KR101174602B1 - System and method for recognizing energy usage pattern using transient response analysis in single point - Google Patents

Abstract

PURPOSE: A system and a method for recognizing energy usage pattern through transient response analysis in a single point are provided to confirm whether household appliances are operated or not using a smart meter. CONSTITUTION: A system for recognizing energy usage pattern through transient response analysis in a single point uses a smart meter(110). The smart meter is installed on a panel board which supplies power to electric appliances and comprises an admittance observation module and a transient response observation module. The admittance observation module observes admittance generated in the panel board when the electric appliances are operated. The transient response observation module observes transient response patterns, which indicate the signal properties of the electric appliances, from the admittance.

Description

SYSTEM AND METHOD FOR RECOGNIZING ENERGY USE PATTERN THROUGH TRANSFER RESPONSE ANALYSIS AT SINGLE POINT {SYSTEM AND METHOD FOR RECOGNIZING ENERGY USAGE PATTERN USING TRANSIENT RESPONSE ANALYSIS IN SINGLE POINT}

Embodiments of the present invention are directed to a system and method for recognizing energy usage patterns through transient response analysis at a single point to measure home power usage.

The ultimate goal of efficient building energy management is to minimize the use of energy consumed to control indoor environments such as air conditioning, heating, ventilation, and lighting without compromising the comfort of living spaces. Even if technical measures are taken to conserve energy in a building, the effect cannot be expected without close and continuous energy management of actual building energy use, system efficiency, normal operation and operation schedule. Therefore, in advanced countries, separate building energy managers are assigned to thoroughly manage the energy consumption level and operation status of the building, so that the building is always operated with the best energy efficiency. In addition, we are focusing on continuous technology development in relation to analysis of energy consumption patterns and diagnosis of abnormality of systems according to the unique thermal characteristics of buildings.

On the other hand, in recent years, the United Nations Climate Change Convention has strengthened the obligation to reduce greenhouse gases by country, and once Korea joins the Organization for Economic Cooperation and Development (OECD), it is difficult to avoid the pressure to reduce the obligations of advanced countries. As a result, it is urgent to develop clean energy that can minimize greenhouse gas emissions and foster environmentally friendly industries, and building is a burden factor that weakens the competitiveness of a company unless it is an energy-saving building that emits less greenhouse gas.

Therefore, in order to manage efficient building energy, it is necessary to accurately monitor the electricity use devices in the building. To this end, Korean Patent Application No. 10-2010-0024810 (filed March 19, 2010) discloses a technology that monitors the power supply of a building in real time, checks for unnecessary power usage, and remotely controls the power usage of an electrical device. Is disclosed.

However, the most obstacle to the spread of electronic electricity meters such as smart meters may be price. Although individual smart meters can be used to accurately measure power usage at home outlets, the cost burden of measuring equipment is hindering market activation.

Provided are a system and a method for measuring whether a single smart meter is used to drive individual home appliances in a home.

Provides a system and method for online monitoring of power consumption for individual household appliances.

A smart meter for measuring the power usage is installed in the distribution panel for supplying power to at least one electrical device; An admittance observation module for observing admittances generated in the distribution boards when the electric device is driven; And a transient response observing module for observing a transient response pattern representing the inherent signal characteristics of the electrical device from the admittance. In this case, the smart meter may classify the electric devices according to the transient response pattern and measure power consumption for each electric device.

The smart meter for measuring the power usage is installed in the distribution panel for supplying power to at least one electrical device; An admittance observing module for observing admittances generated at the distribution boards when the electric device is driven; A transient response observation module for observing a transient response pattern indicative of inherent signal characteristics of the electrical device from an admittance; And a communication module configured to transmit the transient response pattern to a power consumption monitor system, which is a central server system, and to receive information of an electrical device corresponding to the transient response pattern from the power consumption monitor system. In this case, the smart meter may classify the electric devices based on the information of the electric devices received from the power consumption monitor system and measure the power consumption of each electric device.

A distribution panel installed in each individual zone of the building and supplying power to at least one electric device in the individual zone; A smart meter installed in the distribution panel and observing a transient response pattern indicating an inherent signal characteristic of the electrical apparatus from an admittance generated in the distribution panel when the electrical apparatus is driven; And a server configured to receive a transient response pattern from the smart meter and provide information of the electrical device corresponding to the received transient response pattern. In this case, the smart meter may measure electric power consumption for each electric device by dividing the electric device based on the information of the electric device provided by the server.

According to one side, the server can build a transient response pattern for each electrical device as a database to distinguish the electrical devices by comparing the transient response pattern observed in the smart meter with the transient response pattern on the database.

