JP2013134037A - Air-conditioning operation navigation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air-conditioning operation navigation device which can properly create and present an operation schedule of air conditioners having a plurality of different air-conditioning systems.SOLUTION: With an air-conditioning facility provided with one or more air conditioners respectively of different systems to carry out air-conditioning through respectively different air-conditioning systems, as an object, an air-conditioning operation navigation device determines which air conditioner of which air-conditioning system is to be preferentially operated in which time zone, to create the optimum operation schedule of a plurality of air conditioners of different air-conditioning systems. Furthermore the air-conditioning operation navigation device is configured to display the created operation schedule.

Description

  The present invention relates to an air conditioner operation navigation device for presenting an operation schedule of an air conditioning system.

It is required to efficiently operate air conditioning equipment in buildings in consideration of energy saving, cost reduction, environmental load (CO ₂ emission amount) and the like. Therefore, a system for navigating the operation schedule of the air conditioning equipment has been proposed as follows. That is, after setting a combination pattern of operation priorities of a plurality of air conditioning heat source units, an allowable operation schedule of the heat source unit is set for each combination pattern. Next, a simulation for controlling the number of operating heat source units that is optimized according to the building load is executed for each combination pattern based on the allowable operation schedule of the heat source units. And based on this simulation result, it is going to calculate and evaluate energy consumption, running cost, and CO2 discharge | emission amount (for example, refer patent document 1).

JP 2011-2112 A

  In recent years, air conditioning systems have been diversified for the purpose of promoting energy saving from environmental considerations. Along with this, for example, air conditioning equipment in one building is also being used for air conditioning using a plurality of types of air conditioners with different air conditioning methods.

  Against the backdrop of the above, even in an air conditioning facility that uses air conditioners of a plurality of air conditioning systems, it is required to support efficient operation by performing navigation of the operation schedule. However, the technique in Patent Document 1 is based on the premise that the air conditioning equipment is configured by only one type of air conditioning system. For this reason, it is difficult to appropriately create an operation schedule of a plurality of air conditioners of different air conditioning systems by the technique according to Patent Document 1.

  Therefore, an object of the present invention is to provide an air conditioning operation navigation apparatus that can appropriately create and present an operation schedule of air conditioners of different air conditioning systems.

  The present invention has been made in order to solve the above-mentioned problems, and targets any air conditioning facility having one or more air conditioning units that perform air conditioning by different air conditioning methods, and any air conditioning by any method in any time zone. By determining whether to perform priority control for operating the machine with priority, an operation schedule creation unit that creates an operation schedule for each of the optimum air conditioners by method, and the created operation schedule are displayed. And a display control unit to be displayed on the apparatus.

  Further, the present invention further includes an evaluation unit that evaluates a predetermined evaluation item when the air conditioner for each method is operated according to the created operation schedule in the air conditioning operation navigation device described above, and the display control The unit displays an evaluation result by the evaluation unit.

  Further, the present invention is characterized in that the air conditioning operation navigation apparatus further includes an operation control unit that operates the air conditioner according to each method according to the created operation schedule when automatic operation is designated. To do.

  According to the present invention, there is an effect that it is possible to provide an air conditioning operation navigation device that appropriately creates and presents an operation schedule of air conditioners of different air conditioning systems.

It is a figure which shows the structural example of the air conditioning equipment in embodiment of this invention. It is a figure which shows the structural example of the air-conditioning driving | operation navigation apparatus 400 in this embodiment. It is a figure which shows the driving | running pattern applied to a radiation ceiling air conditioner and a desiccant air conditioner in performing an operation simulation in this embodiment. It is a figure which shows the example of the radiation air-conditioning priority control in a core time operation mode. It is a figure which shows the example of the external air cooling air-conditioning priority control in a core time operation mode. It is a figure which shows the example of the radiation air-conditioning priority control in the working hours non-core time operation mode. It is a figure which shows the example of the floor blowing air-conditioning priority control in the working hours non-core time operation mode. It is a figure which shows the example of an aspect of the driving schedule screen in this embodiment. It is a figure which shows the example of an aspect of the driving schedule screen in this embodiment. It is a figure which shows the example of a display mode about the evaluation result of the calorie | heat amount and electricity usage in this embodiment. It is a diagram showing a display mode example of the evaluation results of the cost and CO ₂ emissions in the present embodiment. It is a figure which shows the example of a process sequence which the air-conditioning driving | operation navigation apparatus in this embodiment performs for preparation and a display of a driving schedule. It is a figure which shows the example of a process sequence which the air-conditioning driving | operation navigation apparatus in this embodiment performs for operation control.

