CN108460963B - Remote fire-fighting monitoring platform - Google Patents

Abstract

The invention discloses a remote fire-fighting monitoring platform, which solves the problem that a user and a related unit cannot be notified in time when a fire disaster happens, and has the technical scheme that the remote fire-fighting monitoring platform comprises data acquisition equipment, data transmission equipment, a cloud data monitoring center, a networking unit user APP end, a higher-level department of charge APP end and a maintenance unit APP end, wherein the data acquisition equipment is used for monitoring fire alarms in real time in each area of a building and transmitting the monitored fire information to the cloud data monitoring center through the data transmission equipment, thus, measures are taken quickly to reduce the probability of damage to the life of the property.

Description

Remote fire-fighting monitoring platform

Technical Field

The invention relates to a fire fighting system, in particular to a remote fire fighting monitoring platform.

Background

The fire disaster has the characteristics of sudden and random property, and once the fire disaster happens or is not put out in time, the loss of lives and properties of people can be brought. With the rapid development of urban construction in recent years, high-rise and super high-rise buildings are continuously emerging, and with the wide use of various new technologies, new processes, new materials and new equipment, new conditions and new problems faced by building fire fighting work are increased.

In real life, when a building is in fire, users and fire-fighting units cannot be informed in time, and life and property safety of people is easily damaged.

Disclosure of Invention

The invention aims to provide a remote fire-fighting monitoring platform which can inform a user in time when a fire disaster occurs in a building.

The technical purpose of the invention is realized by the following technical scheme:

a remote fire-fighting monitoring platform comprises data acquisition equipment, data transmission equipment, a cloud data monitoring center, a networking unit user APP end, a superior department of charge APP end and a maintenance unit APP end;

the data acquisition equipment is used for carrying out real-time fire alarm monitoring on each area of the building and sending the monitored fire information to the cloud data monitoring center through the data transmission equipment;

the networking unit user APP terminal, the upper-level department of charge APP terminal and the maintenance unit APP terminal exchange data with the cloud data monitoring center in a wireless communication mode;

when data acquisition equipment monitors the conflagration breaing out in the building, cloud data monitoring center sends control command to networking unit user APP end, higher level department of charge APP end and maintenance unit APP and serves to make networking unit user APP end, higher level department of charge APP end and maintenance unit APP end warn.

Adopt above-mentioned scheme, can monitor the conflagration condition in the building through data acquisition equipment, when detecting the conflagration breaing out, cloud data monitoring center can send corresponding control command to networking unit user APP end, higher level person in charge department APP end and maintenance unit APP end in, makes the people in time receive the conflagration notice to take measures fast, receive the probability of damage with reduction property life.

Preferably, the data acquisition equipment is coupled with a plurality of camera devices distributed at fire alarm monitoring points, and when the data acquisition equipment monitors that a fire disaster occurs in the building, the data acquisition equipment controls the camera devices to be started so as to upload images acquired by the camera devices to the cloud data monitoring center.

By adopting the scheme, the image of the fire scene can be acquired in time through the camera device, so that people can know the situation of the fire scene more clearly and more humanized.

Preferably, the data transmission device comprises a first switch coupled to the data acquisition device, a second switch coupled to the cloud data monitoring center, a wireless transmitting device coupled to the first switch, and a wireless receiving device coupled to the second switch; and the wireless transmitting device and the wireless receiving device exchange data through wireless communication.

By adopting the scheme, the data acquisition equipment can realize wireless transmission with the cloud data monitoring center, so that the transmission distance is longer and the data acquisition equipment is more stable.

Preferably, the camera device comprises an electric holder fixed at the monitoring point and a camera fixed on the electric holder, and the cloud data monitoring center is coupled with a controller used for controlling the movement of the electric holder to change the shooting angle of the camera.

By adopting the scheme, the controller controls the electric pan-tilt to move, so that the shooting angle of the camera can be changed, and workers can check the fire condition of a scene at the optimal angle.

