WO2012081088A1

WO2012081088A1 - Simulation feedback system for energy conservation control program

Info

Publication number: WO2012081088A1
Application number: PCT/JP2010/072502
Authority: WO
Inventors: 三輪和夫
Original assignee: 株式会社テクノミライ
Priority date: 2010-12-14
Filing date: 2010-12-14
Publication date: 2012-06-21
Also published as: JPWO2012081088A1; JP4849373B1

Abstract

The objective of the present invention is to correct an energy conservation control program automatically so as to approach the target energy conservation operation when multiple energy-consuming devices are operated and controlled on the basis of an energy conservation control program. A total correction rate for correction of a control rate is derived from the actual energy usage amount after multiple energy-consuming devices are operated and controlled on the basis of an energy conservation control program using a prescribed control rate, and from the target energy usage amount for the energy conservation control program. An individual correction rate is derived from the amount by which the target is not attained for the individual energy-consuming devices of the multiple energy-consuming devices, and from the energy conservation efficiency amount when the individual energy-consuming devices are operated and controlled on the basis of the first correction rate. The corrected control rate, which is derived from the aforementioned control rate, total correction rate, and individual correction rate, is corrected in the energy conservation control program being used.

Description

Energy saving control program simulation feedback system

According to the present invention, the operation of a plurality of energy consuming devices arranged in a building is controlled by a computer using an energy saving control program, and the plurality of energy can be more efficiently consumed with less energy consumption (that is, with energy saving). The present invention relates to an energy saving control system for operating and controlling consumer devices. In particular, when the plurality of energy consuming devices are operated and controlled based on the energy saving control program, and when the target energy saving effect cannot be achieved, the energy saving is made closer to the target energy saving operation. The present invention relates to a system for automatically correcting a control program.

Under the computer using the energy saving control program, the operation of the plurality of energy consuming devices deployed in the building is controlled, and the plurality of energy consuming devices can be operated more efficiently with less energy consumption (that is, with energy saving). Various proposals have been made regarding energy-saving control systems for operation and control. Various proposals have also been made regarding methods and systems for evaluating the energy saving effect of such an energy saving control system (for example,

Patent Documents

1, 2, and 3).

JP 2000-329805 A Japanese Patent Laid-Open No. 2003-50626 JP 2005-141403 A

According to the above-described conventional energy saving control system, it is said that it is possible to achieve the reduction of the target energy consumption and the cost required for energy consumption and to evaluate the energy saving effect.

However, when multiple energy consuming devices deployed in a building are operated and controlled based on the energy saving control program and the energy saving effect targeted by the energy saving control program cannot be achieved, There has not been a sufficient proposal for a system that automatically corrects the energy saving control program so as to approach the energy saving operation that is being performed.

The present invention is a case where a plurality of energy consuming devices deployed in a building are operated and controlled based on the energy saving control program, and the energy saving effect targeted by the energy saving control program cannot be achieved. An object of the present invention is to propose a system for automatically correcting the energy saving control program so as to approach the target energy saving operation.

The invention described in claim 1
The first setting when operating / controlling energy consuming equipment with energy saving The building in which a plurality of the energy consuming equipment operated and controlled according to the first energy saving control program in which the energy saving control rate is set are deployed When a plurality of energy consuming devices are operated for the predetermined period, the energy consumption amount for each energy consuming device is added and the plurality of energy consuming devices are operated for the predetermined period. An energy usage actual amount calculation processing unit that calculates an overall actual usage energy amount that is an overall energy usage amount used by
Individual energy consumption devices for each energy consumption device to be used when the plurality of energy consumption devices are operated for the predetermined period in accordance with each set first energy saving control program. Comparing the total target energy usage that is the sum of the target energy usage and the total actual energy usage, and determining that the total actual energy usage is greater than the overall target energy usage, the total actual energy usage A first correction factor calculation processing unit that calculates a first overall correction factor by subtracting the overall target energy usage from an amount, and dividing this by the total actual energy usage;
For each energy consuming device constituting the plurality of energy consuming devices, the installation capacity of the energy consuming device, the first overall correction factor, the number of operation days in the predetermined period, and the operation time on the operation day And a corrected energy saving effect amount calculation processing unit that calculates an individual corrected energy saving effect amount of each energy consuming device by multiplying the operation rate,
The individual actual energy use amount when the energy consuming device constituting the plurality of energy consuming devices is operated for the predetermined period, and the energy consuming device is predetermined according to the first energy saving control program. When the individual target energy usage amount that is the target to be used when the vehicle is operated for a certain period of time is compared and it is determined that the individual actual energy usage amount is larger than the individual target energy usage amount, the individual actual energy usage amount The individual target energy use amount is subtracted from the individual unachieved energy amount for each energy consuming device, and the individual corrected energy saving effect amount calculated by the corrected energy saving effect amount calculation processing unit for the energy consuming device is calculated. Divide by A second correction factor calculation processing unit for calculating a first individual correction factor for conservation consumers,
The first individual correction for the energy consuming device calculated by the second correction factor calculation processing unit to the first set energy saving control rate set by the first energy saving control program for each energy consuming device. The third correction rate calculation process for calculating the first post-correction set energy saving control rate for each energy consuming device by adding the rate and the first overall correction rate calculated by the first correction rate calculation processing unit And
The first corrected energy saving control program after replacing the first set energy saving control rate for each energy consuming device in the energy saving control program with the first corrected set energy saving control rate calculated above, An energy saving control program simulation feedback system comprising: a first energy saving control program changing unit that is set as an energy saving control program for operating and controlling each energy consuming device.

