KR101633969B1 - Building Energy Management System Based on Context-Aware and Method for Managing Energy of Building Using The Same - Google Patents

Abstract

A building energy management system based on a situation recognition according to an aspect of the present invention which can predict the energy consumption of a building in real time by using the situation recognition includes sensing data transmitted from a moving sensor or a fixed sensor installed in a building, Personalized data composed of at least one of user social network data on a social network of users and schedule data of a group composed of a user or a plurality of users and operation schedule data of facilities installed in the building; And generating a prediction model by applying a context-aware technique to the sensing data, the personalization data, and the operation schedule data of the facilities, and calculating a situation estimation Module < / RTI >

Description

TECHNICAL FIELD The present invention relates to a building energy management system based on context awareness and a building energy management method using the same,

The present invention relates to an energy management system, and more particularly, to a building energy management system and a building energy management method using the same.

Building Automation System (BAS), which utilizes computers to operate, control, and manage large-scale building facilities due to the large size of buildings, various electric power equipment, air conditioning equipment, Has been applied. Recently, with the development of computer and communication technology, a building automatic control system is rapidly developing and a building automatic control system is installed according to the use and size of a building.

Such a building automatic control system mainly functions as monitoring and control of each facility in order to maintain the facilities of a large building in an optimal state. Therefore, the general building automatic control system can perform the integrated management of the hardware / power / lighting installed in the building, but since it can not integrate the facilities installed in the building in terms of actual energy management, There is a drawback that it falls.

In order to compensate for the disadvantages of such automatic building control systems, a building energy management system (hereinafter referred to as a "building energy management system"), which automatically calculates the performance and efficiency of facilities using operation data of facilities measured by various sensors, BEMS: Building Energy Management System) has been proposed. An example of such a building energy management system is disclosed in Korean Patent Laid-Open No. 10-2009-0066107.

However, the existing building energy management system can not predict the energy usage of each facility installed in the building. Therefore, it can not reflect the energy state of equipment that changes rapidly when the operation plan of each facility is established, There is a limitation that it can not effectively manage energy use.

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a building energy management system based on a situation recognition capable of predicting energy consumption of a building in real time by using the situation recognition, and a building energy management method using the same do.

The present invention also relates to a building expert-based energy management system capable of generating an energy management schedule of a building based on the energy consumption of the building and using the renewable energy as a building energy source according to the generated building energy management schedule And a method for managing building energy using the same.

According to one aspect of the present invention, there is provided a building energy management system based on context recognition, comprising sensing data transmitted from a mobile sensor or a fixed sensor installed in a building, a social network ) Personalized data composed of at least one of user social network data on a plurality of users and schedule data of a group composed of a user or a plurality of users, and an operation schedule data of facilities installed in the building; And generating a prediction model by applying a context-aware technique to the sensing data, the personalization data, and the operation schedule data of the facilities, and calculating a situation estimation And a module.

According to another aspect of the present invention, there is provided an energy management method for context awareness based on sensing data transmitted from a mobile sensor or a fixed sensor installed in a building, a user social network Collecting personalized data composed of at least one of data and schedule data of a group consisting of a user or a plurality of users, and operational schedule data of facilities installed in the building; And generating a prediction model by applying a situation recognition technique to the sensing data, the personalization data, and the operation schedule data of the facilities, and predicting the energy use amount of the building using the generated prediction model .

According to the present invention, the energy consumption of a building can be predicted in real time by applying a situation recognition technique to sensing data, individual and group schedule data provided from various sensors, and post data registered in a social network, It also has the effect of optimizing the energy use of buildings by adaptively coping with the energy usage status of facilities.

According to the present invention, the energy management schedule of the building is generated using the predicted energy usage amount, and the renewable energy is used as the energy source of the building instead of the existing energy according to the energy management schedule of the building. Construction / urban / energy fields can be fused and the energy required for building operation can be efficiently managed and used at low cost.

According to the present invention, since the system is designed in a platform layer structure, it is possible to extend not only the non-residential building but also the residential building, thereby maximizing the application range of the system.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram of a network configuration to which a context awareness based energy management system according to an embodiment of the present invention is applied. FIG.
FIG. 2 is a block diagram schematically illustrating the configuration of a context awareness-based energy management system according to an embodiment of the present invention; FIG.
3 is a block diagram schematically showing the configuration of the situation recognition module shown in Fig.
FIG. 4 is a flow chart illustrating a method of energy management based on context recognition according to an embodiment of the present invention. FIG.
5 is a flow chart illustrating a method for predicting real-time energy usage according to an embodiment of the present invention.

