CN216927797U - Emergency disaster prevention management system - Google Patents

Abstract

The utility model discloses an emergency disaster prevention management system, which comprises: the monitoring module is arranged in a pre-trained target mine and used for monitoring the mine shaft environmental parameters of the target mine; the processing module is connected with the monitoring module and used for determining whether a fire hazard accident exists in the target mine or not according to the shaft environment parameters; responding to the fire hazard accident existing in the target mine, and determining a mine fire emergency plan corresponding to the mine environmental parameters according to the mine environmental parameters; and the display module is connected with the processing module and used for displaying an emergency escape scheme corresponding to the mine emergency plan according to the mine fire emergency plan and guiding escape when a fire disaster actually occurs in the target mine. Therefore, real-time monitoring and dynamic simulation of mine fires can be realized, and a favorable reference is provided for timely making danger avoiding planning under a catastrophe condition.

Description

Emergency disaster prevention management system

Technical Field

The utility model belongs to the technical field of intelligent simulation, and particularly relates to an emergency disaster prevention management system.

Background

The fire disaster is one of the main disasters which most often and generally threaten the life safety of people, and basic fire fighting passageways are provided for residences, office buildings and the like to help people escape in the fire disaster. However, for building lands such as mines with difficult conditions, people cannot escape in time when disasters such as fire disasters come. Therefore, how to ensure the safety of miners in the mine becomes a technical problem which needs to be solved urgently.

SUMMERY OF THE UTILITY MODEL

In order to achieve the purpose, the technical scheme of the utility model is realized as follows:

the embodiment of the utility model provides an emergency disaster prevention management system, which comprises:

the monitoring module is arranged in a pre-trained target mine and used for monitoring the mine shaft environmental parameters of the target mine;

the processing module is connected with the monitoring module and used for determining whether a fire hazard accident exists in the target environment or not according to the shaft environment parameters; responding to the fire hazard accident existing in the target mine, and determining a mine fire emergency plan corresponding to the mine environmental parameters according to the mine environmental parameters;

and the display module is connected with the processing module and used for displaying the mine emergency escape scheme according to the mine fire emergency plan and guiding escape in the target mine when a fire disaster actually occurs.

In the above solution, the system further includes:

and the fire extinguishing module is connected with the processing module and used for controlling the fire extinguishing module to perform automatic fire extinguishing treatment according to the mine fire emergency plan.

In the scheme, the emergency escape scheme comprises the following steps: the escape time of an emergency escape route and a specific place on the emergency escape route;

the display module is specifically used for displaying an emergency escape route corresponding to the mine fire emergency plan and the escape time of a specific place on the emergency escape route according to the mine fire emergency plan.

In the above scheme, the display module is specifically configured to display an emergency escape scheme corresponding to the mine emergency plan in a GIS imaging manner according to the mine fire emergency plan.

In the above scheme, the monitoring module includes: a temperature sensor; the wellbore environmental parameters include: a temperature value within the wellbore;

the processing module is specifically used for responding to the fact that the temperature value in the shaft is larger than a temperature threshold value according to the temperature value in the shaft, and determining that a fire hazard accident exists in the target shaft; alternatively, in response to the temperature value within the wellbore being less than or equal to the temperature threshold value, determining that a fire hazard event is not present within the target wellbore.

In the above-mentioned scheme, the control module includes: a temperature sensor; the wellbore environmental parameters include: a temperature value within the wellbore;

the processing module is specifically used for responding to the fact that the temperature value in the shaft is larger than a temperature threshold value according to the temperature value in the shaft, and determining that a fire hazard accident exists in the target shaft; alternatively, in response to the temperature value within the wellbore being less than or equal to the temperature threshold value, determining that a fire hazard event is not present within the target wellbore.

In the foregoing solution, the processing module is further configured to: in response to the temperature value in the wellbore being greater than a temperature threshold value, determining a first wellbore location corresponding to the temperature value in the wellbore being greater than the temperature threshold value; and determining the mine fire emergency plan according to the position of the first shaft.

