WO2020256305A1 - Gamified v2g service system and method linking electric rental vehicle and tour course - Google Patents

Abstract

The present invention relates to a gamified V2G service system and method linking an electric rental vehicle and a tour course, the gamified V2G service system and method generating a customized tour course for a user using an electric rental vehicle, and inducing the user to stay at a tourist site for a long period of time by introducing gamification, and, thereby, participating in an electricity trading market by using the electricity supplied from the electric rental vehicle parked at the tourist site.

Description

Gamification V2G service system and method linking electric rental car and sightseeing course

The present invention relates to a gamification V2G service system and method linking an electric rental car and a tour course, and in particular, a tourist destination in which a user participates in V2G service by creating a customized tour course for a user using an electric rental car and introducing gamification. It relates to a gamification V2G service system and method to participate in the power trading market with power supplied from an electric rental car parked in a tourist destination by inducing tourists to tour.

V2G (vehicle to grid) means that the electric vehicle and the power grid transmit power in both directions, and the electric vehicle can be charged according to the charging time and amount of power required by the vehicle owner, and, if necessary, power can be supplied or sold to the power company. It means a system that can.

The supply of electric vehicles is intensively expanding in specific areas, centering on rental cars. Using this trend, it is possible to operate V2G services in connection with local tourist destinations where many rental cars are operated.

Representatively, Jeju Island has high demand for rental cars, and tourist attractions are adequately distributed within the island, and tourists stay in individual tourist destinations for 1 hour for short and 3-4 hours for long.

It is important that many tourists visit each tourist destination and stay for an appropriate time, and it is important for the V2G service operator to park the electric rental car for as long as possible for tourists visiting each tourist destination. Therefore, there is a need for a system that induces many tourists to stay for a long time in tourist destinations participating in V2G service in order to activate V2G service using electric rental car.

The present invention is to solve the above problems, by creating a customized tour course for a user using an electric rental car, and introducing a gamification to induce the user to stay in a tourist destination for a long time, thereby being supplied from an electric rental car parked in a tourist destination. You can participate in the electricity trading market with electricity

In addition, it is possible to induce interest by providing points to users according to participation in the V2G service and inducing competition among participants.

In order to achieve the above object, the gamification V2G service management server according to an embodiment of the present invention is a gamification V2G service management server linking an electric rental car and a tour course, Includes a tourist destination management unit that manages tourist destination information including type, basic parking time and basic point information, a database unit that maps and stores the electric rental car and the user who received the electric rental car, and the desired tourist destination type received from the user terminal. A tour course generation unit that generates at least one tour course according to the user participation information and transmits the tour course and directions information on the tour course to the user terminal, and the electric rental car parked in the tourist site from the tourist site server. A state information collection unit that receives a unique identifier, parking information, and EV available capacity information, provides a point to the user when the electric rental car parked in the tourist destination satisfies the basic parking time of the tourist destination, and provides a point to the user terminal. It may include a gamification management unit that transmits accumulated points, grades, and real-time ranking information, and a power transaction processing unit that participates in the power transaction market with the available EV capacity secured through the electric rental car parked in the tourist destination.

In an embodiment, the user participation information may include a type of tourist destination desired by the user, a tour schedule, and a target point.

In one embodiment, the state information collection unit may predict the future available EV capacity by analyzing the tourism course.

In an embodiment, the power transaction processing unit may determine a power transaction participation time using the EV available capacity prediction information.

In an embodiment, the gamification management unit may provide additional points to the user when the electric rental car parks longer than the basic parking time of the tourist destination.

In an embodiment, the gamification management unit may designate an electric rental car and a group of a friend or family, and provide the group with points of the friend or family summing up.

In an embodiment, the power transaction processing unit may manage a settlement amount to be provided to the tourist destination with profits generated by participating in the power transaction market.

A user terminal according to an embodiment of the present invention, in a user terminal providing a gamification V2G service, receives user participation information including a desired tourist destination type from a communication unit that communicates with a gamification V2G management server. User participation information input unit transmitted to the gamification V2G management server, receiving at least one tourism course generated by analyzing the user participation information from the gamification V2G management server, and receiving from the user during the at least one tourism course A tourism course selection unit that receives a selection of one, a tourism course information unit that receives and outputs directions information for the tourism course selected by the user and the tourism course selected by the user, and the accumulation of the user from the gamification V2G management server It includes a gamification display unit receiving points, grades, and real-time rankings and displaying them on a screen, and the accumulated points are provided by satisfying the basic parking time of the tourist destination by electric rental cars parked in the tourist destination included in the tourist course. Points can be added up.

In the gamification V2G service method according to an embodiment of the present invention, in the gamification V2G service method linking an electric rental car and a tour course, the type of tourist attraction participating in the V2G service, basic parking time, and basic point information are provided. Managing the included tourist destination information, mapping and storing the electric rental car and the user who received the electric rental car, generating at least one tour course according to user participation information including the desired tourist destination type received from the user terminal And, transmitting the tour course and directions information on the tour course to a user terminal, receiving a unique identifier, parking information, and available EV capacity information of the electric rental car parked in the tourist site from the tourist site terminal, When the electric rental car parked in the tourist destination satisfies the basic parking time of the tourist destination, providing points to a user account, transmitting accumulated points, grades, and real-time ranking information of the user to the user terminal, and to the tourist destination It may include the step of participating in the power trading market with the available EV capacity secured through the parked electric rental car.

The gamification V2G service system according to an embodiment of the present invention is a gamification V2G service system that links an electric rental car and a tourist course, in which a two-way charger installed in a parking lot of a tourist destination is connected to the electric rental car. At least one tourist destination server that charges and discharges electric power in both directions and manages at least one of a unique identifier of the electric rental car, a parking situation, and an available EV capacity, and maps and stores the electric rental car and the user who received the electric rental car. , After transmitting at least one tourist course to the user terminal, receiving at least one of the unique identifier of the at least one electric rental car parked in the parking lot, the parking situation, and the available EV capacity from the tourist destination server, and the electric rental car at the tourist destination Parking is provided to provide points to the user who satisfies the basic parking time of the tourist destination, and transmits the user's accumulated points, grades, and real-time ranking to the user terminal, while electric power with the available EV capacity of the electric rental car parked in the tourist destination Selecting one of the at least one tourism course received from the gamification V2G service management server participating in the trading market and the gamification V2G service management server, and outputting directions information for the selected tourism course, It may include a user terminal that displays the accumulated points, grades, and real-time rankings of users according to participation in the V2G service.

The gamification V2G service system and method linking the electric rental car and the tour course according to the embodiment of the present invention as described above can induce users to participate in the V2G service, thereby obtaining profits through power transactions.