  FIG. 1 shows a configuration example of an air conditioning facility provided with an air conditioning operation navigation apparatus 400 in the present embodiment. The air conditioning equipment includes N sets of air conditioning systems from the first air conditioning system 100-1 to the Nth air conditioning system 100-N and an air conditioning operation navigation device 400 in the building 1.

  The first air conditioning system 100-1 to the Nth air conditioning system 100-N are a group of air conditioners that are divided into different systems in the building 1. In the following description, the first air conditioning system 100-1 to the Nth air conditioning system 100-N will be described as the air conditioning system 100 unless otherwise distinguished. Each air conditioning system 100 has different systems such as a control system and a power supply system.

  Further, the air conditioning system 100 is provided with air conditioning facilities each having one or more air conditioners by different air conditioning systems. As an example of different air conditioning systems, here, a case where a radiation air conditioning system and a floor blowing air conditioning system are applied will be described. The radiation air conditioning method is included in internal load processing air conditioning that performs air conditioning according to the heat load inside the building, and the internal load processing air conditioning is included in sensible heat treatment that performs air conditioning on sensible heat. The floor blowing air conditioning system is included in the outside air processing air conditioning that processes the outside air and performs air conditioning, and the outside air processing air conditioning is included in the latent heat processing that performs air conditioning with respect to latent heat.

In this figure, a case will be described in which a plurality of radiation ceilings 200 are applied as an example of equipment that performs air conditioning by a radiation air conditioning system, and a plurality of air conditioners 300 are applied as an example of equipment that performs air conditioning by a floor blowing air conditioning system.
The radiant ceiling 200 is an air conditioner that is disposed on the ceiling of the building 1 and performs air conditioning by a radiant air conditioning system. The air conditioner 300 is an air conditioner that introduces outside air by a desiccant method and performs humidification or dehumidification with a moisture absorbent.

  As described above, each of the air conditioning systems 100 in the present embodiment performs air conditioning by operating in combination with two types of air conditioning units corresponding to different air conditioning methods of the radiation air conditioning method and the floor blowing air conditioning method. Is possible.

In addition, the air conditioning operation navigation device 400 is an optimal operation schedule (optimal operation) for the radiant ceiling 200 and the air conditioner 300 arranged in each of the first air conditioning system 100-1 to the Nth air conditioning system 100-N. Schedule). Here, the “optimal driving schedule” means that the radiant ceiling 200 and the air conditioner 300 are set so that predetermined evaluation items have as high an evaluation result as possible while maintaining the comfort of residents in the building 1. It will be a driving schedule. As the evaluation items may include, for example, heat, power usage, and cost and CO ₂ emissions.

  And the air-conditioning operation navigation apparatus 400 displays and outputs the optimal operation schedule created as described above. In addition, the air-conditioning operation navigation apparatus 400 displays the evaluation result for each evaluation item when the operation is performed according to the optimal operation schedule, along with the display of the optimal operation schedule.

  The manager of the air conditioning equipment of the building 1 can accurately determine how to operate the air conditioning equipment with reference to the optimum operation schedule and the evaluation result displayed and output as described above.

  In addition, the air-conditioning operation navigation device 400 performs operation control as follows when automatic operation is designated by the operation of the administrator. That is, the air-conditioning operation navigation apparatus 400 operates the radiation ceiling 200 and the air conditioner 300 in each air-conditioning system 100 according to the created optimum operation schedule. For this reason, the air-conditioning operation navigation apparatus 400 and each of the radiant ceiling 200 and the air conditioner 300 in each air conditioning system 100 are connected so that communication is possible, for example, by a data interface or a network.

  FIG. 2 shows a configuration example of the air-conditioning operation navigation apparatus 400. The air-conditioning operation navigation apparatus 400 includes an operation schedule creation unit 401, an evaluation unit 402, a display control unit 403, an operation control unit 404, a storage unit 405, an operation unit 406, a display unit 407, a network communication unit 408, and a data interface 409.