According to another aspect, the server can store the power consumption for each electrical device measured by the smart meter for each individual zone.

According to another aspect, the server may provide the user with power consumption for each electric device for the individual zone through at least one of a web or an application mounted on the communication terminal.

According to another aspect, the server may provide a function for the user to correct information related to the transient response pattern of the electrical device.

A database for storing and maintaining a transient response pattern representing a unique signal characteristic of the electrical device for each of the plurality of electrical devices; And according to the request of the smart meter installed in each individual area of the building provides a system comprising a server for providing information of the electrical device corresponding to the transient response observed in the smart meter to the smart meter. At this time, the smart meter is installed in the distribution board installed in the individual zone, and observes the transient response pattern of the electrical equipment from the admittance generated in the distribution board when the electrical equipment is driven, and classifies the electrical equipment based on the information of the electrical equipment provided from the server. You can measure the power consumption of each electric device.

The control method of the power consumption monitor system, which monitors the power consumption of individual areas by using smart meters installed in each individual area of a building, stores a transient response pattern representing the unique signal characteristics of the electric devices for each of the electric devices. Making; Providing information on an electric device corresponding to the transient response pattern observed by the smart meter to the smart meter according to the request of the smart meter; Storing power consumption for each electric device measured by the smart meter; And providing the user with the electric power consumption for each electric device for the individual zone through at least one of the applications mounted on the web or the communication terminal. At this time, the smart meter is installed in the distribution board installed in the individual zone, and observes the transient response pattern of the electrical equipment from the admittance generated in the distribution board when the electrical equipment is driven. Usage can be measured.

By measuring the operation of individual home appliances in the area with only one smart meter in one individual area in the building, the cost burden of equipment construction can be reduced, and the spread of smart meters can be activated.

Real-time monitoring of the power consumption of each household appliance from smart meters in each individual area allows remote visibility of power usage, thus reducing power loss efficiently.

1 is a diagram illustrating a configuration of an energy management system using a smart meter that provides a transient response analysis function according to an embodiment of the present invention.
2 is a block diagram illustrating an internal configuration of a smart meter for analyzing a transient response pattern of an electric device according to an embodiment of the present invention.
3 and 4 are diagrams for explaining the transient response characteristics for the electrical equipment.
FIG. 5 is a block diagram illustrating an internal configuration of a power consumption monitor system for monitoring power consumption of individual zones through interworking with a smart meter according to one embodiment of the present invention.
6 is a flowchart illustrating a service method for monitoring power consumption of individual zones according to an embodiment of the present invention.
7 is a diagram illustrating an example of a service screen showing power consumption for each electric device.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Embodiments of the present invention may be applied to an energy management system for monitoring electrical devices in separate zones for energy management. In the present specification, an individual zone may mean an area unit that receives electric power from a power company such as each floor or an individual home in a building, and hereinafter, a home will be described as an example.

1 is a diagram illustrating a configuration of an energy management system using a smart meter that provides a transient response analysis function according to an embodiment of the present invention.

Referring to FIG. 1, the energy management system monitors power consumption in a home through a smart meter 110 measuring power consumption in a home and smart meters 110 installed in each home for a plurality of homes. System 120 may be configured.

The smart meter 110 may include an electronic wattmeter in which a metering module for measuring power consumption of electric appliances in the home and a communication module for transmitting the measured power consumption of the electrical devices to the power consumption monitor system 120 which is a central server system are combined. Can mean. In the present embodiment, the smart meter 110 is installed in a distribution board (aka, toad house) corresponding to the power consumption inlet of the home, and in particular, the transient response analysis function may be used to analyze the transient response pattern for the electric device.

The power consumption monitoring system 120 may monitor the power consumption of individual electric devices in the home through the smart meter 110 of each home by using wired or wireless communication, and collects the power consumption of the electric devices for each home. And can be stored. In addition, the power consumption monitor system 120 may provide a monitoring service so that a user may grasp power consumption occurring in his / her home anytime, anywhere. The user may access the monitoring service provided by the power consumption monitor system 120 using the smart meter 110 or the separate communication terminal 130 to determine the power consumption generated in his / her home. In this case, the communication terminal 130 may refer to all communication devices that can be connected to the power consumption monitor system 120, such as a smart TV, a smart phone, a PC, a tablet.

The energy management system having the above-described configuration may monitor whether or not individual electric devices used in each home are driven by only one smart meter 110 in one home.

Hereinafter, a smart meter configuration that provides a transient response analysis function will be described in detail.