In the above-mentioned scheme, the control module includes: a camera module; the wellbore environmental parameters include: image information within the wellbore;

the processing module is specifically used for responding to the image information indicating that a flame image exists according to the image information in the shaft and determining that a fire hazard accident exists in the target shaft; alternatively, in response to the image information indicating that no image of flames exists, determining that no fire hazard event exists within the target mine.

In the foregoing solution, the processing module is further configured to: in response to the image information indicating the presence of a flame image, determining a second wellbore location at which the image information indicates the presence of a flame image; and determining the mine fire emergency plan according to the position of the second shaft.

In the above solution, the system further includes:

the timing module is connected with the monitoring module and used for generating a timing starting instruction according to a time period;

and the monitoring module is also used for starting and monitoring the shaft environmental parameters of the target mine according to the timing starting instruction.

In the above scheme, the display module comprises a display panel of at least one of the following: a display, a tablet, a cell phone, or a kiosk.

The embodiment of the utility model provides an emergency disaster prevention management system, which comprises: the monitoring module is arranged in a pre-trained target mine and used for monitoring the mine shaft environmental parameters in the target mine; the processing module is connected with the monitoring module and used for determining whether a fire hazard accident exists in the target mine or not according to the shaft environment parameters; responding to the fire hazard accident existing in the target mine, and determining a mine fire emergency plan corresponding to the mine environmental parameters according to the mine environmental parameters; and the display module is connected with the processing module and used for displaying an emergency escape scheme corresponding to the mine emergency plan according to the mine fire emergency plan and guiding escape when a fire disaster actually occurs in the target mine. Therefore, real-time monitoring and dynamic simulation of mine fires are realized, and a favorable reference is provided for timely making danger avoiding planning under a catastrophe condition.

Drawings

Fig. 1 is a schematic structural diagram of an emergency disaster avoidance management system according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an emergency disaster avoidance management system according to an embodiment of the present invention;

fig. 3 is another schematic structural diagram of an emergency disaster avoidance management system according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of an emergency disaster prevention management system according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings, which illustrate some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Fig. 1 is a schematic structural diagram of an emergency disaster avoidance management system according to an embodiment of the present invention, and as shown in fig. 1, the emergency disaster avoidance management system 1 includes:

the monitoring module 11 is installed in a pre-drilling target mine and used for monitoring the mine shaft environmental parameters of the target mine;

the processing module 12 is connected with the monitoring module 11 and used for determining whether a fire hazard accident exists in the target mine according to the shaft environment parameters; responding to the fire hazard accident existing in the target mine, and determining a mine fire emergency plan corresponding to the mine environmental parameters according to the mine environmental parameters;

and the display module 13 is connected with the processing module 12 and is used for displaying an emergency escape scheme corresponding to the mine emergency plan according to the mine fire emergency plan so as to guide escape in the target mine when a fire disaster actually occurs.

It should be noted that a mine is a generic term for a roadway, a chamber, equipment, a ground building, and a structure forming an underground coal mine production system. Inclined shafts, vertical shafts, adits and the like in underground mining of mines are also sometimes referred to as mines. The determination of the field range size, the mine production capacity and the service life of each mine is one of the key problems which must be solved in the mine self-design. Certainly, in order to ensure the safety in the mine, fire defense measures for the mine are indispensable, and how to ensure the safety in the mine is the technical problem to be solved by the application.

The shaft environment parameters can be used for reflecting the environment in the shaft of the mine. The monitoring module 11 is installed in a pre-drilling target mine, and includes but is not limited to a temperature sensor, a humidity sensor, and/or a camera module.

The processing module 12 is respectively connected with the monitoring module 11 and the display module 13, and is used for determining whether a fire hazard accident exists in the target mine according to the shaft environment parameters of the target mine monitored by the monitoring module 11; determining a mine fire emergency plan corresponding to the shaft environment parameters according to the shaft environment parameters if a fire hazard accident exists; and an emergency escape scheme corresponding to the mine emergency plan is displayed through the display module 13 according to the mine fire emergency plan, so as to guide escape when a fire disaster actually occurs in the target mine.

