JP6880864B2 - Energy management system and energy management method - Google Patents

Description

The present invention relates to an energy management system and an energy management method.

As a system for managing or evaluating the energy of a facility, a system for evaluating the energy saving potential of the process block to be evaluated is known (see, for example, Patent Document 1).
Patent Document 1 Japanese Unexamined Patent Publication No. 2016-91068

With the conventional technology, it is possible to identify a process block having a high energy saving potential. However, it is not possible to evaluate the relationships between parameters related to energy consumption in the facility.

In the first aspect of the present invention, it is an energy management system that manages energy information in a facility, based on a data acquisition unit that acquires series data of a plurality of related parameters related to energy consumption in the facility, and a series data. To provide an energy management system including a correlation calculation unit for calculating the correlation strength between two related parameters.

The second aspect of the present invention is an energy management method for managing energy information in a facility, which is based on a data acquisition stage for acquiring series data of a plurality of related parameters related to energy consumption in the facility, and a series data. To provide an energy management method comprising a correlation calculation step of calculating the correlation strength between two related parameters.

The above outline of the invention does not list all the features of the present invention. A subcombination of these feature groups can also be an invention.

It is a figure explaining the outline of the energy management system 100 which concerns on one Embodiment of this invention. This is an example of the configuration of the energy management system 100. It is a figure explaining the correlation strength between related parameters. It is a figure which shows an example of the correlation strength calculated based on the data which conforms to a predetermined environmental condition X. It is a figure which shows an example of the series data of related parameters D and E. It is a figure which shows an example of the presentation information generated by the parameter processing unit 14 and presented by the presentation unit 16. It is a figure which shows another example of the operation of the correlation calculation unit 12. It is a figure which shows the other configuration example of the energy management system 100. It is a figure which shows another example of the presentation information which a presentation part 16 presents. It is a flowchart which shows the operation example of the energy management system 100 shown in FIG. It is a flowchart which shows the other operation example of the energy management system 100. It is a flowchart which shows the other operation example of the energy management system 100. It is a flowchart which shows the other operation example of the energy management system 100. It is a flowchart which shows the other operation example of the energy management system 100. It is a flowchart which shows the other operation example of the energy management system 100. It is a figure which shows the other configuration example of the energy management system 100. Book It is a figure which shows another example of the usage mode of the energy management system 100. It is a figure which shows the configuration example of the energy management system 100. An example of a computer 2200 in which multiple aspects of the present invention may be embodied in whole or in part is shown.

Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the inventions that fall within the scope of the claims. Also, not all combinations of features described in the embodiments are essential to the means of solving the invention.

FIG. 1 is a diagram illustrating an outline of an energy management system 100 according to an embodiment of the present invention. The energy management system 100 manages energy information in the facility 200. The energy information is information related to energy consumption in the facility 200. The information related to energy consumption is information that affects the energy consumption in the facility 200 when the information fluctuates, or fluctuates with the fluctuation of the energy consumption in the facility 200. For example, the information includes energy efficiency in the facility 200, an operating status of each facility 220 that consumes energy, an operation control value, and the like.

In the present specification, energy such as electric power or raw materials given to the facility 200 is referred to as an input to the facility 200. The value obtained by converting the amount of energy or raw materials given to the facility 200 using a predetermined conversion formula is referred to as an input amount to the facility 200. In addition, products such as products produced by the facility 200, reusable energy and raw materials discharged from the facility 200, wastes, and the like are referred to as outputs of the facility 200. The value obtained by converting the amount of each output of the facility 200 using a predetermined conversion formula is referred to as the output amount of the facility 200. Further, the ratio of the output amount to the input amount is referred to as an energy efficiency value of the facility 200. For example, in a facility 200 that produces steam, the fuel and water supplied to the facility 200 are the inputs of the facility 200, and the steam and exhaust gas generated by the facility 200 are the outputs of the facility 200.

Facility 200 includes one or more equipment 220 and one or more control units 210. Energy, materials, etc. are input to each facility 220, and intermediate products, energy, etc. are output. Intermediate products, energy, etc. output by other equipment 220 may be input to each equipment 220.

Each control unit 210 controls the corresponding equipment 220. The control unit 210 is a terminal such as a computer. The control unit 210 may be provided for each equipment 220. The control unit 210 controls each parameter that defines the operation of the equipment 220 based on the instruction of the energy management system 100 or the operator or the like. For example, the control unit 210 controls each controllable parameter such as the operation timing such as start, interruption, and end of the operation of the equipment 220, the input amount of energy, the opening / closing degree of the valve included in the equipment 220, the opening / closing speed, and the like. To do. In addition, the control unit 210 may acquire each parameter indicating the operating status of the corresponding equipment 220. For example, the control unit 210 acquires parameters such as temperature, pressure, humidity, and the flow rate of gas or liquid flowing in the equipment 220 at a specific location of the corresponding equipment 220. Parameters that can be controlled and acquired in the equipment 220 and that are related to energy consumption in the equipment 220 are referred to as related parameters.

The energy management system 100 communicates with each control unit 210 of the facility 200. The energy management system 100 acquires series data of related parameters of each equipment 220 from each control unit 210. Series data includes two or more data measured under different conditions. For example, the series data is time series data measured at two or more different timings.

The energy management system 100 acquires sequence data of two or more related parameters in the facility 200. The energy management system 100 calculates the correlation strength between the two related parameters based on the series data. The correlation strength is a value indicating the degree of correlation of how the fluctuations occur between the two series data. In the present specification, a correlation coefficient that varies between +1 and -1 is used as the correlation strength. In this case, the correlation strength approaches +1 as the fluctuation modes of the two series data are closer, and the correlation strength approaches -1 as the fluctuation modes of the two series data are opposite to each other. The less the association is, the closer the correlation strength is to zero.

The energy management system 100 calculates the correlation strength between the related parameters. Therefore, when a certain related parameter fluctuates, it is possible to easily estimate how the other related parameter fluctuates. The energy management system 100 may present the calculated correlation strength of each related parameter to the user, or may present the processing result of the related parameter or the like based on the correlation strength to the user, and the control unit 210 or the like may present the processing result based on the processing result. May be controlled.

