KR101821807B1 - Power demand response management server and method of apartment house - Google Patents

Abstract

The present invention relates to a power demand reaction management server for an apartment and a method thereof. The power demand response management server generates and manages the optimal values of the power demand reaction capacity of the apartment. According to the present invention, the power demand reaction management server includes: a building demand reaction capacity calculation unit which calculates the demand reaction capacity for each building from a complex demand reaction capacity with reference to the ratio of the power load of each building and the power load of the complex; a household demand reaction capacity calculation unit which calculates the demand reaction capacity for each household from the demand reaction capacity for each building with reference to the ratio of the demand reaction capacity for each household and the demand reaction capacity of each building; a household power load reconfiguration scenario generation unit which generates the household power load reconfiguration scenarios satisfying the demand reaction capacity of each household with reference to the weather information and household power load configuration information; a proposal information notification unit for notifying household demand reaction proposal information including the household demand reaction capacity and the household power load reconfiguration scenarios; and a power demand reaction capacity determining unit which determines the power demand reaction capacity including the household power demand reaction capacity when user authentication information for the household power demand reaction proposal information is received through a household user terminal.

Description

[0001] POWER DEMAND RESPONSE MANAGEMENT SERVER AND METHOD OF APARTMENT HOUSE [0002]

The present invention relates to a power demand response management server and method in a multi-family house. More particularly, the present invention relates to a power demand response management server and method of a apartment house capable of generating and managing an electric power demand response capacity of an apartment house at an optimized value.

Generally, the power grid is designed so that the demand and supply of electricity operate in harmony with each other. At present, it is very difficult to adjust the electric power demand in the operation of the power grid because it depends on the individual's electricity use. Therefore, electric power supply is always operated so as to follow electric power demand.

However, since electric power demand has a characteristic that fluctuates with time, the electric power supply is always supposed to meet the maximum demand.

In Korea, the demand for maximum 10% is actually 3 days out of 365 days a year. Therefore, there may be a situation where many generators are waiting all year round for these three days. This is as uneconomic and inefficient as maintaining several highway facilities that are not used for one year for the three days of the Chuseok holiday.

If the demand can be reduced by 10% during the three days of the peak demand in a year, the operation of the power grid will be very stable, and in the case of Korea, there will be no need to construct five or six large nuclear power plants. .

In this regard, Demand Response (DR) has led to the demand management technology related to the provision of incentives by the voluntary energy saving of the consumers.

The power demand response is very difficult to adjust because the number of users is large and the power demand is increased, so that the user reacts to reduce the power use. It is very difficult for the power operator to adjust the current power system. Even if it does not exist, it is not an observation.

In particular, a simple electricity tariff system does not motivate the consumer to voluntarily respond. Therefore, in the United States and Europe, a basic demand response is generated based on various tariffs, And more active demand response services are being applied through sales in the market.

On the other hand, since the demand of small and medium-sized enterprises is small, the demand for response is not so motivated. Therefore, Load Aggregator (LA) operators are collecting the demand of each individual.

Considering the domestic environment in which apartment houses, such as apartment houses, are supplied on a large scale, implementing a power demand response service on a unit basis of the apartment complex can be considered as a measure.

However, unlike industrial facilities such as factories where uniform management is possible, it is difficult to appropriately calculate the demand capacity of the electric power demand for apartment houses composed of a large number of households, Accordingly, there is a problem that it is difficult to provide a stable power demand response service satisfying the consumer because the entire power situation can be largely fluctuated due to the internal circumstances of each household even during the execution of the power demand reaction service.

Korean Patent Publication No. 10-2015-0048601 (Published Date: May 07, 2015, entitled: Collective Transaction Service System and Method for Small Demand Response Resources Utilizing Open Power Usage History Data Based on Social Network Service)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a power demand response management server and method of a apartment house capable of generating and managing an electric power demand response capacity of a apartment house with optimized values.

Further, in the process of collecting surplus electric power and bidding for electric power demand reaction, the present invention estimates the optimal electric power demand reaction capacity that the generations constituting the complex can tolerate and bids, In the process of performing the power demand response procedure according to the capacity, the electric power demand of the apartment house, which adaptively changes the electric power block object according to the feedback from the generations constituting the apartment, And an object of the present invention is to provide a reaction management server and method.

