KR20210097261A - Energy supply system for electric-car charging station - Google Patents

Abstract

The present invention relates to an energy supply system for an electric vehicle charging station which can efficiently manage and maintain energy by using weather information. More specifically, the energy supply system for an electric vehicle charging station comprises: system power supplying power to an electric vehicle charger provided on an electric vehicle charging station; a gas generator producing electricity through a gas engine to supply power to the electric vehicle charger or store generated power in an energy storage device provided on the electric vehicle charging station; a photovoltaic power generation means supplying power to the electric vehicle charger through photovoltaic power generation or storing generated power in the energy storage device; the energy storage device receiving and storing spare power produced by the gas generator and the photovoltaic power generation means, and supplying power to the electric vehicle charger during a peak load of the system power supplied to the electric vehicle charging station; a heat pump linked to the gas generator to be operated and produce cold/hot heat to supply cold/hot heat for cooling/heating to a facility of the electric vehicle charging station or surrounding shopping malls and houses; an energy management system (EMS) controlling maintenance and management and power charging supplied to the energy storage device and the electric vehicle charger by the system power, the gas generator, and the photovoltaic power generation means, and supply/storage of cold/hot heat produced by the heat pump through operation control of the gas generator; and a weather information collection device installed near the electric vehicle charging station or integrated into the energy management system to manage power stored in the energy storage device based on collected weather information.

Description

Electric vehicle charging station energy supply system {Energy supply system for electric-car charging station}

The present invention relates to an electric vehicle charging station energy supply system, and more particularly, using commercial electric power as well as electric power produced by solar power generation and gas generators as electric vehicle charging station supply power, and an energy storage device based on predicted weather information It relates to an electric vehicle charging station energy supply system configured to enable efficient energy use by controlling the use/charging of electric power stored in the .

The importance of the use of alternative energy is being emphasized as the environmental pollution of the earth has reached a serious level due to the excessive use of fossil fuels, the increase of automobiles and population, and the expansion of industrial facilities.

In particular, automobiles, which are transportation means that determine the quality of human life, and power plants that produce electricity are mostly powered by fossil fuels to drive vehicles or produce electricity.

Therefore, many studies are being made on the use of eco-friendly renewable energy as a means to reduce the use of fossil fuels and replace fossil fuels used in automobiles and power plants, and in recent years, as it enters the commercialization stage, it replaces the conventional fossil fuel use. is currently doing.

The technical field of the present invention relates to the efficient use and power of electric vehicle charging stations while reducing the use of commercial power by using renewable energy as supply power for electric vehicle charging stations necessary for the operation of electric vehicles developed to reduce environmental pollution caused by the increase in automobiles. It is related to the energy supply system of the electric vehicle charging station to efficiently utilize the additional energy generated during production.

Unlike general vehicles, electric vehicles are configured to drive the power system using electricity stored in the battery, so they are equipped with a battery that can supply electricity necessary for vehicle operation, and the amount of charge in the vehicle’s battery is the vehicle’s mileage. will depend on

However, due to the technical limitations of batteries and the limitations of the vehicle's battery loading capacity, electric vehicles have a shorter mileage compared to general vehicles, so there is an inconvenience of having to recharge the consumed electricity of the battery from time to time.

In addition, since it takes more time to charge the battery of an electric vehicle compared to a conventional vehicle, a technology for charging electricity is very important.

Currently, electric vehicle charging stations required for electric vehicle operation are charged using general commercial power, so the use of commercial electric power increases with the increase of electric vehicles. As the operation of thermal power plants increases, the contradiction arises that the emission gas that pollutes the atmospheric environment increases rather than the increase in the operation of thermal power plants. There is a problem that the power supply may be disrupted due to insufficient power supply.

Therefore, as the number of electric vehicles increases, it is essential to install an electric vehicle charging station so that drivers who operate electric vehicles can easily charge anywhere. However, since the use of commercial power increases with the increase of electric vehicle charging stations, it is necessary to efficiently use the overall commercial power.

In particular, recognizing the need for a means to safely charge an electric vehicle while reducing the use of commercial electric power when a peak load of commercial electric power occurs, securing electric vehicle charging power using renewable energy is suggested as an alternative.

As an example, in Patent Registration No. 10-1245647, “battery fast charging system through linkage with solar power generation system”, it is possible to rapidly charge the battery by receiving maximum power not only from commercial power but also from the solar system. Systems have been known to do so.

