JPWO2019235272A1 - Energy saving diagnostic program - Google Patents

Abstract

As a technology for promoting energy saving, there has been no method for enabling energy saving diagnosis for a large number of offices, factories, and other buildings by using information that is easily available even without specialized knowledge. The present invention, in the processing device for energy-saving diagnosis, from the electricity usage data of the building and the meteorological data acquired using the building address data, air conditioners, lighting, etc., the estimation of the electricity usage by base application, It provides programs for forecasting electricity usage, forecasting electricity usage for each base application such as air conditioning, lighting, etc., and conducting energy-saving diagnosis such as energy-saving analysis.

Description

The present invention relates to a program for automatically performing energy-saving diagnosis using electricity usage data for each building such as an office and a factory and address information of the building.

In recent years, the momentum to promote energy saving (hereinafter referred to as energy saving) has become more and more active, and as part of this, energy saving diagnosis of buildings (diagnosis for energy saving) is performed. Therefore, in order to develop a simple and highly accurate energy-saving diagnosis method and to efficiently support energy-saving measures, the building with high energy-saving effect is extracted from a large number of buildings using the information available from electric power companies. Development of the method is desired.
In order to save energy in buildings, it is extremely important to understand the energy usage status of the building, but in recent years, the spread of smart meters has rapidly increased, and in many buildings the measurement interval is less than 30 minutes. Quantitative data are readily available. Therefore, there is a conventional technique in which an energy saving diagnosis is performed by a program or an electricity usage amount is predicted by using an electricity usage amount measured by a smart meter or the like.
For example, in Patent Document 1, a program for diagnosing energy usage according to application is presented as a pre-stage for energy saving diagnosis. A model case is created by using a building scale and a usage pattern as input values, and usage of the model case Energy usage by application is estimated by apportioning the measured value of energy usage by the composition ratio of energy usage by usage.
Patent Document 2 creates a prediction model using past electricity usage data for each building, meteorological data, and the operating status of the equipment, and the weather forecast data and the operating status of the equipment during the prediction period, It presents a program to predict electricity usage by application.
In Patent Document 3, the past weather data is input, multiple regression is performed using the electricity usage amount as an output, a prediction model is created, and the weather forecast data is input to the prediction model to predict the electricity usage amount. The method is presented. The type of data used for input is set in advance by the analyst.

JP, 2013-65087, A JP, 2017-50971, A JP, 2004-164388, A

However, in Patent Document 1, since a model case is created by using the scale and usage pattern of a building as input values, energy consumption by application can be set when an appropriate model case cannot be set in a building in which the building size and usage pattern are unknown. The accuracy of the estimation of is low.
Further, in Patent Document 2, in order to predict the amount of electricity used, it is necessary to previously input the operating status of the equipment in the past. Furthermore, if the operating status is unknown, it is necessary for the analyst to input assuming the operating status, but the assumption of the same operating status does not apply to various buildings. If the actual operating status is different, the accuracy of the prediction will be lower.
Then, in Patent Document 3, a multiple regression model is created from past meteorological data and electricity usage data, and weather forecast data is input to the multiple regression model to obtain forecast data. Then, it is necessary for the analyst to set what is used to create the multiple regression model, such as temperature. Furthermore, the information on the operation schedule of the building needs to be input separately, and in addition, the analyst needs to select whether to analyze using the operation schedule of the building. That is, the technique of Patent Document 3 provides an analyst with a method for analyzing energy usage, and automatically predicts usage by using meteorological data and electricity usage data. It does not, but requires the analyst in advance to have knowledge of energy usage analysis.
Furthermore, for example, when using the technology of Patent Document 1, Patent Document 2 and Patent Document 3 for a customer's building in an electric power company or the like, the scale and usage form of the building are targeted for many buildings such as tens of thousands. , It is not easy to obtain and input the building-specific information such as working days and working hours.
In view of the above problems, the present invention provides a program capable of energy-saving diagnosis for a large number of buildings such as offices and factories by using readily available information without requiring specialized knowledge. The purpose is to

The present invention comprises the following technical means for the above purpose.
The first technical means is a computer
Using the electricity usage data of the building and the meteorological data around the building, which are measured in a regular cycle from the outside, operating/non-operating the building at the measurement date and time, air-conditioning, lighting, etc. A program to calculate another electricity usage and
It consists of a discrimination module, a model-type estimation module, and a usage-specific electricity usage calculation module.
