CN219678693U - Rescue scene based dynamic on-line monitoring system for rescue personnel - Google Patents

Abstract

The utility model discloses a dynamic on-line monitoring system for rescue workers based on a rescue scene, wherein the on-line monitoring system comprises a protective helmet which sends collected position information outwards; the command terminal establishes rescue high-low risk areas, displays the risk areas of the rescue workers in real time, dynamically monitors the rescue workers in the low-risk areas, and timely carries out risk early warning prompt on the rescue workers in the high-risk areas; the protective helmet comprises a positioning module for acquiring position information in real time; the communication module is used for sending the position information or receiving command terminal instructions for establishing communication; a voice input/output module for voice communication with the command terminal; and a controller for controlling the modules to work cooperatively. When the rescue helmet is used, the command terminal obtains the position information of the protective helmet in real time, determines the risk of the area where each rescue worker is located, prompts the rescue workers in the high-risk area, improves the rescue efficiency of the rescue scene, and reduces the risk and accidents of rescue in the rescue process.

Description

Rescue scene based dynamic on-line monitoring system for rescue personnel

Technical Field

The utility model relates to the technical field of rescue equipment, in particular to a dynamic on-line monitoring system for rescue workers based on a rescue scene.

Background

When the existing fire disaster is rescuing, especially in a large fire scene, the rescue is basically carried out by professional firefighters. When a fire disaster occurs in a factory, the scene fire condition is usually required to be judged, and a rescue scheme is formulated. However, in actual rescue, internal fires are not well known and fire development changes often occur rapidly. When the rescue site is larger, the visual command cannot be carried out generally, the rescue efficiency is affected, meanwhile, rescue workers cannot rest due to the fact that the rescue workers do not support physical power, and huge potential safety hazards are brought to the rescue workers.

Disclosure of Invention

The utility model mainly solves the technical problem of providing a rescue scene-based dynamic on-line monitoring system for rescue workers, wherein the rescue scene-based dynamic on-line monitoring device for rescue workers can protect the rescue workers in a rescue scene, and avoid accidents of the rescue workers in the rescue process.

In order to solve the problems, the utility model provides a rescue scene-based dynamic on-line monitoring system for rescue workers, which comprises,

at least one protective helmet, which collects the position information and sends the position information outwards according to preset intervals or in real time;

the command terminal is communicated with at least one protective helmet, a rescue high-low risk area is established, position information of the protective helmet is obtained, positions of rescue workers are displayed in real time, and dynamic monitoring is carried out on the rescue workers in the low-risk area; timely performing risk early warning prompt on rescue workers in a high risk area;

the protective helmet comprises a positioning module, a communication module, a voice input/output module and a controller, wherein,

the positioning module acquires position information in real time;

the communication module is used for sending the position information acquired by the positioning module outwards according to a preset interval or in real time and receiving command terminal instructions for establishing communication;

the voice input/output module is communicated with the command terminal;

the controller, the protocol position adjusting module and the communication module work.

Further, the positioning module comprises a Beidou positioning module and/or a GPS positioning module.

Further, the protective helmet is provided with a battery which works for the controller, the voice input/output module, the communication module and the positioning module.

Further, the gesture acquisition module comprises a multi-axis acceleration sensor that can obtain whether the protective helmet is in a motion or a stationary state.

Further, the on-line monitoring system further comprises a light prompting module which is arranged in the protective helmet and is in signal connection with the communication module and the controller, wherein the light prompting module displays different colors at the position of a risk area where a rescuer is positioned, or flashes when the communication module receives a command terminal command.

Further, the on-line monitoring system further comprises a vibration module which is arranged on the protective helmet and is in signal connection with the communication module and the controller, and the vibration module vibrates in a risk area position where a rescuer is located or vibrates the protective helmet when the communication module receives a command terminal command.

Further, the on-line monitoring system further comprises a gesture acquisition module in signal connection with the controller, and the controller acquires the motion state of the protective helmet through data acquired by the gesture acquisition module.

