JP5287798B2 - Energy management system and control device - Google Patents

Description

  The present invention relates to an energy management system and a control device.

In recent years, as efforts to protect the global environment such as global warming prevention,
The movement of adjusting the amount of energy demand and supply to control the amount of energy has become widespread.

  For adjusting the demand amount and supply amount of energy, for example, as disclosed in Patent Document 1 (Japanese Patent Laid-Open No. 2005-107901), energy for managing the energy amount (power amount) supplied to a plurality of properties To the management company, the amount of energy that each property can control and the time period during which energy (electric power) can be controlled are presented, or the amount of energy in the property is controlled in response to a request from the energy management company to control the amount of energy Something to do is proposed.

  In the system disclosed in Patent Document 1 (Japanese Patent Application Laid-Open No. 2005-107901), in calculating the amount of energy to be suppressed, the demand-side demand energy amount based on the supply-side suppliable energy amount (suppliable power amount). A value is calculated such that a reserve energy amount (standby power amount) with respect to (demand power amount) is equal to or greater than a predetermined value.

  However, in order to reduce the amount of energy, it is desirable to consider the comfort of the user of the equipment that consumes energy. Further, it is desirable that the amount of energy to be suppressed is obtained more accurately.

  Accordingly, an object of the present invention is to provide an energy management system and a control device that can take into account the comfort of a user of a facility device that consumes energy and can more accurately calculate the amount of energy that can be suppressed when suppressing energy. There is to do.

An energy management system according to a first aspect of the present invention includes an energy management device and a control device. The energy management device is positioned above a plurality of properties, and manages the energy supplied to the equipment installed in each property. The control device controls the equipment of each property. The control device includes an operation state grasping unit, a calculating unit, and a suppressable amount determining unit. The operation status grasping unit grasps the operation status of the equipment. The calculation unit calculates the energy consumption amount and the estimated consumption amount based on an input value by the user of the facility device and / or an actual measurement value of the energy amount that varies depending on the driving situation. The energy consumption amount is the amount of energy consumed by the first control that does not perform energy suppression. The estimated consumption amount is the amount of energy consumed by the second control that performs energy suppression according to conditions. The suppression possible amount determination unit determines a plurality of energy suppression possible amounts for each condition of the facility equipment, and an energy suppression possible amount based on the energy consumption amount and the estimated consumption amount. Further, the calculation unit further calculates a fluctuation value of the energy amount of the equipment that is not subjected to the second control among the equipment. In addition, the suppression possible amount determination unit determines the energy suppression possible amount based further on the variation value.

In the energy management system according to the first aspect of the present invention, the user's intention can be reflected when the energy consumption amount and the estimated consumption amount are calculated based on the user input value. Control in consideration of comfort level can be performed. In addition, when calculating energy consumption and estimated consumption based on measured values of energy, the energy consumption and estimated consumption can be calculated more accurately, resulting in more accurate energy suppression possible amounts. Can be determined. In addition, when the energy consumption amount and the estimated consumption amount are calculated based on the input value of the user and the actual measurement value of the energy amount, a more accurate energy suppression possible amount can be determined while considering the user's comfort. . Moreover, for example, when the fluctuation value of the energy amount of the facility device for which the second control is not performed is large, there is a concern that the amount of energy suppression that is presented may be exceeded. On the other hand, by calculating the fluctuation value of the energy amount of the equipment that is not subjected to the second control, it is possible to prevent the presented energy suppression possible amount from being exceeded.

  An energy management system according to a second aspect of the present invention is the energy management system according to the first aspect, wherein the calculation unit calculates an energy consumption amount based on at least an actual measurement value, and calculates an estimated consumption amount at least for a user. It calculates based on the input value by.

  In the energy management system according to the second aspect of the present invention, it is possible to determine a more accurate energy suppression possible amount while considering user comfort.

  The energy management system which concerns on the 3rd viewpoint of this invention is an energy management system which concerns on a 1st viewpoint or a 2nd viewpoint, Comprising: The input value by a user is at least one of an allowable driving capability value and a variable value. . The allowable operating capacity value is an operating capacity value of the equipment that can be allowed when the second control is executed. The variable value is a value in an arithmetic expression for calculating an allowable driving ability value. The control device further includes a driving capability setting unit that sets an allowable driving capability value.

  In the energy management system according to the third aspect of the present invention, when the user inputs either the allowable driving capability value or the variable value in the arithmetic expression for calculating the allowable driving capability value, the user's intention (comfort Control) can be performed.

  The energy management system which concerns on the 4th viewpoint of this invention is an energy management system which concerns on a 3rd viewpoint, Comprising: A control apparatus further has a correction part which corrects at least the input value by a user by learning.

  In the energy management system according to the fourth aspect of the present invention, it is possible to perform more suitable control for the user by correcting the input value by the user by learning such as evaluation of the user's comfort level, for example. it can.

  An energy management system according to a fifth aspect of the present invention is the energy management system according to any one of the first aspect to the fourth aspect, and the equipment includes an air conditioner. The control device further includes a control command generating unit that generates a control command for performing control for each indoor unit of the air conditioner.

  For example, when controlling the whole air conditioner uniformly, if 2nd control of a certain indoor unit is cancelled | released, 2nd control of all the indoor units will be cancelled | released. In this case, there is a concern that the amount of energy suppression possible for the entire property will decrease.

  Therefore, in the energy management system according to the fifth aspect of the present invention, by generating a control command so that control can be performed for each indoor unit, it is possible to prevent a decrease in opportunities for second control, It is also possible to prevent a decrease in the amount of energy suppression possible.

The energy management system according to a sixth aspect of the present invention is the energy management system according to the third aspect or the fourth aspect , wherein the operating capacity setting unit sets an allowable operating capacity value for each indoor unit of the air conditioner, The calculation unit calculates an energy consumption amount and an estimated consumption amount for each indoor unit.

  For example, when controlling the whole air conditioner uniformly, the case where it controls according to the living room which requires the most energy amount is assumed. In this case, there is a concern that the amount of energy suppression can be reduced as a whole property.

  Therefore, in the energy management system according to the sixth aspect of the present invention, it is possible to calculate the energy consumption amount and the estimated consumption amount for each indoor unit, thereby suppressing a decrease in the energy suppression possible amount.

An energy management system according to a seventh aspect of the present invention is the energy management system according to any one of the first to sixth aspects , wherein the second control is included in equipment that is not subjected to the second control. Equipment that is in the state of the second non-controllable time during which it cannot be performed is included. The control device further includes a second uncontrollable time occurrence predicting unit that predicts the occurrence of the second uncontrollable time.

In the energy management system according to the seventh aspect of the present invention, it is possible to predict a sudden change in the energy amount by predicting the occurrence of the second uncontrollable time. Therefore, it is possible not to exceed the presented energy suppression possible amount.

An energy management system according to an eighth aspect of the present invention includes an energy management device and a control device. The energy management device is positioned above a plurality of properties, and manages the energy supplied to the equipment installed in each property. The control device controls the equipment of each property. The control device includes a driving condition grasping unit, a calculating unit, a suppressable amount determining unit, and a suppressable amount presenting unit. The operation status grasping unit grasps the operation status of the equipment. The calculation unit calculates the energy consumption amount and the estimated consumption amount based at least on the input value by the user of the facility device and / or the estimated value of the energy amount based on the operation schedule of the facility device. The energy consumption amount is the amount of energy consumed by the first control that does not perform energy suppression. The estimated consumption amount is the amount of energy consumed by the second control that performs energy suppression according to conditions. In addition, the calculation unit further calculates a fluctuation value of the energy amount of the equipment device that is not subjected to the second control among the equipment devices, and the suppression possible amount determination unit further calculates the energy suppression possible amount based on the fluctuation value. decide.

