CN210786087U - Fire extinguishing system based on new energy automobile battery subregion management - Google Patents

Abstract

The utility model discloses a fire extinguishing system based on new energy automobile battery subregion management, including fire control medium storage device, battery charging storehouse and fire extinguishing controller, be equipped with rechargeable battery in the battery charging storehouse, fire control medium storage device is equipped with medium pipeline intercommunication with battery charging storehouse, is equipped with medium output control assembly on medium pipeline, the automatically controlled end of medium output control assembly links to each other with the output of fire extinguishing controller; be equipped with the smoke sensor in the battery charging storehouse, the signal output part of smoke sensor and the temperature signal output part of BMS that battery self has all link to each other with fire extinguishing controller's input. The utility model has the advantages of can carry out the fire control before the battery develops into the conflagration and handle, the fire control effect is better, better reduction economic loss.

Description

Fire extinguishing system based on new energy automobile battery subregion management

Technical Field

The utility model belongs to the technical field of electric automobile, very much relate to a fire extinguishing system based on new energy automobile battery subregion management.

Background

The electric automobile uses electric power as energy and is a green vehicle. Specifically, the electric vehicle is equipped with a battery, which provides a power source for the electric vehicle. Since the electric energy stored in the battery of the electric vehicle is constant, the distance that the electric vehicle can travel without being charged is limited. In order to make the electric vehicle travel longer, there are some charging stations installed on the road side to provide charging for the electric vehicle. The charging station is similar to a gas station of a common automobile, and when the battery of the electric automobile is consumed or is about to be consumed, the electric automobile can charge the battery in the charging station; when the battery is fully charged, the electric vehicle can continue to run. When the electric vehicle charges the battery in the charging station, the electric vehicle needs to stop for a long time for waiting, and the waiting time is two hours less and seven-eight hours more.

At present, a plurality of electric vehicles adopt a mode of replacing batteries to supplement energy for the electric vehicles, and the replaced batteries need to be charged in a centralized manner.

The replaced batteries are uniformly placed in the trays, the trays containing the batteries are transported to a battery stack by using a conveying mechanism, the trays are placed in battery charging bins by using a stacker for charging and management, one battery stack comprises a plurality of battery charging bins, and each battery charging bin can contain a plurality of batteries; this means that in the process of charging the battery, any battery in any one battery charging bin breaks down, and the battery in the whole battery charging bin may be subjected to accidents such as heating, burning and even explosion, and further the battery will reach the whole battery stack, which will cause huge economic loss.

Therefore, it is a technical problem to be solved by those skilled in the art to provide a fire fighting system based on battery partition management, which can perform fire fighting treatment before the battery develops into a fire, has better fire fighting effect, and better reduces economic loss.

SUMMERY OF THE UTILITY MODEL

To the not enough of above-mentioned prior art, the utility model aims to solve the technical problem that: how to provide one kind and can carry out the fire control before the battery develops into the conflagration and handle, the fire control effect is better, the better fire control system based on new energy automobile battery subregion management that reduces economic loss.

In order to solve the technical problem, the utility model discloses a following technical scheme:

a fire fighting system based on new energy automobile battery partition management comprises a fire fighting medium storage device, a battery charging bin and a fire fighting controller, wherein a battery to be charged is arranged in the battery charging bin, the fire fighting medium storage device and the battery charging bin are communicated through a medium conveying pipeline, a medium output control assembly is arranged on the medium conveying pipeline, and an electric control end of the medium output control assembly is connected with an output end of the fire fighting controller; the intelligent fire extinguishing device is characterized in that a smoke sensor is arranged in the battery charging bin, and a signal output end of the smoke sensor and a temperature signal output end of a BMS (battery management system) of the battery are connected with an input end of the fire extinguishing controller.

Thus, the BMS (battery management system) transmits the monitored information (temperature) of the battery to the fire extinguishing controller; the smoke sensor transmits the monitored information (smoke amount) in the battery charging bin to the fire extinguishing controller; and the fire extinguishing controller controls the fire-fighting medium storage device to inject fire-fighting medium into the battery charging bin according to the temperature and smoke quantity of the battery. Because the battery is in the battery charging storehouse, the time interval from beginning to produce smog to the time of starting a fire is very short, and the smoke that designs feels the sensor can be after the battery breaks down, and the fault condition is in the time quantum between producing smog and producing flame and reacts, can be better to react before the battery charging storehouse fires to feel information transfer to fire extinguishing controller with the cigarette. The battery fire can be well restrained before the battery fire happens, the fire spreading and spreading can be well avoided, the rest of battery charging bins can be well avoided, the fire fighting effect of the whole system can be improved, and the economic loss can be better reduced.

