KR101384519B1 - Eco-green energe management system for fire station - Google Patents

Abstract

Fire station environmentally friendly energy management system of the present invention, the solar cell module is installed on the roof of the fire station having a solar panel and hot water generation unit; A storage battery for charging electricity produced from the solar cell module; A power converter converting the direct current of the battery into alternating current; A hot water storage tank storing hot water heated by the hot water generating unit of the solar cell module; A first heat exchanger circulating hot water stored in the hot water storage tank to produce warm air; A second heat exchanger configured to generate warm air by receiving electricity from the power converter; A warm air supply unit for supplying warm air produced by the first heat exchanger and / or the second heat exchanger to the fire station; A ventilation system for discharging the fumes of the fire station; By detecting the outside temperature and the indoor temperature and CO2 concentration of the fire station, supplying hot water to the fire station, supplying warm air to the fire engine, or by including a control unit for selectively controlling the ventilation function of the fire station, by generating a solar cell module By operating an energy management system using electricity, it produces electricity and hot water on its own, saving energy, reducing the use of fossil fuels and preventing environmental pollution, and selecting areas where fire trucks are expected to freeze. By intensively supplying warm air, the freezing of fire trucks is effectively prevented, and the effect of reducing the indoor air pollution of fire trucks is generated by performing a garage ventilation according to the CO 2 concentration in the fire truck.

Description

Eco-green energe management system for fire station

The present invention relates to a fire station eco-friendly energy production and supply system using solar energy, and more specifically, to provide electrical and thermal energy used in the fire station from the solar cell module, in particular, the hot air to anticipate the freezing of the winter fire truck It is the technology about energy management system which supplies intensively.

In general, fire departments that suppress fires and perform work on emergency rescues have a large number of personnel required to carry out their duties, day and night, and also operate fire trucks in the garage to respond quickly to emergency situations. have. Thus, in order for a large number of personnel to reside in the fire station, electric and thermal energy necessary for daily living must be continuously supplied, and a general fire department uses the energy from a power or gas source rather than using it on its own.

The fire truck waiting in the garage of the fire station is equipped with a water tank and stores water for extinguishing fire, such as a pump device for spraying fire water at a high pressure and a waterproof device for spraying water at an increased pressure by the pump. In addition, the pumps and conduits of the fire trucks may be frozen in conduits or pumps if exposed to prolonged temperatures below the freezing point in winter. Is not possible or there is a problem that the conduit or pump is broken.

As a conventional technique for preventing such an accident, a heating device is provided in a garage of a fire station where a fire engine is waiting, or a waterproof device of a fire engine of Korean Patent Publication No. 10-0237834 (January 15, 2000). Anti-icing systems are known. As described in the above patent publication, as shown in FIG. 1, the heating means 101 is installed in a waterproof valve or a waterproof tube 100 in which water is stagnant in a fire engine, and a temperature is sensed by a temperature sensor 102. The current of the vehicle battery 103 of the fire engine is converted by the voltage conversion unit 104, the control device 105 controls the current to heat the heating means 101 to prevent freezing.

As such, most of the energy consumed by the fire station uses fossil fuels, and thus there is a problem in that energy use costs continue to increase due to exhaustion of fossil fuel resources and supply and demand imbalance, and also provide a cause of environmental pollution. A freeze protection system using battery power of a fire engine has a problem of causing battery discharge of a vehicle or shortening battery life.

The present invention is to solve the above-mentioned problems, to obtain and supply the hot water and electricity for living in the fire station from the sun, to generate hot air using the heat energy and electrical energy obtained from the sun, and to wait in the fire garage It is to provide an eco-friendly energy management system of fire departments that supply intensively to the anticipated freezing areas of fire trucks in winter.