FIG. 2 is an example of the configuration of the energy management system 100. The energy management system 100 of this example includes a data acquisition unit 10, a correlation calculation unit 12, a parameter processing unit 14, and a presentation unit 16. The data acquisition unit 10 communicates with each control unit 210 to acquire the series data of each related parameter. The data acquisition unit 10 may store each series data in association with the related parameters.

In addition, the data acquisition unit 10 may further acquire the environmental parameters corresponding to the respective series data. The environmental parameter is a parameter indicating the state of the external environment that can affect the energy consumption of each facility 220. The environmental parameters may include weather data such as the outside temperature, humidity, wind speed, wind direction, rainfall amount, and sunshine amount of the facility 200 when each data of the series data is measured, and when each data of the series data is measured. It may include time data indicating the time, and may include operator information that identifies the operator of each facility 220 when each data of the series data is measured. The data acquisition unit 10 may store the environment parameters in association with each data of the respective series data.

The correlation calculation unit 12 calculates the correlation strength between the two related parameters. The correlation calculation unit 12 may calculate the correlation strength for all combinations of the plurality of related parameters acquired by the data acquisition unit 10. The correlation calculation unit 12 may calculate the correlation strength between the related parameters each time the data acquisition unit 10 newly acquires the series data. The correlation calculation unit 12 may store the calculated correlation strength in association with the related parameters. Further, the correlation calculation unit 12 may calculate the correlation strength between the related parameters specified by the user or the like of the energy management system 100. The correlation calculation unit 12 acquires series data of related parameters for which the correlation strength should be calculated from the data acquisition unit 10.

The parameter processing unit 14 performs a predetermined process based on the correlation strength calculated by the correlation calculation unit 12. For example, the parameter processing unit 14 extracts other related parameters whose correlation strength with respect to the related parameters specified by the user or the like satisfies a preset condition. The parameter processing unit 14 may extract other related parameters whose absolute value of the correlation strength with respect to the specified related parameter is equal to or higher than a predetermined threshold value. As a result, other related parameters that are closely related to the specified related parameters can be extracted. Further, the parameter processing unit 14 may generate information in which other related parameters are extracted and listed in the order of the magnitude of the correlation strength with respect to the specific related parameter.

From the information extracted by the parameter processing unit 14, it is possible to easily estimate which related parameter follows and how much it fluctuates when the designated related parameter is changed to a predetermined value. In addition, it is possible to easily estimate which related parameter should be changed and how much in order to set the specified related parameter to a predetermined target value.

The presentation unit 16 presents the presentation information based on the correlation strength calculated by the correlation calculation unit 12 to the user. The presented information may include at least one of a numerical value of the correlation strength and information identifying the relevant parameter. The presentation unit 16 of this example presents the related parameters extracted by the parameter processing unit 14 to the user of the energy management system 100.

The presentation unit 16 may have a monitor that displays information about related parameters. The monitor may be a small device attached to the terminal operated by the operator of the energy management system 100, or may be a large device that can be simultaneously observed by a plurality of employees in the facility 200. In another example, the presentation unit 16 may have a printing unit that prints information about the related parameters, may have a speaker that audibly notifies the information about the related parameters, and informs the user of the information about the related parameters. Other means may be provided.

According to the energy management system 100 of this example, it is possible to calculate the correlation strength indicating the correlation between the related parameters. In addition, since information according to the correlation strength is presented to the user, energy management by the user can be supported.

The data acquisition unit 10 may acquire series data of an input amount including an energy amount input to the facility 200 and an output amount including a product amount generated by the facility 200. The data acquisition unit 10 may calculate the series data of the efficiency value of the facility 200 from the series data of the input amount and the output amount. For example, the ratio of the output amount to the input amount may be used as the efficiency value of the facility 200. In the present specification, the efficiency value of the facility 200 is used as the first related parameter. Further, a related parameter other than the efficiency value of the facility 200 is set as a second related parameter.

The correlation calculation unit 12 calculates the correlation strength between the first related parameter and each of the second related parameters. That is, a value indicating how the second related parameter in the facility 200 correlates with the efficiency value of the facility 200 is calculated for each second related parameter. Thereby, it is possible to easily estimate how the second related parameter fluctuates when the efficiency value of the facility 200 is set to a predetermined target value. In addition, it is possible to easily estimate how the second related parameter should be changed in order to set the efficiency value of the facility 200 to a predetermined target value.

The data acquisition unit 10, the correlation calculation unit 12, and the parameter processing unit 14 may be configured by one computer, or may be configured by a plurality of distributed computers. The computer may store a program for making the computer function as a data acquisition unit 10, a correlation calculation unit 12, and a parameter processing unit 14, and the program may be provided via a recording medium, and a communication line may be provided. The program may be provided via.

FIG. 3A is a diagram illustrating the strength of correlation between related parameters. In FIG. 3A, the strength of correlation between the first related parameter and the three second related parameters (A, B, C) will be described. Each axis in each graph of FIG. 3A shows the average value of each related parameter in a predetermined period. Each plot in each graph shows the relationship between the mean values of each related parameter over the same period.

The smaller the variance of the value of the other related parameter with respect to the value of one related parameter, the greater the correlation strength. In the example of FIG. 3A, the value of the second related parameter A is almost uniquely determined with respect to each value of the first related parameter. Therefore, the correlation strength of the second related parameter A with respect to the first related parameter is large.

Regarding the second related parameter B, a negative correlation can be seen that decreases as the value of the first related parameter increases, but the variance of the value of the second related parameter B is higher than that of the second related parameter A. large. Therefore, the correlation strength of the second related parameter B with respect to the first related parameter is relatively large, but smaller than the correlation strength of the second related parameter A.

Regarding the second related parameter C, the values are distributed in a wide range regardless of the value of the first related parameter. Therefore, the correlation strength of the second related parameter C with respect to the first related parameter is small.

The correlation calculation unit 12 may calculate the correlation strength based on the variance of the value of the other related parameter with respect to each value of one related parameter. The variance can be calculated from the respective series data measured in the same period. The value of each related parameter may be calculated from the series data measured in different time periods. For example, when there is a predetermined delay time between the fluctuation of a certain related parameter and the fluctuation of another related parameter, the correlation calculation unit 12 may use the series data of different periods according to the delay time. .. The correlation calculation unit 12 may preset the delay time between each related parameter, and may calculate the delay time from the past series data. The correlation calculation unit 12 may calculate the correlation strength by changing the delay time in the past series data between the two related parameters, and extract the delay time at which the correlation strength is maximized.