In addition, the gamification V2G service system and method linking an electric rental car and a tour course according to an embodiment of the present invention may induce interest of a user by providing a customized tour course to a user and inducing competition among participants.

In addition, the gamification V2G service system and method linking an electric rental car and a tour course according to an embodiment of the present invention may provide a point according to participation in the V2G service to a user, so that the user can obtain a benefit for the point.

1 is a diagram schematically illustrating a network relationship of a gamification V2G service system linking an electric rental car and a tour course according to an embodiment of the present invention.

2 is a block diagram showing the configuration of a gamification V2G service management server according to an embodiment of the present invention.

3 is a diagram illustrating a method for a gamification V2G service management server to provide points to a user according to an embodiment of the present invention.

4 is a block diagram showing the configuration of a terminal according to an embodiment of the present invention.

5 to 7 are diagrams for explaining information output to a user terminal according to an embodiment of the present invention.

8 is a flowchart illustrating a gamification V2G service management method performed by a gamification V2G service management server according to an embodiment of the present invention.

9 is a flowchart illustrating a power transaction method performed by a gamification V2G service management server according to an embodiment of the present invention.

10 is a flowchart illustrating a gamification V2G service method performed by a user terminal according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to clarify the technical idea of the present invention. In describing the present invention, when it is determined that a detailed description of a related known function or component may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. Constituent elements having substantially the same functional configuration among the drawings are assigned the same reference numerals and reference numerals as much as possible, even if they are indicated on different drawings. If necessary for convenience of explanation, the device and the method will be described together.

FIG. 1 is a diagram showing a virtual power plant operating system for participation of small and medium-sized companies in an industrial complex microgrid according to an embodiment of the present invention.

Referring to FIG. 1, the virtual power plant operating system 1000 may include a virtual power plant operating server 100, a RE100 management server 200, at least one renewable power generation resource 300, and a RE100 participating company 400. have.

The virtual power plant operation server 100 manages the renewable power generation resources 300 built in the industrial complex and monitors the amount of power generation of the renewable power generation resources 300, and the economic burden for securing the RE100 certificate of the RE100 participating companies 400 A cost reduction program can be provided that reduces the cost. In one embodiment, the cost reduction program may include at least one of an energy saving program in factories and buildings, a factory power facility abnormality detection program, and a demand response implementation program.

The RE100 management server 200 supports a method for the RE100 participating companies 400 to obtain a RE100 certificate, and may recommend a RE100 portfolio for achieving the RE100 of the RE100 participating companies 400. That is, the RE100 management server 200 recommends at least one of a self-generation method, an electric power transaction method, and a premium rate payment method to the companies 400 participating in the RE100 to achieve RE100, and supports securing the RE100 certificate through each method. I can.

Here, the at least one renewable power generation resource 300 may include all power generation resources capable of generating renewable energy or supplying power to buildings and/or factories in the industrial complex by using renewable energy.

In an embodiment, the renewable power generation resource 300 may include at least one of a solar power generation system (PV), a fuel cell energy storage system (ESS), an electric vehicle (EV) charging station, and .

The photovoltaic (PV) 300_1 may supply electricity generated using a solar power generation system to buildings and/or factories in an industrial complex, and is not limited thereto, and may supply power to an ESS or EV charging station.

The fuel cell 300_2 may react hydrogen and oxygen to directly convert chemical energy into electrical energy to supply power to a building and/or a factory, but is not limited thereto, and may supply power to an ESS or EV charging station.

The ESS 300_3 may be charged with solar light (PV) or electric power generated from a fuel cell, and discharge the charged electric power to be supplied to a building and/or a factory. The ESS (300_3) can charge electricity during a time when the power load is low, and, on the contrary, use the charged electricity during a time when the power load is high to reduce the maximum amount of power used.

The EV charging station 300_4 may receive power by supplying power to a vehicle or discharging a battery of the vehicle. That is, the EV charging station 200 may be provided with at least one vehicle and a device capable of charging and discharging in both directions (Bi-directional On Board Charger). Here, the means of transport may be a means of transportation that is driven by using power from a built-in battery such as an electric vehicle, an electric motorcycle, an electric bicycle, or a drone, but is not limited thereto. Can be

In other words, the new and renewable power generation resource 300 according to the present embodiment is a new energy source (fuel cell, hydrogen energy, etc.) used by converting the existing fossil fuel and a renewable energy source (solar, hydrogen energy, etc.) In addition to renewable energy sources including solar, bio, wind, hydro, etc.), electric vehicles (EV) that supply power to buildings/factory by using the surplus power of batteries, and electricity are charged during times when the power load is low. On the contrary, in times of high power load, an ESS that uses charged electricity to reduce the maximum amount of power used can be included.

The RE100 participating company 400 is located in the industrial complex microgrid, and may be a company participating in the RE100. The RE100 participating company 400 may own at least one building and/or factory in the industrial complex. The RE100 participating company 400 may exchange data with the virtual power plant operation server 100 and the RE100 management server 200 through their terminals.

FIG. 2 is a diagram illustrating a virtual power plant operating server for participation of small and medium-sized companies in an industrial complex microgrid according to an embodiment of the present invention.

2, the virtual power plant operation server 100 includes a renewable power generation resource management unit 110, a power generation monitoring unit 120, a power consumption measurement unit 130, an energy saving unit 140, a factory facility abnormality detection unit 150 and a demand response implementation unit 160 may be included. According to an embodiment, the virtual power plant operation server 100 may further include a power generation predicting unit and a power plant maintenance unit. In addition, the virtual power plant operation server 100 may further include at least one of an ESS charge/discharge control unit and an EV charge/discharge control unit.

The renewable power generation resource management unit 110 may build and manage the renewable power generation resource 300 in the industrial complex. The renewable power generation resource management unit 110 may establish a construction plan of the renewable power generation resource 300, receive investment from the RE100 participating company 400, and build and manage the renewable power generation resource 300 in the industrial complex. .

In one embodiment, the renewable power generation resource management unit 110 may store a power generation amount distribution rate according to the permeability of each renewable power generation resource 300 to distribute the power generation amount of the RE100 participating companies 400.

In one embodiment, the renewable power generation resource may include at least one of photovoltaic (PV), an energy storage system (ESS), an electric vehicle (EV) charging station, and a fuel cell. The renewable power generation resource is not limited thereto, and may include all power generation resources capable of supplying electric power to buildings/factory within the industrial complex by using renewable energy.

The power generation monitoring unit 120 may monitor the power generation amount of the renewable power plant. Here, the renewable power plant may include solar light (PV) or a fuel cell that generates renewable energy.