It is.

The invention according to claim 2
Second setting when operating / controlling energy consuming equipment with energy saving The building in which a plurality of the energy consuming equipment operated and controlled according to the second energy saving control program in which the energy saving control rate is set are deployed When a plurality of energy consuming devices are operated for the predetermined period, the plurality of energy consuming devices obtained by adding an energy usage fee for each energy consuming device are operated for the predetermined period. An energy usage fee calculation processing unit that calculates an overall actual energy usage fee that is an overall energy usage fee due to
Targets of each energy consuming device when the plurality of energy consuming devices are operated for the predetermined period in accordance with the second corrected energy saving control program after correcting / changing the second energy saving control program The total target energy usage fee obtained by totaling the individual target energy usage fees and the overall actual energy usage fee are compared, and when it is determined that the overall actual energy usage fee is greater than the overall target energy usage fee, A fourth correction factor calculation processor that calculates a second overall correction factor by subtracting the overall target energy usage fee from the overall actual energy usage fee and dividing this by the overall actual energy usage fee;
For each energy consuming device constituting the plurality of energy consuming devices, the installed capacity of the energy consuming device, the second overall correction factor, the number of operating days in the predetermined period, and the operating time on the operating day And a corrected energy saving effect usage charge calculation processing unit that calculates an individual corrected energy saving effect usage charge for each energy consuming device by multiplying the operation rate,
The individual actual energy use fee when operated for the predetermined period for each energy consuming device constituting the plurality of energy consuming devices, and the energy consuming device according to the second corrected energy saving control program Compare the individual target energy usage charges that are the targets to be used when operating for a predetermined period of time, and determine that the individual actual energy usage charges are greater than the individual target energy usage charges. The individual target energy usage fee is subtracted from the fee to obtain an individual unachieved energy usage fee for each energy consuming device, and the individual correction calculated by the corrected energy saving effect usage fee calculation processing unit for the energy consuming device Energy saving A fifth correction factor calculation processing unit for calculating a second individual correction factor for the energy consuming device is divided by the over effect toll,
The second individual correction for the energy consuming device calculated by the fifth correction factor calculation processing unit to the second set energy saving control rate set in the second energy saving control program for each energy consuming device. A sixth correction factor calculation process for calculating a second post-correction set energy saving control factor for each energy consuming device by adding the rate and the second overall correction factor calculated by the fourth correction factor calculation processing unit And
Second corrected energy saving control after replacing the second set energy saving control rate for each energy consuming device in the second energy saving control program with the second corrected energy saving control rate calculated above. An energy saving control program simulation feedback system comprising: a second energy saving control program changing means for setting a program as an energy saving control program for operating and controlling each energy consuming device.

According to the present invention, a plurality of energy consuming devices deployed in a building are operated and controlled based on the energy saving control program, and the energy saving effect targeted by the energy saving control program cannot be achieved. Sometimes, it is possible to provide a system for automatically correcting the energy saving control program so as to approach the target energy saving operation.

The figure showing the schematic structure of the system of this invention. The figure which shows an example of outline | summary, such as a control rate of a some energy consumption apparatus, installation capacity, etc. when several energy consumption apparatus is drive | operated and controlled by the energy saving control program. The figure which shows an example of the basic information regarding the building stored in building basic information DB. (A), (b), (c) is a figure which shows an example of the performance information stored in energy saving performance DB. The figure showing an example of the performance operated and controlled under the computer using an energy saving control program. The figure showing an example of the table referred when calculating an individual correction factor. The figure showing an example of the monthly control rate of FCU. The figure showing an example of the table referred when planning the usage fee reduction of the following year based on an energy usage fee performance. The figure showing an example of the processing flow based on the system of this invention. The figure showing an example of the other processing flow based on the system of this invention.

In the present invention, a plurality of energy consuming devices deployed in a building are operated and controlled under a computer using an energy saving control program.

Generally, buildings (eg commercial buildings, business buildings, factory facilities, public halls, theaters, sports facilities, large-scale complex facilities, etc.) are equipped with air conditioning equipment, external air conditioners, supply / exhaust machines, and refrigerator equipment. Many energy consuming devices such as heat source pumping equipment and lighting equipment are installed.

Each of the plurality of energy consuming devices has a predetermined capacity and is operated and controlled under the control of a computer in accordance with an energy saving control program.

This energy saving control program is created to operate and control the plurality of energy consuming devices with less energy consumption, that is, energy saving.

In this energy saving control program, a set energy saving control rate is set for operating and controlling each energy consuming machine constituting the plurality of energy consuming devices with energy saving.