It is understood that the processing module 12 can be integrated on the same terminal device as the display module 13, for example, the processing module 12 and the display module 13 are integrated on the same computer. Of course, in other embodiments, the processing module 12 may be integrated on a cloud terminal, and the display module 13 may be a user terminal. Here, the processing module 12 and the display module 13 are not integrated on the same terminal device. In this embodiment, the system further comprises: the communication module, this communication module is connected respectively in processing module 12 and display module assembly 13, can be used for sending the emergent case of mine conflagration for this display module assembly 13 in advance.

Here, the shaft environmental parameters have a corresponding relationship with the mine fire emergency plan. It should be noted that the severity of the environment in the mine indicated by the shaft environment parameters is different, and the corresponding mine fire emergency plans are different. Or the mine disaster occurrence points indicated by the shaft environment parameters are different, and the corresponding mine fire emergency plans are also different. Of course, the emergency escape schemes corresponding to different fire emergency plans are also different, and it can be understood that the emergency escape schemes include, but are not limited to, emergency escape routes and the like.

According to the emergency disaster-avoiding management system of the embodiment of the disclosure, by means of the display module 13, the processing module 12 determines whether a fire hazard accident exists in a target mine or not according to the shaft environment parameters monitored by the monitoring module 11; responding to the existence of fire hazard accidents in the target mine, determining a mine fire emergency plan corresponding to the mine environmental parameters according to the mine environmental parameters, and displaying an emergency escape scheme corresponding to the mine fire emergency plan, thereby guiding escape when a fire hazard actually occurs in the target mine. Therefore, miners can be assisted to timely and accurately escape from a fire scene through the emergency disaster-avoiding management system, and the safety of the miners is guaranteed. Therefore, the embodiment can realize real-time monitoring and dynamic simulation of mine fires and provide favorable reference for timely making risk avoiding planning under a catastrophe condition.

In other embodiments, fig. 2 is a schematic structural diagram of an emergency disaster avoidance management system in an embodiment of the present invention, and as shown in fig. 2, the system further includes:

and the fire extinguishing module 14 is connected with the processing module 12 and used for controlling the fire extinguishing control module to automatically extinguish fire according to the mine fire emergency plan.

It should be noted that the fire extinguishing module 14 herein includes: a fire extinguisher or fire extinguishing equipment capable of being automatically turned on based on a control command, and the like.

So, can realize intelligent fire extinguishing based on module 14 of putting out a fire, reduce the danger that personnel got into the mine.

In other embodiments, the emergency escape scenario comprises: the escape time of an emergency escape route and a specific place on the emergency escape route;

the display module 13 is specifically configured to display an emergency escape route corresponding to the mine fire emergency plan, and a specific location and an escape time on the emergency escape route according to the mine fire emergency plan.

It is understood that the specific location and the escape time on the emergency escape route refer to, for example, the escape time required to be reached at point a of the emergency escape route, and if the specific location is not reached at the escape time, a danger may exist. Therefore, the fire rescue personnel can be helped to judge the escape possibility in advance, and rescue assistance to a greater extent is realized; meanwhile, the escape system can help the escape personnel in the mine to pre-judge the escape route and the escape time and escape by grasping.

In other embodiments, in order to achieve better visual experience and obtain an emergency escape scheme more clearly, accurately and quickly, the display module 13 is specifically configured to display the emergency escape scheme corresponding to the mine emergency escape scheme in a GIS graphical manner according to the mine fire emergency scheme.

The GIS, Geographic Information System, a Geographic Information System, is a specific very important spatial Information System, and is a technical System for collecting, storing, managing, operating, analyzing, displaying and describing relevant Geographic distribution data in the whole or partial earth surface including the atmospheric space under the support of a computer hardware and software System.

So, in this embodiment, through the emergent scheme of fleing that shows and the emergent plan correspondence of mine with the graphical form of GIS to be convenient for look over of display module assembly 13 one end, be favorable to visual experience.

In other embodiments, the monitoring module 11 includes: a temperature sensor; the wellbore environmental parameters include: a temperature value within the wellbore;

the processing module 12 is specifically configured to respond that the temperature value in the wellbore is greater than a temperature threshold value according to the temperature value in the wellbore, and determine that a fire hazard accident exists in the target wellbore; alternatively, in response to the temperature value within the wellbore being less than or equal to the temperature threshold value, determining that a fire hazard event is not present within the target wellbore.

