KR20150113807A - Energy trade method and energy management system - Google Patents

Abstract

Disclosed are a resource trading method and an energy management system. The energy management system is an energy-prosumer expanding system, capable of additionally securing an energy source for providing energy to a user or others (or power device) by saving the energy in an energy consumption system or allowing the user or others to trade the energy source, secured through the operation of an energy generation device. In other words, the present invention is capable of determining an energy consumption price by energy supply step, an energy amount to be secured by the user, and an energy purchase price; and determining an energy sales price for a residual amount of energy. The energy management system relays the trading of resources by using the sales and purchase prices.

Description

Energy trading method and energy management system

The present invention relates to a resource transaction method and apparatus capable of trading resources based on a hierarchical structure among energy management apparatuses.

Recently, Smart Grid technology has been selected as a core business of next generation in many countries and is actively researched. The smart grid system is aimed at power saving. In order to reduce power consumption, a smart grid system generally uses a method of turning on / off a specific device as shown in Korean Patent Laid-Open Publication No. 2012-0097551.

This conventional smart grid system uses IT technology in the electric power industry to monitor and control the convenience of power use and various energy resources centering on smart metering or demand / response (DR) through a two-way communication service between a user and a power company It is concentrated.

That is, the conventional smart grid and the energy management system can independently schedule the energy to be used according to a user's desired method or monitor the energy used to plan the appropriate supply amount from a long term viewpoint, The energy management system of each unit is focused only on the side, and the energy production through the storage device other than the energy consumption, the production capable of producing its own energy, the role as the consumer, and the energy system are hierarchically integrated and managed. There is no way to deal with resources based on hierarchies.

The present invention relates to an energy management system for a building, an apartment, a home, a factory, etc., as an energy management system, in addition to energy consumption, energy production through energy saving, energy production through energy storage, And to provide a resource trading method and an energy management system for providing a role as a combined prosumer.

In addition, the present invention provides a resource transaction method and an energy management system capable of hierarchically integrating each regional unit energy management system, efficiently using resources, and relaying resource transactions between respective unit energy management apparatuses.

Accordingly, the present invention can be applied to other regional energy management systems in the case where resources are saved through saving or storage devices in each regional energy management system, so that resource transaction methods and energy Management system.

According to one aspect of the present invention, there is provided an energy management system for a building, an apartment, a home, a factory, etc. as an energy management system, as well as an energy producer through energy storage and energy generation, An energy management system for providing a role as a prosumer, and a system capable of trading resources between each energy management device based on hierarchical structure are provided.

According to an embodiment of the present invention, there is provided an energy management apparatus comprising: an energy management apparatus; At least one energy consuming device; At least one energy storage device; And at least one energy generation device, wherein the energy management device controls resource distribution in accordance with energy consumption, production or storage of the energy consumption device, the energy storage device and the energy generation device. System can be provided.

The energy management apparatus can control the resource distribution by monitoring the energy consumption of the energy consuming apparatus based on at least one of the energy use level of the energy consumption apparatus and the user's required level.

Wherein the energy management device distributes resources such that the energy consuming device consumes energy differentially according to an energy supply and demand step, and the amount of energy stored in the energy storage device or the amount of energy stored in the energy storage device The energy amount can be controlled to be distributed to the energy consuming device in a differential manner.

The energy supply and demand is determined by considering the amount of energy supplied and the amount of energy consumed, and the energy supply amount to be supplied to the energy consumption device, the unit price according to the energy supply, Price or selling price can be determined differently.

According to another embodiment of the present invention, there is provided a method of managing energy in a wireless communication system comprising: at least one first layer energy management device; And at least one second layer energy management device, wherein the first layer energy management device and the second layer energy management device are connected to the upper and lower layers.

The second layer energy management apparatus is located in an upper layer of the first layer energy management apparatus, and the upper layer can distribute resources of the lower layer energy management apparatus.

The first layer energy management apparatus may be a unit energy management apparatus for distributing resources of individual unit areas, and at least one may be an energy storage apparatus for providing resources to individual areas.