The power generation monitoring unit 120 may supply the generated renewable energy to a building/factory, ESS or EV charging station in the industrial complex. In one embodiment, the power generation monitoring unit 110 may distribute the power generation amount to the building and/or factory of the RE100 participating company 400 according to the investment rate of the renewable power generation resource 300 of the RE100 participating company 400.

In addition, the power generation predicting unit (not shown) may predict the power generation amount of the renewable power plant. Taking a solar power plant as an example, the power generation predicting unit may predict the solar power generation amount for each time of the day by referring to the characteristics of the solar power generation system and meteorological data provided from the Meteorological Administration.

To this end, the generation amount prediction unit may analyze/retain a linkage relationship between the past meteorological information and the past generation amount, and based on this, based on the weather data of the day, the amount of solar power generation for each time of the day may be predicted.

In addition, the power plant maintenance unit (not shown) may detect an abnormality through the amount of generation measured by the generation amount monitoring unit 120 and the amount of generation predicted by the generation amount prediction unit 130 to maintain the new and renewable power plant. For example, when the renewable power plant is a solar power plant, the power plant maintenance department may perform defective replacement, cleaning, and facility failure repair of PV panels that detect abnormalities. Through this, an effect of increasing the power generation efficiency of the renewable power generation resource 300 can be expected.

The power consumption measurement unit 130 may monitor actual power consumption of a factory or a building in the industrial complex. In addition, the power consumption measurement unit 130 may predict the power demand of a factory or a building in the industrial complex for a certain period.

The ESS charging/discharging control unit (not shown) may control charging/discharging of the energy storage system (hereinafter, ESS). ESS stores electric energy generated by renewable energy sources (PV, fuel cells, etc.) and can supply power to buildings/factory.

The EV charging/discharging controller (not shown) may control charging/discharging of an electric vehicle (EV) charging station. As a V2G resource, the EV charging/discharging control unit can supply power to the building/factory by using the battery power reserve of the electric vehicle (EV) parked at the electric vehicle (EV) charging station after the vehicle has finished driving.

The energy saving unit 140 may control the power consumption in the factory and/or building to be suppressed. The energy saving unit 140 may control the power consumption to be suppressed through the installation of smart devices in the factory/building, control of electronic devices, and the like. For example, the energy saving unit 150 may save energy in a factory/building through smart lighting and control of a heating/cooling air conditioner.

The factory facility abnormality detecting unit 150 may detect an abnormality in a problem facility that consumes excessive power in the factory. The factory facility abnormality detection unit 150 may attach a sensor to a power facility of a factory or discover a problem facility that consumes excessive power through big data analysis and take action. As a result, there is an effect that can be expected to increase the efficiency of consumption of power equipment in the factory.

The demand response execution unit 160 may perform a demand response within the industrial complex. The demand response execution unit 160 may request a demand response from a building/factory within the industrial complex when the amount of generation measured by the total amount measurement unit 120 does not meet the power consumption measured by the power consumption measurement unit 130. . The demand response execution unit 160 may provide an incentive to the RE100 participating company 400 corresponding to the building/factory participating in the demand response.

3 is a diagram showing a RE100 management server for participation of small and medium-sized companies in an industrial complex microgrid according to an embodiment of the present invention.

Referring to Figure 3, RE100 management server 200 is a participating company management unit 210, self-generation method support unit 220, power transaction method support unit 230, premium payment simulation unit 240, portfolio recommendation unit 250 ) And a cost reduction program providing unit 260.

Participating company management unit 210 may manage the information of the company 400 participating in the RE100. The participating company management unit 210 may receive an application for participation in RE100 from companies distributed in the industrial complex. The RE100 participating company 400 may own at least one building and/or factory in the industrial complex.

The self-generation method support unit 220 may support securing the RE100 certificate through a self-generation method including equity investment in renewable power generation resources 300.

The self-generation method support unit 220 may receive a stake in the renewable power generation resource 300 for the self-generation method from the RE100 participating company 400 through a self-generation method. The self-generation method support unit 220 may transmit the stake received from the RE100 participating company 400 to the virtual power plant management server 100.

At this time, the virtual power plant management server 100 may build and expand the renewable power generation resource 300 in the industrial complex. The virtual power plant management server 100 may monitor the amount of power generation of the constructed renewable power generation resource 300. In addition, the virtual power plant management server 100 may support the RE100 participating companies 400 to secure the RE100 certificate through the distribution of the power generation amount according to the investment rate of the power generation amount.

In one embodiment, the virtual power plant management server 100 may predict the power generation amount of the new and renewable power plant, and detect an abnormality through the monitored power generation amount and the predicted power generation amount to maintain the new and renewable power plant.

The power transaction method support unit 230 may support securing the RE100 certificate through a power transaction method with the renewable power generation resource 300. In this case, the power transaction method may mean a method of purchasing renewable energy power at a contract price for a certain period by signing a contract with a power generation company.

The power transaction method support unit 230 may receive an input of the amount of renewable generation to be secured through the power transaction method from the company 400 participating in the RE100. In addition, the power transaction method support unit 230 may enter into a contract for a power transaction between the renewable power generation resource 300 and the RE100 participating company 400 according to the power transaction rule. In one embodiment, the power transaction rule may include a contract period, power amount, and power rate, and the RE100 participating company 400 conducts power transaction according to the renewable power generation resource 300 and the contract period, power amount, and power rate. can do. Accordingly, the RE100 participating company 400 can secure the RE100 certificate according to the amount of transaction development.

The premium rate payment simulation unit 240 may provide a premium rate plan simulation for securing the RE100 certificate through a premium rate payment method. The premium rate plan payment method is a method in which a sales business operator such as KEPCO forms a separate rate plan with a premium equivalent to the price of a certificate for renewable energy sources, and authorizes the procurement of renewable energy to power consuming companies that subscribe to this rate plan.

For example, if the electricity bill is 100 won per 1 kWh and the certificate price is 20 won per 1 kWh, customers who have subscribed to the premium plan can pay 120 won per kWh and be recognized for renewable energy procurement.

The premium fee payment simulation unit 240 may be set from the RE100 participating company 400 to set the amount and period of renewable generation to be secured through premium fee payment. The premium fee payment simulation unit 240 may simulate the cost required for securing the amount of renewable generation to be secured based on the premium rate plan and provide it to the RE100 participating companies 400.

The portfolio recommendation unit 250 may recommend at least one of a self-generation method, a power transaction method, and a premium rate payment method to the companies 400 participating in the RE100 to achieve RE100.