The meaning of the terms described herein should be understood as follows.

The word " first, "" second," and the like, used to distinguish one element from another, are to be understood to include plural representations unless the context clearly dictates otherwise. The scope of the right should not be limited by these terms.

It should be understood that the terms "comprises" or "having" does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

It should be understood that the term "at least one" includes all possible combinations from one or more related items. For example, the meaning of "at least one of the first item, the second item and the third item" means not only the first item, the second item or the third item, but also the second item and the second item among the first item, Means any combination of items that can be presented from more than one.

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

Building awareness-based building energy management system

First, a building awareness-based building energy management system according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 and 2. FIG.

FIG. 1 is a diagram schematically showing a network configuration to which a building energy management system based on a situation recognition (hereinafter referred to as a 'building energy management system') according to an embodiment of the present invention is applied.

1, the building energy management system 100 according to the present invention operates in conjunction with the renewable energy management apparatus 110 and the building group energy integrated management center 120, ) To manage the energy of the building in which it is installed. At this time, a building means a concept including not only a non-residential building but also a residential building. Hereinafter, for the convenience of explanation, it is assumed that the building in which the building energy management system 100 is installed is a non-residential building, but the building energy management system 100 according to the present invention may be installed in a residential building.

First, the building energy management system 100 is installed for each building group in which a building or a plurality of buildings are grouped, and estimates the energy usage amount of the buildings included in each building or building group in real time. Based on the predicted energy usage amount, Optimize the energy use of each building by creating a building energy management schedule. Hereinafter, for the sake of convenience of explanation, it is assumed that the building energy management system 100 is installed in one building.

The construction of such a building energy management system 100 will be described in more detail with reference to Fig.

2 is a block diagram schematically illustrating a configuration of a building energy management system 100 according to an embodiment of the present invention.

2, the building energy management system 100 according to an exemplary embodiment of the present invention includes a data collection device 210, a building automation device 220, and a situation recognition module 230. [

First, the data collection device 210 collects sensing data sensed by each sensor from various sensors installed in the building. In one embodiment, the data collection device 120 may collect sensing data sensed by each sensor from a static sensor 211 and a mobile sensor 212 installed in each building. At this time, the fixed sensor 211 and the moving sensor 212 may include a temperature sensor, a room sensor, a humidity sensor, an illuminance sensor, an entrance sensor, and the like.

Particularly, in order to enable the situation recognition module 230 to predict the energy consumption of each building in real time, the data collection device 210 according to the present invention may be configured so that the user social Network data can be collected in real time. At this time, the data collection device 120 receives predetermined energy-related keywords (for example, 'hot', 'cold', 'moist', etc.) among the posts uploaded on the social network by the users located in the building from the social network server 213 A keyword related to temperature such as 'air conditioning', 'electric fan', 'heater', 'humidifier', etc.) can be collected as social network data. Hereinafter, the social network data will be described as the post data for convenience of explanation.

The data collection device 210 according to the present invention collects daily / weekly / monthly schedule data of users and groups of the building from the task management server 214 and receives various schedule data from the building management server 215, And collects the operation schedule data of the users. The daily / weekly / monthly schedule data and the operation schedule data of the users and the groups are used for predicting the movement pattern of the users in each building in each building or for predicting the usage state of energy use facilities in each building.

In this case, daily / weekly / monthly schedule data of the bulletin data, users and groups are data for enabling energy management according to the characteristics or preferences of specific individuals or groups. Therefore, Weekly / monthly schedule data may be collectively referred to as personalized data.

2, the task management server 214 and the building operation server 215 are separated from the building automation device 220. However, this is merely one example, (215 may be included in the building automation device 220).

The data collecting unit 210 collects climate information at predetermined time points from a weather station server (not shown).

The data collecting unit 210 transmits the sensing data, the bulletin data, the schedule data, the operation schedule data of the facilities, and the climate information as described above to the situation recognition module 230 through the building automation device 220.

Next, the building automation apparatus 220 performs measurement and control on various facilities constituting the building.

In particular, the building automation apparatus 220 according to the present invention transmits the data collected by the data collection unit 210 to the situation recognition module 230 according to a predetermined communication protocol, And controls the operation of each facility installed in the building according to the control command.