In order to solve such a problem, a power demand response management server of a multi-house according to the present invention includes a demand demand reaction capacity calculation unit for calculating a demand demand response capacity only from a demand response capacity with reference to a ratio of a power load and a power load, A demand reaction capacity calculation unit for each household to calculate a demand response capacity for each household from the demand response capacity by the reference with reference to the ratio of the power load by each household to the power load by household, A power generation reconstruction scenario generation unit for each generation that generates a scenario of a power load reconstruction for each household that satisfies the demanded response capacity of each household; a demand response suggestion information generation unit for each generation including the demand response capacity for each generation and the power load reconstruction scenario for each generation; Demand Response by Generation to Notify User Terminal And a power demand reaction capacity determining unit for determining the power demand reaction capacity including the demand response capacity for each household when the user approval information on the demand response suggestion information for each household is received through the notification unit and the household user terminal do.

In a power demand response management server of a multi-family house according to the present invention, the power load reconfiguration scenario for each household includes power demand device specifying information, which is information for specifying power demand devices capable of power interruption and power adjustment for each household, And power demand device control time information, which is information on the time of shutdown and power control.

In the power demand response management server of the apartment house according to the present invention, the power load reconstitution scenario generation unit for each household may calculate the generation power amount according to the execution of the power load reconstruction scenario for each household and the demand response capacity calculation unit for each household The demand response capacity for each household and the power load reconstruction scenario for each household calculated by the demand reaction capacity calculation unit for each household are changed so that the difference between the demand response capacity for each generation and the demand reaction capacity for each household is less than the threshold, And the difference between the demand response capacity of each generation and the demand response capacity of each generation is calculated as a margin to the demand demand reaction capacity by the margin.

In the power demand response management server of the apartment house according to the present invention, the power load reconstitution scenario generation unit for each household may be configured such that when receiving counter-user information on demand response suggestion information for each household through the household user terminal, And re-establishing a separate power load reconfiguration scenario.

The power demand response management server of the apartment house according to the present invention further includes a feedback processor for processing user feedback on the demand response capacity of each household determined by the power demand reaction capacity determining unit, When satisfaction feedback information on the demand response capacity is received, the power demand reaction capacity determined by the power demand reaction capacity determining unit is finally finalized, and when unsatisfied feedback information on the demand response capacity for each generation is received, And the dynamic demand response capacity calculation unit recalculates the dynamic demand response capacity after changing the demand response capacity.

In the power demand response management server of the apartment house according to the present invention, the information on the power load per household is received from the power meter of each household and processed and stored into the electric power history data in the electric power history DB, The configuration information is information estimated by applying the history data stored in the power amount history DB to the machine learning algorithm.

In the power demand response management server of the apartment house according to the present invention, the information on the power load per household is information received from the intelligent power meter that measures the power consumption of power demand devices of each household, And the configuration information is information obtained from the information received from the intelligent power meter.

In the power demand response management server of the apartment house according to the present invention, the demand demand reaction capacity calculation unit calculates the demand demand reaction capacity by multiplying the value obtained by dividing the power load amount by the simple power load with the simple demand reaction capacity .

In the power demand response management server of the apartment house according to the present invention, the demand demand reaction capacity calculation unit may calculate the electricity demand response history data stored in the power demand response history DB Algorithm to calculate the demand demand reaction capacity from the demand demand reaction capacity.

In the power demand response management server according to the present invention, the demand response capacity calculation unit for each household multiplies a value obtained by dividing the power load amount for each household by the power load amount for each household by the dynamic demand response capacity, And the capacity is calculated.

In the power demand response management server of the apartment house according to the present invention, the demand response capacity calculation unit for each household may include a power demand response history data stored in the power demand response history DB, And calculates a demand response capacity for each generation from the demand response capacity by the same.

The power demand response management method of a apartment house according to the present invention is characterized in that the demand demand reaction capacity calculation step of the same step calculates the demand demand reaction capacity by the dynamic demand from the demand response capacity only by referring to the ratio of the power load and the power load by each node A demand reaction capacity calculation step for each household to calculate the demand response capacity for each household from the demand response capacity by the reference by referring to the ratio of the power load by household to the power load by household, A scenario generating unit generates a power load reconstruction scenario for each household to generate a power load reconstruction scenario for each household satisfying the demand response capacity for each household by referring to the power load configuration information and weather information for each household, The demand response capacity of each generation, A demand response proposal information notification step and a power demand response capacity determination step for each household that notifies the generation user demand information including the power load reconstruction scenario including the generation demand response request information, And a power demand reaction capacity determining step of determining the power demand reaction capacity including the demand response capacity for each household when the user demand information is received.

In the power demand response management method for a multi-family house according to the present invention, the power load reconfiguration scenario for each household includes power demand device specifying information, which is information for specifying power demand devices capable of power interruption and power adjustment for each household, And power demand device control time information, which is information on the time of shutdown and power control.