Fire station eco-friendly energy management system to achieve the above object, the solar cell module is installed on the roof of the fire station having a solar panel and hot water generating unit; A storage battery for charging electricity produced from the solar cell module; A power converter converting the direct current of the battery into alternating current; A hot water storage tank storing hot water heated by the hot water generating unit of the solar cell module; A first heat exchanger circulating hot water stored in the hot water storage tank to produce warm air; A second heat exchanger configured to generate warm air by receiving electricity from the power converter; A warm air supply unit for supplying warm air produced by the first heat exchanger and / or the second heat exchanger to the fire station; A ventilation system for discharging the fumes of the fire station; It detects the outside temperature and the indoor temperature and CO2 concentration of the fire station to supply hot water to the fire station, to supply warm air to the fire engine, or to include a control unit for selectively controlling the ventilation function of the fire station.

The solar cell module forms a hot water generating unit for cooling the solar panel by circulating the cooling water on the solar panel and the solar panel made of polycrystalline silicon, and the angle of the light by tracking the movement of the sun to adjust the light receiving angle Be sure to

The electricity converted into alternating current in the power conversion unit may be supplied for a power supply for driving an electric device included in the environmentally friendly energy management system of the present invention, or to a power supply source receiving general electricity.

The hot air supply unit is installed on the ceiling of the fire station garage and has a hot air supply fan, and connects the first conduit receiving the warm air produced by the first heat exchanger and the second conduit receiving the warm air from the second exchanger on one side. A third conduit having a plurality of connection ports is formed on the other side, and the connection length of the third conduit is to be equipped with a warm air duct each having a long length. Each hot air duct is provided with an on / off valve that opens or closes the hot air flow path adjacent to the connection port of the third conduit, and each of the hot air ducts forms a plurality of hot air discharge ports at predetermined intervals, and a drive motor is installed at the hot air discharge ports. Then, ascending and descending toward the anticipated freezing area of the fire truck waiting in the garage to be installed detachably.

The control unit receives an outside air temperature from a temperature sensor installed outside the fire station, receives a hot water temperature stored in the hot water storage tank from a temperature sensor installed in the hot water storage tank of the solar cell module, and detects CO 2 installed in the fire garage. A temperature and CO2 concentration input step of receiving CO2 concentration in the fire station detected by the sensor; A freezing temperature determination step of determining whether the outside temperature is a temperature at which the freezing of the fire engine is expected based on the received temperature value; A hot water pump driving step of driving a first hot water pump for supplying hot water from a hot water tank to a first heat exchange or a second heat exchanger when the outside temperature is a temperature at which the fire engine can be frozen; A hot water valve opening step of selectively opening the first hot water valve or the second hot water valve to supply hot water to the first heat exchanger if the hot water temperature of the hot water storage tank is equal to or higher than a predetermined temperature, and to the second heat exchanger if the hot water temperature is lower than the predetermined temperature; A warm air supply step of supplying warm air generated by the first heat exchanger or the second heat exchanger to the expansion pipe by driving the warm air supply fan; According to the type of the vehicle waiting in the fire garage, the control including the expansion pipe driving step for lowering the expansion pipe to be close to the expected region.

The control unit may further include: stopping the first hot water pump to stop the operation of the first hot water pump when the outside temperature is determined to be equal to or higher than a temperature at which the fire engine is expected to freeze in the freezing temperature determination step; The fourth hot water pump is operated to further control the living water supplying step of supplying hot water from the hot water storage tank to the living water.

The control unit may include a charging step of charging the storage battery with electricity generated from the solar cell module; A power conversion step of converting direct current into alternating current by supplying electricity charged in the battery to the power conversion device; A power supply step of supplying the converted electricity to power of a driving motor for driving a solar cell module, a hot water pump, a valve, a hot air supply fan, a ventilation fan, and a expansion tube included in an energy management system; In the freezing temperature determination step, it is determined that the outdoor air temperature is expected to be frozen in the fire engine, and when the second hot water valve is opened because the hot water temperature of the hot water storage tank is below a predetermined temperature through the hot water valve opening step, the converted electricity is removed. An electric heater operating step of supplying an electric heater of the two heat exchangers to operate the electric heater; In the case of not supplying power to the energy management system, the generated electricity is supplied to the electricity supplier to further control the electricity sales step of selling electricity.

