KR20110038979A - Method for controlling energy consumption based on energy consumption model - Google Patents

Abstract

PURPOSE: An energy consumption control method based on energy consumption model is provided to intellectually control the energy consumption according to the various situation of the user by controlling energy consumption by considering information about an energy consumption device and user situations. CONSTITUTION: An information inquiry unit(120) request device information registered to a current unit space of a user. The information inquiry unit inquires information of a device installed to the unit space. A user situation determining unit determines user situation information by applying static information of a user and dynamic information of a user as an information ontology. An energy consumption model determiner(140) determines an energy consumption model which is matched to the situation information of the user. A device combination determiner(150) determines device combination for controlling operation in the unit space.

Description

Energy consumption control method based on energy consumption model {Method for controlling energy consumption based on energy consumption model}

The present invention relates to a method of controlling energy consumption, and more particularly, to determine a type of device consuming energy in an energy use space, and to optimize energy consumption while considering user satisfaction according to various user information. It is to provide an energy consumption control method based on a possible energy consumption model.

Energy consumption continues to increase due to economic growth and improved living standards, while conventional energy sources such as petroleum, coal and natural gas are limited. Therefore, with the development of new alternative energy, various ways to save energy and use efficiently are being studied.

Intelligent energy control method, which has recently emerged as one of the efficient energy usage methods, uses an information technology infrastructure to determine a user's location and provides information about the types of devices available to the user in the user's location space and the use of the sun. Acquisition using a Zigbee network or the like, intelligently determines the appropriate energy consumption pattern using the obtained information to control the user to use energy efficiently. However, the conventional intelligent energy control method recognizes the user, what kind of device the user is using, how much energy is consumed by the device being used, and how much is the cost of replaceable energy? The energy consumption pattern is presented to the user using only basic information about energy.

Since the conventional intelligent energy consumption control method described above suggests an energy consumption pattern to the user by using only basic information on the energy consumption, the intelligent energy consumption control method only provides a uniform energy consumption pattern to the user and is adaptively adapted to various situations of the user. The problem is that energy consumption patterns cannot be presented.

Furthermore, in order to implement the proposed energy consumption pattern or to implement a higher efficiency energy consumption pattern, information on related devices or components must be provided to the user in a timely manner. The conventional intelligent energy consumption control method provides an energy consumption pattern to the user. It only presents new devices and services needed to implement energy consumption patterns, or provides information on new devices and services with higher efficiency that can implement energy consumption patterns.

The present invention is to solve the problems of the conventional energy consumption control method described above, the object of the present invention is to achieve the most appropriate according to the various situations of the user using not only the basic information on the energy consumption but also the user's situation information It is to provide an energy consumption control method that presents an energy consumption model.

Another object of the present invention is to provide a method for retrieving an energy consumption model matching a user's context information from an energy saving database and controlling the energy consumption of the user simply and efficiently based on the retrieved energy consumption model. .

Another object of the present invention is to provide a method of controlling energy consumption of a user by searching for an adaptive energy consumption model according to various situations of a user by applying user static information or user dynamic information to an information ontology.

Another object of the present invention is to provide an energy consumption control method for providing information on a device or service necessary for implementing the determined energy consumption model or information on a device or service necessary for implementing the energy consumption model with higher efficiency. To provide.

In order to achieve the object of the present invention, the energy consumption control method according to the present invention comprises the steps of receiving information on the device registered in the current unit space of the user based on the location information of the user terminal, user static information and user dynamic Generating user context information by applying the information to the information ontology, determining an energy consumption model matching the user context information in the energy consumption model database, and controlling the operation based on the determined energy consumption model and information of the registered device. And determining the device combination for providing the information about the determined device combination to the user terminal or controlling the device combination.

The information on the energy consuming device may include at least one of a device ID, a device type, a device location, whether it is currently used, a standard energy consumption, a manufacturer, and a measured energy consumption.

The determining of the energy consumption model may include retrieving an energy consumption model matching the user context information from the energy consumption model database using the user context information as an index, and calculating a matching degree between the retrieved energy consumption model and the user context information. And selecting an energy consumption model showing the highest matching degree based on the matching degree and the calculated matching degree.

Preferably, the method for controlling energy consumption according to the present invention comprises the steps of retrieving information on an energy consumption device that is more efficient than the energy consumption device in use from a device information database, and providing information on the retrieved energy consumption device to a user terminal. It further comprises a step.