In the energy management system according to the eighth aspect of the present invention, when the energy consumption amount and the estimated consumption amount are calculated based on the input value of the user, the user's intention can be reflected. Control in consideration of comfort level can be performed.

In addition, when calculating energy consumption and estimated consumption based on the estimated amount of energy based on the operation schedule of the equipment, the accuracy is slightly inferior compared to using measured values. Since the calculation is based on the schedule, the energy consumption amount and the estimated consumption amount can be calculated approximately accurately, and as a result, the approximately accurate energy suppression possible amount can be determined. In addition, when calculating the energy consumption amount and the estimated consumption amount based on the input value of the user and the estimated value of the energy amount based on the operation schedule of the equipment, it is substantially accurate while considering the comfort of the user. The amount of energy suppression can be determined. Moreover, for example, when the fluctuation value of the energy amount of the facility device for which the second control is not performed is large, there is a concern that the amount of energy suppression that is presented may be exceeded. On the other hand, by calculating the fluctuation value of the energy amount of the equipment that is not subjected to the second control, it is possible to prevent the presented energy suppression possible amount from being exceeded.

A control device according to a ninth aspect of the present invention includes an operating state grasping unit, a calculating unit, and a suppressable amount determining unit. The operation status grasping unit grasps the operation status of the equipment. The calculation unit calculates the energy consumption amount and the estimated consumption amount based on an input value by the user of the facility device and / or an actual measurement value of the energy amount that varies depending on the driving situation. The energy consumption amount is the amount of energy consumed by the first control that does not perform energy suppression. The estimated consumption amount is the amount of energy consumed by the second control that performs energy suppression according to conditions. The suppression possible amount determination unit determines a plurality of energy suppression possible amounts for each condition of the facility equipment, and an energy suppression possible amount based on the energy consumption amount and the estimated consumption amount. In addition, the calculation unit further calculates a fluctuation value of the energy amount of the equipment device that is not subjected to the second control among the equipment devices, and the suppression possible amount determination unit further calculates the energy suppression possible amount based on the fluctuation value. decide.

In the control device according to the ninth aspect of the present invention, when the energy consumption amount and the estimated consumption amount are calculated based on the input value of the user, the user's intention can be reflected, so that the user's comfort It is possible to perform control in consideration of the degree. In addition, when calculating energy consumption and estimated consumption based on measured values of energy, the energy consumption and estimated consumption can be calculated more accurately, resulting in more accurate energy suppression possible amounts. Can be determined. In addition, when the energy consumption amount and the estimated consumption amount are calculated based on the input value of the user and the actual measurement value of the energy amount, a more accurate energy suppression possible amount can be determined while considering the user's comfort. . Moreover, for example, when the fluctuation value of the energy amount of the facility device for which the second control is not performed is large, there is a concern that the amount of energy suppression that is presented may be exceeded. On the other hand, by calculating the fluctuation value of the energy amount of the equipment that is not subjected to the second control, it is possible to prevent the presented energy suppression possible amount from being exceeded.

In the energy management system which concerns on the 1st viewpoint of this invention, the comfort of the user of the equipment which consumes energy can be considered, and the energy amount which can be suppressed can be calculated more correctly. Moreover, it can be made not to exceed the presented energy suppression possible amount.

  In the energy management system according to the second aspect of the present invention, it is possible to determine a more accurate energy suppression possible amount while considering user comfort.

  In the energy management system according to the third aspect of the present invention, it is possible to perform control in consideration of the user's intention (comfort level).

  In the energy management system according to the fourth aspect of the present invention, it is possible to perform more suitable control for the user.

  In the energy management system which concerns on the 5th viewpoint of this invention, the reduction | decrease in the opportunity of 2nd control can be prevented, and the reduction | decrease in the energy suppression possible amount as the whole property can also be prevented.

  In the energy management system according to the sixth aspect of the present invention, a decrease in the amount of energy suppression can be suppressed.

In the energy management system according to the seventh aspect of the present invention, the presented energy suppression possible amount can be prevented from being exceeded.

In the energy management system according to the eighth aspect of the present invention, it is possible to consider the comfort of the user of the equipment that consumes energy, or to calculate the amount of energy that can be suppressed substantially accurately. Moreover, it can be made not to exceed the presented energy suppression possible amount.

With the control device according to the ninth aspect of the present invention, it is possible to consider the comfort of the user of the equipment that consumes energy, or to calculate the amount of energy that can be suppressed more accurately. Moreover, it can be made not to exceed the presented energy suppression possible amount.

1 is a schematic configuration diagram of an energy management system according to an embodiment of the present invention. The schematic block diagram of a high-order controller. The schematic block diagram of a low-order controller. The figure which shows an example of the conditions memorize | stored in the condition memory area. The flowchart which shows the flow of a process in a low-order controller. The flowchart which shows the flow of the determination process of energy suppression possible quantity. The schematic block diagram of the low-order controller which concerns on the modification 1B. The schematic block diagram of the low-order controller which concerns on the modification 1G.

  Hereinafter, an energy management system 100 according to an embodiment of the present invention will be described with reference to the drawings.

(1) Overall Schematic Configuration of Energy Management System 100 FIG. 1 is a schematic configuration diagram of an energy management system 100 according to an embodiment of the present invention.

  The energy management system 100 includes a power company 1 that supplies energy to buildings A and B, such as buildings and factories, and a plurality of installed equipment (air conditioners 40, 40,..., 40, 40, ... from the electric power company 1 by adjusting the supply amount for the energy demand with the above-mentioned property A, B where the demand for energy is performed by a water heater, lighting, and other devices that generate power) This is a system for managing energy supplied to the properties A and B.

  More specifically, in the energy management system 100, first, each property A, B (specifically, lower controllers 30, 30 described later) is the electric power company 1 (specifically, an upper controller described later). 10) A plurality of energy suppression possible amounts indicating how much energy amount can be suppressed are presented. Next, the electric power company 1 receives a plurality of energy-suppressable amounts, selects one of the energy-suppressible amounts, and suppresses the energy amount based on the selected energy-suppressable amount. We request each property A and B. Note that the power company 1 may not make the request.

  The energy management system 100 is mainly installed in the electric power company 1, and is installed in a host controller (corresponding to an energy management device) 10 for managing and controlling the amount of energy consumed in the properties A and B, and in each property A and B. And a lower controller (corresponding to a control device) 30 that directly manages and controls the amount of energy of the air conditioners 40, 40,... Installed in each property A, B. In each property A, B, in addition to the air conditioners 40, 40,..., A power source 6 that supplies power to the air conditioners 40, 40,. A power meter 7 for measuring the amount of energy supplied to is installed.

  The air conditioners 40, 40, ... are outdoor units 41, 41, ..., indoor units 42, 42, ..., outdoor units 41, 41, ..., and indoor units 42, 42. ,... Are connected to refrigerant piping (not shown). The air conditioners 40, 40,... In FIG. 1 are assumed to be multi-type in this embodiment, but may be pair-type. In FIG. 1, only two properties A and B are clearly shown as properties for which the power company 1 manages the amount of energy, but the number of properties is not limited to this.