In the power demand re-formation scenario generation step of the household according to the present invention, in the generation step of the power load re-formation scenario for each household, the generation power amount according to the execution of the power load re- The demand reaction capacity for each household and the power load reconstruction scenario for each household calculated by the demand reaction capacity calculation unit for each household are changed so that the difference between the demand response capacity for each household and the demand reaction capacity for each household is below the threshold, The difference between the demand response capacity of each generation calculated by the calculation unit and the demand response capacity of each generation is accumulated in the margin demand response capacity.

In the method of managing a power demand response of a multi-family house according to the present invention, in the generation of a power load re-formation scenario for each household, when receiving counter-user information on the demand response proposal information for each household through the household user terminal, And reconstructing a generation-by-generation power load reconstruction scenario.

The power demand response management method of the present invention further includes a feedback processing step of processing user feedback on a demand response capacity of each household determined in the power demand reaction capacity determination step, When satisfaction feedback information on the demand response capacity for each household is received, the power demand response capacity determined by the power demand response capacity determination unit is finally determined, and when unsatisfied feedback information on the demand response capacity for each household is received, And the dynamic demand capacity calculation unit may re-calculate the dynamic demand response capacity after the dynamic demand capacity is changed.

According to the present invention, there is provided an electric power demand response management server and method of a apartment house capable of generating and managing an electric power demand response capacity of a apartment house at an optimized value.

In addition, in the process of collecting surplus power and bidding for electricity demand reaction, the apartment complex will calculate and bid on the optimal capacity demand capacity that can be tolerated by households constituting the complex, A power demand reaction management server of the apartment house, which performs a stable power demand response procedure by adaptively changing the electric power shutdown object according to the feedback from generations constituting the complex in the course of performing the power demand response procedure And a method is provided.

FIG. 1 is a diagram illustrating a system configuration in which a power demand response management of a apartment house is performed according to an embodiment of the present invention.
2 is a diagram illustrating a power demand response management server of a multi-family house according to an embodiment of the present invention,
3 is a diagram illustrating a power demand response management method for a multi-family house according to an embodiment of the present invention
4 is a diagram for explaining a specific operation of generation of a power load reconstruction scenario for each generation in the temporal examples of the present invention.

It is to be understood that the specific structural or functional description of embodiments of the present invention disclosed herein is for illustrative purposes only and is not intended to limit the scope of the inventive concept But may be embodied in many different forms and is not limited to the embodiments set forth herein.

The embodiments according to the concept of the present invention can make various changes and can take various forms, so that the embodiments are illustrated in the drawings and described in detail herein. It should be understood, however, that it is not intended to limit the embodiments according to the concepts of the present invention to the particular forms disclosed, but includes all modifications, equivalents, or alternatives falling within the spirit and scope of the invention.

The terms first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The terms may be named for the purpose of distinguishing one element from another, for example, without departing from the scope of the right according to the concept of the present invention, the first element may be referred to as a second element, The component may also be referred to as a first component.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between. Other expressions that describe the relationship between components, such as "between" and "between" or "neighboring to" and "directly adjacent to" should be interpreted as well.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, the terms "comprises" or "having" and the like are used to specify that there are features, numbers, steps, operations, elements, parts or combinations thereof described herein, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the meaning of the context in the relevant art and, unless explicitly defined herein, are to be interpreted as ideal or overly formal Do not.

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

FIG. 1 is a diagram illustrating a system configuration in which a power demand response management of a multi-family house is performed according to an embodiment of the present invention. FIG. 2 is a diagram illustrating a power demand response management server Fig. The present invention can be applied to both cases where the electric power demand reaction capacity is bid for the electric power demand reaction company and the electric power demand reaction is performed in the complex according to the winning electric power demand reaction capacity.

1 and 2, the power demand response management server 1 of the apartment house according to an embodiment of the present invention includes a demand demand capacity calculation unit 10, a household demand capacity calculation unit 20, Generation demand-response suggestion information notification unit 40, a power demand reaction capacity determination unit 50, and a feedback processing unit 60. The power demand re-

The demand-demand capacity calculation unit 10 calculates the demand demand capacity from the demand-demand capacity only by referring to the ratio of the power load and the power load by the dynamic cost.