In one embodiment, the building automation device 220 and the situation recognition module 230 may use OPC (OLE for Process Control) as a protocol. OPC refers to a standard interface that enables various applications to transfer data from various types of process control devices to the upper end according to the OPC Tag system. OPC also provides a high level of interoperable information processing between client applications and server applications supplied by different vendors.

Specifically, the building automation device 220 performs control of the heating ventilation air conditioning (HVAC) for air conditioning and cooling / heating of the building, and control of electric system devices such as a water distribution facility and a distribution facility.

Also, the building automation device 220 adjusts the power consumption of the building so that the power consumption of the building does not exceed the set target value. For this, the building automation device 220 monitors the power consumption of the building, and when the monitored power consumption exceeds the set target value, the building automation device 220 determines the operation of each facility according to a predetermined priority (for example, So that the power consumption does not exceed the set target value.

Also, the building automation device 220 controls the lighting equipment installed in the building using the field control device information for the lighting distribution board of the building. At this time, the building automation device 220 can automatically control lighting facilities using program control (e.g., time schedule, program switch control, or telephone control).

In addition, the building automation device 220 prevents the occurrence of accidents such as theft or fire in a building through automatic control of a security facility, and controls the entry / exit of outsiders and passers-by and visitors, So that it can cope and process.

Next, the situation recognition module 230 estimates energy usage in each building in real time using sensing data, bulletin data, schedule data, operation schedule data of the facilities, and climate information transmitted from the building automation device 220 And generates a building energy management schedule according to the predicted energy usage. At this time, the energy management schedule of the building means a stop / start plan of the facilities installed in each building at each time point.

The situation recognition module 230 analyzes sensed data sensed by a moving sensor or a fixed sensor, posted data uploaded on a social network, and schedule data of users to analyze how the energy usage in the building will be changed And recommend the operation plan of each facility according to the predicted result.

Specifically, the context recognition module 230 applies not only the sensing data but also the context data that the users located in the building upload to the social network and the context-aware method using the schedule data of each user and the group, We generate forecasting models to predict the energy usage of buildings in real time, and predict the energy consumption of the buildings by using the generated prediction models.

In addition, the situational awareness module 230 may optimize building energy management by creating an energy management schedule for the building based on the predicted energy usage.

Hereinafter, the configuration of the situation recognition module 230 will be described in more detail with reference to FIG.

FIG. 3 is a block diagram illustrating a configuration of a situation recognition module according to an exemplary embodiment of the present invention. Referring to FIG.

3, the situation recognition module 230 according to an exemplary embodiment of the present invention includes an analyzing unit 232 and a predicting unit 234, and the adjusting unit 236 and the operation schedule generating unit 238 ).

First, the analyzing unit 232 analyzes the energy usage amount and the average energy usage amount of each time zone in the building using the sensing data, the bulletin data, the schedule data, the operation schedule data of the facilities, and the climate information transmitted from the building automation apparatus 220 .

Specifically, the analyzing unit 232 calculates the energy consumption (for example, electricity consumption / gas consumption / water usage / lighting usage amount) in each time zone with the time (for example, minute / day / month / season / Etc.) as a Y-axis. At this time, the analysis unit 232 can generate an energy usage pattern for each floor in the case of a building having a plurality of layers.

The analysis unit 232 stores a pattern of the energy usage amount of the building of each building generated in each time zone in the database 238.

In addition, the analysis unit 232 may generate and store a movement pattern of a user in a building, an operation pattern of each facility or facility installed in the building, and a moving trend pattern such as room temperature / humidity / outdoor temperature / Co2.

Then, the analyzing unit 232 selects factors that affect the generated pattern using a regression analysis model. Specifically, the analysis unit 232 assigns the energy usage of each floor to the predetermined regression analysis model, the sensing data received from the building automation apparatus 220, the schedule data, the operation schedule data of the facilities, and the climate information as input values Thereby selecting factors that affect energy usage in the layer. For example, factors influencing energy consumption in the corresponding layer include the number of occupants, the number of lights that are on, the temperature of the layer, the type of facility in operation, the humidity of the floor, And so on.

In one embodiment, the analyzer 232 may output the selected factors in the form of an output function having the energy usage of each layer as the Y value and the factors affecting the energy usage as the X value.

For example, when the energy consumption of the first floor of the building is 120, the analysis unit 232 sets the energy consumption amount 120 of the first floor as the Y value, and the temperature value of the first floor given weight "A" Quot; C "and the number of servers to which the weight" D "is assigned as the X value.