Preferably, the data acquisition equipment is used for judging the fire condition of the monitoring point and controlling the corresponding camera to start, and simultaneously, the controller is used for controlling the electric holder to operate so as to enable the lens of the camera to face the fire point.

By adopting the scheme, when a fire disaster occurs at the monitoring point, the data acquisition equipment can automatically start the camera, and control the electric holder to adjust the camera to the best shooting angle, and the camera is in a closed state at ordinary times, so that the purpose of saving electricity is achieved.

Preferably, the cloud data monitoring center is used for receiving information of the data acquisition equipment and calculating a path between the position and the APP end of the maintenance unit according to the position of the data acquisition equipment.

By adopting the scheme, when a fire disaster occurs, the cloud data monitoring center can calculate the route between the fire disaster position and the maintenance unit, so that the maintenance unit can dispatch fire fighters to the fire disaster position in time in the shortest time according to the route, and the loss caused by the fire disaster is greatly reduced.

Preferably, the cloud data monitoring center uploads images acquired by the camera device to a user APP end of a networking unit and an APP end of a superior department of administration and displays the images, and the APP end of the maintenance unit is controlled by the APP end of the superior department of administration to warn.

Adopt above-mentioned scheme, can look over and confirm the on-the-spot conflagration condition through higher level department of being responsible for APP end, avoid the on-the-spot someone to lead to data acquisition equipment misjudgement because modes such as point cigarette, and remind maintenance unit APP end, make the fire fighter catch up to the scene, extravagant manpower resources.

In conclusion, the invention has the following beneficial effects: can monitor the conflagration condition in the building through data acquisition equipment, when detecting the conflagration that takes place, cloud data monitoring center can send corresponding control command to networking unit user APP end, higher level person in charge department APP end and maintenance unit APP end in, make the people in time receive the conflagration notice to take measures fast, receive the probability of damage with reduction property life.

Drawings

FIG. 1 is a first system architecture diagram of the present embodiment;

fig. 2 is a second system architecture diagram of the present embodiment.

In the figure: 1. a data acquisition device; 2. a data transmission device; 3. a cloud data monitoring center; 4. networking unit user APP terminal; 5. an APP end of a superior department of charge; 6. an APP terminal of a maintenance unit; 7. a first switch; 8. a second switch; 9. a wireless transmitting device; 10. a wireless receiving device; 11. a camera; 12. a controller; 13. an electronic map; 14. a path generation module; 15. a route calculation module; 16. a road condition calculation module; 17. a comprehensive scoring module; 18. and selecting a module.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present invention.

The remote fire-fighting monitoring platform disclosed in the embodiment, as shown in fig. 1, includes data acquisition device 1, data transmission device 2, cloud data monitoring center 3, networking unit user APP end 4, superior department of charge APP end 5 and maintenance unit APP end 6.

The data acquisition equipment 1 is used for monitoring fire alarms in real time in each area of a building, transmitting monitored fire information to the cloud data monitoring center 3 through the data transmission equipment 2, is arranged at each fire monitoring point in the building, and can be one or any combination of a smoke detector, a flame detector, a special gas detector or a temperature sensor.

The data transmission device 2 comprises a first switch 7 coupled to the data acquisition device 1, a second switch 8 coupled to the cloud data monitoring center 3, a wireless transmitting device 9 coupled to the first switch 7, and a wireless receiving device 10 coupled to the second switch 8; the wireless transmitting apparatus 9 and the wireless receiving apparatus 10 exchange data by wireless communication.

The "wireless communication" includes one or more of communication modes of a wireless communication network such as GSM, CDMA2000, WCDMA, TDS-CDMA.

The cloud data monitoring center 3 is preferably a computer, which is connected with a data server and a display, and can check data information detected, acquired and transmitted by the data acquisition equipment 1 in real time through the display and analyze the data.

Networking unit user APP end 4, higher level department of charge APP end 5 and maintenance unit APP end 6 all carry out data exchange with cloud data monitoring center 3 through wireless communication mode. And the three are respectively arranged in the users of the networking units, the superior administrative department and the mobile phones or tablet computers of the maintenance units.