The utility model relates to a dynamic on-line monitoring system for rescue workers based on rescue scenes, wherein the on-line monitoring system comprises a protective helmet which is used for sending collected position information outwards; the command terminal establishes rescue high-low risk areas, displays the risk areas of the rescue workers in real time, dynamically monitors the rescue workers in the low-risk areas, and timely carries out risk early warning prompt on the rescue workers in the high-risk areas; the protective helmet comprises a positioning module for acquiring position information in real time; the communication module is used for sending the position information or receiving command terminal instructions for establishing communication; a voice input/output module for voice communication with the command terminal; a gesture acquisition module for determining whether the protective helmet is in a motion state; and a controller for controlling the modules to work cooperatively. When the rescue system is used, the command terminal determines the risk of the region where each rescue worker using the protective helmet is located according to the protective helmet position information obtained in real time, prompts the rescue workers in the high-risk region, improves the rescue efficiency of the rescue scene, and reduces the risk and accidents of rescue in the rescue process.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the following brief description will be given of the drawings required for the description of the embodiments or the prior art, it being apparent that the drawings in the description only illustrate certain embodiments of the utility model and should not be construed as limiting the scope, and that other relevant drawings can be obtained from these drawings without inventive effort to a person skilled in the art.

FIG. 1 is an electrical schematic diagram of an embodiment of the rescue scene rescue personnel dynamic on-line monitoring system of the utility model.

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

Description of the embodiments

The claims hereof are to be read in further detail with reference to specific embodiments and to the accompanying drawings, in which the embodiments described are only some, but not all embodiments of the utility model. Based on the embodiments of the present utility model, one of ordinary skill in the art would be able to devise all other embodiments that are obtained without inventive effort and that are within the scope of the present utility model.

It should be understood that, in the embodiments of the present utility model, all directional terms, such as "upper", "lower", "left", "right", "front", "rear", etc., are used for convenience in describing the present utility model only and are not intended to be limiting, since the directional terms, such as "upper", "lower", "left", "right", "front", "rear", etc., are based on the orientation, positional relationship shown in the drawings or the orientation or positional relationship in which the inventive product is conventionally put in use. Merely to explain the relative positional relationship, movement, etc. between the components shown in the drawings, the directional indication may be changed when the specific posture is changed.

Furthermore, ordinal words such as "first," "second," and the like in the description of the present utility model are used for distinguishing purposes only and are not to be construed as indicating or implying a relative importance or an implicit indication of the number of technical features indicated. The features defining "first", "second" may be explicit or implicit and at least one of the features. In the description of the present utility model, the meaning of "plurality" means at least two, i.e., two or more, unless otherwise specifically defined; the meaning of "at least one" is one or more.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "configured," "connected," "secured," "screwed," and the like are to be construed broadly, and may, for example, be defined as having a relatively fixed positional relationship between components, as having a physically fixed connection between components, as being detachably connected, or as a unitary structure; the connection can be mechanical connection or electric signal connection; can be directly connected or indirectly connected through intermediate media or components; the communication between two elements or the interaction relationship between two elements is not limited by the specification, and the specific meaning of the terms in the present utility model will be understood by those skilled in the art according to the specific circumstances except that the corresponding function or effect cannot be achieved when other understanding is made.

The controller, control circuit, etc. to which the present utility model may relate are conventional control techniques or units for those skilled in the art, and the control circuit of the controller may be implemented by those skilled in the art using existing techniques, such as simple programming. The software or program for realizing the control result in cooperation with the hardware is used as the conventional technology of the prior art or the person skilled in the art if the description does not show the control process of the related software or program in detail. The power supply also adopts the prior art in the field, and the main technical point of the utility model is to improve the mechanical device, so the utility model does not describe specific circuit control relation and circuit connection in detail.

As shown in fig. 1, the utility model provides an embodiment of a rescue scene rescue personnel dynamic on-line monitoring system.