The correlation strength of related parameters may vary depending on environmental parameters such as temperature. The correlation calculation unit 12 may extract the data corresponding to the environmental parameters conforming to the designated environmental conditions from the respective series data, and calculate the correlation strength from the extracted data. As a result, the correlation strength can be calculated with higher accuracy.

FIG. 3B is a diagram showing an example of the correlation strength calculated based on the data conforming to the predetermined environmental condition X. FIG. 3B shows the correlation strength of the second related parameter B with respect to the first related parameter.

The correlation calculation unit 12 extracts data that meets the designated environmental condition X from the series data. As a result, the number of plots in the graph shown in FIG. 3B is smaller than that shown in the interruption in FIG. 3A. The environmental condition X may be specified by a user or the like.

The correlation calculation unit 12 calculates the correlation strength based on the extracted data. In this example, by narrowing down the environmental condition X, the correlation strength of the second related parameter B is increased. For the environmental condition X, a range of predetermined environmental parameters such as temperature may be specified, a time range such as a period for measuring data and a season may be specified, and an operator or the like of each equipment 220 may be specified. By such processing, the correlation strength under a predetermined environmental condition can be calculated accurately.

FIG. 4 is a diagram showing an example of series data of related parameters D and E. In FIG. 4, the horizontal axis represents the time and the vertical axis represents the value of each parameter. The data acquisition unit 10 of this example acquires time-series data indicating the values of the related parameters at each time. It is preferable that the time series data is also associated with the values of predetermined environmental parameters at each time.

The correlation calculation unit 12 may calculate the average value of the data included in the series data for each predetermined period T. Although the period T is shown discretely in FIG. 4, the period T may be set to scan the entire range of the time series data. Each period T may have overlapping times.

The correlation calculation unit 12 calculates the correlation strength between the related parameters based on the variance when the average value of the two related parameters is plotted as shown in FIGS. 3A and 3B. Environmental parameters may be associated with the data for each period. As shown in FIG. 3B, the correlation calculation unit 12 may calculate the correlation strength only from the data conforming to the designated environmental conditions.

FIG. 5 is a diagram showing an example of presentation information generated by the parameter processing unit 14 and presented by the presentation unit 16. The presentation unit 16 of this example presents a list of the second related parameters arranged in order from the one having the largest absolute value of the correlation strength with the first related parameter. This makes it possible to present to the user a second related parameter that has a large effect on the efficiency value of the facility 200. The example of FIG. 5 shows a second relevant parameter in a boiler facility that produces steam from fuel and water. The parameter processing unit 14 may generate a list of the second related parameters under the condition that the absolute value of the correlation strength is larger than a predetermined threshold value.

FIG. 6 is a diagram showing another example of the operation of the correlation calculation unit 12. The correlation calculation unit 12 of this example calculates the correlation strength between the second related parameters in addition to the correlation strength between the first related parameter and the second related parameter. In the example of FIG. 6, the second related parameters are P1, P2, P3, ....

The correlation calculation unit 12 calculates the correlation strength based on the series data of the two second related parameters. The method of calculating the correlation strength is the same as the calculation of the correlation strength for the first related parameter. The correlation calculation unit 12 may calculate a value corresponding to the designated environmental condition also in the correlation strength between the second related parameters.

By calculating the correlation strength between the second related parameters, for example, when the value of any of the second related parameters is changed for the purpose of setting the first related parameter to a predetermined target value, the relevant Another second related parameter that fluctuates following the second related parameter can be extracted. As a result, the operation of the facility 200 can be managed in more detail.

FIG. 7 is a diagram showing another configuration example of the energy management system 100. In the energy management system 100 of this example, target values of predetermined related parameters are input to the parameter processing unit 14. The target value may be input by a user or the like. The parameter processing unit 14 performs processing according to the target value. The data acquisition unit 10, the correlation calculation unit 12, and the presentation unit 16 are the same as the energy management system 100 described with reference to FIGS. 1 to 6.

FIG. 8 is a diagram showing another example of the presentation information presented by the presentation unit 16. The presentation unit 16 of this example has a monitor 20. The monitor 20 of this example includes a name designation area 22, a period designation area 24, a fluctuation parameter designation area 26, a target value designation area (in this example, a fluctuation amount designation area 28, a fluctuation direction designation area 30), and a parameter value display area. 32 and the display parameter designation area 34 are displayed.

In the name designation area 22, the name of the facility 200 to be managed, which is designated by the user or the like, is displayed. Each designated area displayed by the monitor 20 may be provided with a pull-down button (for example, a triangular button in FIG. 8) for allowing the user to select the content in the pull-down list format. The correlation calculation unit 12 may extract the series data of the related parameters corresponding to the designated facility 200 from the data acquisition unit 10.

In the period designation area 24, the measurement period of the series data designated by the user or the like is displayed. The monitor 20 may have an area for designating and displaying environmental conditions other than the period in addition to or in place of the period designation area 24. The correlation calculation unit 12 calculates the correlation strength between each related parameter based on the series data that matches the environmental conditions specified in these areas.

The variable parameter designation area 26 displays information for identifying related parameters designated by the user or the like. A target value is set by the user or the like for the parameter. The fluctuation amount designation area 28 displays the fluctuation amount of the related parameter designated in the fluctuation parameter designation area 26. The amount of fluctuation in this example specifies the ratio of fluctuation to the value of the related parameter for the period specified in the period designation area 24. The fluctuation direction designation region 30 displays whether the fluctuation amount designated in the fluctuation amount designation region 28 is an ascending fluctuation or a descending fluctuation. As a result, the target value of the specified related parameter is determined. In another example, the monitor 20 may have an area for inputting and displaying the absolute value of the target value in addition to or in place of the fluctuation amount designation area 28 and the fluctuation direction designation area 30.

The parameter value display area 32 displays the series data of the related parameters specified by the user or the like in a predetermined period. The parameter value display area 32 of this example displays the series data of the related parameters specified by the user or the like in the display parameter designation area 34. In another example, the parameter value display area 32 may display the series data of the related parameters extracted by the parameter processing unit 14 according to the correlation strength with respect to the related parameters specified in the variable parameter designation area 26. For example, the parameter value display area 32 is selected in order from the one having the highest correlation strength with respect to the designated related parameter, and is displayed in each parameter value display area 32.