2 is a block diagram illustrating an internal configuration of a smart meter for analyzing a transient response pattern of an electric device according to an embodiment of the present invention. As shown in FIG. 2, the smart meter 200 according to an embodiment includes a digital AC monitor 210, an admittance observation module 220, a transient response observation module 230, and a communication module 240. Can be.

The smart meter 200 may be installed in a distribution panel that supplies power to at least one electric device in a home, that is, a power consumption inlet at the home.

The digital AC monitor 210 may display a voltage, a current consumption, and the like in digital numbers in relation to the input AC power.

The admittance observation module 220 serves to observe the admittance generated in the distribution panel when the electric device is driven. In this case, the admittance indicates the degree of current resistance in the AC circuit and may be used to analyze the transient response characteristic of the electric device.

The transient response observation module 230 observes a transient response pattern for the electric device from the admittance observed in the admittance observation module 220. At this time, the transient response observation module 230 serves as a weighing module for measuring the power consumption of each electric device by checking whether the individual electric devices are driven, and transient response for the purpose of classifying the electric devices prior to the measurement of the power consumption. Patterns can be observed.

The electrical devices exhibit a transient period 301 before the ballast 302 as shown in FIG. 3 at initial drive. The transient response over the transient period 301 is a unique signal characteristic of the devices, which is used as a major indicator of device performance. When the transient response of the transient period 301 is shown on the complex plane, it can be expressed as a variation over time, and a parameter can be defined to characterize the width and period of the variation. The definition of the transient response specification is shown in FIG. 4, and the description of each parameter is as follows.

(1) M _p means the maximum overshoot, which is the maximum peak of the response curve minus the final value (1). (2) t _d is the delay time, which is the time it takes for the response to be half of the final value for the first time. (3) t _r means the rise time, which is the time taken for the response to rise to 10 to 90%, 5 to 95%, and 0 to 100% of the final value. Depending on the system, the rise time can be different and can be based on 0 ~ 100% in under damping system and 10 ~ 90% in over damping system. (4) t _p means peak time, which is the time it takes for the response to reach the first peak of the overshoot. (5) t _s means the settling time, which is the time it takes for the response curve to enter and stay within the percent absolute tolerance (based on 2% or 5%) of the final value. The transient response observation module 230 may analyze the transient response characteristic through the above parameters.

As described above, since the transient response pattern has unique characteristics for each electric device, the corresponding device may be classified based on the transient response pattern generated during initial driving of the electric devices. In order to classify individual devices, smart meter suppliers can provide a database of transient response characteristics for individual devices to provide a classification for individual devices based on signals generated in each household. For example, when the smart meter 200 further includes a storage unit (not shown) for storing and maintaining a transient response pattern for each electric device, the transient response pattern observed by the transient response observation module 230 is stored. The individual devices may be directly distinguished from the smart meter 200 by comparing with the transient response pattern stored in the smart meter 200. In this case, the storage unit may match and store device information (device type, product information, etc.) and transient response characteristics of the corresponding device for each electric device. That is, the transient response observation module 230 observes the transient response pattern according to the initial operation of the electrical device, and then compares the transient response pattern stored in the storage unit to check the electrical device corresponding to the observed transient response pattern. Observe whether the device is driven or not. As another example, a database storing a transient response pattern for each electric device may be built on a server (ie, a power consumption monitor system). In this case, the smart meter 200 may request the information of the device corresponding to the transient response pattern by transmitting the transient response pattern observed in the transient response observation module 230 to the server. Accordingly, the smart meter 200 may receive information of the electric device having the corresponding transient response pattern in response to the request from the server, and confirm the driving of the electric device through the received information.

Accordingly, the transient response observation module 230 may classify the electrical devices through the transient response pattern analysis and measure the power consumption for each electrical device.

The communication module 240 serves to perform data communication with a server (that is, a power consumption monitoring system), and may transmit power consumption for each electric device measured by the transient response observation module 230 to the server. In addition, when a database storing a transient response pattern for each electric device is constructed on the server, the communication module 240 transmits the transient response pattern observed in the transient response observation module 230 to the server and then applies the transient response pattern from the server. Information of the corresponding electric device may be received.

Hereinafter, the power consumption monitor system and service procedure for monitoring the power consumption in the home through interworking with the smart meter will be described in detail.

FIG. 5 is a block diagram illustrating an internal configuration of a power consumption monitor system for monitoring home power consumption according to an embodiment of the present invention. As shown in FIG. 5, the power consumption monitor system 500 according to an embodiment may include a collection server 510, a log database 520, a transient response pattern database 530, and an analysis server 540. have.