According to another aspect of the present invention, there is provided a method of trading resources between energy management devices based on a hierarchical structure.

According to an embodiment of the present invention, there is provided a method for relaying resource transactions in an upper layer energy management apparatus connected to at least one unit energy management apparatus in a hierarchical structure, the method comprising: receiving an energy addition distribution request from a first unit energy management apparatus ; Receiving selling price data from the second unit energy management device in accordance with the additional distribution request; And relaying the resource transaction to the first unit energy management device based on the selling price data.

Wherein the energy additional distribution request includes an additional requested energy amount and the step of relaying the resource transaction may relay the resource transaction in the order of the lowest available resource based on the selling price data .

Wherein the step of relaying the resource transaction further comprises the step of relaying the resources of the second unit energy management device with the minimum difference in the result of comparison between the purchase price data and the selling price data, It is possible to distribute the resource transaction to the unit energy management device.

The purchase price data includes data on purchase price of each grade, and the step of relaying the resource transaction may relay the resource transaction differentially for each grade based on the purchase price reference data for each grade.

The selling price data includes selling price data for each rank, and the step of relaying the trading of the resources further comprises the steps of: distributing, by the first unit energy management device, Transactions can be relayed.

Each of the above grades is a priority of resource distribution.

The selling price data may further include a sellable energy amount, and the purchase price data may further include a purchase amount of energy, wherein the step of relaying the resource transaction is a step of comparing the difference between the purchase price data and the selling price data The redeemable energy amount of the second unit energy management apparatus can be redistributed to the first unit energy management apparatus by the purchase energy amount in the order of the first unit energy management apparatus and the second unit energy management apparatus.

The step of relaying the resource transaction may not relay the resource transaction if the selling price data exceeds the reference value based on the purchase price data.

The step of relaying the resource transaction may relate the resource transaction in consideration of the reserve resource amount.

The preliminary resource amount includes an amount of energy available for each grade, and the step of relaying the resource transaction can relay the resource transaction in consideration of the amount of energy available for each grade.

Wherein at least one of the unit energy management apparatuses is an energy management apparatus that provides resources to the unit energy management apparatus, and the step of relaying the resource transactions includes: Redistribution to an energy management device.

By providing a resource trading method and an energy management system according to an embodiment of the present invention, a single energy management system for a building, an apartment, a home, and a factory can be used for energy production and energy generation As a producer of energy, it can serve as a combined prosumer of energy production and consumer.

In addition, the present invention can hierarchically integrate each regional unit energy management system, efficiently use resources, and relay resource transactions between each unit energy management apparatuses.

Accordingly, when resources are left in each regional unit energy management system, the present invention can be used in other regional unit energy management systems, thereby being able to actively cope with the energy demand.

1 schematically illustrates the structure of an energy management system according to an embodiment of the present invention;
FIG. 2 illustrates a regional energy management system by binding an energy management system according to an embodiment of the present invention to a hierarchical network; FIG.
3 is a flowchart illustrating a process of monitoring energy amount in a hierarchical energy management system according to an embodiment of the present invention.
4 is a flowchart illustrating a process of distributing resources in a hierarchical energy management system according to an embodiment of the present invention.
5 is a flowchart illustrating a method for relaying resource transactions among unit energy management apparatuses according to an embodiment of the present invention.
6 is a block diagram schematically illustrating an internal structure of an upper layer energy management apparatus for relaying resource transactions between unit energy management apparatuses according to an embodiment of the present invention.

The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated and described in the drawings. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

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

FIG. 1 is a view schematically showing the structure of an energy management system according to an embodiment of the present invention.

Referring to FIG. 1, an energy management system according to an embodiment of the present invention includes at least one unit energy management device 110 and at least one energy consumption device 120. Here, the energy consuming device is an energy consuming power device, for example, an air conditioner, a lamp, an electricity, a heating and cooling appliance, or the like.

1, the unit energy management apparatus 110 includes an energy storage device 130 for selectively storing energy and an energy generation device 140 for generating energy in addition to the energy consumption device 120 You may.