Further, the parameter value display area 32 displays the measured value of the series data and the virtual value (or target value) of the series data. For example, for the related parameter (“efficiency” parameter in the example of FIG. 8) designated in the variable parameter designation area 26, the measured value of the series data and the designated target value are displayed. In the example of FIG. 8, the measured value is shown by a solid line, and the target value whose efficiency is improved by 10% from the measured value is shown by a dotted line.

For related parameters other than the related parameters specified in the variable parameter designation area 26 (in the example of FIG. 8, the vapor pressure, gas flow rate, steam flow rate, and temperature of each facility), the measured values of the series data and the virtual series data Display the value. The virtual value of the series data is calculated from the measured value of the series data, the volatility of the "efficiency" parameter, and the correlation strength between the related parameter and the "efficiency" parameter. The parameter processing unit 14 may calculate a virtual value of the series data of the related parameter according to the product of the measured value of the series data, the volatility, and the correlation strength. In the example of FIG. 8, the measured value of each related parameter is shown by a solid line, and the virtual value is shown by a dotted line.

With such a configuration, it is possible to infer how other related parameters will fluctuate when a user-specified related parameter (eg, an "efficiency" parameter) is set to a specified target value. Therefore, the facility 200 can be managed in more detail.

FIG. 9 is a flowchart showing an operation example of the energy management system 100 shown in FIG. In step S300, the target value of the first related parameter (efficiency value of the facility 200) is input to the energy management system 100. Further, in step S302, when the first related parameter is set as the target value, the second related parameter for which the virtual value is to be calculated is designated. Information may be input from the user or the like in S300 and S302. The order of S300 and S302 may be first.

Further, the second related parameter for which the virtual value is calculated may be specified by the parameter processing unit 14 based on the related strength with respect to the first related parameter. For example, the parameter processing unit 14 designates the second related parameters in order from the one having the largest related strength to the first related parameter to a predetermined number.

In step S304, the correlation calculation unit 12 acquires the actual value of the series data of the first related parameter and the designated second related parameter from the data acquisition unit 10. The actual value may be a series data indicating an actually measured measured value or an actually used control setting value. The correlation calculation unit 12 calculates the correlation strength between each of the designated second related parameters and the first related parameter from the series data.

In step S306, the parameter processing unit 14 calculates a virtual value of the second related parameter based on the actual value of the series data of each related parameter and the correlation strength. As an example, the parameter processing unit 14 calculates the volatility of the first related parameter when the first related parameter is set as the target value. The parameter processing unit 14 calculates the virtual volatility based on the value obtained by multiplying the volatility by the correlation strength of each second related parameter. The parameter processing unit 14 calculates the virtual series data based on the value obtained by multiplying the actual value of the series data of each second related parameter by the respective virtual volatility.

In step S308, the presentation unit 16 presents the virtual series data of each second related parameter calculated by the parameter processing unit 14 to the user. The presentation unit 16 may present an average value or the like of virtual series data. By such processing, when the first related parameter is set as the target value, the virtual value of the second related parameter can be calculated and presented.

FIG. 10 is a flowchart showing another operation example of the energy management system 100. The energy management system 100 of this example further includes step S303 in addition to the operation example described in FIG. The operation of the other steps is the same as the operation example described in FIG.

In the energy management system 100 of this example, environmental conditions such as temperature are specified in S303. Environmental conditions may be specified by the user or the like. The processing of S300, S302 and S303 may be performed first.

In step S304, the correlation calculation unit 12 acquires the actual value of the series data of the first related parameter and the designated second related parameter from the data acquisition unit 10. The actual value of this example refers to the data conforming to the specified environmental conditions among the actual values described in FIG. The processing after S306 is the same as the example of FIG.

By such processing, a more appropriate correlation strength can be calculated according to the environmental conditions. The environmental conditions may be specified by the energy management system 100 instead of being specified by the user. For example, the energy management system 100 may measure environmental conditions such as the current temperature and calculate the correlation strength based on the current environmental conditions. Further, the energy management system 100 may set environmental conditions such as future temperature based on a prediction means such as a weather forecast and calculate the correlation strength based on the future environmental conditions.

FIG. 11 is a flowchart showing another operation example of the energy management system 100. The energy management system 100 of this example further includes steps S310 and S312 in addition to the operation example described with reference to FIG. 9 or 10. The operation of the other steps is the same as the operation example described with reference to FIG. 9 or 10.

In this example, each second related parameter is set with a constraint indicating an allowable fluctuation range. The constraint conditions are determined based on, for example, the performance of the equipment. In S310, the parameter processing unit 14 determines whether or not the calculated virtual value is within the permissible range of the corresponding constraint condition. If within the permissible range, the energy management system 100 ends the process.

If the calculated virtual value is out of the permissible range, the parameter processing unit 14 causes the presentation unit 16 to present that fact in step S310. The presentation unit 16 makes the display mode of the second related parameter whose virtual value is out of the permissible range different from the display mode of the other second related parameter. As an example, the presentation unit 16 changes the display color of the second related parameter whose virtual value is out of the permissible range, or blinks the display. As a result, the user's attention can be drawn.

FIG. 12 is a flowchart showing another operation example of the energy management system 100. In the examples of FIGS. 9 to 11, the virtual value of the second related parameter when the first related parameter is set as the target value is calculated, but in this example, the second related parameter is set to the virtual value. Calculate the virtual value of the first related parameter when set.

The energy management system 100 of this example sets the target value of the first related parameter in step S300 in the same manner as in the examples shown in FIGS. 9 to 11. In step S312, the parameter processing unit 14 selects the second related parameter having the highest correlation strength with the first related parameter. In step S314, the parameter processing unit 14 sets the virtual value of the selected second related parameter within the permissible range of the constraint condition of the second related parameter so that the value of the first related parameter approaches the target value. Determined by. For example, when it is desired to increase the value of the first related parameter and the second related parameter has a positive correlation strength with respect to the first related parameter, the parameter processing unit 14 determines the value of the second related parameter. Is increased within the tolerance of the constraint.

In step S316, the parameter processing unit 14 calculates the virtual value of the first related parameter by increasing the value of the second related parameter. The parameter processing unit 14 multiplies the current value of the first related parameter by the product of the correlation strength between the second related parameter and the first related parameter and the volatility of the value of the second related parameter. The virtual value may be calculated based on the calculated value.