  The operation schedule creation unit 401 creates an optimum operation schedule for the radiation ceiling 200 and the air conditioner 300 in each air conditioning system 100.

The evaluation unit 402 evaluates evaluation items (such as heat amount, power usage amount, cost, and CO ₂ emission amount) when the operation is performed according to the optimum operation schedule created by the operation schedule creation unit 401.

  The display control unit 403 performs control for causing the display unit 407 to display the optimum operation schedule created by the operation schedule creation unit 401 and the evaluation result corresponding to the optimum operation schedule in a predetermined manner.

  The operation control unit 404 performs operation control on the radiation ceiling 200 and the air conditioner 300 in each air conditioning system 100. Further, the operation control unit 404 executes operation control corresponding to automatic operation and manual operation. That is, the air conditioning operation navigation device 400 is configured to set either automatic operation or manual operation in accordance with a predetermined operation performed on the operation unit 406. When automatic operation is set, the operation control unit 404 executes operation control according to the optimum operation schedule created by the operation schedule creation unit 401. On the other hand, when the manual operation is set, the operation control unit 404 executes the operation control according to the operation schedule set by the administrator through the operation on the operation unit 406.

  The storage unit 405 stores various types of data required for navigation in air conditioning operation. Here, among the data stored in the storage unit 405, weather forecast data 451 and actual building load data 452 are shown as data used by the operation schedule creation unit 401.

  The weather forecast data 451 is data composed of weather forecast information acquired from a weather forecast server (not shown) via the network 500. The weather forecast data 451 includes information such as weather, temperature, and humidity for each time zone on each forecast day.

  The actual building load data 452 is past actual data on the thermal load or the like in the building 1. Specifically, the actual building load data 452 includes the indoor temperature, indoor humidity, medium temperature, heat consumption of the air conditioner, power consumption of office equipment and lighting power, and power consumption of the air conditioner for each area that has been previously classified in the building 1. Information such as quantity, CO2 emissions from air conditioners, electricity billing system, etc.

  The operation unit 406 collectively indicates various operation devices such as a keyboard and a mouse. In response to an operation performed on the operation device included in the operation unit 406, the operation unit 406 outputs an operation signal. In response to this operation signal, the predetermined functional unit shown in FIG. 2 performs an appropriate operation.

  The display unit 407 includes a predetermined display device such as a liquid crystal display, for example, and displays an image according to the control of the display control unit 403.

  The network communication unit 408 is a part that performs communication via the network 500. The network communication unit 408 can access the weather forecast server existing on the network 500 and download the weather forecast data 451 as described above.

  The data interface 409 executes communication with an external terminal according to a predetermined data interface standard. In the present embodiment, communication is performed with each of the radiant ceiling 200 and the air conditioner 300 in each air conditioning system 100 via the data interface 409.

  As described above, the air conditioning equipment in the present embodiment includes the radiant ceiling 200 and the air conditioner 300 that are different from each other in the air conditioning system. For this reason, when operating the air conditioner, it is necessary to consider what pattern should be operated between the radiation ceiling 200 and the air conditioner 300 according to the difference in the air conditioning system.

  Therefore, with reference to FIG. 3, an operation pattern applied to the radiation ceiling 200 and the air conditioner 300 when performing the operation simulation in the present embodiment will be described. First, the operation pattern in the present embodiment is divided into the following four operation modes according to the time zone. That is, it is divided into a core time operation mode, a non-core time working hour operation mode, a night operation mode, and an optimal start-up mode.

  The core time operation mode is an operation mode adapted to the time zone of the core time among working hours in one day (24 hours).

  The non-core time working time driving mode is an operation mode adapted to a time zone other than the core time among working hours in one day (24 hours). In addition, as a time zone other than the core time in the working hours here, for example, an overtime time zone in which a worker is working in the building 1 other than the core time is assumed for one day working hours, for example. doing. In addition, it is assumed that a worker is working in the building 1 due to work on a holiday.

  The night driving mode is a driving mode adapted to a time zone in which a worker is not working in the building 1.

  The optimum activation mode is an operation mode for causing the radiant ceiling 200 and the air conditioner 300 to warm up so as to reach the target temperature and the target humidity at the target time.