  The upper controller 10 and the lower controllers 30 and 30 are connected via the Internet 80a. In each property A, B, the air conditioners 40, 40,... And the lower controller 30 are connected via a dedicated control line 80b.

  In the energy management system 100, in the respective properties A and B, the upper controller 10 and the lower controller 30 exchange data such as control commands in the respective properties A and B, thereby being consumed by the properties A and B. The amount of energy to be managed is managed.

  Hereinafter, the structure of each part which mainly comprises the energy management system 100 is demonstrated, referring drawings suitably.

(2) Configuration of Each Unit (2-1) Configuration of Host Controller 10 FIG. 2 is a schematic configuration diagram of the host controller 10. Hereinafter, the configuration of the host controller 10 will be described with reference to FIG.

  As shown in FIG. 2, the host controller 10 mainly includes a communication unit 11, a display unit 12, an input unit 13, a storage unit 14, and a control unit 15.

  The communication unit 11 is a network interface that enables the host controller 10 to be connected to the Internet 80a.

  The display unit 12 is mainly composed of a display. On the display unit 12, a management screen showing various information stored in the storage unit 14 to be described later is displayed.

  The input unit 13 mainly includes operation buttons, a keyboard, a mouse, and the like, and receives input from an administrator or the like. When an administrator or the like performs an input operation on the input unit 13, internal processing is executed by the control unit 15 described later.

  The storage unit 14 is mainly composed of a hard disk or the like, and holds a managed property storage area 14a, a property information storage area 14b, and a presentation content storage area 14c.

(2-1-1) Managed property storage area 14a
In the managed property storage area 14a, managed properties A and B of the electric power company 1 are stored. Specifically, information on the names of the properties A and B, the scales of the properties A and B, the necessary minimum energy amount, and the like are stored.

(2-1-2) Property information storage area 14b
The property information storage area 14b stores property information related to properties A and B including information related to energy consumption and the like sent from lower controllers 30, 30 described later. The information on energy consumption is information on the amount of energy consumed in each property A and B in a predetermined period.

(2-1-3) Presentation content storage area 14c
In the presentation content storage area 14c, information regarding a plurality of energy suppression possible amounts presented by the lower controllers 30 and 30 is stored. In addition, the information regarding the several energy suppression possible amount shown from the low-order controllers 30 and 30 is received by the presentation reception part 15a mentioned later.

  The control unit 15 mainly includes a CPU, a ROM, a RAM, and the like. The control unit 15 functions as the presentation reception unit 15a, the selection command transmission unit 15b, and the like by reading and executing the program stored in the storage unit 14.

(2-1-4) Presentation accepting unit 15a
The presentation receiving unit 15a receives a plurality of energy suppression possible amounts sent from the properties A and B.

(2-1-5) Selection command transmission unit 15b
The selection command transmission unit 15b includes the energy suppression possible amount of 1 requested to each property A and B among the plurality of energy suppression possible amounts sent from the property A and B that the presentation receiving unit 15a periodically receives. A command (selection command) corresponding to the determined content is transmitted to each of the properties A and B.

(2-2) Configuration of Lower Controllers 30 and 30 FIG. 3 is a schematic configuration diagram of the lower controllers 30 and 30.

  Hereinafter, the lower controllers 30 and 30 installed in the properties A and B will be described with reference to FIG. One subordinate controller 30, 30 is installed in each property A, B. In the following description, the controller 30 installed in the property A will be described, but the lower controller 30 installed in the property B is assumed to have the same configuration.

  In addition, the control part 36 of the low-order controller 30 is controlling for every air conditioner 40,40, ... (indoor unit 42,42, ...). By controlling each indoor unit 42, 42,... Independently, air conditioning corresponding to each room in which the individual indoor units 42, 42,. Control can be performed. Here, examples of the control include execution / non-execution of energy suppression control (described in the calculation unit 36cd), relaxation / enhancement of energy suppression control, and the like.

  As shown in FIG. 3, the lower controller 30 mainly includes a communication unit 31, a display unit 32, an input unit 33, a timer unit 34, a storage unit 35, and a control unit 36.

  The communication unit 31 is an interface that enables the lower controller 30 to be connected to the Internet 80a.

  The display unit 32 mainly includes a display. In the display unit 32, the operating state of the air conditioners 40, 40,... (Operation / stop state, operation mode (cooling mode, heating mode, etc.), wind direction, air volume, humidity, suction temperature, set temperature, etc.) is displayed. A screen is displayed.

  The input unit 33 mainly includes a touch panel that covers the display. When an administrator or the like touches a button on the touch panel, a control process corresponding to the button is executed by the control unit 36 described later.

  The timer unit 34 measures various times. Specific operations will be described later.

  The storage unit 35 is composed of a hard disk or the like, and mainly holds an operation state storage area 35a, a condition storage area 35b, a control information storage area 35c, a meter value storage area 35d, and a comfort determination result storage area 35e. doing.

(2-2-1) Operation status storage area 35a
The operation status storage area 35a stores the operation status of each air conditioner 40, 40,... The operation status of the air conditioners 40, 40,... Includes the operation / stop state of the air conditioners 40, 40,..., The set temperature, the operation mode such as cooling / heating, the operation time, the operation rate, and the operation time. Of the outdoor units 41, 41,... And the state values of the various units of the indoor units 42, 42,... (Fan rotation speed, compressor rotation speed, expansion valve opening, refrigerant temperature, Refrigerant pressure, etc.), outdoor temperature, room temperature, suction temperature, degree of deviation between set temperature and room temperature, execution / non-execution of energy suppression control, and the like. Note that various temperatures, pressures, and the like included in the operation status are detected by various sensors.

(2-2-2) Condition storage area 35b
FIG. 4 is a diagram illustrating an example of the conditions stored in the condition storage area 35b.

  In the condition storage area 35b, conditions for presenting a plurality of energy suppression possible amounts to the host controller 10 are stored for each of the air conditioners 40, 40,. As shown in FIG. 4, the conditions for presenting a plurality of energy suppression possible amounts include time for executing energy suppression control (that is, duration of energy suppression control) (minutes), and operation during energy suppression control. The relationship with ability (%) is stored in association. The operating capacity at the time of energy suppression control is the operating capacity of the air conditioners 40, 40,... That can be permitted when the energy suppression control is executed, relative to the operating capacity at the time of normal operation of the air conditioners 40, 40,. (Hereinafter, referred to as an allowable operating capacity value, which corresponds to an allowable operating capacity value), and is changed by adjusting the frequency of the compressor accommodated in the outdoor units 41, 41,.

  Here, the allowable driving ability included in the condition uses an input value input by the user, and is set by an allowable driving capacity setting unit 36m described later.

  Here, the energy suppression control is control for realizing an energy suppression possible amount presented to the host controller 10.

(2-2-3) Control information storage area 35c
The control information storage area 35c stores the contents of the control commands transmitted to the air conditioners 40, 40,. Specifically, information on the energy suppression possible amount selected by the host controller 10 among a plurality of energy suppression possible amounts presented by the later-described suppression possible amount presentation unit 36f is stored. The content of the control command includes the allowable driving capability and the duration of the energy suppression control (that is, the command content indicating under which conditions the energy suppression control is performed), the energy suppression control start time, the energy suppression control end time, and the like. .

(2-2-4) Meter value storage area 35d
The meter value storage area 35d stores the meter values for each of the air conditioners 40, 40,... Acquired by the meter value acquisition unit 36b, which will be described later, and the overall meter values of the air conditioners 40, 40,. Is done.

