KR102258975B1 - Power sharing system for battery charging or high capacity mobile devices - Google Patents

Abstract

A power sharing system according to one embodiment of the present invention comprises: a first high-capacity mobile device of an electricity consumer; a second high-capacity mobile device of a power provider; a battery charging device that charges a battery of the first high-capacity mobile device according to a battery sharing condition set between the first and second high-capacity mobile devices; and a power sharing server that provides power sales and purchase service between the first and second high-capacity mobile devices. Therefore, the present invention is capable of allowing power to be shared anytime and anywhere without being limited to time and space.

Description

{POWER SHARING SYSTEM FOR BATTERY CHARGING OR HIGH CAPACITY MOBILE DEVICES}

The present invention relates to a power sharing system for charging a battery of a large-capacity mobile device. More specifically, it forms a platform that can share power between mobile devices (eg, electric vehicles, drones, and electric bicycles) that have a large amount of power to provide a system that can charge batteries without space and time restrictions. it's about

In general, the secondary battery has the advantage of not generating any by-products according to the use of energy as well as the primary advantage of being able to dramatically reduce the use of fossil fuels.

In addition, unlike a primary battery that is used and thrown away once, a secondary battery has the advantage of being able to be charged multiple times. Due to these advantages, the secondary battery is an energy storage system (ESS) or an uninterruptible power source using a medium-to-large battery used for an electric vehicle (EV), a hybrid vehicle (HV), home or industrial use. It is used in a wide range of fields such as supply devices (UPS, Uninterruptible Power Supply).

In particular, recently, electric vehicles and drones using large-capacity secondary batteries (hereinafter referred to as “battery”) have been commercialized, and the demand for charging stations for charging them is also increasing. The number of charging stations is insufficient.

Due to this situation, owners of electronic devices equipped with various large-capacity batteries, such as electric vehicles and drones, have the inconvenience of having to visit charging stations to charge them, and charge large-capacity batteries even when visiting a charging facility. Since it takes at least 20 minutes or more to charge, there is another inconvenience of having to wait for charging.

Therefore, it is required to develop a power sharing system capable of charging a large-capacity battery at a time and place desired by a user even if it is not a parking lot or a dedicated charging station in which the charging device is installed, and the present invention relates to this.

Republic of Korea Patent Publication No. 10-2019-0097407 (2019.08.21.)

The technical problem to be solved by the present invention is to provide a power sharing system that can solve the problem of lack of charging stations by intermediarying a consumer who wants to charge a large-capacity battery and a supplier who supplies power.

Another technical problem to be solved by the present invention is to provide a method by which individuals and individuals can share power for charging large-capacity mobile devices.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

A power sharing system according to an embodiment of the present invention for achieving the above technical problem is a battery set between a first large-capacity mobile device of a power consumer, a second large-capacity mobile device of a power provider, and the first and second large-capacity mobile devices and a battery charging device for charging a battery of the first large-capacity mobile device according to a sharing condition, and a power sharing server for providing power sales and purchase services between the first and second large-capacity mobile devices.

According to an embodiment, the power sharing server receives power purchase request information from the first high-capacity mobile device, and generates a list of power providers available for purchase based on the power purchase request information, and the first high-capacity mobile device can be sent to the device.

According to an embodiment, the power purchase request information may include identification information of the first large-capacity mobile device, battery information, charging amount, charging time, current location information, location information for which power transaction is desired, power consumer information, payment information, It may include charging type information of the high-capacity mobile device, whether a battery charging device is required, and power charging type information.

According to an embodiment, the power provider list may include power provider information from which power can be jointly purchased.

According to an embodiment, the power sharing server checks a battery sharing condition between the first and second high-capacity mobile devices together with identification information of the second high-capacity mobile device selected through the first high-capacity mobile device from the list of power providers. and at least one battery charging device to share power through the second high-capacity mobile device may be recognized.

According to an embodiment, the power sharing server calculates in real time a battery charging rate charged to a power consumer based on battery charging information performed through the recognized battery charging device, and the calculated battery charging rate is the battery sharing If the condition is not satisfied, a charge excess notification may be transmitted to the first large-capacity mobile device.

According to an embodiment, the power sharing server may monitor an overload of the second large-capacity mobile device sharing power.