As an example, the dynamic demand capacity calculation unit 10 may be configured to calculate the dynamic demand demand capacity by multiplying the demand power capacity by the dynamic power capacity alone. This can be expressed as the following equation

[Equation 1]

Demand Response Capacity by Mode = Only Demand Reaction Capacity × Power Load by Equivalent / Complex Power Load

As another example, the dynamic demand response capacity calculation unit 10 may apply the electric power demand response history data stored in the power demand response history DB 100 to the machine learning algorithm in association with the past power demand response capacity calculation, And calculate the demand response capacity by the equation from the reaction capacity. Because the consumer's response to the electricity demand reaction can vary greatly depending on various factors, if the history data related to the calculation of the capacity demand response capacity in the past is sufficient in calculating the demand response capacity by the transition, Demand response capacity can be assigned appropriately for each phase.

The demand response capacity calculation unit 20 for each household calculates the demand response capacity of each household from the demand response capacity by the reference to the ratio of the power load per household to the power load per household.

As an example, the demand response capacity calculation unit 20 for each household may be configured to calculate the demand response capacity for each household by multiplying the value obtained by dividing the power load per household by the power load per household by the demand demand capacity by household. This can be expressed by the following equation (2).

[Equation 2]

Demand Response by Households = Demand Reaction Capacity by Dynasty × Power Load by Household / Power Load by Household

As another example, the demand response capacity calculation unit 20 for each generation applies the power demand response history data stored in the power demand response history DB 100 to the machine learning algorithm with respect to the past calculation of the power demand reaction capacity, And calculate the demand response capacity for each generation from the demand response capacity. Since the response of the consumer to the demand response can be greatly affected by various factors, similar to the calculation of the demand response capacity by the same time, the historical data related to the past demand calculation If it is secured, the demand response capacity of each household can be appropriately allocated to each household through machine learning.

As another example, if the power load configuration used in each household is known, it can be configured to reflect the amount of power consumed by the load of the user with high demand by season in the demand response capacity of each generation. If these factors are not reflected in the demand response capacity of each household, it is likely to infringe on the convenience of users of each household, and it will be difficult to obtain the consent of each household user for the power demand response.

Generation-by-Generation Power Load Reconfiguration Scenario Generation Unit 30 generates Generation-by-Generation Power Load Reconfiguration Scenario that meets household demand response capacity by referring to the power load configuration information and weather information for each generation.

For example, the generation-by-generation power load reconfiguration scenario includes power demand device specific information, which is information for specifying power demand devices capable of power cutoff and power control for each generation, and power demand device Control time information. That is, the generation power restructuring scenario for each household is information related to which power demand device is to be turned off at a certain time in each household.

The power load configuration information for each household is information about how much power demand devices use the power in each household. The weather information is information on the external environment, and may include information on temperature, precipitation, and the like. Such weather information may be collected by a weather sensor provided in each household or the like and transmitted to the power demand reaction management server 1 or may be information provided by an external institution to the power demand reaction management server 1. [

Information on the power load per household is received from the power meter of each household and processed and stored as power amount history data in the power amount history DB 200. The power amount configuration information for each household is stored in the power amount history DB 200 And may be information estimated by applying stored power amount history data to a machine learning algorithm. The means for estimating generation power load configuration information may be provided in the power amount history DB 200 or may be provided independently of the power amount history DB 200. [

As another example, the information on the power load per household is information received from the intelligent power meter that measures the power consumption of the power demand devices of each household, and the power load configuration information per household is obtained directly from the information received from the intelligent power meter Information. For example, the intelligent power meter may be an Energy Management System (EMS) device or an Advanced Metering Infrastructure (AMI) device or a smart meter. Since these intelligent power meters separately measure the power consumption data for each power demand device of each generation and transmit them to the power demand response management server 1, the power demand response management server 1 stores the data as a history In this case, the power load configuration information for each generation can be acquired based on actual data without using the estimation method.

For example, the generation-by-generation power load reconstitution scenario generation unit 30 generates the power demanded by the generational power amount and the demand reaction capacity by generation calculated by the generation demand power generation capacity calculation unit 20 By-household demand response capacity calculation unit 20 and the generation-by-generation power load reconfiguration scenario so that the difference between the household demand response capacity calculation unit 20 and the household demand reaction capacity calculation unit 20 ), And the difference between the demanded response capacity of each household and the demanded response capacity of each household by the margin.

The reason for this configuration is as follows. In other words, there is no way to control the amount of power used except for the ON / OFF method in most of the power demand devices provided in each household. In the case of the air conditioner capable of temperature control, the power consumption can be accurately adjusted Therefore, when calculating the above power generation reconstruction scenario for each household, that is, when calculating the power load composition, there arises a difference from the requested demand capacity for each generation. Generally, in the case of apartment houses, about 10 to 60 households receive electricity through one transformer, so the sum of the demand response capacities for each household must be a sum of the demand response capacities for each household, plus a certain margin. Since there is no problem in the reaction operation, the margin is secured through the configuration as described above.

