that the light detector is made of an LED located on the module body in such a way that when the LED is located on the helmet of the module, it is in the user's peripheral vision.

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