Then, the analyzer 232 analyzes the correlation between the respective factors and determines the weight values included in the generated function. In one embodiment, the value of each weight may be determined according to the priority of each factor. For example, the analyzer 232 may determine the priorities of the respective factors based on the past analysis data, and determine the values of the weights of the respective factors according to the determined priorities. For example, when the amount of energy used in the corresponding layer tends to increase as the room occupancy increases in the corresponding layer based on the past analysis data in the corresponding layer, the analyzing unit 232 assigns weight values to the occupancy You can set the highest ranking.

Next, the predicting unit 234 predicts the output function, the energy (electricity / gas / water supply) unit price, the schedule data received from the building automation apparatus 220 and the facilities The prediction model is generated by reflecting the operation schedule data to the predetermined space-time probability model, and the real-time energy consumption in the building is predicted through the generated prediction model. At this time, the spatiotemporal probability model may be generated for each facility for each facility installed in the building.

That is, in the case of the present invention, the energy consumption is estimated by reflecting the output function, the energy unit price, the schedule data received from the building automation device 220, and the operation schedule data of the facilities calculated by the analysis unit 232 in the space- The prediction accuracy can be improved.

For example, according to the operation schedule data of the facilities, it is scheduled that the cooling and heating facilities of the first meeting room are not operated at 10:00 am. When the schedule data is used, five users are allowed to meet at 10:00 am in the first meeting room , And it is assumed that the temperature at 10 am is expected to be 28 degrees. In this case, the predicting unit 234 determines that the cooling facility of the first meeting room should be operated at 10:00 am, and adds the energy usage amount for the cooling facility operation of the first meeting room to the predicted energy usage amount by the predetermined energy usage prediction model It is possible to accurately predict real-time energy usage in the building.

In one embodiment, the prediction unit 234 may further estimate the energy usage based on the preference of the individual by reflecting the posted data uploaded on the social network in predicting the energy consumption of the building. For example, as a result of analyzing the posted data uploaded by the user A, if the user A frequently uploads a post that is cold due to cooling even during the summer, the user A determines that the user does not want to operate the air conditioning equipment in summer, The energy consumption of the building can be predicted by reflecting the personal preference of the user A by reducing the energy consumption for the operation of the air conditioning system of the space.

The prediction unit 234 transmits the predicted energy usage amount to the building group energy integrated management center 120 so that the building group energy integrated management center 120 can distribute the energy required for the building based on the predicted energy usage amount .

On the other hand, the predicting unit 234 temporally patterns and stores data generated from the sensing data, the bulletin data, the schedule data, and the facility operation schedule data received from the building automation apparatus 220 over a predetermined number of times , The stored pattern may be used for energy usage prediction.

Next, the correcting unit 236 compares the actual energy usage with the predicted energy usage by the predicting unit 234, and corrects the predicted energy usage when the result is different. In one embodiment, if it is determined that an error has occurred in the predicted energy usage due to the error of the sensing data measured by the sensor, the correction unit 236 may determine that the error The predicted energy use amount by the prediction unit 234 can be corrected using the data. For example, when the temperature data sensed by the temperature sensor is judged to be erroneous and the post data containing the current temperature exists in the post data, the sensed data is replaced with the temperature included in the post, Predict again.

Next, the operation schedule generation unit 238 generates an energy operation schedule of the building based on the energy usage amount predicted by the prediction unit 234 or the energy usage amount corrected by the correction unit 236. [ Specifically, the operation schedule generation unit 238 establishes a start or stop plan for each facility installed in the building based on the energy consumption of the building.

The operation schedule generator 238 generates a control signal for starting or stopping each facility when it is time to start or stop each facility according to the building energy operation schedule and transmits the control signal to the building automation apparatus 220 So that the building automation apparatus 220 can start or stop the facility.

In the above-described embodiment, it is described that the situation recognition module 230 performs the start or stop of each facility according to the predicted energy usage amount through the building automation device 220. However, in the modified embodiment, Lt; RTI ID = 0.0 > 230 < / RTI > For this, the situation recognition module 230 may further include a remote control module (not shown) for starting or stopping each facility remotely according to a control signal.

Although not shown in FIG. 2, the situation recognition module 230 learns the result calculated by the analysis unit 232 and inverts the energy consumption in the building only by the factors selected by the analysis unit 232 And an artificial neural network learning module for estimating the neural network model. For example, if the room temperature is 18 degrees and the room occupancy is predicted to be 30 by learning the result calculated by the analyzing unit 232, the artificial neural network learning module estimates that the energy consumption in the corresponding layer will be 120 can do. In this case, the neural network learning module can estimate the indoor temperature and the room occupancy from the schedule data.