A method of providing electricity sales and purchase service according to another embodiment of the present invention is a method for a power sharing server to provide electricity sales and purchase service, comprising: receiving a power purchase request from a first large-capacity mobile device of a power consumer; Transmitting to the first high-capacity mobile device a list of power providers available for purchase of power generated based on a power purchase request, second high-capacity mobile device identification information of the power provider selected through the first high-capacity mobile device, and the first and first 2 Checking a battery sharing condition between high-capacity mobile devices, recognizing at least one battery charging device to share power through the second high-capacity mobile device, and calculating a battery charging fee charged to the power consumer in real time includes

According to an embodiment, after the step of calculating in real time, when the calculated battery charge rate does not satisfy the battery sharing condition, the method may further include transmitting a charge excess notification to the first large-capacity mobile device. have.

According to the present invention, by connecting a power supplier capable of purchasing power/charging a battery to a power consumer, the consumer can charge the battery in a space other than a parking lot or a battery-only charging station where a charging device is installed. In addition, if consumers and suppliers are matched, electricity can be shared anytime, anywhere without being limited by time and space.

In addition, the consumer in the power sharing system can specify the amount of power to be purchased and the seller can designate the amount of power to be sold, and when the specified amount of power is exceeded, charging is stopped, so power can be shared efficiently.

The effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a diagram showing the configuration of a power sharing system according to a first embodiment of the present invention.
FIG. 2 is a flowchart illustrating a flow of a method of providing power sales and purchase services using the power sharing system according to the first embodiment of the present invention.
3 is a diagram showing the configuration of a power sharing server according to the first embodiment of the present invention.
FIG. 4 is a flowchart illustrating a flow of a method of providing power sales and purchase services performed by the power sharing server shown in FIG. 3 .
5 is a diagram showing the configuration of a power sharing system according to a second embodiment of the present invention.
6 is a flowchart illustrating a flow of a method for providing a battery charging station in a power sharing system according to a second embodiment of the present invention.
7 is a view exemplarily showing a charging station recommendation list provided by the power sharing server according to the second embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Advantages and features of the present invention, and a method of achieving them will become apparent with reference to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments allow the publication of the present invention to be complete, and common knowledge in the technical field to which the present invention pertains. It is provided to fully inform the possessor of the scope of the invention, and the present invention is only defined by the scope of the claims. The same reference numerals refer to the same elements throughout the specification.

Unless otherwise defined, all terms (including technical and scientific terms) used in the present specification may be used with meanings that can be commonly understood by those of ordinary skill in the art to which the present invention belongs.

In addition, terms defined in a commonly used dictionary are not interpreted ideally or excessively unless explicitly defined specifically. The terms used in this specification are for describing exemplary embodiments and are not intended to limit the present invention. In this specification, the singular form also includes the plural form unless specifically stated in the phrase.

As used herein, "comprises" and/or "comprising" means that the stated component, step and/or action excludes the presence or addition of one or more other components, steps and/or actions. I never do that.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

1 is a diagram showing the configuration of a power sharing system 1000 according to a first embodiment of the present invention.

Referring to FIG. 1 , the power sharing system 1000 includes a first large-capacity mobile device 100a of a power consumer, a power consumer terminal 100b, a second large-capacity mobile device 200a of a power provider, and a power provider terminal 200b. , the power sharing server 300 and the battery charging device 400 may be included.

The first and second large-capacity mobile devices 100a and 200a may be electric vehicles that generally suffer from a shortage of charging stations, and in addition to drones having large-capacity batteries, two-wheeled electric vehicles, electric kickboards or small fuel electric vehicles, hybrid vehicles and such as electric motor-driven vehicles. In addition, the first and second large-capacity mobile devices 100a and 200a may include a communication module, and a power consumer who needs power or a power provider who wants to sell power to an electronic device (eg, a navigation device) installed in the device. ) to use the power sharing platform.

The power consumer may transmit power purchase request information for charging the battery to the power sharing server 300 using the first large-capacity mobile device 100a. Specifically, the power purchase request information includes identification information, battery information, charge amount, charging time, current location information, power transaction desired location information, power consumer information, payment information, and high-capacity mobile device of the first large-capacity mobile device 100a. may include charging type information of , whether the battery charging device 400 is required, and power charging type information. Here, the identification information may be a vehicle, a unique license plate of an electronic device, a serial number, device owner information, a vehicle model, etc., and a personal identification number such as a mobile phone number of a power consumer and the front digit of a resident registration number may also be transmitted to the power sharing server 300 . .

