CN112337029A - Fire-fighting monitoring system for large inverted-T dock gate - Google Patents
Fire-fighting monitoring system for large inverted-T dock gate Download PDFInfo
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- A—HUMAN NECESSITIES
- A62—LIFE-SAVING; FIRE-FIGHTING
- A62C—FIRE-FIGHTING
- A62C37/00—Control of fire-fighting equipment
- A62C37/50—Testing or indicating devices for determining the state of readiness of the equipment
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Abstract
The invention relates to the technical field of fire control monitoring, in particular to a fire control monitoring system for a large inverted T-shaped dock gate, which comprises an operation state parameter acquisition unit, a fire monitoring unit, a state analysis unit, an operation parameter backtracking unit, a remote monitoring unit and an emergency fire control unit, wherein the operation state parameter acquisition unit is used for acquiring a fire state parameter of a large inverted T-shaped dock gate; monitoring the running state of each device in an electric control chamber and a device chamber on the dock gate and power grid parameter data through a running state parameter acquisition unit, and detecting the environmental state of the electric control chamber and the device chamber on the dock gate through a fire monitoring unit; comparing and analyzing the detection data with the standard operation parameters of the equipment, and judging whether a fire hazard happens or not; marking abnormal parameter data, tracking data sources and determining abnormal parameter positions; each monitoring data and analysis result are displayed through the remote monitoring equipment, and according to the abnormal parameter position, the automatic control fire fighting equipment carries out emergency fire fighting operation, eliminates fire hazard and prevents fire spread.
Description
Technical Field
The invention relates to the technical field of fire control monitoring, in particular to a fire control monitoring system for a large inverted T-shaped dock gate.
Background
An inverted T-shaped floating dock gate belongs to a floating box type dock gate. Different from a square box-shaped floating dock gate commonly adopted in China, the structure form is as follows: the middle section is of an inverted T shape, the two ends are of square box shapes, the dock gate is symmetrical about the longitudinal center line of the dock gate, and the dock gate can be alternately used on two sides. As a low gravity center floating box door, under the rated load acting on a door body structure, the inverted T-shaped dock gate can stably stand on the threshold, so that most of the pressure of the dock gate on the dock entrance is concentrated at the position of the dock threshold, the stress on the side face dock wall is much smaller than that of the opposite box type floating dock gate, and the civil engineering cost can be reduced. The inverted T-shaped dock gate has small light-load water discharge and light structure, and has obvious advantages particularly for large dock gates; when the dock gate is in a working state, one side of the dock gate is used for stopping water, and the other side of the dock gate is in a water-free side, so that the dock gate has the advantages of being capable of being maintained and repaired and the like.
The design research and development of the ultra-large inverted T-shaped dock gate can solve the main problems that the conventional square box type floating dock gate is high in manufacturing cost, the ballast water cannot be drained in a closed state to prevent ice damage caused by ice freezing of the ballast water in an ice period and the like, and breakthrough of the floating dock gate in variety, use region (extremely cold region) and technology is realized. And two ends of the upper part of the dock gate are provided with a passage for people to enter and exit the dock gate. Two sides of the rectangular part of the dock gate are provided with ballast water tanks, and the middle part of the lower layer of the dock gate is provided with a water injection pipe valve for injecting water into the dock. The middle part of the dock gate is provided with a fixed ballast tank, a diesel generator room, a control room, a rest room and the like are arranged at two ends of the dock gate, and in order to ensure the safety of cabins such as an electric control room, an equipment room and the like, a complete fire fighting device and a fire fighting monitoring system need to be arranged on the dock gate.
Disclosure of Invention
The invention aims to provide a fire-fighting monitoring system for a large inverted-T dock gate, which aims to solve the problems in the background technology.