The unit energy management apparatus 110 also performs energy control management and monitoring of the energy consumption apparatus 120, the energy storage apparatus 130, and the energy generation apparatus 140 managed by the corresponding unit energy management apparatus 110 (Hereinafter, referred to as a power network). It is natural that the unit energy management apparatus 110 can distribute power through an independent separate power network.

2, the unit energy management apparatus 110 may include a plurality of hierarchical structures. This will be described in more detail in Fig.

Each of the unit energy management apparatuses 110 may calculate the energy usage of various power devices included in the lower unit energy management system (for example, a home, a building, a factory, etc.) And the use of energy by the supply and demand phase of energy supply). Each of the unit energy management apparatuses 110 may be configured to calculate the amount of energy required for each of the various power devices included in the lower unit energy management system, the amount of energy that can be saved according to the unit price of each energy supply and demand stage, The amount of energy that can be supplied from the energy storage device 130 in consideration of the amount of energy that can be supplied through the power generation device 140 and the energy state by energy supply and demand stages is controlled or the distribution of resources for efficient use of resources of each power device is controlled .

Here, the energy supply and demand stage is determined by taking into consideration the amount of spare energy according to the amount of energy supply and energy consumption, and the energy sale / purchase and additional energy supply can be applied differently depending on the energy supply and demand stages.

The limits for energy supply by energy supply and demand, the unit price for energy supply, and the selling price or purchase price for selling or buying stored energy or produced energy to other users can be determined differently. The selling price or purchase price may be set differentially by each user or may be differentially set according to the energy supply and demand stage by the unit energy management device.

For example, in the case of emergency devices, heaters, air conditioners, and the like among the power devices, the energy use class is set to the first class, the TV and the electromagnetic cooker are set to the second class And the energy use class of the washing machine or the refrigerator is set to the third grade, and the energy use class may be set to the fourth grade for the electric lamp, dishwasher, and reserve power.

It is also assumed that the energy supply and demand stage is divided into a first stage (green stage), a second stage (yellowing alarm stage), a third stage (red warning stage), and a fourth stage (blackout stage). At this time, the first stage (green stage) may be provided with a reserve power amount so that sufficient energy can be used in all power devices according to all energy use classes.

The second stage (yellow stage) is the step of recommending restraint of energy use. It can limit the energy supply limit and raise the unit price for energy supply. In addition, in the case of the second stage (yellow caution phase), additional costs may be required in addition to the unit price for additional supply if the user wishes to use additional energy. In addition, the third stage (red alert phase) , Which does not allow any additional energy supply other than the amount of energy supplied by the other energy consuming device. That is, in the case of the third step (red warning step), the energy used in the specific energy consuming device is turned off, the additional remaining energy is limited and the additional energy is supplied to the other energy consuming device, / Buy price can be determined. In addition, the third stage (red alert phase) may be allowed to sell / buy energy sources in other detail unit energy management systems (eg, other buildings, other factories, other homes, other areas, etc.).

The fourth stage (blackout stage) is a stage in which a blackout is anticipated and prohibits the sale / purchase of energy. The energy consumption is limited by restricting the use of energy amount exceeding the limit of each energy consuming device (i.e., power device) So that a reserve amount of electricity can be secured. In the fourth step (blackout step), the energy amount of all the available energy storage devices is secured to secure a reserve energy amount, and additional energy production can be promoted through operation of the energy generation device.

FIG. 2 is a diagram illustrating a regional energy management system by binding an energy management system according to an embodiment of the present invention to a hierarchical network.

Referring to FIG. 2, the regional energy management system according to an exemplary embodiment of the present invention includes at least one unit energy management device 210 and at least one upper layer energy management device 220.

As shown in FIG. 2, the unit energy management apparatus 210 and the upper layer energy management apparatus 220 are connected in a hierarchical structure.

In FIG. 2, only the first layer is described for the upper layer energy management apparatus 220 in order to facilitate understanding and explanation. However, as shown in FIG. 1, the upper layer energy management apparatus includes a plurality of layers .