In addition, after the power consumer transmits power purchase request information to the power sharing server 300 using the first large-capacity mobile device 100a, a power provider list may be received in response thereto. Here, the power provider list may include information on the power charging rate for each provider, the amount of power that can be charged, the power charging time, whether the time can be extended or shortened, and the distance or travel time to the power sharing place. You can choose one or more and trade electricity with the power provider of your choice.

Meanwhile, the power provider may register power provider information with the power sharing server 300 using the second large-capacity mobile device 200a. For example, the power supplier information includes the date, time, amount of power available for power sale, power charging rate, power charging rate discount conditions, power sharing sale, and battery charging device 400 possession and type according to the possession. may include

The power consumer terminal 100b and the power provider terminal 200b are terminals possessed by a user who wants to make a power purchase request or power sale by possessing a large-capacity mobile device, and a display module such as a smart phone, a wearable device, or a tablet PC. It may be an equipped portable terminal.

On the other hand, the communication between the first large-capacity mobile device 100a or the second large-capacity mobile device 100b and the power sharing server 300 described below is a power consumer terminal 100b or a power provider terminal 200b and a power sharing server. It can be understood that the same can be performed through (300). In other words, power consumers and power providers may selectively use a large-capacity mobile device or use a terminal to use a power sharing service as needed.

The power sharing server 300 is a single server device, and may provide power sales and purchase services between the first and second high-capacity mobile devices 100a and 200a. Specifically, the power sharing server 300 may match a power consumer and a power provider that best meet each other's conditions, and after power sharing is completed based on the battery charging device 400 to be described later, the power provider sets The final battery charging rate may be calculated in real time based on one power charging rate and the amount of power used by the second large-capacity mobile device 100b. Accordingly, the final battery charging charge may be transmitted to the power consumer terminal 100b, and after receiving it from the power consumer, the revenue may be shared with the power provider. Meanwhile, the battery charging fee may be not only cash, but also various electronic money such as virtual currency and points.

Meanwhile, the power sharing server 300 may receive power purchase request information from the first large-capacity mobile device 100a in order to match the power consumer and the power provider, and a power provider capable of purchasing power based on the power purchase request information. A list may be created and transmitted to the first large-capacity mobile device 100a. Here, the list of power providers includes information on the amount of power to be sold and the cost as described above, as well as information on power providers that can jointly purchase power, how many high-capacity mobile devices can be charged, and up to what capacity It may include power charging information such as whether charging is possible.

In addition, the power sharing server 300 may check which power provider the power consumer has selected after providing the power provider list to the power consumer, and at the same time, the battery sharing condition between the power consumer and the power provider and charging the battery to perform the same The device 400 may be recognized. In other words, the power sharing server 300 determines the identification information of the second high-capacity mobile device 200a selected through the first high-capacity mobile device 100a, the battery sharing condition (eg, power sharing amount, time, sharing location, matching). unique identification information) and at least one battery charging device 400 to share power through the second large-capacity mobile device 200a may be recognized.

In other words, in the present invention, an individual has (charging) the power that an individual possesses (charging), going beyond what has been limited in the prior art to a public institution such as an operator or Korea Electric Power that develops a power charging device as the subject of supplying power for charging a large-capacity mobile device. It is possible to provide and use a power sharing service capable of distributing and selling electricity, and one-to-many power transaction sharing may be made instead of one-to-one power sharing.

Also, the power sharing server 300 may calculate in real time a battery charging fee charged to the power consumer based on the battery charging information performed through the recognized battery charging device 400 . Accordingly, when the calculated battery charge rate does not satisfy the battery sharing condition, a charge excess notification may be provided to the power consumer (to the first large-capacity mobile device 100a), and a second large-capacity device sharing power ( 100b) may be monitored, and a blocking notification of at least one battery charging device 400 may be transmitted to a power provider, or a blocking notification may be transmitted to each battery charging device 400 .