The building energy management system 100 as described above may be configured such that various sensors and data collection units 210 are disposed in a first layer, an analysis unit 232 of a situation recognition module 230 is disposed in a second layer, The system may be designed in a platform layer structure in which the prediction unit 234, the correction unit 236, and the operation schedule generation unit 236 of the recognition module 230 are arranged in the third layer. Therefore, the present invention can easily extend not only the non-residential building but also the residential building, thereby maximizing the application range of the system.

 Referring to FIG. 1 again, the renewable energy management apparatus 110 collects and analyzes the climate information and the electric power market information, and compares the generated amount of new and renewable energy with the amount of energy required in the building integrated energy management center 120 To establish a feed plan. In addition, the renewable energy management apparatus 110 plays a role of supplying renewable energy to each building in which the building energy management system 100 is installed, as an energy source of the building, according to a power supply plan.

Next, the building group energy integrated management center 120 distributes or manages energy required in each building according to the energy consumption of a building group defined as a building or a group of building groups located in a predetermined area. To this end, the building group energy integrated management center 120 includes a building group energy distribution device 122, an energy control device 124, a building group energy overall management device 126, and a building group integrated operation module 128 do.

First, the building group energy distribution device 122 supplies renewable energy supplied by the renewable energy management device 110 and power supplied from a power plant such as hydroelectric power, thermal power, and nuclear power under the control of the energy control device 124 Energy is distributed to each building and supplied to each building.

The energy control unit 124 calculates the amount of energy to be allocated to each building based on the total energy consumption of the building group calculated by the building group energy management system 126, And controls the building group energy distribution device 122 to be supplied.

The Building Energy Total Management System (BETMS, 126) monitors the energy usage of each building or group of buildings located in the area in real time. Particularly, the energy management system 100 installed in each building or group of buildings according to the present invention collects information on a building located in the corresponding area based on the predicted energy usage for each building or group of buildings And transmits it to the renewable energy management device 110 and the energy control device 124. The renewable energy management device 110,

The building group energy overall management device 126 requests the renewable energy management device 110 to supply energy based on the total energy consumption of the building group and the energy analyzed by the minimum cost, Check whether it is actually supplied.

Particularly, the building group energy management apparatus 126 according to the present invention is a device for managing the renewable energy as an energy source for the energy consumption based on the energy unit price and the energy usage amount requested by the energy management system 100 Decides whether to utilize energy supplied from power plants such as hydroelectric power, thermal power, and nuclear power. Accordingly, the building group energy management apparatus 126 requests the renewable energy management apparatus 110 to determine the amount of energy determined when the renewable energy is determined as the energy source, and the remaining energy amount is required to be determined by the hydro-power, thermal power, KEPCO will supply energy by

 In addition, the building group energy general management apparatus 126 may remotely access the energy management apparatus 100 installed in each building or group of buildings to monitor the hardware / lighting equipment / power status of each building or group of buildings, Depending on the result, the equipment / lighting fixture / power status is controlled remotely.

Next, the integrated building management module 128 generates and provides each building energy consumption collected through the building group energy management apparatus 126 or the estimated energy consumption for each building in a report format, Manage events and alarms in the form of history.

Building awareness-based building energy management method

Hereinafter, a method for managing building energy based on the context recognition according to the present invention will be described with reference to FIG.

FIG. 4 is a flowchart illustrating a method for managing building energy based on a situation recognition according to an embodiment of the present invention.

The building awareness-based building energy management method shown in FIG. 4 can be performed by a building energy management system based on the situation recognition (hereinafter referred to as 'building energy management system') shown in FIG.

First of all, the building energy management system includes sensing data sensed by a moving sensor or a fixed sensor, posted data uploaded by users located in a building on a social network, daily / weekly / monthly Schedule data, and operation schedule data of various facilities installed in the building (S400).

In one embodiment, the sensing data may include the temperature sensed by the temperature sensor, the humidity sensed by the humidity sensor, the illuminance sensed by the illuminance sensor, or whether or not it is obtained by an access sensor or the like.

In addition, the bulletin data is used to predict the energy usage of each building in real time, and it is possible to use a predetermined temperature-related keyword (e.g., 'hot', 'cold', ' Related keywords such as 'air conditioners', 'electric fans', 'heaters', 'humidifiers', and the like).