FIG. 2 shows a plurality of energy consumption devices when a plurality of energy consuming devices deployed in a building are operated and controlled under a computer using an energy saving control program and the system of the present invention is applied thereto. An example of a structure of an apparatus is shown.

In the embodiment shown in FIG. 2, a fan coil unit (FCU), an air conditioner (air handling unit) (AHU), a large air conditioner for business / building (Package） Air Conditiner) (PAC), a pump Is provided. The set energy saving control rate (control rate) employed in the energy saving control program for operating and controlling each energy consuming device is FCU: 20%, AHU: 23%, PAC: 20%, and pump: 15%. Further, it is assumed that the installed capacity of each energy consuming device, the number of operation days (days) in a predetermined period, the operation time (h / day) on the operation day, and the operation rate (%) are as shown in FIG.

In FIG. 2, the “implementation control rate” is a control rate used to calculate the power effect rate. Although the control rate is the same in FCU and PAC, since AHU and pump perform inverter control, the implementation control rate is the third root of device control. That is, since the device control rate of AHU is 23% = 0.23, the execution control rate for performing inverter control is 1− (1−0.23) × (1−0.23) × (1−0.23). ) = 0.543. Similarly, the implementation control rate of the pump with the device control rate of 15% = 0.15 is 0.39.

The “energy saving effect amount” in FIG. 2 is determined in advance for each energy consuming device based on the set energy saving control rate (implementation control rate in FIG. 2) of the energy saving control program set for the energy consuming device. It represents the amount of energy saving effect when driving for a certain period. For each energy consuming device, the installation capacity of the energy consuming device, the set energy saving control rate (implementation control rate in FIG. 2), the number of operating days in the predetermined period (365 days in FIG. 2), and the operation This is obtained by multiplying the operation time in the day (10 hours per day in the case of FIG. 2) and the operation rate of each energy consuming device.

In the case of FIG. 2, since the number of operation days in a predetermined period is 365 days, the energy saving effect amount per year is calculated.

As shown in FIG. 1, the system of the present invention comprising a computer includes an actual energy use amount calculation processing unit 2, a first correction rate calculation processing unit 3, a corrected energy saving effect amount calculation processing unit 4, and a second correction rate calculation. Processing unit 5, third correction factor calculation processing unit 6, first energy saving control program changing means 7, energy usage fee calculation processing unit 12, fourth correction factor calculation processing unit 13, correction energy saving effect usage fee calculation processing unit 14, a fifth correction factor calculation processing unit 15, a sixth correction factor calculation processing unit 16, a second energy saving control program changing means 17, and a database 30.

The database 30 includes an energy saving control program DB 31, an energy saving performance DB 32, a building basic information DB 33, and an energy usage fee 34.

A plurality of energy consuming devices deployed in a building are operated and controlled under a computer using an energy saving control program, and the system of the present invention is applied here.

Basic information on the building is stored in the building basic information DB 33. FIG. 3 shows an example of basic information about a building stored in the building basic information DB 33.

In the energy saving performance DB 32, as shown in FIG. 4, for example, information related to the performance when the computer operates and controls a plurality of energy consuming devices by the energy saving control program is stored.

The energy saving control program DB 31 stores information related to the implemented energy saving control program.

The implemented energy saving control program is constructed using information stored in the building basic information DB 33 of the building to which the energy saving control program is applied and information stored in the energy saving performance DB 32. The For example, based on the type and size of buildings and the types, number, and installation capacities of multiple energy consuming devices deployed there, the results of energy conservation effects on buildings and energy consuming devices that are similar to this The energy-saving control program is constructed while referring to and repeating the simulation.

The system of the present invention operates and operates a plurality of energy consuming devices deployed in a building under a computer using an energy saving control program for a predetermined period, as will be described in more detail in Examples 1 and 2 below. Based on the operation results, when the energy saving effect and energy saving operation targeted by the energy saving control program have not been achieved, the energy saving control program is automatically executed so that the target energy saving effect and energy saving operation can be realized. It corrects automatically. In addition, refer to the operation and control results of a plurality of energy consuming devices in a predetermined period, plan a reduction in the energy usage fee associated with the operation of the plurality of energy consuming devices in the future, and install an energy saving control program to be used at that time It is created by correcting from the energy saving control program used conventionally.

In the present invention, the operation of the plurality of energy consuming devices is simulated a plurality of times, the result is fed back, and the control rate for each energy consuming device employed in the energy saving control program is corrected. Thus, the energy saving control program is corrected.

Hereinafter, an example in which the energy saving control program is automatically corrected by the system of the present invention will be described. In this embodiment, when a plurality of energy consuming devices deployed in a building are operated and controlled under a computer using an energy saving control program for a predetermined period of time, the target energy saving effect cannot be achieved. The energy saving control program is automatically corrected so as to approach the target energy saving operation.

First, the actual energy usage amount calculation processing unit 2 calculates the total actual energy usage amount (S101). That is, the plurality of energy consuming devices in the building where the plurality of energy consuming devices were operated and controlled using the first energy saving control program to be corrected were used when the plurality of energy consuming devices were operated for a predetermined period. The total energy usage is calculated.