Through the control of the control unit, the hot water generated from the solar cell module is used as daily hot water for the fire department, or the hot air is generated using the electricity and hot water generated from the solar cell module, and the fire engine is supplied to prevent freezing, and the ventilation facility in the fire engine is driven. Do it.

As described above, the fire station eco-friendly energy management system of the present invention produces warm air using hot water generated by the solar cell module, and saves energy by driving the energy management system by using electricity generated by the solar cell module. By reducing the use of fossil fuels, the effect is to prevent environmental pollution.

In addition, the fire station eco-friendly energy management system of the present invention by supplying hot water generated in the solar cell module to the living water of the fire station, while saving energy, reducing the use of fossil fuel to prevent the environmental pollution is generated.

In addition, the fire station eco-friendly energy management system of the present invention by intensively supplying the warm air by the new pipe is expected to freeze the location of the fire truck, the garage heating for preventing the freezing of the fire truck is not necessary to maximize the energy saving.

In addition, garage ventilation is performed according to the CO2 concentration generated in the atmosphere of the fire engine in the fire truck, thereby reducing the indoor air pollution of the fire truck.

1 is a view showing a fire truck freezing prevention state according to the prior art.
2 is a view showing a general configuration of a fire station eco-friendly energy management system according to an embodiment of the present invention.
3 is a view showing the position change and hot water generation state of the solar cell module according to an embodiment of the present invention.
4 is a view showing a structure of a first heat exchanger according to an embodiment of the present invention.
5 is a view showing a second heat exchanger structure according to an embodiment of the present invention.
6 is a view showing a hot air supply fan portion according to an embodiment of the present invention.
7 is a view showing a warm air supply unit according to an embodiment of the present invention.
8 is a view showing a hot water and hot air supply step according to an embodiment of the present invention.
9 is a view showing the electricity supply step according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 2, the fire station-friendly energy management system according to the present invention includes a solar cell module 3 installed on the roof of the fire station and having a solar cell panel 1 and a hot water generating unit 2; A storage battery 4 for charging electricity produced by the solar cell module 3; A power converter 5 for converting direct current of the battery into alternating current; A hot water storage tank 6 for storing hot water generated by the hot water generating unit of the solar cell module; A first heat exchanger 7 for producing warm air by heat-exchanging hot water stored in the hot water storage tank; A second heat exchanger 8 which receives hot current stored in the hot water storage tank and current from the power converter to produce warm air through heat exchange; Hot air supply unit 9 for supplying the warm air produced in the first heat exchanger (7) and / or the second heat exchanger (8) to the fire station; Ventilation facility 10 for exhausting the smoke of the fire station garage; The control unit 11 detects the outside temperature and the indoor temperature and the CO 2 concentration of the fire station to supply hot water to the fire station, supply hot air to the fire engine, or selectively control the ventilation function of the fire station.

As shown in FIG. 3, the solar cell module 3 forms a hot water generating unit 2 that cools the solar panel by circulating cooling water on the rear surface of the solar cell panel 1 made of polycrystalline silicon. By supplying the cooling water to the hot water generating unit 2 and cooling water absorbs the heat generated from the solar cell module to lower the temperature of the solar cell module, by using the heat absorbed from the solar cell module while improving the solar cell power generation efficiency To generate hot water. That is, the hot water generation method according to the present invention is to generate hot water through a cooling method for increasing the power generation efficiency of the solar cell, and is not limited to the above-described embodiment, and various cooling methods for supplying cooling water to cool the solar panel. It can be used including the applied solar cell module.

