JP5195817B2 - Schedule providing apparatus and schedule providing system - Google Patents

Description

  The present invention relates to a schedule providing apparatus and a schedule providing system.

  Conventionally, as disclosed in Patent Document 1 (Japanese Patent Application Laid-Open No. 2007-183035), a control system that performs energy-saving control of a device such as an air conditioner based on energy-saving schedule data for performing energy-saving control has been proposed. Yes. In the control system disclosed in Patent Document 1, an energy saving schedule of one pattern of devices is set per day, and energy saving control of the devices is performed based on the energy saving schedule.

  Here, sometimes, users of devices (referred to as users) place more importance on comfort than energy saving. Therefore, a control system that performs energy saving control of equipment has been proposed that automatically cancels energy saving control when a predetermined condition is satisfied.

  However, in the case where the energy saving schedule of one pattern device is set as in the control system disclosed in Patent Document 1 (Japanese Patent Laid-Open No. 2007-183035), the energy saving control is once canceled. The energy saving control must be stopped, which is not desirable in ensuring energy saving.

  Then, the subject of this invention is providing the schedule provision apparatus and schedule provision system which can ensure the energy-saving property of an apparatus as much as possible.

A schedule providing device according to a first aspect of the present invention is a schedule providing device that provides an energy saving schedule for causing a device control device that controls a device to operate the device, and includes a storage unit, a transmission unit, and a resource grasp A part . The storage unit stores a plurality of energy saving schedules having different degrees of energy saving. The transmission unit transmits the energy saving schedule to the device control apparatus. The resource grasping unit grasps the resource of the device control apparatus. And a transmission part transmits the number of energy-saving schedules according to the resource grasped | ascertained by the resource grasping | ascertainment part to an apparatus control apparatus. In addition, the transmission unit is a second energy saving schedule that is different from the first energy saving schedule that is the energy saving schedule that has been transmitted first when there is a request from the device control device or when it is determined that the predetermined condition is satisfied. Send the energy saving schedule to the device control device.

In the schedule providing apparatus according to the first aspect of the present invention, for example, by transmitting an energy saving schedule having a degree of energy saving less than that of the first energy saving schedule to the apparatus control device as the second energy saving schedule, the energy saving control of the apparatus is suddenly stopped. It is possible to operate equipment that has been gradually reduced in energy savings. Thereby, the energy-saving property of an apparatus can be ensured as much as possible. Moreover, a plurality of energy saving schedules can be transmitted to the device control apparatus by grasping the resources.

The schedule providing apparatus according to the second aspect of the present invention is the schedule providing apparatus according to the first aspect , further comprising a determination unit. The determination unit determines whether or not the resource grasped by the resource grasping unit is at a level that can hold a plurality of energy saving schedules. Then, when the determination unit determines that the resource is not high enough to hold a plurality of energy saving schedules, the transmission unit first transmits the energy saving schedule with the most energy saving degree among the plurality of energy saving schedules to the device control apparatus.

In the schedule providing apparatus according to the second aspect of the present invention, by transmitting the energy saving schedule with the most energy saving degree among the plurality of energy saving schedules to be held to the apparatus control apparatus, the apparatus is operated with as much energy saving as possible. Can do.

The schedule providing apparatus according to the third aspect of the present invention is the schedule providing apparatus according to the first aspect or the second aspect , and when there is a request from the device control apparatus or when it is determined that the predetermined condition is satisfied. The transmitting unit transmits, to the device control apparatus, a second energy saving schedule that is less energy-saving than the first energy saving schedule among the plurality of energy saving schedules.

In the schedule providing apparatus according to the third aspect of the present invention, the energy saving schedule having a lower degree of energy saving than the first energy saving schedule is transmitted as the second energy saving schedule, so that the energy saving control is suddenly stopped without suddenly stopping the energy saving control. It is possible to operate the equipment with a reduced degree.

The schedule providing apparatus according to the fourth aspect of the present invention is the schedule providing apparatus according to any one of the first aspect to the third aspect , and when the predetermined condition is satisfied, the energy saving schedule is manually operated by a device user. This is a case where the energy-saving control of the device based on is released, or a case where a release condition for releasing the energy-saving control is satisfied.

  Usually, when the predetermined condition as described above is satisfied, the energy saving control of the device is often stopped once.

On the other hand, in the schedule providing device according to the fourth aspect of the present invention, when a predetermined condition is satisfied, a new energy saving schedule is transmitted to the device control device, so the energy saving degree is gradually increased without stopping the energy saving control suddenly. It is possible to operate the equipment loosened.

The schedule provision system which concerns on the 5th viewpoint of this invention is provided with the schedule provision apparatus in any one of a 1st viewpoint-a 4th viewpoint, and an apparatus control apparatus. The device control apparatus includes a schedule setting unit that sets an energy saving schedule. When there are a plurality of energy saving schedules transmitted by the transmission unit, the schedule setting unit sets the tightest energy saving degree.

In the schedule providing system according to the fifth aspect of the present invention, the schedule setting unit can set the one having the most energy saving degree, and thereby can operate the equipment that secures energy saving as much as possible.

A schedule providing system according to a sixth aspect of the present invention is the schedule providing system according to the fifth aspect , and the device control apparatus further includes an energy saving control unit that performs energy saving control of the device based on the energy saving schedule. When there is a request from the device control apparatus to the schedule providing apparatus, or when it is determined that the schedule providing apparatus satisfies the predetermined condition and there is no energy saving schedule transmitted by the transmission section, the energy saving control section Stop control.

In the schedule providing system according to the sixth aspect of the present invention, by stopping the energy saving control only when there is no energy saving schedule that can be transmitted, it is possible to operate a device that ensures energy saving as much as possible.

A schedule providing system according to a seventh aspect of the present invention is the schedule providing system according to the sixth aspect , wherein the device control device is configured to release the energy saving control by the manual operation of the user of the device or to save energy. When a cancellation condition for canceling the control is satisfied, a request is made to the schedule providing apparatus.

  Usually, when energy-saving control is canceled by a manual operation of a user of the device, or when a cancellation condition for canceling the energy-saving control is satisfied, the energy-saving control of the device is often temporarily stopped.

On the other hand, in the schedule providing system according to the seventh aspect of the present invention, a new energy saving schedule can be provided when the controller makes a request to the schedule providing apparatus in the above case. Therefore, it is possible to operate a device whose energy saving degree is gradually reduced without suddenly stopping the energy saving control.

In the schedule providing apparatus according to the first aspect of the present invention, the energy saving performance of the equipment can be ensured as much as possible. In addition, a plurality of energy saving schedules can be transmitted to the device control apparatus.

In the schedule providing apparatus according to the second aspect of the present invention, it is possible to operate an apparatus that secures energy saving as much as possible.

In the schedule providing apparatus according to the third aspect of the present invention, it is possible to operate a device whose energy saving degree is gradually reduced without suddenly stopping the energy saving control.