FIG. 5 shows an example in which the usage record of a plurality of energy consuming devices in a building in which a plurality of energy consuming devices are operated and controlled using the first energy saving control program to be corrected is extracted from the building basic information DB 33. It is shown.

By using such information, the FCU having the configuration illustrated in FIG. 2 in the building in which a plurality of energy consuming devices are operated and controlled using the first energy saving control program to be corrected, It is assumed that the total energy consumption of AHU, PAC, and pump for one year is 2,300,000 kwh.

Next, the first correction factor calculation processing unit 3 calculates the first overall correction factor.

Here, first, the plurality of energy consuming devices (in the example, FCU, AHU, PAC, and pump) are respectively set to the predetermined period (the above-described) according to each set first energy saving control program. Then, the total target energy usage totaling the individual target energy usage for each energy consuming device that is the target used by each energy consuming device when operated for one year, and the total actual energy usage (2, 300,000 kwh) is compared with the first correction factor calculation processing unit 3 (S102).
The individual target energy usage amount and the overall target energy usage amount for each energy consuming device are calculated as targets when the first energy saving control program is set, and are respectively stored in the energy saving control program DB 31.

Here, for example, if the total target energy usage is 2,200,000 kwh, the first correction factor calculation processing unit 3 compares both, and in this case, the total actual usage energy (2,300 , 000 kwh) is determined to be larger than the overall target energy usage (2,200,000 kwh).

As described above, when it is determined that the total actual use energy amount is larger than the total target energy use amount, the first correction factor calculation processing unit 3 subtracts the total target energy use amount from the total actual use energy amount, Is divided by the total actual use energy amount to calculate a first overall correction factor (S103).

In the above case, the first overall correction factor is calculated as (2,300,000 kwh-2,200,000 kwh) ÷ 2,300,000 kwh × 100 = 4.4%.

Next, the corrected energy saving effect amount calculation processing unit 4 calculates the individual corrected energy saving effect amount of each energy consuming device (S104).

This individual corrected energy saving effect amount is derived by using the first overall correction factor derived by “(total actual use energy amount−total target energy use amount) ÷ total actual use energy amount”.

That is, the corrected energy saving effect amount calculation processing unit 4 determines, for each energy consuming device constituting a plurality of energy consuming devices, the equipment capacity of the energy consuming device, the first overall correction factor described above, and the predetermined amount. The individual corrected energy saving effect amount of each energy consuming device is calculated by multiplying the number of operation days in a certain period, the operation time on the operation day, and the operation rate.

For example, in the case of the example illustrated in FIG. 6, the individual corrected energy saving effect amount of the FCU is calculated as follows. Facility capacity (180 kW) × control rate (ie, implementation control rate) (0.044) × number of operating days in a predetermined period (365 days) × operating time on operating days (10 hours / day) × operating rate ( 0.6) = 17,000 kwh. This is described in column H in FIG.

In the case of an AHU in which the execution control rate is 1− (1−0.044) × (1−0.044) × (1−0.044) = 0.13 in the inverter control, the following is performed ( Advance to the third decimal place). Equipment capacity (70 kW) x control rate (ie, implementation control rate) (0.13) x number of operating days in a predetermined period (365 days) x operating time on operating days (10 hours / day) x operating rate ( 0.6) = 20,000 kwh (rounded up to the nearest hundred).

Next, the second correction factor calculation processing unit 5 calculates a first individual correction factor for each energy consuming device.

Here, first, the individual actual energy use amount when the energy consuming device constituting the plurality of energy consuming devices is operated for the predetermined period, and the energy consuming device is the first energy saving control program. Then, the second correction factor calculation processing unit 5 compares the individual target energy use amount that is a target to be used when the vehicle is operated for the predetermined period according to (S105).

For example, a plurality of energy consuming devices in a building in which a plurality of energy consuming devices are operated and controlled using the first energy saving control program to be corrected has a configuration illustrated in FIG. The actual energy consumption (actual energy consumption over the past year) even though the target energy consumption is 228,000 kwh, which is the target for operation for one year in accordance with the first energy conservation control program. ) Is 250,000 kwh.

In such a case, the second correction factor calculation processing unit 5 compares both and determines that the actual energy usage (250,000 kwh) is larger than the target energy usage (228,000 kwh). Become.

As described above, when it is determined that the individual actual energy usage is larger than the individual target energy usage, the second correction factor calculation processing unit 5 subtracts the individual target energy usage from the individual actual energy usage. An individual unachieved energy amount for each energy consuming device is obtained (S106).

In the above, 250,000 kwh-228,000 kwh = 22,000 kwh and the individual unachieved energy amount (22,000 kwh) for the FCU are obtained.

Then, the second correction rate calculation processing unit 5 uses the calculated individual unachieved energy amount as the individual corrected energy saving effect amount calculated by the corrected energy saving effect amount calculation processing unit 4 for the energy consuming device (FCU). The first individual correction factor for the energy consuming equipment (FCU) is calculated by division (S107).

