JP2014070782A - Energy consumption equipment control device, energy consumption equipment control method and energy consumption equipment control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an energy consumption equipment control device, an energy consumption equipment control method and an energy consumption equipment control system capable of differentiating an air conditioner to be started from air conditioners other than the air conditioner to be started when the number of started air conditioners among a plurality of air conditioners within a house is restricted.SOLUTION: A home server 1 includes: a control signal transmitting part 19 which transmits a starting request signal toward each of a plurality of air conditioners within a house H; a response signal receiving part 20; a control air conditioner specifying part 15 which specifies an air conditioner to be started in accordance with a schedule; a calculation part which calculates the whole power consumption within the house H in such a case as to start all of the specified air conditioners; and a judgment part 18 which judges whether a calculated power exceeds the upper limit power. Therein, when the calculated power exceeds the upper limit power, the control signal transmitting part transmits the starting request signal only to a part of the air conditioners at execution time point of air conditioning control and, then, transmits the starting request signal toward remaining air conditioners after the elapse of a predetermined time and a response signal transmission part receives a response signal from the air conditioner which is started by receiving the starting request signal.

Description

  The present invention relates to an energy consuming equipment control device, an energy consuming equipment control method, and an energy consuming equipment control system, and in particular, communicates with each of a plurality of energy consuming equipment of the same type in a building or a room of a building to communicate each energy. The present invention relates to an energy consuming device control apparatus, an energy consuming device control method, and an energy consuming device control system for controlling an operating state of a consuming device.

  As a control system for energy consuming equipment, a system that installs a home server in a house to control the electrical equipment in the house or monitor the power consumption status in the house, so-called HEMS (Home Energy Management System) has recently been developed. Attention has been paid. In HEMS, a home server outputs a control signal to an electrical device and collects information on power usage from the electrical sensor by communicating with the electrical device and the electrical sensor through a network built in a house. To do.

In addition, among the above control systems, there is a system that controls the operating state of electrical equipment in a house according to the total amount of power in the house acquired from an electric sensor (see, for example, Patent Document 1). Patent Document 1 discloses a power control device that acquires the total amount of power in a house through a main breaker in a distribution board, and controls the operating state of home appliances in the house according to the total power. Yes.
Furthermore, some systems that control the operating state of each electrical device in accordance with the total amount of electric power in the house control the same type of electrical equipment installed in the house (for example, Patent Document 2). reference). In Patent Document 2, communication is made with each of a plurality of air conditioners installed in a house to obtain the operating status of each air conditioner, and a plurality of air conditioners when the total power amount in the house is likely to exceed the upper limit value. A power control device that controls the operation of at least one of the above is disclosed.

JP 2009-254219 A JP 2002-13778 A

  By the way, when controlling the operation state of each electric device according to the total electric energy in the house as described above, the control signal is transmitted to the electric device to be controlled, whereas the electric device to be controlled It may not be known whether the operation state is in a state corresponding to the control signal. In such a case, in order to confirm whether or not the operation state of the electric device is reliably controlled, the operation state is actually visually confirmed by going to the place where the electricity is installed.

  In addition, in cases where an electrical device to be controlled is automatically selected, if the electrical device that is the control target is not known, the life of the resident of the house who is the user of the control system will be hindered. There is no doubt. In the system using the power control device disclosed in each of Patent Documents 1 and 2 described above, a resident in a house cannot grasp which electric device is in what operation state, and is in operation, for example. There is a possibility that the resident's life may be disturbed because the electrical device that is supposed to be in operation is actually on standby. In particular, as in the case described in Patent Document 2, when controlling the number of operating air conditioners in a house based on the total amount of power in the house, it is known which air conditioner is restricted in operation. Otherwise, the presence or absence of adjustment of temperature and humidity in each room in the house cannot be grasped, and it becomes difficult for a resident of the house to live a comfortable life.

  Therefore, the present invention has been made in view of the above problems, and the object of the present invention is to load more than a predetermined amount among the same type of energy consuming equipment installed in a building or a room of a building. To provide an energy consuming device control device, an energy consuming device control method, and an energy consuming device control system capable of distinguishing between a device to be controlled and other devices in a configuration in which the number of devices to be operated is limited. It is.

  According to the energy consuming equipment control device of the present invention, the subject is communicated with each of a plurality of energy consuming equipment of the same type in a building or a room of the building, and the operation state of each of the plurality of energy consuming equipment is determined. An energy consuming device control apparatus for controlling, a control signal transmitting unit for transmitting a control signal for controlling the operation state toward each of the plurality of energy consuming devices, and each of the plurality of energy consuming devices A response signal receiving unit that receives a response signal indicating the driving state; a storage unit that stores a schedule that defines a period of time during which the load is set to a predetermined amount or more for each of the plurality of energy consuming devices; Reading the schedule stored in the storage unit, and controlling the energy consuming device from the plurality of energy consuming devices A specifying unit that specifies a device to be controlled to be operated under the operation condition at the time of execution of control by a device, and all of the control target devices that the specifying unit has specified from among the plurality of energy consuming devices are operated under the operation condition. A calculation unit for calculating the amount of energy consumed in the building or the room of the building at the time of execution of the control, and whether the calculation result of the calculation unit exceeds a preset upper limit amount And when the determination unit determines that the calculation result exceeds the upper limit amount, the control signal transmission unit is operated at the operation condition at the time of execution of the control. After transmitting a driving request signal which is the control signal for only a part of the devices to be controlled, after a predetermined time has elapsed since the execution time of the control Transmitting the turn request signal to the remaining devices among the control target devices, and the response signal transmitting unit receives the operation request signal from the control signal transmitting unit. This is solved by receiving the response signal that is sent to indicate that it has begun driving.

  According to the above device, when the number of devices to be operated with a load of a predetermined amount or more among the same type of energy consuming devices installed in the building or the room of the building is limited, on the control device side, the load is A response signal is received from a device that has started to operate under conditions such that the amount exceeds a predetermined amount. Thereby, on the control device side, it becomes possible to clearly distinguish the device to be controlled from the other devices. Further, if the control device is provided with means for notifying the user of the device to be operated with a load of a predetermined amount or more, the user can use the notification means to determine the device to be operated with a load of the predetermined amount or more and other devices. It becomes possible to grasp.

Moreover, in said energy consumption apparatus control apparatus, when the said calculation result exceeds the said upper limit amount as a control mode when the said energy consumption apparatus control apparatus controls the driving | running state of each of these energy consumption apparatus. The number limit mode for limiting the number of devices to be controlled to be operated under the operation conditions at the time of execution of the control when the determination unit determines, and the operation conditions for all of the devices to be controlled at the time of execution of the control. It is possible to specify a non-unit limit mode to be operated at the time, and when the unit limit mode is specified, the control signal transmission unit is limited to only a part of the control target devices at the time of execution of the control. To receive the input operation performed by the user in order to transmit the driving request signal toward the destination and specify the control mode A setting request receiving unit that receives the setting request for the control mode from a user terminal that transmits the setting request for the control mode to the energy consuming equipment control device, and the setting request receiving unit sends the setting request for the control mode. It is preferable to further include a control mode setting unit that sets the control mode to a mode on the designated side of the number limit mode and the non-number limit mode by receiving.
With the above configuration, it is possible to switch the control mode according to the intention of the user.For example, if you want to practice energy saving, specify the number limit mode and fully use the functions of energy consuming equipment Can specify the non-unit limit mode. As a result, highly convenient control for the user is realized.

Further, in the above-described energy consuming apparatus control device, the storage unit controls the operation under the operation condition at the time of execution of the control when the determination unit determines that the calculation result exceeds the upper limit amount. A preset number is stored as the maximum number of target devices, and the control is executed at regular intervals according to the schedule, and the number of control target devices specified by the specifying unit exceeds the set number. And when the determination unit determines that the calculation result exceeds the upper limit amount, the control signal transmission unit is configured to control the number of control objects corresponding to the set number at the time of execution of the control. The operation request signal is transmitted to only some of the devices to be controlled so that only the devices are operated under the operation conditions, In line point, the operation request signal to the control target device is increased to be operated by the operating condition and transmits it to the rest of the equipment of the control target device, is more preferable.
With the above configuration, if the calculated value of energy consumption in the building or the room of the building exceeds the upper limit, increase the number of devices to be operated with a load greater than the predetermined amount in stages. Is possible. This makes it possible to gradually increase the number of devices that are operated with a load greater than or equal to a predetermined amount while monitoring the energy consumption in the building or the room of the building.

In the energy consuming device control apparatus, the storage unit stores a priority order determined for each of the plurality of energy consuming devices, and the calculation result exceeds the upper limit amount. When the determination unit determines, the control signal transmission unit is configured to select the control target device having a higher priority as the control target device to be operated under the operation condition at the time of execution of the control. A request signal is transmitted to only a part of the devices to be controlled, and the priority is set to each installation location of the plurality of energy consuming devices in the building or the room of the building, or the plurality of devices. More preferably, it is determined based on the maximum energy consumption amount of each energy consuming device.
With the above configuration, a priority order is determined for each of the same type of energy consuming equipment provided in a building or a room of a building, and a higher amount of equipment with a higher priority is given during a limited number operation. It will be operated with the above load. As described above, the device to be operated with a load of a predetermined amount or more in the number-limited operation is determined according to the priority order, so that it is possible to execute control with improved convenience for the user.

In the energy consuming device control apparatus, when there are devices that communicate with each other using different communication protocols among the plurality of energy consuming devices, the control signal transmission unit sends the control signal to the device to be controlled. It is more preferable to switch the communication protocol used when transmitting in accordance with the communication protocol used by the control target device as the transmission destination.
With the above configuration, the energy consuming device control device switches the communication protocol according to the communication partner, so that the user side does not have to be aware of the difference in the communication protocol and the energy consuming device control device Control can be requested.

In the energy consuming device control apparatus, it is more preferable that the storage unit stores an installation location of the energy consuming device in the building or a room of the building.
With the above configuration, since the installation location of the energy consuming device is stored on the control device side, each energy consuming device is controlled appropriately after grasping where the controlled device is installed. It becomes possible.