On the other hand, in order to achieve the object of the present invention, the energy consumption control apparatus according to the present invention to request the device information registered in the current unit space of the user based on the user location information to query the information of the device registered in the unit space An information inquiry unit, a user situation determination unit that determines user context information by applying user static information and dynamic information to an information ontology, and an energy consumption model determination unit that determines an energy consumption model matching the determined user context information. And a device combination determination unit that determines a device combination for operation control in the current unit space based on the determined energy consumption model and registered device information, and an output unit that outputs information on the determined device combination to a user terminal. It is done.

The energy consumption control method according to the present invention has various effects as follows as compared to the conventional energy consumption control method.

First, the energy consumption control method according to the present invention can control energy consumption in consideration of the user context as well as information on the energy consumption device, thereby intelligently controlling energy consumption according to various situations of the user.

Second, the energy consumption control method according to the present invention first selects an energy consumption model matching only the user context information and determines a combination of various energy consumption devices according to the selected energy consumption model, thereby obtaining an energy consumption model that matches the user context information. Simple search with high probability.

 Third, the energy consumption control method according to the present invention can apply the user information to the information ontology to search for an adaptive energy consumption model according to various situations of the user, thereby controlling energy consumption most appropriately for the current situation of the user.

Fourth, the energy consumption control method according to the present invention provides the user terminal with information about a device or service necessary to implement the energy consumption model, so that the user can implement the energy consumption model or the energy consumption model with higher efficiency Information about a device or service for the user can be easily obtained.

Fifth, the energy consumption control method according to the present invention automatically selects a device combination to satisfy the energy consumption model determined according to the user's current situation information, thereby satisfying the user's satisfaction according to the energy consumption and at the same time simply reducing the energy consumption. Can be.

Hereinafter, an intelligent energy control method according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a functional block diagram schematically showing an intelligent energy control system according to the present invention.

Referring to FIG. 1, the device information database server 10 and the user terminal 100 are connected to the wired / wireless network 1. The device information database server 10 stores information on devices installed in locations divided into unit spaces and information on various devices of the same type as new or installed devices that are not installed in the unit space. Here, the term device is a general term for a device that consumes energy. On the other hand, unit space refers to a space that can be recognized by human beings. For example, a home space means a space divided into a room, a living room, and a kitchen. It means a space divided into a rest space, and a school means a space divided into a lecture space, a seminar space, and a rest space.

The user terminal 100 receives information on energy consuming devices currently registered in the unit space from the device information database server 10 connected to the wired / wireless network 1 and based on the received energy consuming device information. To control the energy consumption of devices mounted in the current unit space in which the user is located.

2 is a functional block diagram of an energy consumption control apparatus according to an embodiment of the present invention.

1 and 2, the transceiver 110 transmits location information of a space where the user terminal 100 is located to the device information database server 10 through the wired / wireless network 10. The device information database server 10 searches for energy consuming devices that are installed and registered in the unit space where the user terminal 100 is located, based on the location information of the user terminal 100, and the transceiver 110 searches for the found energy. Information about the consuming device is received from the device information database server 10. On the other hand, the transceiver 110 receives the information on the device directly from the device installed in the unit space where the user terminal 100 is located. The information inquiry unit 120 compares the device information received from the device information database server 10 with the device information directly received from the device installed in the unit space and inquires the device currently installed in the unit space.

The user context information generating unit 130 stores user static information and user dynamic information, and generates user context information for extracting the user's current situation by applying the stored user static information and dynamic information to the information ontology. The energy consumption model determiner 140 receives the user's context information generated by the user context information generation unit 130 and stores a plurality of stored in the energy consumption model database 145 based on the received context information of the user. The energy expenditure model is determined among the energy expenditure models that most closely match the user's situation information or exhibit a matching degree equal to or greater than a first threshold. The energy consumption model is a model of an energy consumption control method that minimizes the energy consumed by the device while increasing the user's satisfaction by operating the device most efficiently in the current situation of the user.

The device combination determiner 150 uses information on the energy consumption model received from the energy consumption model determiner 140 and information on the energy consumption devices registered in the current unit space received from the information inquiry unit 120. In order to meet the user's satisfaction in the current situation of the user, a combination of devices capable of minimizing energy consumption is determined. The determined energy consumption model stores information on the type and capacity of devices required to maintain control items, such as temperature, humidity, lighting, and so on. The device combination determination unit 150 may use a combination of devices that may satisfy the control item of the energy consumption model determined according to the current situation of the user by using information such as the type, capacity, and standard consumption energy of the device registered in the current unit space. Determine.