(2-2-5) Comfort determination result storage area 35e
In the comfort determination result storage area 35e, the comfort determination result input via the input unit 33 by the user or administrator of the equipment (hereinafter referred to as a user) is stored in the air conditioners 40, 40,. -Stored for each (indoor unit 42, 42, ...). Specifically, in the comfort determination result storage area 35e, when the user feels discomfort by executing the energy suppression control, a determination result indicating that the discomfort is felt is stored.

  The control unit 36 includes a CPU, a ROM, a RAM, and the like. Mainly, the driving state grasping unit 36a, the meter value acquisition unit 36b, the calculation unit 36cd (energy consumption calculation unit 36c, estimated consumption calculation unit 36d), and can be suppressed. An amount determining unit 36e, a suppressable amount presenting unit 36f, a presentation control unit 36g (first processing unit 36ga, second processing unit 36gb), a selection command receiving unit 36h, a control command generating unit 36i, a control command transmitting unit 36j, an allowable operation It functions as a capability acquisition unit 36k, a correction unit 36l, an allowable driving capability setting unit 36m, and the like.

  Hereinafter, each function of the control unit 36 will be described.

(2-2-6) Driving condition grasping part 36a
The driving condition grasping unit 36a grasps the driving condition of each air conditioner 40, 40,... At a predetermined time interval (in this embodiment, every five minutes). The driving situation grasping unit 36a stores the driving situation in the above-described driving situation storage area 35a.

(2-2-7) Meter value acquisition unit 36b
The meter value acquisition unit 36b acquires the meter value (data related to the energy amount) measured by the power meter 7 at a predetermined time interval (for example, every 1 minute). The meter value acquisition unit 36b stores the meter value in the meter value storage area 35d described above.

(2-2-8) Calculation unit 36cd
The calculation unit 36cd calculates an energy consumption amount and an estimated consumption amount for each of the air conditioners 40, 40,. The calculation here includes prediction and estimation. The energy consumption amount is the energy amount of the air conditioners 40, 40,... Consumed in the current normal control (corresponding to the first control) in which energy suppression control is not performed. The estimated consumption is the air conditioners 40, 40,... That are consumed when executing the energy suppression control (corresponding to the second control) that suppresses energy according to conditions such as the conditions A to C shown in FIG.・ ・ The amount of energy.

  Specifically, the calculation unit 36cd functions as an energy consumption calculation unit 36c that calculates energy consumption and an estimated consumption calculation unit 36d that calculates estimated consumption. Hereinafter, these operations will be briefly described.

(2-2-8-1) Energy consumption calculation unit 36c
The energy consumption amount calculation unit 36c includes the current operation status of each air conditioner 40, 40,... Grasped by the operation status grasping unit 36a and each air conditioner 40, 40 stored in the meter value storage area 35d. ,... Based on the meter value (corresponding to the actual measurement value), the energy consumption amount of each air conditioner 40, 40,. It is calculated every time (for example, 30 minutes). Here, the predetermined time refers to the duration (for example, 60 minutes, 30 minutes, and 15 minutes as shown in FIG. 4) stored in the condition storage area 35b. That is, in this case, the energy consumption calculation unit 36c does not change the current setting, and each energy when the control of each air conditioner 40, 40,... Is performed for 60 minutes, 30 minutes, and 15 minutes. The consumption is calculated.

(2-2-8-2) Estimated consumption calculator 36d
The estimated consumption amount calculation unit 36d estimates the estimated consumption for each air conditioner 40, 40,... When the air conditioners 40, 40,. The amount is calculated every predetermined time (for example, 30 minutes). Specifically, the estimated consumption calculation unit 36d operates each air conditioner 40, 40,... For 60 minutes with an allowable driving capacity of 80% and operates for 30 minutes with an allowable driving capacity of 60%. In this case, the estimated consumption for each case of driving at an allowable driving capacity of 40% for 15 minutes is calculated. That is, the estimated consumption calculation unit 36d calculates the estimated consumption of each air conditioner 40, 40,... For each condition as shown in FIG. Here, the estimated consumption is determined by the product of the rated power (kW) and the allowable driving capacity (%).

(2-2-9) Suppressable amount determination unit 36e
The controllable amount determination unit 36e is configured to use the air conditioners 40, 40,... Based on the energy consumption calculated by the energy consumption calculation unit 36c and the estimated consumption calculated by the estimated consumption calculation unit 36d. The energy suppression possible amount is determined every predetermined time (for example, 30 minutes). Specifically, the controllable amount determination unit 36e calculates the difference between the energy consumption amount according to the current setting and the energy consumption amount (estimated consumption amount) when the current setting is changed according to the condition for each duration. Is determined as an energy-suppressible amount (energy-suppressable amount = energy consumption-estimated consumption). Therefore, the energy suppression possible amount W (kW) of the entire air conditioner 40, 40,... Is obtained by the formula: W = Σ (energy consumption amount−estimated consumption amount).

  Specifically, the suppression possible amount determination unit 36e determines the energy suppression possible amount when the air conditioners 40, 40,... Are controlled according to the conditions stored in the condition storage area 35b. That is, here, the controllable amount determination unit 36e determines the three types of energy controllable amounts corresponding to each condition (a condition that the energy suppression control is continued for what percentage of the allowable operating capacity) and the air conditioners 40, 40. , ... determined each time.

(2-2-10) Suppressable amount presentation unit 36f
The suppression possible amount presentation unit 36f displays a plurality of energy suppression possible amounts for each condition for each of the air conditioners 40, 40,... Determined by the suppression possible amount determination unit 36e every predetermined time (for example, 30 minutes). To the host controller 10. Specifically, the suppression possible amount presentation unit 36f presents the plurality of energy suppression possible amounts for each of the air conditioners 40, 40,... To the upper controller 10 by sending them to the upper controller 10 via the communication unit 31. doing.

  The suppression possible amount presentation unit 36f presents the energy suppression possible amount in accordance with the control of the presentation control unit 36g described later. This will be described in the presentation control unit 36g.

(2-2-11) Presentation control unit 36g
The presentation control unit 36g controls the presentation of the energy suppression possible amount by the above-described suppression possible amount presentation unit 36f. Specifically, the presentation control unit 36g functions as a first processing unit 36ga and a second processing unit 36gb.

  The first processing unit 36ga restricts the presentation of the energy suppression possible amount by the suppression possible amount presentation unit 36f. Specifically, the first processing unit 36ga presents the energy suppression possible amount by the suppression possible amount presentation unit 36f for a predetermined time after a control command related to energy suppression control is generated by the control command generation unit 36i described later. Limit. Here, the predetermined time after the control command related to the energy suppression control is generated is a duration time during which the energy suppression control is continued. When the first processing unit 36ga restricts the presentation of the energy suppression possible amount, the above-described suppression possible amount presentation unit 36f presents a response with a zero answer or an energy suppression possible amount of 0 kW to the host controller 10. .

  On the other hand, the second processing unit 36gb permits the presentation of the energy suppression possible amount by the suppression possible amount presentation unit 36f. Specifically, during the time when the energy suppression control is not being executed, the second processing unit 36gb allows the suppression possible amount presentation unit 36f to present the energy suppression possible amount.

  As long as presentation is not limited by the first processing unit 36ga, the suppression possible amount presentation unit 36f presents the energy suppression possible amount to the host controller 10 every predetermined time (for example, 30 minutes). To do.

