JP2004085087A - Air conditioner power derivation device, energy diagnostic system, and energy diagnostic device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily estimate the power consumption of an air conditioner used for energy diagnosis and to perform the consumed energy diagnosis in a building based on the power consumption estimation value of the air conditioner. <P>SOLUTION: This energy diagnostic system has a local controller 10. The local controller 10 has a part power estimation program 11a and an air conditioner power derivation program 11b. The part power estimation program 11a estimates the power consumption value of a specified power consuming part possessed by air conditioners 31 and 32 set in the building 60. The air conditioner power derivation program 11b derives the power consumption of the air conditioners 31 and 32 based on the power consumption estimation value of the power consuming part estimated by the program 11a. The power consuming part includes, for example, the compressor 33a of the air conditioner 31 and 32, an indoor fan motor 34d, an outdoor fan motor 33g, or a heater 33b that is an auxiliary heater for the compressor 33a. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an air conditioner power derivation device, an energy diagnosis system, and an energy diagnosis device, and in particular, an air conditioner power derivation device for deriving an estimated power consumption value of an air conditioner and estimation of power consumption in a building in which the air conditioner is installed. The present invention relates to an energy diagnostic system and an energy diagnostic device for calculating a value.
[0002]
[Prior art]
In recent years, with the increasing awareness of energy saving, businesses that diagnose the energy usage of buildings and other buildings have attracted attention. In this diagnosis, in order to reduce the energy cost in a building such as a building, the power consumption of equipment in the building is measured, and a diagnosis is made as to whether there is no waste in operation. In addition, utilizing the measured power consumption of the equipment and the like, it proposes updating of the equipment and the like.
[0003]
In this energy diagnosis, it is important to measure the power consumption of the air conditioner among the equipment. The power consumption of the air conditioner accounts for the majority of the power consumed in buildings such as buildings. Therefore, measuring the power consumption of the air conditioner and diagnosing useless power consumption of the air conditioner leads to a reduction in energy costs in the building. Therefore, in the conventional energy diagnosis, a power meter or a special device such as a current transformer (CT) is attached to the air conditioner to measure the power consumption.
[0004]
However, in this conventional energy diagnosis, the period during which the power consumption of the air conditioner can be measured is limited to the period during which the special device is attached. Therefore, at present, it is difficult to acquire data such as seasonal variations in the power consumption of the air conditioner and use the data for energy diagnosis. Therefore, it is required to easily measure the power consumption of the air conditioner without installing a special device in the air conditioner.
[0005]
[Problems to be solved by the invention]
Therefore, an object of the present invention is to provide an air conditioner power derivation device for easily estimating the power consumption of an air conditioner for use in energy diagnosis, and a diagnosis of energy consumption in a building based on an estimated power consumption value of the air conditioner. To provide an energy diagnosis system and an energy diagnosis device.
[0006]
[Means for Solving the Problems]
An air conditioner power deriving device according to a first aspect includes a component power estimating unit and an air conditioner power deriving unit. The component power estimation unit estimates a power consumption value of a specific power consuming component of the air conditioner installed in the building. The air conditioner power derivation unit derives an estimated power consumption value of the air conditioner based on the estimated power consumption value of the power consuming component estimated by the component power estimation unit.
[0007]
Here, the power consuming component is, for example, a compressor of an air conditioner, an indoor fan motor, an outdoor fan motor, or an auxiliary heater for the compressor. The component power estimating means acquires information on the operation of the power consuming component and estimates power consumption. For example, it is known that the power consumption of the compressor can be estimated from the evaporation temperature of the refrigerant in the evaporator connected to the same refrigerant circuit and the condensation temperature of the refrigerant in the condenser. Therefore, for the compressor, the evaporating temperature of the refrigerant in the evaporator and the condensing temperature of the refrigerant in the condenser are acquired, and the power consumption is estimated. Further, the air conditioner power deriving means sums the power consumption estimated values of the respective power consuming components estimated by the component power estimating means, or multiplies the power consumption estimated value of the power consuming parts by a predetermined coefficient. To derive an estimated value of power consumption of the air conditioner.
[0008]
With this air conditioner power derivation device, the power consumption of the air conditioner can be easily estimated without installing a special device for measuring the power consumption in the air conditioner. In addition, it is possible to measure the trend of the power consumption of the air conditioner over a long period of time, and it is possible to perform more detailed energy diagnosis.