In the above example, the first individual correction factor for the FCU is obtained as: individual unachieved energy amount (22,000 kwh) ÷ individual corrected energy saving effect amount (17,000 kwh) ÷ 100 = 0.012.

Next, the third correction factor calculation processing unit 6 calculates the first post-correction set energy saving control factor (108).

The calculation of the first post-correction set energy saving control rate performed by the third correction rate calculation processing unit 6 is performed on the first set energy saving control rate set in the energy saving control program for each energy consuming device. By adding the first individual correction factor for the energy consuming device calculated by the second correction factor calculation processing unit 5 and the first overall correction factor calculated by the first correction factor calculation processing unit 3 Done.

That is, in the example illustrated in FIG. 6, the first corrected energy saving control rate after correction for the FCU is calculated to the first set energy saving control rate (20%) set by the first energy saving control program for the FCU. The first individual correction factor (1.2%) for the FCU calculated by the second correction factor calculation processing unit 5 and the first overall correction factor (4) calculated by the first correction factor calculation processing unit 3 .4%) and 25.6%.

The same process is performed for AHU, PAC, and pump, and the first corrected post-correction set energy saving control rate is as follows.

AHU: 23% + 1.2% + 4.4% = 28.6%
PAC: 20% + 1.2% + 4.4% = 25.6%
Pump: 15% + 1.2% + 4.4% = 20.6%

Next, the first energy saving control program changing means 7 uses the first corrected energy saving control rate calculated above as the first set energy saving control rate for each energy consuming device in the first energy saving control program. A processing operation for setting the first corrected energy saving control program after the replacement with the control rate as an energy saving control program for operating and controlling each energy consuming device is performed (S109).

As a result, after the energy saving control program is corrected in this way, the first corrected energy saving control that adopts the first corrected energy saving control rate that has been corrected so as to be closer to the energy saving operation that was originally targeted. A plurality of energy consuming devices are operated and controlled based on the program.

As described above, according to the present invention, a plurality of energy consuming devices are operated and operated for a predetermined period based on the first energy saving control program adopting the first setting energy saving control rate that was initially set. Using the overall actual energy usage after control and the overall target energy usage resulting from the use of the first energy-saving control program, the first overall correction factor is “(Overall actual energy usage minus total energy Target energy consumption) ÷ Overall actual energy consumption ”.

Next, by using the first overall correction factor, how much energy saving effect is exhibited when the individual energy consuming devices constituting the plurality of energy consuming devices are operated for the predetermined period. Is calculated. That is, the individual corrected energy saving effect amount for each energy consuming device is calculated.

On the other hand, the first set energy saving control rate is calculated from the individual actual energy consumption when each energy consuming device is operated for the predetermined period using the first energy saving control program of the first set energy saving control rate. In accordance with the first energy saving control program, an individual unachieved energy amount is calculated by subtracting an individual target energy usage amount that is a target to be used when the vehicle is operated for the predetermined period, and the individual unachieved energy amount is calculated as the energy amount. Divide by the individually corrected energy saving effect amount calculated above for the consumer device. Thereby, the first individual correction factor for the energy consuming device is calculated.

In the present invention, as described above, first, the first overall correction factor is calculated by subtracting the overall target energy usage amount from the overall actual usage energy amount and dividing this by the overall actual usage energy amount. When the actual usage record is larger than the target for a plurality of energy consuming devices, a correction numerical value necessary for increasing the energy saving control rate is derived, and this is used as the first overall correction factor.

Next, for each individual energy consuming device, the individual unachieved energy amount is divided by the individual corrected energy saving effect amount that can be expected when control is performed using the correction value for the whole obtained above. A correction numerical value necessary for increasing the energy saving control rate for energy consuming equipment is derived, and this is used as the first individual correction rate.

Thus, the first overall correction factor calculated in two steps and the first individual correction factor are added to the first set energy saving control rate initially set for the energy consuming device. One post-correction set energy saving control rate is calculated.

Therefore, when individual energy consuming devices that constitute a plurality of energy consuming devices cannot achieve the target energy saving operation by the operation / control with the first set energy saving control rate that was initially set, In accordance with the operating status of the energy consuming equipment, the initially set energy saving control rate is corrected to a suitable value by realizing the energy saving operation targeted by the first set energy saving control rate that was initially set. can do.

In this way, for each individual energy consuming device that constitutes a plurality of energy consuming devices, the appropriate energy saving control rate is corrected based on the operation results. As a result, the entire energy consumption device is changed to the first post-correction control program suitable for realizing the energy saving operation targeted by the initially set energy saving control program.・ Control will be performed.

After the energy saving control program is corrected in this way, the first corrected energy saving control program adopting the first corrected energy saving control rate corrected so as to be closer to the energy saving operation that was initially targeted is used. Multiple energy consuming devices are operated and controlled.