(2-2-12) Selection command receiving unit 36h
The selection command receiving unit 36h receives a selection command sent from the host controller 10. The selection command is a signal indicating the energy suppression possible amount selected by the host controller 10 among the plurality of energy suppression possible amounts presented by the suppression possible amount presentation unit 36f.

(2-2-13) Control command generator 36i
The control command generation unit 36i generates a control command that realizes an energy-suppressible amount based on the selection command received by the selection command reception unit 36h. Here, the control command generator 36i can control each of the air conditioners 40, 40,... So that the indoor units 42, 42,. A control command is generated for each (indoor unit 42, 42,...).

(2-2-14) Control command transmitter 36j
The control command transmission unit 36j transmits the control commands generated by the control command generation unit 36i to the air conditioners 40, 40,. Thereby, the control part (not shown) of each air conditioner 40, 40, ... performs control based on each control command.

(2-2-15) Allowable driving ability acquisition unit 36k
The allowable driving capacity acquisition unit 36k acquires the allowable driving capacity of each of the air conditioners 40, 40,.

  Specifically, when the allowable driving capability of the air conditioners 40, 40,... Is input by the user via the input unit 33, the allowable driving capability acquisition unit 36k receives the input information (that is, the air conditioners 40, 40,. 40,... (Acceptable driving capacity information). Here, the user inputs the allowable driving capacity for each duration of the energy suppression control. And the allowable driving capability acquisition part 36k acquires the allowable driving capability for every duration of energy suppression control.

  Specifically, as shown in FIG. 4, when the condition for setting the duration of energy suppression control to 60 minutes, 30 minutes, and 15 minutes is stored in the condition storage area 35b, the energy suppression control is performed for 60 minutes, The allowable driving capability for each of the cases where the operation continues for 30 minutes and 15 minutes is input by the user. And the allowable driving capability acquisition part 36k acquires the allowable driving capability for every continuation time of energy suppression control.

  Therefore, when the allowable driving capability acquisition unit 36k acquires the allowable driving capability by the user's input, the conditions A to C shown in FIG. 4 are input with the allowable driving capability of 80% when the duration is 60 minutes. This is a condition when the allowable driving capacity when the time is 30 minutes is input as 60% and the allowable driving capacity when the duration is 15 minutes is input as 40%.

(2-2-16) Correction unit 36l
Based on the determination result of the user's comfort stored in the comfort determination result storage area 35e, the correction unit 36l learns under what conditions the user feels uncomfortable when performing the energy suppression control. As a result, the input value of the user, and thus the permissible operating capacity, is corrected for each air conditioner 40, 40,. In addition, the allowable driving capability of the air conditioners 40, 40,... Corrected by the correcting unit 36l is acquired by the allowable driving capability acquiring unit 36k.

(2-2-17) Allowable driving capacity setting unit 36m
The allowable driving capacity setting unit 36m sets the allowable driving capacity acquired by the allowable driving capacity acquisition unit 36k for each of the air conditioners 40, 40,. Here, the allowable driving capacity setting unit 36m sets the allowable driving capacity for each duration of the energy suppression control. Specifically, the allowable driving capacity setting unit 36m stores the acquired allowable driving capacity in the condition storage area 35b held by the storage unit 35 for each duration of energy suppression control. That is, the conditions stored in the condition storage area 35b are periodically updated by the allowable driving capacity setting unit 36m.

(3) Control Process Performed by Energy Management System 100 FIG. 5 is a flowchart showing a process flow in the lower controller 30. FIG. 6 is a flowchart showing the flow of the process for determining the energy suppression possible amount.

  Hereinafter, the flow of processing in the lower controller 30 that exhibits the above-described functions will be described with reference to FIGS. 5 and 6.

  As shown in FIG. 5, in step S101, the suppression possible amount determination unit 36e determines a plurality of energy suppression possible amounts for each condition.

  Here, the determination process of the energy suppression possible amount in step S101 will be described with reference to FIG.

  As shown in FIG. 6, first, in step S111, the driving status grasping unit 36a grasps the driving status of each of the air conditioners 40, 40,. Next, in step S112, the meter value acquisition unit 36b acquires the meter values of the air conditioners 40, 40,... Measured by the power meter 7. Next, in step S113, the energy consumption calculation part 36c calculates the energy consumption of each air conditioner 40, 40, .... Next, in step S114, the estimated consumption calculation unit 36d calculates the estimated consumption of each air conditioner 40, 40,. Next, in step S115, the suppression possible amount determination unit 36e determines the energy suppression possible amount of each air conditioner 40, 40,... Has been decided. Then, the process proceeds to step S102.

  In step S102, the suppression possible amount presentation unit 36f presents a plurality of energy suppression possible amounts to the host controller 10.

  At this time, the controllable amount presentation unit 36f further presents to the host controller 10 a selection command reception valid time during which the selection command sent from the host controller 10 can be received.

  In step S103, the control command generation unit 36i determines whether the selection command receiving unit 36h has received a selection command from the host controller 10. When it determines with having received, it transfers to step S104, and on the other hand, when determining with having not received, the process of step S103 is repeated.

  Here, the timer unit 34 measures the time from when the suppression possible amount presentation unit 36f presents a plurality of energy suppression possible amounts to the host controller 10 until the selection command reception valid time ends. When the selection command receiving unit 36h receives a selection command from the host controller 10 within the selection command reception valid time after presenting the plurality of energy suppression possible amounts, the process proceeds to step S104, and the plurality of energy suppression possible amounts are determined. If it is within the selection command reception valid time after the presentation, the selection command reception unit 36h stands by until the selection command is received (that is, the process of step S103 is performed again).

  Therefore, when the selection command receiving unit 36h does not receive the selection command from the host controller 10 within the selection command reception valid time after presenting a plurality of energy suppression possible amounts, the process returns to step S101 again and thereafter. Processing will be performed. That is, in step S103, when the selection command acceptance valid time has not elapsed since the plurality of energy suppression possible amounts have been presented, the process waits until the selection command acceptance unit 36h accepts the selection command (the process of step S103 is performed). Although not shown, when the selection command acceptance valid time has elapsed since a plurality of energy suppression possible amounts have been presented, the process returns to step S101 to perform subsequent processing.

  Here, when the selection command acceptance effective time has elapsed after the amount of energy suppression possible is presented, the flag is set so that the selection command acceptance unit 36h does not accept the selection command from the host controller 10. .

  In step S104, the control command generator 36i generates a control command based on the selection command. Then, it progresses to step S105 and the control command transmission part 36j transmits the said control command to each air conditioner 40,40, ....

(4) Features (4-1)
In the present embodiment, the calculation unit 36cd calculates the energy consumption amount of each air conditioner 40, 40,... And the estimated consumption amount of each air conditioner 40, 40,. It calculates based on the meter value (actual value) of the energy amount which fluctuates according to the operating condition of air conditioners 40, 40,. Specifically, the energy consumption calculation unit 36c displays the energy consumption as the current operation status of each air conditioner 40, 40,... And the latest meter of each air conditioner 40, 40,. It is calculated based on the value (actual value). Moreover, the estimated consumption calculation part 36d calculates the estimated consumption of each air conditioner 40, 40, ... when energy suppression control is performed on the conditions based on a user's input value (allowable driving ability value). ing. And the suppression possible quantity determination part 36e is based on these energy consumption and estimated consumption, and each energy suppression machine 40,40, ... and the air conditioning machine 40,40, ... the energy suppression possible quantity of the whole. Has been decided.