An air conditioner power deriving device according to claim 2 is the air conditioner power deriving device according to claim 1, wherein the power consuming component includes a compressor of the air conditioner.
[0009]
The component power estimating means acquires information related to the operation of the compressor and estimates the power consumption of the compressor. For example, it is known that the power consumption of the compressor can be estimated from the evaporation temperature of the refrigerant in the evaporator connected to the same refrigerant circuit and the condensation temperature of the refrigerant in the condenser. Therefore, for the compressor, the evaporating temperature of the refrigerant in the evaporator and the condensing temperature of the refrigerant in the condenser are acquired, and the power consumption is estimated. Further, the air conditioner power deriving means derives an estimated power consumption value of the air conditioner based on the estimated power consumption value of the compressor estimated by the component power estimating means.
[0010]
Power consumption by the compressor accounts for most of the power consumption of the air conditioner. Therefore, it is possible to more accurately derive the power consumption of the air conditioner by accurately estimating the power consumption of the compressor.
An energy diagnosis system according to claim 3 includes the air conditioner power derivation device according to claim 1 or 2, and a power calculation device in a building. The air conditioner power derivation device according to claim 1 or 2 derives an estimated power consumption value of the air conditioner. The in-building power calculation device calculates an estimated value of the power consumption in the building based on the estimated power consumption value of the air conditioner derived by the air conditioner power deriving device.
[0011]
The in-building power calculation device calculates an estimated value of power consumption in a building by, for example, multiplying a total of estimated values of power consumption by air conditioners in the building by a predetermined coefficient. Here, the predetermined coefficient is a coefficient set based on, for example, statistical data such as a ratio of the power consumption of the air conditioner to the power consumption in the building. If this coefficient is set according to the season or the type of the building, the power consumption in the building is more accurately estimated. Here, the type of building refers to, for example, an office, a hospital, a school, or a factory.
[0012]
With this energy diagnosis system, it is possible to easily calculate the power consumption in a building without installing a special device for measuring the power consumption. In addition, it is possible to measure the trend of power consumption in the building for a long time, and it is possible to perform more detailed energy diagnosis.
The energy diagnostic apparatus according to claim 4 includes an air conditioner power deriving unit and a building power calculating unit. The air conditioner power derivation unit estimates a power consumption value of a specific power consuming component of the air conditioner installed in the building, and, based on the estimated power consumption value of the power consuming component, estimates a power consumption of the air conditioner. Derive a power estimate. The in-building power calculation means calculates an estimated value of power consumption in the building based on the estimated power consumption value of the air conditioner derived by the air conditioner power deriving means.
[0013]
Here, the power consuming component is, for example, a compressor of an air conditioner, an indoor fan motor, an outdoor fan motor, or an auxiliary heater for the compressor. The air conditioner power derivation unit acquires information on the operation of the power consuming component and estimates power consumption. For example, it is known that the power consumption of the compressor can be estimated from the evaporation temperature of the refrigerant in the evaporator connected to the same refrigerant circuit and the condensation temperature of the refrigerant in the condenser. Therefore, for the compressor, the evaporating temperature of the refrigerant in the evaporator and the condensing temperature of the refrigerant in the condenser are acquired, and the power consumption is estimated. Further, the air conditioner power deriving means may add the estimated power consumption value of each power consuming component or multiply the estimated power consumption value of the power consuming component by a predetermined coefficient, and Deriving an estimated power consumption value. The in-building power calculation means calculates an estimated value of power consumption by the air conditioner in the building based on the estimated power consumption value of the air conditioner derived by the air conditioner power deriving means. Further, the in-building power calculating means calculates the estimated value of the power consumption in the building, for example, by multiplying the estimated value of the power consumption by the air conditioner in the building by a predetermined coefficient. Here, the predetermined coefficient is a coefficient set based on, for example, statistical data such as a ratio of the power consumption of the air conditioner to the power consumption in the building. If this coefficient is set according to the season or the type of the building, the power consumption in the building is more accurately estimated. Here, the type of building refers to, for example, an office, a hospital, a school, or a factory.