Each unit energy management device 210 monitors the amount of energy of various power devices located in each unit area (for example, a home, a building, a factory, etc.), and performs operations such as resource distribution for efficient resource use of each power device As shown in FIG.

At least one of the plurality of unit energy management devices 210 may be an energy storage device that supplies energy to each unit area.

Each of the unit energy management apparatuses 210 collects the energy usage amounts of the respective devices located in the respective unit areas, and transmits the collected energy usage amounts to the upper layer energy management apparatus 220. At this time, each of the unit energy management apparatuses 210 may collect the energy usage amount according to the grade of each device. Here, the rating may be a priority for resource usage of each device. For example, emergency lights, heaters, air conditioners, etc. in the device can be set to a first class and an energy use rating. The TV and the electric rice cooker are set to the second grade and the energy use class is set, and the washing machine, the refrigerator and the like are set to the third grade and the energy use class is set, and the lamp, the dishwasher and the reserve power are set to the fourth class .

In addition, each unit energy management device 210 monitors energy usage for devices located in each unit area periodically / non-periodically, and when a change occurs in the energy usage amount, it is reported to the upper layer energy management device 220 can do.

In addition, each unit energy management device 210 collects energy usage amounts of devices located in each unit area, and then receives resources corresponding to the total energy usage amount from the upper layer energy management device 220, And can be distributed to each of the located devices.

At this time, each of the unit energy management apparatuses 210 may distribute the resources to the devices differently based on the resource amount (referred to as a reserve resource amount) distributed from the upper layer energy management apparatus 220 have.

In one embodiment of the present invention, a resource means a power resource and should be interpreted in the same sense as energy.

The upper layer energy management apparatus 220 functions to distribute resources to each unit energy management apparatus 210 based on the energy usage amount collected from the lower layer energy management apparatus, that is, the unit energy management apparatus 210.

In distributing the resources, the upper layer energy management device 220 may distribute the resources differentially to each unit energy management device based on the reserve resource amount secured through the next higher layer energy management device 220 or the utility.

The upper layer energy management device 220 may also be configured to perform a resource transaction between the unit energy management devices 210 when the reserve resource amount is not sufficient at the time of requesting additional energy distribution from at least one unit energy management device 210 of each unit energy management device 210. [ May be relayed and redistributed. This will be described in more detail with reference to FIG. 5 below.

3 is a flowchart illustrating a process of monitoring energy amount in a hierarchical energy management system according to an embodiment of the present invention.

A first unit energy management device, a second unit energy management device, a third unit energy management device, and a third unit energy management device for managing the first building, the second building, the third building and the fourth building, respectively, It is assumed that the fourth unit energy management device is located. Also, at least one of the first to fourth unit energy management devices may be an energy storage device.

An energy management apparatus that integrally manages the first to fourth unit energy management apparatuses for convenience of understanding and explanation will be referred to as an upper hierarchy energy management apparatus. It is a matter of course that the upper layer energy management apparatus can have a plurality of hierarchical structures.

In step 310, each unit energy management apparatus sets energy usage amount and energy use level of each power device.

Here, the energy use class represents the priority of distribution of resources according to the importance of each power device.

The energy use class can be classified into n (natural number) class. In the embodiment of the present invention, it is assumed that the first class has the highest importance of resource use and the nth class has the lowest importance of resource use.

For example, among electric power devices, emergency lights, heaters, air conditioners and the like can be set to the first class and the energy use class can be set. The TV and the electric rice cooker are set to the second grade and the energy use class is set, and the washing machine, the refrigerator and the like are set to the third grade and the energy use class is set, and the lamp, the dishwasher and the reserve power are set to the fourth class .

It is a matter of course that the above-described energy use level for each power device is one embodiment for convenience of understanding and explanation, and the degree of energy use and grade classification for each power device can be different.

In step 315, each unit energy management device 210 sets selling price data for resource selling criteria, respectively.

For example, each unit energy management device may set resource trading standards for each grade differently.

Here, the resource sales standard for each grade can set the sales criterion for energy amount excluding the minimum energy amount for each grade and the minimum energy amount for each grade.