  In addition, in the core time operation mode, the operation is performed by either the radiation air conditioning priority control or the outside air cooling air conditioning priority control. The radiant air conditioning priority control is an operation control in which the radiant ceiling 200 is preferentially operated and the air conditioner 300 is dependently operated in the air conditioning control.

  FIG. 4 shows an example of radiation air conditioning priority control in the core time operation mode. FIG. 4 shows the configuration of air conditioning equipment in a certain room 600 in the building 1. In the room 600, a radiant ceiling 200 is disposed on the ceiling. Also, one air conditioner 300 is disposed in the room 600. The outside air introduced into the air conditioner 300 is subjected to humidity adjustment or the like by the air conditioner 300 as necessary, and then discharged to the lower portion of the floor 601 in the room 600. The conditioned air discharged to the lower portion of the floor 601 is blown out into the living space of the room 600 from the floor outlet 602.

In the radiant air conditioning priority control in the core time operation mode, first, in the heat load process, the radiant ceiling 200 performs the air conditioning in accordance with the set temperature of the room 600. In addition, with respect to the air conditioner 300, the introduced outside air is blown out from the floor outlet 602 at a temperature substantially equal to the set temperature of the room 600. Note that the amount of outside air introduced by the air conditioner 300 at this time is adjusted to be appropriate based on the CO ₂ concentration in the room 600 and the like.

  Specifically, in this figure, the surface temperature of the radiation ceiling 200 is set to 20 degrees. Further, the air conditioner 300 is shown in a state where the outside air is set to about 26 degrees which is substantially equal to the set temperature and is blown out from the floor outlet 602. Thus, the set temperature of the room 600 is set to 26 degrees.

  FIG. 5 shows an example of the outside air cooling air conditioning priority control in the core time operation mode. In this figure, the same parts as those in FIG. In the outside air cooling air conditioning priority control in the core time operation mode, first, the air conditioner 300 introduces outside air with the outside air introduction amount set to the maximum. Thereby, the cool air of the outside air is blown out as it is from the floor outlet 602 to the room 600, and the temperature of the room 600 is lowered. In addition, the radiant ceiling 200 performs air conditioning that is insufficient for only the outside air cooling to reach the set temperature of the room 600. In FIG. 5, as a specific example, outside air of about 20 degrees is introduced by the air conditioner 300 and blown into the room 600, and the surface temperature of the radiant ceiling is set to 22 degrees, so that the set temperature of the room 600 is 26 degrees. The state of maintaining is shown.

  5, the surface temperature of the radiant ceiling 200 can be set higher than the radiant air conditioning priority control of FIG. 4, and the load on the radiant ceiling 200 is reduced. As a result, in the core time operation mode, the outside air cooling air conditioning priority control can improve the energy saving performance than the radiant air conditioning priority control.

  In addition, as shown in FIG. 3, in the non-core time working mode operation mode, the operation is performed by either the radiation air conditioning priority control or the floor blowing air conditioning priority control. However, the radiation air-conditioning priority control and the floor blowing air-conditioning priority control in the non-core-hour working hours operation mode are different from those in the core time operation mode as follows.

  FIG. 6 shows an example of radiation air conditioning priority control in the non-core time working mode operation mode. In working hours other than the core time, the number of workers working in the room 600 is less than in the core time. Therefore, in the radiant air conditioning priority control in the non-core time working mode operation mode, not all the radiant ceilings 200 in the room 600 are operated, but a part thereof is operated. That is, as shown in the figure, in the room 600, for example, an operation area 610 for operating the radiant ceiling 200 corresponding to the place where the worker is located, and a stop area for stopping the radiant ceiling 200 other than the operation area 610 And divide into

In addition, in the radiant air conditioning priority control in the non-core time working mode operation mode, the same operation as in FIG. 4 is performed. That is, the radiation ceiling 200 in the operation area 610 is operated so as to perform air conditioning in accordance with the set temperature of the room 600 for heat load processing. In addition, the outside air introduced by the air conditioner 300 is set to a temperature substantially the same as the set temperature of the room 600 and blown out from the floor outlet 602. Note that the amount of outside air introduced by the air conditioner 300 at this time is adjusted to be appropriate based on the CO ₂ concentration in the room 600 and the like. Such control can also be performed in the core time operation mode.

  In FIG. 6, as a specific example, the surface temperature of the radiant ceiling 200 in the operation area 610 is set to 20 degrees, and the outside air of about 26 degrees is blown into the room 600 by the air conditioner 300. The state is shown.