[0014]
With this energy diagnostic device, it is possible to easily calculate the power consumption in a building without installing a special device for measuring the power consumption. In addition, it is possible to measure the trend of power consumption in the building for a long time, and it is possible to perform more detailed energy diagnosis.
An energy diagnostic device according to a fifth aspect is the energy diagnostic device according to the fourth aspect, wherein the power consuming component includes a compressor of an air conditioner.
[0015]
The air conditioner power derivation unit acquires information related to the operation of the compressor and estimates the power consumption of the compressor. For example, it is known that the power consumption of the compressor can be estimated from the evaporation temperature of the refrigerant in the evaporator connected to the same refrigerant circuit and the condensation temperature of the refrigerant in the condenser. Therefore, for the compressor, the evaporating temperature of the refrigerant in the evaporator and the condensing temperature of the refrigerant in the condenser are acquired, and the power consumption is estimated. Further, the air conditioner power deriving means derives an estimated power consumption value of the air conditioner based on the estimated power consumption value of the compressor estimated by the component power estimating means.
[0016]
Power consumption by the compressor accounts for most of the power consumption of the air conditioner. Therefore, by accurately estimating the power consumption of the compressor using this energy diagnosis device, it is possible to more accurately derive the power consumption of the air conditioner. Furthermore, if the power consumption of the air conditioner can be derived more accurately, the power consumption in the building can be calculated more accurately.
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
[First Embodiment]
<Overview of the system>
FIG. 1 shows an air conditioner management system according to a first embodiment of the present invention. This air conditioner management system is a system that manages the operation of the air conditioner 30 installed in the building 60, and uses a control device called a local controller 10 to perform status monitoring, start / stop control, operation settings, and the like of the air conditioner 30. Do. In addition, information collected by the local controller 10 from the air conditioner 30 and information on operation settings of the air conditioner 30 are notified to the management server 20 via the communication network 50. The management server 20 monitors an abnormality of the air conditioner 30 based on the notified information.
[0018]
In addition, the air conditioner management system can estimate the power consumed in the building 60 and diagnose the energy use state. In the present embodiment, the energy diagnosis will be described.
<System configuration>
The air conditioner management system of the present invention includes an air conditioner 30 installed in a building 60, a local controller 10, and a management server 20 connected to the local controller 10 via a communication network 50.
[0019]
In the building 60, in addition to the air-conditioning equipment 30, equipment such as an electric equipment 40, a lighting equipment 41, and a disaster prevention / security equipment 42 are installed.
The air conditioner 30 includes air conditioners 31, 32,. The configuration of the air conditioner 30 will be described later.
The local controller 10 is a computer equipped with a CPU 12 and having a RAM, a ROM, and the like as a storage unit 11 controlled by the CPU 12. The storage unit 11 includes a component power estimation program 11a and an air conditioner power derivation program 11b.
[0020]
The communication network 50 is, for example, a public line or a dedicated line.
The management server 20 is a computer equipped with a CPU 22 and a RAM, a ROM, a hard disk, or the like as a storage unit 21 controlled by the CPU 22. The storage unit 21 includes a building power calculation program 21a.
<Configuration of air conditioning equipment 30>
The air conditioners 31, 32,... Provided in the air conditioner 30 are multi-type air conditioners. In the multi-type air conditioner 31, a plurality of indoor units 31b, 31c,... Are connected to one outdoor unit 31a via refrigerant pipes and transmission lines. Similarly, for the air conditioner 32, a plurality of indoor units are connected to one outdoor unit. Hereinafter, the air conditioners 31, 32,... Will be described using the air conditioner 31 as an example.
[0021]
The air conditioner 31 includes an outdoor unit 31a and a plurality of indoor units 31b, 31c,... Connected to the outdoor unit 31a via refrigerant pipes and transmission lines.
The outdoor unit 31a includes a compressor 33a, a heater 33b as an auxiliary heater for the compressor, a four-way valve 33c, an outdoor heat exchanger 33d, an accumulator 33e, an outdoor fan 33f, an outdoor fan motor 33g, a sensor 33h, and the like. .
[0022]
The indoor units 31b, 31c,... Have the same configuration. The indoor units 31b, 31c,... Include an indoor heat exchanger 34a, an expansion valve 34b, an indoor fan 34c, an indoor fan motor 34d, a sensor 34e, and the like. (The indoor heat exchanger 34a, expansion valve 34b, indoor fan 34c, indoor fan motor 34d, and sensor 34e of the indoor units 31c,... Are not shown.)