In another embodiment, the “solar power generation device-linked power supply system” of Patent Registration No. 10-1775957 is proposed, which uses a household load in using the power generated in connection with the photovoltaic device to charge an electric vehicle. An invention has been devised to shorten the charging time of an electric vehicle and to efficiently use the stored energy by selectively using the AC charging mode and the DC charging mode using the energy stored in the battery. .

As another embodiment, "Electric vehicle charging station equipped with fuel cell system, charger and control method thereof" of Patent Registration No. 10-0963529 was devised, and in order to cover the load of grid power by intensive charging of electric vehicles, An invention for supplying auxiliary power using an equipped fuel cell generator has also been known.

As another embodiment, the “electric vehicle charging device using natural energy” of Patent Registration No. 10-1261165 is proposed, and a solar cell and wind power generating electricity using natural energy, that is, solar energy, wind energy, and hydraulic energy A charging device has been proposed that allows electric vehicles to be charged using energy obtained through generators and hydroelectric generators, so that electric vehicles can be charged using electric power generated from natural energy in places where charging stations are difficult to install. .

As such, in order to reduce or replace the load of the conventional grid power, various technologies have been devised to produce power using various new and renewable energy and to use the generated power for charging an electric vehicle.

However, these conventional electric vehicle charging systems using various new and renewable energies or devices thereof generate electric power only for the purpose of reducing the load on the grid power, and in addition to the one purpose of charging electric vehicles, these energy generation and use devices There was a disadvantage in that there was no way to utilize another energy generated from the .

In addition, the power supply of electric vehicle charging stations using alternative energy devised in the past is only proposed as a means of replacing commercial power, so the efficiency of use of the production power of alternative energy that is sensitive to external weather changes is high. There was a downside.

- Patent Registration No. 10-1245647 (Registration Date: March 14, 2013) - Patent Registration No. 10-1775957 (Registration Date: 2017.09.01) - Patent Registration No. 10-0963529 (Registration Date: 2010.06.07)

The present invention avoids the peak load of commercial power through efficient control of generated power using alternative energy that is additionally provided in addition to commercial power, and reduces the use of additional commercial power through the use of byproducts generated during power generation using alternative energy. It aims to provide an electric vehicle charging station energy supply system that enables efficient management and maintenance of energy using weather information.

In order to achieve the above object, an electric vehicle charging station energy supply system according to the present invention includes a grid power for supplying power to an electric vehicle charger provided in an electric vehicle charging station; a gas generator for producing electricity through a gas engine and supplying power to the electric vehicle charger or storing electric power generated by an energy storage device provided in an electric vehicle charging station; photovoltaic power generation means for supplying power to the electric vehicle charger through photovoltaic power generation or storing power generated by an energy storage device; an energy storage device that receives and stores the excess power produced by the gas generator and the solar power generation means, and supplies power to the electric vehicle charger during a peak load of grid power supplied to the electric vehicle charger; a heat pump configured to produce cold/hot heat while operating in connection with the gas generator to supply cool/hot heat for cooling/heating to facilities of electric vehicle charging stations, surrounding factories, houses, etc.; Energy to control the supply/storage of hot/cold heat produced by the heat pump through power storage and maintenance from the grid power and gas generator and solar power generation means to an electric vehicle charger and energy storage device, and operation control of the gas generator management system (EMS); A meteorological information collecting device installed near an electric vehicle charging station or integrally configured with the energy management system to collect weather information, and to manage the power stored in the energy storage device based on the collected weather information.

In addition, a cold/hot water storage tank that stores cold/hot water using the cold/hot heat produced by the heat pump, and the cold water stored in the cold/hot water storage tank is supplied to cool the high heat generated during the power generation of the solar power generation means. Solar module cooling means for circulating cooling water to the module is further provided.