In addition, the solar cell module (3) to track the movement of the sun by the angle adjustment motor to adjust the light receiving angle. More specifically, the first rotation motor 12 for rotating the horizontal axis of the solar module and the second rotation motor 13 for rotating the vertical axis so that the sunlight incident on the light collecting surface of the solar cell module as close to the vertical as possible. And a solar incident angle detection sensor so that the controller 11 controls the forward rotation and the reverse rotation driving of the first and second rotation motors 12 and 13 according to the signal of the solar incident angle detection sensor. The light receiving angle adjusting device of the solar cell module is not limited to the above-described embodiment, and may be formed using various methods of changing the position of the solar cell module by tracking the movement of sunlight.

As such, the electricity produced in the solar cell module 3 is supplied to the storage battery 4 and charged, and the direct current charged in the storage battery 4 is converted into alternating current in the power conversion unit 5, thereby saving environment-friendly energy according to the present invention. It can be used as a power source to drive electrical devices included in the management system or to a power supply source that receives general electricity. That is, the electricity produced by the solar cell module 3 and charged in the storage battery is a power source for driving the first and second rotation motors 12 and 13 to adjust the rotation angle of the solar cell module under the control of the controller 11; Energy is supplied by power supply for driving pump to supply water for hot water generation, power for electric heater for producing warm air, power for blower fan for supplying warm air and power for lifting motor for lifting and expanding expansion pipes, and power for driving ventilation equipment. The management system is operated using electricity generated by itself from the solar cell module. The electricity produced when the energy management system is not in operation can be supplied to a power supply that produces general electricity and can be sold.

In addition, as shown in Figure 2, when the hot water is circulated in the hot water generating unit 2 of the solar cell module 3 to the heat exchanger that operates the third hot water valve 22 or the fourth hot water valve (23). According to the opening, the cooling water supply valve 24 and the cooling water discharge valve 25 to be closed. When the cooling water is supplied to the hot water generating unit from the external water source, the hot water valve 19 is shut off, the cooling water supply valve 24 and the cooling water discharge valve 25 are opened, and the hot water is supplied to the living water. The fourth hot water pump 18 is driven, the driving of the first hot water pump 15 and the second hot water pump 16 is stopped, the hot water valve 19 and the cooling water supply valve 24 are opened, and the coolant is discharged. Shut off valve 25.

In addition, as shown in Figure 4, the first heat exchanger 7 for producing warm air using the hot water stored in the hot water storage tank is installed a radiator (7b) inside the housing (7a) and a blowing fan on one side of the housing (7a) 7c is provided, and a discharge port 7d is installed at the other side of the housing to supply hot water generated in the hot water generating unit of the solar cell module to the radiator 7b and to perform heat exchange in the radiator.

In addition, as shown in Figure 5, the second heat exchanger 8 for producing warm air using the hot water stored in the hot water storage tank is a heat exchanger used when the hot water temperature of the hot water storage tank is below a predetermined temperature, the first heat exchange Like the 7, the heater 8e is provided with a heat radiator 8e for exchanging heat by supplying hot water below a predetermined temperature generated by the hot water generating unit in the housing 8b and supplying electricity to one side of the radiator to generate heat. (8a) is installed. And a blower fan (8c) for supplying heat exchange air to the radiator (8e) and the electric heater (8a) is installed on one side of the housing (8b), and the discharge port (8d) is formed on the other side of the housing (8b). Through this structure, the radiator 8e is first warmed, and the first warmed warm air is further warmed while passing through the electric heater 8a to be supplied to the warm air supply unit 9.

As shown in FIG. 6, the hot air supply unit 9 is installed on the ceiling of a fire station garage and has a hot air supply fan (not shown), and the first air exchanger produces hot air produced by the first heat exchanger 7 on one side. The first conduit (9a) supplied through the discharge port (7d) installed in the machine (7) is connected, and the hot air produced in the second heat exchanger (8) is discharged (8d) installed in the second heat exchanger (7) Connect the second conduit (9b) supplied through, and to connect the third conduit (9d) is formed a plurality of connecting ports (9c) on the other side.