As optimizing, still include the EMS, smoke and feel sensor and BMS all link to each other with the input of EMS, the output of EMS links to each other with the input of fire extinguishing controller.

Thus, after the BMS (battery management system) transmits the monitored information (temperature) of the battery and the monitored information (smoke amount) in the battery charging chamber to the EMS, the EMS transmits the battery temperature and smoke amount information to the fire extinguishing controller. When the EMS serves as a transfer station for information transmission, the EMS can judge the change of the energy of the battery, the energy of the battery can change due to a fire caused by a short circuit, the EMS monitors the change of the energy of the battery, and the EMS can more accurately obtain whether the battery breaks down or not, so that the judgment on the battery fault is more accurate. The fire fighting effect of the whole system can be better.

As optimization, the fire-fighting medium storage device comprises a fire-fighting water tank and a fire-fighting gas cylinder, the fire-fighting water tank is connected with the battery charging bin through a water conveying pipeline, and the fire-fighting gas cylinder is connected with the battery charging bin through a gas conveying pipeline; the medium output control device comprises a water pump, a water control electromagnetic valve and a gas control electromagnetic valve; the water pumps are arranged on the water conveying pipeline in a one-to-one correspondence manner with the battery charging bins, and the water control electromagnetic valves are arranged between the water pumps and the battery charging bins; the gas control electromagnetic valves are arranged on the gas transmission pipeline in a one-to-one correspondence manner with the battery charging bins; and the electric control end of the water pump, the water control electromagnetic valve and the gas control electromagnetic valve are all electrically connected with the fire extinguishing controller.

Therefore, in the charging process, after the battery charging bin breaks down, the fire-fighting gas bottle can charge fire-fighting gas (carbon dioxide or nitrogen) into the battery charging bin to protect the battery in the battery charging bin; the fire water tank can carry out the flood protection to this battery charging storehouse to battery charging storehouse injected water to make the trouble can not spread to remaining battery charging storehouse. The fire-fighting gas is filled into the battery charging bin to serve as first heavy protection, so that faults in the battery charging bin can be better restrained; and then, water is injected into the battery charging bin to serve as second protection, so that the aim of reducing the fault spreading to the other battery charging bins can be fulfilled. The battery passenger stack for the whole electric automobile is safer when in use, and the economic loss caused by faults can be reduced.

Preferably, the fire-fighting gas cylinder comprises a main gas cylinder and an auxiliary gas cylinder, gas outlets of the main gas cylinder and the auxiliary gas cylinder are respectively connected with branch gas pipes, and far ends of the two branch gas pipes are connected with a gas transmission pipeline.

Like this, through setting up main gas cylinder and vice gas cylinder, the unexpected emergence of reduction that can be better can make when breaking down in the battery charging storehouse, more reliable to aerifing in battery charging storehouse, reduces unexpected probability.

As optimization, a first one-way valve is arranged on a branch air pipe corresponding to the main air bottle; and a second one-way valve is arranged on the branch gas pipe corresponding to the auxiliary gas cylinder.

Like this for the gaseous one-way battery storehouse that charges of following the fire control gas cylinder flow direction of fire control, more reasonable in design can improve the fire control effect.

As optimization, a main electromagnetic valve is arranged between the main gas cylinder and the first one-way valve; an auxiliary electromagnetic valve is arranged between the auxiliary gas cylinder and the second one-way valve.

Like this, the gaseous flow direction of control fire control that can be more accurate, the gaseous leakage of avoiding fire control that can be better flows to the battery storehouse of charging.

As an optimization, the water delivery pipeline comprises a main pipeline and a branch pipeline, the fire water tank is provided with two water outlets, one ends of the two branch pipelines are respectively connected with the two water outlets, the other ends of the two branch pipelines are connected with one end of the main pipeline, and the other end of the main pipeline is connected with the battery charging bin; and the two branch pipelines are respectively provided with a water pump.

Like this, design two water pumps, the emergence of avoiding the trouble that can be better can improve fire extinguishing system's reliability.