For example, in the case of the first class, it can be set as the selling target, and the minimum guaranteed energy amount (i.e., the minimum used energy amount) for the first class can be set.

In the case of the second grade, the selling standard can be set to twice the unit price, and the amount of energy to be sold can be set to 6 watts (watt) compared to the selling standard.

In the case of the third grade, the sell standard can be set at 1.8 times the unit price, the energy amount to be sold can be set to 7 watts (watt), and the fourth grade can be set at 1.5 times the unit price , And the fourth-level sell target energy amount may be set to the total energy amount.

In this way, each unit energy management apparatus 210 can set the resource selling criterion separately in consideration of the energy amount for each grade.

In step 320, each unit energy management device 210 transmits at least one of the energy usage amount and selling price data to the upper layer energy management device.

Here, the amount of energy used may be the total amount of energy used for each grade or the total amount of energy used for all grades.

In step 325, the upper layer energy management device 220 calculates the total amount of used energy by summing at least one of the energy usage amount and the resource sales amount collected through each unit energy management device 210 to calculate the reserve amount (energy amount) .

The upper layer energy management apparatus 220 can request resource distribution including the total amount of used energy calculated from the next higher layer energy management apparatus 220 and can calculate the total amount of used energy calculated from the next higher layer energy management apparatus 220 (Amount of energy) can be distributed based on the amount of energy.

In step 330, the upper layer energy management device 220 transmits a response including at least one of the calculated total used energy amount and the ensured reserved energy amount to each unit energy management device 210. [

At this time, the upper layer energy management device 220 may divide the amount of the preliminary energy into each grade. In such a case, the preliminary energy amount for each grade may be transmitted to each unit energy management apparatus 210. [

In step 335, when a variation occurs in the amount of energy used, each unit energy management apparatus 210 transmits the changed amount of energy to the upper layer energy management apparatus 220 and reports it. The amount of the fluctuating energy may be a fluctuating amount of energy depending on the grade. Of course, the amount of fluctuating energy may be the sum of the amount of fluctuating used energy.

Of course, each of the unit energy management apparatuses 210 may periodically report the amount of energy and the amount of energy used by each grade to the upper layer energy management apparatus 220.

In FIG. 3, the procedure of reporting and monitoring the amount of energy between each unit energy management apparatus and the upper layer energy management apparatus is described. Hereinafter, a process of distributing resources from the upper layer energy management apparatus in each unit energy management apparatus will be briefly described with reference to FIG.

4 is a flowchart illustrating a process of distributing resources in a hierarchical energy management system according to an embodiment of the present invention.

In step 410, the unit energy management device sums up the amount of energy of each power device by grade and then requests resource allocation to the upper layer energy management device 220. Here, the request for resource allocation may include the amount of energy required for distribution (or the amount of energy for each grade).

In step 415, the upper layer energy management apparatus 220 sums all the required energy amounts required by the respective unit energy management apparatuses.

In step 420, the upper layer energy management apparatus 220 determines whether the summed required energy amount exceeds the preliminary energy amount held by the upper layer energy management apparatus 220 in question.

If the required energy amount exceeds the reserve energy amount, in step 425, the higher-layer energy management apparatus distributes the resources differentially in consideration of the amount of energy required in each unit energy management apparatus.

That is, when the amount of the reserve energy possessed by the upper layer energy management apparatus is insufficient, the upper layer energy management apparatus can distribute the resources in such a manner that the resources are distributed in the order of importance.

Of course, according to another embodiment, it is needless to say that the upper layer energy management apparatus may request additional resource allocation to the next higher layer energy management apparatus, allocate additional resources, and distribute resources.

However, if the required energy amount is less than the preliminary energy amount, in step 430, the upper layer energy management apparatus distributes the resources according to the amount of energy required by each unit energy management apparatus.

5 is a flowchart illustrating a method of relaying resource transactions between unit energy management apparatuses according to an embodiment of the present invention.

In step 510, the upper layer energy management device 220 receives an additional distribution request of resources from at least one unit energy management device. Hereinafter, a unit energy management apparatus requesting additional distribution of resources will be referred to as a purchase request energy management apparatus in order to facilitate understanding and explanation. Here, the resource addition distribution request may include the buy price data.