The air conditioner 31 includes a compressor 33a, a four-way valve 33c, an outdoor heat exchanger 33d, an expansion valve 34b, an indoor heat exchanger 34a, an accumulator 33e, and a refrigerant circuit configured by refrigerant pipes connecting these components. Air conditioning is performed by evaporation.
[0023]
<Operation of the system>
The energy diagnosis function of the air conditioner management system according to the present invention will be described.
(1) Function of local controller 10
The local controller 10 derives the power consumption of the air conditioners 31, 32,. Hereinafter, the derivation of the power consumption of the air conditioner 31 will be described.
[0024]
(1-1) Operation of the component power estimation program 11a
First, the component power estimation program 11a acquires information from the sensor 33h of the outdoor unit 31a or the sensor 34e of the indoor units 31b, 31c,... In order to estimate the power consumption of the power consuming components of the air conditioner 31. Here, the power consuming component is a component that operates by consuming power. For example, the compressor 33a included in the outdoor unit 31a, the heater 33b serving as an auxiliary heater for the compressor 33a, and the outdoor fan motor 33g Or the indoor fan motor 34d of the indoor units 31b, 31c,...
[0025]
When estimating the power consumption of the compressor 33a, the component power estimation program 11a acquires the temperature of the refrigerant in the outdoor heat exchanger 33d from the sensor 33h of the outdoor unit 31a. Further, the temperature of the refrigerant in the indoor heat exchanger 34a is obtained from the sensors 34e of the indoor units 31b, 31c,. In general, it is known that the power consumption of a compressor of an air conditioner can be estimated from the evaporation temperature and condensation temperature of the refrigerant in an indoor heat exchanger and an outdoor heat exchanger connected to the refrigerant circuit. Using this fact, the component power estimation program 11a estimates the power consumption of the compressor 33a based on the refrigerant temperatures acquired from the sensors 33h and 34e.
[0026]
Next, when estimating the power consumption of the heater 33b, which is an auxiliary heater for the compressor 33a, the component power estimation program 11a determines the time during which the heater 33b operates and the power consumed by the heater 33b per unit time. Based on this, the power consumption of the heater 33b is estimated. Further, when the heater 33b operates by switching a plurality of levels, the sensor 33h acquires the operation state, and based on the operation time at the level and the power consumed per unit time by the operation at the level. Thus, the power consumption of the heater 33b can be estimated.
[0027]
Further, when estimating the power consumption of the outdoor fan motor 33g, the component power estimation program 11a calculates the outdoor fan motor 33g based on the time during which the outdoor fan motor 33g operates and the power consumed by the outdoor fan motor 33g per unit time. The power consumption of the motor 33g is estimated. When the outdoor fan motor 33g operates by switching a plurality of high and low levels, the sensor 33h acquires the operation state, and based on the time of operation at that level and the power consumed per unit time by the operation at that level. Thus, the power consumption of the outdoor fan motor 33g can be estimated.
[0028]
Further, the power consumption of the indoor fan motor 34d can be estimated similarly to the outdoor fan motor 33g. In this case, the sensor 34e acquires the operation status of the indoor fan motor 34d.
(1-2) Operation of Air Conditioner Power Derivation Program 11b
The air conditioner power derivation program 11b sums up the power consumption estimation values of the power consuming components of the air conditioner 31 obtained by the component power estimation program 11a, and derives an estimated value of the power consumption by the air conditioner 31. When only the power consumption of some of the power consuming components can be estimated by the component power estimation program 11a, the sum of the estimated power consumption values of the power consuming components estimated by the component power estimation program 11a is multiplied by a predetermined coefficient. Thereby, the estimated value of the power consumption by the air conditioner 31 can be derived.
[0029]
Further, the air conditioner power derivation program 11b similarly derives estimated power consumption values of the other air conditioners 32,.