On the other hand, in order for the power sharing server 300 to calculate the battery charging rate in real time and monitor the overload through the battery charging device 400, it may be performed under the condition that both the power consumer and the power provider transmit the same power transaction information, If the battery charging device 400 is a device shared by the power sharing server 300, it is possible to control the power transaction to proceed only when the same power transaction information is received from both sides.

The battery charging device 400 may charge the battery of the first high-capacity mobile device 100a according to a battery sharing condition and battery charging information set between the first and second high-capacity mobile devices 100a and 200a. Specifically, the battery charging device 400 is a device that directly supplies energy by connecting a plug, and is largely classified into a home charger, a slow charger, and a quick charger depending on the installation space, and according to the charging type, DC combo, DC Chademo, AC3 It may be classified into phase and slow type, and the power sharing server 300 may provide or sell it. In addition, the wired charging device may include an outlet for supplying an externally usable AC power that is conventionally used.

2 is a flowchart illustrating a flow of a method of providing power sales and purchase services using the power sharing system according to the first embodiment of the present invention.

This is only the most preferred embodiment to achieve the object of the present invention, and it goes without saying that some steps may be added or deleted as needed.

Referring to FIG. 2 , the second large-capacity mobile device 200a registers power provider information for power sales with the power sharing server 300 ( S101 ). Here, the power supplier information may include the date, time, amount of power available for power sale, power charging rate, power charging rate discount conditions, power sharing sales, battery charging device 400 possession and type depending on whether or not possessed. can

After step S101, the first large-capacity mobile device 100a requests power purchase from the power sharing server 300 (S102). Here, the information included in the power purchase request includes identification information of the first large-capacity mobile device 100a, battery information, charging amount, charging time, current location information, location information for which power transaction is desired, power consumer information, payment information, and large capacity. It may include charging type information of the mobile device, whether the battery charging device 400 is required, and power charging type information. Here, the identification information may be a vehicle, a unique license plate of an electronic device, a serial number, device owner information, a vehicle model, etc., and a personal identification number such as a mobile phone number of a power consumer and the front digit of a resident registration number may also be transmitted to the power sharing server 300 . .

After step S102, the power sharing server 300 transmits a list of power providers to the first high-capacity mobile device 100a (S103), and receives a selection of any one power provider from the first high-capacity mobile device 100a (S104) , transmits a power transaction notification to the second high-capacity mobile device 200a (S105). At this time, the list of power providers may include information on the power charging rate for each provider, the amount of power that can be charged, the power charging time, whether the time can be extended or shortened, and the distance or travel time to the power sharing place. You can choose one or more of them to trade electricity with any electricity provider you want.

After step S105, the power sharing server 300 checks the battery sharing condition, and recognizes the battery charging device 400 (S106). Meanwhile, one-to-many power sharing may be performed depending on the power provider, and the power sharing server 300 may recognize at least one battery charging device 400 to be connected to the second high-capacity mobile device 200a.

After step S106, a transaction is made between the power consumer and the power sharer, and power sharing between the first and second large-capacity mobile devices 100a and 200a is started (S107). At the same time, the power sharing server 300 determines the identification information of the second high-capacity mobile device 200a selected through the first high-capacity mobile device 100a, and the battery sharing condition (eg, power sharing amount, time, sharing location, matching). unique identification information) and at least one battery charging device 400 to share power through the second large-capacity mobile device 200a may be recognized.

After step S107, the power sharing server 300 monitors the power usage of the second large-capacity mobile device 200a from the battery charging device 400, and determines whether power is overloaded in the second large-capacity mobile device 200a (S108). ). On the other hand, in order for the power sharing server 300 to calculate the battery charging rate in real time and monitor the overload through the battery charging device 400, it may be performed under the condition that both the power consumer and the power provider transmit the same power transaction information, If the battery charging device 400 is a device shared by the power sharing server 300, it is possible to control the power transaction to proceed only when the same power transaction information is received from both sides.

In step S108, when it is determined that the power is overloaded in the second large-capacity mobile device 200a, the power sharing server 300 notifies the battery charging device removal to the second large-capacity mobile device 200a or the power provider terminal 200b. can be transmitted (S109, YES).