  Here, in floor blowing air conditioning, other priority control can also be performed. FIG. 7 is a diagram illustrating an example of another operation mode using floor blowing air conditioning, and an example of floor blowing air conditioning priority control in the non-core time working mode operation mode will be described using this diagram. In floor blowing air conditioning priority control in the non-core time working mode operation mode, air conditioning is performed only by floor blowing air conditioning. That is, all of the radiation ceiling 200 in the room 600 is stopped. In addition, depending on the air conditioner 300, for example, the outside air is introduced from the floor outlet 602 by introducing the outside air with the maximum introduction amount, so that the outside air at a temperature that is substantially the outside air temperature. In FIG. 7, as a specific example, a state in which about 20 degrees of outside air is introduced by the air conditioner 300 and blown out from the floor outlet 602 so that the set temperature of the room 600 is 26 degrees is shown. Has been. Here, since the internal load is low, by setting the outside air for ventilation to 20 degrees, the room can be in a state of 26 degrees even if the radiation ceiling 200 is stopped.

  Returning to FIG. The night operation mode performs either the operation by night purge control or the operation to stop without performing night purge control. Night purge refers to reducing heat accumulated in the building during the daytime by performing ventilation with low temperature outside air at night, for example, in the cooling season such as summer. This can reduce the morning air conditioning startup load. This night purge control can be realized by performing ventilation with the air conditioner 300 in correspondence with the present embodiment.

  In the optimum start mode, operation is performed by optimum start control. The optimal start-up control controls the operation of the radiant ceiling 200 and the air conditioner 300 so that the target temperature and the target humidity are reached at the target time.

  The operation schedule creation unit 401 uses the weather forecast data 451 and the actual building load data 452 to create an optimum operation schedule as follows. That is, the operation schedule creation unit 401 determines an optimal combination pattern of the operation by the radiation air conditioning priority control and the operation by the outside air cooling air conditioning priority control in the core time operation mode in the time zone of the core time. Note that this determination is performed in the air conditioning system 100, for example, for each air conditioner group divided for each area.

  Similarly, the operation schedule creation unit 401 determines an optimal combination of the operation by the radiation air-conditioning priority control and the operation by the outdoor air cooling air-conditioning priority control in the working hours outside the core time in the working hours other than the core time. In addition, this determination is also performed for each air conditioner group divided for each area in the air conditioning system 100, for example.

  Further, the operation schedule creation unit 401 determines the air conditioner (air conditioner 300) to be subjected to the night purge control and the time in the time zone corresponding to the night mode other than the working hours. In the time zone corresponding to the night mode, it is determined that the air conditioner 300 that has not been determined to perform the night purge control is stopped.

  Further, the operation schedule creation unit 401 determines the air conditioner group to be optimally activated and the time in the optimal activation mode. In addition, the operating state of the air conditioner (radiant ceiling 200 and air conditioner 300) at the optimal start-up is set. And the operation schedule preparation part 401 produces the optimal operation schedule for 1 day so that the operation pattern for every operation mode determined in this way may be integrated.

  The operation schedule creation unit 401 has a learning function. For this reason, for example, when the created optimum driving schedule deviates from the past driving schedule results under similar conditions shown in the actual building load data 452, the driving schedule creation unit 401 has created the learning function described above. Correct the optimal operation schedule.

  Then, the display control unit 403 causes the display unit 407 to display the optimum operation schedule created as described above, for example, as an operation schedule screen 700 as illustrated in FIGS. 8 and 9. 8 shows the left part of the driving schedule screen 700, and FIG. 9 shows the right part following the driving schedule screen 700 of FIG.

  In the operation schedule screen 700 shown in FIG. 8 and FIG. 9, the operation state for each time in a day is shown corresponding to each air conditioner group. Each of the air conditioner groups shown in this figure corresponds to, for example, one of the first air conditioning system 100-1 to the Nth air conditioning system 100-N in FIG.

Further, the evaluation unit 402 evaluates a predetermined evaluation item when the vehicle is operated according to the optimum operation schedule created by the operation schedule creation unit 401. Here, it is assumed that the evaluation items are four items of heat amount, power consumption, cost, and CO ₂ emission amount.

