JP2017161205A - Humidification control system and control program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a humidification control system which can, prior to an operation of a heating device, calculate the cost required for the electric power of the heating device which heats an outside air to be sent to a humidity absorbing/releasing material for humidification.SOLUTION: A humidification control system 10 includes: a humidity absorbing/releasing material 210; a fan device 220 for sending outside air to the humidity absorbing/releasing material 210; a heating device 230 for heating the outside air sent to the humidity absorbing/releasing material 210 by the fan device 220; and a control unit 100 for controlling an operation of the heating device 230. The control unit 100 calculates the cost required for the operation of the heating device 230 in the future set time period based on an outside air temperature, displays the cost for the operation of the heating device 230 in the set time period using the calculation result, and the like.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a humidification control system and a control program used in the humidification control system.

  Conventionally, humidification systems (such as air conditioners) that send moisture to the moisture absorber to adsorb moisture in the air and humidify the moisture absorber by heating it with a heater to desorb moisture (patents) Reference 1).

JP 2006-189210 A

  By the way, in the humidification control system that humidifies the room space etc. to an appropriate humidity by the moisture released from the moisture absorbing / releasing material by heating the outside air sent to the moisture absorbing body (absorbing / releasing material) with a heater, The heater load may be relatively large.

  Therefore, the present invention is made to deal with a user who wants to select one that is not humidified depending on the cost required to operate the heater. That is, according to the present invention, it is possible to select whether the heating device is operated or not according to the cost required for the operation of the heating device such as an electric heater. It aims at providing the humidification control system which can calculate. Moreover, an object of this invention is to provide the control program used with this humidification control system.

  In order to achieve the above object, a humidification control system according to an aspect of the present invention includes a moisture absorbing / releasing material, a blowing device that sends outside air to the moisture absorbing / releasing material, and the moisture absorbing / releasing material by the blowing device. A humidification control system comprising a heating device for heating the outside air to be sent and a control device for controlling the operation of the heating device, the control device operating the heating device in a set time zone in the future Is calculated based on the outside air temperature, and a predetermined process related to the operation of the heating device in the set time period is executed using the calculation result.

  Moreover, in order to achieve the said objective, the control program which concerns on 1 aspect of this invention is a moisture absorption / release material, the air blower which sends external air to the said moisture absorption / release material, and the said moisture absorption / release material by the said air blower. Control for causing the control device to execute a control process in a humidification control system comprising a heating device for heating the outside air sent to and a control device having a microprocessor and controlling the operation of the heating device In the program, the control process includes an acquisition step of acquiring information related to an outside air temperature, an outside air temperature specifying step of specifying an outside air temperature in a future set time zone based on the information acquired in the acquisition step, A calculation step for calculating a cost required for operating the heating device in a set time period based on the outside air temperature specified in the outside air temperature specifying step; Using said costs are calculated in step, and a process step of executing a predetermined processing related to the operation of the heating device in the set time zone.

  According to the present invention, it is possible to calculate costs such as power consumption of a heating device required for humidification. For this reason, for example, it is possible to select whether or not to operate the heating device depending on the cost.

It is a figure which shows schematic structure of the humidification control system which concerns on Embodiment 1. FIG. 3 is a functional block diagram of a control device according to Embodiment 1. FIG. It is a figure which shows an example of the input screen of the humidification control setting information which concerns on Embodiment 1. FIG. It is a figure which shows an example of the information for target temperature specification. It is a figure which shows an example of weather forecast information. 4 is a flowchart illustrating an example of a control process performed by the control device according to the first embodiment. It is a figure which shows an example of the screen output by control processing. It is a figure which shows an example of the screen output by the control process changed partially. It is a figure which shows schematic structure of the humidification control system which concerns on Embodiment 2. FIG. 6 is a functional block diagram of a control device according to Embodiment 2. FIG. FIG. 6 is a functional block diagram of a control device according to Embodiment 3. It is a figure which shows an example of the input screen of the humidification control setting information which concerns on Embodiment 3. FIG. 12 is a flowchart illustrating an example of a control process performed by a control device according to a third embodiment.

(Embodiment 1)
Hereinafter, embodiments will be described with reference to the drawings. Each of the embodiments shown here shows a specific example of the present invention. Accordingly, the numerical values, shapes, materials, components, component arrangement and connection forms, steps (steps) and order of steps, and the like shown in the following embodiments are examples and limit the present invention. is not. Among the constituent elements in the following embodiments, constituent elements that are not described in the independent claims can be arbitrarily added. Each figure is a mimetic diagram and is not necessarily illustrated strictly.

  Hereinafter, a humidification control system according to an embodiment of the present invention will be described.

(Constitution)
FIG. 1 is a diagram showing a schematic configuration of a humidification control system 10 according to the present embodiment. The example of the figure shows each component of the humidification control system 10 provided in the inside (indoor) of the house 20 which is a building.