  Here, since the energy suppression control of the air conditioners 40, 40,... Is performed on the condition based on the user input value, the user's intention (comfort level) is performed while suppressing the energy of each property A and B as a whole. It is possible to perform air conditioning control in consideration of

  Further, since the latest meter value is used in calculating the energy consumption, the energy consumption can be calculated as accurately as possible.

  As a result, the energy management system 100 takes into account the comfort of the user and takes energy as close as possible to the amount of energy that can be suppressed as accurately as possible, that is, energy consumption based on a request (selection command) from the host controller 10. The amount that can be suppressed can be determined.

(4-2)
In the present embodiment, an allowable driving capability that is an allowable driving capability of the air conditioners 40, 40,... Is input by the user via the input unit 33. Then, the allowable driving capability input unit 36k acquires the allowable driving capability input by the user, and the allowable driving capability setting unit 36m stores it in the condition storage area 35b.

  Thereby, the air-conditioning control which considered the user's comfort level can be performed.

(4-3)
In the present embodiment, the correction unit 36l corrects the input value (allowable driving ability value) by the user by learning the determination result of the user's comfort.

  The correction unit 361 learns the relationship between the energy suppression control and the comfort level of the user, so that the air conditioning control that is more suitable for the user can be performed. Therefore, user comfort is improved.

  Moreover, the correction | amendment part 36l corrects the input value by learning, and can consider the fluctuation | variation of the air-conditioning load in a room by the fluctuation | variation of a season.

(4-4)
For example, when energy suppression control is uniformly performed for a plurality of air conditioners (indoor units) in each property, when the energy suppression control of a certain indoor unit is canceled, the energy suppression control of all the indoor units is canceled. If the energy suppression control of all indoor units is released, the chance of energy suppression control is reduced in each property, so it is assumed that the amount of energy suppression possible for each property as a whole is also reduced.

  Therefore, in the present embodiment, the control command generator 36i generates a control command for performing control for each of the indoor units 42, 42,... Of the air conditioners 40, 40,. That is, the lower controller 30 performs control (execution / non-execution of energy suppression control, relaxation / enhancement of energy suppression control, etc.) for each air conditioner 40, 40,... (Each indoor unit 42, 42,...). )It is carried out.

  By controlling the air conditioners 40, 40,... (Indoor units 42, 42,...) Temporarily, the energy suppression control of some indoor units 42, 42,. Can be released. Thereby, the reduction | decrease of the opportunity of energy suppression control can be prevented, and the reduction | decrease of the energy suppression possible amount as the property A and B whole can also be prevented.

  In addition, for example, when energy suppression control is uniformly performed for a plurality of air conditioners (indoor units) in each property, control may be performed in accordance with the room with the highest priority (the most energy is required). Therefore, there is a concern that the amount of energy suppression possible for the entire property will decrease.

  Therefore, in this embodiment, the allowable driving capacity setting unit 36m sets the allowable driving capacity for each of the air conditioners 40, 40,... And for each duration of the energy suppression control. Further, the calculation unit 36cd (the energy consumption calculation unit 36c and the estimated consumption calculation unit 36d) calculates the energy consumption and the estimated consumption for each of the air conditioners 40, 40,.

  Therefore, it is possible to suppress a decrease in the amount of energy suppression that can be achieved for the entire property A and B.

(5) Modifications While the embodiment of the present invention has been described with reference to the drawings, the specific configuration is not limited to the above-described embodiment, and can be changed without departing from the gist of the invention. .

(5-1) Modification 1A
In the above-described embodiment, the energy consumption calculation unit 36c uses the air conditioners 40, 40 based on the current operation state and the latest meter value (corresponding to the actual measurement value) stored in the meter value storage area 35d. ,... Have been described as being calculated, but the present invention is not limited to this.

  For example, the energy consumption calculation unit 36c may calculate the energy consumption of each of the air conditioners 40, 40,... Based on the current driving situation and the estimated value from the latest meter value.

  For example, it is assumed that the meter value acquisition unit 36b acquires a meter value every minute. In this case, if the energy consumption calculation unit 36c tries to calculate the energy consumption at the time of 5 minutes 30 seconds from the start of the measurement of the meter value, the meter value at the time of 5 minutes is used. Therefore, the energy consumption can be calculated more accurately by estimating the energy consumption at the time of 5 minutes 30 seconds from the meter value based on the rate of increase of the meter value and the remaining time. Therefore, the energy suppression possible amount can be determined more accurately.

(5-2) Modification 1B
FIG. 7 is a schematic configuration diagram of the low-order controller 30 according to Modification 1B.

  In the above embodiment, it has been described that the user inputs the permissible operating capacity of the air conditioners 40, 40,... Via the input unit 33, but the present invention is not limited to this.

  For example, as shown in FIG. 7, the storage unit 35 holds an arithmetic expression storage area 35f, and an arithmetic operation for calculating the allowable operating capacity of the air conditioners 40, 40,... In the arithmetic expression storage area 35f. When the formula is stored, the user may input a variable value in the calculation formula via the input unit 33. In this case, the allowable driving capability calculation unit 36n that further configures the control unit 36 substitutes the input value input by the user for the variable part in the arithmetic expression, and the allowable driving capability of the air conditioners 40, 40,. Is calculated.

  The condition stored in the condition storage area 35b is updated when the allowable driving capacity acquisition unit 36k acquires the calculated allowable driving capacity and the allowable driving capacity setting unit 36m sets the allowable driving capacity. Is done.

  Here, the arithmetic expression is an expression using various values included in the operation status of the equipment including the operation status of the air conditioners 40, 40,.

  Even in this case, similarly to the above, it is possible to perform control in consideration of the user's comfort level.

  Further, in the above-described embodiment, the correction unit 36l has been described as correcting the user input value, and thus the allowable driving ability, by performing learning based on the determination result of the user's comfort. However, the correction unit 36l is limited to this. is not. The correcting unit 36l may also correct the constant portion in the arithmetic expression stored in the arithmetic expression storage area 35f by learning.

  Thereby, an air conditioning environment more suitable for the user can be provided, and the comfort of the user is improved.

(5-3) Modification 1C
In the above-described embodiment, the energy consumption calculation unit 36c calculates the energy consumption based on the current operation status of each air conditioner 40, 40,... And the most recent meter of each air conditioner 40, 40,. The estimated consumption calculation unit 36d calculates each air conditioner 40, 40,... When it is controlled under the condition based on the user input value (driving capability value). Explained that the estimated consumption was calculated.

  However, the present invention is not limited to this, and the estimated consumption calculation unit 36d performs the operation status of each of the air conditioners 40, 40,... During the energy suppression control (second control), and each air conditioner 40. , 40,..., The estimated consumption may be calculated (estimated) from the latest meter values (actually measured values). In this case, although the user's comfort is somewhat inferior, it is possible to determine a more accurate estimated consumption amount, and thus a more accurate energy suppression possible amount.

  Moreover, when it is desired to prioritize energy suppression over user comfort, each air conditioner 40, under conditions based on the input value (allowable driving ability value) by the user, even during normal control (first control) 40,... May be controlled. That is, in this case, the energy consumption calculation unit 36c calculates the energy consumption of each of the air conditioners 40, 40,... Based on the input value by the user. In this case, the user input value in the normal control in which energy suppression is not performed needs to be higher than the user input value in energy suppression control.

  In this case, since the user can input an allowable driving capability that can be permitted by the user, it is possible to perform air-conditioning control in consideration of user comfort while giving priority to energy suppression.