The portfolio recommendation unit 250 may receive a target year of RE100, power consumption data for the last three years, and payable costs from the RE100 participating company 400, and recommend a possible method to the RE100 participating company 400. The portfolio recommendation unit 250 may provide the RE100 participating company 400 with a method of securing a RE100 certificate combining a self-generation method, a power transaction method, and a premium rate payment method.

In one embodiment, the portfolio recommendation unit 250 may recommend an economically inexpensive method for the target year and payable cost when the payable cost is insufficient compared to the target year.

In addition, the portfolio recommendation unit 250 may simulate and provide a savings expected when participating in a cost reduction program.

The cost reduction program providing unit 260 may provide a cost reduction program for reducing the cost required for securing the RE100 certificate. The cost reduction program provider 260 may transmit a list of the RE100 participating companies 400 to the virtual power plant operation server 100 to provide a cost reduction program for the RE100 participating companies 400.

In one embodiment, the cost reduction program may include at least one of an energy saving program in factories and buildings, a factory power facility abnormality detection program, and a demand response implementation program. The cost reduction program may be implemented by at least one of the energy saving unit 140 of the virtual power plant operation server 100, the factory facility abnormality detection unit 150, and the demand response execution unit 160. The cost reduction program will be described in detail in FIG. 4.

4 is a diagram showing a cost reduction program for reducing RE100 securing cost according to an embodiment of the present invention.

Referring to FIG. 4, the cost reduction program may include an energy saving program 261 in a factory/building, a factory facility abnormality detection program 263, and a demand response program participation program 265.

The energy saving program 261 in the factory/building is a program that aims to reduce the cost for securing RE100 by controlling the amount of power consumption through the installation of smart devices in the factory/building, control of electronic devices, and the like. For example, the energy saving unit 150 of the virtual power plant operation server 100 may save energy in a factory/building through smart lighting and air conditioning/cooling control.

The factory facility abnormality detection program 263 is a program that seeks to reduce the cost for securing RE100 by detecting and replacing an abnormality in the factory power equipment. That is, the factory facility abnormality detection unit 150 of the virtual power plant operation server 100 may attach a sensor to the power facility of the factory or discover a problem facility that consumes power through big data analysis and take action. Accordingly, the factory facility abnormality detection program 263 has an effect of expecting efficiency of consumption of the factory power facility.

The Demand Response Program Participation Program 265 is a program that aims to reduce costs for securing RE100 by providing incentives to companies participating in demand response in the industrial complex. The demand response program participation program 265 may be performed by the demand response execution unit 170 of the virtual power plant operation server 100, and may provide incentives to companies participating in the demand response.

In other words, the RE100 participating company 400 establishes a reduction implementation contract for the amount of power and price to be reduced and implements load reduction. Incentives of

5 is a flowchart illustrating a method of operating a virtual power plant for participation in RE100 of a small and medium-sized company in an industrial complex microgrid according to an embodiment of the present invention.

5, in the RE100 participating company management step (S510), the RE100 management server 200 may manage information of the company 400 participating in the RE100. That is, the RE100 management server 200 may manage information of the RE100 participating companies 400 by receiving an application for participation in RE100 from a company occupying the industrial complex.

In the self-generation method support step (S520), the RE100 management server 200 may support securing the RE100 certificate through a self-generation method including equity investment of renewable power generation resources. A method of supporting securing the RE100 certificate through the self-generation method will be described in detail in FIG. 6.

In the power transaction method support step (S530), the RE100 management server 200 may support securing the RE100 certificate through a power transaction method with renewable power generation resources. A method of supporting securing the RE100 certificate through the power transaction method will be described in detail in FIG. 7.

In the premium fee payment support step (S540), the RE100 management server 200 may provide a premium rate plan simulation for securing the RE100 certificate through a premium rate payment method. A method of supporting securing the RE100 certificate through the premium fee payment method will be described in detail in FIG. 8.

In the portfolio recommendation step (S550), the RE100 management server 200 may recommend at least one of a self-generation method, a power transaction method, and a premium rate payment method to the RE100 participating company 400 to achieve RE100. A method for the RE100 management server 200 to recommend a portfolio to the RE100 participating company 400 will be described in detail in FIG. 9.

In the cost reduction step (S560), the RE100 management server 200 may provide a cost reduction program for reducing the cost required to secure the RE100 certificate. In one embodiment, the cost reduction program may include at least one of an energy saving program in factories and buildings, a factory power facility abnormality detection program, and a demand response implementation program.

6 is a flow chart illustrating a method for securing RE100 of a self-powered method according to an embodiment of the present invention.

The RE100 management server 200 may communicate with the virtual power plant management server 100 to perform a process of securing RE100 through a self-powered method.

Referring to FIG. 6, the RE100 management server 200 may receive a stake in the renewable power generation resource 300 for self-generation from the RE100 participating company 400 (S610). The RE100 management server 200 may recruit equity investment companies according to the new renewable power generation resource construction plan received from the virtual power plant management server 100.

At this time, the RE100 participating company 400 may independently invest in the desired renewable power generation resource 300 to receive power generation amount from the corresponding renewable power generation resource 300, and receive the power generation amount distribution through joint investment.

Next, it is possible to build and expand the renewable power generation resources 300 in the industrial complex (S620). The virtual power plant management server 100 may manage the renewable power generation resources 300 built and expanded in the industrial complex. In one embodiment, the renewable power generation resource 400 may include at least one of photovoltaic (PV), an energy storage system (ESS), an electric vehicle (EV) charging station, and a fuel cell.

The virtual power plant management server 100 may monitor the amount of power generation of the renewable power plant (S630).

In one embodiment, the virtual power plant management server 100 may predict the amount of power generation of the new and renewable power plant (S640). In addition, the virtual power plant management server 100 may detect an abnormality through the monitored power generation amount and the predicted power generation amount to maintain the new and renewable power plant (S650).

In addition, the virtual power plant management server 100 may support the RE100 participating companies 400 to secure the RE100 certificate through the distribution of the generation amount according to the investment rate of the renewable power generation resources 300 of the RE100 participating companies 400 (S660).

7 is a flowchart illustrating a method of supporting RE100 securing of a power transaction method according to an embodiment of the present invention.

Referring to FIG. 7, the RE100 management server 200 may receive an input of the amount of renewable power to be secured from the RE100 participating company 400 through a power transaction method (S710). In this case, the power transaction method may mean a method of purchasing renewable energy power at a contract price for a certain period by signing a contract with a power generation company.

The RE100 management server 200 may enter into a contract for a power transaction between the renewable power generation resource 300 and the RE100 participating company 400 according to the power transaction rule (S720). At this time, the power transaction rule may include the contract period, the amount of electricity, and the electricity rate, and the RE100 participating company 400 may conduct the electricity transaction according to the renewable power generation resource 300 and the contract period, electricity amount, and electricity rate. have.