  In addition to the operation schedule screen 700, the display control unit 403 causes the display unit 407 to display an evaluation result for each evaluation item by the evaluation unit 402. 10 and 11 show examples of display modes for the evaluation result in the core time operation mode as the evaluation result for each evaluation item displayed on the display unit 407.

  FIG. 10A shows a display mode example of the evaluation result for the heat quantity. In the image of the evaluation result shown in FIG. 10 (a), the heat quantity is shown in a graph format, the heat quantity graph when the radiant air conditioning priority control is performed is shown on the left side, and the outside air cooling air conditioning priority control is shown on the right side. A graph of the amount of heat when performing is shown.

  The evaluation result image shown in FIG. 10A is based on the premise that the optimum operation schedule created by the operation schedule creation unit 401 is set to perform the operation by the radiation air conditioning priority control at the core time. Therefore, in the case of FIG. 10A, the heat amount graph when the right outside air-conditioning air-conditioning priority control is performed is the heat amount when the operation is performed according to the optimum operation schedule created by the operation schedule creation unit 401. It becomes the evaluation result of. The graph of the evaluation result on the left is a comparison target. The evaluation result shown as a graph when the left side radiation air-conditioning priority control is performed is also obtained by the evaluation unit 402 performing evaluation as a simulation result when performing operation by the radiation air-conditioning priority control in the core time operation mode. It is what In addition, the amount of heat for each of the first air conditioning system 100-1 to the Nth air conditioning system 100-N illustrated in FIG. 1 is reflected in this graph.

  Moreover, FIG.10 (b) shows the example of a display mode of the evaluation result about the amount of electricity used. In this way, the amount of electricity used is also displayed in the form of a graph format, and the graph when the radiation air conditioning priority control is performed on the left side and the outside air cooling air conditioning priority control is performed on the right side Arrange the graph.

  Moreover, Fig.11 (a) shows the example of a display mode of the evaluation result about cost. This cost indicates, for example, an electricity usage fee. Also in FIG. 11A, the cost is shown in a graph format, the graph when the radiation air-conditioning priority control is performed on the left side, and the graph when the outdoor air cooling air-conditioning priority control is performed on the right side.

Further, FIG 11 (b) shows a display mode example of evaluation results for CO ₂ emissions. Also in FIG. 11B, the CO ² emission amount is shown in the form of a graph, the graph in the case where the radiant air conditioning priority control is performed on the left side, and the graph in the case of performing the outside air cooling air conditioning priority control on the right side is illustrated. It is.

  In addition, although illustration is abbreviate | omitted, the evaluation result in each of the working time driving mode outside core time, the night driving mode, and the optimal starting mode is also displayed by the same mode as FIG. 10 and FIG.

  Further, the operation schedule screen 700 shown in FIGS. 8 and 9 and the evaluation results shown in FIGS. 10 and 11 may be displayed in the same screen area, for example, or displayed on individual screens. You may be made to do.

  The administrator can refer to the operation schedule screen 700 displayed as described above and the evaluation result screen to be a reference for assembling the operation schedule manually. For example, if the administrator determines that the optimum driving schedule as displayed on the driving schedule screen 700 is acceptable, the administrator sets automatic driving by a predetermined operation on the operation unit 406. Thereby, the operation control unit 404 in the air-conditioning operation navigation apparatus 400 executes the operation control according to the optimum operation schedule created by the operation schedule creation unit 401. That is, automatic operation according to the optimal operation schedule is performed.

  FIG. 12 shows an example of a processing procedure executed by the air-conditioning operation navigation apparatus 400 for creating and displaying an optimal operation schedule. First, the operation schedule creation unit 401 in the air-conditioning operation navigation apparatus 400 reads the weather forecast data 451 and the actual building load data 452 from the storage unit 405 (step S101).

  Next, the operation schedule creation unit 401 uses the read weather forecast data 451 and the actual building load data 452 to operate the operation patterns of the air conditioners (radiant ceiling 200 and air conditioner 300) that are optimized in the core time operation mode. Is determined (step S102).

  In addition, the operation schedule creation unit 401 uses the read weather forecast data 451 and the actual building load data 452 to determine the operation pattern of the air conditioner that is optimal in the non-core time working mode operation mode (step S103). .