The discrimination module, for each measurement time zone, using the electricity consumption data and the measurement time zone data obtained by extracting the weather data, creates a discrimination model for discriminating between operation and non-operation at the measurement date and time, In the measurement time zone, the operation at the target measurement date and time and the non-operation are carried out,
The model type estimation module uses the operation/non-operation determined by the determination module and the measurement time zone-specific data to determine the measurement time zone-specific data for each measurement time zone-specific operation/non-operation. Perform regression analysis using the meteorological data as input and the electricity usage data as output, and create an electricity usage estimation model by operating time/non-operation by measurement time zone,
The use-specific electricity usage calculation module is an upper limit value of the outside temperature of the meteorological data of the measurement time zone data, or the outside air temperature and humidity, from the operation time/operating non-operation electricity consumption estimation model according to the measurement time zone. From the lower limit value, the minimum value of the estimated value of electricity usage calculated from the electricity usage estimation model by operation/non-operation by measurement time zone is calculated as the baseline by operation/non-operation by measurement time zone. hand,
In the measurement time zone, by operating/non-operating, the difference between the electricity consumption data and the operating time/non-operating baseline by the measurement time zone is calculated as the electricity consumption such as air conditioning,
Of all the baselines by operation/non-operation by the above measurement time zones, calculate the minimum value as the base electricity usage,
Calculated as the amount of electricity used for lighting, etc., by calculating the difference between the baseline for each operation/non-operation by the measurement time zone and the amount of electricity used for the base,
It is provided with a program for calculating an electricity usage estimation model for each operation time/non-operation by the measurement time zone, an operation/non-operation flag, and an electricity usage for each base use such as air conditioning, lighting, etc. And
The second technical means is the computer according to the first technical means,
Using weather forecast values obtained from outside, the weather data, and the electricity usage data, the electricity usage forecast value, the occurrence probability distribution of the electricity usage forecast value, air conditioning, lighting, etc., It is a program that calculates the electricity usage forecast value by application of the base,
The operating/non-operating flag, the operating time/non-operating baselines for each measurement time zone, and the base electricity usage are calculated using the first technical means,
The measurement date and time when the electricity usage is smaller than the maximum value of the non-operation baseline according to the measurement time zone, which is a set of measurement dates and times that are non-operation among the measurement time zone-based operation/non-operation baselines, is Activate and correct the above operating/non-operating flag,
Input the day of the week, holidays, time zone, etc. of the measurement date and time, create an operation regression model with the corrected operating/non-operating flag output,
In the operation regression model, input the day of the week, holidays, time zone, etc. of the predicted date and time to calculate the operating/non-operating prediction flag,
Create a forecast model of electricity usage by operation time/non-operation by measurement time zone by performing regression analysis using the meteorological data as input and the electricity usage data as output by the corrected operation/non-operation. do it,
To the operation usage/non-operation-specific electricity usage prediction model for each measurement time zone, the weather forecast value is input, and an electricity usage prediction value and a probability distribution of the electricity usage prediction value are calculated,
A predicted value of electricity usage, a predicted value of operation/non-operation, a baseline for each operation/non-operation by the measurement time zone, and the amount of base electricity used And the like, and a program for calculating the electricity usage predicted value for each application such as lighting.
A third technical means is the computer according to the first or second technical means,
A program to calculate the energy saving amount by changing the set temperature of air conditioning,
Set the amount of change in the air conditioning set temperature in advance,
By using the meteorological data, the electricity usage data, and the operating time/non-operating time-based baselines,
As a temperature threshold value for switching between cooling and heating, the temperature when the operating/non-operating baselines for each of the measurement time zones occur,
When the temperature on the measurement date and time is higher than the temperature threshold, it is a value obtained by subtracting the amount of change in the air-conditioning set temperature from the temperature, and when the subtracted value is smaller than the temperature threshold, the value was corrected to the temperature threshold. The value is the temperature for energy saving calculation,
When the temperature at the measurement date and time is lower than the temperature threshold, the value is the value obtained by adding the amount of change in the air conditioning set temperature from the temperature, and when the added value is larger than the temperature threshold, the value is corrected to the temperature threshold. The calculated value is the energy-saving calculation temperature,
Electricity for energy-saving calculation calculated by inputting data obtained by replacing the temperature of the meteorological data with the temperature for energy-saving calculation in the electricity usage estimation model for operation/non-operation by measurement time zone derived by the first technical means. Estimated usage amount and
Using the estimated electricity usage value calculated by inputting the meteorological data to the electricity usage estimation model for each operation/non-operation by the measurement time period derived by the first technical means,
It is characterized by comprising a program for calculating a difference between the estimated value of electricity consumption and the estimated value of electricity consumption for energy-saving calculation as an energy-saving amount by changing a set temperature of air conditioning.
A fourth technical means is the computer according to any one of the first to third technical means,
A program to calculate a reasonable target value for power demand,
In advance, determine the probability of occurrence of outliers,
Using the total value of the electricity usage amount data in 30-minute intervals and the average value of the meteorological data in 30-minute intervals, the electricity usage amount according to the operating time/non-operation according to the measurement time zone. Calculate the estimation model,
As a current power demand value, a value obtained by doubling the maximum value of the total values of the electricity usage amount data in 30-minute intervals is
As a achievable demand value, a value obtained by doubling the maximum value of the estimated value of electricity consumption calculated from the electricity consumption estimation model by operating/non-operating according to the measurement time zone is
When creating the electricity usage estimation model by operating/non-operating by the measurement time zone, the probability distribution of the estimated value is calculated, and the estimated value in which the probability of occurrence of the abnormal value becomes the threshold value is calculated from the probability distribution. And double the value as the demand value that is easy to achieve,
When each demand value is larger than the current power demand value, a program for correcting and calculating the current power demand value is provided.
A fifth technical means is the computer according to any one of the first to fourth technical means,
A program that displays a breakdown of power demand,
Using the 30-minute interval total value of the electricity usage amount data and the 30-minute interval average value of the meteorological data as the method of the first technical means, electricity usage according to base use such as air conditioning, lighting, etc. Calculate the amount,
The power consumption value and the air-conditioning, lighting and other base applications are obtained by doubling the total value of the electricity usage data in 30-minute intervals and the electricity usage by base usage, such as the air-conditioning and lighting. As another power demand value,
Sorting the power demand values in descending order,
It is characterized by being provided with a program for displaying a breakdown by use of the power demand value using a stacked bar graph.
A sixth technical means is the computer according to any one of the first to fifth technical means,
A program to calculate additional electricity consumption due to overtime work such as overtime work,
Using the first technical means, the operating/non-operating flag, the operating time/operating non-operating electricity consumption estimation model for each measurement time zone, and the operating/non-operating baseline for each measurement time zone are calculated. hand,
The measurement date and time when the electricity usage is smaller than the maximum value of the non-operation baseline according to the measurement time zone, which is a set of measurement dates and times that are non-operation among the above-mentioned measurement time zone-based operation/non-operation baselines, is set to non-operation. To fix the working/non-working flag,
Input the day of the week, holidays, time zone, etc. of the measurement date and time, create an operation regression model with the corrected operating/non-operating flag output,
In the operation regression model, input the day of the week, the holidays, the time zone, etc. of the measurement date and time to calculate the regular operation/non-operation flag of the building,
If the corrected working/non-working flag is working at the measurement date/time when the regular working/non-working flag is not working, a flag is set as overtime work,
Using the non-working electricity usage estimation model by the measurement time zone, estimating the non-working electricity usage at the measurement date and time of the predetermined overtime work,
The difference between the electricity usage amount at the measurement date and time when the overtime work flag is set and the non-working electricity usage amount at the measurement date and time of the overtime work is defined as an additional electricity usage amount due to overtime work. It is characterized by having a program for calculation.