The RE100 participating company 400 may obtain a RE100 certificate according to the amount of transaction power generated with the contracted renewable power generation resource 300 (S730).

8 is a flowchart illustrating a method of securing RE100 in a premium rate payment method according to an embodiment of the present invention.

The RE100 management server 200 may receive the amount and period of renewable generation to be secured from the RE100 participating company 400 through premium fee payment (S810). For example, the RE100 management server 200 may receive a desired power generation amount of 1000 kWh and a desired period of 1 year from the RE100 participating company 400.

The RE100 management server 200 may simulate the cost required for securing the amount of renewable power to be secured based on the premium rate plan (S820). For example, if the premium rate is 120 won per 1 kWh, RE100 participating companies 400 may have to pay 120,000 won depending on the desired power generation amount of 1000 kWh and the desired period of one year.

Accordingly, the RE100 participating company 400 can secure the RE100 certificate by paying the premium rate plan (S850).

9 is a flowchart illustrating a method of recommending a RE100 portfolio according to an embodiment of the present invention.

Referring to FIG. 9, the RE100 management server 200 may receive input of a target year of RE100, power consumption data for the last three years, and payable costs from the RE100 participating company 400 (S910).

In addition, the RE100 management server 200 predicts the amount of power consumed by the achievement target year, derives a method that can be performed with a payable cost and an achievement period, and recommends at least one of a self-generation method, a power transaction method, and a premium fee payment method. Can be (S920).

For example, as of 2019, the RE100 management server 200 has a target year of 2030 from the RE100 participating companies 400, a total of 3000 kWh of power consumption data for the last 3 years, and a payable cost of 1000 You can enter 10,000 won.

At this time, the RE100 management server 200 calculated each method, the self-powered method is an estimated cost of 7 million won, the expected achievement period is 15 years, the power transaction method is an estimated cost of 9 million won, and the expected achievement period is 10 years, When the result is that the premium fee payment method is 10 million won in the budget and the expected achievement period is 3 years, the RE100 management server 200 may recommend a power transaction method and a premium fee payment method to the RE100 participating companies 400. . In addition, the RE100 management server 200 may combine them in consideration of the estimated cost and expected achievement period of the self-generation method, the power transaction method, and the premium fee payment method, and the expected cost and the expected achievement period are minimized. The portfolio may be extracted and provided to the RE100 participating company 400.

In an embodiment, the RE100 management server 200 may recommend an economically inexpensive method for the target year and payable cost when the payable cost is insufficient compared to the target year.

In addition, the RE100 management server 200 may simulate and provide the expected savings when participating in the cost reduction program (S930). In one embodiment, the cost reduction program may include at least one of an energy saving program in factories and buildings, a factory power facility abnormality detection program, and a demand response implementation program.

The RE100 participating company 400 may construct a portfolio for achieving RE100 by referring to a method recommended from the RE100 management server 200.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to clarify the technical idea of the present invention, centering on the preferred embodiments shown in the drawings with respect to the present invention. In describing the present invention, when it is determined that a detailed description of a related known function or component may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. Constituent elements having substantially the same functional configuration among the drawings are assigned the same reference numerals and reference numerals as much as possible, even if they are indicated on different drawings. If necessary for convenience of explanation, the device and the method will be described together.

1 is a diagram illustrating a gamification V2G service system linking an electric rental car and a tour course according to an embodiment of the present invention.

Referring to FIG. 1, the gamification V2G service system 10 may include an electric rental car 400, a user terminal 200, a tourist destination server 300, and a gamification V2G service management server 100. .

Electric car rental 400 may be paid to users participating in the V2G service. The electric rental car 400 may have a unique identifier for each electric rental car 400, and when paid to the user, the electric rental car 400 and the electric rental car 400 receive the unique identifier of the electric rental car 400 to the gamification V2G server 100 One user can be mapped and saved. In addition, the unique identifier of the electric rental car 400 may be used for the tourist destination server 300 to manage information of the electric rental car 400 connected to the bidirectional charger in the touristic parking lot.

The user terminal 200 is a terminal used by a user who operates the electric rental car 400, and may include a smartphone, tablet PC, laptop, etc. that can be carried by the user, and a terminal mounted on the electric rental car 400, For example, it may include a navigation terminal. In addition, the user terminal 200 may include various types of devices capable of communicating with the gamification V2G service management server 100 through a network.

The user terminal 200 may be provided with a gamification V2G service from the gamification V2G service management server 100 after linking the electric rental car 300 by executing an application installed on the user terminal 200.

The tourist destination server 300 may transmit parking information of the electric rental car 400 to the gamification V2G service management server 100 using a two-way charger installed in a parking lot of a tourist destination participating in the V2G service.

Specifically, at least one bidirectional charger is installed in the parking lot of the tourist destination, so that the battery of the electric rental car parked in the touristic parking lot can be used as a resource for the V2G service. When a two-way charger is connected to the electric rental car 400 parked in a touristic parking lot, the two-way charger receives the unique identifier information of the electric rental car 400 and receives the real-time parking status and available EV capacity information of the electric rental car 400. Can be transmitted to the application V2G service management server 100.

2 is a block diagram showing the configuration of a gamification V2G service management server according to an embodiment of the present invention. 3 is a diagram illustrating a method for a gamification V2G service management server to provide points to a user according to an embodiment of the present invention.

2, the gamification V2G service management server 100 according to an embodiment of the present invention includes a server communication unit 110, a tourist destination management unit 120, a database unit 130, a tour course generation unit 140 , A state information collection unit 150, a gamification management unit 160, and a power transaction processing unit 170 may be included.

The server communication unit 110 may exchange data by communicating with the user terminal 200 and the tourist destination server 300.

The server communication unit 110 may provide an application for providing a gamification V2G service to the user terminal 200. In addition, the server communication unit 110 may communicate with the tourist destination server 300 to receive the parking status and available EV capacity of the electric rental car 400 parked in the parking lot for each tourist destination.

The tourist destination management unit 120 may manage tourist destination information including types of tourist destinations participating in the V2G service, basic parking time, and basic point information. Tourist information participating in the V2G service may further include the number of two-way chargers installed in the parking lot of the tourist destination, and location information of the tourist destination.

In an embodiment, the tourist destination management unit 120 may manage event information for each tourist destination. Event information for each tourist destination may be displayed together when a user selects one of at least one tourist course through the user terminal 200. As a result, when a user selects a tourist course, there is an effect of inducing the user to select a tourist course including a corresponding tourist destination.