As shown in FIG. 7, the long air duct 9e having a long length is attached to the connection port 9c of the third conduit 9d. Each of the hot air ducts 9e is provided with an on / off valve 9f that opens or closes the hot air flow paths adjacent to the connection port 9c of the third conduit. In addition, a plurality of hot air discharge ports 9g are formed in each of the hot air ducts 9e at predetermined intervals. The plurality of hot air discharge ports 9g are provided with a drive motor 26b and a removable tube 26 that is stretched and stretched toward a freeze-expected part of the fire truck waiting in the garage.

This is because the fire trucks parked in the fire truck may be different from each other in areas expected to freeze, and the parts of the fire trucks expected to be frozen may be different from each other in the hot air duct as described above. By installing the expansion and contraction of the expansion and contraction of the expansion and contraction by the drive motor, it is possible to supply the warm air to the different parts of the expected freezing according to the type of the vehicle waiting.

In addition, by intensively supplying warm air to the expected part of the fire truck waiting in the fire garage, it is not necessary to heat the entire garage to prevent fire truck freezing, it is possible to save excessive energy use.

When explaining the configuration of the expansion tube 26 in more detail, the expansion tube is formed of a corrugated tube 26a freely stretched, a drive motor 26b is installed at the hot air outlet, and the end of the expansion tube is wired 26d. ), The wire winding device 26c is installed on the shaft of the drive motor, the drive motor is rotated forward or reverse, and the wire 26d is wound or unwound on the winding device, and the expansion and contraction pipe 26 is lifted. The expansion pipe discharge port 26e is brought close to the anticipated freezing area to supply warm air, and when the warm air is not supplied, the expansion pipe discharge port 26e is raised to the hot air discharge port 9g of the hot air duct, and the fire truck passes through the interior of the fire truck. This is done freely.

In addition, the fire garage ventilation system 10 is a facility for discharging the smoke of the fire engine in the fire station, including a fan (not shown), but to install a plurality of at a predetermined interval on the wall of the fire garage. .

The control unit 11 detects the outside temperature, the indoor temperature, and the CO 2 concentration of the fire truck to supply hot water to the fire station, supply hot air to the fire truck, or selectively control the ventilation function of the fire truck.

In more detail, as shown in FIG. 8, the control unit 11 performs the following steps to control the environmentally friendly energy management system of the fire station.

First, a hot air supply control method for supplying warm air to a fire truck waiting in a fire station in the control unit 11 will be described. The outside air temperature is input from the temperature sensor installed outside the firefighting garage, and the hot water temperature stored in the hot water storage tank is input from the temperature sensor installed in the hot water storage tank 6 of the solar cell module 3 and installed inside the firefighting garage. A temperature and CO2 concentration input step of receiving the CO2 concentration in the firefighting garage detected through the CO2 detection sensor; A freezing temperature determination step of determining whether the outside temperature is a temperature at which the freezing of the fire engine is expected based on the received temperature value; A hot water pump driving step of driving the first hot water pump 15 for supplying hot water of the hot water tank to the first heat exchanger 7 or the second heat exchanger 8 when the outside temperature is a temperature at which the fire engine can be frozen; Selectively opening the first hot water valve 20 or the second hot water valve 21 to supply hot water to the first heat exchanger when the hot water temperature of the hot water storage tank is above a predetermined temperature and to the second heat exchanger when the hot water temperature is below a predetermined temperature. Hot water valve opening step; A warm air supply step of supplying warm air generated by the first heat exchanger 7 or the second heat exchanger 8 to the expansion pipe 26 by driving a warm air supply fan; According to the type of the vehicle waiting in the fire garage, the control including the expansion pipe driving step for lowering the expansion pipe to be close to the expected region. Through this step, the warm air is produced from the heat source and the current generated in the solar cell module, and the fire engine is to be intensively supplied to the site where the freezing of the fire engine is expected.