For example, generation-by-generation power load reconstitution scenario generation unit 30 generates reverse power demand information for each household by the generation demand user notification unit 40, which will be described later, If so, it can be configured to regenerate generation-by-generation power load reconstruction scenarios.

The demand response information notification unit 40 for each household notifies the household user terminal of the demand response suggestion information including generation demand response capacity and generation load reconfiguration scenario.

When receiving the user approval information on the demand reaction suggestion information for each household via the household user terminal, the power demand reaction capacity determining unit 50 determines whether or not the demand response response determining unit 50 Provisionally determine the demand capacity of the electric power demand including the demand response capacity for each generation.

The feedback processing unit (60) processes user feedback on the demand response capacity of each generation determined by the power demand reaction capacity determining unit (50).

When the satisfaction feedback information on the demand response capacity for each household determined by the power demand reaction capacity determining section 50 is received, the feedback processing section 60 performs the power demand reaction determined by the power demand reaction capacity determining section 50 The demand response capacity calculation unit 10 calculates the demand response capacity after changing the demand response capacity when the dissatisfied feedback information for the demand response capacity for each household determined by the power demand reaction capacity determining unit 50 is received, The demand response capacity of the system is recalculated. That is, in the case of unsatisfied feedback, the demand response capacity calculation unit 10, generation demand capacity calculation unit 20, household power restructuring scenario generation unit 30, generation demand response request information reporting unit 40 ), The operation of the components including the power demand reaction capacity determining unit 50 is performed again from the beginning, and this procedure can be continuously performed until satisfaction feedback is received.

3 is a diagram illustrating a power demand response management method for a multi-family house according to an embodiment of the present invention. 3 and 4 can be used to explain the operation of the power demand reaction management server of the apartment house according to an embodiment of the present invention.

3, in step S10, a process is performed in which the dynamic demand reaction capacity calculation unit 10 calculates the dynamic demand response capacity only from the demand response capacity with reference to the ratio of the electric power load to the electric power load.

As an example, the step S10 may be configured so that the dynamic demand reaction capacity calculation unit 10 multiplies the value obtained by dividing the electric power load amount by dynamic power load only by the demand reaction capacity to calculate the dynamic demand response capacity.

As another example, step S10 is a step in which the dynamic demand response capacity calculation unit 10 stores the electric power demand response history data stored in the power demand response history DB 100 in association with the past power demand response capacity calculation, Can be applied to calculate the demand demand response capacity only from the demand response capacity. Because the consumer's response to the electricity demand reaction can vary greatly depending on various factors, if the history data related to the calculation of the capacity demand response capacity in the past is sufficient in calculating the demand response capacity by the transition, Demand response capacity can be assigned appropriately for each phase.

In step S20, a process of calculating the demand response capacity for each household from the demand response capacity of each household by referring to the ratio of the power load by household to the power load by household is performed by the demand response capacity calculation unit 20 for each household.

As an example, the step S20 may be configured to calculate the demand response capacity for each generation by multiplying the demand-response capacity for each household by the power demand load for each household divided by the power load for each household .

As another example, the step S20 is a step in which the demand response capacity calculation unit 20 for each household calculates the power demand response history data stored in the power demand response history DB 100 in relation to the past power demand reaction capacity calculation, To calculate the demand response capacity for each household from the demand demand capacity for each household. Since the response of the consumer to the demand response can be greatly affected by various factors, similar to the calculation of the demand response capacity by the same time, the historical data related to the past demand calculation If it is secured, the demand response capacity of each household can be appropriately allocated to each household through machine learning.

As another example, if the power load configuration being used in each generation is known, step S20 may be configured to reflect the amount of power consumed by the users with high demand of the user for each seasonal season, to the demand response capacity for each household. If these factors are not reflected in the demand response capacity of each household, it is likely to infringe on the convenience of users of each household, and it will be difficult to obtain the consent of each household user for the power demand response.

In step S30, generation-by-generation power load reconfiguration scenario generation unit 30 refers to power generation configuration information and meteorological information for each generation to generate generation-by-generation power load reconfiguration scenarios that satisfy the demand response capacity for each generation.

For example, the generation-by-generation power load reconfiguration scenario includes power demand device specific information, which is information for specifying power demand devices capable of power cutoff and power control for each generation, and power demand device Control time information. That is, the generation power restructuring scenario for each household is information related to which power demand device is to be turned off at a certain time in each household.