In the schedule providing apparatus according to the fourth aspect of the present invention, it is possible to operate a device whose energy saving degree is gradually reduced without suddenly stopping the energy saving control.

In the schedule providing system according to the fifth aspect of the present invention and the schedule providing system according to the sixth aspect of the present invention, it is possible to operate the equipment that secures energy saving as much as possible.

In the schedule providing system according to the seventh aspect of the present invention, it is possible to operate a device whose energy saving degree is gradually reduced without suddenly stopping the energy saving control.

1 is a schematic configuration diagram of a schedule providing system according to an embodiment of the present invention. The schematic block diagram of an air conditioner. The schematic block diagram of a controller. The schematic block diagram of a remote monitoring apparatus. The figure which shows an example of the relationship between an energy saving degree and the driving capability of an air conditioner. The figure which shows an example of the management screen for cancellation | release condition setting displayed on a display. The flowchart which shows the flow of a process of provision of a schedule of a remote monitoring apparatus. The flowchart which shows the flow of a process of the controller in a schedule provision system.

  Hereinafter, a schedule providing system 100 according to an embodiment of the present invention will be described with reference to the drawings.

(1) Overall Schematic Configuration of Schedule Providing System 100 FIG. 1 is a schematic configuration diagram of a schedule providing system 100 according to an embodiment of the present invention.

  Briefly, the schedule providing system 100 (see FIG. 1) is equivalent to an air conditioner 10 (see FIG. 1, referring to FIG. 1) installed in each room in order to air-condition each room in a building such as a building. The remote monitoring device 71 (refer to FIG. 1, corresponding to the schedule providing device) arranged separately from the controller 40 is connected to the controller 40 (see FIG. 1, corresponding to the device control device) that directly controls the air conditioner) 10 is a system that provides a schedule for operating 10.

  As shown in FIG. 1, the schedule providing system 100 mainly includes an air conditioner 10, a controller 40, and a remote monitoring device 71. The air conditioner 10 and the controller 40 are arranged in the same building. Further, the air conditioner 10 and the controller 40 are connected via a dedicated communication line 5, and bidirectional communication is possible. The remote monitoring device is arranged in a remote monitoring center 70 that exists separately from the building where the air conditioner 10 and the controller 40 are arranged. The controller 40 and the remote monitoring device 71 are connected via the Internet 6, and bidirectional communication is possible.

  In the schedule providing system 100, the air conditioner 10 is directly monitored and controlled by the controller 40 and remotely monitored and controlled by the remote monitoring device 71 in the remote monitoring center 70. In the schedule providing system 100, the remote monitoring device 71 performs energy-saving control of the air conditioner 10 via the controller 40 so that the power consumption of the air conditioner 10 is reduced by a certain amount. Specifically, the remote monitoring device 71 provides an energy saving schedule, which is an operation schedule for performing energy saving control of the air conditioner 10, to the controller 40, whereby the energy saving of the air conditioner 10 is performed via the controller 40. Energy saving control is performed based on the schedule. The energy saving schedule will be described later.

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

(2) Configuration of Each Part (2-1) Configuration of Air Conditioner 10 FIG. 2 is a schematic configuration diagram of the air conditioner 10.

  Hereinafter, the configuration of the air conditioner 10 will be described. In the present embodiment, only one air conditioner 10 is exemplified as an air conditioner to be controlled by the controller 40, but there are a plurality of air conditioners. The air conditioner 10 in the present embodiment is a so-called multi-type air conditioner, although not shown. However, a pair type air conditioner may be used.

  As shown in FIG. 1, the air conditioner 10 mainly includes an outdoor unit 20 installed outside a living room, which is a target space for air conditioning, and a plurality of indoor units 30 installed on a ceiling or wall in the living room. The refrigerant pipe 8 that connects the outdoor unit 20 and the indoor unit 30 is provided. The outdoor unit 20 and the indoor unit 30 have an outdoor refrigerant circuit 20a and an indoor refrigerant circuit 30a, respectively, and these are connected by a refrigerant pipe 8 to form one refrigerant circuit 9. In the outdoor unit 20, devices constituting the outdoor refrigerant circuit 20 a such as the compressor 21 and the outdoor heat exchanger 22 and the outdoor fan 23 are accommodated. In the indoor unit 30, the indoor heat exchanger 31 and The apparatus which comprises the indoor side refrigerant circuit 30a, such as the expansion valve 32, and the indoor fan 33 are accommodated.

  The control unit 11 (see FIG. 2) of the air conditioner 10 is an aggregate of control units (not shown) included in the outdoor unit 20 and the indoor unit 30 that constitute the air conditioner 10, respectively. The control unit of the outdoor unit 20 and the control unit of the indoor unit 30 are connected via a dedicated communication line (not shown) and can exchange control signals with each other.

  The control unit 11 of the air conditioner 10 is connected to a control unit 46 of the controller 40 described later via a dedicated communication line 5. Thereby, the control unit 11 of the air conditioner 10 controls the operation of various devices arranged in the outdoor unit 20 and the indoor unit 30 based on a control command from the controller 40. Here, the control command is an operation / stop command for the indoor unit 30, an operation mode change command for the indoor unit 30, or the like. Control of the operation of various devices refers to adjustment of the rotation speed (frequency) of the compressor 21, outdoor fan 23, and indoor fan 33, adjustment of the opening degree of the expansion valve 32, and the like.

  As shown in FIG. 2, a remote controller 99 is connected to the control unit 11 of the air conditioner 10 via a dedicated communication line 5.

  The remote controller 99 is an operation interface device for a user of the indoor unit 30 (air conditioner 10) to input an operation command to the indoor unit 30 (air conditioner 10). Thus, the control unit 11 of the air conditioner 10 performs the same control as the control based on the operation command from the controller 40 even based on the operation command from the remote controller 99.

  In addition, the remote control 99 is provided with a release operation unit 99a that can be operated by the user in order to release the energy saving control. The release operation unit 99a is, for example, a button, and this button may be a hardware button or a software button. The user of the air conditioner 10 or the owner or manager of the building where the air conditioner 10 is located (these persons are equivalent to the users of the equipment, and are hereinafter collectively referred to as users) rather than energy saving. When the user wants to emphasize the comfort of the vehicle, the energy saving control can be canceled by operating the canceling operation unit 99a of the remote controller 99.

  Further, the control unit 11 of the air conditioner 10 transmits data related to the operation results of the air conditioner 10 (hereinafter referred to as operation data) to the controller 40 in accordance with a control command from the controller 40. The operation data of the air conditioner 10 includes the operation parameters of the outdoor unit 20 (normal mode, capacity restriction mode, etc.), the operation parameters of the indoor unit 30 (start / stop state, set temperature, cooling / heating / dehumidifying operation mode, etc. Etc.), outdoor temperature, indoor temperature, outdoor humidity, indoor humidity, state values of various devices in the outdoor unit 20 (the rotational speed of the outdoor fan 23, the rotational speed (frequency) of the compressor 21, the refrigerant temperature, the refrigerant pressure, etc.) In addition, data indicating the state values of various devices in the indoor unit 30 (the rotational speed of the indoor fan 33, the opening degree of the expansion valve 32, the refrigerant temperature, the refrigerant pressure, etc.) is included.