Preferably, the number of the smoke sensors is two, and the two smoke sensors are fixed at two ends of the same diagonal line on the top surface of the battery charging bin in a one-to-one correspondence manner.

Like this, set up two smoke and feel the sensor, the economic loss who avoids bringing because of the maloperation that can be better prevents the maloperation.

As optimization, a check valve is arranged on the circumferential side wall of the battery charging bin.

Therefore, the fire-fighting medium in the battery charging bin can flow out of the battery charging bin from the check valve. The battery charging bin is convenient to clean.

As an optimization, the fire extinguishing system further comprises an operation panel, and the operation panel is connected with the fire extinguishing controller.

Therefore, the operation of operators can be facilitated, and the use is more convenient.

Preferably, the gas of the fire-fighting gas cylinder is carbon dioxide gas.

Thus, the fire fighting effect can be better.

Preferably, the fire extinguishing controller is further connected with the UPS, and the UPS supplies power to the fire extinguishing controller.

Like this, UPS (uninterrupted power source) power supply can make fire extinguishing system be in operating condition always, can be better protect the battery in the battery charging storehouse.

The invention also discloses a fire fighting method based on the battery partition management of the new energy automobile, which is characterized in that two smoke sensors are arranged in the battery charging bin to respectively obtain a first smoke value and a second smoke value in the corresponding battery charging bin, and the battery temperature and the first smoke value and the second smoke value in the battery charging bin are monitored; when any two or three of the three monitoring factors of the first smoke value, the second smoke value and the battery temperature exceed corresponding limit values, a step of injecting a fire-fighting medium into the battery charging bin is executed; after the fire-fighting medium is injected into any one battery charging bin, when three monitoring factors, namely a first smoke value, a second smoke value and a battery temperature, monitored in any one subsequent battery charging bin exceed corresponding limit values, the step of injecting the fire-fighting medium into the battery charging bin is executed.

The applicant applies for a fire protection method for a battery stack for charging a battery of an electric vehicle, which is characterized in that the method comprises the steps of monitoring three factors of battery temperature, flame of battery failure and smoke amount of battery failure, and spraying a fire-fighting medium to the battery when the battery temperature is higher than a preset temperature value; when the battery temperature is between a preset temperature value and a limit temperature value and only one of three conditions of flame sensor alarm or smoke sensor alarm is met, the step of taking the tray with the detected battery out of the battery stack is executed; and when the temperature of the battery reaches or exceeds the limit temperature value, and any two conditions of the flame sensor alarm or the smoke sensor alarm are met, the step of popping the tray with the detected battery from the battery stack is executed.

However, in the practical application process, the problem that fire fighting delay exists by taking the three factors of the battery temperature, the flame with the battery fault and the smoke amount with the battery fault as the judgment conditions for executing fire fighting is found, and because the battery is in the battery charging bin, the time interval from the beginning of generating smoke to the fire is very short, the combustion is judged by the flame to indicate that the whole fire fighting delay is caused, the fire fighting is carried out after the fire fighting combustion, the purpose of better fire fighting cannot be achieved, and greater economic loss is easily caused. Therefore, the applicant takes the first smoke value, the second smoke value and the temperature as the fire-fighting judgment factors, so that the fire-fighting reaction is carried out in the time interval from the generation of smoke to the fire, the reaction can be better carried out before the fire of the battery charging bin occurs, the fire-fighting judgment is carried out before the flame combustion occurs, the fire-fighting timeliness of the battery charging bin is better improved, and the economic loss is reduced. And through first smog numerical value, the reduction misjudgment that second smog numerical value can be better, improve the accuracy of fire control. Meanwhile, after the fire-fighting medium is injected into any battery charging bin, when three monitoring factors, namely a first smoke value, a second smoke value and a battery temperature, monitored in any subsequent battery charging bin exceed corresponding limit values, and the difference value between the first smoke value and the second smoke value is smaller than a preset value, the step of injecting the fire-fighting medium into the battery charging bin is executed. This can reduce the influence of the first battery charging bin on the remaining battery charging bins. The design is more reasonable. Because of when arbitrary one battery charging storehouse breaks down and produces smog, smog flows scurrying the battery charging storehouse outside, and spread remaining battery charging storehouse, smog when diffusing remaining battery charging storehouse this moment, often get into from one side in battery charging storehouse, make the interval set up the difference of the first smog numerical value that two smoke detector sensors obtained in the battery charging storehouse like this and the difference of second smog numerical value great, thereby when the difference of first smog numerical value and second smog numerical value is more than or equal to the default, be the interference in outside charging storehouse promptly, can prevent the maloperation. And particularly, only when the difference value between the first smoke value and the second smoke value is smaller than the preset value, the battery charging bin can be judged to be in fault. The mutual influence between the battery charging bins can be reduced, and the misjudgment probability is reduced.