In addition, terms used in the present specification are defined as follows.
Operating/non-operating assumes that there are basically two situations in the building, assuming that the employee is working and working, the employee is absent, and the main equipment is stopped. When it is used for analysis, the status that it is present is treated as a flag.
Regarding the electricity usage by base use such as air conditioning and lighting, “air conditioning etc.” mainly refers to the air conditioning electricity usage. “Lighting etc.” mainly refers to the amount of electricity used for lighting and office automation equipment. “Base” refers to the electricity usage of equipment such as guide lights that is used for 24 hours.
The measurement time zone refers to a value obtained by extracting the time zone of the measurement date and time of the periodic cycle of the electricity usage data of the building.

According to the energy-saving diagnosis program of the present invention, from the electricity usage data of the building and the address data of the building, the estimation of the electricity usage by the usage of the building, the prediction of the electricity usage, the prediction of the electricity usage by usage, the energy-saving analysis, etc. By doing so, it is possible to extract buildings that are easy to save energy from among buildings such as offices and factories.
The energy-saving diagnosis program of the present invention does not require any special technical knowledge regarding energy-saving diagnosis, etc., and achieves energy-saving diagnosis by using easily obtainable data such as building electricity usage data and building address data. There is an advantage that you can.
Further, according to the energy-saving diagnosis program of the present invention, by performing the energy-saving diagnosis for the buildings of customers such as electric power companies, etc., a building with a high energy-saving effect can be efficiently extracted from a large number of buildings. It is possible.
The energy-saving diagnostic program of the present invention is based on past electricity usage, electricity usage by base such as lighting such as air conditioning in the past, predicted electricity usage, electricity usage by base usage such as air conditioning, lighting, etc. It is possible to display a graph of the predicted value of usage and the probability distribution of the predicted value of usage of electricity, and it is easy to understand the occurrence of abnormalities in the past usage of electricity and the transition of future usage of electricity, which is useful for energy conservation measures. There is an advantage that you can.
The energy-saving diagnostic program of the present invention can display a breakdown of the power demand value for each base application such as air conditioning, lighting, etc., and when a reasonable target value of the power demand value or the maximum power demand value occurs. There is an advantage that you can check the breakdown of the amount of electricity used for each application and use it for energy conservation measures.

FIG. 1 is a block diagram showing an example of the configuration of the analysis unit of the processing device according to the present embodiment.
FIG. 2 is a block diagram showing an example of the configuration of the energy saving diagnosis system according to this embodiment.
FIG. 3 is a block diagram showing an example of the configuration of the processing apparatus according to this embodiment.
FIG. 4 is a diagram showing an example of an analysis method for combining the electricity usage data and the meteorological data, creating a measurement time zone flag, and creating analysis data.
FIG. 5 is a diagram illustrating an example of a method for determining whether a building is operating/not operating for the determination module.
FIG. 6 is a flowchart showing an example of the operation of the model type estimation module.
FIG. 7 is a diagram illustrating an example of a calculation method of the usage-specific electricity usage calculation module.
FIG. 8 is a diagram illustrating an example of a calculation method of the usage-specific electricity usage calculation module.
FIG. 9 is a diagram showing an example of a graph display of a past electricity usage amount, a past electricity usage amount according to usage, an electricity usage predicted value, a usage-wise electricity usage predicted value, and a probability distribution of an electricity usage predicted value. ..
FIG. 10: is a figure which shows an example of a display of the demand curve graph of the electric power consumption classified by purpose.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings.
The measurement period of the data used in this embodiment can be analyzed as long as the data is 6 months or more.
FIG. 2 is a block diagram illustrating an example of the configuration of the energy saving diagnosis system 10 according to the present embodiment.
The energy saving diagnosis system 10 according to this embodiment includes a client-side machine 3000, an external weather information database 4000, an external location information database 5000, an external communication network 6000, and a server 1000 as an analysis system.
The electricity consumption data 3002 and the building address data 3001, which will be described later, are sent from the client-side machine 3000 through the external communication network 6000 to the server 1000 as an analysis system, and the results analyzed by the analysis system are sent to the client-side machine 3000. .. The weather observation facility position information 4001, the weather observation data 4002, and the weather forecast data 4003, which will be described later, are sent from the external weather information database 4000 to the server 1000 as an analysis system via the external communication network 6000. The building address data 3001 is sent to the external position information database 5000 through the external communication network 6000 from the server 1000 in which the analysis system is installed, and the latitude, longitude, and altitude data required for analysis are obtained.
The building address data 3001 is information indicating a building address or postal code information.
The electricity usage amount data 3002 is electricity usage amount data measured at regular intervals (for example, every 30 minutes) from a smart meter or the like.
The weather observation facility position information data 4001 is latitude, longitude, and altitude data of the weather observation facility.
The meteorological observation data 4002 is data observed at meteorological stations such as temperature, humidity, sunshine duration, wind speed, wind direction, and precipitation.
The weather forecast data 4003 is data predicted by a weather station such as temperature, humidity, sunshine duration, wind speed, wind direction, and precipitation amount.
The position information database 5000 is latitude, longitude, altitude data and the like.
The communication network 6000 is an internet network, an intranet network, or the like.
The server 1000 includes, for example, the communication device 1 and the processing device 2. The communication device 1 is an arbitrary device that is communicably connected to the external communication network 6000.
The processing device 2 executes various control processes in the server 1000. The processing device 2 includes one or a plurality of servers including a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), an I/O interface (Input-Output Interface), and the like. The functions of each unit are realized by causing a computer to execute a predetermined program.
FIG. 3 is a block diagram showing an example of the configuration of the processing device 2 according to the present embodiment.