  The indoor temperature is detected by an indoor temperature sensor 12 that is installed in the indoor unit 30 and detects the temperature in the room where the indoor unit 30 is installed. The outdoor temperature is detected by an outdoor temperature sensor 13 that is installed in the outdoor unit 20 and detects the outside air temperature in the vicinity of the outdoor unit 20. The refrigerant temperature is detected by a refrigerant temperature sensor 14 installed at a predetermined position of the refrigerant circuit 9. The refrigerant pressure is detected by a refrigerant pressure sensor 15 installed at a predetermined position of the refrigerant circuit 9. The indoor humidity is detected by an indoor humidity sensor 16 that is installed in the indoor unit 30 and detects the humidity in the living room where the indoor unit 30 is installed. The outdoor humidity is detected by an outdoor humidity sensor 17 that is installed in the outdoor unit 20 and detects the outdoor air humidity in the vicinity of the outdoor unit 20.

  When the user operates the release operation unit 99a of the remote control 99, the control unit 11 of the air conditioner 10 receives the input signal (release command) from the remote control 99, and changes this signal (release command) into an appropriate form. To the controller 40. Note that this energy saving control cancellation command may be transmitted directly to the controller 40. In this case, it is assumed that the remote controller 99 and the controller 40 are connected by a dedicated communication line 5.

(2-2) Configuration of Controller 40 FIG. 3 is a schematic configuration diagram of the controller 40.

  Hereinafter, the configuration of the controller 40 will be described with reference to FIG.

  The controller 40 is installed in a management room or the like of a building where the air conditioner 10 is installed, and is a device that monitors and controls the air conditioner 10. Specifically, the controller 40 monitors and controls the air conditioner 10 based on various data transmitted from the remote monitoring device 71.

  As shown in FIG. 3, the controller 40 mainly includes an air conditioner communication unit 41, a remote monitoring device communication unit 42, a storage unit 43, an input unit 44, an output unit 45, and a control unit 46. Have.

  The air conditioner communication unit 41 is a network interface that enables the controller 40 to be connected to the dedicated communication line 5.

  The remote monitoring device communication unit 42 is a network interface that enables the controller 40 to be connected to the Internet 6.

  The storage unit 43 includes a hard disk or the like, and mainly includes an air conditioner database 43a, an air conditioner control database 43b, a setting schedule database 43c, a release command database 43d, a daily report database 43e, and a request database 43f. keeping.

(2-2-1) Air conditioner database 43a
The air conditioner database 43 a stores operation data of the air conditioner 10 transmitted from the control unit 11 of the air conditioner 10.

(2-2-2) Air conditioner control database 43b
The air conditioner control database 43b stores various data (hereinafter referred to as air conditioner control data as appropriate) for controlling the air conditioner 10 transmitted from the control unit 76 of the remote monitoring device 71 described later. Note that the air conditioner control data is data on the energy saving schedule of the air conditioner 10, cancellation condition data indicating conditions for releasing the energy saving control of the air conditioner 10, and the like. The air conditioner control data will be described as appropriate in (2-3) the configuration of the remote monitoring device 71 and (4) the setting of the release condition.

(2-2-3) Setting schedule database 43c
The setting schedule database 43c is an energy saving schedule sent from the remote monitoring device 71 stored in the air conditioner control database 43b, and is determined (set) as an operation schedule of the air conditioner 10 by the schedule setting unit 46c described later. The setting schedule is stored.

(2-2-4) Release command database 43d
The release command database 43d stores release command data (hereinafter referred to as release command data). The cancellation command is a command indicating that energy-saving control of the air conditioner 10 is canceled. The release command is generated by manual operation of the release operation unit 99a by the user.

(2-2-5) Daily report database 43e
Daily report data transmitted from the controller 40 to the remote monitoring device 71 is stored in the daily report database 43e.

  The daily report data is created based on the operation data of the air conditioner 10 stored in the air conditioner database 43a, and the operation history and operation state information of the air conditioner 10 for one day, the energy saving control of the air conditioner 10 is stopped. Data, information on the generation of the release command, information indicating that the release condition is satisfied, and the like. Here, the operation history and the operation state information of the air conditioner 10 include the maximum value / minimum value of the detection values of the various sensors 12 to 17 on that day, information on the accumulated operation time of the air conditioner 10 on that day, and the like.

  The daily report data includes operation data and release command data stored in the air conditioner database 43a and the release command database 43d by the control unit 46 at predetermined time intervals (every 30 minutes in the present embodiment), and release conditions. Is processed based on the frequency of how often the air conditioner is satisfied, the energy-saving control stop data of the air conditioner 10, etc., and is monitored remotely via the remote monitoring device communication unit 42 once a day at a predetermined time. It will be transmitted to the device 71. When the transmission of the daily report data to the remote monitoring device 71 is completed, the transmitted daily report data is deleted from the daily report database 43e. That is, the daily report database 43e becomes a free area because it is handed over for creation of daily report data for the next day.

(2-2-6) Request database 43f
The request database 43f stores request data generated by a request generation unit 46e described later.

  The input unit 44 and the output unit 45 are integrally configured as a touch panel display. When the administrator or the like touches a button or the like having a function of receiving an input from the administrator or the like displayed on the display, the control process corresponding to the button is executed by the control unit 46. The input unit 44 and the output unit 45 are not integrally configured as described above, and may be separate. For example, the input unit 44 may be configured with a mouse or a keyboard, and the output unit 45 may be configured with a display or a speaker.

  The control unit 46 includes a CPU, a ROM, a RAM, and the like, and reads out and executes a program stored in the storage unit 43, whereby a data collection unit 46a, a data transmission unit 46b, a schedule setting unit 46c, an energy saving unit. It functions as a control unit 46d, a request generation unit 46e, and the like.

(2-2-7) Data collection unit 46a
The data collection unit 46a collects operation data of the air conditioner 10 or collects release command data from the control unit 11 of the air conditioner 10 at predetermined time intervals (in this embodiment, every minute). To do. Note that the operation data of the air conditioner 10 collected by the data collecting unit 46a is stored in the air conditioner database 43a as described above. Further, the data collection unit 46a collects air conditioner control data from the control unit 76 of the remote monitoring device 71 at predetermined time intervals (in this embodiment, every minute). This air conditioner control data is stored in the air conditioner control database 43b.