The output unit 160 outputs the information on the combination of the determined device and the value of the control item to be set according to the determined energy consumption model. The output unit 160 may use a display unit or an audio unit that outputs a value of a control item set according to information on a combination of devices or an energy consumption model. For example, the device combination of the air conditioner 1, the air conditioner 2, the fluorescent lamp 1, the fluorescent lamp 2, and the fluorescent lamp 3 is displayed through the display unit, and the control item value of the control temperature 22 ° C. and the control illumination 3100 lm is displayed.

Meanwhile, the device search control unit 170 is the same as the type identifier of each device included in the device combination among the devices stored in the device information database, and has a higher energy efficiency than the device registered in the current unit space. Search for information on the device information database server, and outputs the information about the searched device to the user through the output unit 160.

3 is a functional block diagram for explaining in more detail the user context information generation unit according to an embodiment of the present invention.

Referring to FIG. 3, the user context information generating unit includes a user static information database 131 storing user static information and a user dynamic information database 132 storing user dynamic information. The user static information is user information which does not change easily among user information, and means information such as user gender, age, name, occupation, school, home / school address, and the like. On the other hand, the user dynamic information is user information that can be easily changed among the user information, for example, refers to information such as the user's current location, current time, current temperature, user's schedule, taste. Preferably, the user static information is input by the user directly through the user interface unit 180, and user dynamic information such as the current position, current time, and current temperature among the user dynamic information is installed in the current unit space. The node may be collected and stored by a node or Zigbee nodes, and user dynamic information, such as a schedule and a taste of the user, may be input and stored in the user terminal through the user interface unit 180.

The context information generating unit 133 uses the user static information stored in the user's static information database 131 and the user dynamic information database 132 or the information ontology stored in the user dynamic information and information ontology database 135. To generate user context information. Information ontology is a set of new semantic words that can extract the user's current situation information from user static information or user dynamic information. It is a conceptual and conceptual discussion of what people have agreed to see, hear, feel and think about the world. A model expressed in a form that can be handled by a computer. It is a technology that explicitly defines concept types or constraints on use.

4 is a flowchart illustrating an energy consumption control method according to an embodiment of the present invention.

Referring to FIG. 4, information of an energy consuming device currently installed in a unit space is received (S1). Information on the energy consuming device currently installed in the unit space is received from the device information database server 10 to the user terminal or directly from the devices currently installed in the unit space through the wired / wireless network to the user terminal. In order to receive information about a device currently installed in the unit space from the device information database server 10, an information request message including location information of a user stored in a user terminal is first sent to the device information database server 10. In response to the request message, the device information database server 10 transmits information about a device registered at the user location to the user terminal. The device actually installed in the current unit space is inquired based on the device information received from the device information database server and the device information received in the current unit space (S2).

FIG. 5 is an example of information received from a device installed in the device information database server 10 or a space in which the user terminal 100 is located, and is a device installed in the current unit space in which the user terminal 100 is located. ID (ID) of the device, type indicating the purpose of the device, the location where each device is currently installed in the unit space, the amount of energy consumed by each device, whether each device is used in the current unit space, Information about the manufacturer of the device, and the like.

Meanwhile, the user's current situation information is generated by applying user static information and user dynamic information to the information ontology (S3). The information ontology is used to extend semantic information that can be generated from each word constituting the user's static information or user dynamic information. For example, time-related ontology such as day / night, morning / afternoon, day, month, season, year, etc., situation-related ontology such as country, city, school, company, etc., situation such as travel, work, meeting, seminar, exercise, etc. The related ontology is used as the information ontology.

6 illustrates an example of user context information generated by applying acquired user static information or user dynamic information to an information ontology. As shown in Figure 6, the current time of July 29, 2:05 PM, the current location B312 underground lecture room, personal schedule of the dynamic seminar stretching user schedule from 2 pm to 4 pm July 29 Apply user dynamic information of 2:05 PM to time ontology to create user situation information of summer and hottest day, and apply user dynamic information of B312 underground lecture room to location ontology for user situation information of hot, wet and dark classroom Create In addition, user dynamic information, such as stretching class, is applied to activity ontology to generate user context information of high activity.

Based on the created situation information of the user, among the plurality of energy consumption models stored in the energy consumption model database, an energy consumption model that best matches the situation information of the user or exhibits a matching degree equal to or greater than a first threshold value is selected (S5). .