The processing device 2 includes, for example, a communication processing unit 21, an input unit 22, a storage unit 23, an analysis unit 24, and an output unit 25.
The communication processing unit 21 controls the communication device 1 and acquires the weather observation facility position information 4001, the weather observation data 4002, the weather forecast data 4003, the building address data 3001, and the electricity usage data 3002 via the external communication network 6000. To do.
The input unit 22 acquires the weather observation facility position information 4001, the weather observation data 4002, the weather forecast data 4003, the building address data 3001, and the electricity usage data 3002 from the communication processing unit 21, and the weather observation facility in the storage unit 23. The database 231, the weather database 232, the building address database 233, and the electricity usage database 234 are stored in the corresponding databases.
The analysis unit 24 acquires necessary data from the input unit 22 and the storage unit 23. Further, the analysis unit 24 connects to the external position information database 5000 through the communication processing unit 21 by Web API (Web Application Programming Interface) or the like, transmits the building address data 3001, and transmits the building position information such as latitude, longitude, and altitude. To get The configuration of the analysis unit 24 will be described in detail later. The result analyzed by the analysis unit 24 is stored in the analysis result database 235 in the storage unit 23.
The output unit 25 acquires necessary data from the analysis unit 24 and outputs the analysis result to the client-side machine 3000 through the communication processing unit 21.
It is assumed that the building address data 3001 and the electricity usage data 3002 do not need to be input from the outside and are already stored in the database.
The input unit 22, the analysis unit 24, and the output unit 25 may be physically separate servers or the same server.
The output of the analysis result may be displayed on the client-side machine 3000 through the output unit 25, or may be used for analysis on the analysis result database 235.
FIG. 1 is a block diagram showing an example of the configuration of the analysis unit 24 of the processing device 2 according to this embodiment.
The analysis unit 24 includes, for example, a weather data acquisition package 241, a data preprocessing package 242, a usage-specific electricity usage estimation package 243, an electricity usage prediction package 244, and an energy saving analysis package 245.
A package is a set of program codes roughly classified by function, and a module is a set of program code roughly classified by analysis content.
The weather data acquisition package 241 includes, for example, a position information acquisition module 2411 and a weather data extraction module 2412.
The position information acquisition module 2411 transmits the building address data 3001 of the building to be analyzed from the building address database 233 of the storage unit 23 to the external position information database 5000 through the communication processing unit 21 to the external position information database 5000 through the Web API or the like, and the latitude of the building, Get location information such as longitude and altitude. Using the acquired position information of the building, the weather observation facility database 231 of the storage unit 23 is used to extract, for example, a weather observation facility within the latitude ±1 degree and the longitude ±1 degree of the building position information. The distance between two points of the building and the extracted weather observation facility is calculated, and the weather observation facility closest to the building is selected.
The meteorological data extraction module 2412 executes the analysis of the meteorological data of the meteorological observation facility located closest to the building for which the analysis is to be performed, from the meteorological database 232 of the storage 23, in the electricity usage database 234 of the storage 23. The amount of electricity used and the amount for the same period are extracted. Also, the weather forecast data is extracted.
The data preprocessing package 242 acquires electricity usage data, weather data, and weather forecast data.
The data preprocessing package 242 matches the electricity usage data, the weather data, and the weather forecast data with the same measurement interval. Basically, upsampling or downsampling is performed on the meteorological data and the meteorological forecast data in accordance with the measurement interval of the electricity usage data. Upsampling uses linear interpolation, spline interpolation, or the like. The interpolated data are analyzed using an abnormal value detection method, and if an abnormal value is found, it is deleted and treated as a defect. If the data is missing for a short period of time, the data is interpolated by linear interpolation or the like. If there is a long-term loss, leave it as it is.
As shown in FIG. 4, the data preprocessing package 242 combines the electricity usage amount data 242c and the meteorological data 242d with the measurement date/time 242a as a key, and creates the measurement time zone flag 242b from the measurement date/time 242a. Create analytical data. The measurement time zone flag 242b is calculated as, for example, a value of time of measurement date and time×100+minute of measurement date and time.
The electricity usage estimation package 243 by application is
It is a package that estimates the amount of electricity used by application from the analysis data. The usage-based electricity usage estimation package 243 includes, for example, a determination module 2431, a model-based estimation module 2433, and a usage-based electricity usage calculation module 2435.
The determination module 2431 is a module that determines whether the building is in operation or not at the measurement date and time.
Regarding analysis data, operation/non-operation is determined from a set of pairs of electricity usage data and meteorological data. As a discriminating method, a method using a K-means algorithm, a method using a conditional mixed model, or the like can be considered. Here, a method using a support vector machine will be described.
The method using the support vector machine requires training data of working/non-working. The operating data/non-operating training data is obtained by dividing the range of the minimum value to the maximum value of the temperature of the analysis data into, for example, 8 divisions and 10 divisions, and counting several points from the maximum in the electricity usage data within the range. Training data is operating, and several points counting from the minimum are extracted as non-operating training data. A discriminant model is created from the training data by a support vector machine, and the remaining analysis data is discriminated as working/non-operating using the discriminant model.
FIG. 5 shows an example of a method of determining whether a building is operating or not for the determination module 2431.
In FIG. 5, the horizontal axis indicates temperature, and the vertical axis indicates electricity usage. The analysis data of a pair of electricity usage data and meteorological data is a white circle (2431a), operating training data is a black circle (2431b), non-operating training. The data is indicated by a cross mark (2431c), and the dividing line when the range of the minimum value to the maximum value of the air temperature is divided into eight is indicated by the dotted line (2431d).
The model-type estimation module 2433 uses the measurement time zone data obtained by extracting the analysis data for each measurement time zone to create an electricity consumption estimation model for each operation time/non-operation for estimating the electricity usage amount. Yes, it will be described with reference to the flowchart of FIG.
The estimation of the electricity usage is started from the data for each measurement time zone (S201).