(5-4) Modification 1D
In the above embodiment, it has been described that the control can be performed for each of the indoor units 42, 42, ... of the air conditioners 40, 40, .... In addition to the above embodiment, a priority may be set for each of the indoor units 42, 42,... (For each room (conference room, hot water supply room, etc.)). Here, the priority setting includes flag setting, weighting setting, and the like. Also in this case, adjustment is possible for each of the indoor units 42, 42,..., Such as relaxing the energy suppression control of the high priority indoor units 42, 42,. .

  Moreover, you may set the energy suppression control object exclusion time which is time which is not the object of energy suppression control to 1 or the predetermined number of indoor units 42, 42, ... besides the said embodiment.

  In this case, as described in the feature (4-4), the energy suppression control of some of the indoor units 42, 42,. Thereby, the reduction | decrease of the opportunity of energy suppression control can be prevented, and the reduction | decrease of the energy suppression possible amount as the property A and B whole can also be prevented.

(5-5) Modification 1E
In the above embodiment, the comfort determination result storage area 35e stores a determination result indicating that the user feels uncomfortable when the user feels uncomfortable by executing the energy suppression control. explained. However, the present invention is not limited to this, and in advance, when the user inputs a range of allowable deviation between the set temperature and the room temperature (referred to as the allowable deviation of the user) via the input unit 33, The storage unit 35 may store a range of the allowable deviation degree of the user. In this case, the correction unit 36l corrects the input value of the user, and thus the allowable driving ability, by learning based on the range of the allowable deviation stored in the comfort determination result storage area 35e. In other words, the correction unit 36l corrects the user input value and thus the allowable driving ability by learning the case where the allowable deviation degree range is exceeded.

  To give a specific example, for example, when the range of the allowable deviation degree of the user is 2 ° C. or less, if the deviation degree between the set temperature and the room temperature exceeds 2 ° C., the correction unit 36l Then, the allowable driving ability is corrected.

  Even in this case, the same effects as described above can be obtained.

(5-6) Modification 1F
In the above embodiment, the energy consumption calculation unit 36c uses a meter value (actual measurement value) in calculating the energy consumption, but is not limited thereto.

  For example, when the power meter 7 is not installed in each property A, B, or when the power meter 7 breaks down, the energy consumption calculation unit 36c replaces the meter value with each air conditioner 40, 40. The energy consumption may be calculated based on the estimated value of the energy amount estimated from the operation schedule of. Here, the operation schedule is a schedule based on the time, time zone, ON / OFF state, operation mode, set temperature, etc., and saves energy such as “from what time to what time the operation capacity is at the upper limit of what percentage”. It may be an energy saving schedule that contributes.

  In this case, measurement by the power meter 7 is not performed, which contributes to cost saving.

  Further, since the energy consumption is calculated based on the operation schedule, the energy consumption can be calculated as accurately as possible, although it is somewhat inferior to the case where the actual measurement value is used.

(5-7) Modification 1G
FIG. 8 is a schematic configuration diagram of the lower controller 30 according to the modification 1G.

  The operation of the suppression possible amount determining unit 36e is not limited to the above operation.

  For example, when there is an air conditioner for which energy suppression control is not performed, it is assumed that the energy consumption of the air conditioner may suddenly increase. At this time, there is a concern that the energy suppression possible amount presented to the host controller, and consequently, the energy amount based on the request (selection command) from the host controller cannot be satisfied. Here, an air conditioner that is not subjected to energy suppression control is, for example, an air conditioner that is set as an exclusion for energy suppression control or an energy suppression that cannot perform energy suppression control due to priority of equipment maintenance. The air conditioner is in an uncontrollable period (corresponding to a second uncontrollable period). In addition, the air conditioner in the state of the energy suppression control disabled time includes an air conditioner that is executing an oil return operation or a defrost operation. Here, the oil return operation means that the refrigerating machine oil accumulated in the refrigerant pipes connecting the outdoor units 41, 41,... And the indoor units 42, 42,. It is the operation | movement returned to the compressor accommodated in this, and is an operation normally performed for about 5 to 10 minutes. Moreover, defrost operation is operation performed in order to prevent that frost adheres to the outdoor heat exchanger (not shown) accommodated in outdoor unit 41,41, ... at the time of heating operation, 5 minutes- It takes about 10 minutes.

  In order to solve the above-described concerns, the energy suppression control is not performed in the controllable amount determination unit 36e in addition to the above-described embodiment when the air conditioners 40, 40,. The energy suppression possible amount may be determined in consideration of the fluctuation value (hereinafter referred to as the fluctuation value) of the energy amount of one or a plurality of air conditioners 40, 40,. .

  In this case, the calculation unit 36cd predicts (calculates) the fluctuation value. In this case, as shown in FIG. 8, the control unit 36 further functions as an energy suppression control impossible timing generation prediction unit 36 o (second control impossible timing generation prediction unit) that predicts the occurrence of the energy suppression control disable timing. Shall.

  Specifically, the calculation unit 36cd may predict the fluctuation value based on the estimated value of the suppression energy amount based on the operation schedule of each air conditioner 40, 40,. , 40,... May be estimated from the latest energy gradient. In addition, the calculation unit 36cd detects the maximum change gradient of the energy amount based on the past change in the energy amount of each of the air conditioners 40, 40, ..., and from the change gradient of the maximum energy amount, A variation value may be predicted.

  Further, the calculation unit 36cd may calculate the variation value in consideration of the energy suppression control impossible time predicted by the energy suppression control impossible time occurrence prediction unit 36o illustrated in FIG.

  Thereby, the amount of suppression energy based on the request | requirement (selection command) from the high-order controller 10 among the energy suppression possible amounts shown to the high-order controller 10 is protectable.

  Moreover, as shown in FIG. 8, the control part 36 is the air conditioner 40 with which energy suppression control is performed for the part of the variation value of the air conditioners 40, 40, ... with which energy suppression control is not performed. It may further function as an adjustment unit 36p that adjusts at 40,.

  Specifically, the adjustment unit 36p uniformly allocates the amount of variation to the air conditioners 40, 40,... For which energy suppression control is performed. For example, if the fluctuation value is 10% in terms of driving capacity, 10% is divided by the number of air conditioners 40, 40,. Are allocated to the air conditioners 40, 40,... That is, the air conditioners 40, 40,... That are subjected to energy suppression control are further subjected to energy suppression control.

  In this case, if a priority related to comfort is set for each of the indoor units 42, 42,... Of the air conditioners 40, 40,. You may allocate a value. In other words, the indoor units 42, 42,... With high priority have less fluctuation values (converted driving ability) than the indoor units 42, 42,.

  In this case, since the fluctuations can be suppressed as much as possible for the property A and B as a whole, the request from the host controller 10 can be easily observed.

(5-8) Modification 1H
In the above embodiment, the lower controller 30 performs energy suppression control of each of the air conditioners 40, 40,... By presenting a possible energy suppression amount to the upper controller 10 and receiving a selection command from the upper controller 10. However, the configuration is not limited to such a configuration, and a configuration without the host controller 10 may be used.

  In this case, the lower controller 30 has the function of the upper controller 10.

  Specifically, in the lower controller 30, energy suppression control is performed from the overall meter values stored in the meter value storage area 35d and the respective conditions stored in the condition storage area 35b. To determine the energy suppression control target air conditioner and the amount of energy suppression possible. And based on the said energy suppression possible quantity, the control of the air conditioner targeted for energy suppression control is performed.