(2) Operation of management server 20
The management server 20 acquires an estimated value of power consumption by the air conditioners 31, 32,... In the building 60 from the local controller 10 via the communication network 50. The in-building power calculation program 21a calculates an estimated value of the power consumption in the building 60 based on the obtained estimated value of the power consumption. For example, the estimated value of the power consumption in the building 60 is calculated by multiplying the estimated value of the power consumption by the air conditioner 30 in the building 60 by a predetermined coefficient. Here, the predetermined coefficient is a coefficient set based on, for example, statistical data of the ratio of the power consumption of the air conditioner 30 to the power consumption in the building 60. If this coefficient is set according to the season and the type of the building 60, the power consumption in the building 60 can be more accurately estimated. Here, the type of the building 60 is, for example, a type such as an office, a hospital, a school, or a factory.
[0030]
<System effects>
With this air conditioner management system, the power consumption of the air conditioners 31, 32,... Can be easily estimated without installing a special device for measuring the power consumption in the air conditioners 31, 32,. It is possible to do. This makes it possible to measure the power consumption trends of the air conditioners 31, 32,... Over a long period of time. Also, for example, when an abnormality is found in the power consumption of the air conditioners 31, 32,..., The air conditioners 31, 32,. 32,... Can be proposed.
[0031]
Furthermore, this air conditioner management system makes it possible to easily calculate the power consumption in the building 60 without installing a special device for measuring the power consumption. In addition, it is possible to measure the trend of power consumption in the building for a long time, and it is possible to perform more detailed energy diagnosis.
Also, in this air conditioner management system, the power consumption in the building 60 is estimated from the estimated values of the power consumption of the plurality of air conditioners 31, 32,. Here, even if there is an error between the estimated value of the power consumption of each of the air conditioners 31, 32,... And the actual power consumption, the power consumption estimation for the actual power consumption value of the air conditioner 30 is performed. The error ratio of the value does not exceed the worst value of the error ratio of the estimated power consumption value to the actual power consumption value of each of the air conditioners 31, 32,. For this reason, it is possible to perform a sufficiently accurate energy diagnosis as a whole, even though the system is a simple energy diagnosis system.
[0032]
[Second embodiment]
<Overview of the system>
FIG. 2 shows an air conditioner management system according to a second embodiment of the present invention. This air conditioner management system is a system that manages the operation of the air conditioner 30 installed in the building 60, and uses a control device called a local controller 70 to monitor the state of the air conditioner 30, perform start / stop control, set operations, and the like. Do. In addition, information collected by the local controller 70 from the air conditioner 30 and information on operation settings of the air conditioner 30 are notified to the management server 80 via the communication network 50. The management server 80 monitors an abnormality of the air conditioner 30 based on the notified information.
[0033]
In addition, the air conditioner management system can estimate the power consumed in the building 60 and diagnose the energy use state. In the present embodiment, the energy diagnosis will be described.
<System configuration>
The air conditioner management system of the present invention includes an air conditioner 30 installed in a building 60, a local controller 70, and a management server 80 connected to the local controller 70 via a communication network 50. Hereinafter, the configuration of the local controller 70 and the management server 80, which is a difference from the air conditioner management system according to the first embodiment described in FIG. 1, will be described.
[0034]
The local controller 70 is a computer equipped with a CPU 72 and a RAM, a ROM, and the like as a storage unit 71 controlled by the CPU 72. The storage unit 71 includes an information acquisition program 71a.
The management server 80 is a computer equipped with a CPU 82 and a RAM, a ROM, a hard disk, or the like as a storage unit 81 controlled by the CPU 82. The storage unit 21 includes a component power estimation program 81a, an air conditioner power derivation program 81b, and an in-building power calculation program 81c.
[0035]
<Operation of the system>
The energy diagnosis function of the air conditioner management system according to the present invention will be described. The information acquisition program 71a of the local controller 70 acquires information on the air conditioner 31 from the sensor 33h of the outdoor unit provided in the air conditioner 31 and the sensor 34e of the indoor unit. Information is similarly obtained for the other air conditioners 32,. The information acquired by the information acquisition program 71a is notified to the management server 80 via the communication network 50. The management server 80 estimates the power consumption of the power consuming components of the air conditioners 31, 32,... Based on the information notified by the component power estimation program 81a. Further, the air conditioner power derivation program 81b estimates the power consumption of the air conditioners 31, 32,... Based on the estimated power consumption values of the power consuming components estimated by the component power estimation program 81a. Further, the in-building power calculation program 81c calculates the power consumption in the building 60 based on the estimated power consumption values of the air conditioners 31, 32,... Derived by the air conditioner power derivation program 81b. Regarding the respective operations of the component power estimation program 81a, the air conditioner power derivation program 81b, and the in-building power calculation program 81c, the component power estimation program 11a, the air conditioner power derivation program 11b, and the in-building power calculation of the first embodiment are described. The operations are the same as those of the program 21a, and a detailed description thereof will be omitted.