The processing from S202 to S209 is repeated for each measurement time period.
By using the determination module 2431, the measurement time zone-based data is discriminated between operating and non-operating (S203 to S204).
The training data when the support vector machine is used for the determination module 2431 is a method in which the temperature is divided into a plurality of parts, and the upper few points of the electricity usage data are activated and the lower few points are not activated, and the model type estimation module 2433. Before carrying out, the period operation/non-operation flag extracted in the measurement time zone is used as training data among the operation/non-operation flags created by the determination module 2341 using the meteorological data and the electricity usage data. The method used may be considered.
Data for each measurement time zone is extracted by operating/non-operating, polynomial regression analysis including regularization term or kernel regression analysis using meteorological data as input and electricity usage data as output, and measurement time zone by An electricity usage estimation model for each operation/non-operation is created (S205 to S208).
The probability distribution of the predicted value of the electricity usage for the working/non-operating flag and the meteorological data is created by using the electricity usage estimation model according to the working hours/non-working for each measurement time zone. The probability distribution indicates the probability of occurrence of output for a certain input.
The model type estimation module 2433 is executed for each measurement time zone, and the obtained results are combined (2432 to 2434).
The usage-based electricity usage calculation module 2435 will be described with reference to FIGS. 7 and 8.
The usage-based electricity usage calculation module 2435 receives the usage-based electricity usage estimation model by measurement time zone and the operation/non-operation flag, and uses electricity such as air conditioning by operation/non-operation by measurement time zone. Quantity, electricity usage such as lighting, and base electricity usage.
Within the range of the meteorological data of the measurement time zone data from the operation/non-operation electricity consumption estimation model by measurement time zone, the operation/ The minimum value of estimated electricity usage by non-operation is set as the operation/non-operation baseline for each measurement time period. The temperature obtained by deriving the minimum value is set as an air temperature threshold, and a range of air temperature higher than the air temperature threshold is set as a cooling range, and a temperature below the air temperature threshold is set as a heating range.
FIG. 7: is a figure which shows an example of the discrimination|determination method of the cooling range and heating range of the amount of electricity usage.
In FIG. 7, the horizontal axis represents temperature and the vertical axis represents electricity consumption. Electricity consumption data during operation is indicated by a white circle (2438a), electricity consumption data during non-operation is indicated by a cross (2438b), electricity consumption during operation. The boundary line between the cooling range and the heating range of the usage amount data is a dotted line 2438e, the boundary line between the cooling range and the heating range of the non-operating electricity usage data is a dotted line 2438f, and the minimum value of the estimated electricity usage amount during operation is the minimum value. The baseline is indicated by a dotted line 2438c, and the baseline that is the minimum value of the estimated value of the electricity usage amount during non-operation is indicated by a dotted line 2438d.
There may be separate cooling and heating ranges for operating and non-operating. If air temperature data and electricity usage data are shown to have a significant positive correlation using operating/non-operation data for each measurement range of the cooling range, cooling is considered The difference between the data and the operating/non-operating baselines for each measurement time zone is the electricity usage for air conditioning. If it is not significant, the electricity usage such as air conditioning is set to 0, and the baseline of the relevant measurement date and time is further corrected to the electricity usage on the relevant measurement date and time. Similarly, if it is shown that there is a significant negative correlation between the temperature data and the electricity usage data by using the operating time/non-operation data for each heating range, , And the difference between the operating time/non-operating time base line by the measurement time zone is the electricity usage such as air conditioning. If it is not significant, the electricity usage such as air conditioning is set to 0, and the baseline of the relevant measurement date and time is further corrected to the electricity usage on the relevant measurement date and time.
Of all the baselines by operation/non-operation by measurement time zone before correction, the minimum baseline value is the base electricity usage.
For each measurement date and time, compare the electricity usage data with the baseline, and if the baseline is larger than the electricity usage data, correct the corresponding baseline to electricity usage data and use the electricity usage such as air conditioning. Is corrected to 0.
The difference between the baseline and the base electricity usage is the electricity usage such as lighting.
In the embodiment of FIG. 8, the measurement time zone flag, the temperature, the electricity usage, the operation/non-operation, the use/non-use of the air conditioner, the baseline, the air conditioner, the lighting, etc. This is an example of a summary of the amount of electricity used by application. For example, the baseline (non-operation: 1000) indicates the non-operation baseline in the measurement time zone 1000, and the baseline (non-operation: 30)' is the non-operation baseline in the measurement time zone 30 corrected. The value indicates that the electricity usage [110] indicates that the electricity usage is 110 kWh.
The electricity usage amount for each base use such as operating/non-operating flag, air conditioning, lighting, etc. is recorded in the analysis result database 235 of the storage unit 23.
The electricity usage forecasting package 244 uses the electricity usage data and the meteorological data to create an electricity usage forecasting model by operation/non-operation, and a weather forecast value in the electricity usage forecasting model by operation/non-operation. Is input to calculate the electricity usage predicted value, and the electricity usage predicted value is used to predict the electricity usage according to the base use such as air conditioning and lighting. The probability distribution of the predicted value of electricity usage is created and the probability of occurrence of the predicted value of electricity usage is calculated.
The operation/non-operation flag is corrected using the calculation result of the usage-based electricity usage estimation package 243. It is a set of measurement dates and times that are non-operational among the baselines by operation time/non-operation by measurement time period. , Modify the working/non-working flag.
The operation regression model is created by inputting the day of the week, holidays, time zone, etc. of the measurement date and time and outputting the corrected operating/non-operating flag. It is conceivable to use logistic regression analysis, support vector machine analysis, or the like to create the regression model.
In order to predict the operation/non-operation in the period for which the prediction is performed, the day of the week, the holidays, the time zone, etc. of the predicted date and time are input to the operation regression model, and the operation/non-operation prediction flag is calculated.
Performs a polynomial regression analysis or a kernel regression analysis that includes a regularization term with input of past weather data and output of electricity usage data for each measurement time zone and corrected operation/non-operation, and operation for each measurement time zone / Create a forecast model of electricity usage by non-operation.