Further, in the energy consuming device control device, the energy consuming device control device communicates with each of the plurality of electric devices as the plurality of energy consuming devices to control an operation state of each of the plurality of electric devices. The storage unit is installed in a distribution board provided in the building or the room of the building, contract power determined by a contract with an electric power company as the maximum power consumption in the building or the room of the building One of the working power that is power consumption in the building or the room of the building when the circuit breaker is activated and the target power set as the target value of power consumption in the building or the room of the building It is even more preferable that power is stored as the upper limit amount.
In the case of the above configuration, when the electric power exceeding the upper limit amount is consumed with the contract power, the breaker operating power and the target power as the upper limit amount, Limit the number. This makes it possible to appropriately manage the number of electrical devices that are operated with a load of a predetermined amount or more while monitoring the power consumption in the building or the room of the building.

  In addition, according to the energy consuming device control method of the present invention, the above-described problem is communicated with each of a plurality of energy consuming devices of the same type in a building or a room of the building, and each of the plurality of energy consuming devices. An energy consuming device control method for controlling an operating state, wherein a schedule that defines a period of time during which the load is set to a predetermined amount or more for each of the plurality of energy consuming devices is read from a storage unit, From among energy consuming devices, specifying a control target device to be operated under the operating condition at the time of execution of control for the plurality of energy consuming devices, and specifying the control target device identified from among the plurality of energy consuming devices When everything is operated under the operating conditions, at the time of execution of the control, the building or the building When calculating the amount of energy consumed indoors, determining whether the calculation result of the energy amount exceeds a preset upper limit amount, and the calculation result exceeds the upper limit amount When determined, at the time of execution of the control, an operation request signal for operating under the operation conditions is transmitted to only some of the devices to be controlled, and then predetermined from the time of execution of the control. After the time has elapsed, the operation request signal is transmitted to the remaining devices among the control body target devices, and the control target device that has received the operation request signal has started operating under the operation conditions. It is solved by receiving a response signal that is transmitted to indicate

  According to the above method, the control target device and other devices can be clearly distinguished by receiving a response signal from a device that has started to operate under a condition that causes a load of a predetermined amount or more in the number-limited operation. It becomes possible to do. In addition, by using a means for notifying a device to be controlled, it becomes possible for the user to grasp a device to be operated with a load of a predetermined amount or more and other devices.

  In addition, according to the energy consuming device control system of the present invention, the above-described problem is communicated with a plurality of energy consuming devices of the same type in a building or a room of the building, and each of the plurality of energy consuming devices. An energy consuming device control system having an energy consuming device control device that controls each operating state, wherein the energy consuming device control device controls the operating state toward each of the plurality of energy consuming devices. A control signal transmission unit that transmits the control signal, a response signal reception unit that receives a response signal indicating the operation state from each of the plurality of energy consuming devices, and a load of a predetermined amount for each of the plurality of energy consuming devices A storage unit that stores a schedule that defines a period of operation under the above operating conditions, and a previous storage stored in the storage unit A schedule is read out, and from the plurality of energy consuming devices, a specifying unit that specifies a control target device to be operated under the operation condition at the time of execution of control by the energy consuming device control device, and the specifying unit is the plurality of the plurality of energy consuming devices A calculation unit that calculates an amount of energy consumed in the building or a room of the building at the time of execution of the control when all the control target devices identified from the energy consuming devices are operated under the operation conditions; A determination unit that determines whether the calculation result of the calculation unit exceeds a preset upper limit amount, and when the determination unit determines that the calculation result exceeds the upper limit amount, The control signal transmission unit transmits an operation request signal, which is the control signal for operating under the operation conditions, at the time of execution of the control. Transmitting only to some of the devices, and then transmitting the operation request signal to the remaining devices among the control target devices after a predetermined time has elapsed since the execution of the control, The response signal transmission unit is solved by receiving the response signal transmitted to indicate that the control target device that has received the operation request signal from the control signal transmission unit has started operating under the predetermined load condition. Is done.

  According to the above system, the control target device and other devices can be clearly distinguished by receiving a response signal from a device that has started to operate under a condition that causes a load of a predetermined amount or more in the number-limited operation. It becomes possible to do. In addition, by using a means for notifying a device to be controlled, it becomes possible for the user to grasp a device to be operated with a load of a predetermined amount or more and other devices.

  According to the energy consuming equipment control device, the energy consuming equipment control method, and the energy consuming equipment control system of the present invention, among a plurality of the same type of energy consuming equipment installed in a building or a room of a building, with a load of a predetermined amount or more. When the number of devices to be operated is limited, it is possible to distinguish between devices to be controlled and other devices. Furthermore, if a means for notifying a user of a device to be operated with a load of a predetermined amount or more is provided, the user can grasp a device to be operated with a load of a predetermined amount or more and other devices.

It is a figure which shows the schematic structural example of the energy consumption apparatus control system which concerns on this invention. It is a figure which shows the hardware constitutions of the energy consumption apparatus control apparatus which concerns on this invention. It is explanatory drawing of the memory which the energy consumption apparatus control apparatus which concerns on this invention has. It is a figure which shows the software structure of the energy consuming equipment control apparatus which concerns on this invention. It is explanatory drawing about the data transmission between apparatuses in the energy consuming apparatus control system which concerns on this invention. It is a figure which shows an example of the operation screen drawn on the user terminal which concerns on this invention. It is explanatory drawing about the schedule which concerns on this invention. It is a figure which shows an example of the operation panel for a schedule update. It is explanatory drawing about unit control operation. It is a figure which shows the table which prescribed | regulated the pattern of number control. It is a block diagram which shows the structural example of each part of the energy consuming equipment control system which concerns on this invention. It is a figure which shows the corresponding | compatible relationship between the installation place of an energy consumption apparatus, and a priority. It is a figure which shows the example of a procedure of the energy consumption apparatus control method which concerns on this invention. It is a figure which shows the example of a procedure of a schedule control step. It is a figure which shows an example of the confirmation screen of a control condition.

An example of an energy consuming device control apparatus, an energy consuming device control method, and an energy consuming device control system according to the present invention will be described with reference to FIGS.
Below, the house H is mentioned as an example of the building where an energy consumption apparatus is used, and the control apparatus, the control method, and the control system which control the electric equipment used in the house H are demonstrated.

However, the present invention is also applicable to controlling energy consuming devices other than electric devices, for example, devices that consume gas or water.
Further, the house H is merely an example of a building where energy consuming equipment is used, and the present invention is an energy consuming equipment used in buildings other than the house H, such as commercial buildings, buildings in factories, stores, and the like. It can also be applied to control.
In addition, the house H is a concept including one room in an apartment house such as a condominium as well as a detached house. In other words, the present invention is also applicable when controlling energy consuming equipment used in a building or a room of a building.

<< Entire configuration of energy consuming equipment control system >>
First, an overall configuration of an energy consuming equipment control system (hereinafter, this system) S according to an embodiment of the present invention will be outlined with reference to FIG.
This system S is a system in which the home server 1 installed in the house H communicates with the electric equipment in the house H to control the electric equipment, so-called HEMS. That is, in the house H in which the present system S is installed, the home server 1 as an energy consuming equipment control device is arranged, and the home server 1 communicates with each electrical device in the house H via the home network 5. To do. Further, the home server 1 is connected to the power data logger 7 via the home network 5 so as to be communicable.

  With the configuration as described above, a resident (hereinafter referred to as a user) of the house H can remotely control the electric device through the home server 1 or visually recognize the power consumption of the house H based on the data collected from the power data logger 7. It becomes possible to do. Here, the user uses the user terminal 3 as an interface in order to use the functions of the home server 1 described above. More specifically, the user can request the home server 1 to transmit data or control the electrical device by performing a predetermined input operation on the user terminal 3. Here, the user terminal 3 is a communication terminal including a PDA, a smartphone, a PC, an operation panel, and the like, and receives a user input operation and executes a predetermined process. In the following description, a case where the user terminal 3 is composed of a PDA used in the house H will be described. More specifically, the user terminal 3 that communicates with the home server 1 via a router (not shown) provided in the house H will be described below. However, the present invention is not limited to this, and the user terminal 3 may communicate with the home server 1 via an external network such as the Internet.

In this system S, the home server 1 can individually control each electrical device in the house H in response to a control request made by the user through the user terminal 3. Further, in the present system S, the home server 1 can execute schedule control for controlling each of the same type of electrical devices installed in the house H, for example, each of a plurality of air conditioners, according to a preset schedule. It is. That is, in the schedule control, the home server 1 communicates with the plurality of air conditioners simultaneously to control the operation state of each of the plurality of air conditioners.
Although FIG. 1 shows an example in which four air conditioners are installed, the number of air conditioners is not particularly limited and can be set to an arbitrary number. Moreover, in this system S, although the four air conditioners installed in the house H are the targets of schedule control, the present invention is not limited to this, and other electric devices installed in the house H, for example, It is good also considering making lighting equipment into the object of schedule control.

  When the schedule control is outlined, a schedule regarding the operation control of the air conditioner is set in advance and stored in the home server 1. When the user requests execution of the schedule control, the home server 1 reads the stored schedule, and specifies the operation conditions corresponding to the execution time of the schedule control for each air conditioner from the read schedule. Thereafter, the home server 1 controls the corresponding air conditioner under the operation condition specified for each air conditioner.

Further, in the present system S, it is possible to perform the number-limited operation for limiting the number of air conditioners in the activated state during execution of the schedule control. More specifically, if it is attempted to simultaneously operate a predetermined number or more of air conditioners at a certain time according to a schedule, the total power consumption in the house H may exceed the upper limit power described later. In such a case, if the number-limited operation is specified, the number of air conditioners that are operated simultaneously at a certain time is limited, and more specifically, the number is less than the number of air conditioners that are scheduled to be operated at a certain time in the schedule. Operate the number of air conditioners and start the rest of the air conditioners in sequence.
By performing the above-mentioned number-limited operation, it is possible to suppress a rapid increase in power consumption in the house H. As a result, the breaker (an example of a circuit breaker) placed on the distribution board in the house H may drop, or the power consumption in the house H may exceed the contract power determined by the contract with the power company. Can be prevented.
The schedule and the number-limited operation will be described in detail later.

<< Home server configuration >>
Next, the configuration of the home server 1 will be described with reference to FIGS.
The home server 1 corresponds to the energy consuming device control device of the present invention, and is connected to be communicable with an electric device or a power data logger 7 in the house H. In this system S, the home server 1 is constituted by a so-called home gateway, and includes a CPU 1a, a memory 1b, and a communication interface 1c as shown in FIG. In the memory 1b, the above-described schedule is stored in the schedule storage area 1p illustrated in FIG.