In addition, in the energy management system, whether to use grid power as power supplied to the electric vehicle charger according to the electric vehicle charging power demand input from the electric vehicle charger, or to use the electric power stored in the energy storage device, or to produce through the operation of a gas generator A charger supply power selection unit that selects whether to use the obtained power, and according to the determination of the charger supply power selection unit, the electricity produced by the gas generator is stored in an energy storage device or supplied to an electric vehicle charger, and to the energy storage device A power supply control unit that controls and manages supplying the stored power to the electric vehicle charger or supplying grid power to the electric vehicle charger, and storing the grid electric power and the electric power produced by the solar power generation means and the gas generator in an energy storage device or energy storage A power conversion unit that converts the power stored in the device into power required for charging the electric vehicle and controls it to be supplied, and the power supplied from grid power to the electric vehicle charger by monitoring the peak load of the grid power in real time when the grid power is supplied to the electric vehicle charger a system power control and management unit for controlling the temperature; Based on the next-day weather information output from the weather information prediction determining unit, the power storage state stored in the energy storage device is monitored in real time, and the power generated by the gas generator and photovoltaic power generation means is converted into additional power storage or power use of other devices. An energy storage device charging management unit that manages the sale of electricity stored by electric power, the overall control of the respective units, temperature and supply control of cold and hot water stored in the cold and hot water storage tank, temperature sensing of the solar module and the detected temperature state Accordingly, an integrated control unit for controlling the operation of the solar module cooling means, identifying the temperature state of the cold/hot water storage tank according to the cooling/warming demand, and controlling the operation of the gas generator and the heat pump;

In addition, the integrated control unit includes a cold/hot water management unit that controls the supply of cold and hot water in the cold and hot water storage tank according to the temperature management of the cold and hot water stored in the cold and hot water storage tank and the heating and cooling demand of the facility, and the temperature of the solar module when the solar power generation means is operated A photovoltaic module cooling management unit that monitors and controls the operation of the photovoltaic module cooling means when the temperature is higher than the set reference temperature, the total amount of power produced by the gas generator and the photovoltaic power generation means, and the amount of power stored in the energy storage device, each It consists of a configuration that further includes; a display unit that provides the manager with related information by expressing the operating state and the failure state of the part.

In addition, the meteorological information collected by the weather information collection device consists of at least one of weather information measured by a weather sensor installed near an electric vehicle charging station, weather information forecasted by the Korea Meteorological Administration, and weather information predicted by an AI weather forecasting system. Preferably, the weather sensor is an integrated weather sensor in which an air volume anemometer, a thermometer, a hygrometer, a solar radiation sensor, and a rain gauge are integrally configured to form a single unit rate.

Electric vehicle charging station energy supply system according to the present invention As described above, the most economical power is supplied to the charging station for charging electric vehicles, and the heat generated from the gas generator can be used as a heat source for cooling or heating, thereby reducing the use of grid power. let it be

In addition, the present invention allows the electric power produced through the gas generator and the solar power generation means to be used for charging the electric vehicle in addition to the grid electric power, so that the problem of electric power supply and demand does not occur during the peak load of the grid electric power, and the electric vehicle charging is smoothly performed make it happen

In addition, the present invention enables the cooling of the photovoltaic means by using the cooling water stored in the cold and hot water storage tank when high heat that reduces the power generation efficiency of the photovoltaic means is generated, thereby further improving the power generation efficiency of the photovoltaic means.

In addition, the present invention makes it possible to efficiently supply electric power to an electric vehicle charger by ensuring sufficient amount of electric power to be used the next day and efficiently managing electric power based on the weather forecast information generated through the meteorological information collecting device.

1 is an overall conceptual diagram of an electric vehicle charging station energy supply system according to the present invention;
2 is a block diagram of a main configuration of an energy management system in an electric vehicle charging station energy supply system according to the present invention;
3 is a block diagram simply showing the power supply flow in the electric vehicle charging station energy supply system according to the present invention;
4 is a flowchart simply illustrating a process in which charging is performed through an electric vehicle charger.

The electric vehicle charging energy supply system according to an embodiment of the present invention uses one or more electric power production means using renewable energy as a means for supplying electric power required for electric vehicle charging. It is configured so that the power stored in the energy storage device can be used in consideration of the peak load time, etc. In particular, the charge/discharge state of the power stored in the energy storage device can be controlled based on the weather forecast data obtained through the weather information collection device. It has structured features.

To this end, in the electric vehicle charging energy supply system according to an embodiment of the present invention, as a means for supplying electric power to an electric vehicle charger, grid power, which is commercial power, and electricity are produced through a gas engine to supply electric power to the electric vehicle charger or energy storage. A gas generator for storing electric power generated by the device, and a photovoltaic power generation means for supplying electric power generated through photovoltaic power generation to the electric vehicle charger or storing power with the energy storage device are provided.