  Hereinafter, the flow of processing in the lower controller 30 in this case will be briefly described.

  First, it is determined whether energy suppression control of each air conditioner 40, 40,... Is necessary, and when it is determined that it is necessary, the above-described energy suppression is performed for the above-described energy suppression control target air conditioner. A control command for performing the energy suppression control unit based on the possible amount is generated. And the said control instruction | command is transmitted to each air conditioner 40,40, ....

  On the other hand, when it is determined that the energy suppression control of each air conditioner 40, 40,... Is not necessary, the determination is repeated.

(5-9) Modification 1I
In the above embodiment, the suppression possible amount presentation unit 36f basically presents the energy suppression possible amount to the host controller 10 on a regular basis, but is not limited thereto.

  For example, the controllable amount presentation unit 36f can suppress the periodic energy when the elapsed time after transmission after the control command transmission unit 36j transmits the control command for the air conditioners 40, 40,. An amount may be presented. At this time, the elapsed time after transmission is measured by the timer unit 34.

(5-10) Modification 1J
Although the control object in the said embodiment is taken as the air conditioners 40, 40, ..., it is not restricted to this. For example, other devices such as lighting and a water heater may be controlled (in this case, the air conditioners 40, 40,... And other devices correspond to equipment). In this case, the energy management system 100 further includes devices necessary for control in the energy management system 100, such as a meter for measuring the amount of energy of these devices. In this case, the lighting operation state and operation state include ON / OFF state, brightness level, etc., and the water heater operation state and operation state include ON / OFF state, hot water temperature, The amount of hot water is included. Various temperatures, pressures, and the like included in various operating situations are detected by various sensors.

(5-11) Modification 1K
In the above embodiment, it has been described that the lower controller 30 performs control for each of the air conditioners 40, 40,... (Indoor units 42, 42,...), But is not limited thereto. 40, 40,... (Indoor units 42, 42,...) May be controlled uniformly. In this case, management in the lower controller 30 is facilitated.

(5-12) Modification 1L
The energy consumption calculation unit 36c and the estimated consumption calculation unit 36d are not limited to the above-described operations, and the overall energy consumption and estimated consumption of the air conditioners 40, 40,. May be calculated. Moreover, the suppression possible amount presentation part 36f may present the energy suppression possible amount of the air conditioners 40, 40,.

(5-13) Modification 1M
In the above-described embodiment, the suppression possible amount presentation unit 36f periodically presents the periodic energy suppression possible amount to the host controller 10, but the present invention is not limited to this.

  For example, the lower controller 30 controls the upper controller 10 with the properties A and B by making a request to the lower controller 30 to present the amount of energy that can be suppressed with the properties A and B to the lower controller 30. A possible amount of energy may be presented.

  The present invention is applicable to various energy management systems that present energy-suppressible amounts that can be suppressed to a host controller.

10 Host controller (energy management device)
30 Lower level controller (control device)
35 storage unit 36a driving condition grasping unit 36cd calculating unit 36e controllable amount determining unit 36i control command generating unit 36l correcting unit 36m allowable driving capability setting unit (driving capability setting unit)
36o Energy suppression control impossible time occurrence prediction unit (second control impossible time occurrence prediction unit)
40 Air conditioner 100 Energy management system A, B Property

JP-A-2005-107901

Claims (9)

An energy management device (10) that is located above a plurality of properties (A, B) and manages energy supplied to equipment installed in each property (A, B);
A control device (30) for controlling the equipment of each property (A, B);
With
The control device (30)
An operation state grasping unit (36a) for grasping the operation state of the equipment;
An energy consumption that is the amount of energy consumed by the first control that does not perform energy suppression and an estimated consumption that is the amount of energy that is consumed by the second control that performs energy suppression according to conditions are the A calculation unit (36cd) that calculates based on an input value by a user and / or an actual measurement value of an energy amount that varies depending on the driving situation;
A reducible amount determination unit (36e) that determines a plurality of energy reducible amounts according to the conditions of the facility equipment, and that determines an energy reducible amount based on the energy consumption amount and the estimated consumption amount;
I have a,
The calculation unit further calculates a fluctuation value of the energy amount of the equipment that is not subjected to the second control among the equipment,
The suppressible amount determining unit determines the energy suppressible amount based further on the variation value.
Energy management system (100). The calculation unit (36cd)
Calculating the energy consumption based on the measured value;
Calculating the estimated consumption based on an input value by the user;
The energy management system (100) of claim 1. The input value by the user is at least one of an allowable operating capacity value of the equipment that can be allowed when the second control is executed, and a variable value in an arithmetic expression for calculating the allowable operating capacity value.
The control device (30) further includes a driving capability setting unit (36m) for setting the allowable driving capability value.
The energy management system (100) according to claim 1 or 2. The control device (30) further includes a correction unit (36l) that corrects at least an input value by the user through learning.
The energy management system (100) of claim 3. The equipment includes air conditioners (40, 40,...)
The control device (30)
A control command generation unit (36i) for generating a control command for controlling each indoor unit (42, 42, ...) of the air conditioner (40, 40, ...);
The energy management system (100) according to any one of claims 1 to 4. The driving capacity setting unit (36m) sets the allowable driving capacity value for each of the air conditioners (40, 40, ...),
The calculation unit (36cd) calculates the energy consumption amount and the estimated consumption amount for each of the air conditioners (40, 40, ...).
The energy management system (100) according to claim 3 or 4 . The equipment that has not been subjected to the second control includes equipment that is in a state of the second uncontrollable time during which the second control cannot be performed,
The control device (30)
A second uncontrollable time occurrence prediction unit (36o) for predicting the occurrence of the second uncontrollable time;
The energy management system (100) according to any of claims 1 to 6 . An energy management device (10) that is located above a plurality of properties (A, B) and manages energy supplied to equipment installed in each property (A, B);
A control device (30) for controlling the equipment of each property (A, B);
With
The control device (30)
An operation state grasping unit (36a) for grasping the operation state of the equipment;
An energy consumption that is the amount of energy consumed by the first control that does not perform energy suppression and an estimated consumption that is the amount of energy that is consumed by the second control that performs energy suppression according to conditions are the A calculation unit (36cd) for calculating based on an input value of the user and / or an estimated value of the energy amount based on an operation schedule of the facility equipment;
A reducible amount determination unit (36e) that determines a plurality of energy reducible amounts according to the conditions of the facility equipment, and that determines an energy reducible amount based on the energy consumption amount and the estimated consumption amount;
I have a,
The calculation unit further calculates a fluctuation value of the energy amount of the equipment that is not subjected to the second control among the equipment,
The suppressible amount determining unit determines the energy suppressible amount based further on the variation value.
Energy management system (100). An operation status grasping unit (36a) for grasping the operation status of the equipment ;
An energy consumption that is the amount of energy consumed by the first control that does not perform energy suppression and an estimated consumption that is the amount of energy that is consumed by the second control that performs energy suppression according to conditions are the A calculation unit (36cd) that calculates based on an input value by a user and / or an actual measurement value of an energy amount that varies depending on the driving situation;
A reducible amount determination unit (36e) that determines a plurality of energy reducible amounts according to the conditions of the facility equipment, and that determines an energy reducible amount based on the energy consumption amount and the estimated consumption amount;
Equipped with a,
The calculation unit further calculates a fluctuation value of the energy amount of the equipment that is not subjected to the second control among the equipment,
The suppressible amount determining unit determines the energy suppressible amount based further on the variation value.
Control device (30).

Images