  In addition, in the memory 1b, the installation location storage area 1q illustrated in FIG. 3 stores the installation locations in the house H of electric devices used in the house H including air conditioners. The installation location of each electrical device is written into the memory 1b through a predetermined input device by an inspector when the connection state between the home server 1 and each electrical device is inspected at the construction stage of the house H. However, the acquisition method of the installation location is not limited to the above case, and may be acquired by, for example, determining the installation location of each electrical device from the data indicating the construction drawing of the house H.

Further, in the memory 1b, the priority order determined for each air conditioner is stored in the priority order storage area 1r shown in FIG. The priority order defines the order of priority for driving in the number-limited operation. In the present system S, the priority order is determined based on the installation location of each air conditioner in the room of the house H, more specifically based on the type of installation location. Here, the type of installation location is a concept indicating the style and use of a room to which the installation location belongs, such as a living room, a bedroom, a Japanese-style room, and a Western-style room.
In the present system S, as shown in FIG. 12, the living room has the highest priority, followed by the bedroom, the Japanese-style room, and the western-style room. Note that the priority order is not limited to the case where it is determined based on the type of air conditioner installation location, and may be determined based on, for example, the maximum power consumption (corresponding to the maximum energy consumption) of each air conditioner. .

  Further, in the memory 1b, the number limit pattern as shown in FIG. 10 is stored in the number limit pattern storage area 1s shown in FIG. The number limit pattern defines the number of air conditioners that can be operated at each stage of the number limit operation for each number of air conditioners in the house H, and will be described in detail later.

Further, in the memory 1b, the upper limit power storage area 1t illustrated in FIG. 3 stores an upper limit power that serves as a determination criterion when determining whether or not to perform the limited number of operations. Here, the upper limit power corresponds to a preset upper limit amount, and specifically, is contract power determined by a contract with an electric power company as maximum power consumption in the house H. The contract power is determined by the area where the house H is built, the number of air conditioners in the house H, whether or not a system (so-called all electrification) that uses electricity to cover all of the hot water supply, cooking and air conditioning in the house H is adopted. .
However, the upper limit power is not limited to the contract power described above. For example, the circuit breaker installed in the distribution board provided in the house H, that is, the operating power that is the power consumption in the house H when the breaker operates may be set as the upper limit power. Moreover, it is good also as the target electric power set as the target value of the power consumption in the house H being set to the upper limit electric power.

  Furthermore, in the memory 1b, the bundle storage area 1u illustrated in FIG. 3 stores an application program (hereinafter referred to as a bundle) that is executed by the CPU 1a so that the home server 1 performs its function. The bundles stored in the bundle storage area 1u include communication bundles that are executed when the home server 1 communicates with each electrical device.

  By the way, generally, it is recommended to use an electric device that adopts a common communication protocol (synonymous with a communication method and a communication standard) in a house H in which HEMS is mounted. For example, the ECHONET Consortium proposes It is desired that the devices adopt a communication protocol to be unified. On the other hand, as protocols proposed by the ECHONET consortium, ECHONET (registered trademark) and its successor standard, ECHONET Lite (registered trademark), are available. In addition, electric devices purchased by the user may include devices other than communication protocols other than ECHONET and ECHONETLite.

  In the present system S, more specifically, among a plurality of electrical devices used in the house H, among the four air conditioners, there are air conditioners that communicate with each other using different communication protocols. For this reason, in the bundle storage area 1u of the memory 1b, communication bundles for the home server 1 to communicate with the communication partner of the house H are stored for each communication protocol. That is, in the present system S, the communication bundles are stored in the memory 1b by the number of types of communication protocols adopted by the electric devices in the house H. Specifically, in the bundle storage area 1u, a bundle for communicating with the first communication protocol (for example, ECHONET), a bundle for communicating with the second communication protocol (for example, ECHONET Lite), and the first Three communication protocols (for example, communication protocols other than ECHONET and ECHONET Lite) are stored.

  And in this system S, the communication bundle read out and executed among the communication bundles memorize | stored in the bundle storage area | region 1u switches according to a communicating party. Thereby, the home server 1 can switch the communication protocol adopted when communicating with the air conditioner according to the communication protocol adopted by the air conditioner of the communication partner. Switching the communication protocol is synonymous with rewriting a message (command) transmitted by a certain communication protocol together with the other communication protocol when transmitting a message to a communication device using the other communication protocol.

  Here, the program execution environment in the home server 1 will be described. As shown in FIG. 4, the home server 1 includes an OS 101, a JAVA (registered trademark) virtual machine (hereinafter referred to as JVM) 102, and an OSGi (Open Services Gateway initiative). ) The framework 103 and various bundles operating on the OSGi framework 103 are provided. The OSGi framework 103 is built on the JVM 102 and manages a life cycle such as downloading, installing, starting and stopping a bundle operating on the OSGi framework 103. The bundles operating on the OSGi framework 103 can be dynamically replaced, and a plurality of bundles can be executed in parallel.

  Here, some bundles operating on the OSGi framework 103 communicate with the bundle (hereinafter referred to as the first communication bundle) 104 for communication using the first communication protocol described above and the second communication protocol. Bundle (hereinafter referred to as second communication bundle) 105 and a bundle (hereinafter referred to as third communication bundle) 106 for communication using the third communication protocol are included. Of the functions of the OSGi framework 103, the function of dynamically exchanging bundles replaces the communication bundle to be executed according to the communication protocol of the electrical device that is the communication partner when the home server 1 communicates. It becomes like this. By such communication bundle replacement, the communication protocol employed by the home server 1 is switched. As a result, the home server 1 can communicate with the electrical devices in the house H regardless of the communication protocol.

  Furthermore, when each communication bundle 104, 105, 106 is registered in the OSGi framework 103, an interface for using the function of each communication bundle 104, 105, 106 is registered in the service registry. The OSGi framework 103 provides a combination of these interfaces as an API (Application Program Interface). By using this API, the user does not need to be aware of the difference in communication bundle, that is, the difference in communication protocol between electrical devices. Thus, when developing a program that requires the home server 1 to control the electric device, the developer only needs to know the object rules for each electric device and develop a general Web communication program. The method can be applied.

  If it explains clearly, if it uses said API when request | requiring communication with the electric equipment in the house H with respect to the home server 1, it is not necessary to arrange the request message | telegram into the format according to a communication protocol, and relatively A simple telegram. More specifically, when the user requests control of the air conditioner from the home server 1, as shown in FIG. 5, an HTTP request from the user terminal 3, specifically, an execution request for air conditioner control is directed to the home server 1. Sent. On the other hand, when receiving the HTTP request from the user terminal 3, the home server 1 communicates with the air conditioner and transmits a control signal to the air conditioner. As a result, the home server 1 comes to control the air conditioner that is a control target in accordance with the control rule specified in the HTTP request. Here, the communication protocol adopted when the home server 1 transmits the control signal is set to the communication protocol adopted by the air conditioner that is the transmission destination of the control signal.

  The home server 1 further communicates with the air conditioner that has received the control signal, and receives a response signal indicating the operating state of the air conditioner. At this time, the communication protocol adopted by the home server 1 is set to the communication protocol adopted by the air conditioner that is the source of the response signal.

  On the other hand, the home server 1 transmits data for drawing a screen for confirming the control status of each air conditioner (hereinafter referred to as confirmation screen data) to the user terminal 3 in the XML format. On the user terminal 3 side, the confirmation screen data is expanded so that the confirmation screen illustrated in FIG. 15 is displayed on the display of the user terminal 3. By viewing the confirmation screen, the user visually recognizes which air conditioner is operating under what operating condition among the four air conditioners installed in the house H, and which air conditioner is stopped. It becomes possible to do. The confirmation screen will be described in detail later.

  As described above, in the present system S, bidirectional communication is performed between the home server 1 and the air conditioner. Specifically, a control signal is transmitted from the home server 1 to each air conditioner, and from each air conditioner to the home server 1. A response signal is transmitted. Thereby, among the air conditioners installed in the house H, the air conditioner to be controlled and the other air conditioners can be clearly distinguished on the home server 1 side.

In the present system S, data exchange between the user terminal 3 and the home server 1 is performed using a highly versatile communication protocol, while an air conditioner is used for communication between the home server 1 and the air conditioner. The communication protocol is adapted to the communication protocol to be adopted. Accordingly, the user can request the home server 1 to control each air conditioner without being aware of the difference in the communication protocol between the air conditioners.
In the present system, the control signal and the response signal are data signals and are transmitted and received through the home network 5. On the other hand, the home network 5 may be a wired communication network or a wireless communication network. Here, the communication network means a network capable of bidirectional communication as communication between the home server 1 and the communication target device, and supports only one-way communication from the home server 1 to the communication target device. The network is excluded.

<< Control specifications of air conditioner >>
Next, the control specifications of the air conditioner in the present system S will be described. In the following, of the four air conditioners installed in the house H, the first air conditioner (hereinafter referred to as air conditioner A) is located in the tea room on the second floor, and the second air conditioner (hereinafter referred to as air conditioner B) is located on the second floor. A case will be described in which a third air conditioner (hereinafter referred to as air conditioner C) is installed in the living room on the first floor and a fourth air conditioner (hereinafter referred to as air conditioner D) is installed in the bedroom on the first floor in the child room.

  In this system S, the user can select the control type of the air conditioner through the user terminal 3. Control types that can be selected in the system S are an individual control type, a collective control type, and a schedule control type. Note that these control types are merely examples, and control types other than those described above may be included.

  More specifically, the operation screen shown in FIG. 6 (hereinafter referred to as a control type selection screen) is drawn on the display of the user terminal 3, and the user selects the selection button Bt1 displayed on the control type selection screen. , Bt2, and Bt3 are touched to select a control type.

The individual control type is a type for individually controlling the air conditioner in the house H, and is selected by touching a selection button Bt3 on the control type selection screen. When the individual control type is selected, a setting panel (not shown) is drawn on the display of the user terminal 3, and the user designates an air conditioner to be individually controlled through the setting panel, and starts and stops the air conditioner. Switching, operation mode switching such as cooling / heating / dehumidification, and operation control values such as temperature and humidity can be set. When the operation on the setting panel is completed, a command corresponding to the operation is transmitted from the user terminal 3 to the home server 1, and the home server 1 that has received the command specifies the air conditioner that is the object of individual control. The air conditioner is controlled according to the command.
The collective control type is a type that collectively controls the air conditioners in the house H, and is selected by touching the selection button Bt2 on the control type selection screen. When the collective control type is selected, the home server 1 executes control to turn off all the air conditioners in the house H.