The smart meter in the home may transmit the transient response information to the collection server 510 periodically or immediately according to the user's setting. In this case, the collection server 510 receives the transient response pattern from the smart meter in the home and stores the transient response pattern in the log database 520, and the analysis server 540 of the electrical device corresponding to the transient response pattern received from the smart meter. It can serve to request information.

The transient response pattern database 530 stores and maintains a transient response pattern representing the inherent signal characteristics of the electrical device for each electrical device. In this case, the transient response pattern database 530 may match and store device information (device type, product information, etc.) and transient response characteristics of the corresponding device for each electric device.

The analysis server 540 serves to provide information of the electric device corresponding to the transient response pattern transmitted from the smart meter at the request of the collection server 510. The analysis server 540 may compare the transient response pattern transmitted from the smart meter with the transient response pattern on the transient response pattern database 530 to distinguish the electric device having the corresponding pattern. In addition, the analysis server 540 transmits the information of the electrical device corresponding to the transient response pattern transmitted from the smart meter to the collection server 510, and the collection server 510 transmits the information of the electrical device to the smart meter. Can be. In this case, the smart meter may determine whether the electric device is driven according to the transient response pattern and measure the power consumption of each electric device. Thus, the collection server 510 may receive power consumption for each electric device measured by the smart meter for each home and store it through the log database 520.

The analysis server 540 may provide a monitoring service that provides the user with the power consumption for each electric device in the home stored in the log database 520 so that the user can grasp the power consumption occurring in his home anytime, anywhere. To this end, the analysis server 540 may provide a user with power consumption for each electric device for each home through at least one of applications mounted on a web or a communication terminal. In other words, power consumption for individual home electrical appliances is monitored online and this information can be provided in the form of smart TVs or dedicated applications. Furthermore, the analysis server 540 serves to correct information related to the transient response pattern of the electric device according to a request of the user. That is, the analysis server 540 may provide a function that a user can correct by selecting on his or her electronic product profile in a monitoring service environment.

6 is a flowchart illustrating a service method for monitoring power consumption of individual zones according to an embodiment of the present invention. In the service method according to the present embodiment, each step may be performed by the power consumption monitor system 500 described above. The power consumption monitor system 500 may provide a monitoring service that provides a user with power consumption for each electric device for each home through at least one of applications installed in a web or a communication terminal according to a user's request.

In detail, the power consumption monitor system 500 performs an authentication procedure for the personal information of the user requesting the execution of the monitoring service (610). When at least one user registers personal information for each home where the smart meter is installed, the power consumption monitoring system 500 may grant monitoring authority for the power consumption of the home.

When the authentication process for the user's personal information is completed, the power consumption monitor system 500 may check whether information corresponding to the user's home exists in a database built therein (620). In this case, when the information corresponding to the home of the user does not exist, the power consumption monitor system 500 may provide a search list by searching for home appliances in which a transient response pattern is registered in a database. The power consumption monitor system 500 may register the home appliance selected by the user in the search list as information corresponding to the user's home (640).

If there is information corresponding to the user's home in the database, the power consumption monitor system 500 may load the information and provide the information to the user (650). Referring to FIG. 7, the power consumption monitor system 500 may show power consumption for each home appliance through a smart meter installed in a user's home or a communication terminal used when a user accesses the same. In this case, the power consumption monitor system 500 may reconfigure the screen by day / week / month and may configure the screen by home appliances. In addition, the power consumption monitor system 500 may provide a page that can be modified when a particular bar 701 is selected in a graph showing power consumption for each home appliance. Since the transient response may occur in a very short time and may not be recognized depending on the situation, the power consumption monitor system 500 provides a function of directly registering or correcting an electric device in a monitoring service environment. The power consumption monitor system 500 may provide a page with a correction function when a modification request is made from a user (660). In this case, the user selects a power consumption line from the page and then selects it on the home appliance profile database. Updates to revised information can be requested (670-690).