Purchase price data may include purchase price data and purchasing energy amount for each grade. In addition, the purchase price data may be different for each grade depending on the purchase price data.

In another example, the buy price data may include a plurality of buy price reference data for each rank. That is, the purchase price data may include the first purchase price standard for each grade and may include the second purchase price standard in case the first purchase price standard is not satisfied.

Also, the buy price data may include the buy price limit data. Buying marginal price data can be a high price that is too expensive to sell and will not buy. Purchase marginal price data may also be set for each grade.

In step 515, the upper layer energy management apparatus 220 determines whether the reserve resource amount is insufficient at the time of the resource addition distribution request of the purchase request energy management apparatus.

If the reserve resource amount is not insufficient, the upper hierarchy energy management apparatus 220 may further allocate resources by the amount of purchased energy based on the unit price provided by the utility in step 520. [

However, if the reserve resource amount is insufficient, in step 525, the upper layer energy management apparatus 220 transmits the purchase transaction request to each unit energy management apparatus to collect the selling price data. Of course, when the amount of spare resources is insufficient, the upper layer energy management apparatus may further distribute and provide resources from another upper layer energy management apparatus or a next higher layer energy management apparatus. This is different from the resource transaction between each unit energy management device, so this will not be described in FIG.

Here, the selling price data includes a price criterion for selling resources in each unit energy management device.

The selling price data may be set differently for each grade.

In addition, the selling price data may include the amount of sellable energy available for sale in each unit energy management device. At this time, the amount of energy available for sale may include the amount of energy available for each grade.

In step 530, the upper layer energy management device 220 redistributes the resource transaction by redistributing the resource of the unit energy management device to the purchase request energy management device using the purchase price data and selling price data.

According to an embodiment of the present invention, the upper layer energy management apparatus 220 may compare the purchase price data with the selling price data, and as a result, the resource of the unit energy management apparatus corresponding to the selling price data having the minimum price difference, And can redistribute resource transactions to management devices.

In the case where the price data for each category includes the price data for each category and the selling price data for each category, the upper layer energy management device 220 compares the price criteria for each category, Can be relayed by redistributing the resources of the buyer to the purchase request energy management device.

If the amount of available energy contained in the selling price data of one unit energy management device is insufficient compared with the amount of purchased energy included in the buying price data, the price of the other energy managing device The resource can be relayed by redistributing the resource to the buying target energy management device.

At this time, the cost may be paid based on the selling price data to the unit energy management device 210 that redistributes (i.e., sells) the resources in accordance with the purchase price data, and the total usage amount used by the unit energy management device 210 It may be deducted and deducted for the payment of the fee for

For example, there is a first unit energy management apparatus for managing the resource distribution of the first building, a second unit energy management apparatus for managing the resource distribution of the first building, a third unit energy management apparatus for managing the resource distribution of the third building, A unit energy management device, and a fourth unit energy management device exist. Here, it is assumed that the fourth unit energy management device is an energy storage device.

The first building uses 8 watts, the second class device uses 7 watts of resources, the third class device uses 6 watts of resources, the fourth class device uses 9 watts of resources .

The second energy management device is using 9-watt resources for a first-class device, a second-class device, a third-class device, and a fourth-class device, respectively. 4 Watts is set to be sold if the selling price is paid twice, and 5 Watts of 9 Watts of Class 3 is set to be sold if 1.5 times the selling price is paid. Assume that the entire watt is set at selling price data (referred to as first selling price data) when the selling price is 1.2 times as much as selling is possible.

Also, the third energy management device is using 9-watt resources for the first-class device, the second-class device, the third-class device, and the fourth-class device, respectively. 3 watt is set to be sold when a 2.5-fold selling price is paid, and 6 watt of 9 watt of 3 rd grade is set to be sold when a 2-fold selling price is paid. Of 9 watt of 4th grade, 9 Assume that the entire watt is set to sell price data (referred to as second selling price data) when the selling price is paid 1.5 times as much as selling is possible.