When a fire disaster occurs in a building, the temperature, the smoke concentration, the concentration of carbon monoxide, carbon dioxide and other special gases in the corresponding fire disaster monitoring points correspondingly rise, and at the moment, the data acquisition equipment 1 can monitor the occurrence of the fire disaster in the building. At this moment, the cloud data monitoring center 3 sends a control instruction to the networking unit user APP end 4, the upper management department APP end 5 and the maintenance unit APP end 6, so that the networking unit user APP end 4, the upper management department APP end 5 and the maintenance unit APP end 6 warn. Wherein, the warning mode can pop up corresponding warning bullet window for SMS, phone ring or in corresponding APP interface to indicate, send the sound suggestion simultaneously, make the people can know the disaster more clearly and take place. Meanwhile, the networking unit users, the superior department of charge and the maintenance unit personnel can use various functions through the cloud data monitoring center 3.

A plurality of camera devices distributed at fire alarm monitoring points are coupled to the data acquisition equipment 1, when the data acquisition equipment 1 monitors a fire in a building, the data acquisition equipment 1 controls the camera devices to be started so as to upload images acquired by the camera devices to the cloud data monitoring center 3, and therefore workers can check the fire situation on site through the display. When the worker confirms the disaster, the worker can inform the fire department of rescue in time or actively dial 119 alarm calls.

The camera device comprises an electric holder fixed at a monitoring point and a camera 11 fixed on the electric holder, and the electric holder can control the camera 11 to change different angles, so that the shooting angle is changed. The cloud data monitoring center 3 is coupled with a controller 12 for controlling the motion of the electric pan-tilt to change the shooting angle of the camera 11, the controller 12 can be a single chip microcomputer or a PLC, a control rocker is arranged outside the controller 12, and the camera 11 can perform corresponding angle conversion by changing the direction of the rocker. The camera 11 is preferably a fire-resistant high-definition camera 11 to suit the fire scene.

The data acquisition equipment 1 is used for judging the fire condition of the monitoring point and controlling the corresponding camera 11 to start, the camera 11 is provided with a temperature sensor, when the temperature sensor detects the temperature rise of the monitoring point, the camera 11 can be automatically started to acquire image information, and meanwhile, the controller 12 can control the electric pan-tilt to operate so that the lens of the camera 11 faces the ignition point.

The cloud data monitoring center 3 is used for receiving the information of the data acquisition equipment 1 and calculating a path between the position and the APP terminal 6 of the maintenance unit according to the position of the data acquisition equipment 1.

The cloud data monitoring center 3 uploads the image acquired by the camera 11 to the networking unit user APP terminal 4 and the superior department of charge APP terminal 5 for display, and the maintenance unit APP terminal 6 is controlled by the superior department of charge APP terminal 5 for warning.

When data acquisition equipment 1 detects the fire alarm condition of monitoring point unusual, camera 11 can in time acquire on-the-spot image information and upload image information to cloud data monitoring center 3 through data transmission equipment 2, and upload networking unit user APP end 4 and higher level department of charge APP end 5 by cloud data monitoring center 3 with image information, let the staff of department of charge carry out the affirmation of on-the-spot condition, if the on-the-spot intensity of a fire is comparatively serious, rethread higher level department of charge APP end 5 sends warning signal to maintenance unit APP end 6, so that maintenance unit APP end 6 sends out the warning, send out special fire fighter by the maintenance unit and arrive the scene and rescue.

If the fire condition is light, or the data acquisition equipment 1 judges by mistake, the APP end 5 of the upper administrative department does not send out warning, so that the labor force consumption of personnel is reduced.

As shown in fig. 2, the cloud data monitoring center 3 includes an electronic map 13, a route generating module 14, a route calculating module 15, a road condition calculating module 16, a comprehensive scoring module 17, and a selecting module 18.