When the energy consumption model is selected, the information on the energy consumption device registered in the current unit space received and the selected energy consumption model can be used to minimize energy consumption while satisfying the user's satisfaction in the current situation of the user. The combination of the devices is determined (S7). For example, if the user's current situation information is summer, 2:00 pm, and in a 10-square-foot underground seminar room, 15 students are doing active stretching classes, the energy consumption that best matches the user's context information Assume that the air conditioning capacity required by the model is 7 in total and the size of the lights is 10 in total. Currently, four air conditioners (air conditioner 1, air conditioner 2, air conditioner 3, and air conditioner 4) are installed in the unit space, and 10 fluorescent lights are installed, and the capacity of the air conditioners 1 to 4 is 5, 2, 4, and 5, respectively. If the lighting size is 2, the air conditioner 1 and air conditioner 4 or air conditioner 2 and air conditioner 4 combinations are selected to satisfy the air conditioner capacity and light intensity required by the energy consumption model. Choose. That is, a combination of air conditioners and fluorescent lamps that do not exceed the capacity and lighting intensity of the air conditioner required by the energy consumption model while satisfying the user's satisfaction is selected. Preferably, a combination of air conditioners or a combination of fluorescent lamps is selected based on the mounting position of the air conditioner or the fluorescent lamp so as to satisfy the air conditioner capacity or the light intensity required by the energy consumption model while optimizing the effect of cooling or the efficiency of the lighting. For example, the air conditioner 1 and the air conditioner 2 of the air conditioner 2, which is far from the air conditioner 4, can be selected as a combination with the air conditioner 4 or a combination of fluorescent lamps that operate according to the lighting intensity required by the energy consumption model among the 10 fluorescent lamps. have.

The information on the combination of the selected device is output through the display unit or the audio to provide the user with the information on the device combination that can satisfy the user satisfaction and minimize the energy consumption (S9). Preferably, the device constituting the selected device combination is operated while providing information about the device combination to the user.

7 is a flowchart illustrating an example of a method of determining a device combination in the present invention.

Referring to FIG. 7, among the plurality of energy consumption models stored in the energy consumption model database, an energy consumption model having the same user's situation information and a category item or index word is searched for (S11). The degree of matching (MD) between the retrieved energy consumption models and the user's context information is calculated. Preferably, the matching degree between the energy consumption model and the user context information may be calculated as in Equation (1) below.

[Equation 1]

Where A, B, C, ... are the same as the category, such as season, time, activity type, lighting, attendance, area, etc., α is the weight of each category, and f is the category This value indicates the degree of correspondence between the content of the index word and the user context information.

For example, if the user context information generated by applying user static information and dynamic information to the information ontology is season-summer, a value of 1 if the category of the energy consumption model includes season, otherwise 0 The value is assigned. In addition, if summer exists in the index of the energy consumption model, the degree of matching is 1, a value of 0.5 for energy consumption models with an index term of fall or spring, and an energy consumption model with an index term of winter. A value of zero is assigned. On the other hand, when controlling the energy consumed by the heating and cooling device, the category of the season, time, activity type has a high weight, the lighting has a relatively low weight compared to the category of the season.

Among the searched energy consumption models, it is determined whether there is an energy consumption model in which the matching degree MD between the energy consumption model and the user context information exceeds the first threshold value TH1 (S15), and the matching degree is the first threshold value. An energy consumption model that exceeds the value TH1 is selected and a device combination is determined based on the selected energy consumption model (S17). Preferably, when there are a plurality of energy consumption models whose matching degree exceeds the first threshold value TH1, the energy consumption model with the highest matching degree is selected and the device combination is determined based on the selected energy consumption model. . Meanwhile, when there is no energy consumption model whose matching degree exceeds the first threshold value TH1 among the searched energy consumption models, only information on each device currently installed and registered in the unit space is provided to the user. S19). The user can manually select a device combination to suit the current situation of the user by using the information on each device.

8 is a flowchart illustrating an example of a method for providing homogeneous device information to a user in the present invention.

In more detail with reference to FIG. 8, when a device combination is determined based on the selected energy consumption model, the device constituting the device combination is determined (S21), and the device type determined from the device information received from the device information database server. The identifier is extracted (S23). Information about a device having the same type identifier as the extracted device type identifier among the devices stored in the device information database server is obtained (S25). Based on the obtained device information, it is determined whether there is a device which is used for the same purpose as the device constituting the device combination and has a higher energy efficiency (S27). Preferably, it is determined whether there is a device that is higher in energy efficiency than the energy efficiency of the devices constituting the device combination. The device information is provided to the user by outputting information about a device having a higher energy efficiency than the device configuring the device combination to the display unit or the audio unit (S29).

9 is a flowchart for explaining an example of a method for receiving information on a device currently installed in a unit space.