(2-2-8) Data transmission unit 46b
The data transmission unit 46b transmits various data to the control unit 11 of the air conditioner 10 via the air conditioner communication unit 41. Further, the data transmission unit 46b sends various data (specifically, daily report data and request database stored in the daily report database 43e) to the control unit 76 of the remote monitoring apparatus 71 via the remote monitoring apparatus communication unit 42. Request data etc. stored in 43f).

(2-2-9) Schedule setting unit 46c
The schedule setting unit 46c determines (sets) the energy saving schedule sent from the remote monitoring device 71 and stored in the air conditioner control database 43b as a setting schedule for operating the air conditioner 10. Specifically, the energy saving schedule stored in the air conditioner control database 43b is determined (set) as a setting schedule by storing it in the setting schedule database 43c. When there are a plurality of energy saving schedules sent from the remote monitoring device 71 (when there are a plurality of energy saving schedules stored in the air conditioner control database 43b), the schedule setting unit 46c determines the degree of energy saving among the plurality of energy saving schedules. Select the hardest one and decide (set) it as a setting schedule.

(2-2-10) Energy saving control unit 46d
The energy saving control unit 46d performs energy saving control of the air conditioner 10. Specifically, the energy saving control unit 46d performs energy saving control of the air conditioner 10 based on the setting schedule stored in the setting schedule database 43c.

  In addition, the energy saving control unit 46d determines that the release condition stored as data in the air conditioner control database 43b is satisfied, or receives an input signal to cancel the energy saving control when the user manually operates the remote control 99. When received, the fact is transmitted to the request generation unit 46e described later.

  Moreover, the energy-saving control part 46d cancels | releases the energy-saving control of the air conditioner 10 on predetermined conditions, and stops. This will be described later.

(2-2-11) Request generator 46e
The request generation unit 46e determines that the energy saving control unit 46d satisfies the release condition stored as data in the air conditioner control database 43b, or the energy saving control unit 46d manually operates the remote control 99 by the user. When an input signal for canceling is received, an energy saving schedule (second energy saving schedule) different from the previously transmitted energy saving schedule (corresponding to the first energy saving schedule) is sent to the control unit 76 of the remote monitoring device 71. Request data for requesting to be sent). The request data is stored in the request database 43f.

(2-3) Configuration of Remote Monitoring Device 71 FIG. 4 is a schematic configuration diagram of the remote monitoring device 71.

  Hereinafter, the configuration of the remote monitoring device 71 will be described with reference to FIG.

  The remote monitoring device 71 is a server computer that exists in a remote monitoring center 70 (see FIG. 1) that exists remotely from the building where the air conditioner 10 is installed.

  The remote monitoring device 71 remotely monitors and controls the air conditioner 10. Specifically, the remote monitoring device 71 monitors and controls the air conditioner 10 via the controller 40.

  The contents of the remote monitoring of the remote monitoring device 71 include various remote monitoring services performed for a contract organization such as a building where the air conditioner 10 is installed. In the remote monitoring service, the remote monitoring device 71 acquires the operation data of the air conditioner 10 via the controller 40 and remotely monitors the air conditioner 10 while monitoring the operation data of the air conditioner 10. Specifically, in various remote monitoring services, an abnormality / failure of the air conditioner 10 is detected, and if an abnormality or the like has occurred, an abnormality / failure detection service for the service person to deal with, It includes a report creation service for creating a report on the usage status, a report delivery service for delivering the created report, and the like.

  As described above, the contents of the remote control of the remote monitoring device 71 include an energy saving control service that performs energy saving control so that the power consumption of the air conditioner 10 is reduced by a certain amount. Specifically, the energy saving control service is a service that creates an energy saving schedule for performing energy saving control of the air conditioner 10 and causes the controller 40 to control the air conditioner 10 based on the energy saving schedule. Details of this will be described later.

  As shown in FIG. 4, the remote monitoring device 71 mainly includes a communication unit 72, a storage unit 73, an input unit 74, an output unit 75, and a control unit 76.

  The communication unit 72 is a network interface that enables the remote monitoring device 71 to be connected to a network (specifically, the Internet 6).

  The storage unit 73 is mainly composed of a hard disk or the like, and holds an air conditioner database 73a, a weather database 73b, an energy saving schedule database 73c, and a release condition database 73d.

(2-3-1) Air conditioner database 73a
In the air conditioner database 73a, operation data and daily report data of the air conditioner 10 sent from the control unit 46 of the controller 40 at predetermined time intervals are stored in an appropriate format. The operation data and daily report data of the air conditioner 10 stored in the air conditioner database 73a are used for various remote monitoring services such as an abnormality detection service and a report distribution service in addition to the energy saving control service provided by the remote monitoring device 71. .

(2-3-2) Weather database 73b
In the weather database 73b, the latest weather information of the day (specifically, a predetermined point (observation point) in the area where the building where the air conditioner 10 is installed is obtained, which is acquired by the data acquisition unit 76a described later. Data of weather information such as predicted temperature and expected humidity for a predetermined time (1 hour in the present embodiment) is stored.

(2-3-3) Energy saving schedule database 73c
The energy saving schedule database 73c stores energy saving schedule data created by an energy saving schedule creating unit 76d described later.

(2-3-4) Release condition database 73d
The release condition database 73d stores release condition data. The release condition will be described in (4) Setting of release condition described later.

  The input unit 74 includes a mouse and a keyboard, and the output unit 75 includes a display and a speaker.

  The control unit 76 includes a CPU, a ROM, a RAM, and the like, and by reading and executing a program stored in the storage unit 73, a data acquisition unit 76a, a data transmission unit 76b, a release condition reception unit 76c, It functions as an energy saving schedule creation unit 76d, a request reception unit 76e, a resource grasping unit 76f, a resource determination unit 76g, a notification generation unit 76h, an abnormality detection unit 76i, a report creation unit 76j, and the like.

(2-3-5) Data acquisition unit 76a
The data acquisition unit 76a acquires various data transmitted from the control unit 46 of the controller 40 or the like.

  Specifically, the data acquisition unit 76a receives the operation data of the air conditioner 10 sent from the controller 40 at a predetermined time interval (every minute in the present embodiment) or from the controller 40 at a predetermined time interval. The daily report data sent (every day in this embodiment) is acquired.

  Further, the data acquisition unit 76a obtains the latest weather information of the day from a weather information distribution server 91 (see FIG. 1) arranged in the weather information distribution center 90 (see FIG. 1) at a predetermined time interval. get. As shown in FIG. 1, the control unit (not shown) of the weather information distribution server 91 and the control unit 76 of the remote monitoring device 71 are connected via the Internet 6 so that data can be transmitted and received. It has become.

(2-3-6) Data transmission unit 76b
The data transmission unit 76b transmits various types of data stored in the storage unit 73 (specifically, energy saving schedule data created by an energy saving schedule creation unit 76d described later) to the controller 40.