In addition, the daily / weekly / monthly schedule data of the users and the groups are for predicting the movement pattern of the users in each time zone or the utilization pattern of the facility (e.g., conference room) of the building, and the operation schedule data of the facilities And to predict the usage status of the facilities.

In addition, the building energy management system may collect additional climate information at predetermined time points from the weather service server (not shown).

Then, the building energy management system generates the prediction model by applying the situation recognition technique to the collected sensing data, the bulletin data, the schedule data, the operation schedule data of the facilities, and the climate information, The usage amount is predicted in real time (S410). The building energy management system analyzes sensed data sensed by a moving sensor or a fixed sensor, posted data uploaded on a social network, and schedule data of users to determine how energy usage in the building will be changed And recommend the operation plan of each facility according to the predicted result.

Specifically, the building energy management system applies not only the sensing data but also the post data uploaded to the social network by the users located in the building and the context-aware method using the schedule data of each user and the group, The energy consumption of each building is predicted in real time through the generated prediction model, and the building energy management schedule is generated based on the predicted energy usage amount so that the energy management of the building can be optimized.

Hereinafter, referring to FIG. 5, a method for real-time prediction of energy consumption of a building by the building energy management system will be described in more detail.

FIG. 5 is a flowchart illustrating a method for predicting energy consumption in real time by a building energy management system according to an embodiment of the present invention.

5, the building energy management system uses the collected sensing data, bulletin data, schedule data, operation schedule data of facilities, and climate information to calculate energy consumption and average energy usage (S500).

Specifically, the building energy management system uses the time (for example, minute / day / month / season / year and the like) as the X axis and calculates the amount of energy used in each time zone (for example, electricity consumption / gas consumption / water usage / ) As a Y-axis to generate a pattern of energy usage. At this time, the building energy management system can generate an energy usage pattern for each floor in the case of a building having a plurality of layers.

In the above-described embodiment, the building energy management system is described as generating a pattern of energy usage. In a modified embodiment, however, the building energy management system can be classified into a moving pattern of a user in a building, And a moving trend pattern such as a room temperature / humidity / outdoor temperature / Co2 may be additionally generated.

Thereafter, the building energy management system selects a factor that affects the pattern generated in S500 using a regression analysis model (S510). Specifically, the building energy management system assigns energy values of each floor to the predetermined regression analysis model, the collected sensing data, schedule data, operation schedule data of facilities, and climate information as input values, And the factors that affect the performance of the system.

For example, factors influencing energy consumption in the corresponding layer include the number of occupants, the number of lights that are on, the temperature of the layer, the type of facility in operation, the humidity of the floor, And so on.

In one embodiment, the building energy management system may output the energy usage of each floor as an output value in the form of an Y value and factors that affect the energy usage as X values.

For example, assuming that the energy consumption of the first floor of the building is 120, the building energy management system sets the energy consumption amount 120 of the first floor to the Y value, and the temperature value of the first floor to which the weight "A" Quot; C "and the number of servers to which the weight" D "is assigned as the X value can be generated and output.

Thereafter, the building energy management system determines the values of the weights included in the output function output at S510 by analyzing the correlation between the respective factors selected at S510 (S520). In one embodiment, the building energy management system may determine the value of each weight according to the priority of each of the factors. At this time, the building energy management system can determine the priorities of the respective factors based on the past analysis data, and determine the values of the weights of the respective factors according to the determined priorities.

For example, if energy usage in a given floor tends to increase as the number of residents increases in a given floor based on past analysis data in that floor, the building energy management system will prioritize the weight Can be set to the highest.

Next, the building energy management system reflects the weighted output function, energy (electric / gas / manual, etc.) unit price, schedule data, and operation schedule data of the facilities calculated in S520 to the predetermined space-time probability model, And estimates real-time energy usage in the building through the generated prediction model (S530). At this time, the spatiotemporal probability model may be generated for each facility for each facility installed in the building.

That is, in the case of the present invention, prediction accuracy can be improved because the energy consumption is estimated by reflecting the output function, the energy cost, the schedule data, and the operation schedule data of the facilities, which are output in S520, to the spatiotemporal probability model.