Subsequently, the hot water supply method for supplying the hot water for living used in the fire department, when the outside air temperature is determined to be higher than the temperature at which the freezing of the fire engine is expected in the freezing temperature determination step of the hot air supply method, stops driving of the first hot water pump 15. A first hot water pump stopping step of stopping the hot air production; The fourth hot water pump 18 is operated to control the water supply step of supplying hot water from the hot water storage tank 6 to the living water. Through this method, the hot water generated in the solar cell module can be used as living water for fire department workers.

In addition, the ventilation facility in the firefighting garage may further include a ventilation facility driving step of driving the ventilation fan when the CO2 concentration is detected at a predetermined value or more in the temperature and CO2 concentration input step S1.

In addition, the supply method of electricity generated in the solar cell module, as shown in Figure 9, the charging step of charging the storage battery (4) the electricity generated in the solar cell module (3); A power conversion step of converting direct current into alternating current by supplying electricity charged in the battery to the power conversion unit 5; A power supply step of supplying the converted electricity to power of a driving motor for driving a solar cell module, a hot water pump, a valve, a hot air supply fan, a ventilation fan, and a expansion tube included in an energy management system; In the freezing temperature determination step, it is determined that the outdoor air temperature is expected to be frozen in the fire engine, and the second hot water valve 21 is opened because the hot water temperature of the hot water storage tank 6 is below a predetermined temperature through the hot water valve opening step. The electric heater operation step of supplying the converted electricity to the electric heater of the second heat exchanger (8) to operate the electric heater; In the case of not supplying power to the energy management system, the generated electricity is supplied to the electricity supplier to control the electricity sales including selling electricity. Through these steps, the present invention operates the energy management system of the present invention with electricity produced by the solar cell module, or sells the electricity produced when the electricity is not supplied to the energy management system while operating the energy management system in an environmentally friendly manner. The economically viable effect is generated.

1: solar cell plaque 2: hot water generator
3: solar cell module 4: storage battery
5: power conversion unit 6: hot water storage tank
7: first heat exchanger 8: second heat exchanger
9: hot air supply unit 10: ventilation equipment
11 control unit 12 first rotation motor
13: 2nd rotation motor 15: 1st hot water pump
16: second hot water pump 17: third hot water pump
18: fourth hot water pump 19: hot water valve
20: first hot water valve 21: second hot water valve
22: third hot water valve 23: fourth hot water valve
24: cooling water supply valve 25: cooling water discharge valve
26: new building

Claims (7)