(2-3-7) Cancellation condition receiving unit 76c
The cancellation condition receiving unit 76c receives input information of cancellation conditions via the input unit 74 by an administrator or the like. The release condition receiving unit 76c stores the received release condition information in the release condition database 73d.

(2-3-8) Energy saving schedule creation unit 76d
FIG. 5 is a diagram illustrating an example of a relationship between the degree of energy saving and the driving capability of the air conditioner 10.

  The energy saving schedule creation unit 76d creates an energy saving schedule. The energy saving schedule is a schedule in which the power consumption of the air conditioner 10 is reduced by a certain amount. For example, a time such as “from what time to what time the operation capacity of the air conditioner 10 is operated at an upper limit of 80%”. This is a schedule that takes into account the time, the operating capacity of the air conditioner 10, and the like.

  Specifically, the energy-saving schedule creation unit 76d is stored in the daily report data of the air conditioner 10 (specifically, operation data of the air conditioner 10 on the previous day) stored in the air conditioner database 73a and the weather database 73b. An energy saving schedule for the air conditioner 10 of the day is created from the weather information data of the day. Here, the energy saving schedule creation unit 76d creates a plurality of energy saving schedules having different degrees of energy saving. Then, the energy saving schedule creation unit 76d stores the created energy saving schedules having different degrees of energy saving in the energy saving schedule database 73c.

  Note that the energy saving degree indicates the degree of the upper limit value of the operating capacity of the air conditioner 10. For example, as shown in FIG. 5, in the case of an energy saving schedule with an energy saving degree of 1, the upper limit value of the driving ability is operated at 100%, and in the case of an energy saving schedule with an energy saving degree of 2, the upper limit value of the driving ability is set to 80. In the case of an energy saving schedule with an energy saving degree of 3, the driving capacity is driven at an upper limit value of 60%. That is, in FIG. 5, as the degree of energy saving increases in order from 1, the energy saving schedule becomes tighter, that is, the energy saving schedule with high energy saving performance.

  In the present embodiment, the driving capability reduction control for reducing the driving capability of the air conditioner 10 is performed by controlling the frequency of the compressor 21 and the refrigerant temperature (target condensation temperature, target evaporation temperature).

(2-3-9) Request receiving unit 76e
The request receiving unit 76e receives request data sent from the controller 40.

(2-3-10) Resource grasping unit 76f
The resource grasping unit 76f grasps the resource of the controller 40.

(2-3-11) Resource determination unit 76g (corresponding to determination unit)
The resource determination unit 76g determines whether or not the resource grasped by the resource grasping unit 76f is at a level that can hold a plurality of energy saving schedules.

(2-3-12) Notification generator 76h
The notification generation unit 76 h generates notification data for notifying the controller 40 that there is no energy saving schedule that can be transmitted to the controller 40. The notification data is stored in a predetermined database in the storage unit 73.

(2-3-13) Abnormality detection unit 76i
The abnormality detection unit 76i includes data of detection values of the various sensors 12 to 17 included in the operation data of the air conditioner 10 accumulated in the air conditioner database 73a and a predetermined value stored in the storage unit 73 in advance. The abnormality of the air conditioner 10 is detected by, for example, comparing with a threshold value (an arbitrary value that is considered not to cause an abnormality of the air conditioner 10 and a value set by an administrator or the like). When the abnormality detection unit 76i detects an abnormality such as the detection values of the various sensors 12 to 17 exceeding a predetermined threshold, the air conditioner 10 dispatches a service person to the installation location to deal with the abnormality. Will be.

(2-3-14) Report preparation section 76j
The report creation unit 76j creates an energy saving report related to the evaluation of energy saving based on the operation results of the air conditioner 10 based on the operation data and daily report data of the air conditioner 10 stored in the air conditioner database 73a.

(3) About the energy-saving control of the air conditioner 10 Hereinafter, the energy-saving control of the air conditioner 10 is demonstrated easily.

  The energy saving control of the air conditioner 10 is performed by the controller 40 when the energy saving schedule created by the energy saving schedule creating unit 76d of the remote monitoring device 71 is transmitted to the controller 40 by the data transmitting unit 76b of the remote monitoring device 71. Yes. Specifically, the energy saving schedule sent from the remote monitoring device 71 and stored in the air conditioner control database 43b is determined (set) by the schedule setting unit 46c as a setting schedule, and based on the setting schedule, the energy saving control unit 46 d performs energy saving control of the air conditioner 10.

(4) Cancellation condition setting The cancellation condition is set by the administrator entering the cancellation condition on the management screen displayed on the input unit 74, and this input information (information on the cancellation condition) is the cancellation condition reception unit. It is performed by being received by 76c and stored in the release condition database 73d.

  FIG. 6 shows an example of a release condition setting management screen displayed on the input unit 74 in order to set a release condition as a release condition setting management screen 80. The release condition setting management screen 80 will be briefly described below.

  The candidate indoor unit field 81 includes a candidate list of indoor units 30 that are remotely monitored and controlled by the remote monitoring device 71. Then, by operating the indoor unit addition button / indoor unit deletion button 82 by an administrator or the like, one or a plurality of indoor units 30 for which the release condition is set in the monitored indoor unit column 83 are selected. ing. A predetermined threshold value is input to the room temperature column 84 of the monitoring temperature range item and the duration 85 of the cancellation condition of the energy saving control cancellation / resume condition item.

  In the release condition setting management screen 80 shown in FIG. 6, the room temperature (corresponding to the predetermined threshold value) in the room where the indoor unit 30 selected in the column of the monitored indoor unit is installed is the monitored temperature range. The state in which the room temperature input in the room temperature column 84 of the item is higher in the cooling mode and lower in the heating mode is the duration of the release condition of the energy saving control release / restart condition item If the release condition duration (corresponding to the predetermined threshold value) input in the column 85 is continued, the energy saving control unit 46d determines that the release condition is satisfied. Therefore, simply speaking, the release condition is a state in which the indoor temperature in which the indoor unit 30 (air conditioner 10) is installed exceeds a predetermined threshold in the cooling mode or less than a predetermined threshold in the heating mode. However, the condition is such that the set release time is continued. Here, in the following description, the room temperature input in the room temperature field 84 of the monitored temperature range item is referred to as a release condition setting threshold.

  As described above, the release condition is set by inputting a predetermined item or value in a predetermined field of the release condition setting management screen 80.

  The release condition may be corrected each time a learning unit (not shown) learns the number of times the release command is generated, how often the release condition is satisfied, and the like.

(5) About the flow of the process of provision of the schedule to the controller 40 of the remote monitoring apparatus 71 FIG. 7 is a flowchart showing the flow of the process of providing the schedule of the remote monitoring apparatus 71. Hereinafter, the schedule provision processing of the remote monitoring device 71 will be described with reference to FIG.