In addition, an energy storage device for receiving and storing the excess power produced by the gas generator and the solar power generation means, and supplying power to the electric vehicle charger at a peak load of the grid power supplied to the electric vehicle charging station, and the gas generator A heat pump configured to produce cold/hot heat in connection with the electric vehicle charging station or to supply cold/hot heat required for heating and cooling to facilities of the electric vehicle charging station, nearby offices, houses, factories, etc. is provided.

In addition, in the electric vehicle charging energy supply system according to an embodiment of the present invention, the electric power charging and maintenance supplied from the grid power, the gas generator and the solar power generation means to the electric vehicle charger and energy storage device, and the operation control of the heat pump are performed. An energy management system (EMS) is provided that controls the supply of hot/cold heat produced by the heat pump and the resale of excess power.

In addition, it is installed in the vicinity of the electric vehicle charging station or is integrally configured with the energy management system to further include a meteorological information collecting device for managing the power stored in the energy storage device based on the collected weather information.

The terms used in the detailed description of the present invention use general terms and terms arbitrarily selected by the applicant in consideration of the functions of the present invention, and in this case, the meaning of the terms is defined based on the content throughout the present invention do.

In addition, when a part "includes" a certain component in the detailed description, this means that other components may be further included, rather than excluding other components, unless specifically stated to the contrary.

In addition, terms such as "means", "unit", "module", "device" and the like described in the specification mean a unit that processes at least one function or operation, which is implemented as hardware or software, or a combination of hardware and software. can be implemented as

In addition, when it is said that a part is "connected" or "connected" with another part throughout the specification, it is not only "directly connected" but also indirectly connected "with another element in the middle". It is interpreted as meaning including a state in which power transmission/distribution and data transmission/reception are possible.

In addition, not only the weather sensors installed near the “weather information” charging station referred to in the present invention, but also the weather forecast information provided by the local meteorological office, etc. It refers to weather information that predicts a state, and such weather information is automatically calculated by hardware and software such as various sensors and computers, and is configured to extract weather data.

In addition, since the electric vehicle charging station energy supply system according to the embodiment of the present invention is configured the same as the main configuration of the applicant's prior patent application No. 10-201934734 (hereinafter referred to as the "previous application"), in the present specification, Description of the described configuration will be omitted or briefly mentioned as much as possible.

Hereinafter, the configuration and operation of each part of the electric vehicle charging station energy supply system according to the present invention will be described in detail with reference to the accompanying drawings.

1 shows an overall conceptual diagram of an electric vehicle charging station energy supply system 100 (hereinafter, abbreviated as “energy supply system”) according to the present invention.

1, the power supply means of the energy supply system 100 according to the embodiment of the present invention is a system power 10 used as basic power, and a gas generator 50 that produces electricity through a gas engine. ) and the solar power generation means 30 for generating electricity through solar power generation are configured.

In addition, the energy storage device 90 for storing the electric power produced by the gas generator 50 and the solar power generation means 30, and a heat pump that is operated in connection with the gas generator 50 to produce cold/warm heat (60), and charging and maintenance of the electric power supplied from the grid power 10, the gas generator 50 and the solar power generation means 30 to the electric vehicle charger and the energy storage device 90, and the heat pump ( 60), the energy management system (EMS, 80) that controls the supply of hot/cold heat produced by the heat pump 60 through the operation control and the energy storage device ( 90) is configured to include a meteorological information collecting device 20 to increase the utility of the electric power stored in the device.

In addition, a cold/hot water storage tank 70 for generating/storing cold/hot water using the cold/hot heat produced by the heat pump 60, and the cold water stored in the cold/hot water storage tank 70 are supplied to the solar power generation means 30 ), a solar module cooling means 40 for circulating cooling water to the solar module to cool the high heat generated during power generation is further provided.

In more detail about the above-mentioned main configuration, the grid power is supplied as basic power of a charging station equipped with an electric vehicle charger, but it is possible to reduce the use of grid power through the use of new and renewable energy or to use alternative power at peak load. is configured to

The power supply source produced by renewable energy or alternative energy used in the present invention uses the gas generator 50 and the photovoltaic power generation means 30 .

The gas generator 50 is the same as the contents described in the previous application of the present applicant, and thus the description thereof will be simplified in the detailed description of the present invention.

The gas generator 50 is configured to minimize air pollution by using natural gas as a raw material, and generates electric power while the generator rotates through the rotation of the engine. The gas engine has a maximum output of 44kW/1,800rpm, a rated output With a 34kWe/1,800rpm class, it is composed of a four-cylinder engine and is configured to drive a generator.