Preferably, the fire-fighting medium comprises a fire-fighting liquid and a fire-fighting gas.

Like this, through pour into fire control liquid and fire control gas into in the storehouse to battery charging, can be faster more rapid the completion to the fire control operation in battery charging storehouse.

As an optimization, the time for injecting the fire fighting liquid into the battery charging bin is twenty seconds, and the time for injecting the fire fighting gas into the battery charging bin is twenty-five seconds.

Like this, can be better accomplish the fire control operation to battery charging storehouse, can avoid fire control liquid to flow back towards the fire control gas side.

Preferably, the fire-fighting liquid is fire-fighting water, and the fire-fighting gas is carbon dioxide gas.

Like this, better to the fire control effect of battery in the battery charging storehouse, can be better restrain the trouble in the battery charging storehouse.

As optimization, the fire-fighting medium is injected into the battery charging bin, and meanwhile, an alarm signal is sent out.

Therefore, the staff can know that the battery charging bin is out of order through the alarm signal conveniently. To make corresponding emergency treatment.

Drawings

Fig. 1 is a schematic view of a connection structure according to an embodiment of the present invention.

Fig. 2 is a flow chart of a fire fighting method based on battery partition management.

Detailed Description

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

In the specific implementation: as shown in fig. 1 and 2, a fire fighting system based on new energy vehicle battery partition management comprises a fire fighting medium storage device, a battery charging bin 1 and a fire fighting controller 2, wherein a battery to be charged is arranged in the battery charging bin, the fire fighting medium storage device and the battery charging bin are communicated through a medium conveying pipeline, a medium output control assembly is arranged on the medium conveying pipeline, and an electric control end of the medium output control assembly is connected with an output end of the fire fighting controller 2; the intelligent fire extinguishing device is characterized in that a smoke sensor is arranged in the battery charging bin, and a signal output end of the smoke sensor and a temperature signal output end of a BMS (battery management system) of the battery are connected with an input end of the fire extinguishing controller.

Thus, the BMS (battery management system) transmits the monitored information (temperature) of the battery to the fire extinguishing controller; the smoke sensor transmits the monitored information (smoke amount) in the battery charging bin to the fire extinguishing controller; and the fire extinguishing controller controls the fire-fighting medium storage device to inject fire-fighting medium into the battery charging bin according to the temperature and smoke quantity of the battery. Because the battery is in the battery charging storehouse, the time interval from beginning to produce smog to the time of starting a fire is very short, and the smoke that designs feels the sensor can be after the battery breaks down, and the fault condition is in the time quantum between producing smog and producing flame and reacts, can be better to react before the battery charging storehouse fires to feel information transfer to fire extinguishing controller with the cigarette. The battery fire can be well restrained before the battery fire happens, the fire spreading and spreading can be well avoided, the rest of battery charging bins can be well avoided, the fire fighting effect of the whole system can be improved, and the economic loss can be better reduced.

In this specific embodiment, still include EMS3, smoke and feel sensor and BMS all link to each other with EMS's input, EMS's output links to each other with fire extinguishing controller's input.

Thus, after the BMS (battery management system) transmits the monitored information (temperature) of the battery and the monitored information (smoke amount) in the battery charging chamber to the EMS, the EMS transmits the battery temperature and smoke amount information to the fire extinguishing controller. When the EMS serves as a transfer station for information transmission, the EMS can judge the change of the energy of the battery, the energy of the battery can change due to a fire caused by a short circuit, the EMS monitors the change of the energy of the battery, and the EMS can more accurately obtain whether the battery breaks down or not, so that the judgment on the battery fault is more accurate. The fire fighting effect of the whole system can be better.