In order to achieve the purpose, the invention provides the following technical scheme: a fire-fighting monitoring system for a large inverted-T dock gate comprises an operation state parameter acquisition unit, a fire monitoring unit, a state analysis unit, an operation parameter backtracking unit, a remote monitoring unit and an emergency fire-fighting control unit; wherein:
the operation state parameter acquisition unit is used for monitoring the operation state of each device in the electric control chamber and the device chamber on the dock gate and the parameter data of the power grid, acquiring data and marking the distribution position of each device;
the fire monitoring unit is used for detecting the environmental states in an electric control chamber and an equipment chamber on the dock gate, comprises a temperature sensor, a humidity sensor and a water level sensor, and is provided with a smoke detector and an infrared camera for real-time monitoring;
the state analysis unit is used for receiving the detection data of the operation state parameter acquisition unit and the fire monitoring unit, comparing and analyzing the detection data with the standard operation parameters of the equipment and judging whether fire danger occurs or not;
the operation parameter backtracking unit marks the abnormal parameter data after the state analysis unit analyzes the abnormal data result, tracks the data source, performs corresponding analysis with the equipment coordinate marking module, and determines the position of the abnormal parameter;
the remote monitoring unit displays each monitoring data and analysis result through remote monitoring equipment, wherein the monitoring data and the analysis results comprise a parameter list and a video monitoring picture;
the emergency fire control unit monitors the fire equipment in the electric control room and the equipment room, ensures that the fire equipment is in an effective working state, automatically controls the fire equipment to carry out emergency fire control operation according to abnormal parameter positions, eliminates fire hazard and prevents fire spread.
Preferably, the operation state parameter acquisition unit and the fire monitoring unit are connected to a state analysis unit, and the state analysis unit is connected to a remote monitoring unit and an emergency fire control unit; the operation parameter backtracking unit is connected to the state analysis unit and the operation state parameter acquisition unit.
Preferably, the operation state parameter acquiring unit comprises an equipment parameter acquiring module, a power grid parameter acquiring module and an equipment coordinate marking module; wherein:
the equipment parameter acquisition module is used for acquiring various operating equipment parameters in the equipment room, wherein the operating equipment parameters comprise current data, voltage data and temperature data;
the power grid parameter acquisition module is used for acquiring power grid operation parameters in the electric control room and also comprises current data, voltage data and temperature data;
and the equipment coordinate marking module is used for marking the positions of the electric control assembly in the electric control chamber and the electric equipment in the equipment chamber.
Preferably, the fire monitoring unit comprises an environment detection module, a smoke detection module and a video monitoring module; wherein:
the environment detection module is used for detecting the temperature, the humidity and the water level parameters in the environment through a temperature sensor, a humidity sensor and a water level sensor which are arranged at each part of the electric control chamber and the equipment chamber;
the smoke detection module is uniformly provided with smoke detectors at all positions of the electric control chamber and the equipment chamber and used for detecting whether combustible smoke exists or not;
and the video monitoring module is uniformly provided with infrared cameras at each part of the electric control room and the equipment room, and is used for monitoring the interiors of the electric control room and the equipment room in real time.
Preferably, the state analysis unit comprises a standard parameter storage module, a data receiving module and a data analysis module; wherein:
the standard parameter storage module is used for setting standard preset values for the power grid operation states and equipment operation parameters in the electric control room and the equipment room and storing and recording the standard parameters;
the data receiving module is used for receiving the detection data of the operation state parameter acquisition unit and the fire monitoring unit and integrating the data;
and the data analysis module is used for analyzing and comparing the integrated detection data with the standard parameters and judging whether fire hidden danger occurs or fire dangerous cases occur.
Preferably, the operation parameter backtracking unit comprises an abnormal parameter marking module, a coordinate backtracking module and a state display module; wherein:
the abnormal parameter marking module is used for marking the abnormal data searched out in the data analysis module;
the coordinate backtracking module is used for searching a source of the abnormal data, comparing the source of the abnormal data with the equipment coordinate marking module, searching a coordinate position of a point where the abnormal data is located and providing a target object for the emergency fire control unit;
and the state display module is used for sending the abnormal data and the equipment position information where the abnormal data is located to the remote monitoring unit for displaying.