In step S318, it is determined whether or not the difference between the calculated virtual value of the first related parameter and the target value is equal to or less than a predetermined value. When the difference is larger than a predetermined value, in step S312, the second related parameter having the next highest correlation strength is selected. The parameter processing unit 14 repeats the processing of S312 to S318 until the calculated virtual value of the first related parameter is within a predetermined error range with respect to the target value.

When the error calculated in step S318 is equal to or less than a predetermined value, the second related parameter selected so far, the virtual value of each second related parameter, and the virtual value of the first related parameter are presented. It will be presented in Part 16. By such processing, when it is desired to set the first related parameter as the target value, the type of the second related parameter to be controlled and the candidate of the value can be presented to the user.

The type of the second related parameter to be controlled and the extraction of candidates for the value are not limited to those described above. Extraction may be performed in a variety of ways based on the strength of the correlation between the first related parameter and the second related parameter.

Further, in S312, the parameter processing unit 14 preferentially designates the second related parameter having a large absolute value of the correlation strength with the first related parameter. On the other hand, the parameter processing unit 14 may specify the second related parameter using another reference.

FIG. 13 is a flowchart showing another operation example of the energy management system 100. In this operation example, the process of S320 is provided instead of the process of S312 in the operation example shown in FIG. S312 and S320 are processes for designating the second related parameter. Other processing is the same as the operation example shown in FIG.

In S320, the parameter processing unit 14 calculates the number of other second related parameters whose correlation strength is higher than a predetermined threshold value for each second related parameter. For example, in the example of FIG. 6, assuming that the threshold value of the absolute value of the correlation strength is 0.5, in the second related parameter P1, the number of other second related parameters whose correlation strength is higher than the threshold value is P2, P3. , P5. Similarly, in the second related parameter P2, the number of other second related parameters whose correlation strength is higher than the threshold value is two, P1 and P3. Similarly, in the second related parameter P3, the number of other second related parameters whose correlation strength is higher than the threshold value is P1 and P2. Similarly, in the second related parameter P4, the number of other second related parameters whose correlation strength is higher than the threshold value is 0. Similarly, in the second related parameter P5, the number of other second related parameters whose correlation strength is higher than the threshold value is P1, P3, and P6. Similarly, in the second related parameter P6, the number of other second related parameters whose correlation strength is higher than the threshold value is one of P5.

In S320, the parameter processing unit 14 selects the second related parameter P4. In S314, a virtual value of the second related parameter P4 is set. Further, in S316, the virtual value of the first related parameter corresponding to the virtual value of the second related parameter P4 is calculated. In S318, when the error of the virtual value of the first related parameter with respect to the target value is larger than the predetermined value, the process from S320 is repeated.

For example, the parameter processing unit 14 selects the second related parameter P6, which has the second smallest number of other related second related parameters. When the number of other related second related parameters is the same, the parameter processing unit 14 may preferentially specify the one having a larger absolute value of the correlation strength with respect to the first related parameter.

By such processing, when it is desired to set the first related parameter as the target value, the type of the second related parameter to be controlled and the candidate of the value can be presented to the user. Further, the virtual value can be calculated by giving priority to the second related parameter which has less influence on the other second related parameter.

FIG. 14 is a flowchart showing another operation example of the energy management system 100. The energy management system 100 of this example calculates a virtual value of the first related parameter when the value of the second related parameter is set. Further, when the value of the second related parameter is set, the energy management system 100 also calculates the virtual value of the other second related parameter, and depends on the fluctuation of the value of the other second related parameter. , The variation of the first related parameter is further calculated.

In step S322, one of the second related parameters is selected as the variation parameter and a set value is specified. Fluctuation parameters and set values may be specified by the user or the like.

In step S324, the parameter processing unit 14 extracts another second related parameter whose correlation strength with respect to the second related parameter selected as the variation parameter is equal to or greater than the threshold value.

In step S326, the parameter processing unit 14 sets the virtual value of the other second related parameter when the second related parameter selected as the variation parameter is set as the set value, and sets the correlation strength between the second related parameters. Calculated based on. For example, the parameter processing unit 14 calculates a virtual value based on a value obtained by multiplying the product of the volatility of the value in the fluctuation parameter and the correlation strength by the actual value of the other second related parameter.

In step S328, the parameter processing unit 14 calculates the virtual value of the first related parameter when the second related parameter of the fluctuation parameter is set as the set value and the other second related parameter is set as the virtual value. For example, the parameter processing unit 14 sets the product of the volatility of the value in the fluctuation parameter and the correlation strength with respect to the first related parameter, and the volatility of the value in the other second related parameter with respect to the first related parameter. A virtual value may be calculated based on a value obtained by multiplying the product with the correlation strength by the actual value of the first related parameter.

In step S330, the presenting unit 16 presents the set value, the virtual value, and the set value of the first related parameter of each of the second related parameters. By such an operation, the fluctuation of the value of the first related parameter when the set value of any of the second related parameters is changed can be analyzed in more detail.

For example, consider a facility 200 including a refrigerator that cools the inside of the refrigerator with a refrigerant and a cooler that cools the entire refrigerator. The input in the facility 200 is energy such as electric power for operating the refrigerator and the cooler, and the output is the cold air output in the refrigerator or the temperature in the refrigerator.

The power consumed by the refrigerator has a relatively large proportion of the power consumed by the facility 200, and the second related parameter for controlling the refrigerator has a relatively large correlation strength with the efficiency value of the facility 200. When the flow rate of the refrigerant or the like that cools the inside of the refrigerator is adjusted as the second related parameter in order to adjust the efficiency of the facility 200, the temperature of the refrigerator itself also fluctuates as another second related parameter. The cooler adjusts the flow rate of the refrigerant that cools the entire refrigerator based on the temperature of the refrigerator itself. Therefore, when the flow rate of the refrigerant or the like for cooling the inside of the refrigerator is changed, the flow rate of the refrigerant or the like flowing through the cooler is changed accordingly.

Fluctuations in the operation of the cooler also affect the power consumption of the facility 200, so that the efficiency value of the facility 200 may fluctuate. The variation of the second related parameter in the cooler can be estimated from the variation of the second related parameter in the refrigerator and the correlation strength between these parameters. The effect of fluctuations in the second related parameter in the cooler on the efficiency value of the facility 200 can be estimated from the strength of the correlation between the second related parameter and the efficiency value. Therefore, the fluctuation of the value of the first related parameter when the set value of any of the second related parameters is changed by the operation shown in FIG. 14 can be analyzed in more detail.