The dynamic on-line monitoring system for rescue personnel based on rescue scene comprises,

at least one protective helmet A, which collects the position information and sends the position information outwards according to the preset interval or in real time;

the command terminal B establishes communication with at least one protective helmet, establishes a rescue high-low risk area, acquires the position information of the protective helmet, displays the positions of the rescue workers in real time, and dynamically monitors the rescue workers in the low-risk area; timely performing risk early warning prompt on rescue workers in a high risk area; the protective helmet comprises a positioning module 3, a communication module 5, a voice input/output module 4 and a controller 1, wherein the positioning module acquires position information in real time; the communication module is used for sending the position information acquired by the positioning module outwards according to a preset interval or in real time and receiving command terminal instructions for establishing communication; the voice input/output module is communicated with the command terminal; the controller, the protocol position adjusting module and the communication module work.

Specifically, the protective helmet a includes a main body and an electrical part disposed on the main body, the electrical part is powered by a battery, wherein the electrical part includes a positioning module, a communication module, a voice input/output module and a controller, the positioning module 3 collects position information in real time, and the positioning module includes a Beidou positioning module and/or a GPS positioning module, and may also adopt other means to obtain a module with an accurate position; the communication module 5 sends the position information collected by the positioning module outwards according to a preset interval or in real time, receives command terminal instructions for establishing communication, and the communication module 5 usually adopts a wireless transmission module, such as a radio module with specific frequency; the voice input/output module 4 is in communication with the command terminal, namely when the command terminal needs to be reminded or prompted, the command terminal B sends voice to the voice input/output module to realize command, and rescue workers can report site conditions and the like through the voice input/output module 4 and the command terminal B; the controller coordinates the modules, namely the positioning module 3, the communication module 5 and the voice input/output module 4. The command terminal is provided with a display screen and an electronic map, and can read the position information of at least one protective helmet and send command instructions to any protective helmet.

When the rescue system is used, the command terminal determines the risk of the region where each rescue worker using the protective helmet is located according to the protective helmet position information obtained in real time, prompts the rescue workers in the high-risk region, improves the rescue efficiency of the rescue scene, and reduces the risk and accidents of rescue in the rescue process.

In order to more intuitively and conveniently enable on-site rescue workers to know the position, each protective helmet A is provided with a light indication unit connected with a controller in a signal mode, the light indication units automatically display different colors according to the risk positions of the rescue workers, if the light indication units are located in low-risk areas, the light indication units are green, the high-risk areas are red and the like, so that the light indication units are distinguished, and the rescue workers can intuitively know the position and the safety of the rescue workers.

According to the need, the on-line monitoring system further comprises a light prompt module which is arranged in the protective helmet and is in signal connection with the communication module and the controller, wherein the light prompt module automatically displays different colors at the position of a risk area where a rescuer is located, for example, when the rescuer is located in a low risk area, the light prompt module is displayed as green, and thus nearby rescuers know the approximate range of the surrounding risk area; if when the rescue personnel are in the high risk area, the light prompt module is displayed in red, so that the nearby rescue personnel know the risk area, and the rescue personnel can be better protected.

The working process of the light prompting module is as follows: the risk area where the rescue personnel is located is matched with the set risk area by the command terminal according to the obtained rescue personnel position information, and when the rescue personnel is located in the set risk area, the command terminal controls the light prompting module to output and display or prompt according to a preset mechanism by the control module according to the received instruction through the communication module on the protective helmet. The preset mechanism is that green light is output when the current protective helmet is positioned in a low-risk area, and red light is output when the current protective helmet is positioned in a high-risk area. When the protective helmet is positioned in the risk area according to the requirement, the light prompting module can flash when the communication module receives the command of the command terminal.

According to the needs, the on-line monitoring system further comprises a vibration module which is arranged on the protective helmet and is in signal connection with the communication module and the controller, and the vibration module automatically vibrates at the risk area position where the rescue person is or vibrates the protective helmet when the communication module receives a command terminal command.