The database unit 130 may map and store the electric rental car and the user who received the electric rental car.

In an embodiment, the database unit 120 may further include a tourist destination DB, a user DB, a gamification DB, and a power transaction DB. The tourist destination DB may include tourist destination information participating in V2G, event information for each tourist destination, real-time tourist parking lot status, and point/coupon provision details. In addition, the user DB may include user participation information, accumulated points, and user grade. In addition, the gamification DB may include a tour course selected by each user, current location information of the user, group information, and real-time ranking. The power transaction DB may include EV available capacity for each tourist destination, predicted future EV available capacity, and settlement information.

The tourist course generation unit 140 generates at least one tourist course according to user participation information including the desired tourist destination type received from the user terminal 200, and generates the tourist course and directions information for the tourist course. It can be transmitted to the terminal 200. In this case, the user terminal 200 may receive a selection of one tourist course among at least one tourist course received from the user. In addition, the generated at least one tourist course may be composed of a tourist destination that satisfies the user's desired tourist destination type.

In one embodiment, the user participation information may include a desired tourist destination type, tour schedule information, and target points. At this time, the generated at least one tourist course may be generated by analyzing user participation information including a user's desired tourist destination type, tourist schedule information, and target points, types of each tourist destination, basic parking time, and basic provision point information.

In one embodiment, the tourism course generation unit 140 is based on the type of the user's desired tourist destination input from the user terminal 300, tourist itinerary information, and target points. At least one tourist course candidate may be generated by analyzing traffic congestion, basic parking time for each tourist destination, and parking situation information for each tourist destination.

In this case, the generated at least one tourist course candidate may be a user-customized tourist course in consideration of a tourist destination type selected by the user, a target point, and a tourist schedule, while a parking situation is sufficient and movement between tourist sites is short.

The state information collection unit 150 may collect the unique identifier, parking information, and available EV capacity information of the electric rental car 400 parked in each tourist destination from the tourist destination server 300.

In this case, the unique identifier of the electric rental car may be information for providing points to a user who has received each electric rental car 400. In addition, the parking information may include the number of electric car rentals 400 in a real-time parking lot, parking start time and parking end time of each electric car rental 400. In addition, the available EV capacity information may be information obtained by calculating the available EV capacity using the battery of the electric rental car 400 parked in the tourist destination for each tourist destination.

In one embodiment, the user's tour course stored in the gamification DB may be analyzed to predict how many electric rental cars 400 will be parked in a parking lot for each tourist destination at a future point in time, thereby predicting an available EV capacity in the future.

In one embodiment, it is possible to collect trading market reference information for participation in the power trading market. The collected information may be transmitted to the power transaction processing unit 170 to be used as basic data for establishing a strategy for determining the timing of participation in the power transaction.

In an embodiment, the state information collection unit 150 may collect weather information or traffic jam information. Weather information or traffic jam information may be used when the tour course generation unit 140 generates a tour course.

The gamification management unit 160 provides points to the user account when the electric rental car 400 parked at the tourist destination included in the tourist course satisfies the basic parking time of the tourist destination, and provides the user's accumulated points to the user terminal 200. , Rating, and real-time ranking information can be transmitted.

Referring to FIG. 3, a name of a tourist destination 31 participating in the V2G service, a point acquisition condition 33 of each tourist destination, and an acquisition point 35 provided when the point acquisition condition 33 is satisfied at each tourist destination are shown. . For example, if you park for an hour and a half at a folk museum, 800 pt is provided, so a user can get 800 pt when parked in a parking lot of the folk museum for more than 1 hour and 30 minutes.

In addition, it is possible to induce users to participate in the tour course until the end by reflecting the points accumulated every day during the entire schedule in a real-time ranking.

In one embodiment, the gamification management unit 160 may provide additional points to a user if the electric rental car 400 stays in a tourist destination where a lot of points are provided, or stays longer than the basic parking time of the tourist destination.

In one embodiment, the gamification management unit 160 may designate a group with the electric rental car 400 of a friend or family member, and provide the designated group with points of a friend or family member added up. Since a user is set based on one electric rental car, if a friend or family of the user has another electric rental car 400, the corresponding friend and family may be designated as a group and managed as the summed points. This has the effect of allowing more electric rental cars 400 to move along the recommended sightseeing course.

In an embodiment, the gamification management unit 160 may provide user point management or user level management. The user point management may manage accumulated points for each user so that they can be inquired through the user terminal 200. In addition, the user grade management can upgrade the grade when the accumulated points secured by designating a plurality of grades through the accumulated points of the user exceeds the reference value, and can provide additional benefits to users with a high grade.

The power transaction processing unit 170 may participate in the power transaction market with the available EV capacity secured through the electric rental car 400 parked in the tourist destination. In other words, it is possible to generate profit by participating in the power trading market through the electric rental car 400 secured in all tourist destinations participating in the V2G service and managing the capacity secured.

In one embodiment, the power transaction processing unit 170 may increase a profit rate by establishing a power transaction participation strategy in connection with the future EV available capacity prediction information predicted by the power transaction information collection unit 150.

In one embodiment, the power transaction processing unit 170 may manage the settlement amount to be provided to the tourist destination through the profit generated through the power transaction. That is, points and coupons provided to users by each tourist destination after generating profits through power transactions can be deducted, and the settlement amount to be provided to tourist destinations according to the contract can be managed.

4 is a block diagram showing the configuration of a user terminal according to an embodiment of the present invention. 5 to 7 are diagrams for explaining information output to a user terminal according to an embodiment of the present invention.

4, a user terminal 200 according to an embodiment of the present invention includes a communication unit 210, a user participation information input unit 220, a tour course receiving unit 230, a tour course guide unit 240, and a gameplay. A location display unit 240 may be included, and a point management unit (not shown) may be further included according to an embodiment.

The communication unit 210 may communicate with the gamification V2G service management server 100 to exchange data.

The user participation information input unit 220 may receive user participation information including a desired tourist destination type from the user and transmit it to the gamification V2G management server 100. In this case, the user participation information may include a desired tourist destination type, a tour schedule, and a target point.

The tourism course selection unit 230 may receive at least one tourism course generated by analyzing the user information from the gamification V2G management server 100 and select one of the at least one tourism course from the user.

In an embodiment, if there is a separate event in a tourist destination included in at least one tourist course, the tour course selection unit 230 may check the event content before the user's final selection and consider it at the time of selection.

The tour course guide 230 may receive and output information about a tour course selected by the user and the tour course selected by the user from the gamification V2G management server 100.