The power load configuration information for each household is information about how much power demand devices use the power in each household. The weather information is information on the external environment, and may include information on temperature, precipitation, and the like. Such weather information may be collected by a weather sensor provided in each household or the like and transmitted to the power demand reaction management server 1 or may be information provided by an external institution to the power demand reaction management server 1. [

Information on the power load per household is received from the power meter of each household and processed and stored as power amount history data in the power amount history DB 200. The power amount configuration information for each household is stored in the power amount history DB 200 And may be information estimated by applying stored power amount history data to a machine learning algorithm. The means for estimating generation power load configuration information may be provided in the power amount history DB 200 or may be provided independently of the power amount history DB 200. [

As another example, the information on the power load per household is information received from the intelligent power meter that measures the power consumption of the power demand devices of each household, and the power load configuration information per household is obtained directly from the information received from the intelligent power meter Information. For example, the intelligent power meter may be an Energy Management System (EMS) device or an Advanced Metering Infrastructure (AMI) device or a smart meter. Since these intelligent power meters separately measure the power consumption data for each power demand device of each generation and transmit them to the power demand response management server 1, the power demand response management server 1 stores the data as a history In this case, the power load configuration information for each generation can be acquired based on actual data without using the estimation method.

For example, in step S30, the generation-by-generation power load reconstitution scenario generation unit 30 generates a generation-by-generation power load reconfiguration scenario 30, It may be configured to change the demand response capacity for each household and the power load reconstruction scenario for each household calculated by the demand reaction capacity calculation unit 20 for each household so that the difference between the demand response capacity and the demand reaction capacity is below the threshold, The difference between the demand response capacity of each generation calculated by the calculation unit 20 and the demand response capacity of each generation may be accumulated to the margin demand response capacity as a margin.

This will be described with reference to FIG. 4 additionally.

4, in step S32, the generation-by-generation power-load reconstitution scenario generation unit 30 generates a generation-by-generation power-load reconfiguration scenario generation unit 30, A process of calculating a per-generation power load configuration, that is, a generation-by-generation power load reconstruction scenario, is performed.

In step S34, the generation-by-generation power-load reconstitution scenario generation unit 30 generates a demand-response-capacity-by-generation demand response capacity for each generation, which is calculated by the demand-demand capacity calculation unit 20 for each generation, A process of determining whether the difference in consumed power amount is equal to or less than a threshold value is performed. For example, the threshold may be a value close to zero or zero. As a result of the determination at step S34, if the difference is less than or equal to the threshold value, the process proceeds to step S38, and if not, the process proceeds to step S36.

In step S36, the generation-by-generation power-load reconstitution scenario generation unit 30 generates a demand-response-capacity-by-generation demand response capacity for each generation, which is calculated by the demand-demand capacity calculation unit 20 for each generation, The process of changing the demand response capacity for each household is performed so that the difference in consumed power amount is equal to or less than the threshold value.

After step S36 is performed, the process proceeds to step S32, and a process of generating the power load reconfiguration scenario generation unit 30 for each household reassigns the power load configuration for each generation based on the changed demand response capacity for each generation through step S36 . That is, in step S32, the generation-by-generation power load reconstitution scenario generation unit 30 sets a generation-by-generation power load configuration having the smallest difference from the demanded capacity of each generation, which is changed through the step S36, The shipment process is performed.

If the difference is less than or equal to the threshold value, the process proceeds to step S38.

In step S38, the generation-by-generation power load reconstitution scenario generation unit 30 calculates the difference between the demand response capacity for each generation, which is calculated by the demand response capacity calculation unit 20 for each generation, and the demand response capacity for each generation, The process of integrating the data into the margin is performed.

The reason for this configuration is as follows. In other words, there is no way to control the amount of power used except for the ON / OFF method in most of the power demand devices provided in each household. In the case of the air conditioner capable of temperature control, the power consumption can be accurately adjusted Therefore, when calculating the above power generation reconstruction scenario for each household, that is, when calculating the power load composition, there arises a difference from the requested demand capacity for each generation. Generally, in the case of apartment houses, about 10 to 60 households receive electricity through one transformer, so the sum of the demand response capacities for each household must be a sum of the demand response capacities for each household, plus a certain margin. Since there is no problem in the reaction operation, the margin is secured through the configuration as described above.

For example, in the following step S50, when the user inverse information for the demand response suggestion information for each household is received through the household user terminal, the step S30 is performed again, and the power load reconstitution scenario generation unit 30 for each household May be configured to regenerate generation-by-generation power load reconstruction scenarios.