FIG. 15 is a diagram showing another configuration example of the energy management system 100. The energy management system 100 of this example further includes a control unit 18 with respect to the configuration of the energy management system 100 described with reference to FIGS. 1 to 14. Other configurations are the same as the energy management system 100 described with reference to FIGS. 1 to 14.

The control unit 18 controls the equipment 220 included in the facility 200 based on the virtual values of the respective second related parameters calculated by the parameter processing unit 14. The control unit 18 may store conversion information for determining a control value to be input to the equipment 220 from the virtual value of the second related parameter. The conversion information may be a table in which each value of the virtual value of the second related parameter is associated with the control value to be input to the equipment 220, or may be a function. With such a configuration, the efficiency value of the facility 200 can be improved.

FIG. 16 is a diagram showing another example of the usage mode of the energy management system 100. The energy management system 100 of this example is connected to one or more client terminals 230 via a network 160. As an example, network 160 includes the Internet.

The client terminal 230 is provided corresponding to each customer's facility 200. The client terminal 230 acquires the series data of each related parameter in the facility 200 and transmits it to the energy management system 100. The client terminal 230 further acquires the environmental parameters corresponding to the respective series data and transmits them to the energy management system 100. Further, the client terminal 230 may transmit various information input or specified by the user to the energy management system 100 as described in FIGS. 1 to 15. Further, the client terminal 230 may function as at least one of the presentation unit 16 and the control unit 18.

FIG. 17 is a diagram showing a configuration example of the energy management system 100. The energy management system 100 of this example includes a transmission / reception unit 50, an amount calculation unit 60, and a case database 62 for the configuration of the energy management system 100 described with reference to FIGS. 1 to 16. Further, the energy management system 100 does not have to include the presentation unit 16. Other configurations are similar to any of the energy management systems 100 described in FIGS. 1-16.

The transmission / reception unit 50 is connected to the client terminal 230 via the network 160, and receives series data and the like of related parameters from the client terminal 230. The data acquisition unit 10, the correlation calculation unit 12, and the parameter processing unit 14 operate in the same manner as the examples described in FIGS. 1 to 16 from the acquired series data and the like. The parameter processing unit 14 notifies the transmission / reception unit 50 of various information based on the correlation strength calculated by the correlation calculation unit 12.

The transmission / reception unit 50 transmits various information received from the parameter processing unit 14 to the client terminal 230. The transmission / reception unit 50 may transmit information on the correlation strength as shown in FIGS. 5 and 6, and transmits information on the set value, target value, and virtual value of each related parameter described in FIGS. 8 to 15. Often, information for controlling equipment 220 may be transmitted.

The transmission / reception unit 50 determines the efficiency value of the facility 200 before transmitting the information including at least one of the set value, the target value, and the virtual value of each related parameter to the client terminal 230, and the facility after transmitting the information. Information indicating an efficiency value of 200 is received from the client terminal 230. That is, the transmission / reception unit 50 receives information indicating the degree of improvement in the efficiency of the facility 200 before and after providing the information from the energy management system 100 to the client terminal. As the efficiency value of the facility 200, for example, a value measured over a period of about one month may be used.

The amount calculation unit 60 calculates the charge amount for the user of the client terminal 230 based on the difference between the efficiency values of the facility 200 before and after transmitting information such as the set values of the related parameters to the client terminal 230. The amount calculation unit 60 calculates a larger charge amount as the degree of improvement in efficiency in the facility 200 increases.

Further, the parameter processing unit 14 may calculate an improvement target value of the first related parameter (efficiency value) in the facility 200 based on the series data or the like received from the client terminal 230. The parameter processing unit 14 may compare the actual value of each of the second related parameters with the constraint condition to calculate the room for improving the first related parameter. For example, the parameter processing unit 14 improves the first related parameter based on the difference between the actual value of the second related parameter and the limit value of the constraint condition multiplied by the correlation strength with respect to the first related parameter. You may calculate the room. The amount calculation unit 60 may change the billing amount depending on whether or not the improvement target value has been achieved.

The case database 62 stores cases such as setting values of related parameters presented to each client terminal 230. The case database 62 stores information indicating the degree of improvement in which the efficiency is improved in the facility 200 for each case. The parameter processing unit 14 may extract cases in which the degree of improvement is greater than a predetermined value in the cases in the case database 62 in the facility 200 in which at least a part of the related parameters match. The parameter processing unit 14 may preferentially select and fluctuate the value of the related parameter whose value is fluctuating in the past case where the degree of improvement is large also in this case. Since cases for a plurality of client terminals 230 can be accumulated in the case database 62, more appropriate setting values of related parameters and the like can be presented to each client terminal 230.

Further, the transmission / reception unit 50 may extract a case in which the degree of improvement of the efficiency value in the facility 200 is large and transmit it to one or more client terminals 230. In this case, the transmission / reception unit 50 may transmit a list of cases, which is ranked based on the degree of improvement of the efficiency value, to the client terminal 230. The list of cases may include a varied list of second relevant parameters and the value of each parameter.

The presentation unit 16 described with reference to FIGS. 1 to 17 may display the target value of the efficiency (first related parameter) of the facility 200 and the current actual value in real time. In addition, the current actual value of one or more second related parameters having a high correlation strength with the first related parameter may be displayed in real time.

In addition, various embodiments of the present invention may be described with reference to flowcharts and block diagrams, wherein the block serves (1) the stage of the process in which the operation is performed or (2) the role of performing the operation. It may represent a section of the device it has. Specific stages and sections are implemented by dedicated circuits, programmable circuits supplied with computer-readable instructions stored on a computer-readable medium, and / or processors supplied with computer-readable instructions stored on a computer-readable medium. You can. Dedicated circuits may include digital and / or analog hardware circuits, and may include integrated circuits (ICs) and / or discrete circuits. Programmable circuits are memory elements such as logical AND, logical OR, logical XOR, logical NAND, logical NOR, and other logical operations, flip-flops, registers, field programmable gate arrays (FPGA), programmable logic arrays (PLA), etc. May include reconfigurable hardware circuits, including, etc.