Preferably, the remote monitoring unit comprises a display device in a monitoring room and a mobile intelligent terminal carried by a worker, the detection result is checked through the display device and the mobile intelligent terminal, and the emergency fire control unit can be manually controlled to take emergency measures.
Preferably, the emergency fire control unit comprises a fire control device monitoring module, an emergency setting module and an emergency starting module; wherein:
the fire fighting device monitoring module is characterized in that a dock gate is provided with a fire fighting emergency pipeline and a fire extinguisher box, and the pipeline state of the fire fighting emergency pipeline is monitored to ensure that the fire fighting emergency pipeline is in a normal operation state;
the emergency setting module is used for reasonably preparing the distribution state of the fire fighting device according to the equipment distribution conditions in the electric control room and the equipment room;
emergent start module, control assembly and fire extinguisher case on the emergent pipeline of pertinence start fire control carry out emergent fire control.
Compared with the prior art, the invention has the beneficial effects that: the method comprises the steps that an operation state parameter acquisition unit is used for monitoring operation states of all devices in an electric control chamber and a device chamber on a dock gate and power grid parameter data, and a fire monitoring unit is used for detecting environmental states of the electric control chamber and the device chamber on the dock gate; comparing and analyzing the detection data with the standard operation parameters of the equipment, and judging whether a fire hazard happens or not; marking abnormal parameter data, tracking data sources and determining abnormal parameter positions; each monitoring data and analysis result are displayed through the remote monitoring equipment, and according to the abnormal parameter position, the automatic control fire fighting equipment carries out emergency fire fighting operation, eliminates fire hazard and prevents fire spread.
Drawings
FIG. 1 is a schematic diagram of the system of the present invention.
In the figure: 1. an operation state parameter acquisition unit; 11. an equipment parameter acquisition module; 12. a power grid parameter acquisition module; 13. a device coordinate marking module; 2. a fire monitoring unit; 21. an environment detection module; 22. a smoke detection module; 23. a video monitoring module; 3. a state analyzing unit; 31. a standard parameter storage module; 32. a data receiving module; 33. a data analysis module; 4. a parameter backtracking unit is operated; 41. an abnormal parameter marking module; 42. a coordinate backtracking module; 43. a status display module; 5. a remote monitoring unit; 6. an emergency fire control unit; 61. a fire fighting device monitoring module; 62. an emergency setting module; 63. and an emergency starting module.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. 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.
In the description of the present invention, it should be noted that the terms "vertical", "upper", "lower", "horizontal", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.
In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.
Referring to fig. 1, the present invention provides a technical solution: a fire-fighting monitoring system for a large inverted-T dock gate comprises an operation state parameter acquisition unit 1, a fire monitoring unit 2, a state analysis unit 3, an operation parameter backtracking unit 4, a remote monitoring unit 5 and an emergency fire-fighting control unit 6; wherein:
the operation state parameter acquisition unit 1 is used for monitoring the operation state of each device and power grid parameter data in an electric control chamber and a device chamber on the dock gate, acquiring data and marking the distribution position of each device;
the fire monitoring unit 2 is used for detecting the environmental states in an electric control chamber and an equipment chamber on the dock gate, comprises a temperature sensor, a humidity sensor and a water level sensor, and is provided with a smoke detector and an infrared camera for real-time monitoring;
the state analysis unit 3 is used for receiving the detection data of the operation state parameter acquisition unit 1 and the fire monitoring unit 2, comparing and analyzing the detection data with the standard operation parameters of the equipment and judging whether a fire danger occurs or not;
the operation parameter backtracking unit 4 marks the abnormal parameter data after the state analysis unit 3 analyzes the abnormal data result, tracks the data source, and correspondingly analyzes the abnormal parameter data with the equipment coordinate marking module 13 to determine the position of the abnormal parameter;
the remote monitoring unit 5 is used for displaying monitoring data and analysis results through remote monitoring equipment, and the monitoring data and the analysis results comprise a parameter list and a video monitoring picture;
the emergency fire control unit 6 monitors the fire equipment in the electric control room and the equipment room, ensures that the fire equipment is in an effective working state, automatically controls the fire equipment to carry out emergency fire control operation according to abnormal parameter positions, eliminates fire hazard and prevents fire spread.