Conversely, in step S108 , when it is determined that the power is not overloaded in the second large-capacity mobile device 200a , the power sharing server 300 performs the power sharing while performing the first power sharing through the at least one battery charging device 400 . It may be determined whether the charging status of the high-capacity mobile device 100a exceeds a preset battery charging rate (S110, NO). Here, the preset battery charge rate can be checked through the battery sharing condition,

In step S110, when it is determined that the battery charging charge is not exceeded, the power sharing server 300 may transmit a charging completion notification to the first and second large-capacity mobile devices 100a and 200a (S111, NO ), on the contrary, when it is determined that the battery charging charge is exceeded, the power sharing server 300 may transmit a charge excess notification to the first large-capacity mobile device 100a (S112, YES).

So far, a method for a power consumer and a power provider to trade power using the power sharing system 1000 according to the first embodiment of the present invention has been described. According to the present invention, through the power sharing system 1000, the power consumer can charge the battery in a space other than a parking lot or a battery-only charging station where the charging device is installed, and the power provider can charge the battery in the second large-capacity mobile device 200a. You can use your power to generate revenue.

In addition, since the power sharing server 300 can monitor transactions that do not satisfy the specified battery sharing condition, both the power consumer and the power provider can efficiently share power.

Meanwhile, FIG. 3 is a diagram showing the configuration of the power sharing server 300 according to the first embodiment of the present invention, and FIG. 4 is a power sales and purchase service performed by the power sharing server 300 shown in FIG. 3 . A flowchart showing the flow of the method.

Referring to FIG. 3 , the power sharing server 300 includes the above processor 310 , a network interface 320 for communication with an external device, and a memory 330 for loading a computer program performed by the processor 310 . ), a storage 340 for storing large-capacity network data and computer programs, and a power sharing server 300 including a system bus 350 may be implemented. In this case, the computer program 341 performs an operation ( S10 ) of receiving a power purchase request from the power consumer's first high-capacity mobile device, and a list of power purchaseable power providers generated based on the power purchase request. The first high-capacity mobile device an operation (S20) of transmitting to the first high-capacity mobile device, an operation of confirming second high-capacity mobile device identification information of a power provider selected through the first high-capacity mobile device, and a battery sharing condition between the first and second high-capacity mobile devices (S30), the An operation of recognizing at least one battery charging device to share power through the second high-capacity mobile device and calculating a battery charging rate charged to the power consumer in real time (S40), and the calculated battery charging rate is the battery sharing condition If not satisfied, an operation ( S50 ) of transmitting a charge excess notification to the first large-capacity mobile device is included.

So far, the power sharing system 1000 according to the first embodiment of the present invention has been described. Hereinafter, a method in which the power provider of the present invention also provides a personal space for charging the battery of a large-capacity mobile device will be described. do.

5 is a diagram showing the configuration of the power sharing system 1000 according to the second embodiment of the present invention.

Referring to FIG. 5 , the power sharing system 1000 may include a power sharing server 300 , a power consumer terminal 100b , and a power provider terminal 200b .

First, the power sharing server 300 is at least one server device, and serves as an intermediary between a power consumer and a power provider to a charging station capable of charging a battery of a large-capacity mobile device and a battery charging cost. More specifically, the power sharing server 300 may match the power supply condition of the power provider and the power charging condition of the power consumer in order to provide a power supply system that can satisfy both the power consumer and the power provider. A detailed description will be given after each component is described in detail.

The power provider terminal 200b may be a terminal of an administrator who manages a charging station for charging a battery of a large-capacity mobile device. For example, a charging station can be a single-family home, villa, apartment, factory site, parking-only building, parking-only structure, etc., where the administrator is an individual owner or custodian who owns a space to park or mount a large-capacity mobile device. can

That is, in the present invention, an individual distributes and sells power allocated to the individual, further than that the subject of supplying power for charging a large-capacity mobile device has been limited to a public institution such as a business or Korea Electric Power Company that develops a power charging device in the prior art. This can solve the problem of insufficient charging stations for charging the batteries of large-capacity mobile devices.

Meanwhile, the power provider terminal 200b may periodically transmit space information and charging information possessed by the user to the power sharing server 300 in order to distribute and sell the power allocated to the user.