For example, according to the operation schedule data of the facilities, it is scheduled that the cooling and heating equipments of the first meeting room do not operate at 10:00 am, and when the schedule data is used, 5 users at the first meeting room at 10:00 am , And it is assumed that the temperature at 10 am is expected to be 28 degrees. In this case, the building energy management system judges that the cooling facility of the first meeting room should be operated at 10:00 am, and the energy consumption for the cooling facility operation of the first meeting room is added to the predicted energy consumption by the predetermined energy consumption prediction model It is possible to accurately predict real-time energy usage in the building.

In addition, the building energy management system can use the posted data uploaded on the social network to predict energy usage based on an individual's preference. For example, as a result of analyzing the posted data uploaded by the user A, if the user A frequently uploads a post which is cold due to cooling despite the summer, the building energy management system judges that the user A does not want to operate the cooling facility in the summer It is possible to predict the energy consumption of the building by reflecting the personal preference of the user A by reducing the energy consumption for the operation of the cooling system of the space in which the user A stays.

Thereafter, the building energy management system compares the estimated energy usage with the actual measured energy usage at S530 (S540). If the predicted energy usage is different from the actually measured energy usage, the predicted energy usage is corrected (S550), and then the process of S540 is repeated.

In one embodiment, if the predicted energy usage differs from the actual measured energy usage, the building energy management system may be caused by errors in the sensing data measured by the sensor, which are caused by the difference between the predicted energy usage and the actual measured energy usage If it is determined that the sensed data is replaced with the posted data uploaded on the social network, the amount of energy usage predicted in S530 can be corrected by predicting the energy usage again.

For example, when it is determined that the temperature data sensed by the temperature sensor is erroneous, and the post data containing the current temperature exists in the post data, the building energy management system stores the sensed data at the temperature included in the post By replacing it, energy usage can be revised to compensate for energy usage.

On the other hand, if the predicted energy usage amount is equal to the actually measured energy usage amount as a result of the comparison in step S540, the predicted energy usage amount in step S530 is output as a final prediction result (S560).

Meanwhile, although not shown in FIG. 5, the building energy management system may temporally pattern and store data generated at a predetermined number of times or more among sensing data, bulletin data, schedule data, and facility operation schedule data, May also be used to predict energy usage.

Although not shown in FIG. 5, the building energy management system may learn the result calculated in S520 and inversely estimate the energy usage in the building using only the factors included in the output function generated in S520.

For example, the building energy management system can estimate that if the room temperature is 18 degrees and the residential capacity is estimated to be 30 through the learning of the result calculated in S520, the energy consumption in the corresponding floor will be 120 degrees. At this time, the building energy management system can estimate the room temperature and the residence time from the schedule data.

Referring again to FIG. 4, the building energy management system generates an energy operation schedule of the building according to the predicted energy usage (S420). At this time, the energy management schedule of the building means a stop / start plan of the facilities installed in each building at each time point.

Thereafter, the building energy management system determines whether or not it is time to start or stop each facility according to the building energy operation schedule generated in S420 (S430), and it is time to start or stop each facility If it is judged, the control signal for starting or stopping the facility is generated and transmitted to the building automation device (S440). Accordingly, the building automation device starts or stops the facility according to the received control signal.

In the above-described embodiment, the building energy management system has been described that the start or stop of each facility is performed through the building automation device according to the predicted energy usage amount. However, in the modified embodiment, It may also control the start or stop of each facility installed in the building.

Meanwhile, although not shown in FIG. 4, the building energy management system transmits the predicted energy usage amount in S410 to the integrated energy management center of the building group so that the integrated energy management center of the building collects the energy required for the building To be distributed.

In the above description, it has been described that the building energy management system based on the situation recognition is implemented as a physical system. However, this is only an example, and the building energy management system based on the situation recognition is a system in which each function is programmed, And may be implemented through the execution of a program by a server or a computer.

At this time, a program for implementing a situation awareness-based building energy management system is stored in a computer-readable recording medium such as a hard disk, a CD-ROM, a DVD, a ROM, a RAM, or a flash memory.

Those skilled in the art will appreciate that the invention described above may be embodied in other specific forms without departing from the spirit or essential characteristics thereof.

For example, when the situation-aware building energy management system according to the present invention is applied to a residential building, the situation-aware building energy management system operates in conjunction with a home network server that controls the residential building, Which can control the facilities that are installed.