  The schedule control type is a type that controls the daily operation of each air conditioner in the house H according to a preset schedule, and is selected by touching the selection button Bt1 on the control type selection screen. Here, the schedule defines which air conditioner is operated under what operating condition in which time zone of the day, and is a time schedule related to the air conditioner operation control shown in FIG.

  More specifically, the schedule is configured by collecting the individual schedules for each air conditioner, which stipulate for each air conditioner what load is to be operated at which time zone. In this sense, it can be said that the schedule defines a period during which each of the plurality of air conditioners is operated under an operation condition in which the load is a predetermined amount or more.

Here, “load” means an electric power load, and “operate under an operating condition in which the load is a predetermined amount or more” means that the electric power more than the rated power of the air conditioner is consumed after consuming start-up power of the air conditioner. It means that the vehicle is operated under operating conditions that consume it, that is, the air conditioner is started. However, the present invention is not limited to this, and “operating under an operating condition in which the load is equal to or greater than a predetermined amount” is an operating condition in which the cooling temperature is set to a predetermined value or lower, or an operation in which the heating temperature is set to a predetermined value or higher. It may mean that the vehicle is operated under conditions.
In the following description, an operating condition that consumes power equal to or higher than the rated power of the air conditioner after consuming the starting power of the air conditioner is referred to as a standard operating condition.

  And when schedule control is selected, the home server 1 controls the driving | running state of each air conditioner in the house H according to a schedule. More specifically, the home server 1 reads the schedule from the memory 1b, and specifies the operating condition at the time of execution of the regular control for each air conditioner. Here, the regular control is control that the home server 1 executes at regular time intervals in schedule control, and is executed at 0 minutes, 15 minutes, 30 minutes, and 45 minutes every hour in the present system S. However, the execution interval of the regular control is not limited to the above case, and can be arbitrarily set.

  In each regular control, the home server 1 transmits a control signal for controlling the operation state to each of the four air conditioners so that each air conditioner starts to operate under the operation condition specified for each air conditioner. More specifically, when the home server 1 controls each air conditioner according to the schedule shown in FIG. 7, in the regular control at 13:00, the home server 1 keeps the air conditioner B and the air conditioner D in a stopped state. Then, the air conditioner A is activated, and the already activated air conditioner C is maintained in the activated state. That is, the air conditioners operated under the standard operation conditions in the regular control at 13:00 are the air conditioner A and the air conditioner C.

  Then, the home server 1 transmits an activation request signal to the air conditioner A in the regular control at 13:00. Here, the activation request signal is an example of an operation request signal, and specifically, a control signal for operating under standard operating conditions. Then, when the air conditioner A receives the activation request signal through the home network 5, it starts to operate under the standard operation condition in response to the activation request signal (in other words, it starts up).

  In this system S, when the schedule control type is selected, the selection of the operation mode is also requested. The operation mode is a control policy in the schedule control, and a plurality of operation modes are set for the air conditioners in the house H. The user can select an operation mode by inputting in the mode input field N1 on the control type selection screen. More specifically, when a pull-down button P1 provided on the right side of the mode input field N1 is touched, an operation mode list L1 is displayed. The user touches one of the plurality of operation modes presented in the operation mode list L1, and inputs the operation mode designated by the user in the mode input field N1.

There are four types of operation modes that can be selected in the system S: mode X, mode Y, mode Z, and user setting mode. However, these modes are merely examples of operation modes, and modes other than those described above may be included.
And in this system S, the above-mentioned schedule is prepared for every operation mode. That is, when performing the schedule control in a certain operation mode, the home server 1 of the present system S controls each air conditioner in the house H according to the schedule corresponding to the certain operation mode.

  Of the operation modes that can be selected in the system S, the mode X is a mode adapted to the user's lifestyle, and the schedule corresponding to the mode X is mainly activated by an air conditioner installed in a frequently used room. It is a content to be made. Mode Y is a mode that matches the user's life rhythm, and the schedule corresponding to mode Y has the content of changing the air conditioner to be controlled according to the time zone. Mode Z is a mode that emphasizes comfort, and the schedule corresponding to mode Z is to continuously start all the air conditioners installed in the house H for 24 hours and set the temperature of each air conditioner according to the life rhythm of the user. It is the content to control. The user setting mode is a mode in which the user can set a schedule independently, and the schedule corresponding to the user setting mode has original contents customized by the user.

  When the selection of the operation mode is completed, the schedule screen illustrated in FIG. 7 is drawn on the display of the user terminal 3, and the schedule corresponding to the operation mode selected by the user is displayed on the schedule screen. Furthermore, in the state drawn on the schedule screen on the display of the user terminal 3, the user can correct the schedule displayed on the schedule screen.

  More specifically, when the user touches a range to be corrected in the schedule displayed on the schedule screen, the update panel shown in FIG. 8 is popped up. Through this update panel, the user can make corrections to the correction target range in the schedule, specifically the operating conditions, the start and end times of the time zone to which the operating conditions are applied, and the operating conditions related to the correction. Enter the air conditioner that applies. When the user touches the update button Bt4 in the update panel at the time when the input operation of the correction items is completed, a schedule update request is transmitted from the user terminal 3 to the home server 1, and the request is received on the home server 1 side. When received, the schedule stored in the memory 1b is corrected and updated according to the content of the correction operation by the user.

  The schedule of each operation mode can be corrected by the procedure as described above. On the other hand, the schedule of each operation mode is a default schedule when no correction has been made. If it demonstrates concretely, the individual schedule regarding each air-conditioner will have the content corresponding to the classification of the installation place of each said air-conditioner among default schedules. More specifically, the installation location and type of each air conditioner in the house H are as shown in FIG. 12. For example, the installation location of the air conditioner A is “Japanese-style room”. When the schedule is the default, the individual schedule of the air conditioner A is a schedule corresponding to the “Japanese room” that is the type of the installation location of the air conditioner A.

By the way, when the schedule control is selected in the system S, the home server 1 further designates a control mode for controlling the operation states of the plurality of air conditioners. As control modes prepared in the system S, there are a number limit mode and a non-number limit mode.
The user can specify the control mode by inputting in the mode input field N2 in the control type selection screen shown in FIG. More specifically, when a pull-down button P2 provided on the right side of the mode input field N2 is touched, a control mode list L2 is displayed. The user touches one of the two control modes presented in the control mode list L2 and inputs the control mode designated by the user in the mode input field N2.

  When the number limit mode is designated, the number limit operation for limiting the number of air conditioners in the activated state is performed. Specifically, in the limited number operation, it is a transmission destination when the home server 1 transmits the activation request signal according to the total power consumption of the house H at the time when the regular control at 0 hour per hour is executed. The number of air conditioners can be limited.

  More specifically, the home server 1 obtains data indicating the current total power consumption of the house H from the power data logger 7 when N hour 0 minutes (N is an integer of 0 to 23), The control air conditioner in the regular control at N o'clock is specified from the schedule. Here, the controlled air conditioner means a control target device that is operated under the standard operating condition in the regular control at N o'clock. After that, the home server 1 is in the house H at the time of execution of the regular control at 0:00 when all the controlled air conditioners are temporarily started based on the total power consumption indicated by the data obtained from the power data logger 7. The total power consumption consumed in is calculated.

  When the calculation result (hereinafter, calculated power) of the total power consumption by the home server 1 exceeds the above-mentioned upper limit power, specifically, the contract power of the house H stored in the memory 1b, the home server 1 In the regular control at N o'clock, the activation request signal is transmitted to only some of the controlled air conditioners. More specifically, in the limited number mode, the home server 1 specifies the set number stored in the memory 1b. This set number is the number set in advance as the maximum number of controlled air conditioners that are operated under standard operating conditions at the time of execution of the regular control at 0:00 when the calculated power exceeds the upper limit power. Further, the set number is specified based on the number limit pattern stored in the number limit pattern storage area 1s of the memory 1b and the number of air conditioners in the house H.

  After specifying the set number, when the home server 1 determines that the number of the controlled air conditioners specified from the schedule exceeds the set number and the calculated power exceeds the upper limit power, a regular example of N hours 0 minutes Limit the number of controlled air conditioners that operate under standard operating conditions. That is, when the above determination result is obtained, the home server 1 controls a part of the control air conditioner so that only the control air conditioners corresponding to the set number are operated under the standard operation condition in the regular control at N: 00: 00. Strictly speaking, the activation request signal is transmitted only to a part of the non-activated control air conditioners. At this time, the home server 1 transmits an activation request signal to only some of the controlled air conditioners so that a controlled air conditioner having a higher priority is selected as the controlled air conditioner to be operated under the standard operating condition. As described above, since the air conditioner to be operated under the standard operation condition in the number-limited operation is determined according to the priority order, in the present system S, it is possible to execute control with improved convenience for the user.

  Thereafter, after a predetermined time has elapsed from the execution time of the regular control at N o'clock, the home server 1 has received the activation request signal among the air conditioners specified as the control air conditioner in the regular control at N o'clock. Send a start request signal to the rest of the air conditioner. In particular, in the present system S, after the execution of the regular control at N o'clock 0, the operation is performed under the standard operating condition at the time of execution of the next regular control (that is, the regular control at N o'clock 15 minutes, 30 minutes, and 45 minutes). An activation request signal is transmitted to the remaining air conditioners of the control air conditioners so that the number of control air conditioners to be increased.

  The above procedure will be described in detail with reference to the schedule illustrated in FIG. 9. In the regular control executed at 18:00 (hereinafter, regular control at 18:00), the home server 1 operates from the power data logger 7 to 18:00. Data indicating the total power consumption of the house H at the time is obtained. On the other hand, in the schedule illustrated in FIG. 9, the control air conditioners in the regular control at 18:00 are set to the air conditioners A, B, C, and D. That is, in the schedule shown in FIG. 9, the number of controlled air conditioners in the regular control at 18:00 is set to four.

  Thereafter, when the home server 1 starts all of the air conditioners A, B, C, and D based on the total power consumption of the house H at 18:00 indicated by the data obtained from the power data logger 7, the time is 18:00. The total power consumed in the house H, that is, the calculated power is calculated. Specifically, since the air conditioner A and the air conditioner C are already activated at the time of 18:00, the total power consumption of the house at the time of 18:00 indicated by the data obtained from the power data logger 7 is The calculated power is calculated by adding the respective power consumptions.