Referring to FIG. 9, device information is directly received from a device currently installed in a unit space (S31), and device information received directly from a device information database server is compared with each other (S33). As a result of the comparison, when the device information received from the device information database server does not include the directly received device (S35), that is, when the directly received device is not registered in the device information database server, the device information database is not registered. It is determined whether a user command for requesting a registration to the server is input and the unregistered device is registered in the device information database server (S36). Meanwhile, as a result of the comparison, when information on some devices among the devices registered in the device information database server is not directly received in the current unit space, that is, when the device registered in the current unit space is removed, It is determined whether a user command for deleting information is input to the device information database server, and the removed device is deleted from the device information database server (S37).

Meanwhile, the above-described embodiments of the present invention can be written as a program that can be executed in a computer, and can be implemented in a general-purpose digital computer that operates the program using a computer-readable recording medium.

The computer-readable recording medium may include a magnetic storage medium (eg, ROM, floppy disk, hard disk, etc.), an optical reading medium (eg, CD-ROM, DVD, etc.) and a carrier wave (eg, the Internet). Storage medium).

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 is a functional block diagram schematically showing an intelligent energy control system according to the present invention.

2 is a functional block diagram of an energy consumption control apparatus according to an embodiment of the present invention.

3 is a functional block diagram of a user context information generation unit according to an embodiment of the present invention.

4 is a flowchart illustrating a method of controlling energy consumption according to an embodiment of the present invention.

5 is an example of information received from a device that is installed and registered in a space in which the device information database server 10 or the user terminal 100 is located.

6 illustrates an example of user context information generated by applying acquired user static information or user dynamic information to an information ontology.

7 is a flowchart illustrating an example of a method of determining a device combination in the present invention.

8 is a flowchart illustrating an example of a method of providing homogeneous device information to a user in the present invention.

9 is a flowchart for explaining an example of a method for receiving information on a device currently installed in a unit space.

Description of the main parts of the drawing

100: user terminal 110: transceiver

120: device inquiry unit 130: user context information generation unit

140: energy consumption model determination unit 145: energy consumption model DB

150: device combination determination unit 160: output unit

170: device search control unit 180: user interface unit

Claims (10)

An information inquiry unit for requesting device information registered in a current unit space of a user based on user location information and inquiring information of a device installed in the unit space; A user context determination unit which determines user context information by applying static information of the user and dynamic information of the user to the information ontology; An energy consumption model determiner configured to determine an energy consumption model matching the determined situation information of the user; A device combination determination unit determining a device combination for operation control in the current unit space based on the determined energy consumption model and the inquired device information; And And an output unit for outputting information on the determined device combination to a user terminal. The method of claim 1, wherein the user situation determination unit A user information database storing static information of the user and dynamic information of the user; An information ontology database that stores the information ontology; And And a situation information generator for generating situation information of the user by applying the static and dynamic information of the user to the information ontology. The energy consumption control device of claim 2, wherein And a device search control unit for searching for information on a device of the same type as the device included in the device combination, and providing information about the searched device of the same kind to a user terminal. (a) querying information on a device installed in a user's current unit space based on location information of the user terminal; (b) generating user context information by applying user static information and user dynamic information to an information ontology; (c) determining an energy consumption model matching the user context information in an energy consumption model DB; (d) determining a device combination for operation control based on the determined energy consumption model and the information of the inquired device; And (e) providing information on the determined device combination to a user terminal or directly controlling the determined device combination. The method of claim 4, wherein Information about the device And at least one of a device ID, a device type, a device location, a standard energy consumption, a manufacturing company, and a measured energy consumption. The method of claim 4, wherein The user static information is at least one of a user's name, age, occupation, school, gender, and address. The user dynamic information is energy consumption control method, characterized in that at least one of the user's current location, current time, current temperature, the user's schedule, taste. The method of claim 4, wherein the information ontology And at least one of time ontology, location ontology, and activity ontology. The method of claim 4, wherein step (c) Searching the energy consumption model database for an energy consumption model matching the user context information using the user context information as an index word; Calculating a matching degree between the retrieved energy consumption model and the user context information; And And selecting an energy consumption model that shows the highest matching degree based on the calculated matching degree. The method of claim 4, wherein step (a) Receiving information from an energy consuming device currently present in the unit space; Determining whether the energy consuming device is an energy consuming device previously registered in a device information database based on the received information; And Registering an unregistered energy consuming device in the device information database or deleting a device removed from the current unit space from the device information database based on the determination result.  The method of claim 4, wherein the energy consumption control method is Extracting information about each device and the same device from a device information database based on the type of each device included in the energy consuming device combination; Comparing the extracted homogeneous devices with energy consumption for each of the devices; And And providing the user terminal with information about a homogeneous device, the energy consumption of which is lower than the respective devices by a threshold value, based on the comparison result.

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