The temperature threshold value here may be a temperature value in the case where the temperature is increased, which may be considered to be caused by a fire.

Therefore, the temperature sensor is arranged in the mine, so that the pre-judgment of fire hazard accidents can be realized, and a judgment basis is provided for the emergency disaster avoidance management system.

In other embodiments, the processing module is further configured to: in response to the temperature in the wellbore being greater than a temperature threshold, determining a first wellbore location corresponding to the temperature value in the wellbore being greater than the temperature threshold; and determining the mine fire emergency plan according to the position of the first shaft.

It is understood that the temperature sensors herein may comprise a plurality of different temperature sensors installed at different wellbore locations and identified differently. The determining that the temperature value in the wellbore is greater than a first wellbore location corresponding to a temperature threshold value in response to the temperature value in the wellbore being greater than the temperature threshold value comprises: in response to a temperature value within the wellbore being greater than a temperature threshold value, determining an identification of a temperature sensor corresponding to the temperature value being greater than the temperature threshold value; and determining the position of the first shaft according to the identifier of the temperature sensor corresponding to the temperature value greater than the temperature threshold value.

So, in this embodiment, be greater than the position at the temperature sensor place that the temperature value corresponds through finding the temperature value to find the fire point position, and then confirm the emergent scheme of mine conflagration through the fire point position, thereby can obtain more accurate scheme of fleing according to the fire point position, realize the safety guarantee better.

In other embodiments, the monitoring module 11 includes: a camera module; the wellbore environmental parameters include: image information within the wellbore;

the processing module 12 is specifically configured to respond to the image information indicating that a flame image exists according to the image information in the wellbore, and determine that a fire hazard accident exists in the target wellbore; or, in response to the image information indicating that a fire image exists, determining that a fire hazard accident does not exist within the target mine.

It should be noted that, by using an image processing method and an algorithm model of image processing, whether flame images exist in the image information in the shaft is analyzed, so that under the condition that the image information indicates that flame images exist, it is determined that fire hazard accidents exist in the target shaft.

Of course, the present embodiment can also be combined with the temperature sensor described in the above embodiments to determine whether there is a fire risk accident, so that the accuracy of determining the fire risk accident can be ensured, and misdirection can be reduced.

In other embodiments, the processing module 12 is further configured to: in response to the image information indicating the presence of a flame image, determining a second wellbore location at which the image information indicates the presence of a flame image; and determining the mine fire emergency plan according to the position of the second shaft.

So, in this embodiment, indicate to have the second pit shaft position of flame image through finding image information to find the position of fire point, and then confirm the emergent scheme of mine conflagration through the position of fire point, thereby can obtain more accurate scheme of fleing according to the position of fire point, realize the safety guarantee better.

Referring to fig. 3, fig. 3 is another schematic structural diagram of an emergency disaster avoidance management system according to an embodiment of the present invention, and as shown in fig. 3, the emergency disaster avoidance management system further includes:

the timing module 15 is connected with the monitoring module 11 and used for generating a timing starting instruction according to a time period;

and the monitoring module 11 is further configured to start monitoring of the shaft environment parameters of the target mine according to the timing start instruction.

Therefore, the shaft environment parameters of the target mine can be monitored according to the time period, and dangerous accidents such as fire disasters can be found in time.

In other embodiments, the display module 13 includes at least one of the following display panels: a display, a tablet, a mobile phone or a all-in-one machine, etc.

Fig. 3 is a schematic structural diagram of an emergency disaster prevention management system in an embodiment of practical information of the present invention, and as shown in fig. 3, the emergency disaster prevention management system includes:

a monitoring device 31 for installing in the mine 30 and obtaining monitoring data in the monitoring mine 30, the monitoring device 31 including but not limited to a camera or a temperature sensor, etc.

And the processing equipment 32 is used for realizing automatic alarm or automatic fire extinguishing control devices by utilizing the power transformation according to the monitoring data, and the processing equipment 32 is connected with the monitoring equipment 31.