On the other hand, the home server 1 specifies the set number described above based on the number limit pattern stored in the memory 1b and the number of air conditioners in the house H. More specifically, two number restriction patterns shown in FIG. 10 are stored in the number restriction pattern storage area 1s of the memory 1b. Here, it is possible for the user to freely decide which of the two number limit patterns is used, but in the following, the upper pattern (in FIG. 10, among the number limit patterns illustrated in FIG. 10). A method for determining the set number using the number limit pattern 1) will be described as an example.
In addition, the number of the number restriction patterns stored in the number restriction pattern storage area 1s is not limited to two and can be determined to an arbitrary number. Further, the content of the number restriction pattern illustrated in FIG. 10 is merely an example, and is not limited to the content illustrated in FIG. That is, the set number specified from the number limit pattern can be determined as an arbitrary number.

  Referring to the number-of-units restriction pattern 1, among the values indicating the number of operating units, the value described in the column “current” is equivalent to the set number, and the number of air conditioners installed in the house H is four. In the case, there are three. On the other hand, in the schedule illustrated in FIG. 9, the number of controlled air conditioners in the regular control at 18:00 is four, which exceeds the set number (three). In such a case, when all four air conditioners are activated, the calculated value of the total power consumption of the house H at 18:00, that is, when the calculated power exceeds the upper limit power, the home server 1 performs regular control at 18:00. , The activation request signal is transmitted to only some of the controlled air conditioners so that only the three controlled air conditioners are activated.

  More specifically, the control air conditioners in the regular control at 18:00 are the air conditioners A, B, C, and D, but the air conditioners A and C are activated at 18:00. For this reason, the air conditioner B and the air conditioner D are candidates for the control air conditioner to which the activation request signal is newly transmitted in the regular control at 18:00. On the other hand, the number of controlled air conditioners (4 units) in the regular control at 18:00 exceeds the set number (3 units). In such a case, when the calculated power when all four air conditioners are activated exceeds the upper limit power, the home server 1 applies only to one of the air conditioners B and D in the regular control at 18:00. Send an activation request signal.

  Comparing the priorities of the air conditioner B and the air conditioner D, the priority order of the air conditioner D is higher than the priority order of the air conditioner B as shown in FIG. Therefore, in the regular control at 18:00, the home server 1 transmits an activation request signal only to the air conditioner D. As a result, in the regular control at 18:00, the number of units corresponding to the set number, that is, the three air conditioners A, C, and D operate under the standard operating conditions, while the remaining one air conditioner B enters the operation standby state.

  Here, referring again to the number-of-units restriction pattern 1, among the values indicating the number of operating units, the values described in the columns labeled “next time” and “next time” are operated under standard operating conditions in the regular control after the next time. Indicates the number of additional controlled air conditioners. Here, the additional number is the number of controlled air conditioners to which the activation request signal is transmitted in the regular control after the next time among the controlled air conditioners that are set in operation standby in the regular control at N: 0. The next regular control is a regular control at N: 15, and the next regular control is a regular control at N: 30.

  In the case where the number of air conditioners installed in the house H is four, the additional number in the next regular control is one. Therefore, when the start request signal is transmitted only to the air conditioner D among the air conditioners B and D in the regular control at 18:00 because the calculated power at the time of 18:00 exceeds the upper limit power, the home server 1 In the regular control at 15 minutes, an activation request signal is transmitted to the air conditioner B. As a result, the number of air conditioners operating under the standard operating conditions increases, and after a predetermined time has elapsed since the regular control at 18:00, all the air conditioners initially specified as control air conditioners at the regular control at 18:00 are under the standard operating conditions. I will drive.

  As described above, when the number limit mode is designated as the control mode, the number of air conditioners to be activated simultaneously is limited according to the power consumption state in the house H, and the number is increased step by step as time passes. The air conditioner control by the home server 1 is executed. As a result, it is possible to gradually increase the number of air conditioners operated under standard operating conditions according to the total power consumption in the house H while monitoring the total power consumption in the house H.

  On the other hand, when the non-unit limit mode is designated as the control mode, the home server 1 controls each air conditioner according to the schedule regardless of the power consumption status in the house H. That is, when the non-unit limit mode is designated, the home server controls the control air conditioner specified from the schedule in the regular control at N: 00: 00 regardless of the magnitude of the calculated power at the time of execution of the regular control at 00:00. A start request signal is transmitted to the control air conditioner so that everything is operated under standard operating conditions.

  As described above, in the present system S, it is possible to switch the control mode of the schedule control according to the user's intention. As a result, for example, it is possible to specify the number limit mode if you want to practice energy savings, and to specify the non-number limit mode if you want to fully use the air conditioner function. Realized.

<< Configuration of each part of the system >>
Next, the configuration of each part of the system S, that is, the air conditioner, the user terminal 3, and the home server 1 will be described from the functional aspect with reference to FIG.
(Air conditioner)
Each of the four air conditioners includes a control signal receiver 31, a controller 32, and a response signal transmitter 33, as shown in FIG. The control signal receiving unit 31, the control unit 32, and the response signal transmitting unit 33 are configured by a microcomputer and a control circuit built in the air conditioner, and a communication interface. The control signal receiving unit 31 receives a control signal transmitted from the home server 1 via the home network 5. The control unit 32 controls the air conditioner body according to the control signal received by the control signal receiving unit 31. The response signal transmission unit 33 generates a response signal indicating the operation state of the air conditioner and transmits the response signal to the home server 1. In particular, in the present system S, when the control signal receiving unit 31 receives the activation request signal as the control signal and the control unit 32 controls the air conditioner body, the response signal transmitting unit 33 determines that the air conditioner as the control target is the standard operating condition. A response signal is transmitted toward the home server 1 to indicate that the vehicle has started driving.

(User terminal)
As illustrated in FIG. 11, the user terminal 3 includes an operation reception unit 41, a data generation unit 42, a data transmission unit 43, a data reception unit 44, and a display unit 45.
The operation receiving unit 41 includes a touch panel provided in the user terminal 3 and receives a user input operation. The operation received by the operation receiving unit 41 includes an input operation performed by the user in order to specify a control mode or an operation mode. An input operation for designating a control mode or an operation mode is performed through a control type selection screen shown in FIG. Further, the operation received by the operation receiving unit 41 includes an input operation performed by the user in order to correct the schedule stored in the memory 1b of the home server 1. The input operation for correcting the schedule is performed through the update panel shown in FIG.

  The data generation unit 42 includes a CPU of the user terminal 3, a memory, and a program installed in the user terminal 3, and generates data indicating the content of the user input operation received by the operation reception unit 41. The data generated by the data generation unit 42 includes a control mode and operation mode setting request designated by the user, and a schedule correction request.

  The data transmission unit 43 transmits the data generated by the data generation unit 42 to the home server 1 through the home network 5, and is installed in the CPU, memory, communication interface, and user terminal 3 of the user terminal 3. Consists of a communication program. Here, the data transmitted by the data transmission unit 43 to the home server 1 includes a control mode and operation mode setting request specified by the user, and a schedule correction request. These data are transmitted to the home server 1 side as an HTTP request. More specifically, the data transmission unit 43 transmits the transmission target data to the home server 1 in accordance with REST (Representational State Transfer).

  The data receiving unit 44 receives data transmitted from the home server 1 and includes a CPU of the user terminal 3, a memory, a communication interface, and a communication program installed in the user terminal 3. The data received by the data receiving unit 44 from the home server 1 includes the above-described confirmation screen data. In the system S, the confirmation screen data received by the data receiving unit 44 from the home server 1 is XML format data.

  The display unit 45 expands the confirmation screen data received by the data reception unit 44 and draws the confirmation screen illustrated in FIG. 15 on the display of the user terminal 3, specifically, the touch panel. The display unit 45 includes a CPU of the user terminal 3, a memory, and a program installed in the user terminal 3. Here, since the confirmation screen data received by the data receiving unit 44 is data in XML format, the display unit 45 can render the confirmation screen in a display format according to the specifications of the user terminal 3. It becomes possible.

  The confirmation screen will be described. As shown in FIG. 15, the operation state of each air conditioner is displayed on the screen in association with the installation location of each air conditioner. The operation state of the air conditioner displayed on the confirmation screen is the operation state indicated by the response signal transmitted by the response signal transmission unit 33 of the air conditioner, that is, the operation when controlled based on the control signal transmitted from the home server 1. State. In addition, since the operation state of each air conditioner is displayed in association with the installation location of each air conditioner, the user clearly sees the confirmation screen and where the air conditioner installed is in what operation state at present. It becomes possible to grasp. Such an effect is achieved by generating the above confirmation screen data so as to display the operation state of each air conditioner in association with the installation location of the air conditioner when generating the confirmation screen data on the home server 1 side. The

  In addition, when the schedule control type is specified as the control type and the number limit mode is specified as the control mode, the start request signal is received from among the operation states of the air conditioners displayed on the confirmation screen, and the standard operation is performed. About the driving | running state of the air conditioner which is drive | operating on condition, as shown in FIG. 15, it is displayed as "in operation", and also setting temperature is displayed together. On the other hand, as shown in FIG. 15, “operation standby” is displayed for the operation state of the air conditioner that is subject to the number restriction and is in the operation standby state in the regular control executed most recently. Thereby, schedule control is executed as control of a plurality of air conditioners installed in the house H, and when the number limit mode is specified, the user can determine which air conditioner is activated and which air conditioner is deactivated. It is possible to confirm through the confirmation screen.

  Further, as described above, an activation request signal is scheduled to be transmitted in the next and subsequent regular controls, as described above, for air conditioners that have been subject to the number restriction in the most recent regular control. Therefore, for the air conditioner subject to the number restriction in the most recently executed regular control, the time until the start request signal is transmitted together with the operation state, that is, the time until the start from the current time (hereinafter referred to as operation standby) Time) is displayed on the confirmation screen. Thus, by displaying the operation standby time for the air conditioner subject to the number restriction in the regular control executed most recently, the user can grasp when the air conditioner is activated. You can know the time when you can use each room comfortably.

The screen illustrated in FIG. 15 is merely an example of a confirmation screen, and the design and layout of the confirmation screen can be arbitrarily set. In particular, the display format of the operation state of each air conditioner, the presence / absence of display of the operation standby time described above, and the like can be freely set without limitation. In addition, the information displayed on the confirmation screen is not limited to the operation state and operation standby time of each air conditioner, but other information such as the load (power consumption) of each air conditioner, the currently applied operation mode and control mode, etc. May be displayed.
Furthermore, when the schedule control type is specified as the control type and the number limit mode is specified as the control mode, the future power load is predicted from the past actual data and executed, for example, several hours later. For air conditioners that may be subject to unit restrictions in regular control, information indicating that may be displayed on the confirmation screen. From the same viewpoint, a caution message indicating that there is a possibility that the limited number of operations may be executed in the regular control executed after several hours may be displayed on the confirmation screen.