  Further, the operation schedule creation unit 401 uses the read weather forecast data 451 and the actual building load data 452 to determine an optimum pattern for the air conditioner 300 to be subjected to the night purge control and the execution time in the night operation mode. (Step S104).

  In addition, the operation schedule creation unit 401 uses the read weather forecast data 451 and the actual building load data 452, and the air conditioners (radiant ceiling 200 and air conditioner 300) that are the targets of execution of the optimum activation control in the optimum activation mode. An optimum pattern is determined for the execution time (step S105).

  Next, the driving schedule creation unit 401 creates an optimum driving schedule based on the determination results from steps S102 to S105 (step S106). Note that each of the determination results for each of the core time operation mode, the non-core time working mode operation mode, the night operation mode, and the optimum start-up mode affects, for example, the subsequent temperature and room temperature. For this reason, when the operation schedule creation unit 401 creates the optimum operation schedule, the determination result in steps S102 to S105 may be corrected in consideration of the influence as described above.

In addition, the evaluation unit 402 evaluates predetermined evaluation items (amount of heat, amount of power used, cost, and CO ₂ emission amount) when the operation is performed according to the optimum operation schedule created in step S106 (step S107). ). Note that the evaluation unit 402 also evaluates the case where the operation is performed in step S107 regardless of the optimum operation schedule created in step S106. As a result, the evaluation result can be displayed together with the comparison object as shown in FIGS. 10 and 11.

  The display control unit 403 causes the display unit 407 to display the optimum operation schedule created in step S106 and the evaluation result in step S107 in a predetermined manner (step S108).

  The flowchart of FIG. 13 shows an example of a processing procedure executed by the air-conditioning operation navigation apparatus 400 for operation control. The operation control unit 404 in the air conditioning operation navigation device 400 determines whether or not automatic operation is set for the operation control of the air conditioner (step S201). Here, when the automatic operation is set (step S201-YES), the operation control unit 404 determines each air conditioner (radiant ceiling 200 and air conditioner 300) according to the optimum operation schedule created in step S106 of FIG. The operation control is executed (step S202). On the other hand, when the automatic operation is not set (step S201-NO), the manual operation is set. In this case, the operation control of each air conditioner is executed according to the operation schedule set manually by the operation of the administrator (step S203).

  In the above embodiment, two types of air conditioners according to the system are the radiation ceiling 200 and the air conditioner 300, but the configuration of the present embodiment can be applied to three or more types. Moreover, the air-conditioning system with which each system-type air conditioner corresponds is not limited to the example given to the said embodiment.

  Further, a program for realizing the function of each unit as the operation schedule creation unit 401, the evaluation unit 402, the display control unit 403, and the operation control unit 404 shown in FIG. 2 is recorded on a computer-readable recording medium. The program recorded on the recording medium may be read by a computer system and executed. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer system” includes a WWW system having a homepage providing environment (or display environment). The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Further, the “computer-readable recording medium” refers to a volatile memory (RAM) in a computer system that becomes a server or a client when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. In addition, those holding programs for a certain period of time are also included.

  The program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the “transmission medium” for transmitting the program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.

1 Building 100-1 to 100-N 1st to Nth Air Conditioning System 200 Radiant Ceiling 300 Air Conditioner 400 Air Conditioning Operation Navigation Device 401 Operation Schedule Creation Unit 402 Evaluation Unit 403 Display Control Unit 404 Operation Control Unit 405 Storage Unit 406 Operation Unit 407 Display unit 408 Network communication unit 409 Data interface 451 Weather forecast data 452 Actual building load data 500 Network

Claims (3)

For air conditioning facilities each having one or more method-specific air conditioners that perform air conditioning by different air-conditioning methods, determine which method should be given priority control in which time zone An operation schedule creation unit that creates an operation schedule for each of the air conditioners classified by method that is optimized,
An air conditioning operation navigation device, comprising: a display control unit that displays the created operation schedule on a display device. An evaluation unit that performs evaluation on a predetermined evaluation item when the air conditioner according to each method is operated according to the created operation schedule;
The air-conditioning operation navigation apparatus according to claim 1, wherein the display control unit displays an evaluation result by the evaluation unit. The air-conditioning operation navigation according to claim 1 or 2, further comprising an operation control unit that operates the air conditioners according to each method according to the created operation schedule when automatic operation is designated. apparatus.

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