Here, the spatial information may include whether the space is indoors or outdoors and ground information of the space, and the ground information of the space may be, for example, gravel, sand, soil, asphalt, or urethane. Such spatial information can be provided as simply as "indoor/urethane", and may be provided by attaching a photo of the corresponding space.

As such, the power provider terminal 200b provides spatial information about the charging station, and the power sharing server 300 shares it with the power consumer, so that the power consumer can select the desired space, and Inconvenience of having to charge in a location that is not there can be eliminated.

In addition, the charging information transmitted by the power provider terminal 200b to the power sharing server 300 may include various types of information related to charging. For example, the charging information may include a chargeable date and time, a type of a wired or wireless charging device, an amount of power that can be sold, a power charging rate, and a discount condition for a power charging rate.

Specifically, the amount of power that can be sold can be adjusted by the power provider in consideration of his/her daily and monthly average power usage and billing accordingly, and the date and time may also be set to the date and time excluding the time used by the power provider.

Wired charging devices are devices that directly supply energy by connecting a plug, and are largely classified into home chargers, slow chargers, and quick chargers according to the installation space, and are classified into DC combo, DC chademo, AC3 phase, and slow type according to the charging type. may be, and the power sharing server 300 may provide or sell it. In addition, the wired charging device may include an outlet for supplying an externally usable AC power that is conventionally used.

In addition, in the case of a wired charging device, various biometric sensors may be included. For example, the biometric sensor may include a PPG (PhotoPlethysmoGraphy) sensor, an ECG (Electrocardiogram) sensor, a camera sensor, etc., through which the unique identification information of the power consumer who uses power at the charging station provided by the power provider is obtained can do.

A wireless charging device is a high-frequency power supply device buried in the floor, and refers to a device that charges a battery by transmitting power through electromagnetic induction. However, in the case of a wireless charging device, since it is provided on the floor, devices that are not driven by electric charging may be parked, and the power sharing server 300 prevents large-capacity mobile devices and devices from occupying their seats depending on the type of charging station. You may.

On the other hand, the power provider can set the power charging rate considering the provider’s profit in the power rate table for large-capacity mobile devices according to the period and hourly load set by KEPCO, and the power consumer compares the power charging rates suggested by the power providers and selects the desired A high-capacity mobile device can be charged at a charging station.

In addition, the power charging rate discount condition is a discount condition set by the power provider. For example, when the large-capacity mobile device is an electric vehicle, the power charging rate can be discounted only to power consumers whose vehicle driver's license penalty points are less than or equal to a reference score.

The power consumer terminal 100b is a terminal of a user possessing a large-capacity mobile device, and may be a mobile terminal such as a smart phone, a wearable device, or a tablet PC, or may include a communication-capable mobile device itself. For example, when the large-capacity mobile device is an electric vehicle, the power consumer terminal 100b may be an electric vehicle, a driver's mobile terminal, or an owner's mobile terminal.

In addition, the power consumer terminal 100b transmits a charging station request message including at least one of device identification information for charging a large-capacity mobile device, battery capacity, battery remaining amount, and current location log to the power sharing server 300 to provide a charging station. can be found Here, the device identification information may be a vehicle license plate, serial number, device owner information, vehicle model, etc., and may also transmit a personal identification number such as a mobile phone number of a power consumer and the front digit of a resident registration number to the power sharing server 300 .

In addition, when the power consumer terminal 100b transmits a charging station request message, the power charging rate, the power charging amount, the power charging time, whether the time can be extended or shortened, the distance or movement time to the charging station from the power sharing server 300 . You can receive charging station selection conditions including

As described above, the power provider terminal 200b periodically charges the power sharing server 300 at the time when the user wants to sell power, the available date, time, the type of wired or wireless charging device, the amount of power available for sale, and power charging. It is possible to provide discount conditions for rates and power charging rates, and the power sharing server 300 generates a list of charging stations using charging stations provided by the power provider terminal 200b every cycle, and meets the priority conditions of power consumers. It can match and recommend charging stations.

In addition, after the charging of the large-capacity mobile device is completed, the power sharing server 300 may calculate the final battery charging cost based on the power charging rate set by the power provider and the amount of power used by the large-capacity mobile device. The final battery charging cost processing request may be transmitted to the power consumer terminal 100b, and after receiving it from the power consumer, it may be settled with the power provider.