As such, according to embodiments of the present invention, it is possible to measure the driving of individual home appliances in the corresponding area by using only one smart meter in one individual area of the building, thereby reducing the cost burden of equipment construction. In addition, according to embodiments of the present invention, it is possible to monitor the power consumption of the electric appliance of the individual home online through a smart meter or a separate communication terminal to grasp the power usage at a glance.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

200: smart meter
210: digital AC monitor
220: admittance observation module
230: transient response observation module
240: communication module
500: power consumption monitor system
510: collection server
520: log database
530: transient response pattern database
540: analytics server

Claims (15)

In the smart meter (measured by smart meter) for measuring the power consumption,
The smart meter,
It is installed in the distribution panel for supplying power to at least one electrical device,
An admittance observation module that observes an admittance generated at the distribution panel when the electric device is driven; And
Transient response observation module for observing a transient response pattern representing the intrinsic signal characteristics of the electrical device from the admittance
Including,
Measuring the power consumption of each electric device by dividing the electric device according to the transient response pattern;
Smart meter characterized in that. The method of claim 1,
The smart meter,
Storage unit for storing and maintaining the transient response pattern for each electrical device
Further comprising:
The transient response observation module,
Classifying the electric device by comparing the observed transient response pattern with the transient response pattern stored in the storage unit.
Smart meter characterized in that. In the smart meter for measuring the power consumption,
The smart meter,
It is installed in the distribution panel for supplying power to at least one electrical device,
An admittance observing module for observing admittance generated in the distribution panel when the electric device is driven;
A transient response observing module for observing a transient response pattern indicative of inherent signal characteristics of the electrical device from the admittance; And
A communication module for transmitting the transient response pattern to a power consumption monitor system, which is a central server system, and receiving information of an electrical device corresponding to the transient response pattern from the power consumption monitor system.
Including,
Measuring power consumption for each electric device by dividing the electric device based on the information of the electric device received from the power consumption monitoring system;
Smart meter characterized in that. The method of claim 3,
The power consumption monitor system,
And a database for storing and maintaining a transient response pattern for each electrical device, and classifying the electrical device by comparing the transient response pattern observed by the smart meter with the transient response pattern stored in the database.
Smart meter characterized in that. A distribution panel installed in each individual zone of the building and supplying power to at least one electric device in the individual zone;
A smart meter installed in the distribution panel and observing a transient response pattern indicating an inherent signal characteristic of the electrical apparatus from an admittance generated in the distribution panel when the electrical apparatus is driven; And
The server receiving the transient response pattern from the smart meter and provides information of the electrical device corresponding to the received transient response pattern
Including,
The smart meter,
Measuring power consumption for each electric device by dividing the electric device based on information of the electric device provided by the server;
System characterized in that. The method of claim 5,
The server,
Constructing a transient response pattern for each electrical device into a database and classifying the electrical device by comparing the transient response pattern observed by the smart meter with the transient response pattern on the database.
System characterized in that. The method of claim 5,
The server,
Storing power consumption for each electric device measured by the smart meter for each individual zone;
System characterized in that. The method of claim 7, wherein
The server,
Providing a user with power consumption for each electric device for the individual zone through at least one of a web or an application mounted on a communication terminal.
System characterized in that. The method of claim 8,
The server,
Providing a function for the user to correct information related to the transient response pattern of the electrical device
System characterized in that. A database for storing and maintaining a transient response pattern representing a characteristic signal characteristic of the electrical device for each of the plurality of electrical devices; And
The server for providing the smart meter with information of the electrical device corresponding to the transient response pattern observed by the smart meter at the request of the smart meter installed in each individual area of the building
Including,
The smart meter,
It is installed in the distribution panel installed in the individual zone and observes the transient response pattern of the electrical device from the admittance generated in the distribution panel when the electrical device is driven, and the electrical device based on the information of the electrical device provided from the server To measure power consumption by the electric device
System characterized in that. The method of claim 10,
The server,
Classifying the electrical device by comparing the transient response pattern observed by the smart meter with the transient response pattern in the database.
System characterized in that. The method of claim 10,
The server,
Storing power consumption for each electric device measured by the smart meter for each individual zone;
System characterized in that. The method of claim 10,
The server,
Providing a user with the power consumption for each electric device for the individual zone through at least one of the applications mounted on the web or communication terminal
System characterized in that. The method of claim 13,
The server,
Providing a function for the user to correct information related to the transient response pattern of the electrical device
System characterized in that. In the control method of the power consumption monitor system for monitoring the power consumption of the individual area by using a smart meter installed in each individual area of the building,
Storing a transient response pattern indicating a characteristic signal characteristic of the electrical device for each of the plurality of electrical devices;
Providing information on an electric device corresponding to the transient response pattern observed by the smart meter to the smart meter at the request of the smart meter;
Storing power consumption for each electric device measured by the smart meter; And
Providing a user with the electric power consumption for each electric device for the individual zone through at least one of the applications mounted on the web or communication terminal
Including,
The smart meter,
It is installed in the distribution panel installed in the individual zone and observe the transient response pattern of the electrical device from the admittance generated in the distribution panel when the electrical device is driven, and classifies the electrical device based on the information of the electrical device Measuring power consumption by stars
Control method characterized in that.

Images