(Home server)
As shown in FIG. 11, the home server 1 includes a setting request receiving unit 11, an operation mode setting unit 12, a control mode setting unit 13, a storage unit 14, a control air conditioner specifying unit 15, and a power consumption calculating unit 16. A power consumption data acquisition unit 17, a determination unit 18, a control signal transmission unit 19, a response signal reception unit 20, an operation state identification unit 21, a communication protocol switching unit 22, a schedule update unit 23, and a confirmation And a screen data transmission unit 24.

The setting request receiving unit 11 receives a setting request for the operation mode and the control mode from the user terminal 3, and includes a CPU 1 a of the home server 1, a memory 1 b, a communication interface 1 c, and a communication bundle installed in the home server 1. Consists of.
The operation mode setting unit 12 receives the operation mode setting request from the user terminal 3 by the setting request receiving unit 11 so that the operation mode is set to the mode on the specified side among the modes X, Y, Z and the user setting mode. It is to set. The control mode setting unit 13 sets the control mode to the designated mode of the number-limited mode and the non-number-limited mode when the setting request receiving unit 11 receives the control mode setting request from the user terminal 3. Is. Note that each of the operation mode setting unit 12 and the control mode setting unit 13 includes a CPU 1 a of the home server 1, a memory 1 b, a communication interface 1 c, and an air conditioner control bundle installed in the home server 1.

  The memory | storage part 14 consists of the memory 1b of the home server 1, and memorize | stores a schedule according to operation mode. In addition, the storage unit 14 stores a device ID as identification information of each air conditioner installed in the house H. In addition, the storage unit 14 stores the installation location of each air conditioner in the house H. In this system S, as shown in FIG. 12, the device ID and the installation location of each air conditioner are stored in the storage unit 14 in a state of being associated with each other. In this way, the identification information of each air conditioner and the installation location are associated with each other, so it is possible to properly execute the air conditioner control after understanding where the air conditioner is installed and under what operating conditions. It becomes. Here, the type is determined for the installation location of each air conditioner, and the priority order is determined according to the type.

  Then, as shown in FIG. 12, the storage unit 14 is in a state in which the device ID of each air conditioner, the installation location and type of each air conditioner, and the priority order determined for each air conditioner according to the type are associated with each other. Remember. Furthermore, the memory | storage part 14 has memorize | stored the unit number restriction pattern which prescribed | regulated the corresponding relationship between the set number of units | sets mentioned above and the number of air conditioners of the house H. FIG. In other words, the storage unit 14 stores the set number set for each air conditioner. Furthermore, the storage unit 14 stores contract power as the upper limit power.

  The control air conditioner specifying unit 15 corresponds to the specifying unit of the present invention, and includes a CPU 1a of the home server 1, a memory 1b, and an air conditioner control bundle. When the schedule control is set as the control mode, the control air conditioner specifying unit 15 reads the schedule stored in the storage unit 14, and the regular time of N o'clock from four air conditioners installed in the house H A control air conditioner that is operated under standard operating conditions at the time of execution of control is specified.

The power consumption calculation unit 16 calculates the total power consumption, that is, the calculated power consumed in the house H at the time of execution of the regular control at 00:00 when all the control air conditioners specified by the control air conditioner specifying unit 15 are activated. Is to be calculated. More specifically, the power consumption data acquisition unit 17 acquires data from the power data logger 7 at N hours 0 minutes. The power consumption calculation unit 16 analyzes the data acquired by the power consumption data acquisition unit 17 and calculates the total power consumption actually used in the house H at N: 00: 00. Thereafter, the power consumption calculation unit 16 calculates the calculated power based on the calculated total power consumption.
The power consumption calculation unit 16 and the power consumption data acquisition unit 17 cooperate to form the calculation unit of the present invention, and the CPU 1a, the memory 1b, the communication interface 1c, the air conditioner control bundle, and the communication of the home server 1, respectively. Consists of bundles.

  The determination unit 18 determines whether or not the calculated power calculated by the power consumption calculation unit 16 exceeds the contract power as the upper limit power stored in the storage unit 14. The CPU 1 a and the memory 1 b of the home server 1. And an air conditioner control bundle.

The control signal transmission unit 19 transmits a control signal for controlling the operation state of the air conditioner to each of the air conditioners installed in the house H. The control signal transmission unit 19 includes a CPU 1a of the home server 1, a memory 1b, an air conditioner control bundle, and a communication bundle.
In the present system S, the communication protocol used when the control signal transmission unit 19 transmits the control signal can be switched by the communication protocol switching unit 22 realized by the function of the OSGi framework 103 described above. That is, in the present system S, the control signal transmission unit 19 switches the communication protocol used when transmitting the control signal to the air conditioner according to the communication protocol used by the destination air conditioner. As described above, in the present system S, the communication protocol can be switched according to the communication partner, so that the user can request the home server 1 to control each air conditioner without being aware of the difference in the communication protocol. It becomes possible.

When the schedule control type is designated as the control type, the control signal transmission unit 19 is in an unstarted state among the controlled air conditioners identified by the controlled air conditioner identifying unit 15 at the time of execution of the regular control at N: 0. A start request signal is transmitted to the air conditioner.
Furthermore, when the number limit mode is designated as the control mode, the number of controlled air conditioners specified by the controlled air conditioner specifying unit 15 exceeds the set number stored in the storage unit 14, and the calculated power is the upper limit power. When the determination unit 18 determines that the value exceeds the limit, the control signal transmission unit 19 transmits a start request signal to only some of the controlled air conditioners at the time of execution of the regular control at N: 00: 00. To do.

  More specifically, the determination unit 18 determines that the control air conditioner in the regular control at N o'clock 0 exceeds the set number and the calculated power at the execution time of the regular control exceeds the upper limit power. At this time, the number of control air conditioners to which the activation request signal is transmitted from the control signal transmission unit 19 is limited. That is, when the above-described requirement (that is, the requirement for limiting the number of units) is satisfied, the control signal transmission unit 19 performs only the control air conditioners corresponding to the set number of units at the standard operation condition at the time of execution of the regular control. An activation request signal is transmitted to only some of the controlled air conditioners so as to be operated. At this time, the control signal transmission unit 19 reads the priority order of each air conditioner stored in the priority order storage area 1r of the memory 1b, so that the control air conditioner having a higher priority order is selected as the control air conditioner that is operated under the standard operating conditions. The start request signal is transmitted to only some of the controlled air conditioners.

  When the number of units is limited in the regular control at 00:00, the control signal transmission unit 19 sends the activation request signal to the remaining control air conditioners after a predetermined time has elapsed since the execution of the regular control. It is sent to the air conditioner (strictly speaking, the control air conditioner is not activated). More specifically, the control signal transmission unit 19 transmits an activation request signal to the control air conditioner that has not been activated so that the number of control air conditioners that are operated under the standard operation condition increases at the time of execution of the regular control from the next time onward. . More specifically, the control signal transmission unit 19 sets the activation request signal in an unactivated state so that the number of controlled air conditioners that are operated under the standard operation condition in the regular control at N: 15 and the regular control at N: 30 is increased stepwise. Send to the control air conditioner.

The response signal receiving unit 20 receives a response signal transmitted from the air conditioner, and includes a CPU 1a of the home server 1, a memory 1b, an air conditioner control bundle, and a communication bundle. The operating state specifying unit 21 analyzes the response signal received by the response signal receiving unit 20 and specifies the operating state of the air conditioner that is the transmission destination of the response signal, and includes the CPU 1a, the memory 1b, and the air conditioner of the home server 1. It is composed of a control bundle. In this system S, the response signal receiving unit 20 periodically receives the response signal from the air conditioner, and the response signal is transmitted in response to the control signal from the control signal transmitting unit 19 being received on the air conditioner side. The response signal is also received.
Further, in the present system S, when the schedule control type is designated as the control type, the control air conditioner that has received the activation request signal from the control signal transmission unit 19 indicates a response signal to indicate that it has started operating under the standard operating conditions. Send. And the response signal receiving part 20 receives the said response signal, and the driving | running state specific | specification part 21 specifies that the driving | running state of said control air conditioner is "operating."

On the other hand, when the number limit mode is designated as the control mode, the control air conditioner subjected to the number limit in the regular control transmits a response signal to indicate that it is in an operation standby state. And the response signal receiving part 20 receives the said response signal, and the driving | running state specific | specification part 21 specifies that the driving | running state of said control air-conditioner is "during driving standby".
In addition, the air conditioner that has already been activated at the time of execution of the regular control transmits a response signal to indicate that it is already operating under standard operating conditions. And the response signal receiving part 20 receives the said response signal, and the driving | running state specific | specification part 21 specifies that the driving | running state of said control air conditioner is "operating."

  As described above, in the home server 1 of the present system S, the response signal receiving unit 20 receives the response signal from the air conditioner, and the operation state specifying unit 21 specifies the operation state of the air conditioner that is the transmission source of the response signal. As a result, among the air conditioners installed in the house H, when the number limit mode is specified and the number of air conditioners to be operated under the standard operating conditions is restricted, the home server 1 and the air conditioners subject to the number restriction It becomes possible to distinguish clearly from other air conditioners (in other words, activated air conditioners).

  In the present system S, the communication protocol used when the response signal receiving unit 20 receives the response signal from the air conditioner can also be switched by the communication protocol switching unit 22. Therefore, in the present system S, it is possible to switch the communication protocol according to the transmission source of the response signal. Therefore, the user does not need to be aware of the transmission source of the response signal, that is, the communication protocol of each air conditioner. It becomes possible to grasp the driving state.

The schedule update part 23 updates the schedule memorize | stored in the memory | storage part 14, and is comprised by CPU1a of the home server 1, the memory 1b, the bundle for air-conditioner control, and the bundle for communication. The schedule update unit 23 communicates with the user terminal 3 to receive a correction request for the schedule, and updates the schedule based on the correction request.
More specifically, the schedule update unit 23 analyzes the correction request and specifies the schedule to be corrected and the correction range. More precisely, the schedule update unit 23 specifies a schedule to be corrected, then corrects which individual schedule among the schedules is corrected, and further corrects operating conditions in which time zone in the individual schedules. To identify. Then, the schedule update unit 23 reads the schedule to be corrected from the schedules stored in the storage unit 14, and updates (corrects) the schedule according to the specified correction content.