Specifically, if the rescue workers are in the low risk area, the vibration module can vibrate at a lower frequency, so that the rescue workers can be reminded of the low risk area; when rescue personnel are in a high-risk area, the vibration module can vibrate at a higher frequency, so that the rescue personnel can be reminded of being in the risk area at present, the rescue personnel can directly feel the safety of the current position, and the rescue personnel can be protected better.

The working process of the vibration module is as follows: the risk area where the rescue personnel is located is matched with the set risk area by the command terminal according to the obtained rescue personnel position information, and when the rescue personnel is located in the set risk area, the command terminal controls the vibration module to perform vibration output prompt according to a preset mechanism by the control module according to the received instruction through the communication module on the protection helmet. The preset mechanism is low-frequency vibration output when the current protective helmet is positioned in a low-risk area, and high-frequency vibration output when the current protective helmet is positioned in a high-risk area.

According to the requirement, the on-line monitoring system further comprises a gesture acquisition module in signal connection with a controller, and the controller acquires the motion state of the protective helmet by the data acquired by the gesture acquisition module. The gesture acquisition module comprises a multi-axis acceleration sensor that can obtain whether the protective helmet is in a motion or a stationary state. When any one of the protective helmets is in a static state, conversation or control light or vibration prompt can be carried out between the protective helmets through the command terminal, when no response is carried out in the preset time, the rescue personnel in the static state can be rescued by sending an instruction to the rescue personnel closest to the protective helmets in the static state, when the rescue personnel in the static state are rescued to be separated from the risk area, when the rescue personnel cannot leave the risk area in the preset time, other nearby rescue personnel are notified until the rescue personnel and the rescue personnel to be rescued leave the risk area.

The above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may be modified or some technical features may be replaced with other technical solutions, which may not make the essence of the corresponding technical solutions deviate from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims (7)

1. A dynamic on-line monitoring system for rescue workers based on rescue scenes is characterized by comprising,

at least one protective helmet, which collects the position information and sends the position information outwards according to preset intervals or in real time;

the command terminal is communicated with at least one protective helmet, a rescue high-low risk area is established, position information of the protective helmet is obtained, positions of rescue workers are displayed in real time, and dynamic monitoring is carried out on the rescue workers in the low-risk area; timely performing risk early warning prompt on rescue workers in a high risk area;

the protective helmet comprises a positioning module, a communication module, a voice input/output module and a controller, wherein,

the positioning module acquires position information in real time;

the communication module is used for sending the position information acquired by the positioning module outwards according to a preset interval or in real time and receiving command terminal instructions for establishing communication;

the voice input/output module is communicated with the command terminal;

the controller, the protocol position adjusting module and the communication module work.

2. The rescue scene based rescue personnel dynamic on-line monitoring system of claim 1, wherein the positioning module comprises a Beidou positioning module and/or a GPS positioning module.

3. The rescue scene based personnel dynamic on-line monitoring system of claim 1 or 2, wherein the protective helmet is provided with a battery working for a controller, a voice input output module and a communication module and a positioning module.

4. The rescue scene rescue personnel dynamic on-line monitoring system according to claim 1, further comprising a light prompting module which is arranged in the protective helmet and is in signal connection with the communication module and the controller, wherein the light prompting module displays different colors at the position of a risk area where a rescue person is positioned or flashes when the communication module receives a command terminal command.

5. The rescue scene based on-line monitoring system of claim 1 or 4, further comprising a vibration module arranged on the protective helmet and in signal connection with the communication module and the controller, wherein the vibration module vibrates at a risk area position where the rescue person is or vibrates the protective helmet when the communication module receives a command terminal command.

6. The rescue scene based personnel dynamic on-line monitoring system of claim 1, further comprising a gesture acquisition module in signal connection with a controller, wherein the controller acquires the protective helmet motion state from data acquired by the gesture acquisition module.

7. The rescue scene based personnel dynamic on-line monitoring system of claim 6 wherein the gesture acquisition module comprises a multi-axis acceleration sensor that can obtain whether the protective helmet is in a moving or stationary state.