In the fire department energy management system,
Installed on the roof of the fire station, the solar panel and the rear of the solar panel to circulate the cooling water to form a hot water generating unit for cooling the solar panel, the angle of the motor to track the movement of the sun to adjust the light reception angle A module;
A storage battery for charging electricity produced from the solar cell module;
A power converter converting the direct current of the battery into alternating current;
A hot water storage tank storing hot water heated by the hot water generating unit of the solar cell module;
A first heat exchanger circulating hot water stored in the hot water storage tank to produce warm air;
A second heat exchanger configured to generate warm air by receiving electricity from the power converter;
A warm air supply unit for supplying warm air produced by the first heat exchanger and / or the second heat exchanger to the fire station;
A ventilation system for discharging the fumes of the fire station;
Fire station eco-friendly energy, comprising a control unit that detects the outside temperature and the indoor temperature and CO2 concentration of the fire station to supply hot water to the fire station, supply warm air to the fire engine, or selectively control the ventilation function of the fire station Management system. The method of claim 1,
The electricity produced by the solar cell module and converted into alternating current in the power conversion unit drives a power supply for driving first and second rotating motors for adjusting the rotation angle of the solar cell module, and a pump for supplying or circulating water for hot water generation. Energy management system with electricity generated from solar cell module by supplying power to power supply, power of electric heater to produce warm air, blower fan to supply warm air, power of lifting motor to raise and lower the expansion pipe, and power to drive ventilation equipment. If the operation, and does not supply electricity to the energy management system, the fire station eco-friendly energy management system, characterized in that the electricity is sold to a general power supply. The method of claim 1,
The hot water stored in the hot water storage tank is supplied to the first heat exchanger to produce warm air through the driving of the first hot water pump,
If the temperature of the hot water stored in the hot water storage tank is below a certain temperature difficult to produce hot air, it is supplied to the second heat exchanger,
The hot water cooled through heat exchange in the first and second heat exchangers is circulated and supplied to the hot water generating unit of the solar cell module through the second hot water pump, or when the temperature of the solar panel exceeds 60 ° C. for a predetermined time or more, an external water supply source. Fire department eco-friendly energy management system, characterized in that the supply and discharge from. The method of claim 3,
The hot air supply unit connects the first conduit receiving the warm air produced by the first heat exchanger and the second conduit receiving the warm air from the second heat exchanger, and a third conduit having a plurality of connection ports formed on the other side thereof. The length of the hot air duct is respectively installed at the connection port of the third conduit, and each of the hot air ducts is provided with an on / off valve for opening or blocking a hot air flow passage adjacent to the connection port of the third conduit. A plurality of hot air discharge openings are formed at regular intervals, and the hot air discharge openings are eco-friendly energy management system for a fire station, which includes detachably installing a new expansion tube that is stretched toward a freezing region of a driving motor and a fire engine. The method of claim 1,
The control unit receives an outside air temperature from a temperature sensor installed outside the fire station, receives a hot water temperature stored in the hot water storage tank from a temperature sensor installed in the hot water storage tank of the solar cell module, and detects CO 2 installed in the fire garage. A temperature and CO2 concentration input step of receiving CO2 concentration in the fire station detected by the sensor;
A freezing temperature determination step of determining whether the outside temperature is a temperature at which the freezing of the fire engine is expected based on the received temperature value;
A hot water pump driving step of driving a first hot water pump for supplying hot water from a hot water tank to a first heat exchange or a second heat exchanger when the outside temperature is a temperature at which the fire engine can be frozen;
A hot water valve opening step of selectively opening the first hot water valve or the second hot water valve to supply hot water to the first heat exchanger if the hot water temperature of the hot water storage tank is equal to or higher than a predetermined temperature, and to the second heat exchanger if the hot water temperature is lower than the predetermined temperature;
A warm air supply step of supplying warm air generated by the first heat exchanger or the second heat exchanger to the expansion pipe by driving the warm air supply fan;
Fire station eco-friendly energy management system comprising the step of controlling the expansion pipe including the step of lowering the expansion pipe so as to approach the area expected to freeze according to the type of vehicles waiting in the fire station. 6. The method of claim 5,
The control unit
Subsequently, if it is determined in the freezing temperature determination step that the outside air temperature is equal to or higher than a temperature at which the fire truck is expected to freeze, stopping the driving of the first hot water pump to stop the production of warm air;
Fire station eco-friendly energy management system, characterized in that further comprising the step of controlling the water supply step of operating the fourth hot water pump to supply hot water from the hot water storage tank to the domestic water. The method according to claim 6,
The control unit is a charging step of charging the storage battery with electricity generated in the solar cell module; A power conversion step of converting direct current into alternating current by supplying electricity charged in the battery to the power conversion device;
A power supply step of supplying the converted electricity to power of a driving motor for driving a solar cell module, a hot water pump, a valve, a hot air supply fan, a ventilation fan, and a expansion tube included in an energy management system;
In the freezing temperature determination step, it is determined that the outdoor air temperature is expected to be frozen in the fire engine, and when the second hot water valve is opened because the hot water temperature of the hot water storage tank is below a predetermined temperature through the hot water valve opening step, the converted electricity is removed. An electric heater operating step of supplying an electric heater of the two heat exchangers to operate the electric heater;
When not supplying power to the energy management system, the fire station eco-friendly energy management system, characterized in that further comprising controlling the electricity sales step of selling electricity by supplying the electricity produced to the electricity supplier.

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