As shown in FIG. 5, the user terminal 200 may display an entire map 51, a tourist course 52 selected by the user, and a tourist destination 53 included in the tourist course.

The gamification display unit 250 may receive the accumulated points, grades, and real-time rankings of the user from the gamification V2G service management server 100 and display them on a screen. In this case, the accumulated points may be information obtained by summing points provided by the electric rental car 400 parked in the tourist destination during the basic parking time of the tourist destination.

As shown in FIGS. 6 and 7, the user terminal 200 may display the user's accumulated points or real-time ranking.

Referring to FIG. 6, the user terminal 200 may visually display the user's goal point achievement status in a manner that fills the user's input target point 54 by the user's accumulated points 55. For example, if the target point 54 input by the user is 100, it is shown that the current accumulated point is 48, thereby inducing the user to achieve the target point.

Referring to FIG. 7, the user terminal 200 may display the ranking of all participants over time through a graph 56, and among them, the real-time ranking 57 of the user may be highlighted. Accordingly, the user can see the graph 56 and check his/her ranking in real time.

In an embodiment, the gamification display unit 240 may provide a mission situation and a goal achievement situation in units of V2G tourist destinations to encourage a user. In addition, it is possible to encourage participants to achieve their goals and prevent departure by displaying their own ranking among participants, such as accumulated point ranking and day point ranking.

In one embodiment, the user may designate a group with the electric rental car 400 of a friend or family, and the gamification display unit 240 adds the points of the friend or family from the gamification V2G service management server 100 Group point information can be received and displayed on the screen.

In one embodiment, the user terminal 300 may further include a point management unit (not shown). The point management unit may receive points according to participation in the V2G service in units of tourist destinations, and exchange points for coupons so that they can be consumed at the coupon use place. That is, the user terminal 300 may display coupons available locations such as restaurants, souvenir shops, and specialty shops.

In one embodiment, the point management unit may allow the remaining points after coupon exchange or not exchanged to be added to the grade upgrade. Participants with a higher level can receive benefits such as paying a start coupon at the next electric car rental.

8 is a flowchart illustrating a gamification V2G service management method performed by a gamification V2G service management server according to an embodiment of the present invention.

In step S610, the gamification V2G service management server 100 may manage tourist destination information including type of tourist destination participating in the V2G service, basic parking time, and basic point information. At this time, the tourist destination information participating in the V2G service may further include the number of two-way chargers installed in the parking lot of the tourist destination and location information of the tourist destination.

In an embodiment, the gamification V2G service management server 100 may manage event information for each tourist destination. Event information for each tourist destination may be displayed together when a user selects one of at least one tourist course through the user terminal 200. As a result, when a user selects a tourist course, there is an effect of inducing the user to select a tourist course including a corresponding tourist destination.

In step S620, the gamification V2G service management server 100 may map and store the electric rental car 400 and the user who received the electric rental car 400.

In step S630, the gamification V2G service management server 100 generates at least one tourist course according to the user participation information including the desired tourist destination type received from the user terminal 200, and the tourist course and the tourist course Direction information for may be transmitted to the user terminal 200.

In one embodiment, the at least one tourist course candidate is optimized by analyzing information on weather information, travel distance for each tourist route section, traffic jam in each section, and parking situation information for each tourist destination in addition to the type of tourist destination selected by the user, a tourist schedule, and a target point. It can be a sightseeing course of

In step S640, the gamification V2G service management server 100 may collect the unique identifier, parking information, and available EV capacity information of the electric rental car 400 parked in each tourist destination from the tourist destination server 300. In this case, the unique identifier of the electric rental car 400 may be information for providing points to a user who has received the electric rental car 400 by analyzing the parking state of each electric rental car 400. In addition, the parking information may include the number of electric car rentals 400 in a real-time parking lot, parking start time and parking end time of each electric car rental 400. In addition, the available EV capacity information may be information obtained by calculating the available EV capacity using the battery of the electric rental car 400 parked in the tourist destination for each tourist destination.

In step S650, the gamification V2G service management server 100 provides points to the user account when the electric rental car 400 parked in the tourist destination included in the tourist course satisfies the basic parking time of the tourist destination, and the user terminal ( 200), the accumulated point, grade, and real-time ranking information of the user may be transmitted.

In step S660, the gamification V2G service management server 100 may participate in the power transaction market with the available EV capacity secured through the electric rental car 400 parked in the tourist destination. In other words, it is possible to generate profit by participating in the power trading market through the electric rental car 400 secured in all tourist destinations participating in the V2G service and managing the capacity secured.

The gamification V2G service management server 100 may participate in the power transaction market while the user parks the electric rental car 400 in a touristic parking lot. The power transaction method performed by the gamification V2G service management server 100 will be described in detail in FIG. 5.

9 is a flowchart illustrating a power transaction method performed by a gamification V2G service management server according to an embodiment of the present invention.

In step S710, the gamification V2G service management server 100 may collect power transaction information including the available EV capacity. The gamification V2G service management server 100 may check the available EV capacity from the battery of the electric rental car 400 parked in the parking lot of each tourist destination. In addition, the gamification V2G service management server 100 may manage the power secured from the electric rental car 400 parked in all tourist destinations participating in the V2G service.

In an embodiment, the gamification V2G service management server 100 may predict how many electric rental cars will be parked for each tourist destination in the future by using a tour course selected by the user to predict the future available EV capacity.

In step S720, the gamification V2G service management server 100 may participate in the power trading market based on the available EV capacity.

In an embodiment, the gamification V2G service management server 100 may determine a power transaction participation time by using transaction market reference information for participation in the power transaction market.

In one embodiment, the gamification V2G service management server 100 may increase a profit rate by establishing a power transaction participation strategy using EV available capacity prediction information.

In step S730, the gamification V2G service management server 100 may manage the settlement amount to be provided to the tourist destination with profits generated by participating in the power transaction market.

That is, the gamification V2G service management server 100 may deduct points and coupons provided by each tourist destination to the user from the profit generated by participating in the power transaction market, and provide settlement money to the tourist destination according to the contract conditions.

10 is a flowchart illustrating a gamification V2G service method performed by a user terminal according to an embodiment of the present invention.

In step S810, the user terminal 200 may execute an application for a V2G service provided from the gamification V2G service management server 100.

In step S820, the user terminal 200 may receive user participation information including a desired tourist destination type from the user and transmit it to the gamification V2G service management server 100. In this case, the user participation information may include a unique identifier of the electric rental car, a desired tourist destination type, a tour schedule, and a target point.

In step S830, the user terminal 300 may execute the V2G service by receiving at least one tourist course candidate from the gamification V2G service management server 100 and selecting a tourist course to participate in from the user.