  The confirmation screen data transmission unit 24 generates confirmation screen data and transmits it to the user terminal 3 in order to draw a confirmation screen indicating the operation state of each air conditioner identified by the operation state identification unit 21 on the user terminal 3. To do. The confirmation screen data transmission unit 24 includes a CPU 1 a of the home server 1, a memory 1 b, an air conditioner control bundle installed in the home server 1, and a communication bundle. In the present system S, the confirmation screen data transmission unit 24 transmits XML format data as confirmation screen data. For this reason, when the user terminal 3 receives the confirmation screen data, the confirmation screen is drawn in a display format according to the specifications of the user terminal 3.

  In addition, the confirmation screen data transmission unit 24 generates confirmation screen data so that the operation state of each air conditioner is displayed in association with the installation location of the air conditioner on the confirmation screen drawn on the user terminal 3. In executing such processing, the confirmation screen data transmission unit 24 reads the installation location stored in the installation location storage area 1q in the memory 1b, and the operation state and the installation location of each air conditioner are generated when the confirmation screen data is generated. Data indicating each of the operation state and the installation information is incorporated in the confirmation screen data so as to be displayed in a corresponding form.

In addition, when there is an abnormal air conditioner that does not transmit a response signal even though the control signal is transmitted, the confirmation screen data transmission unit 24 receives the air conditioner corresponding to the abnormal air conditioner on the confirmation screen. Confirmation screen data is generated so that an error is displayed. Accordingly, the user can check the presence of the abnormal air conditioner and the installation location of the abnormal air conditioner by looking at the confirmation screen.
Further, when the number limit mode is designated as the control mode, as described above, the operation standby time is displayed on the confirmation screen for the air conditioner subjected to the number limit in the regular control at 0:00. It becomes like this. That is, the confirmation screen data transmission unit 24 identifies the air conditioner subject to the number restriction, calculates the operation standby time for the identified air conditioner, and incorporates the data indicating the operation standby time in the confirmation screen data.

<< Air conditioner control method >>
Next, an air conditioner control method used in the present system S described above will be described with reference to FIGS.
The air conditioner control method used in the system S is an example of the energy consuming equipment control method according to the present invention. More specifically, the air conditioner control method is applied in the air conditioner control process executed in the system S. For this reason, below, the procedure of an air-conditioner control process is demonstrated as description of an air-conditioner control method.

  The air conditioner control process starts, for example, when the air conditioner control program is activated on the user terminal 3 side by a program activation operation by the user. When the air conditioner control program is activated, a control type selection screen illustrated in FIG. 6 is drawn on the display of the user terminal 3. The user selects a control type by operating the user terminal 3 while viewing the screen. With this selection operation, the control type selection result is transmitted from the user terminal 3 to the home server 1.

  The subsequent procedure is as shown in FIG. 13. First, the home server 1 receives a control type selection result from the user terminal 3, and specifies the selected control type (S001). Here, when the individual control type is selected as the control type, the home server 1 performs individual control (S002). Note that when executing individual control, the user operates the user terminal 3 to designate an air conditioner and a control condition that are targets of individual control. Thereafter, data indicating the content designated by the user is transmitted from the user terminal 3 to the home server 1. Finally, the home server 1 individually controls the air conditioner designated as the control target based on the data received from the user terminal 3 under the designated control conditions.

When the collective control type is selected as the control type, the home server 1 executes collective control and transmits a control signal for stopping to all the air conditioners in the house H (S003).
On the other hand, when the schedule control type is selected as the control type, the user further operates the user terminal 3 while specifying the operation mode and the restriction mode while viewing the control type selection screen shown in FIG. When the designation operation is accepted by the user terminal 3, a setting request for the operation mode and the control mode is transmitted from the user terminal 3 to the home server 1. The home server 1 receives the above setting request, specifies the mode selected by the user among the plurality of operation modes, and specifies the control mode designated by the user among the two control modes (S004).

  Thereafter, the home server 1 acquires a device ID that is identification information of each air conditioner installed in the house H (S005). More specifically, the device ID is stored as list information in the memory 1b of the home server 1, and the device ID of each air conditioner is acquired by reading the information stored in the memory 1b. After acquiring the device ID, the home server 1 executes schedule control (S006). This schedule control step S006 is a step in which the above-described regular control is executed, and is repeatedly executed every time a predetermined time elapses, unless there is an operation of switching the control type on the user terminal 3 side (No in S007). (Yes in S008). In the present system S, as described above, the schedule control step S006 is executed every hour at 0 minutes, 15 minutes, 30 minutes, and 45 minutes.

Next, the flow of the schedule control step S006 will be described with reference to FIG.
In the schedule control step S006, first, the home server 1 reads the schedule corresponding to the operation mode specified in the previous step S004 from the memory 1b, that is, the storage unit 14 (S011). Thereafter, the home server 1 identifies a control air conditioner that is operated under the standard operating conditions at the time of control of the air conditioner, that is, at the present time, based on the read schedule (S012).

  Then, after specifying the control air conditioner, the home server 1 executes the subsequent processing according to the control mode specified in the previous step 004 (S013). More specifically, when the non-unit restriction mode is designated as the control mode, the home server 1 transmits an activation request signal to the control air conditioner so that all the specified control air conditioners are operated under the standard operation conditions. (S017). The control air conditioner that has received the activation request signal transmits a response signal to indicate that it has started operating under the standard operating conditions, and the home server 1 receives the response signal from the control air conditioner (S021).

  On the other hand, when the number limit mode is designated as the control mode, the home server 1 uses the power consumed in the house H when the schedule control step S006 is executed when all the specified controlled air conditioners are operated under the standard operating conditions. That is, the calculated power is calculated (S014). Thereafter, the home server 1 reads the set number stored in the memory 1b, and determines whether or not the specified number of control air conditioners exceeds the set number (S015). Further, the home server 1 reads the upper limit power stored in the memory 1b, and determines whether or not the calculated power exceeds the upper limit power (S016). When the number of controlled air conditioners does not exceed the set number (No in S015), or when the calculated power does not exceed the upper limit power (No in S016), the home server 1 uses all the specified controlled air conditioners under standard operating conditions. An activation request signal is transmitted to the control air conditioner so as to be operated (S017). And the home server 1 receives the response signal which shows having started driving | running on standard driving | running conditions from the control air conditioner which received the starting request signal (S021).

  On the other hand, when the number of controlled air conditioners exceeds the set number (Yes in S015) and it is determined that the calculated power exceeds the upper limit power (Yes in S016), the home server 1 sets The number-limited operation is performed in which only the number of control air conditioners corresponding to the number is operated under the standard operation conditions. The subsequent procedure differs slightly depending on whether or not the number-limited operation has already been performed in the previous schedule control step S006 (S018).

  When the limited number of operations is not performed in the previous schedule control step S006 (No in S018), the home server 1 activates a start request signal so that only the controlled air conditioners corresponding to the set number are operated under the standard operating conditions. The control air conditioner as the transmission destination is limited to some air conditioners. For this reason, the home server 1 reads the priority order of each air conditioner from the memory 1b, and specifies the transmission destination of the activation request signal based on the priority order (S019). Thereafter, the home server 1 transmits the activation request signal only to the air conditioner specified as the transmission destination of the activation request signal among the controlled air conditioners (S020). And the home server 1 receives the response signal which shows having started driving | running on standard driving | running conditions from the control air conditioner which received the starting request signal (S021).

  On the other hand, if the number restriction has been performed in the previous schedule control step S006 (Yes in S018), the home server 1 selects the current schedule from the air conditioners subject to the number restriction in the previous schedule control step S006. The air conditioner that is the transmission destination of the activation request signal in the control step S006 is specified (S022). Also at this time, the home server 1 reads the priority order of each air conditioner from the memory 1b, and specifies the transmission destination of the activation request signal based on the priority order. Thereafter, the home server 1 transmits an activation request signal to the control air conditioner specified as the transmission destination of the activation request signal (S020), and indicates that the control air conditioner that has received the activation request signal has started to operate under the standard operating conditions. A response signal is received (S021).

  The home server 1 that has received the response signal from the control air conditioner according to the procedure described above generates confirmation screen data for drawing a confirmation image indicating the operation state of each air conditioner, and directs the data to the user terminal 3. (S015). When the confirmation screen data is received on the user terminal 3 side, the confirmation screen data is expanded, and the confirmation screen illustrated in FIG. 15 is drawn on the display of the user terminal 3. By viewing this confirmation screen, the user can confirm whether each air conditioner in the house H is subject to the number restriction, and whether there is an air conditioner in a standby state.

<< Other Embodiments >>
Embodiment described above is only an example regarding the energy consumption apparatus control apparatus of this invention, the energy consumption apparatus control method, and the energy consumption apparatus control system, and is for facilitating the understanding of the present invention, It is not intended to limit the invention. The present invention can be changed and improved without departing from the gist thereof, and the present invention includes the equivalents thereof.

  Moreover, in said embodiment, although the home server 1 was installed in the house H and it was decided to control the electric equipment used in the house H, it is not limited to this. For example, a cloud server installed outside the house H communicates with an electrical device inside the house H via an outside network such as the Internet, and exhibits the same function as the home server 1 according to the above embodiment. Also good.

  In the above embodiment, among the plurality of air conditioners, there is an air conditioner that communicates with a different communication protocol. When the home server 1 transmits a control signal to the air conditioner, the communication protocol is transmitted to the destination. It was decided to switch according to the air conditioner. On the other hand, when the user requests the home server 1 to control each air conditioner through the user terminal 3, an HTTP request as the control execution request is transmitted from the user terminal 3. This makes it possible to request the home server 1 to control each air conditioner without the user being aware of the difference in communication protocol between the air conditioners. However, when the communication protocol is unified between the air conditioners, when the control of each air conditioner is requested to the home server 1 through the user terminal 3, the control execution request message is set to a common communication protocol between the air conditioners. It may be transmitted to the home server 1.

  In the above embodiment, the installation location of each electrical device is stored in the memory 1 b of the home server 1. However, the present invention is not limited to this, and there is information indicating an electrical circuit (specifically, a branch circuit in the distribution board) to which each electrical device is connected together with the installation location information or instead of the installation location information. It may be stored.

  In the above embodiment, ECHONET and ECHONETLite are exemplified as the communication protocol of the electric device. However, naturally, other electric protocols may be adopted by the electric devices in the house H.