  First, in step S101, the resource grasping unit 76f grasps the resource of the controller 40. Specifically, the resource grasping unit 76f grasps the resource of the controller 40 by referring to the name and version of the controller 40. At this time, the resource grasped by the resource grasping unit 76f is temporarily stored in a predetermined database in the storage unit 73. It is assumed that the name and version of the controller 40 are stored in a predetermined database in the storage unit 73 of the remote monitoring device 71.

  In step S102, the resource determination unit 76g determines whether or not the resource grasped by the resource grasping unit 76f is in a level that can hold a plurality of energy saving schedules. When it is determined that the plurality of energy saving schedules can be held, the process proceeds to step S103. On the other hand, when it is determined that the plurality of energy saving schedules cannot be stored, the process proceeds to step S104.

  In step S103, the data transmission unit 76b transmits the energy saving schedule stored in the energy saving schedule database 73c to the controller 40. At this time, the data transmission unit 76b refers to the resource of the controller 40 grasped by the resource grasping unit 76f, and transmits a plurality of energy saving schedules corresponding to the resource to the controller 40.

  In step S104, the data transmission unit 76b transmits the energy saving schedule with the highest degree of energy saving to the controller 40 among the plurality of energy saving schedules stored in the energy saving schedule database 73c. Therefore, for example, when the three energy saving schedules stored in the energy saving schedule database 73c are energy saving schedules having the types of energy saving as shown in FIG. It transmits to the controller 40.

  Here, the process of step S101-step S104 is a process performed when the controller 40 and the remote monitoring apparatus 71 are connected via the internet 6. FIG. Specifically, this is processing that is performed (equivalent to the first) before the energy-saving control of the air conditioner 10 is started. That is, in a state where the energy saving control of the air conditioner 10 is started, the controller 40 is in a state where one or more energy saving schedules are held in the air conditioner control database 46b in advance.

  In step S105, it is determined whether the request reception unit 76e has received request data. When it determines with having received, it transfers to step S106, and on the other hand, when determining with having not received, the process of step S105 is repeated.

  In step S106, the data transmission unit 76b determines whether or not the energy saving schedule database 73c has an energy saving schedule whose degree of energy saving is one step less than that of the previously transmitted energy saving schedule. When it determines with there being, it transfers to step S107, and when it determines with there being no other, it transfers to step S108.

  In step S107, the data transmission unit 76b transmits to the controller 40 an energy saving schedule whose degree of energy saving is one step less than the previously transmitted energy saving schedule. In this case, for example, when the previously transmitted energy saving schedule is an energy saving schedule with an energy saving degree of 3 shown in FIG. 5, the data transmission unit 76 b transmits an energy saving schedule with an energy saving degree of 2 to the controller 40.

  In step S108, the notification generation unit 76h indicates that there is no energy saving schedule that can be transmitted to the controller 40 (specifically, the energy saving schedule database 73c indicates that there is no energy saving schedule with a degree of energy saving that is less than the previously transmitted energy saving schedule). Is generated to be notified to the controller 40 and stored in a predetermined database in the storage unit 73. The notification data is transmitted to the controller 40 by the data transmission unit 76b.

(6) Processing of Controller 40 in Schedule Providing System 100 FIG. 8 is a flowchart showing the flow of processing of the controller 40 in the schedule providing system 100.

  It is assumed that the number of energy saving schedules corresponding to the resources of the controller 40 is transmitted from the remote monitoring device 71 in advance as a premise for performing the processing from step S201.

  First, in step S201, the request generation unit 46e determines whether or not the energy-saving control unit 46d satisfies the release condition stored as data in the air conditioner control database 43b, or the energy-saving control unit 46d determines that the user uses the remote control 99. It is determined whether or not an input signal for canceling the energy saving control by manually operating is received.

  If either of the conditions is satisfied, the process proceeds to step S202. If neither of the conditions is satisfied, the process of step S201 is repeated.

  In step S202, the request generation unit 46e generates the request data described above.

  In step S203, the data transmission unit 46b transmits the request data generated by the request generation unit 46e to the remote monitoring device 71.

  In step S <b> 204, the schedule setting unit 46 c determines whether an energy saving schedule has been received from the remote monitoring device 71. Specifically, the data collection unit 46a determines whether or not the energy saving schedule has been received by determining whether or not the energy saving schedule has been collected from the remote monitoring device 71. When it determines with having received, it transfers to step S207, and when it determines with it not having received on the other hand, it transfers to step S205.

  In step S205, it is determined whether notification data has been received from the remote monitoring device 71. Specifically, it is determined whether or not the notification data has been received by determining whether or not the data collection unit 46 a has collected the notification data from the remote monitoring device 71. When it determines with having received, it transfers to step S206, and on the other hand, when determining with having not received, the process of step S204 is repeated.

  In step S206, the energy saving control unit 46d cancels the energy saving control of the air conditioner 10 and cancels it. That is, when the energy saving control unit 46d determines that the release condition stored as data in the air conditioner control database 43b is satisfied, the energy saving control unit 46d manually operates the remote controller 99. When the controller 40 receives the notification data from the remote monitoring device 71, the energy saving control unit 46d performs the operation.

  Note that the resumption of the energy saving control of the air conditioner 10 is performed when a certain predetermined condition is satisfied, as in the case of the energy saving control being stopped. Specifically, the room temperature in the room where the indoor unit 30 selected in the monitored indoor unit column 83 shown in FIG. 6 is lower than the release condition setting threshold in the cooling mode, When the mode is exceeded, the energy saving control of the indoor unit 30 is automatically performed by continuing the duration for the resumption condition input in the resumption condition duration field of the item of the energy saving control release / resumption condition. Will be resumed. When the energy saving control of the air conditioner 10 is resumed, the processing from step S201 is also performed.

  In step S207, the schedule setting unit 46c determines whether there are a plurality of energy saving schedules collected by the data collection unit 46a (that is, whether a plurality of energy saving schedules are stored in the air conditioner control database 43b). If it is determined that there are a plurality, the process proceeds to step S208. On the other hand, if it is determined that there are not a plurality, the process proceeds to step S209.

  In step S208, the schedule setting unit 46c selects and determines (sets) the energy saving schedule with the most energy saving degree among the energy saving schedules collected by the data collecting unit 46a as the setting schedule.

  In addition, when there are a plurality of energy saving schedules collected by the data collection unit 46a as described above, and when the energy saving control of the air conditioner 10 is first performed based on the energy saving schedule with the most energy saving degree, the energy saving control unit 46d. Receives a release command or determines that the energy saving control unit 46d satisfies the release condition, the schedule setting unit 46c saves energy with a lower degree of energy saving than the energy saving schedule determined (set) as the setting schedule. Select and determine (set) the schedule as a new setting schedule. Then, when such an operation is repeated and there is no energy saving schedule that can be selected as the setting schedule by the schedule setting unit 46c (specifically, when there is no energy saving schedule with a lower degree of energy saving than the previously set energy saving schedule). In addition, the schedule setting unit 46c transmits a message to that effect to the request generation unit 46e, and performs the processing after step S202.