In addition, the generator is configured to have a target output of 30kWe/380V, 60Hz, a double stator method, a rated output of 47.8kAV (38.2kWe), and an efficiency of 90.9% (p.f 1.0) to produce electricity.

In addition, the gas generator 50 is integrally configured with a heat pump 60 to produce cold/hot heat during operation of the gas generator and store it in the cold/hot water tank 70 to cool the cold/hot water stored in the cold/hot water tank to the surrounding facilities. It is constructed so that it can be supplied for poor use.

The cold/hot water storage tank 70 is configured so that a certain amount of cold water/hot water is produced and stored through the cold/hot heat produced by the heat pump. It is configured to be used as a heat source, so that the use of commercial power can be minimized when heating and cooling surrounding facilities.

In addition, the temperature of the cold and hot water stored in the cold and hot water storage tank 70 is grasped in real time through the control of the energy management system 80, and the operation of the gas generator 50 and the heat pump 60 is configured to be controlled.

And, the cold water stored in the cold and hot water storage tank 70 is operated by the solar module cooling means 40 through the control of the energy management system 80 according to the temperature rise of the solar modules constituting the photovoltaic power generation means 30 . It is configured to cool the photovoltaic module in a high temperature state while being circulated to the bottom surface of the photovoltaic module to prevent deterioration of the power generation performance of the photovoltaic module.

The solar module cooling means 40 for operating the circulation of cold water to the bottom of the solar module can be easily implemented by those skilled in the art using various types of known cooling structures or cooling systems, so a detailed description thereof will be omitted.

And, the meteorological information collecting device 20, which is a feature of the present invention, is information collected from a meteorological measurement device including one or more weather sensors capable of measuring the weather conditions around the charging station in real time or provided by a local meteorological station or online. It includes weather information obtained through an AI-based weather forecasting system.

The information collected by the meteorological information collecting device 20 is used as data for predicting the next day's weather conditions, and the collected weather information is stored in energy based on the weather forecast contents predicted through the weather information prediction and judgment unit provided in the energy management system. It is configured to manage the amount of power stored in the device.

It is preferable that the meteorological measuring device installed near the charging station is an integrated weather measuring device in which an air volume anemometer, a thermometer, a hygrometer, a solar radiation sensor, a rain gauge, etc. are integrally constituted to form a single unit rate.

Meanwhile, FIG. 2 shows a simple block diagram of the main configuration of the above-described energy management system.

The block diagram shown in FIG. 2 is an excerpt of the minimum main configuration required for the operation of the energy supply system according to the present invention. In addition to the configuration shown in the drawing, detailed configurations may be added or various functions may be added depending on the structure of the function or device. It can be subdivided into parts.

In addition, each configuration shown in the block diagram of FIG. 2 may be understood as a concept of integrally controlling various functions and operations as well as a meaning of performing an independent function or operation.

As shown in the figure, the energy supply system 80 controls the power supplied to the electric vehicle charger 200 as well as the power generated by the solar power generation means 30 and the gas generator 50, which are renewable energy. It is configured to be supplied to the electric vehicle charger 200 by using it, or to control and manage overall power production and supply such as power storage and output to the energy storage device 90 .

In addition, based on the control of the supply of cold/hot heat necessary for the sale of power stored in the energy storage device 90 or the supply of cold/hot heat required for cooling and heating of facilities, control of the supply of cooling water required for cooling the solar power generation means 30 and weather forecast information Controls overall control necessary for the use/storage of electric power stored in the energy storage device 90 .

In more detail, the energy supply system 80 includes a charger supply power selection unit 820 that selects which power to use as a power source supplied to the charger, and a plurality of power sources according to the determination of the charger supply power selection unit. A power supply control unit 83 that controls so that power is supplied to the electric charger as a selected power source, and a power conversion unit 840 that appropriately converts power input from a plurality of power sources into power used by an energy storage device or an electric vehicle charger. And, the grid power control management unit 850 for monitoring and controlling the grid power supplied to the electric vehicle charger, the energy storage device charging management unit 870 for managing the state of charge of the energy storage device, and the overall control of each unit. It consists of a configuration including the integrated control unit (810).

The charger supply power selection unit 820 determines whether to use the grid power as the power supplied to the electric vehicle charger according to the power demand for electric vehicle charging input from the electric vehicle charger 200, that is, fast charging, slow charging, charging power demand, etc. Otherwise, it is decided whether to use the power stored in the energy storage device or the power generated through the operation of the gas generator.