For example, as shown in FIG. 7, the energy saving control rate set in the energy saving control program initially set for the FCU is January: 35% (0.35), February: 34% (0.34), ..., December: 34% (0.34). Under this condition, it is assumed that, after one year of operation and control, correction is performed as described above, and the first post-correction set energy saving control rate becomes the first set energy saving control rate + 5.6%. In this case, the first post-correction set energy-saving control rate for the FCU for the next year is January: 40.6% (0.406), February: 39.6% (0.396), ...・・ December: 39.6% (0.396).

In this embodiment, the “predetermined period” is described as one year, but the above-described correction of the energy saving control program may be performed every arbitrary period such as three months.

Next, another example in which the energy saving control program is automatically corrected by the system of the present invention will be described. In this embodiment, after operating and controlling a plurality of energy consuming devices installed in a building under a computer using an energy saving control program for a predetermined period, the plurality of energy consuming devices thereafter are used. A target for reducing the energy consumption device usage fee required is set, and the energy saving control program is automatically corrected so as to approach the target reduction.

For example, the profit and loss statement for fiscal 2009 is as shown in Fig. 8, and the utility cost corresponding to the overall energy consumption equipment usage fee is 9 million yen, which is 4% up to 86.4 million yen in the fiscal 2010 budget. Suppose you plan to reduce the amount. The energy saving control program is automatically corrected so as to enable energy saving operation that can approach such a reduction.

In FY2009, the above-mentioned 9 million yen utility bill was made due to the operation and control of a plurality of energy consuming devices based on the second energy-saving control program set at the beginning of FY2009. In this embodiment, correction of the energy saving control program in the case where the amount is reduced by 4% up to 2010, 840,000 yen will be described.

Since the basic configuration is the same as that described in the first embodiment, the description will focus on differences from the description in the first embodiment.

The energy usage fee calculation processing unit 12 calculates an overall actual usage energy fee (S201). That is, the total energy resulting from the operation of the plurality of energy consuming devices for a predetermined period in a building where the plurality of energy consuming devices were operated and controlled using the second energy saving control program to be corrected. Calculate usage fees.

For example, the configuration illustrated in FIG. 2 in a building in which a plurality of energy consuming devices are operated and controlled using the second energy saving control program to be corrected using the information illustrated in FIG. Calculate the total annual energy usage fee for FCU, AHU, PAC, and pump.

Next, the fourth correction factor calculation processing unit 13 calculates the second overall correction factor.

Here, first, the plurality of energy consuming devices (FCU, AHU, PAC, pump in the above example) according to the second corrected energy saving control program after correcting / changing the second energy saving control program. The total target energy usage fee, which is the total of the individual target energy usage fees that are the targets of each energy consuming device when operating for the predetermined period (in the above, one year), and the overall actual usage energy fee The fourth correction factor calculation processing unit 13 performs a process for comparing (S202)
In this case, the total actual usage energy charge is 9 million yen as shown in the fiscal year ending March 2009 in FIG. Then, as shown in FIG. 8 for the fiscal year ending March 2010, the total target energy usage fee is 8.64 million yen.

As a result of this comparison, the fourth correction factor calculation processing unit 13 determines that the total actual energy usage fee is larger than the total target energy usage fee. The second overall correction factor is calculated by subtracting the overall target energy usage fee from this and dividing it by the overall actual usage energy fee (S203).

In this case, the total actual energy usage fee (9 million yen) is larger than the overall target energy usage fee (86.4 million yen), so the second overall correction factor of 4% is calculated.

Next, the corrected energy saving effect fee calculation processing unit 14 calculates an individual corrected energy saving effect fee for each energy consuming device (S204).

This individual corrected energy saving effect charge is derived by using the second overall correction factor derived by “(Overall actual use energy charge-Overall target energy use charge) ÷ Overall actual use energy charge”.

That is, the corrected energy saving effect fee calculation processing unit 14 determines, for each energy consuming device constituting a plurality of energy consuming devices, the equipment capacity of the energy consuming device, the second overall correction factor described above, and the predetermined amount. Multiplying the number of operating days, the operating time on the operating day, and the operation rate, and referring to the basic energy charges stored in the energy usage charge DB 34, the individual corrected energy saving effect charges for each energy consuming device Is calculated.

Next, the fifth correction factor calculation processing unit 15 calculates a second individual correction factor for each energy consuming device.

Here, first, the individual actual energy usage fee when operated for the predetermined period for each of the energy consuming devices constituting the plurality of energy consuming devices (that is, the individual results for one year until March 2009) Energy usage charges) and the individual target energy that was the target when the energy consuming equipment was operated in accordance with the second energy-saving control program for the predetermined period (that is, one year until March 2009) The fifth correction factor calculation processing unit 15 compares the usage fee (S205).

By comparison, when the fifth correction factor calculation processing unit 15 determines that the individual actual energy usage fee is larger than the individual target energy usage fee, the second correction factor calculation processing unit 5 calculates the above-mentioned individual actual energy usage fee from the individual actual energy usage fee. An individual unachieved energy usage fee for each energy consuming device is obtained by subtracting the individual target energy usage fee (S206).

Then, the fifth correction rate calculation processing unit 15 divides the calculated individual unachieved energy usage fee by the individual corrected energy saving effect fee calculated by the corrected energy saving effect fee calculation processing unit 14 for the energy consuming device. Then, a second individual correction factor for the energy consuming device is calculated (S207).