  In step S209, the schedule setting unit 46c determines (sets) the energy saving schedule collected by the data collection unit 46a as a setting schedule.

(7) Features (7-1)
Conventionally, in the case where one pattern of energy saving schedule is set as the energy saving schedule of the air conditioner as in the air conditioner control system disclosed in Patent Document 1 (Japanese Patent Laid-Open No. 2007-183035), the energy saving control is temporarily performed. If released, the energy saving control must be stopped, which is not desirable in ensuring energy saving performance.

  Therefore, in this embodiment, the remote monitoring device 71 (corresponding to the schedule providing device) causes the controller 40 (corresponding to the device control device) that controls the air conditioner 10 (corresponding to the device) to operate the air conditioner 10. An energy saving schedule is provided.

  Specifically, the remote monitoring device 71 stores a plurality of energy saving schedules having different degrees of energy saving in the energy saving schedule database 73 c of the storage unit 73. When there is a request from the controller 40 (specifically, the request data generated by the request generation unit 46e of the controller 40 is transmitted to the remote monitoring device 71 by the data transmission unit 46b of the controller 40). (When the request receiving unit 76e has received the request data), the data transmission unit 76b of the remote monitoring device 71 is different from the energy saving schedule (corresponding to the first energy saving schedule) previously transmitted (second energy saving schedule). Energy saving schedule) is transmitted to the controller 40. At this time, the data transmission unit 76b transmits, to the controller 40, an energy saving schedule having a degree of energy saving that is less than the previously transmitted energy saving schedule among the plurality of energy saving schedules held in the energy saving schedule database 73c.

  As a result, it is possible to operate the air conditioner 10 whose energy saving degree has been gradually reduced, without suddenly stopping the energy saving control of the air conditioner 10. Therefore, it is possible to operate the air conditioner 10 that secures energy saving as much as possible.

(7-2)
In the present embodiment, when the controller 40 and the remote monitoring device 71 are connected, the resource grasping unit 76f of the remote monitoring device 71 grasps the resource of the controller 40, and the number according to the resource grasped by the resource grasping unit 6f. The data transmission unit 76b transmits the energy saving schedule to the controller 40 in advance.

  Specifically, based on the determination of the resource determination unit 76g (corresponding to the determination unit) that determines whether or not the resource grasped by the resource grasping unit 76f can hold a plurality of energy saving schedules, one or more The energy saving schedule is transmitted to the controller 40 in advance. And the controller 40 is performing the energy-saving control of the air conditioner 10 based on the energy-saving schedule transmitted previously.

  In the present embodiment, when the resource of the controller 40 is high enough to hold a plurality of energy saving schedules, the controller 40 can hold a plurality of energy saving schedules having different degrees of energy saving. Therefore, for example, when a certain energy saving schedule is selected as the setting schedule and the energy saving control of the air conditioner 10 is performed based on the setting schedule, a release command for canceling the energy saving control of the air conditioner 10 by the user is received. Even if there is a case where it is determined that the release condition for releasing the energy saving control of the air conditioner 10 is satisfied, an energy saving schedule that is less gradual than the energy saving schedule selected as the setting schedule is selected. It becomes possible to select and set (set) as a new setting schedule. That is, since the energy saving control can be set in a step-by-step manner without suspending the energy saving control suddenly, the air conditioner 10 can be operated with as much energy saving as possible.

  In addition, when the resource of the controller 40 is sufficient to hold a plurality of energy saving schedules, the controller 40 manages the energy saving schedule data of the air conditioner 10 without exchanging the energy saving schedule data with the remote monitoring device 71. It can be carried out.

(7-3)
In the present embodiment, when there are a plurality of energy saving schedules transmitted by the data transmitting unit 76b, the schedule setting unit 46c of the controller 40 selects and determines (sets) the energy saving schedule with the tightest degree of energy saving as the setting schedule.

  In this state, a release command is generated by a manual operation by the user (specifically, the energy saving control unit 46d receives the release command) or satisfies a release condition (specifically, the energy saving control unit 46d If it is determined that the release condition is satisfied), the schedule setting unit 46c determines (sets) an energy saving schedule having a degree of energy saving that is less than the energy saving schedule selected as the setting schedule as a new setting schedule.

  When there is no energy saving schedule that can be set as the setting schedule by the schedule setting unit 46c, the schedule setting unit 46c transmits a message to that effect to the request generation unit 46e, and the request generation unit 46e sends request data for the remote monitoring device 71. Will be sent.

  Thereby, the operation | movement of the air conditioner 10 which ensured energy saving as much as possible is possible.

(7-4)
In the present embodiment, the request receiving unit 76e of the remote monitoring device 71 receives request data transmitted by the data transmitting unit 46b of the controller 40, and the data transmitting unit 76b of the remote monitoring device 71 transmits to the controller 40. When there is no energy saving schedule to be performed, the energy saving control unit 46d of the controller 40 stops the energy saving control of the air conditioner 10.

  Here, the case where there is no energy saving schedule transmitted from the data transmission unit 76b to the controller 40 means that there is no energy saving schedule in the energy saving schedule database 73c of the remote monitoring device 71 that is less energy-saving than the energy saving schedule transmitted earlier. Means.

  In the present embodiment, only when there is no energy saving schedule that can be transmitted from the remote monitoring device 71 to the controller 40, the energy saving control of the air conditioner 10 is stopped, thereby ensuring the energy saving as much as possible and operating the air conditioner 10. be able to.

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

(8-1) Modification 1A
In the above embodiment, when there is a request from the controller 40 to the remote monitoring device 71 (that is, when the request receiving unit 76e of the remote monitoring device 71 receives the request data generated by the request generating unit 46e of the controller 40). However, the remote monitoring device 71 transmits another new energy saving schedule, but the present invention is not limited to this.

  For example, when the remote monitoring device 71 determines that a predetermined condition is satisfied without receiving a request from the controller 40, a processing configuration for transmitting another new energy saving schedule to the controller 40 may be used.

  In this case, the control unit 76 of the remote monitoring device 71 further functions as a predetermined condition determining unit (not shown) that determines whether or not a predetermined condition is satisfied.

  Moreover, when satisfy | filling predetermined conditions, when the cancellation | release command of the energy-saving control of the air conditioner 10 generate | occur | produces by the user's manual operation of the cancellation | release operation part 99, or the cancellation | release conditions for canceling | saving the energy-saving control of the air conditioner 10. This is the case. Therefore, the predetermined condition determination unit determines that the predetermined condition is satisfied when the cancellation command is received or when it is determined that the cancellation condition is satisfied.

  In this case, in step S105 shown in FIG. 7, instead of the process of determining whether or not the request has been received, a determination process in which the predetermined condition determination unit determines whether or not the predetermined condition is satisfied is performed.