[0036]
<System effects>
In this air conditioner management system, the management server 80 has all the programs necessary for the energy diagnosis. Thus, the diagnosis program can be easily changed and adjusted in order to realize more accurate energy diagnosis.
Also, the air conditioner management system can easily reduce the power consumption of the air conditioners 31, 32,... Without installing a special device for measuring the power consumption in the air conditioners 31, 32,. It can be estimated. This makes it possible to measure the power consumption trends of the air conditioners 31, 32,... Over a long period of time. Also, for example, when an abnormality is found in the power consumption of the air conditioners 31, 32,..., The air conditioners 31, 32,. 32,... Can be proposed.
[0037]
Furthermore, this air conditioner management system makes it possible to easily calculate the power consumption in the building 60 without installing a special device for measuring the power consumption. In addition, it is possible to measure the trend of power consumption in the building for a long time, and it is possible to perform more detailed energy diagnosis.
Also, in this air conditioner management system, the power consumption in the building 60 is estimated from the estimated values of the power consumption of the plurality of air conditioners 31, 32,. Here, even if there is an error between the estimated value of the power consumption of each of the air conditioners 31, 32,... And the actual power consumption, the power consumption estimation for the actual power consumption value of the air conditioner 30 is performed. The error ratio of the value does not exceed the worst value of the error ratio of the estimated power consumption value to the actual power consumption value of each of the air conditioners 31, 32,. For this reason, it is possible to perform a sufficiently accurate energy diagnosis as a whole, even though the system is a simple energy diagnosis system.
[0038]
[Other embodiments]
(1) Modification of local controller 10
In the first embodiment, the information notified from the local controller 10 to the management server 20 is an estimated power consumption value of each of the air conditioners 31, 32,... Derived by the air conditioner power derivation program 11b. did. Here, the system may be such that the total of the estimated power consumption values of the air conditioners 31, 32,... Is calculated by the air conditioner power derivation program 11b, and only the total value is notified to the management server 20.
[0039]
In this case, the amount of information notified from the local controller 10 to the management server 20 can be reduced, and the load on the communication network 50 can be reduced. Even in this case, the management server 20 can calculate the power consumption in the building 60 based on the received information.
(2) Modifications of local controllers 10 and 70
In the first and second embodiments, the estimated value of the power consumption in the building 60 is calculated from the estimated value of the power consumption of the air conditioner 30. Here, a system in which the local controller 10 or the local controller 70 acquires operation information from the electric equipment 40, the lighting equipment 41, the disaster prevention / security equipment 42, or the like is also conceivable. In this case, the in-building power calculation programs 21a and 81c can estimate the power consumption by the electric equipment 40, the lighting equipment 41, the disaster prevention / security equipment 42, and the like.
[0040]
Accordingly, it is possible to more accurately calculate the power consumed in the building 60, and it is possible to perform more detailed energy diagnosis.
(3) Modification of air conditioner 30
In the first and second embodiments, the air conditioners 31, 32,... Provided in the air conditioner 30 have been described as multi-type air conditioners. However, the effects of these embodiments are independent of the type of air conditioner. Therefore, as the air conditioners 31, 32,..., For example, one indoor unit may be connected to one outdoor unit. The air conditioners 31, 32, ... may be different types of air conditioners.
[0041]
(4) Modifications of management servers 20 and 80
When the management servers 20 and 80 can acquire power consumption data in the building 60 from a power company or the like, the following energy diagnosis is performed using the air conditioner management system according to the first embodiment and the second embodiment. It can be carried out.
For example, useless use of the air conditioner 30 can be diagnosed based on a ratio of an estimated value of the power consumption of the air conditioner 30 to power consumption data in the building 60 acquired from a power company or the like.