In addition, the battery charging cost may be not only cash, but also various electronic money such as virtual currency and points.

So far, the power sharing system 1000 according to an embodiment of the present invention has been described. According to the present invention, in order to use a space owned by an individual or a small business operator as a space for charging a large-capacity mobile device, the electric charging that can satisfy the electric power supplier by checking the conditions of the electric power provider and matching the electric power consumer accordingly system can be obtained.

In addition, the power consumer can secure an electric charging system that can satisfy both the power supplier and the power consumer by setting the conditions most prioritized in the charging process and receiving a charging station that suits them.

6 is a flowchart illustrating a flow of a method for providing a charging station for a large-capacity mobile device according to a second embodiment of the present invention.

This is only the most preferred embodiment to achieve the object of the present invention, and it goes without saying that some steps may be added or deleted as needed.

First, the power sharing server 300 periodically receives spatial information and charging information on a charging station from the power provider terminal 200b, and generates a charging station list (S210).

That is, the power sharing server 300 may recruit a power provider for charging station sharing on a daily, weekly, and monthly basis, and the power provider may transmit space information and charging information through the power provider terminal 200b.

Here, the spatial information may include whether the space is indoors or outdoors and ground information of the space, and the ground information of the space may be, for example, gravel, sand, soil, asphalt, or urethane. Such spatial information can be provided as simply as "indoor/urethane", and may be provided by attaching a photo of the corresponding space.

In addition, the charging information may include a chargeable date, time, a type of a wired or wireless charging device, an amount of power that can be sold, a power charging rate, and a discount condition for the power charging rate.

Specifically, the power provider may set the power charging rate in consideration of the provider's profit in the power consumption rate table for large-capacity mobile devices according to the load for each period and hour determined by KEPCO. In addition, the power charging rate discount condition is a discount condition set by the power provider. For example, if the large-capacity mobile device is an electric vehicle, the power provider will discount the power charging fee only to power consumers whose car driver’s license penalty points are less than or equal to the standard score. can

After step S210, the power sharing server 300 receives a charging station request message including at least one of device identification information for charging a large-capacity mobile device from the power consumer terminal 100b, battery capacity, remaining battery capacity, and a current location log. (S220). Here, the device identification information may be a license plate of a vehicle, a serial number, etc., and may be a personal identification number such as a mobile phone number of a power consumer or a front digit of a resident registration number, and the current location log may include a moving direction together with the current location.

In addition, when the large-capacity mobile device is an electric vehicle, the power consumer terminal 100b may be an electric vehicle, a driver's mobile terminal, or an owner's mobile terminal.

After step S220, the power sharing server 300 sets the charging station selection condition including at least one of the power charging rate, the power charging amount, the power charging time, whether the time can be extended or shortened, the distance to the charging station, and the moving time to the power consumer terminal ( 100b) (S230).

After step S230, the power sharing server 300 receives at least one of the charging station selection conditions from the power consumer terminal 100b, and confirms the power consumer's charging station selection priority (S240).

In addition, in the case of the power charging rate, since the rate varies according to time, a list of charging stations according to the power charging rate may be provided in consideration of the time required for the power consumer terminal 100b to go to the charging station.

After step S240, the power sharing server 300 recommends a charging station available to the power consumer in the charging station list based on the charging station request message (S250).

In this regard, FIG. 7 is a view exemplarily showing a charging station recommendation list provided by the power sharing server 300 according to an embodiment of the present invention, and the power consumer terminal 100b sets the charging station selection condition as 'power charging fee. ', the power sharing server 300 may provide a charging station recommendation list as shown in FIG. 7 .

That is, the power consumer terminal 100b may select one charging station among a plurality of charging stations and proceed with a charging station reservation, and the power sharing server 300 may notify the power provider terminal 200b of this.

In addition, after the power consumer terminal 100b completes charging at any one charging station, the power sharing server 300 calculates the final battery charging cost based on the power charging rate of the corresponding charging station and the amount of power used by the large-capacity mobile device. and the cost can be billed to the electricity consumer.

In addition, if the final battery charging cost is received from the power consumer, it can be distributed to the power provider. In addition to cash, various electronic money such as virtual currency and points may be used for settlement of expenses.