(8-2) Modification 1B
In the above-described embodiment, when the resource determination unit 76g determines that the resource of the controller 40 is not high enough to hold a plurality of energy saving schedules, the data transmission unit 76b transmits the most energy saving schedule with the most energy saving degree. However, it is not limited to this.

  For example, a control command indicating that a grasping unit (not shown) that grasps the user's comfort, energy saving priority, etc. grasps the priority, and transmits an energy saving schedule having an energy saving degree according to the grasp. The data transmission unit 76b may transmit to the controller 40 an energy saving schedule having a degree of energy saving according to the grasping by the grasping unit.

  Thereby, control of the air conditioner 10 according to a user's intention becomes possible.

(8-3) Modification 1C
In the above-described embodiment, when the remote monitoring device 71 receives request data from the controller 40, the data transmission unit 76b of the remote monitoring device 71 transmits an energy saving schedule that is one step less energy-saving than the previously transmitted energy saving schedule. Although explained, it is not limited to this.

  For example, when the control unit 76 of the remote monitoring device 71 further functions as an analysis unit (not shown) that analyzes various data, the current operating data of the air conditioner 10, the user's comfort and energy saving priority The analysis unit analyzes the data, data indicating whether the release of the energy saving control of the air conditioner 10 is a manual release by the user, and generates a control command to transmit an energy saving schedule having an energy saving degree according to the analysis Accordingly, the data transmission unit 76b may transmit to the controller 40 an energy saving schedule having a degree of energy saving according to the analysis by the analysis unit. That is, not only the energy saving schedule whose degree of energy saving is one step less than the previously transmitted energy saving schedule, but also an energy saving schedule whose degree of energy saving is one step or more low, such as two steps or three steps, may be sent to the controller 40.

  Thereby, control of the air conditioner 10 according to a user's intention becomes possible.

(8-4) Modification 1D
In the above embodiment, the schedule setting unit 46c of the controller 40 has been described as setting the most energy-saving degree and the setting schedule as the most energy-saving schedule when a plurality of energy-saving schedules are stored in the air conditioner control database 43b. It is not limited.

  For example, as described above, the schedule setting unit 46c sets the current operation data of the air conditioner 10, the user's comfort and the priority of energy saving, whether the release of the energy saving control of the air conditioner 10 is a manual release by the user, or the like. May be determined (set) as a setting schedule by an energy saving schedule having a degree of energy saving according to the analysis.

  Thereby, control of the air conditioner 10 according to a user's intention becomes possible.

(8-5) Modification 1E
In the above embodiment, it has been described that the release operation unit 99a that can be operated by the user in order to release the energy saving control is provided in the remote control 99. However, functions such as the release operation unit 99a are provided in the controller 40. It may be provided.

(8-6) Modification 1F
In the above-described embodiment, it has been described that the energy-saving control of the air conditioner 10 is canceled and the energy-saving control is resumed next is to satisfy a predetermined condition input via the cancellation condition setting management screen. For example, the energy-saving control may be resumed when the energy-saving control is canceled and a predetermined time has passed.

(8-7) Modification 1G
In the above embodiment, the energy saving schedule creation unit 76d has been described as creating the energy saving schedule for the day from the operation data of the air conditioner 10 of the previous day and the data of weather information, but the present invention is not limited to this. For example, the energy saving schedule creation unit 76d stores the priority of the user, such as whether the user gives priority to energy saving or comfort, in the storage unit 73, and refers to the priority to save energy. A schedule may be created. The storage of the user priority is, for example, setting of a flag. Thereby, control according to a user's intention becomes possible.

  The present invention can be applied to various systems including a device control apparatus that controls a device in response to provision of a schedule for operating the device from another device.

10 Air conditioner (equipment)
40 Controller (device control device)
46c Schedule setting unit 46d Energy saving control unit 71 Remote monitoring device (schedule providing device)
73 Storage unit 76b Data transmission unit (transmission unit)
76f Resource grasping unit 76g Resource determining unit (determining unit)
100 Schedule providing system

JP 2007-183035 A

Claims (7)

A schedule providing device (71) for providing an energy saving schedule for causing the device control device (40) for controlling the device (10) to operate the device (10),
A storage unit (73) for storing a plurality of the energy saving schedules having different degrees of energy saving;
A transmission unit (76b) for transmitting the energy saving schedule to the device control device (40);
A resource grasping unit (76f) for grasping the resource of the device control device (40);
With
The transmitter (76b)
A plurality of the plurality of energy saving schedules corresponding to the resource grasped by the resource grasping unit (76f);
When there is a request from the device control device (40) or when it is determined that a predetermined condition is satisfied, the second energy saving schedule is different from the first energy saving schedule that is the energy saving schedule that is transmitted first. Transmitting an energy saving schedule to the device control device (40);
Schedule providing device (71). A determination unit (76g) for determining whether or not the resource grasped by the resource grasping unit (76f) can hold a plurality of the energy saving schedules;
When the determination unit determines that the resource is not high enough to hold the plurality of energy saving schedules, the transmission unit (76b) first selects the most energy saving schedule having the most energy saving degree among the plurality of energy saving schedules. To the device control device (40),
The schedule providing device (71) according to claim 1 . When there is a request from the device control device (40) or when it is determined that the predetermined condition is satisfied, the transmission unit (76b) is more than the first energy saving schedule among the plurality of energy saving schedules. An energy saving schedule with a low degree of energy saving is transmitted to the device control device (40) as the second energy saving schedule.
The schedule provision apparatus (71) according to claim 1 or 2 . In the case where the predetermined condition is satisfied, when the energy saving control of the device (10) is released based on the energy saving schedule by a manual operation of the user of the device (10), or to release the energy saving control Is when the release condition is satisfied,
The schedule provision apparatus (71) of any one of Claims 1-3 . The schedule providing device (71) according to any one of claims 1 to 4 ,
The device control device (40);
With
The device control device (40) includes a schedule setting unit (46c) for setting the energy saving schedule,
When there are a plurality of the energy saving schedules transmitted by the transmitting unit (76b), the schedule setting unit (46c) sets the tightest one of the degree of energy saving.
A schedule providing system (100). The device control device (40) further includes an energy saving control unit (46d) that performs energy saving control of the device (10) based on the energy saving schedule,
When there is a request from the device control device (40) to the schedule providing device (71), or when the schedule providing device (71) determines that the predetermined condition is satisfied, the transmission unit (76b) If there is no energy saving schedule to send
The energy saving control unit (46d) stops the energy saving control.
The schedule provision apparatus (71) according to claim 5 . The device control device (40), when the energy saving control is released by a manual operation of a user of the device (10), or when a release condition for releasing the energy saving control is satisfied, Making the request to the schedule providing device (71);
The schedule provision system (100) according to claim 6 .

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