In addition, the charger supply power selection unit 820 is linked to the grid power control and management unit 850 to be described later and automatically stores the power stored in the energy storage device when the peak load of the grid power occurs, as well as the solar power generation means and the gas generator. It is configured so that automatic selection is made so that the power produced by the electric vehicle can be supplied to the electric vehicle charger and facility side.

In addition, the power supply control unit 830 determines whether the electric power produced by the gas generator is stored in an energy storage device or directly supplied to the electric vehicle charger according to the determination of the charger supply power selection unit 820. It is determined whether to supply the electric power stored in the energy storage device to the electric vehicle charger.

Of course, the factor determining which power to supply power to the electric vehicle charger by the power supply control unit is automatically determined in consideration of the state of charge of the energy storage device or the load state of system power according to a set program.

In addition, the power conversion unit 840 stores the power produced by the grid power 10 and the solar power generation means 30 and the gas generator 50 in the energy storage device 90 or in the energy storage device 90 . The stored power is converted into power required for charging the electric vehicle and controlled to be supplied.

The power conversion unit 840 is commonly used in the sense of collectively used inverters and converters power conversion elements, which take into account the power produced by the power generating means and the storage performance of the battery, products of various standards may be used. can

In addition, the grid power control management unit 850 monitors the load state of the incoming grid power when the electric power of the grid power 10 is supplied to the electric vehicle charger 200 in real time to cut off the grid power in the peak load state, and the energy storage device It is configured to operate in conjunction with the charger supply power selection unit 820 so that the electric power stored in the battery or the electric power produced by the photovoltaic power generation or gas generator is supplied to the electric vehicle charger or facility side, and is controlled to be supplied as grid power when excess power is generated. do.

In addition, the weather information prediction determination unit 860 determines the next day's weather conditions based on the actual weather data collected through the execution of a weather prediction program set based on the weather information collected from the weather information collection device and the weather information collected from the outside. designed to predict.

The weather information prediction determination unit 860 generates new weather data through a program set using important factors acting as meteorological factors to predict the next day's weather conditions or to be forecasted by a reliable meteorological observation institution such as the Meteorological Administration. It is configured to predict and judge the weather condition of the next day by citing the weather data as it is.

In addition, the energy storage device charge management unit 870 monitors the power storage state stored in the energy storage device 90 in real time based on the next day weather information output from the weather information prediction and determination unit 860 to connect the gas generator 50 with the gas generator 50 . It performs a function of storing the power produced by the photovoltaic power generation means 30 in an additional battery, converting the spare power to be used as power of other devices, or managing the sale of the spare power through the grid power line. will do

In addition, the integrated control unit 810 controls not only the overall control of each part, but also monitors the temperature of the cold and hot water stored in the cold and hot water storage tank 70 and controls the cooling/hot heat supply, and the temperature sensing of the photovoltaic module and solar power according to the sensed temperature state. Control the operation of the module cooling means 40, grasp the temperature state of the cold/hot water storage tank 70 according to the cooling/heat demand from the facility side, and control the operation of the gas generator 50 and the heat pump 60. Operation control and management will be performed.

In particular, the integrated control unit 810 has a configuration in which a cold/hot water management unit 812 , a solar module cooling management unit 814 , and a display unit 816 are further provided.

The cold/hot water management unit 812 controls and manages the supply of cold/hot heat for maintaining the cold/hot water in the cold/hot water storage tank 70 according to the temperature management of the cold and hot water stored in the cold/hot water storage tank 70 and the demand for heating and cooling of facilities.

In addition, the photovoltaic module cooling management unit 814 monitors the temperature of the photovoltaic module during operation of the photovoltaic power generation means 30 and controls the operation of the photovoltaic module cooling means 40 when the temperature is higher than a set reference temperature. do.

A plurality of photovoltaic modules constituting the photovoltaic power generation means are provided with temperature sensors, respectively, so that the temperature of the photovoltaic module is monitored in real time, and the temperature of the photovoltaic module collected from the temperature sensor is transmitted to the energy management system to transmit the solar Optical module cooling management is performed according to the set program.