At this time, the at least one tourist course candidate is an optimal tourist course that analyzes information on the type of tourist destination selected by the user, tourist schedule, and target points along with weather information, travel distance for each tourist route section, traffic jam in each section, and parking situation information for each tourist destination. Can be That is, the at least one tourist course candidate may be a result of analyzing a tourist attraction residence time suitable for a tourist destination type selected by a customer and a target point while a parking situation is sufficient, movement between tourist destinations is short.

In step S840, the user terminal 300 may receive and output information about a tour course and directions selected by the user from the gamification V2G service management server 100.

In step S850, the user terminal 300 may receive the accumulated points, grades, and real-time rankings of the user from the gamification V2G service management server 100 and display them on the screen. In this case, the accumulated points may be the sum of all points provided by the electric rental car 400 parked in the tourist destination satisfying the basic parking time of the tourist destination.

So far, the present invention has been looked at in detail centering on the preferred embodiments shown in the drawings. These embodiments are not intended to limit the present invention, but are merely illustrative, and should be considered from an illustrative point of view rather than a restrictive point of view. The true technical protection scope of the present invention should be determined not by the above description but by the technical spirit of the appended claims. Although specific terms have been used in the present specification, they are used only for the purpose of describing the concept of the present invention, and not for limiting the meaning or limiting the scope of the present invention described in the claims. Each step of the present invention need not necessarily be performed in the order described, and may be performed in parallel, selectively or individually. Those of ordinary skill in the technical field to which the present invention pertains will understand that various modifications and other equivalent embodiments are possible without departing from the essential technical idea of the present invention claimed in the claims. It is to be understood that equivalents include not only currently known equivalents, but also equivalents to be developed in the future, that is, all components invented to perform the same function regardless of structure.

Claims (10)

1. In the gamification V2G service management server linking electric rental car and sightseeing course,

   A tourist destination management unit that manages tourist destination information including types of tourist destinations participating in the V2G service, basic parking time, and basic point information;

   A database unit for mapping and storing the electric rental car and the user who received the electric rental car;

   A tourism course generation unit for generating at least one tourist course according to user participation information including a desired tourist destination type received from a user terminal, and transmitting directions information on the tourist course and the tourist course to the user terminal;

   A state information collection unit for receiving the unique identifier, parking information, and available EV capacity information of the electric rental car parked in the tourist destination from the tourist destination server;

   A gamification management unit that provides points to a user when the electric rental car parked in the tourist destination satisfies the basic parking time of the tourist destination, and transmits the accumulated points, grades, and real-time ranking information of the user to the user terminal; And

   Gamification V2G service management server comprising a power transaction processing unit to participate in the power transaction market with the available capacity of the EV secured through the electric rental car parked in the tourist destination.
2. The method of claim 1,

   The user participation information,

   Gamification V2G service management server comprising the user's desired tourist destination type, tour schedule and target points.
3. The method of claim 1,

   The status information collection unit,

   Gamification V2G service management server, characterized in that predicting the future available EV capacity by analyzing the tourism course.
4. The method of claim 3,

   The power transaction processing unit,

   Gamification V2G service management server, characterized in that determining the power transaction participation time using the EV available capacity prediction information.
5. The method of claim 1,

   The gamification management unit,

   Gaming V2G service management server, characterized in that when the electric rental car parks longer than the basic parking time of the tourist destination, additional points are provided to the user.
6. The method of claim 1,

   The gamification management unit,

   A gamification V2G service management server, characterized in that by designating an electric rental car and a group of a friend or family, and providing the group with points of the friend or family.
7. The method of claim 1,

   The power transaction processing unit,

   Gamification V2G service management server, characterized in that managing the settlement amount to be provided to the tourist destination with profits generated by participating in the power trading market.
8. In a user terminal providing a gamification V2G service,

   A communication unit that communicates with the gamification V2G management server;

   A user participation information input unit for receiving user participation information including a desired tourist attraction type from a user and transmitting it to the gamification V2G management server;

   A tourism course selection unit receiving at least one tourism course generated by analyzing the user participation information from the gamification V2G management server and selecting one of the at least one tourism course from the user;

   A tour course information unit configured to receive and output the tourist course selected by the user and directions information on the tour course selected by the user; And

   A gamification display unit receiving the accumulated points, ratings, and real-time rankings of the user from the gamification V2G management server and displaying them on a screen,

   The accumulated points are,

   The user terminal, characterized in that the electric rental car parked in the tourist destination included in the tourist course adds up points provided by satisfying the basic parking time of the tourist destination.
9. In the gamification V2G service method linking electric rental car and sightseeing course,

   Managing, by a tourist destination management unit, tourist destination information including types of tourist destinations participating in the V2G service, basic parking time, and basic point information;

   Mapping and storing the electric rental car and the user who received the electric rental car by a database unit;

   Generating at least one tourist course according to user participation information including a desired tourist destination type received from a user terminal by a tourist course generation unit, and transmitting directions information on the tourist course and the tourist course to the user terminal;

   Receiving, by a state information collection unit, a unique identifier, parking information, and available EV capacity information of the electric rental car parked in the tourist destination from the tourist destination server;

   Providing points to a user account when the electric rental car parked in the tourist destination satisfies the basic parking time of the tourist destination by a gaming unit, and transmitting accumulated points, grades, and real-time ranking information of the user to the user terminal; And

   A gamification V2G service method comprising the step of the power transaction processing unit to participate in the power transaction market with the available EV capacity secured through the electric rental car parked in the tourist destination.
10. In the gamification V2G service system linking electric rental car and sightseeing course,

    At least one tourist destination in which a two-way charger installed in a parking lot of a tourist destination is connected to the electric rental car to charge and discharge electric power in both directions with the electric rental car, and manage at least one of a unique identifier of the electric rental car, a parking situation, and an available EV capacity server;

    The electric rental car and the user who received the electric rental car are mapped and stored, and after transmitting at least one tourist course to the user terminal, the unique identifier of the at least one electric rental car parked in the parking lot from the tourist destination server, the parking situation, and Receives at least one of the available EV capacity, parks the electric rental car at the tourist destination to provide points to users who satisfy the basic parking time of the tourist destination, and transmits the user's accumulated points, rating, and real-time ranking to the user terminal On the other hand, a gamification V2G service management server participating in the power trading market with the available EV capacity of the parked electric rental car in the tourist destination; And

    By selecting one of the at least one tourist course received from the gamification V2G service management server, outputting directions information for the selected tourist course, and accumulating points, grades, and real-time ranking of users according to participation in V2G service Gamification V2G service system comprising a user terminal that displays.

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