It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Situation awareness-based energy management system 110: Renewable energy management system
120: building integrated energy management center 210: data collection unit
220: Building Automation Device 230: Situation Recognition Module
232: Analysis section 234: Prediction section
236: Correction 238: Operation schedule creation

Claims (14)

The personalized data consisting of the user's social network data on the social network of the users located in the building and the schedule data of the group composed of a plurality of users, A data collection unit for collecting operation schedule data of facilities installed in the facility; And
A situation recognition module for generating a prediction model by applying a context-aware technique to the sensing data, the personalization data, and the operation schedule data of the facilities, and for predicting energy usage of the building using the prediction model, / RTI >
The situation recognition module includes:
Generating a pattern of energy usage and average energy usage for each time zone of the building using the sensing data, the personalization data, and the operation schedule data of the facilities, and generating at least one of a regression analysis and a correlation analysis An analyzer for calculating the factors associated with the generated pattern and the weights of the respective factors through the generated pattern; And
Generating a predictive model for estimating energy consumption of the building in real time by applying the calculated weighting factor, energy cost, schedule data, and operational schedule data of the facilities to the predetermined space-time probability model, And a prediction unit for predicting an energy use amount of the building using the generated prediction model,
Wherein the data collecting unit collects, as the user social network data, bulletin data including a predetermined energy related keyword among the bulletin data uploaded on the social network. Management system. delete The method according to claim 1,
The situation recognition module includes:
And an operation schedule generator for generating an energy operation schedule of the building based on the predicted energy usage using the prediction model. The method according to claim 1,
The situation recognition module includes:
Data of the sensing data, the personalization data, and data of the facility operation schedule data generated in a predetermined number of times or more are time-serially patterned and stored, and the energy usage is further estimated using the stored pattern Based building energy management system. The personalized data consisting of the user's social network data on the social network of the users located in the building and the schedule data of the group composed of a plurality of users, A data collection unit for collecting operation schedule data of facilities installed in the facility; And
A situation recognition module for generating a prediction model by applying a context-aware technique to the sensing data, the personalization data, and the operation schedule data of the facilities, and for predicting energy usage of the building using the prediction model, / RTI >
Wherein the situation recognition module compares the predicted energy usage with the actual energy usage using the predictive model and if the predicted energy usage and actual energy usage are different using the predictive model, And a correction unit for correcting the predicted energy usage using the model,
Wherein the data collecting unit collects, as the user social network data, bulletin data including a predetermined energy related keyword among the bulletin data uploaded on the social network. Management system. The method according to claim 1,
The situation recognition module includes:
Generating an energy operation schedule of the building based on the predicted energy usage amount using the prediction model,
Wherein when a time for starting or stopping each facility is reached according to the building energy operation schedule, a control signal for starting or stopping the facility is generated and transmitted to the building automation apparatus. system. The method according to claim 1,
The situation recognition module includes:
And an analyzing unit for generating at least one of a moving pattern of a user located in the building, an operation pattern of the facility or facilities constituting the building, and a moving trend pattern of room temperature or humidity, Building energy management system. The method according to claim 1,
And transmitting the sensing data, the user social network data, and the operation schedule data of the facilities to the situation recognition module according to a predetermined protocol, and according to a control signal transmitted from the situation recognition module according to an energy operation schedule of the building Further comprising a building management device for controlling the operation of the facilities. The personalized data consisting of the user's social network data on the social network of the users located in the building and the schedule data of the group composed of a plurality of users, Collecting operational schedule data; And
Generating a prediction model by applying a situation recognition technique to the sensing data, the personalization data, and the operation schedule data of the facilities, and predicting the energy usage of the building using the generated prediction model,
Wherein the predicting comprises:
Generating a pattern of an energy usage amount and an average energy usage amount for each time zone of the building using the sensing data, the personalization data, and the operation schedule data of the facilities;
Calculating a weight for each factor and factors associated with the generated pattern through at least one of regression analysis and correlation analysis;
Generating a prediction model by applying the calculated weighting factor, energy unit cost, schedule data, and operation schedule data of the facilities to the predetermined space-time probability model; And
Estimating energy consumption of the building in real time using the prediction model,
Wherein the collecting step collects, as the social network data, the bulletin data including a predetermined energy related keyword among the bulletin data uploaded on the social network. delete 10. The method of claim 9,
Comparing the predicted energy usage with an actual energy usage; And
Further comprising the step of correcting the predicted energy usage using the user social network data if the predicted energy usage is different from the actual energy usage. 10. The method of claim 9,
Further comprising the step of generating an energy operation schedule of the building including a stop or start plan for each of the facilities according to the predicted energy usage amount. 13. The method of claim 12,
Further comprising the step of controlling the start or stop of the facilities according to an energy operation schedule of the building. delete

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