The weather forecast value is input to the electricity usage prediction model for each operation time/non-operation by the measurement time zone, and the electricity usage prediction value and the probability distribution of the electricity usage prediction value are calculated.
The electricity usage prediction model by operation/non-operation by measurement time zone and the operation regression model are saved and used for real-time electricity usage estimation. The electricity usage prediction model and the operation regression model are updated regularly, such as every month.
Processing equivalent to that of the usage-specific electricity usage calculation module 2435 using the predicted value of usage of electricity, the baseline by operation measurement time zone calculated by the usage-specific electricity usage calculation module 2435, and the base usage of electricity Then, the predicted value of electricity usage such as air conditioning, the predicted value of electricity usage such as lighting, and the predicted value of base electricity usage are calculated.
FIG. 9 shows past electricity usage data, past electricity usage by base application such as air conditioning, lighting, etc., electricity usage prediction value, and electricity usage prediction by base application such as air conditioning, lighting, etc. It is an example of the figure which carried out the graph display of the value and the probability distribution of the electricity usage prediction value collectively.
In FIG. 9, the horizontal axis indicates the date and time, the vertical axis indicates the electricity usage amount, the past electricity usage amount data 244i and the electricity usage predicted value 244j are shown in a line graph, and the past base electricity usage amount 244c and lighting etc. Electricity consumption according to application of electricity consumption 244d and electricity consumption 244e for air-conditioning, etc. is shown in a stacked bar graph, and a predicted value 244f of base electricity consumption 244f, a predicted value 244g of electricity consumption such as lighting, and electricity consumption HVAC The predicted value of the usage amount 244h and the predicted value of the usage amount of electricity for each application are shown in a stacked bar graph. The probability that an abnormal value will occur is set in advance, and from the probability distribution of the electricity usage predicted value, the threshold value is the lower limit value that is 1/2 of the probability that the abnormal value will occur, as the prediction lower limit value 244a. An upper limit value at which the threshold value is ½ of the probability of occurrence of the abnormal value is shown as a predicted upper limit value 244b in an area graph. For example, when the probability that an abnormal value occurs is set to 5%, the range of the prediction lower limit value 244a and the prediction upper limit value 244b is the range of the prediction value that occurs with a probability distribution of 95%. By this graph display method, it is possible to confirm whether or not an abnormality in the amount of electricity used has occurred, how the amount of electricity used will change in the future, etc., in a single graph, which is useful for energy saving measures.
The electricity usage prediction value, the electricity usage prediction value for each application such as air conditioning, lighting, and the like, and the probability distribution of the electricity usage prediction value are recorded in the analysis result database 235 of the storage unit 23.
The energy-saving analysis package 245 uses the calculation result of the usage-based electricity usage estimation package 243 to perform analysis leading to energy saving.
The energy saving analysis package 245 includes, for example, an air conditioning set temperature module 2451, a demand analysis module 2452, and an after-hours analysis module 2453.
The air conditioning set temperature module 2451 calculates the energy saving amount when the air conditioning set temperature is changed. The amount of change in the air-conditioning set temperature is set in advance, and the energy-saving calculation temperature is calculated. The temperature for energy saving calculation is calculated for each measurement date and time.
The boundary line 2438e between the cooling range and the heating range of the electricity usage data during operation shown in FIG. 7 is set to the operating temperature threshold in the target measurement time zone, and the cooling range and the heating range of the electricity usage data during non-operation. The boundary line 2438f is set as the temperature threshold value during non-operation in the target measurement time zone. The temperature for energy-saving calculation of the target measurement date and time is calculated using the temperature threshold value at which the operating time/non-operating time and the measurement time zone at the measurement date and time coincide. When the air temperature is higher than the air temperature threshold value, the value is obtained by subtracting the change amount of the air conditioning set temperature from the air temperature. However, if the subtracted value is smaller than the temperature threshold, the energy-saving calculation temperature is set to the same value as the temperature threshold. When the air temperature is equal to or lower than the air temperature threshold value, it is a value obtained by adding the amount of change in the air conditioning set temperature from the air temperature. However, when the added value is larger than the temperature threshold, the energy-saving calculation temperature is set to the same value as the temperature threshold.
The electricity usage amount for energy saving calculation is estimated by inputting the meteorological data in which the temperature data is replaced with the temperature for energy saving calculation to the usage-specific electricity usage calculation module 2435. At each measurement date and time, the difference between the estimated electricity usage amount calculated from the past data and the electricity usage amount for energy saving calculation is calculated to obtain the energy saving amount due to the setting change. However, if the difference between the estimated electricity usage amount and the electricity usage amount for energy saving calculation becomes negative, the energy saving amount due to the setting change of the corresponding measurement date and time is set to 0.
The demand analysis module 2452 calculates a target value of a rational power demand value to facilitate rational power demand monitoring.
The probability of occurrence of an abnormal value is set in advance.
The 30-minute interval total value of the electricity usage amount data and the 30-minute interval average value of the meteorological data are input to the usage-based electricity usage amount estimation package 243.
A value obtained by doubling the maximum value of the total value of the electricity usage amount data at 30-minute intervals is set as the current power demand value.
A value that doubles the maximum value of the estimated electricity usage calculated from the electricity usage estimation model by operating/non-operating by measurement time zone derived by the usage-specific electricity usage estimation package 243 is defined as the achievable demand value. To do.
Calculate the probability distribution of estimated values when creating an electricity consumption estimation model by operating hours/non-operating hours by measurement time zone. An estimated value in which the probability of occurrence of the abnormal value becomes a threshold value is calculated from the probability distribution, and a value obtained by doubling the estimated value is set as the easily attainable demand value.
A value that is input to the air-conditioning set temperature module 2451 and doubles the maximum value of the obtained estimated value of the electricity consumption for energy saving calculation is set as the demand value by changing the set temperature.