In addition, the fourth unit energy storage device, which is an energy storage device for supplying energy to a specific unit area, is capable of selling the reserve resource when the selling price of 1.5 times is paid without grading and sells price data (third selling price data) .

Here, it is assumed that an additional resource allocation of an additional 20 watts is requested from the unit area of the first unit energy management apparatus.

According to the first embodiment, the upper layer energy management apparatus collects the first to third selling price data from the second to the fourth unit energy management apparatuses, and then analyzes the selling price data to obtain a second unit Relaying trades at a price of 1.2 times the unit price (the unit price offered by the utility) of the fourth grade 9 watts of the energy management device, then 5 watt of the third grade of the second unit energy management device, You can relay the trades at 1.5 times the unit price of 6 watts of the fourth grade of the energy management device.

According to the second embodiment, the selling price data may include the selling price for each grade, and in such a case, the upper layer energy management apparatus can relay the resource transaction in the order of the lowest selling price, respectively.

In addition, according to the third embodiment, the upper layer energy management apparatus can make the resources of the fourth unit energy management apparatus, which is the energy storage device, the top priority.

That is, the upper layer energy management apparatus may relay the resource transactions in consideration of the priority of each unit energy management apparatus.

According to the fourth embodiment, the buy price data may include a buy price or buy price reference for each rank. In such a case, the upper layer energy management apparatus 220 may relay the resource transaction based on the buy price data.

According to the fifth embodiment, the upper-layer energy management apparatus 220 may allocate resources of the unit energy management apparatus having the amount of sellable energy most similar to the total amount of purchased energy to the resources based on the purchase price data, Transactions can be relayed.

6 is a block diagram schematically illustrating an internal structure of an upper layer energy management apparatus for relaying resource transactions between unit energy management apparatuses according to an embodiment of the present invention.

6, an upper layer energy management apparatus 220 according to an embodiment of the present invention includes a communication unit 610, a selling criterion setting unit 615, a buying criterion setting unit 620, a resource trading relay unit 625 ), A memory 630, and a control unit 635. [

The communication unit 610 transmits and receives data to and from other devices (for example, each unit energy management device, an upper layer energy management device, and the like).

The selling criterion setting unit 615 collects selling price data from each unit energy management apparatus 210, and sets the selling price energy data and the selling price data based on the collected selling price data.

The purchase reference setting unit 620 collects purchase price data from each unit energy management apparatus, and sets the purchase energy amount and purchase price reference data for each grade based on the collected purchase price data.

The resource trading relay unit 625 uses at least one of the available energy amount, the selling price reference data, the purchase energy amount, and the purchase price reference data for each grade set in the selling criterion setting unit 615 and the buying criterion setting unit 620 And relay the resource transaction. Since this is the same as that described above with reference to FIG. 5, redundant description will be omitted.

The memory 630 monitors the degree of resource use of each unit energy management apparatus in the upper layer energy management apparatus 220 according to an embodiment of the present invention and stores various algorithms and various data necessary for relaying resource transactions .

The control unit 635 may control the internal components of the upper layer energy management apparatus 220 according to an embodiment of the present invention (e.g., the communication unit 610, the selling criterion setting unit 615, ), The resource transaction relay unit 625, the memory 630, and the like).

Meanwhile, the resource distribution method according to an embodiment of the present invention may be implemented in a form of a program command that can be executed through a variety of means for processing information electronically and recorded in a storage medium. The storage medium may include program instructions, data files, data structures, and the like, alone or in combination.

Program instructions to be recorded on the storage medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of software. Examples of storage media include magnetic media such as hard disks, floppy disks and magnetic tape, optical media such as CD-ROMs and DVDs, magneto-optical media such as floptical disks, magneto-optical media and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as devices for processing information electronically using an interpreter or the like, for example, a high-level language code that can be executed by a computer.

The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the invention may be varied and varied without departing from the scope of the invention.