In the specific embodiment, the fire-fighting medium storage device comprises a fire-fighting water tank 4 and a fire-fighting gas cylinder 5, wherein the fire-fighting water tank is connected with the battery charging bin through a water conveying pipeline, and the fire-fighting gas cylinder is connected with the battery charging bin through a gas conveying pipeline; the medium output control device comprises a water pump 6, a water control electromagnetic valve 7 and a gas control electromagnetic valve 8; the water pumps are arranged on the water conveying pipeline in a one-to-one correspondence manner with the battery charging bins, and the water control electromagnetic valves are arranged between the water pumps and the battery charging bins; the gas control electromagnetic valves are arranged on the gas transmission pipeline in a one-to-one correspondence manner with the battery charging bins; and the electric control end of the water pump, the water control electromagnetic valve and the gas control electromagnetic valve are all electrically connected with the fire extinguishing controller.

Therefore, in the charging process, after the battery charging bin breaks down, the fire-fighting gas bottle can charge fire-fighting gas (carbon dioxide or nitrogen) into the battery charging bin to protect the battery in the battery charging bin; the fire water tank can carry out the flood protection to this battery charging storehouse to battery charging storehouse injected water to make the trouble can not spread to remaining battery charging storehouse. The fire-fighting gas is filled into the battery charging bin to serve as first heavy protection, so that faults in the battery charging bin can be better restrained; and then, water is injected into the battery charging bin to serve as second protection, so that the aim of reducing the fault spreading to the other battery charging bins can be fulfilled. The battery passenger stack for the whole electric automobile is safer when in use, and the economic loss caused by faults can be reduced.

In this specific embodiment, the fire-fighting gas bottle 5 comprises a main gas bottle 9 and an auxiliary gas bottle 10, the gas outlets of the main gas bottle and the auxiliary gas bottle are respectively connected with branch gas pipes, and the far ends of the two branch gas pipes are connected with a gas transmission pipeline.

Like this, through setting up main gas cylinder and vice gas cylinder, the unexpected emergence of reduction that can be better can make when breaking down in the battery charging storehouse, more reliable to aerifing in battery charging storehouse, reduces unexpected probability.

In the embodiment, a first one-way valve 11 is arranged on a branch air pipe corresponding to the main air bottle; and a second one-way valve 12 is arranged on a branch air pipe corresponding to the auxiliary air bottle.

Like this for the gaseous one-way battery storehouse that charges of following the fire control gas cylinder flow direction of fire control, more reasonable in design can improve the fire control effect.

In this embodiment, a main solenoid valve 13 is provided between the main gas bottle and the first check valve; an auxiliary electromagnetic valve 14 is arranged between the auxiliary gas cylinder and the second one-way valve.

Like this, the gaseous flow direction of control fire control that can be more accurate, the gaseous leakage of avoiding fire control that can be better flows to the battery storehouse of charging.

In this specific embodiment, the water pipe includes a main pipeline and a branch pipeline, the fire-fighting water tank is provided with two water outlets, one end of each of the two branch pipelines is connected to the two water outlets, the other end of each of the two branch pipelines is connected to one end of the main pipeline, and the other end of the main pipeline is connected to the battery charging bin; and the two branch pipelines are respectively provided with a water pump 6.

Like this, design two water pumps, the emergence of avoiding the trouble that can be better can improve fire extinguishing system's reliability.

In this specific embodiment, the number of the smoke sensor is two, and the two smoke sensors are fixed to two ends of the same diagonal line on the top surface of the battery charging bin in a one-to-one correspondence manner.

Like this, set up two smoke and feel the sensor, the economic loss who avoids bringing because of the maloperation that can be better prevents the maloperation.

In this embodiment, a check valve 15 is provided on the circumferential side wall of the battery charging bin.

Therefore, the fire-fighting medium in the battery charging bin can flow out of the battery charging bin from the check valve. The battery charging bin is convenient to clean.

In this embodiment, an operation panel 16 is also included, which is connected to the fire suppression controller.

Therefore, the operation of operators can be facilitated, and the use is more convenient.

In this embodiment, the gas in the fire-fighting gas cylinder is carbon dioxide gas.

Thus, the fire fighting effect can be better.

In this embodiment, the fire extinguishing controller is further connected with the UPS, and the UPS supplies power to the fire extinguishing controller.

Like this, UPS (uninterrupted power source) power supply can make fire extinguishing system be in operating condition always, can be better protect the battery in the battery charging storehouse.