The path generating module 14 is configured to generate directional diagrams of all paths between the data acquisition device 1 and the maintenance unit APP on the electronic map 13. The route calculation module 15 is configured to calculate routes of the routes, and sequentially define the routes of the routes as S1, S2, and S3 … … Sn.

The road condition calculating module 16 is configured to calculate a congestion condition of each route, and may check the density of vehicles on the route through a satellite, and determine the congestion condition of the route according to the density.

And the comprehensive scoring module 17 calculates a comprehensive score corresponding to each path according to the distance and the congestion condition of each path. The selection module 18 is configured to sort the paths according to the composite scores, and select a path with the highest composite score for display. The path with the highest comprehensive score is the best path from the maintenance unit to the fire occurrence point.

The road condition calculating module 16 has a reference value corresponding to a standard congestion condition, and when the road condition calculating module 16 detects that the value corresponding to the highest-scoring route is higher than the reference value, it indicates that the congestion condition occurs on the route suddenly. At this time, the selection module 18 displays the route with the highest comprehensive score in the remaining routes to pick out the best route again until the congestion value corresponding to the displayed route is lower than the reference value, so as to ensure that the rescuers can reach the fire occurrence point in the shortest time.

Claims (5)

1. The utility model provides a long-range fire control monitoring platform which characterized by: the system comprises data acquisition equipment (1), data transmission equipment (2), a cloud data monitoring center (3), a networking unit user APP terminal (4), a superior department of charge APP terminal (5) and a maintenance unit APP terminal (6);

the data acquisition equipment (1) is used for carrying out real-time fire alarm monitoring on each area of the building and sending the monitored fire information to the cloud data monitoring center (3) through the data transmission equipment (2);

the networking unit user APP terminal (4), the upper administrative department APP terminal (5) and the maintenance unit APP terminal (6) exchange data with the cloud data monitoring center (3) in a wireless communication mode;

when the data acquisition equipment (1) monitors that a fire disaster occurs in a building, the cloud data monitoring center (3) sends a control instruction to the networking unit user APP end (4), the upper main department APP end (5) and the maintenance unit APP end (6) so as to enable the networking unit user APP end (4), the upper main department APP end (5) and the maintenance unit APP end (6) to warn;

the data acquisition equipment (1) is coupled with a plurality of camera devices distributed at fire alarm monitoring points, and when the data acquisition equipment (1) monitors that a fire disaster occurs in a building, the data acquisition equipment (1) controls the camera devices to be started so as to upload images acquired by the camera devices to a cloud data monitoring center (3);

the data transmission equipment (2) comprises a first switch (7) coupled to the data acquisition equipment (1), a second switch (8) coupled to the cloud data monitoring center (3), a wireless sending device (9) coupled to the first switch (7) and a wireless receiving device (10) coupled to the second switch (8); the wireless transmitting device (9) and the wireless receiving device (10) exchange data through wireless communication.

2. The remote fire monitoring platform of claim 1, wherein: the camera device comprises an electric holder fixed at a monitoring point and a camera (11) fixed on the electric holder, and the cloud data monitoring center (3) is coupled with a controller (12) used for controlling the movement of the electric holder to change the shooting angle of the camera (11).

3. The remote fire monitoring platform of claim 2, wherein: the data acquisition equipment (1) is used for judging the fire condition of a monitoring point and controlling the corresponding camera (11) to start, and meanwhile, the controller (12) is used for controlling the electric holder to operate so that the lens of the camera (11) faces the fire point.

4. The remote fire monitoring platform of claim 1, wherein: the cloud data monitoring center (3) is used for receiving information of the data acquisition equipment (1) and calculating a path between the position and the APP end (6) of the maintenance unit according to the position of the data acquisition equipment (1).

5. The remote fire monitoring platform of claim 1, wherein: cloud data monitoring center (3) upload to networking unit user APP end (4) and higher level department of charge APP end (5) and show with the image that camera device acquireed, maintenance unit APP end (6) are controlled by higher level department of charge APP end (5) in order to warn.

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