210: Unit energy management device
220: Upper layer energy management device

Claims (18)

Energy management devices;
At least one energy consuming device;
At least one energy storage device; And
At least one energy generating device,
Wherein the energy management device controls resource distribution in accordance with energy consumption, production or storage of the energy consumption device, the energy storage device, and the energy generation device.

The method according to claim 1,
The energy management device includes:
Wherein the energy management system monitors the energy usage of the energy consuming device based on at least one of the energy use level of the energy consumption device and the user's required level to control the resource distribution.

The method according to claim 1,
The energy management device includes:
Wherein the energy storage device distributes the energy to the energy consuming device in a manner that the energy consuming device differentially consumes energy according to the energy supply and demand stage, and the amount of energy stored in the energy storage device or the amount of energy produced in the energy generating device, And to be distributed to the energy consuming device. The method of claim 3,
The energy supply and demand is determined in consideration of the amount of energy supplied and the amount of energy reserved for the energy consumption,
Wherein an energy supply amount to be supplied to the energy consuming device, a unit price according to energy supply, a purchase price or a selling price for buying or selling energy are different. At least one first layer energy management device; And
At least one second layer energy management device,
Wherein the first layer energy management device and the second layer energy management device are connected to the upper and lower layers. 6. The method of claim 5,
Wherein the second layer energy management apparatus is located in an upper layer of the first layer energy management apparatus,
Wherein the upper layer distributes resources of the lower layer energy management apparatus. 6. The method of claim 5,
The first hierarchical energy management apparatus is a unit energy management apparatus for distributing resources of individual unit areas,
At least one of which is an energy storage device that provides resources to the individual areas. A method for relaying resource transactions in an upper layer energy management apparatus connected in hierarchical structure with at least one unit energy management apparatus,
Receiving an energy addition distribution request from the first unit energy management apparatus;
Receiving selling price data from the second unit energy management device in accordance with the additional distribution request; And
And relaying the resource transaction to the first unit energy management device based on the selling price data. 9. The method of claim 8,
Wherein the energy additional distribution request includes an additional requested energy amount,
The relaying of the resource transaction comprises:
And relaying the resource transaction in the order of the lowest available resource based on the selling price data. 9. The method of claim 8,
Wherein the energy additional distribution request includes purchase price data,
The relaying of the resource transaction comprises:
And distributing the resources of the second unit energy management apparatus with a difference in the result of comparison between the purchase price data and the selling price data to the first unit energy management apparatus, thereby relaying the resource transaction. 11. The method of claim 10,
The purchase price data includes data on purchase price data for each grade,
The relaying of the resource transaction comprises:
And relaying the resource transaction differentially for each rank based on the purchase price reference data for each rank. 9. The method of claim 8,
The selling price data includes sales price data for each rank,
The relaying of the resource transaction comprises:
And relaying the resource transaction to the first unit energy management apparatus in a different manner for each rank based on the sales price reference data for each rank. 13. The method according to claim 11 or 12,
Wherein each of the classes is a priority of resource distribution. 11. The method of claim 10,
Wherein the selling price data further includes an available energy amount,
The purchase price data further includes a purchase amount of energy,
The relaying of the resource transaction comprises:
The selling price data of the second unit energy management apparatus is redistributed to the first unit energy management apparatus by the purchase amount of energy in the order of the difference in the result of comparison between the buying price data and the selling price data, Wherein the resource transaction relay method comprises: 11. The method of claim 10,
The relaying of the resource transaction comprises:
And does not relay the resource transaction when the selling price data exceeds the reference value based on the buying price data. 9. The method of claim 8,
The relaying of the resource transaction comprises:
And the resource transaction is relayed in consideration of the reserve resource amount. 17. The method of claim 16,
The preliminary resource amount includes an amount of energy available for each grade,
The relaying of the resource transaction comprises:
And the resource transaction is relayed in consideration of the amount of energy available for each grade. 9. The method of claim 8,
Wherein at least one of the unit energy management apparatuses is an energy management apparatus for providing resources to the unit energy management apparatus,
The relaying of the resource transaction comprises:
And redistributing resources of the energy management apparatus to the first unit energy management apparatus based on the selling price data.

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