The computer readable medium may include any tangible device capable of storing instructions executed by the appropriate device, so that the computer readable medium having the instructions stored therein is specified in a flowchart or block diagram. It will be equipped with a product that contains instructions that can be executed to create means for performing the operation. Examples of computer-readable media may include electronic storage media, magnetic storage media, optical storage media, electromagnetic storage media, semiconductor storage media, and the like. More specific examples of computer-readable media include floppy (registered trademark) disks, diskettes, hard disks, random access memory (RAM), read-only memory (ROM), erasable programmable read-only memory (EPROM or flash memory), Electrically erasable programmable read-only memory (EEPROM), static random access memory (SRAM), compact disk read-only memory (CD-ROM), digital versatile disk (DVD), Blu-ray (RTM) disk, memory stick, integrated A circuit card or the like may be included.

Computer-readable instructions are assembler instructions, instruction set architecture (ISA) instructions, machine instructions, machine-dependent instructions, microcode, firmware instructions, state-setting data, or object-oriented programming such as Smalltalk, JAVA®, C ++, etc. Contains either source code or object code written in any combination of one or more programming languages, including languages and traditional procedural programming languages such as the "C" programming language or similar programming languages. Good.

Computer-readable instructions are applied to a general-purpose computer, a special purpose computer, or the processor or programmable circuit of another programmable data processing device, either locally or in a wide area network (WAN) such as the local area network (LAN), the Internet, etc. ) May be executed to create a means for performing the operation specified in the flowchart or block diagram. Examples of processors include computer processors, processing units, microprocessors, digital signal processors, controllers, microcontrollers and the like.

FIG. 18 shows an example of a computer 2200 in which a plurality of aspects of the present invention may be embodied in whole or in part. The program installed on the computer 2200 can cause the computer 2200 to function as an operation associated with the device according to an embodiment of the present invention or as one or more sections of the device, or the operation or the one or more. Sections can be run and / or the computer 2200 can be run a process according to an embodiment of the invention or a stage of such process. Such a program may be run by the CPU 2212 to cause the computer 2200 to perform certain operations associated with some or all of the blocks in the flowcharts and block diagrams described herein.

The computer 2200 according to this embodiment includes a CPU 2212, a RAM 2214, a graphic controller 2216, and a display device 2218, which are interconnected by a host controller 2210. The computer 2200 also includes input / output units such as a communication interface 2222, a hard disk drive 2224, a DVD-ROM drive 2226, and an IC card drive, which are connected to the host controller 2210 via the input / output controller 2220. There is. The computer also includes legacy input / output units such as the ROM 2230 and keyboard 2242, which are connected to the input / output controller 2220 via an input / output chip 2240.

The CPU 2212 operates according to the programs stored in the ROM 2230 and the RAM 2214, thereby controlling each unit. The graphic controller 2216 acquires the image data generated by the CPU 2212 in a frame buffer or the like provided in the RAM 2214 or itself so that the image data is displayed on the display device 2218.

The communication interface 2222 communicates with other electronic devices via the network. The hard disk drive 2224 stores programs and data used by the CPU 2212 in the computer 2200. The DVD-ROM drive 2226 reads the program or data from the DVD-ROM 2201 and provides the program or data to the hard disk drive 2224 via the RAM 2214. The IC card drive reads programs and data from the IC card and / or writes programs and data to the IC card.

The ROM 2230 contains a boot program or the like executed by the computer 2200 at the time of activation, and / or a program depending on the hardware of the computer 2200. The input / output chip 2240 may also connect various input / output units to the input / output controller 2220 via a parallel port, serial port, keyboard port, mouse port, and the like.

The program is provided by a computer-readable medium such as a DVD-ROM 2201 or an IC card. The program is read from a computer-readable medium, installed on a hard disk drive 2224, RAM 2214, or ROM 2230, which is also an example of a computer-readable medium, and executed by the CPU 2212. The information processing described in these programs is read by the computer 2200 and provides a link between the program and the various types of hardware resources described above. The device or method may be configured by implementing manipulation or processing of information in accordance with the use of computer 2200.

For example, when communication is executed between the computer 2200 and an external device, the CPU 2212 executes a communication program loaded in the RAM 2214, and performs communication processing on the communication interface 2222 based on the processing described in the communication program. You may order. Under the control of the CPU 2212, the communication interface 2222 reads and reads transmission data stored in a transmission buffer processing area provided in a recording medium such as a RAM 2214, a hard disk drive 2224, a DVD-ROM 2201, or an IC card. The data is transmitted to the network, or the received data received from the network is written to the reception buffer processing area or the like provided on the recording medium.

Further, the CPU 2212 causes the RAM 2214 to read all or necessary parts of a file or database stored in an external recording medium such as a hard disk drive 2224, a DVD-ROM drive 2226 (DVD-ROM2201), or an IC card. Various types of processing may be performed on the data on the RAM 2214. The CPU 2212 then writes back the processed data to an external recording medium.

Various types of information, such as various types of programs, data, tables, and databases, may be stored on recording media and processed. The CPU 2212 describes various types of operations, information processing, conditional judgment, conditional branching, unconditional branching, and information retrieval described in various parts of the present disclosure with respect to the data read from the RAM 2214. Various types of processing may be performed, including / replacement, etc., and the results are written back to RAM 2214. Further, the CPU 2212 may search for information in a file, a database, or the like in the recording medium. For example, when a plurality of entries each having an attribute value of the first attribute associated with the attribute value of the second attribute are stored in the recording medium, the CPU 2212 specifies the attribute value of the first attribute. Search for an entry that matches the condition from the plurality of entries, read the attribute value of the second attribute stored in the entry, and associate it with the first attribute that satisfies the predetermined condition. The attribute value of the second attribute obtained may be acquired.

The program or software module described above may be stored on or near a computer 2200 on a computer-readable medium. Also, a recording medium such as a hard disk or RAM provided in a dedicated communication network or a server system connected to the Internet can be used as a computer-readable medium, thereby providing the program to the computer 2200 over the network. To do.

Although the present invention has been described above using the embodiments, the technical scope of the present invention is not limited to the scope described in the above embodiments. It will be apparent to those skilled in the art that various changes or improvements can be made to the above embodiments. It is clear from the description of the claims that such modified or improved forms may also be included in the technical scope of the present invention.