In step S40, the demand response proposal information notification unit 40 for each generation notifies the generation user terminal of the demand response proposal information for each generation including the demand response capacity for each generation and the power load reconstruction scenario for each generation.

In step S50, when the user approval information on the demand response suggestion information for each household is received via the household user terminal, the demand response capacity determining unit 50 determines, by the generation demand response suggestion information notification unit 40, The power demand reaction capacity including the demand response capacity for each generation notified to the household user terminal is provisionally determined, and then the process proceeds to step S60. If the user inverse information for the demand response suggestion information for each household is received through the household user terminal in step S50, the process returns to step S30 and is performed again from the process of generating the power load reconfiguration scenario for each household.

In step S60, the feedback processing unit 60 performs a process of processing user feedback on the demand response capacity of each generation determined provisionally by the power demand reaction capacity determining unit 50. [

If satisfactory feedback information for the demand response capacity for each household provisionally determined by the power demand response capacity determination unit 50 is received in step S60, the process proceeds to step S70 so that the feedback processing unit 60 determines whether or not the power demand reaction capacity determination The final determination of the provisionally determined power demand reaction capacity determined by the power management unit 50 is performed.

In the event that unsatisfactory feedback information for the demand response capacity for each household provisionally determined by the power demand reaction capacity determination unit 50 is received in step S60, the feedback processing unit 60 switches the procedure to step S10, A process of controlling the demand-response capacity calculation unit 10 for each node to recalculate the demand-demand response capacity after changing the capacity is performed. That is, in the case of unsatisfactory feedback, the process is switched to the initial step S10 so that the whole procedure is performed again, and this procedure can be continuously performed until satisfaction feedback is received.

As described above in detail, according to the present invention, there is provided an electric power demand response management server and method of a apartment house capable of generating and managing an electric power demand response capacity of an apartment house at an optimized value.

In addition, in the process of collecting surplus power and bidding for electricity demand reaction, the apartment complex will calculate and bid on the optimal capacity demand capacity that can be tolerated by households constituting the complex, A power demand reaction management server of the apartment house, which performs a stable power demand response procedure by adaptively changing the electric power shutdown object according to the feedback from generations constituting the complex in the course of performing the power demand response procedure And a method is provided.

1: Power demand response management server
10: Demand Response Capacity Calculation Unit
20: Demand Response Capacity Calculation Unit by Generation
30: Generation-by-generation power load reconstruction scenario generation unit
40: Demand Response Proposal Information Unit by Generation
50: Power demand reaction capacity determining unit
60:
100: Power demand response history DB
200: Electricity history DB

Claims (16)