So far, a method of providing a charging station for a large-capacity mobile device performed by the power sharing server 300 according to an embodiment of the present invention has been described. According to the present invention, the power provider can sell power to power consumers who satisfy a desired condition, and the power consumer can also select a desired charging station from among many charging stations. In addition, as such a method is proposed, power sales of individuals with space and time margins increase, thereby increasing the effectiveness of a large-capacity mobile device.

Embodiments of the present invention have been described above with reference to the accompanying drawings, but those of ordinary skill in the art to which the present invention pertains can be implemented in other specific forms without changing the technical spirit or essential features. You will be able to understand. Therefore, it should be understood that the embodiments described above are illustrative and non-limiting in all respects.

1000: power sharing system 300: power sharing server
100a: first high-capacity mobile device 200a: second high-capacity mobile device
100b: power consumer terminal 200b: power provider terminal
310: processor 320: interface
330: memory 340: storage
341: computer program 350: system bus

Claims (9)

a first large-capacity mobile device of a power consumer;
a second high-capacity mobile device of the power provider;
a battery charging device for charging a battery of the first high-capacity mobile device according to a battery sharing condition set between the first and second high-capacity mobile devices; and
a power sharing server that provides power sales and purchase services between the first and second high-capacity mobile devices; Including,
The power sharing server receives power purchase request information from the first large-capacity mobile device, generates a list of power suppliers available for purchase based on the power purchase request information, and transmits it to the first high-capacity mobile device,
The power sharing server,
Checking the battery sharing condition between the first and second high-capacity mobile devices together with the identification information of the second high-capacity mobile device selected through the first high-capacity mobile device from the power provider list, and supplying power through the second high-capacity mobile device recognize at least one battery charging device to share;
Calculate the battery charging rate charged to the power consumer in real time based on the battery charging information carried out through the recognized battery charging device, and monitor the overload of the second high-capacity mobile device sharing power,
When the calculated battery charge charge does not satisfy the battery sharing condition, sending a charge excess notification to the first high-capacity mobile device,
The power sharing server is periodically supplied with space information and charging information of the power provider from the second large-capacity mobile, wherein the charging information includes a chargeable date, time, type of charging device, amount of power available for sale, power charging rate and power charging. A power sharing system, characterized in that it includes a rate discount condition. delete According to claim 1, wherein the power purchase request information,
Identification information of the first large-capacity mobile device, battery information, charging amount, charging time, current location information, location information that wants to trade power, power consumer information, payment information, charging type information of the large-capacity mobile device, whether a battery charging device is required and power charging type information. The method of claim 3, wherein the list of power providers,
A power sharing system, including power provider information that can jointly purchase power. delete delete delete A method for a power sharing server to provide power sales and purchase services, the method comprising:
receiving a power purchase request from a first large-capacity mobile device of a power consumer;
transmitting a list of power purchaseable power providers generated based on the power purchase request to the first high-capacity mobile device;
checking second high-capacity mobile device identification information of a power provider selected through the first high-capacity mobile device and a battery sharing condition between the first and second high-capacity mobile devices;
recognizing at least one battery charging device to share power through the second high-capacity mobile device, and calculating a battery charging fee charged to the power consumer in real time; and
After the step of calculating in real time, when the calculated battery charge charge does not satisfy the battery sharing condition, transmitting a charge excess notification to the first large-capacity mobile device;
The power sharing server,
Receiving power purchase request information from the first large-capacity mobile device, generating a list of power suppliers available for purchase based on the received power purchase request information, and transmitting it to the first high-capacity mobile device,
Checking the battery sharing condition between the first and second high-capacity mobile devices together with the identification information of the second high-capacity mobile device selected through the first high-capacity mobile device from the power provider list, and supplying power through the second high-capacity mobile device The second high-capacity mobile that recognizes at least one battery charging device to be shared, and calculates the battery charging rate charged to the power consumer in real time based on the battery charging information proceeding through the recognized battery charging device, and shares power monitor the overload of the device;
Spatial information and charging information of the power provider are periodically supplied from the second large-capacity mobile, wherein the charging information includes a chargeable date, time, type of charging device, amount of power available for sale, power charging rate and power charging rate discount conditions A method of providing electricity sales and purchase services, characterized in that delete

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