Further, the operation state parameter acquiring unit 1 and the fire monitoring unit 2 are connected to a state analyzing unit 3, and the state analyzing unit 3 is connected to a remote monitoring unit 5 and an emergency fire control unit 6; the operation parameter backtracking unit 4 is connected to the state analysis unit 3 and the operation state parameter obtaining unit 1.
Further, the operation state parameter obtaining unit 1 includes an equipment parameter obtaining module 11, a power grid parameter obtaining module 12, and an equipment coordinate marking module 13; wherein:
the equipment parameter acquisition module 11 is used for acquiring various operating equipment parameters in the equipment room, wherein the operating equipment parameters comprise current data, voltage data and temperature data;
the power grid parameter acquisition module 12 is used for acquiring power grid operation parameters in the electric control room, and also comprises current data, voltage data and temperature data;
and the equipment coordinate marking module 13 is used for marking the positions of the electric control assembly in the electric control chamber and the electric equipment in the equipment chamber.
Further, the fire monitoring unit 2 comprises an environment detection module 21, a smoke detection module 22 and a video monitoring module 23; wherein:
the environment detection module 21 is used for detecting the temperature, the humidity and the water level parameters in the environment through a temperature sensor, a humidity sensor and a water level sensor which are arranged at each position of the electric control chamber and the equipment chamber;
the smoke detection module 22 is uniformly provided with smoke detectors at all positions of the electric control chamber and the equipment chamber and used for detecting whether combustible smoke exists or not;
the video monitoring module 23 is provided with infrared cameras at all positions of the electric control room and the equipment room, and monitors the inside of the electric control room and the equipment room in real time.
Further, the state analysis unit 3 includes a standard parameter storage module 31, a data receiving module 32 and a data analysis module 33; wherein:
the standard parameter storage module 31 is used for setting standard preset values for the power grid operation states and the equipment operation parameters in the electric control room and the equipment room, and storing and recording the standard parameters;
a data receiving module 32 for receiving the detection data of the operation state parameter acquiring unit 1 and the fire monitoring unit 2 and integrating the data;
and the data analysis module 33 analyzes and compares the integrated detection data with the standard parameters to judge whether fire hazard occurs or fire dangerous situations occur.
Further, the operation parameter backtracking unit 4 includes an abnormal parameter marking module 41, a coordinate backtracking module 42 and a status display module 43; wherein:
an abnormal parameter marking module 41 for marking the abnormal data found in the data analysis module 33;
the coordinate backtracking module 42 is used for searching a source of the abnormal data, comparing the source of the abnormal data with the equipment coordinate marking module 13, searching a coordinate position of a point where the abnormal data is located and providing a target object for the emergency fire control unit 6;
the status display module 43 sends the abnormal data and the device location information where the abnormal data is located to the remote monitoring unit 5 for display.
Furthermore, the remote monitoring unit 5 comprises a display device in the monitoring room and a mobile intelligent terminal carried by a worker, the detection result is checked through the display device and the mobile intelligent terminal, and the emergency fire control unit 6 can be manually controlled to take emergency measures.