Next, the sixth correction factor calculation processing unit 16 calculates a second post-correction set energy saving control factor (S208).

The calculation of the second post-correction set energy saving control rate performed by the sixth correction factor calculation processing unit 16 is the second set energy saving control set in the second energy saving control program for each energy consuming device. The second individual correction factor for the energy consuming device calculated by the fifth correction factor calculation processing unit 15 and the second overall correction factor calculated by the fourth correction factor calculation processing unit 13 are added to the rate. Is done by doing.

Next, the second energy saving control program changing means 17 uses the second corrected energy saving control rate calculated above as the second set energy saving control rate for each energy consuming device in the second energy saving control program. A processing operation for setting the second corrected energy saving control program after the replacement with the control rate as an energy saving control program for operating and controlling each energy consuming device is performed (S209).

As a result, after the energy-saving control program is corrected in this way, the second energy energy-saving device usage fee of 9 million yen is corrected to be closer to the energy-saving operation in which the following year is reduced by 8% to 8.64 million yen. A plurality of energy consuming devices are operated and controlled based on the second post-correction energy saving control program adopting the post-correction set energy saving control rate.

As described above, according to the present invention, a plurality of energy consuming devices are operated and controlled for a predetermined period based on the second energy saving control program adopting the predetermined second set energy saving control rate. The plurality of energy consuming devices were operated and controlled for the predetermined period in accordance with the overall actual usage energy charge after the second and the second corrected energy saving control program after the second energy saving control program was corrected / changed. The second overall correction factor is obtained by “(total actual energy use fee−total target energy use fee) ÷ total actual energy use fee”.

Next, by using the second overall correction factor, how much energy saving effect fee is exhibited when the individual energy consuming devices constituting the plurality of energy consuming devices are operated for the predetermined period. Is calculated. That is, an individual corrected energy saving effect charge for each energy consuming device is calculated.

On the other hand, from the individual actual energy usage fee when each energy consuming device is operated for the predetermined period using the second energy saving control program of the second setting energy saving control rate, the second setting energy saving control rate In accordance with the second energy saving control program, the individual target energy usage fee to be used when the vehicle is operated for the predetermined period is subtracted to calculate the individual unachieved energy usage fee. Divide by the individually corrected energy saving effect charge calculated above for the energy consuming equipment. Thereby, the second individual correction factor for the energy consuming device is calculated.

In the present invention, as described above, first, the second overall correction factor is calculated by subtracting the overall target energy usage fee from the overall actual usage energy fee and dividing this by the overall actual usage energy fee. A correction numerical value necessary for increasing the energy saving control rate is derived for the plurality of energy consuming devices as a whole, and this is used as the second overall correction rate.

Next, for each individual energy consuming device, the individual unachieved energy usage fee is divided by the individual corrected energy saving effect fee that can be expected when control is performed using the correction value for the whole obtained above. A correction numerical value necessary for increasing the energy saving control rate for the energy consuming equipment is derived and used as the second individual correction rate.

The second overall correction factor calculated in two steps and the second individual correction factor in this way are added to the second set energy saving control rate set for the energy consuming device, and the second A post-correction set energy saving control rate is calculated.

Therefore, with regard to individual energy consuming devices constituting a plurality of energy consuming devices, the total energy in accordance with the operation status of the individual energy consuming devices at the second set energy saving control rate that has been conventionally used. The second energy saving control rate that has been initially set can be corrected to a suitable value by reducing the consumption device usage fee to the target amount.

In this way, for each individual energy consuming device that constitutes multiple energy consuming devices, an appropriate energy saving control rate based on the operation results at the second set energy saving control rate that has been used conventionally is Correction is performed. As a result, the entire energy consumption equipment is changed to a second corrected control program that is more suitable for realizing the reduction of the target overall energy consumption equipment usage fee, and the subsequent operation and control are performed. To be done.

The preferred embodiments and examples of the present invention have been described above with reference to the accompanying drawings, but the present invention is not limited to the above-described embodiments and examples, and can be understood from the description of the scope of claims. Various changes can be made within the technical scope.

Brief description of symbols

DESCRIPTION OF SYMBOLS 1 Energy saving control program simulation feedback system 2 Energy use performance amount calculation processing part 3 First correction rate calculation processing part 4 Correction energy saving effect amount calculation processing part 5 Second correction rate calculation processing part 6 Third correction rate calculation processing part 7 First energy saving control program changing means 12 Energy usage fee calculation processing unit 13 Fourth correction rate calculation processing unit 14 Correction energy saving effect usage fee calculation processing unit 15 Fifth correction factor calculation processing unit 16 Sixth correction factor calculation Processing unit 17 Second energy saving control program changing means 30 Database 31 Energy saving control program DB
32 Energy Saving Performance DB
33 Building Basic Information DB