If the achievable power demand value, the easily attainable power demand value, and the demand value due to the change in the set temperature are larger than the current power demand value, the current power demand value is corrected.
In FIG. 10, the horizontal axis represents time and the vertical axis represents the power demand value, and the amount of electricity used is combined with the amount of electricity used, such as base electricity use amount 24k, lighting electricity use amount 24l, and air conditioning electricity use amount 24m. It is an example of the figure which rearranged in order of the amount of electricity used, and was displayed as a stacked bar graph.
The power demand value 24n indicates a current power demand value, an easily attainable power demand value, an achievable power demand value, and a power demand value due to a change in set temperature, respectively. By this graph display method, it is possible to easily display the breakdown of the electricity usage amount by application when a rational target value of the power demand value or the maximum power demand value is generated.
The overtime analysis module 2453 calculates an additional amount of electricity used by overtime work such as overtime work, and promotes energy saving by reducing overtime work.
Use the usage-specific electricity usage estimation package 243 to calculate the operating/non-operating flag, the operating usage/non-operating electricity usage estimation model by measurement time zone, and the operating/non-operation baseline by measurement time zone. ..
The operation/non-operation flag is corrected using the calculation result of the usage-based electricity usage estimation package 243. It is a set of measurement dates and times that are non-operational among the baselines by operation time/non-operation by measurement time period. , Modify the working/non-working flag.
The operation regression model is created by inputting the day of the week, holidays, time zone, etc. of the measurement date and time and outputting the corrected operating/non-operating flag. It is conceivable to use logistic regression analysis, support vector machine analysis, or the like to create the regression model.
Input the day of the week, holidays, time zone, etc. of the measurement date and time to the operation regression model, and calculate the regular operation/non-operation of the building.
If the corrected working/non-working flag is working at the regular non-working measurement date and time, a flag is set as overtime work.
Using the estimation model of non-operational electricity consumption by measurement time zone, estimate the non-operational electricity consumption at the measurement date of overtime work.
The difference between the electricity usage amount at the measurement date and time when the overtime work flag is set and the non-working electricity usage amount at the measurement date and time of the overtime work is calculated as an additional electricity usage amount due to overtime work.
The result calculated by the energy saving analysis package 245 is recorded in the analysis result database 235 of the storage unit 23.
As described above, according to the present embodiment, even if there is no special expertise, it is possible to use a large number of buildings such as offices and factories only with the easily available information such as the electricity usage of the building and the building address information. Energy saving diagnosis is possible for
The electricity usage and address information of the building, which is required in this embodiment, is information that the power company or the like can easily obtain for the customers, and detailed energy-saving diagnosis can be sent periodically or in real time. It can also be used as a service for checking the diagnostic results via the network.
In addition, by conducting energy-saving diagnosis for buildings of many customers such as offices and factories, it is possible to extract buildings with high energy-saving effect and promote highly efficient energy-saving measures.
Here, an example of a preferable mode is shown, and the present invention can be implemented in other than the described contents. In addition, although the representative examples of the formulas and methods introduced here are shown, the formulas are not limited to these, and other formulas can be substituted.

2 Processing Equipment 21 Communication Processing Section 23 Storage Section 24 Analysis Section 231 Meteorological Observation Facility Database 232 Meteorological Database 233 Building Address Database 234 Electricity Usage Database 235 Analysis Result Database 241 Meteorological Data Acquisition Package 242 Data Preprocessing Package 243 Electricity Usage by Application Estimation package 244 Electricity consumption forecasting package 245 Energy saving analysis package 2431 Discrimination module 2433 Model type estimation module 2435 Electric consumption calculation module by application 2451 Air conditioning temperature setting module 2452 Demand analysis module 2453 Overtime analysis module 3000 Client side machine 3001 Building address Data 3002 Electricity usage data 4000 Meteorological information database 4001 Meteorological observation facility location information 4002 Meteorological observation data 4003 Meteorological forecast data 5000 Location information database

Claims (6)

On the computer,
Using the electricity usage data of the building and the meteorological data around the building, which are measured in a regular cycle from the outside, operating/non-operating the building at the measurement date and time, air-conditioning, lighting, etc. A program to calculate another electricity usage and
It consists of a discrimination module, a model-type estimation module, and a usage-specific electricity usage calculation module.