In addition, the display unit 816 displays the total amount of power produced by the gas generator 50 and the photovoltaic power generation means 30 and the amount of power stored in the energy storage device 90 , the operating state and failure of each part. The presence or absence status is displayed on the monitor through the control of the set program so that the manager can manage and monitor the overall operation status of the energy supply system.

Meanwhile, FIG. 3 shows a simple block diagram of a power supply relationship between devices in the energy supply system of the present invention having the above-described configuration.

As shown in FIG. 3 , the power produced by the photovoltaic power generation means 30 and the gas generator 50 and the power stored in the energy storage device 90 are the energy management system 80 side power conversion device (eg, DC /DC converter, three-phase inverter, etc.) is supplied to the electric vehicle charger 200, and the spare power is sold through the grid power (10) line.

In addition, the power introduced into the grid power 10 is also introduced into the energy management system 80 to be stored in the energy storage device 90 or directly supplied to the electric vehicle charger 200 to be used for charging the electric vehicle.

As described above, the energy management system 80 includes a PCS, that is, a charger supply power selection unit 820 and a power supply control unit 830 for controlling and managing the power supplied to the charger, so that the charger supply power selection unit 820 is provided. ), depending on the demand for electric vehicle charging power, choose whether to use the grid power as the electric power supplied to the electric vehicle charger, use the electric power stored in the energy storage device, or use the electric power produced through the operation of the gas generator.

In addition, according to the determination of the charger supply power selection unit 820 through the power supply control unit 830, the electricity produced by the gas generator is stored in an energy storage device or supplied to an electric vehicle charger, and the energy storage device The power stored in the battery is supplied to the electric vehicle charger or grid power is supplied to the electric vehicle charger to control charging.

And, FIG. 4 is a flowchart schematically illustrating a process of charging an electric vehicle through a charger of a charging station.

That is, as shown in FIG. 4 , when a charging signal is input from the electric vehicle charger (S10), the energy management system compares the grid power with the power stored in the energy storage device and transmits the available charging power information to the charger for display. (S20).

After confirming the displayed charging power information, the driver of the vehicle selects a vehicle power suitable for his/her vehicle from among the plurality of charging power displayed on the display unit (S30), and after selecting the charging power, whether to perform rapid charging or slow charging A charging method can be selected (S40).

According to the charging method selected by the vehicle driver, the electric charger and energy management system prepare for charging (S50), and the charging voltage, current, cost, etc. of the selected charging power are identified through the control of the energy management system (S60) (S70) , a cost settlement step (S80) of confirming whether the driver will pay the cost required for charging by providing information to the display unit is performed.

When the cost is settled, charging power is supplied to the electric vehicle charger in the method selected by the driver, and the driver connects the charging cable to the vehicle to start charging (S90). When charging is complete, the charging cable is disconnected from the vehicle. By (S100), the charging is completed.

In the detailed description of the present invention, detailed description of the electric vehicle charger is not provided, but the electric vehicle charger is equipped with a display unit of a certain size so that the vehicle driver can charge the electric vehicle according to a series of procedures displayed on the screen. It is natural to be configured to guide.

In addition, the above-described charging procedure is automatically carried out in sequence according to each or a series of procedures according to the program set in the energy management system and the electric vehicle charger, and some of the processes are performed in a certain procedure on the energy management system side, and the remaining The procedure will be performed by the electric vehicle charger side.

10: grid power 20: weather information collecting device
30: solar power generation means 40: solar module cooling means
50: gas generator 60: heat pump
70: cold and hot water storage tank
80: energy management system
810: integrated control unit 812: cold/hot water management unit
814: solar module cooling management unit 816: display unit
820: charger supply power selection unit 830: power supply control unit
840: power conversion unit 850: grid power control management unit
860: weather information prediction judgment unit 870: energy storage device charging management unit
90: energy storage device
100: electric vehicle charging energy supply system
200: electric vehicle charger
300 : office
400 : factory