The invention also discloses a fire fighting method based on battery partition management, which is characterized in that two smoke sensors are arranged in a battery charging bin to respectively obtain a first smoke value and a second smoke value in the corresponding battery charging bin, and the three factors of the battery temperature and the first smoke value and the second smoke value in the battery charging bin are monitored; when any two or three of the three monitoring factors of the first smoke value, the second smoke value and the battery temperature exceed corresponding limit values, a step of injecting a fire-fighting medium into the battery charging bin is executed; after the fire-fighting medium is injected into any one battery charging bin, when three monitoring factors, namely a first smoke value, a second smoke value and a battery temperature, monitored in any one subsequent battery charging bin exceed corresponding limit values, the step of injecting the fire-fighting medium into the battery charging bin is executed.

The applicant applies for a fire protection method for a battery stack for charging a battery of an electric vehicle, which is characterized in that the method comprises the steps of monitoring three factors of battery temperature, flame of battery failure and smoke amount of battery failure, and spraying a fire-fighting medium to the battery when the battery temperature is higher than a preset temperature value; when the battery temperature is between a preset temperature value and a limit temperature value and only one of three conditions of flame sensor alarm or smoke sensor alarm is met, the step of taking the tray with the detected battery out of the battery stack is executed; and when the temperature of the battery reaches or exceeds the limit temperature value, and any two conditions of the flame sensor alarm or the smoke sensor alarm are met, the step of popping the tray with the detected battery from the battery stack is executed.

However, in the practical application process, the problem that fire fighting delay exists by taking the three factors of the battery temperature, the flame with the battery fault and the smoke amount with the battery fault as the judgment conditions for executing fire fighting is found, and because the battery is in the battery charging bin, the time interval from the beginning of generating smoke to the fire is very short, the combustion is judged by the flame to indicate that the whole fire fighting delay is caused, the fire fighting is carried out after the fire fighting combustion, the purpose of better fire fighting cannot be achieved, and greater economic loss is easily caused. Therefore, the applicant takes the first smoke value, the second smoke value and the temperature as the fire-fighting judgment factors, so that the fire-fighting reaction is carried out in the time interval from the generation of smoke to the fire, the reaction can be better carried out before the fire of the battery charging bin occurs, the fire-fighting judgment is carried out before the flame combustion occurs, the fire-fighting timeliness of the battery charging bin is better improved, and the economic loss is reduced. And through first smog numerical value, the reduction misjudgment that second smog numerical value can be better, improve the accuracy of fire control. Meanwhile, after the fire-fighting medium is injected into any battery charging bin, when three monitoring factors, namely a first smoke value, a second smoke value and a battery temperature, monitored in any subsequent battery charging bin exceed corresponding limit values, and the difference value between the first smoke value and the second smoke value is smaller than a preset value, the step of injecting the fire-fighting medium into the battery charging bin is executed. This can reduce the influence of the first battery charging bin on the remaining battery charging bins. The design is more reasonable. Because of when arbitrary one battery charging storehouse breaks down and produces smog, smog flows scurrying the battery charging storehouse outside, and spread remaining battery charging storehouse, smog when diffusing remaining battery charging storehouse this moment, often get into from one side in battery charging storehouse, make the interval set up the difference of the first smog numerical value that two smoke detector sensors obtained in the battery charging storehouse like this and the difference of second smog numerical value great, thereby when the difference of first smog numerical value and second smog numerical value is more than or equal to the default, be the interference in outside charging storehouse promptly, can prevent the maloperation. And particularly, only when the difference value between the first smoke value and the second smoke value is smaller than the preset value, the battery charging bin can be judged to be in fault. The mutual influence between the battery charging bins can be reduced, and the misjudgment probability is reduced. According to practical experience, the limit value of the battery temperature is 55 ℃, the limit value of the smoke concentration is 10ppm, and the preset value of the smoke concentration is 2-5 ppm. Such an arrangement is more reasonable.

Preferably, the fire-fighting medium comprises a fire-fighting liquid and a fire-fighting gas.

Like this, through pour into fire control liquid and fire control gas into in the storehouse to battery charging, can be faster more rapid the completion to the fire control operation in battery charging storehouse.

As an optimization, the time for injecting the fire fighting liquid into the battery charging bin is twenty seconds, and the time for injecting the fire fighting gas into the battery charging bin is twenty-five seconds.

Like this, can be better accomplish the fire control operation to battery charging storehouse, can avoid fire control liquid to flow back towards the fire control gas side.

Preferably, the fire-fighting liquid is fire-fighting water, and the fire-fighting gas is carbon dioxide gas.