The discrimination module, for each measurement time zone, using the electricity consumption data and the measurement time zone data obtained by extracting the weather data, creates a discrimination model for discriminating between operation and non-operation at the measurement date and time, In the measurement time zone, the operation at the target measurement date and time and the non-operation are carried out,
The model type estimation module uses the operation/non-operation determined by the determination module and the measurement time zone-specific data to determine the measurement time zone-specific data for each measurement time zone-specific operation/non-operation. Perform regression analysis using the meteorological data as input and the electricity usage data as output, and create an electricity usage estimation model by operating time/non-operation by measurement time zone,
The use-specific electricity usage calculation module is an upper limit value of the outside temperature of the meteorological data of the measurement time zone data, or the outside air temperature and humidity, from the operation time/operating non-operation electricity consumption estimation model according to the measurement time zone. From the lower limit value, the minimum value of the estimated value of electricity usage calculated from the electricity usage estimation model by operation/non-operation by measurement time zone is calculated as the baseline by operation/non-operation by measurement time zone. hand,
In the measurement time zone, by operating/non-operating, the difference between the electricity consumption data and the operating time/non-operating baseline by the measurement time zone is calculated as the electricity consumption such as air conditioning,
Of all the baselines by operation/non-operation by the above measurement time zones, calculate the minimum value as the base electricity usage,
Calculated as the amount of electricity used for lighting, etc., by calculating the difference between the baseline for each operation/non-operation by the measurement time zone and the amount of electricity used for the base,
A program for calculating an electricity usage estimation model by operation/non-operation by the measurement time zone, an operation/non-operation flag, and an electricity usage by base application such as air conditioning and lighting. On the computer,
Using weather forecast values obtained from outside, the weather data, and the electricity usage data, the electricity usage forecast value, the occurrence probability distribution of the electricity usage forecast value, air conditioning, lighting, etc., It is a program that calculates the electricity usage forecast value by application of the base,
The operating/non-operating flag, the operating time/non-operating base line for each measurement time zone, and the base electricity usage amount are calculated using claim 1,
The measurement date and time when the electricity usage is smaller than the maximum value of the non-operation baseline according to the measurement time zone, which is a set of measurement dates and times that are non-operation among the measurement time zone-based operation/non-operation baselines, is Activate and correct the above operating/non-operating flag,
Input the day of the week, holidays, time zone, etc. of the measurement date and time, create an operation regression model with the corrected operating/non-operating flag output,
In the operation regression model, input the day of the week, holidays, time zone, etc. of the predicted date and time to calculate the operating/non-operating prediction flag,
Create a forecast model of electricity usage by operation time/non-operation by measurement time zone by performing regression analysis using the meteorological data as input and the electricity usage data as output by the corrected operation/non-operation. do it,
To the operation usage/non-operation-specific electricity usage prediction model for each measurement time zone, the weather forecast value is input, and an electricity usage prediction value and a probability distribution of the electricity usage prediction value are calculated,
A predicted value of electricity usage, a predicted value of operation/non-operation, a baseline for each operation/non-operation by the measurement time zone, and the amount of base electricity used The program according to claim 1, which is configured to calculate an electricity usage prediction value for each application, such as lighting, and the like. On the computer,
A program to calculate the energy saving amount by changing the set temperature of air conditioning,
Set the amount of change in the air conditioning set temperature in advance,
By using the meteorological data, the electricity usage data, and the operating time/non-operating time-based baselines,
As a temperature threshold value for switching between cooling and heating, the temperature when the operating/non-operating baselines for each of the measurement time zones occur,
When the temperature on the measurement date and time is higher than the temperature threshold, it is a value obtained by subtracting the amount of change in the air-conditioning set temperature from the temperature, and when the subtracted value is smaller than the temperature threshold, the value was corrected to the temperature threshold. The value is the temperature for energy saving calculation,
When the temperature at the measurement date and time is lower than the temperature threshold, the value is the value obtained by adding the amount of change in the air conditioning set temperature from the temperature, and when the added value is larger than the temperature threshold, the value is corrected to the temperature threshold. The calculated value is the energy-saving calculation temperature,
Electricity consumption for energy-saving calculation calculated by inputting data obtained by replacing the temperature of the meteorological data with the temperature for energy-saving calculation in the electricity consumption estimation model by operation/non-operation according to the measurement time period derived in claim 1. Estimated value,
Using the estimated electricity consumption value calculated by inputting the meteorological data to the electricity consumption estimation model by operating/non-operating according to the measurement time period, which is derived in claim 1,
The program according to claim 1 or 2, wherein the difference between the estimated value of electricity consumption and the estimated value of electricity consumption for energy saving calculation is calculated as the amount of energy saved due to a change in the set temperature of air conditioning. On the computer,
A program to calculate a reasonable target value for power demand,
In advance, determine the probability of occurrence of outliers,
A 30-minute interval total value of the electricity usage data and a 30-minute average value of the meteorological data are used for the method of claim 1, and the electricity usage estimation model by operating time/non-operation by measurement time zone is used. And calculate
As a current power demand value, a value obtained by doubling the maximum value of the total values of the electricity usage amount data in 30-minute intervals is
As a achievable demand value, a value obtained by doubling the maximum value of the estimated value of electricity consumption calculated from the electricity consumption estimation model by operating/non-operating according to the measurement time zone is
When creating the electricity usage estimation model by operating/non-operating by the measurement time zone, the probability distribution of the estimated value is calculated, and the estimated value in which the probability of occurrence of the abnormal value becomes the threshold value is calculated from the probability distribution. And double the value as the demand value that is easy to achieve,
The program according to any one of claims 1 to 3, wherein when each demand value is larger than the current power demand value, the current power demand value is corrected and calculated. On the computer,
A program that displays a breakdown of power demand,
Using the total value of the electricity usage amount data at 30-minute intervals and the average value of the meteorological data at 30-minute intervals, the electricity usage amount according to the base use such as air conditioning, lighting, etc. is used. Calculate,
The power consumption value and the air-conditioning, lighting and other base applications are obtained by doubling the total value of the electricity usage data in 30-minute intervals and the electricity usage by base usage, such as the air-conditioning and lighting. As another power demand value,
Sorting the power demand values in descending order,
The program according to any one of claims 1 to 4, wherein a breakdown by use of the power demand value is displayed using a stacked bar graph. On the computer,
A program to calculate additional electricity consumption due to overtime work such as overtime work,
The operating/non-operating flag, the operating time/non-operating electric power consumption estimation model for each measuring time zone, and the operating/non-operating separate baseline for each measuring time zone are calculated using claim 1,
The measurement date and time when the electricity usage is smaller than the maximum value of the non-operation baseline according to the measurement time zone, which is a set of measurement dates and times that are non-operation among the above-mentioned measurement time zone-based operation/non-operation baselines, is set to non-operation. To fix the working/non-working flag,
Input the day of the week, holidays, time zone, etc. of the measurement date and time, create an operation regression model with the corrected operating/non-operating flag output,
In the operation regression model, input the day of the week, the holidays, the time zone, etc. of the measurement date and time to calculate the regular operation/non-operation flag of the building,
If the corrected working/non-working flag is working at the measurement date/time when the regular working/non-working flag is not working, a flag is set as overtime work,
Using the non-working electricity usage estimation model by the measurement time zone, estimating the non-working electricity usage at the measurement date and time of the predetermined overtime work,
The difference between the electricity usage amount at the measurement date and time when the overtime work flag is set and the non-working electricity usage amount at the measurement date and time of the overtime work is defined as an additional electricity usage amount due to overtime work. The program according to claim 1, which is calculated.

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