[0042]
In addition, as described in the above (2), for example, when the power consumption of the air conditioner 30 and the electric equipment 40 can be estimated, if the time variation of the power consumption of the disaster prevention / security equipment 42 can be considered to be small. The time variation of the power consumption data acquired from the power company can be based on the time variation of the power consumption of the lighting equipment 41. In this way, it is possible to make a detailed diagnosis of the power consumption state in the building 60.
[0043]
(5) Modification of air conditioner management system
In the first embodiment and the second embodiment, the case where the air conditioner management system has the function of energy diagnosis has been described. However, the local controllers 10 and 70 do not necessarily have to have a function of performing start / stop control or operation setting of the air conditioner, and may have only a function necessary to execute energy diagnosis.
[0044]
(6) Modified example of air conditioner power derivation programs 11b and 81b
It is also possible for the air conditioner power derivation programs 11b and 81b to derive the power consumption estimates of the air conditioners 31, 32,... Only from the power consumption estimates of the compressor 33a estimated by the component power estimation programs 11a and 81a. It is. In this case, for example, the air conditioner power derivation programs 11b and 81b multiply the air conditioners 31, 32,... By multiplying the estimated power consumption value of the compressor 33a by the component power estimation programs 11a and 81a by a predetermined coefficient. Is derived.
[0045]
Generally, the power consumption of the compressor of an air conditioner accounts for the majority of the power consumption of the air conditioner. Therefore, by estimating the power consumption of the compressor 33a, the power consumption of the air conditioner can be derived sufficiently accurately.
[0046]
【The invention's effect】
In the invention according to claim 1, it is possible to easily estimate the power consumption of the air conditioner without installing a special device for measuring the power consumption in the air conditioner. In addition, it is possible to measure the trend of the power consumption of the air conditioner over a long period of time, and it is possible to perform more detailed energy diagnosis.
[0047]
In the invention according to claim 2, by estimating the power consumption of the compressor sufficiently accurately, it is possible to more accurately derive the power consumption of the air conditioner.
According to the third aspect of the present invention, it is possible to easily calculate the power consumption in a building without installing a special device for measuring the power consumption. In addition, it is possible to measure the trend of power consumption in the building for a long time, and it is possible to perform more detailed energy diagnosis.
[0048]
In the invention according to claim 4, it is possible to easily calculate the power consumption in the building without installing a special device for measuring the power consumption. In addition, it is possible to measure the trend of power consumption in the building for a long time, and it is possible to perform more detailed energy diagnosis.
In the invention according to claim 5, it is possible to more accurately derive the power consumption of the air conditioner by accurately estimating the power consumption of the compressor. Furthermore, if the power consumption of the air conditioner can be derived more accurately, the power consumption in the building can be calculated more accurately.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of an air conditioner management system according to a first embodiment of the present invention.
FIG. 2 is a configuration diagram of an air conditioner management system according to a second embodiment of the present invention.
[Explanation of symbols]
10 Local controller
11a Component power estimation program
11b Air conditioner power derivation program
20 Management server
31, 32, ... air conditioner
60 Building
80 Management server

Claims (5)

Component power estimating means (11a) for estimating a power consumption value of a specific power consuming component of the air conditioners (31, 32,...) Installed in the building (60);
Air conditioner power deriving means for deriving an estimated power consumption value of the air conditioners (31, 32,...) Based on the estimated power consumption value of the power consuming component estimated by the component power estimating means (11a). (11b),
An air conditioner power derivation device (10) comprising: The power consuming component includes a compressor of an air conditioner,
An air conditioner power derivation device (10) according to claim 1. An air conditioner power derivation device (10) according to claim 1 or 2,
An estimated value of power consumption in the building (60) is calculated based on an estimated value of power consumption of the air conditioners (31, 32, ...) derived by the air conditioner power deriving device (10). An in-building power calculator (20);
Energy diagnostic system comprising: Estimate the power consumption value of a specific power consuming component of the air conditioner (31, 32, ...) installed in the building (60), and based on the estimated power consumption value of the power consuming component. Air conditioner power deriving means for deriving an estimated value of power consumption of the air conditioners (31, 32, ...);
An estimated value of power consumption in the building (60) is calculated based on the estimated value of power consumption of the air conditioners (31, 32, ...) derived by the air conditioner power deriving means. Power calculation means;
An energy diagnostic device (80) comprising: The power consuming component includes a compressor of an air conditioner,
The energy diagnostic device (80) according to claim 4.

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