Like this, better to the fire control effect of battery in the battery charging storehouse, can be better restrain the trouble in the battery charging storehouse.

As optimization, the fire-fighting medium is injected into the battery charging bin, and meanwhile, an alarm signal is sent out.

Therefore, the staff can know that the battery charging bin is out of order through the alarm signal conveniently. To make corresponding emergency treatment.

Claims (10)

1. A fire fighting system based on new energy automobile battery partition management comprises a fire fighting medium storage device, a battery charging bin (1) and a fire fighting controller (2), wherein a battery to be charged is arranged in the battery charging bin, the fire fighting medium storage device and the battery charging bin are provided with medium conveying pipelines to be communicated, a medium output control assembly is arranged on the medium conveying pipelines, and an electric control end of the medium output control assembly is connected with an output end of the fire fighting controller (2); the intelligent fire extinguishing device is characterized in that a smoke sensor is arranged in the battery charging bin, and a signal output end of the smoke sensor and a temperature signal output end of a BMS (battery management system) of the battery are connected with an input end of the fire extinguishing controller.

2. A fire fighting system based on battery partition management of new energy vehicles according to claim 1, further comprising an EMS (3), wherein the smoke sensor and the BMS are both connected to an input of the EMS, and an output of the EMS is connected to an input of the fire extinguishing controller.

3. The fire fighting system based on the battery partition management of the new energy automobile according to claim 1, wherein the fire fighting medium storage device comprises a fire fighting water tank (4) and a fire fighting gas cylinder (5), the fire fighting water tank is connected with the battery charging bin through a water conveying pipeline, and the fire fighting gas cylinder is connected with the battery charging bin through a gas conveying pipeline; the medium output control device comprises a water pump (6), a water control electromagnetic valve (7) and a gas control electromagnetic valve (8); the water pumps are arranged on the water conveying pipeline in a one-to-one correspondence manner with the battery charging bins, and the water control electromagnetic valves are arranged between the water pumps and the battery charging bins; the gas control electromagnetic valves are arranged on the gas transmission pipeline in a one-to-one correspondence manner with the battery charging bins; and the electric control end of the water pump, the water control electromagnetic valve and the gas control electromagnetic valve are all electrically connected with the fire extinguishing controller.

4. The fire fighting system based on battery partition management of the new energy automobile is characterized in that the fire fighting gas bottle (5) comprises a main gas bottle (9) and an auxiliary gas bottle (10), the gas outlets of the main gas bottle and the auxiliary gas bottle are respectively connected with branch gas pipes, and the far ends of the two branch gas pipes are connected with a gas transmission pipeline.

5. The fire fighting system based on battery partition management of the new energy automobile according to claim 4, characterized in that a first check valve (11) is arranged on a branch air pipe corresponding to the main air bottle; a second one-way valve (12) is arranged on the branch air pipe corresponding to the auxiliary air bottle.

6. The fire fighting system based on battery partition management of new energy vehicles according to claim 5, characterized in that a main solenoid valve (13) is provided between the main gas cylinder and the first check valve; an auxiliary electromagnetic valve (14) is arranged between the auxiliary gas cylinder and the second one-way valve.

7. The fire fighting system based on battery partition management of the new energy automobile according to claim 3, wherein the water delivery pipeline comprises a main pipeline and a branch pipeline, the fire fighting water tank is provided with two water outlets, one end of each of the two branch pipelines is connected with the two water outlets, the other end of each of the two branch pipelines is connected with one end of the main pipeline, and the other end of the main pipeline is connected with the battery charging bin; and the two branch pipelines are respectively provided with a water pump (6).

8. The fire fighting system according to claim 1, wherein the number of the smoke sensors is two, and the two smoke sensors are fixed to two ends of the same diagonal line on the top surface of the battery charging bin in a one-to-one correspondence manner.

9. The fire fighting system based on battery partition management of new energy vehicles according to claim 1, characterized in that a check valve (15) is provided on the circumferential side wall of the battery charging bin.

10. A fire fighting system based on battery partition management of new energy vehicles according to claim 3, characterized by further comprising an operation panel (16) connected with the fire extinguishing controller;

the gas of the fire-fighting gas cylinder is carbon dioxide gas;

the fire extinguishing controller is also connected with the UPS, and the UPS supplies power to the fire extinguishing controller.

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