Further, the emergency fire-fighting control unit 6 includes a fire-fighting device monitoring module 61, an emergency setting module 62 and an emergency starting module 63; wherein:
the fire fighting device monitoring module 61 is provided with a fire fighting emergency pipeline and a fire extinguisher box on the dock gate, and monitors the pipeline state of the fire fighting emergency pipeline to ensure that the fire fighting emergency pipeline is in a normal operation state;
the emergency setting module 62 is used for reasonably configuring the distribution state of the fire fighting device according to the equipment distribution conditions in the electric control room and the equipment room;
The working principle is as follows: monitoring the running state and power grid parameter data of each device in an electric control chamber and a device chamber on the dock gate through a running state parameter acquisition unit 1, acquiring data, and marking the distribution position of each device; the environment states of an electric control chamber and an equipment chamber on the dock gate are detected through a fire monitoring unit 2, the environment states comprise a temperature sensor, a humidity sensor and a water level sensor, and a smoke detector and an infrared camera are arranged for real-time monitoring;
the state analysis unit 3 receives the detection data of the operation state parameter acquisition unit 1 and the fire monitoring unit 2, compares and analyzes the detection data with the standard operation parameters of the equipment, and judges whether a fire hazard occurs; after analyzing the abnormal data result, the state analysis unit 3 marks the abnormal parameter data, tracks the data source, performs corresponding analysis with the equipment coordinate marking module 13, and determines the position of the abnormal parameter; displaying each monitoring data and analysis result through remote monitoring equipment, wherein the monitoring data and the analysis result comprise a parameter list and a video monitoring picture; the fire fighting equipment arranged in the electric control room and the equipment room is monitored, the fire fighting equipment is ensured to be in an effective working state, and according to the abnormal parameter position, the automatic control fire fighting equipment carries out emergency fire fighting operation, eliminates fire hazard and prevents fire spread.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.
Claims (8)
1. The utility model provides a fire control monitored control system for large-scale type of falling T dock gate which characterized in that: the fire disaster monitoring system comprises an operation state parameter acquisition unit (1), a fire disaster monitoring unit (2), a state analysis unit (3), an operation parameter backtracking unit (4), a remote monitoring unit (5) and an emergency fire control unit (6); wherein:
the operation state parameter acquisition unit (1) is used for monitoring the operation state of each device and power grid parameter data in an electric control chamber and a device chamber on the dock gate, acquiring data and marking the distribution position of each device;
the fire monitoring unit (2) is used for detecting the environmental states in an electric control chamber and an equipment chamber on the dock gate, comprises a temperature sensor, a humidity sensor and a water level sensor, and is provided with a smoke detector and an infrared camera for real-time monitoring;
the state analysis unit (3) is used for receiving the detection data of the operation state parameter acquisition unit (1) and the fire monitoring unit (2), comparing and analyzing the detection data with the standard operation parameters of the equipment and judging whether a fire danger happens or not;
the operation parameter backtracking unit (4) is used for marking the abnormal parameter data after the state analysis unit (3) analyzes the abnormal data result, tracking the data source, and correspondingly analyzing the abnormal parameter data with the equipment coordinate marking module (13) to determine the position of the abnormal parameter;
the remote monitoring unit (5) displays each monitoring data and analysis result through remote monitoring equipment, wherein the monitoring data and the analysis results comprise a parameter list and a video monitoring picture;
the emergency fire control unit (6) monitors fire equipment arranged in an electric control room and an equipment room, ensures that the fire equipment is in an effective working state, automatically controls the fire equipment to carry out emergency fire control operation according to abnormal parameter positions, eliminates fire hazard and prevents fire spread.
2. A fire monitoring system for large inverted-T dock gates as claimed in claim 1, wherein: the operation state parameter acquisition unit (1) and the fire monitoring unit (2) are connected to the state analysis unit (3), and the state analysis unit (3) is connected to the remote monitoring unit (5) and the emergency fire control unit (6); the operation parameter backtracking unit (4) is connected to the state analysis unit (3) and the operation state parameter acquisition unit (1).