A demand demand reaction capacity calculation unit for calculating the demand response capacity by the demand only from the demand reaction capacity with reference to the ratio of the power load and the power load by the same;
A demand reaction capacity calculation unit for each household to calculate a demand response capacity for each household from the demand response capacity by the reference to the ratio of the power load by each household to the power load by household;
A power load reconfiguration scenario generation unit for each generation that generates a power load reconfiguration scenario for each household that satisfies the demand response capacity for each generation by referring to the power load configuration information and weather information for each generation;
A demand response suggestion information notifying unit for each generation for notifying the generation user request terminal of the demand response proposal information including the demand reaction capacity for each generation and the power load reconstruction scenario for each generation; And
And a power demand reaction capacity determining unit for determining the power demand reaction capacity including the demand response capacity for each household when the user approval information for the generation demand response suggestion information is received through the household user terminal,
The generation-by-generation power load reconfiguration scenario includes power demand device specific information, which is information for specifying power demand devices capable of power cutoff and power control for each generation, and power demand device control time Information,
The generation-by-generation power load reconfiguration scenario generation unit includes:
By the demand response capacity calculation unit of each household so that the difference between the generation power according to the execution of the power load reconstruction scenario for each household and the demand reaction capacity for each household calculated by the demand reaction capacity calculation unit for each household is equal to or smaller than a threshold value The demand response capacity of each household and the power load reconfiguration scenario for each household are changed, and the difference between the demand response capacity of each generation and the demand response capacity of each generation, which is calculated by the demand reaction capacity calculation unit for each generation, The difference is generated according to the control of the power demand device whose power consumption is controlled by ON / OFF included in the generation-by-generation power load reconfiguration scenario, - Power is supplied through
A power demand response management server for the apartment house. delete delete The method according to claim 1,
Wherein the generation-by-generation power load reconstitution scenario generation unit regenerates the generation-by-generation power load reconstitution scenario when receiving counter-user information on the demand-response proposal information for each generation through the generation user terminal. Power demand response management server. The method according to claim 1,
Further comprising a feedback processing unit for processing user feedback on a demand response capacity of each generation determined by the power demand reaction capacity determining unit,
Wherein the feedback processing unit comprises:
When satisfying feedback information on the demand response capacity for each generation is received, finalizing the power demand reaction capacity determined by the power demand reaction capacity determining unit,
Wherein when the dissatisfied feedback information on the demand response capacity for each household is received, the dynamic demand response capacity calculation unit re-calculates the dynamic demand response capacity after changing the demand response capacity only. Power demand response management server. The method according to claim 1,
The information on the power load per household is received from the power meter of each household and processed and stored into the power history data in the power history DB,
Wherein the generation power load configuration information is information estimated by applying history data stored in a power amount history DB to a machine learning algorithm. The method according to claim 1,
The information on the power load per generation is information received from the intelligent power meter that measures the power consumption of power demand devices of each household,
Wherein the power load configuration information for each household is information obtained from information received from the intelligent power meter. The method according to claim 1,
Wherein the dynamic demand response capacity calculation unit calculates the dynamic demand response capacity by multiplying a value obtained by dividing the dynamic power load by the dynamic power load by the dynamic demand capacity. The method according to claim 1,
The dynamic demand response capacity calculation unit calculates the dynamic demand response capacity from the demand response capacity by applying the electric power demand response history data stored in the power demand response history DB with respect to the past power demand response capacity calculation to the machine learning algorithm, Wherein the power demand response management server of the apartment house calculates the power demand response management server of the apartment house. The method according to claim 1,
Wherein the household demand response capacity calculation unit calculates the demand response capacity for each household by multiplying the value obtained by dividing the power load amount for each household by the power load amount for each household by the dynamic demand response capacity for each household, Management server. The method according to claim 1,
The demand response capacity calculation unit for each generation applies the power demand response history data stored in the power demand response history DB to the machine learning algorithm with respect to the past power demand response capacity calculation, And the reaction capacity is calculated based on the reaction demand. Calculating a demand response capacity of each node from the demand response capacity only by referring to the ratio of the power load to the power load;
Calculating a demand response capacity for each household from the demand response capacity of each household by referring to a ratio of the power load by household to the power load by household;
Generating a power load reconfiguration scenario for each household that satisfies the demand response capacity for each household by referring to the power load configuration information and weather information for each household;
A step of notifying the household user terminal of demand response suggestion information for each generation including the demand response capacity for each household and the power load reconfiguration scenario for each household; And
Wherein the power demand reaction capacity determining unit includes a step of, when receiving the user approval information for the demand response suggestion information for each household through the household user terminal, determining the power demand response capacity including the demand response capacity for each household ,
The generation-by-generation power load reconfiguration scenario includes power demand device specific information, which is information for specifying power demand devices capable of power cutoff and power control for each generation, and power demand device control time Information,
In the generation of the generation-by-generation power load reconstruction scenario,
By the demand response capacity calculation unit of each household so that the difference between the generation power according to the execution of the power load reconstruction scenario for each household and the demand reaction capacity for each household calculated by the demand reaction capacity calculation unit for each household is equal to or smaller than a threshold value The demand response capacity of each household and the power load reconfiguration scenario for each household are changed, and the difference between the demand response capacity of each generation and the demand response capacity of each generation, which is calculated by the demand reaction capacity calculation unit for each generation, The difference is generated according to the control of the power demand device whose power consumption is controlled by ON / OFF included in the generation-by-generation power load reconfiguration scenario, - Power is supplied through
Wherein said power demand response management method comprises the steps of: delete delete [Claim 15 is abandoned upon payment of registration fee] 13. The method of claim 12,
In the generation of the generation-by-generation power load reconstruction scenario,
Wherein the generation of the power load reconstruction scenario for each household is regenerated when the user inverse information on the demand response suggestion information for each household is received through the household user terminal. [Claim 16 is abandoned upon payment of registration fee.] 13. The method of claim 12,
Further comprising the step of processing user feedback on the demand response capacity for each household determined in the step of determining the power demand reaction capacity,
In the step of processing the user feedback,
When satisfying feedback information on the demand response capacity for each generation is received, finalizing the power demand reaction capacity determined by the power demand reaction capacity determining unit,
Wherein when the dissatisfied feedback information on the demand response capacity for each household is received, the dynamic demand response capacity calculation unit re-calculates the dynamic demand response capacity after changing the demand response capacity only. Of power demand response management.

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