Claims (5)

grid power 10 for supplying power to the electric vehicle charger 200 provided in the electric vehicle charging station;
a gas generator 50 for producing electricity through a gas engine and supplying power to the electric vehicle charger 200 or storing electric power generated by an energy storage device 90 provided in an electric vehicle charging station;
a solar power generation means 30 for supplying power to the electric vehicle charger 200 through solar power generation or for accumulating power generated by an energy storage device 90;
The gas generator 50 and the solar power generation means 30 receive and store the excess power, and supply power to the electric vehicle charger 200 during a peak load of the grid power supplied to the electric vehicle charger 200 . an energy storage device (90);
a heat pump (60) configured to produce cold/hot heat while operating in connection with the gas generator (50) to supply cooling/heating heat/heat for cooling/heating to facilities of electric vehicle charging stations, nearby factories, houses, etc.;
Power storage and maintenance from the grid power 10 , the gas generator 50 and the solar power generation means 30 to the electric vehicle charger 200 and the energy storage device 90 , and operation control of the gas generator 50 . an energy management system (EMS, 80) for controlling the supply/storage of hot/cold heat produced by the heat pump 60 through
A meteorological information collecting device installed near an electric vehicle charging station or integrally configured with the energy management system 80 to collect weather information and to manage the power stored in the energy storage device 90 based on the collected weather information (20); Electric vehicle charging station energy supply system, characterized in that it comprises. According to claim 1,
A cold/hot water storage tank 70 that stores cold/hot water using the cold/hot heat produced by the heat pump 60, and the cold water stored in the cold/hot water storage tank 70 is supplied to the solar power generation means 30. The electric vehicle charging station energy supply system, characterized in that it further comprises a solar module cooling means (40) for circulating cooling water to the solar module so as to cool the generated high heat. 3. The method of claim 1 or 2,
In the energy management system 80,
Whether to use the grid power as the power supplied to the electric vehicle charger according to the electric vehicle charging demand power requested from the electric vehicle charger or the peak load of the grid power, or the electric power stored in the energy storage device, or the electric power produced through the operation of the gas generator A charger supply power selection unit 820 that selects whether to use and
According to the determination of the charger supply power selection unit, the electric power produced by the gas generator is stored in an energy storage device or supplied to an electric vehicle charger, and the electric power stored in the energy storage apparatus is supplied to an electric vehicle charger or system power is supplied to an electric vehicle charger. A power supply control unit 830 that controls and manages to be supplied to
A power conversion unit 840 that stores the grid power and the power produced by the solar power generation means and the gas generator in an energy storage device or converts the power stored in the energy storage device into power required for charging an electric vehicle and supplies it;
At the peak load of the grid power supplied to the electric vehicle charger, the electric power supplied to the electric vehicle charger is cut off from the grid electric power, and the electric power stored in the energy storage device or the excess electric power produced by the solar power generation or gas generator is supplied as grid electric power. and a grid power control management unit 850 to control the
a weather information prediction determination unit 860 for predicting a weather condition of the next day based on the actual weather data collected through the meteorological information collecting device and the weather information collected from the outside;
Based on the next-day weather information output from the weather information prediction determining unit, the power storage state stored in the energy storage device is monitored in real time, and the power generated by the gas generator and photovoltaic power generation means is converted into additional power storage or power use of other devices. An energy storage device charging management unit 870 that manages the sale of electric power stored by electric power;
The overall control of each part, the temperature and supply control of the cold and hot water stored in the cold and hot water storage tank, the operation control of the solar module cooling means according to the temperature detection of the solar module and the sensed temperature state, An electric vehicle charging station energy management system, characterized in that it comprises a; an integrated control unit (810) for controlling the operation of the gas generator and the heat pump to determine the temperature state. 4. The method of claim 3,
In the integrated control unit 810,
a cold/hot water management unit 812 for controlling the supply of hot and cold water in the cold and hot water storage tank according to the temperature management of the cold and hot water stored in the cold and hot water storage tank and the demand for heating and cooling of facilities;
A photovoltaic module cooling management unit 814 for monitoring the temperature of the photovoltaic module during operation of the photovoltaic power generation means and controlling the operation of the photovoltaic module cooling means when the temperature is higher than a set reference temperature;
A display unit 816 that provides related information to the manager by expressing the total amount of electricity produced by the gas generator and the solar power generation means, the amount of power stored in the energy storage device, the operating state of each part, and the state of failure. Electric vehicle charging station energy supply system, characterized in that consisting of an included configuration. According to claim 1,
The weather information collected by the weather information collection device 20 is at least one of weather information measured by a weather sensor installed near the electric vehicle charging station, weather information forecasted by the Korea Meteorological Administration, and weather information predicted by the AI weather forecasting system. composed,
The weather sensor is an electric vehicle charging station energy supply system, characterized in that it is composed of an integrated weather sensor composed of a single unit rate by integrating an air volume anemometer, a thermometer, a hygrometer, a solar radiation sensor, and a rain gauge.

Images