3. A fire monitoring system for large inverted-T dock gates as claimed in claim 1, wherein: the operation state parameter acquisition unit (1) comprises an equipment parameter acquisition module (11), a power grid parameter acquisition module (12) and an equipment coordinate marking module (13); wherein:
the equipment parameter acquisition module (11) is used for acquiring various operating equipment parameters in the equipment room, wherein the operating equipment parameters comprise current data, voltage data and temperature data;
the power grid parameter acquisition module (12) is used for acquiring power grid operation parameters in the electric control room, and also comprises current data, voltage data and temperature data;
and the equipment coordinate marking module (13) is used for marking the positions of the electric control assembly in the electric control chamber and the electric equipment in the equipment chamber.
4. A fire monitoring system for large inverted-T dock gates as claimed in claim 1, wherein: the fire monitoring unit (2) comprises an environment detection module (21), a smoke detection module (22) and a video monitoring module (23); wherein:
the environment detection module (21) is used for detecting the temperature, the humidity and the water level parameters in the environment through temperature sensors, humidity sensors and water level sensors which are arranged at all positions of the electric control chamber and the equipment chamber;
the smoke detection module (22) is uniformly provided with smoke detectors at each part of the electric control chamber and the equipment chamber and is used for detecting whether combustible smoke exists or not;
and the video monitoring module (23) is uniformly provided with infrared cameras at each part of the electric control room and the equipment room, and is used for monitoring the interiors of the electric control room and the equipment room in real time.
5. A fire monitoring system for large inverted-T dock gates as claimed in claim 1, wherein: the state analysis unit (3) comprises a standard parameter storage module (31), a data receiving module (32) and a data analysis module (33); wherein:
the standard parameter storage module (31) is used for setting standard preset values for the power grid operation states and the equipment operation parameters in the electric control room and the equipment room and storing and recording the standard parameters;
the data receiving module (32) is used for receiving the detection data of the operation state parameter acquisition unit (1) and the fire monitoring unit (2) and integrating the data;
and the data analysis module (33) analyzes and compares the integrated detection data with the standard parameters to judge whether fire hazard occurs or fire dangerous situations occur.
6. A fire monitoring system for large inverted-T dock gates as claimed in claim 1, wherein: the operation parameter backtracking unit (4) comprises an abnormal parameter marking module (41), a coordinate backtracking module (42) and a state display module (43); wherein:
an abnormal parameter marking module (41) for marking the abnormal data found in the data analysis module (33);
the coordinate backtracking module (42) is used for searching a source of the abnormal data, comparing the source of the abnormal data with the equipment coordinate marking module (13), searching a coordinate position of a point where the abnormal data is located and providing a target object for the emergency fire control unit (6);
and the state display module (43) is used for sending the abnormal data and the equipment position information where the abnormal data is located to the remote monitoring unit (5) for displaying.
7. A fire monitoring system for large inverted-T dock gates as claimed in claim 1, wherein: the remote monitoring unit (5) comprises a display device in a monitoring room and a mobile intelligent terminal carried by a worker, the detection result is checked through the display device and the mobile intelligent terminal, and the emergency fire control unit (6) can be manually controlled to take emergency measures.
8. A fire monitoring system for large inverted-T dock gates as claimed in claim 1, wherein: the emergency fire control unit (6) comprises a fire control device monitoring module (61), an emergency setting module (62) and an emergency starting module (63); wherein:
the fire fighting device monitoring module (61) is provided with a fire fighting emergency pipeline and a fire extinguisher box on the dock gate, and monitors the pipeline state of the fire fighting emergency pipeline to ensure that the fire fighting emergency pipeline is in a normal operation state;
the emergency setting module (62) is used for reasonably preparing the distribution state of the fire fighting device according to the equipment distribution conditions in the electric control room and the equipment room;
emergent start module (63), control assembly and fire extinguisher case on the emergent pipeline of pertinence start-up fire control carry out emergent fire control.
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Application publication date: 20210209 |