The order of execution of operations, procedures, steps, steps, etc. in the devices, systems, programs, and methods shown in the claims, specification, and drawings is particularly "before" and "prior to". It should be noted that it can be realized in any order unless the output of the previous process is used in the subsequent process. Even if the scope of claims, the specification, and the operation flow in the drawings are explained using "first", "next", etc. for convenience, it means that it is essential to carry out in this order. It's not a thing.

10 ... Data acquisition unit, 12 ... Correlation calculation unit, 14 ... Parameter processing unit, 16 ... Presentation unit, 18 ... Control unit, 20 ... Monitor, 22 ... Name designation Area, 24 ... Period designation area, 26 ... Fluctuation parameter designation area, 28 ... Fluctuation amount designation area, 30 ... Fluctuation direction designation area, 32 ... Parameter value display area, 34 ... Display Parameter designation area, 50 ... transmission / output unit, 60 ... amount calculation unit, 62 ... case database, 100 ... energy management system, 160 ... network, 200 ... facility, 210 ... control Department, 220 ... Equipment, 230 ... Client terminal, 2200 ... Computer, 2201 ... DVD-ROM, 2210 ... Host controller, 2212 ... CPU, 2214 ... AM, 2216 ...・ ・ Graphic controller, 2218 ・ ・ ・ Display device, 2220 ・ ・ ・ Input / output controller, 2222 ・ ・ ・ Communication interface, 2224 ・ ・ ・ Hard disk drive, 2226 ・ ・ ・ DVD-ROM drive, 2230 ・ ・ ・ ROM, 2240 ... input / output chip, 2242 ... keyboard

Claims (13)

An energy management system that manages energy information in facilities
A data acquisition unit that acquires series data of a plurality of related parameters related to energy consumption in the facility,
A correlation calculation unit that calculates the correlation strength between two related parameters based on the series data,
With the presentation unit that presents the presentation information based on the correlation strength calculated by the correlation calculation unit to the user.
With
The data acquisition unit calculates the series data of the efficiency value of the facility from the series data of the input amount including the energy amount input to the facility and the output amount including the product amount generated by the facility. As the series data of the related parameter of 1,
The correlation calculation unit calculates the correlation strength between the first related parameter and one or more second related parameters different from the first related parameter.
The correlation calculation unit further calculates the correlation strength between the second related parameters.
Further, a parameter processing unit for extracting the second related parameter in which the correlation strength with respect to the first related parameter satisfies a preset condition is further provided.
The presentation unit is an energy management system that presents the second related parameter extracted by the parameter processing unit to the user. An energy management system that manages energy information in facilities
A data acquisition unit that acquires series data of a plurality of related parameters related to energy consumption in the facility,
A correlation calculation unit that calculates the correlation strength between two related parameters based on the series data,
With the presentation unit that presents the presentation information based on the correlation strength calculated by the correlation calculation unit to the user.
With
The data acquisition unit calculates the series data of the efficiency value of the facility from the series data of the input amount including the energy amount input to the facility and the output amount including the product amount generated by the facility. As the series data of the related parameter of 1,
The correlation calculation unit calculates the correlation strength between the first related parameter and one or more second related parameters different from the first related parameter.
The correlation calculation unit further calculates the correlation strength between the second related parameters.
When the target value of the first related parameter and one or more of the second related parameters are specified, the second related parameter is used as the target value. A parameter processing unit that calculates virtual values of related parameters based on the correlation strength is further provided.
The presentation unit is an energy management system that presents a virtual value of the second related parameter calculated by the parameter processing unit to the user. When the target value of the first related parameter is input, the parameter processing unit sets one or more of the second related parameters to be controlled in order to set the first related parameter as the target value. , The energy management system according to claim 2 , which is designated based on the correlation strength. The energy management system according to claim 3 , wherein the parameter processing unit preferentially designates the second related parameter having a high correlation strength with the first related parameter. The parameter processing unit calculates the number of other second related parameters whose correlation strength is higher than a predetermined threshold value for each of the second related parameters, and calculates the other second related parameters. The energy management system according to claim 3 , wherein the second related parameter having a small number of parameters is preferentially selected. The energy management system according to any one of claims 2 to 5 , further comprising a control unit that controls equipment included in the facility based on the virtual value calculated by the parameter processing unit. The set value of any of the second related parameters is input, and the virtual value of the first related parameter when the second related parameter is set as the set value is used as the first related parameter and the first related parameter. Further provided with a parameter processing unit that calculates based on the correlation strength of the related parameters of 2.
The energy management system according to claim 1 , wherein the presentation unit presents the virtual value of the first related parameter calculated by the parameter processing unit to the user. The parameter processing unit
When the second related parameter is set as the set value, a virtual value of the other second related parameter is calculated based on the correlation strength between the second related parameters.
The energy management according to claim 7 , wherein the virtual value of the first related parameter is calculated when the second related parameter is the set value and the other second related parameter is the virtual value. system. The energy management system according to claim 8 , wherein the presentation unit presents the virtual value of the other second related parameter to the user. An energy management system that manages energy information in facilities
A data acquisition unit that acquires series data of a plurality of related parameters related to energy consumption in the facility,
With a correlation calculation unit that calculates the correlation strength between two related parameters based on the series data
With
The data acquisition unit further acquires the environmental parameters at the time of data measurement in association with each data in the series data of the related parameters.
The correlation calculation unit is an energy management system that calculates the correlation strength based on the data in which the environmental parameters satisfy a predetermined condition among the series data of the two related parameters. An energy management system that manages energy information in facilities
A data acquisition unit that acquires series data of a plurality of related parameters related to energy consumption in the facility,
A correlation calculation unit that calculates the correlation strength between two related parameters based on the series data,
A transmission / reception unit that is connected to a client terminal via a network, receives series data of the related parameters from the client terminal, and transmits information based on the correlation strength calculated by the correlation calculation unit to the client terminal.
Energy management system with. Further provided is a transmission / reception unit that is connected to a client terminal via a network, receives series data of the related parameters from the client terminal, and transmits the virtual value of the related parameters calculated by the parameter processing unit to the client terminal. The energy management system according to any one of claims 2 to 5. The billing amount for the user of the client terminal is calculated based on the difference between the efficiency value of the facility before transmitting the virtual value to the client terminal and the efficiency value of the facility after transmitting the virtual value. The energy management system according to claim 12 , further comprising a monetary amount calculation unit.

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