Claims

The first setting when operating / controlling energy consuming equipment with energy saving The building in which a plurality of the energy consuming equipment operated and controlled according to the first energy saving control program in which the energy saving control rate is set are deployed When a plurality of energy consuming devices are operated for the predetermined period, the energy consumption amount for each energy consuming device is added and the plurality of energy consuming devices are operated for the predetermined period. An energy usage actual amount calculation processing unit that calculates an overall actual usage energy amount that is an overall energy usage amount used by
Individual energy consumption devices for each energy consumption device to be used when the plurality of energy consumption devices are operated for the predetermined period in accordance with each set first energy saving control program. Comparing the total target energy usage that is the sum of the target energy usage and the total actual energy usage, and determining that the total actual energy usage is greater than the overall target energy usage, the total actual energy usage A first correction factor calculation processing unit that calculates a first overall correction factor by subtracting the overall target energy usage from an amount, and dividing this by the total actual energy usage;
For each energy consuming device constituting the plurality of energy consuming devices, the installation capacity of the energy consuming device, the first overall correction factor, the number of operation days in the predetermined period, and the operation time on the operation day And a corrected energy saving effect amount calculation processing unit that calculates an individual corrected energy saving effect amount of each energy consuming device by multiplying the operation rate,
The individual actual energy use amount when the energy consuming device constituting the plurality of energy consuming devices is operated for the predetermined period, and the energy consuming device is predetermined according to the first energy saving control program. When the individual target energy usage amount that is the target to be used when the vehicle is operated for a certain period of time is compared and it is determined that the individual actual energy usage amount is larger than the individual target energy usage amount, the individual actual energy usage amount The individual target energy use amount is subtracted from the individual unachieved energy amount for each energy consuming device, and the individual corrected energy saving effect amount calculated by the corrected energy saving effect amount calculation processing unit for the energy consuming device is calculated. Divide by A second correction factor calculation processing unit for calculating a first individual correction factor for conservation consumers,
The first individual correction for the energy consuming device calculated by the second correction factor calculation processing unit to the first set energy saving control rate set by the first energy saving control program for each energy consuming device. The third correction rate calculation process for calculating the first post-correction set energy saving control rate for each energy consuming device by adding the rate and the first overall correction rate calculated by the first correction rate calculation processing unit And
The first corrected energy saving control program after replacing the first set energy saving control rate for each energy consuming device in the energy saving control program with the first corrected set energy saving control rate calculated above, An energy saving control program simulation feedback system comprising: a first energy saving control program changing unit that is set as an energy saving control program for operating and controlling each energy consuming device.
Second setting when operating / controlling energy consuming equipment with energy saving The building in which a plurality of the energy consuming equipment operated and controlled according to the second energy saving control program in which the energy saving control rate is set are deployed When a plurality of energy consuming devices are operated for the predetermined period, the plurality of energy consuming devices obtained by adding an energy usage fee for each energy consuming device are operated for the predetermined period. An energy usage fee calculation processing unit that calculates an overall actual energy usage fee that is an overall energy usage fee due to
Targets of each energy consuming device when the plurality of energy consuming devices are operated for the predetermined period in accordance with the second corrected energy saving control program after correcting / changing the second energy saving control program The total target energy usage fee obtained by totaling the individual target energy usage fees and the overall actual energy usage fee are compared, and when it is determined that the overall actual energy usage fee is greater than the overall target energy usage fee, A fourth correction factor calculation processor that calculates a second overall correction factor by subtracting the overall target energy usage fee from the overall actual energy usage fee and dividing this by the overall actual energy usage fee;
For each energy consuming device constituting the plurality of energy consuming devices, the installed capacity of the energy consuming device, the second overall correction factor, the number of operating days in the predetermined period, and the operating time on the operating day And a corrected energy saving effect usage charge calculation processing unit that calculates an individual corrected energy saving effect usage charge for each energy consuming device by multiplying the operation rate,
The individual actual energy use fee when operated for the predetermined period for each energy consuming device constituting the plurality of energy consuming devices, and the energy consuming device according to the second corrected energy saving control program Compare the individual target energy usage charges that are the targets to be used when operating for a predetermined period of time, and determine that the individual actual energy usage charges are greater than the individual target energy usage charges. The individual target energy usage fee is subtracted from the fee to obtain an individual unachieved energy usage fee for each energy consuming device, and the individual correction calculated by the corrected energy saving effect usage fee calculation processing unit for the energy consuming device Energy saving A fifth correction factor calculation processing unit for calculating a second individual correction factor for the energy consuming device is divided by the over effect toll,
The second individual correction for the energy consuming device calculated by the fifth correction factor calculation processing unit to the second set energy saving control rate set in the second energy saving control program for each energy consuming device. A sixth correction factor calculation process for calculating a second post-correction set energy saving control factor for each energy consuming device by adding the rate and the second overall correction factor calculated by the fourth correction factor calculation processing unit And
Second corrected energy saving control after replacing the second set energy saving control rate for each energy consuming device in the second energy saving control program with the second corrected energy saving control rate calculated above. An energy saving control program simulation feedback system comprising: a second energy saving control program changing means for setting a program as an energy saving control program for operating and controlling each energy consuming device.