An automatic fire extinguishing control device 33 for controlling fire extinguishing, the automatic fire extinguishing control device 33 being connected to the monitoring apparatus 31; and/or a display device for displaying the escape scenario, the display device 34 being connected to the monitoring device 31.

The monitoring device 31 corresponds to the monitoring module 11 of the above-mentioned embodiment, the processing device 32 corresponds to the processing module 12 of the above-mentioned embodiment, the automatic fire-extinguishing control device 33 corresponds to the fire-extinguishing module 14 of the above-mentioned embodiment, and the display device 34 corresponds to the display module 13 of the above-mentioned embodiment.

The emergency disaster-avoiding management system is a system developed based on GIS technology and used for intelligent simulation demonstration of a fire disaster ratio route, can provide an intelligent simulation demonstration function of the fire disaster, provide a monitored object relation, can be conveniently accessed to data of other systems for analysis, gives an alarm on a display device, and achieves real-time monitoring and dynamic simulation of mine fire disasters and intelligent planning of disaster-avoiding routes under disaster conditions.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention.

Claims (10)

1. An emergency disaster prevention management system is characterized by comprising:

the monitoring module is arranged in a pre-trained target mine and used for monitoring the mine shaft environmental parameters of the target mine;

the processing module is connected with the monitoring module and used for determining whether a fire hazard accident exists in the target mine or not according to the shaft environment parameters; responding to the fire hazard accident existing in the target mine, and determining a mine fire emergency plan corresponding to the mine environmental parameters according to the mine environmental parameters;

and the display module is connected with the processing module and used for displaying an emergency escape scheme corresponding to the mine fire emergency plan according to the mine fire emergency plan and guiding escape when a fire disaster actually occurs in the target mine.

2. The system of claim 1, further comprising:

and the fire extinguishing module is connected with the processing module and used for controlling the fire extinguishing module to perform automatic fire extinguishing treatment according to the mine fire emergency plan.

3. The system of claim 1, wherein the emergency escape protocol comprises: the escape time of an emergency escape route and a specific place on the emergency escape route;

the display module is specifically used for displaying an emergency escape route corresponding to the mine fire emergency plan and the escape time of a specific place on the emergency escape route according to the mine fire emergency plan.

4. The system according to claim 1 or 3, wherein the display module is specifically configured to display an emergency escape plan corresponding to the mine fire emergency plan in a GIS graphical manner according to the mine fire emergency plan.

5. The system of claim 1, wherein the monitoring module comprises: a temperature sensor; the wellbore environmental parameters include: a temperature value within the wellbore;

the processing module is specifically used for responding to the fact that the temperature value in the shaft is larger than a temperature threshold value according to the temperature value in the shaft, and determining that a fire hazard accident exists in the target shaft; alternatively, in response to the temperature value within the wellbore being less than or equal to the temperature threshold value, determining that a fire hazard event is not present within the target wellbore.

6. The system of claim 5, wherein the processing module is further configured to: in response to the temperature value in the wellbore being greater than the temperature threshold value, determining a first wellbore location corresponding to the temperature value in the wellbore being greater than the temperature threshold value; and determining the mine fire emergency plan according to the position of the first shaft.

7. The system of claim 1, wherein the monitoring module comprises: a camera module; the wellbore environmental parameters include: image information within the wellbore;

the processing module is specifically used for responding to the image information indicating that a flame image exists according to the image information in the shaft and determining that a fire hazard accident exists in the target shaft; alternatively, in response to the image information indicating that no images of flames exist, determining that no fire hazard event exists within the target mine.

8. The system of claim 7, wherein the processing module is further configured to: in response to the image information indicating the presence of a flame image, determining a second wellbore location at which the image information indicates the presence of a flame image; and determining the mine fire emergency plan according to the position of the second shaft.

9. The system of claim 1, further comprising:

the timing module is connected with the monitoring module and used for generating a timing starting instruction according to a time period;

and the monitoring module is also used for starting and monitoring the shaft environmental parameters of the target mine according to the timing starting instruction.

10. The system of claim 1, wherein the display module comprises a display panel comprising at least one of: a display, a tablet, a cell phone, or a kiosk.

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