  In the above embodiment, when the number limit mode is designated as the control mode, the regular control is executed at 0 minutes, 15 minutes, 30 minutes, and 45 minutes per hour, and the number limit operation is mainly performed in the regular control at 0 minutes per hour. Was decided to be executed. That is, in the above embodiment, it is determined whether or not the calculated power exceeds the upper limit power at the time of execution of the regular control at 0 hour per hour, and when it is determined that the calculated power exceeds the upper limit power, The number of air conditioners to which a start request signal is transmitted at the time of execution of control is limited. However, the limited number of operations is not limited to the case where the control is executed with the regular control at 0 hour per hour, but the time other than the execution time of the regular control at 0 hour per hour, for example, the user sets the schedule control type as the control type. It may be executed at the selected time, that is, at the start time of schedule control.

In the above embodiment, when the number limit mode is designated as the control mode, the number of control air conditioners specified as the air conditioner operated under the standard operating condition exceeds the set number, and the calculated power is the upper limit power. Is exceeded, the activation request signal is transmitted to only some of the controlled air conditioners in the regular control at 0:00. In the above embodiment, the activation request is issued to the air conditioner that is subject to the number restriction in the regular control at N 0:00 so that the number of controlled air conditioners to be operated under the standard operation condition in the regular control after the next time is increased. It was decided to send a signal. Specifically, the number of air conditioners that are operated under the standard operating conditions sequentially increases in the regular control at N: 15 and the regular control at N: 30. However, the time interval for increasing the number of air conditioners that operate under the standard operating conditions is not limited to the above case, that is, the 15-minute interval, and may be an arbitrary time interval.
Also, instead of unconditionally increasing the number of air conditioners to be operated under standard operating conditions in the subsequent regular control, calculate the calculated power again in each subsequent regular control, and whether the calculated power exceeds the upper limit power. It may be determined whether or not the number of air conditioners to be operated under the standard operating condition is increased only when the calculated power does not exceed the upper limit power.

S system, H house 1 home server 1a CPU, 1b memory, 1c communication interface 1p schedule storage area, 1q installation location storage area 1r priority storage area, 1s number limit pattern storage area 1t upper limit power storage area, 1u bundle storage Area 3 user terminal, 5 home network 7 power data logger 11 setting request receiving unit, 12 operation mode setting unit 13 control mode setting unit, 14 storage unit 15 control air conditioner specifying unit, 16 power consumption calculating unit 17 power consumption data acquiring unit, DESCRIPTION OF SYMBOLS 18 Determination part 19 Control signal transmission part, 20 Response signal reception part 21 Operation state identification part, 22 Communication protocol switching part 23 Schedule update part, 24 Confirmation screen data transmission part 31 Control signal reception part, 32 Control part, 33 Response signal transmission Unit 41 Operation accepting unit, 42 Data generating unit 4 3 Data transmission unit, 44 Data reception unit, 45 Display unit 101 OS, 102 JVM
103 OSGi Framework 104 First Communication Bundle 105 Second Communication Bundle 106 Third Communication Bundle Bt1, Bt2, Bt3 Select Button Bt4 Update Button L1 Operation Mode List, L2 Control Mode List N1, N2 Mode Input Fields P1, P2 Pull Down Button

Claims (9)

An energy consuming equipment control device that communicates with each of a plurality of energy consuming equipment of the same type in a building or a room of a building to control the operating state of each of the plurality of energy consuming equipment,
A control signal transmitter for transmitting a control signal for controlling the operation state toward each of the plurality of energy consuming devices;
A response signal receiving unit that receives a response signal indicating the operation state from each of the plurality of energy consuming devices;
A storage unit that stores a schedule that defines a period of operation under an operation condition in which a load is a predetermined amount or more for each of the plurality of energy consuming devices;
A specifying unit that reads out the schedule stored in the storage unit and specifies a control target device to be operated under the operation condition at the time of execution of control by the energy consuming device control device from the plurality of energy consuming devices; ,
Energy that is consumed in the building or a room of the building at the time of execution of the control when all the control target devices specified from the plurality of energy consuming devices are operated under the operation conditions by the specifying unit. A calculation unit for calculating an amount;
A determination unit that determines whether the calculation result of the calculation unit exceeds a preset upper limit amount,
When the determination unit determines that the calculation result exceeds the upper limit amount, the control signal transmission unit is an operation request signal that is the control signal for operating under the operation conditions at the time of execution of the control. Is transmitted to only some of the control target devices, and after a predetermined time has elapsed since the execution of the control, the operation request signal is sent to the remaining devices of the control target device. Send to
The response signal transmission unit receives the response signal transmitted to indicate that the control target device that has received the operation request signal from the control signal transmission unit has started to operate under the operation conditions. To control energy consuming equipment. As a control mode when the energy consuming device control device controls the operating state of each of the plurality of energy consuming devices, the control unit performs the control when the determination unit determines that the calculation result exceeds the upper limit amount. Number limit mode for limiting the number of controlled devices to be operated under the operating conditions at the time of execution, and non-number limit mode for operating all the controlled devices at the operating conditions at the time of execution of the control can be specified. And
When the number limit mode is designated, the control signal transmission unit transmits the operation request signal only to some of the devices to be controlled at the time of execution of the control,
A setting request for receiving the control mode setting request from a user terminal that transmits the control mode setting request to the energy consuming equipment control device by receiving an input operation performed by a user to specify the control mode. A receiver,
A control mode setting unit configured to set the control mode to a mode on a specified side of the number limit mode and the non-number limit mode when the setting request reception unit receives the control mode setting request; The energy consuming equipment control device according to claim 1, further comprising: The storage unit is set in advance as the maximum number of devices to be controlled to be operated under the operation condition at the time of execution of the control when the determination unit determines that the calculation result exceeds the upper limit amount. I remember the number,
The control is executed at regular intervals according to the schedule,
When the determination unit determines that the number of the control target devices specified by the specification unit exceeds the set number and the calculation result exceeds the upper limit amount, the control signal transmission unit is: At the time of execution of the control, the operation request signal is transmitted to only a part of the control target devices so that only the control target devices corresponding to the set number are operated under the operation conditions. Then, at the time of execution of the control after the next time, the operation request signal is transmitted to the remaining devices among the control target devices so that the control target devices to be operated under the operation conditions increase. The energy consuming equipment control device according to claim 1 or 2. The storage unit stores priorities determined for each of the plurality of energy consuming devices,
When the determination unit determines that the calculation result exceeds the upper limit amount, the control signal transmission unit has a higher priority than the control target device to be operated under the operation condition at the time of execution of the control. The operation request signal is transmitted to only a part of the control target devices so that the high control target device is selected,
The priority is determined based on an installation location of each of the plurality of energy consuming devices in the building or a room of the building, or a maximum energy consumption amount of each of the plurality of energy consuming devices. The energy consumption apparatus control apparatus as described in any one of Claims 1 thru | or 3.   When there are devices that communicate with each other using a different communication protocol among the plurality of energy consuming devices, the control signal transmission unit uses a communication protocol used when transmitting the control signal to the control target device, 5. The energy consuming equipment control apparatus according to claim 1, wherein switching is performed according to a communication protocol used by the control target equipment as a transmission destination.   The said storage part memorize | stores the installation place of the said energy consumption apparatus in the said building or the room of the said building, The energy consumption apparatus control apparatus as described in any one of Claim 1 thru | or 5 characterized by the above-mentioned. The energy consuming device control device communicates with each of a plurality of electric devices as the plurality of energy consuming devices to control the operating state of each of the plurality of electric devices,
The storage unit is installed in a distribution board provided in the building or the room of the building, contract power determined by a contract with an electric power company as the maximum power consumption in the building or the room of the building Any of the operating power, which is the power consumption in the building or the room of the building when the circuit breaker is activated, and the target power set as the target value of the power consumption in the building or the room of the building Is stored as the upper limit amount, and the energy consuming equipment control device according to any one of claims 1 to 6. An energy consuming device control method for controlling the operating state of each of the plurality of energy consuming devices by communicating with each of a plurality of energy consuming devices of the same type in a building or a room of the building,
For each of the plurality of energy consuming devices, a schedule that defines a period for which the load is operated under an operation condition where the load is a predetermined amount or more is read from the storage unit, and the plurality of energy consuming devices are selected from the plurality of energy consuming devices. Identifying a control target device to be operated under the operation conditions at the time of execution of control;
When all of the devices to be controlled identified from the plurality of energy consuming devices are operated under the operation conditions, the amount of energy consumed in the building or the room of the building at the time of execution of the control is calculated. To do
Determining whether the calculation result of the energy amount exceeds a preset upper limit amount;
When it is determined that the calculation result exceeds the upper limit, at the time of execution of the control, an operation request signal for operating under the operation condition is directed to only some of the devices to be controlled. Transmitting the operation request signal to the remaining devices among the control target devices after a predetermined time has elapsed since the execution of the control,
A method for controlling an energy consuming device, comprising: receiving a response signal transmitted to indicate that the device to be controlled that has received the operation request signal has started to operate under the operation condition. Energy consuming equipment control comprising a plurality of energy consuming equipment of the same type in a building or a room of the building and an energy consuming equipment control device that communicates with each of the plurality of energy consuming equipment and controls each of the operating states. A system,
The energy consuming equipment control device comprises:
A control signal transmitter for transmitting a control signal for controlling the operation state toward each of the plurality of energy consuming devices;
A response signal receiving unit that receives a response signal indicating the operation state from each of the plurality of energy consuming devices;
A storage unit that stores a schedule that defines a period of operation under an operation condition in which a load is a predetermined amount or more for each of the plurality of energy consuming devices;
A specifying unit that reads out the schedule stored in the storage unit and specifies a control target device to be operated under the operation condition at the time of execution of control by the energy consuming device control device from the plurality of energy consuming devices; ,
Energy that is consumed in the building or a room of the building at the time of execution of the control when all the control target devices specified from the plurality of energy consuming devices are operated under the operation conditions by the specifying unit. A calculation unit for calculating an amount;
A determination unit that determines whether the calculation result of the calculation unit exceeds a preset upper limit amount,
When the determination unit determines that the calculation result exceeds the upper limit amount, the control signal transmission unit is an operation request signal that is the control signal for operating under the operation conditions at the time of execution of the control. Is transmitted to only some of the control target devices, and after a predetermined time has elapsed since the execution of the control, the operation request signal is sent to the remaining devices of the control target device. Send to
The response signal transmission unit receives the response signal transmitted to indicate that the control target device that has received the operation request signal from the control signal transmission unit has started to operate under the predetermined load condition. A featured energy consuming equipment control system.

Images