  In FIG. 1, an external (outdoor) network 31 and a server device 30 of the house 20 are added. The server device 30 is a computer having a web server function and the like. For example, the server device 30 is operated by an administrative organization, a private organization, and the like, and provides weather forecast information indicating future temperatures in each region predicted based on various measured weather data. provide. The network 31 is a wide area network such as the Internet.

  The humidification control system 10 is a system for taking in outside air and humidifying each indoor area, and includes a control device 100, a moisture absorption / release unit 200, a blower device 220, a heating device 230, and an information terminal 50. . The indoor areas are the living rooms 21 and 22 in FIG. 1, and specific examples are a bedroom, a living room, a kitchen, and a hallway. Here, for the sake of convenience, description will be given focusing on humidification of the living room 21.

  The moisture absorption / release unit 200 is provided, for example, in a wall panel of the living room 21 and includes a moisture absorption / release material 210. The moisture absorbing / releasing material 210 is a material that absorbs and releases moisture, and is, for example, zeolite. The wall panel has, for example, a height of 2 m, a width of 4 m, and a thickness of 0.1 m, and the moisture absorption / release unit 200 has, for example, the height and width substantially the same as the wall panel and a thickness of about 0.07 m. . The air that has flowed into the moisture absorption / release unit 200 from below flows into the living room 21 through an opening (blower) provided in the upper part of the moisture absorption / release unit 200 by touching the moisture absorption / release material 210.

  The air blower 220 has a fan and sends outdoor air (outside air) to the moisture absorbing / releasing material 210 of the moisture absorbing / releasing unit 200. For example, an air duct or the like may be provided as a path that takes in outside air and guides it from the blower 220 to the lower portion of the moisture absorption / release unit 200.

  The heating device 230 is a device that heats the air sent to the moisture absorption / release material 210 by the blower 220, and includes a heater that heats the air using electrical energy, a temperature sensor that measures the temperature of the heated air, and the like. The heating method may be any method, for example, a resistance heating method. The heating device 230 can be operated at a set time period under the control of the control device 100. Here, as an example, the set time zone is described assuming that it is a time zone from night to the next morning, but it does not mean that other time zones are excluded. In a state where the heating device 230 is not operating, the moisture-absorbing / releasing material 210 adsorbs moisture by the outside air containing moisture being sent to the moisture-absorbing / releasing material 210. In a state where the heating device 230 is in operation, the outside air is heated, and dry air is sent to the moisture absorbing / releasing material 210 so that moisture in the moisture absorbing / releasing material 210 is desorbed, and the air containing the moisture is in the room. It flows to 21. Thereby, the living room 21 is humidified.

  The control device 100 is a computer having a function of controlling the heating device 230 and the like. The control device 100 includes a communication interface (I / F) 101, a memory 102, and a processor (microprocessor) 103. The communication I / F 101 is a communication circuit for wireless communication or wired communication. With the communication I / F 101, the control device 100 can communicate with the information terminal 50, the server device 30, and the like, for example. The memory 102 is a ROM that stores a program and data in advance, a RAM that is used to store data when the program is executed, and may include, for example, a nonvolatile memory. Note that the control device 100 may include a storage device such as a hard disk device in addition to the memory 102. The processor 103 executes various programs by controlling the communication I / F 101 and the like by executing a program stored in the memory. The control device 100 may include a display device (display) and an input device (keyboard, touch panel, etc.) as user interfaces. Here, the control device 100 uses the information terminal 50 as a user interface (display device and input device) of the control device 100 by communicating with the information terminal 50 using the communication I / F 101. The information terminal 50 is a computer such as a tablet or a smartphone including a communication I / F, a memory, a processor, a display device, and an input device, and is used for a resident (user) of the house 20.

  The control device 100 executes a control process for control related to the operation of the heating device 230. For this purpose, as shown in FIG. 2, the control device 100 includes a user interface unit 110, a storage unit 120, a spatial information acquisition unit 130, a time zone information acquisition unit 140, a weather forecast information acquisition unit 150, and a temperature specification unit. 160, a cost calculation unit 170 and a control unit 180.

  The user interface unit 110 has a function of displaying information and accepting user operations, and is realized by the communication I / F 101, the processor 103 that executes a control program, and the like. Specifically, the user interface unit 110 transmits information (for example, information on the amount of power required for humidification) to the information terminal 50 to display on the information terminal 50. Then, the user interface unit 110 acquires the information related to the user operation received by the information terminal 50 from the information terminal 50. Information that can be input by the user includes humidification control setting information. The humidification control setting information includes space information indicating the size of the space to be humidified, time zone information indicating a time zone for humidification (set time zone), etc., and a predetermined default value when the user does not input (Default value) is used. The size of the space to be humidified can be expressed by numerical values of various units (for example, cubic meters, square meters, tatami mats, etc.) related to the volume of the space (living room) or the floor area, for example. FIG. 3 shows an example of an input screen for humidification control setting information. The screen 51 shown in the figure includes an input field 51a for inputting the size of a space to be humidified, input fields 51b and 51c for inputting a time period (set time period) for humidification, and a setting button 51d. The user inputs a numerical value in each input field and presses the setting button 51d to perform a setting operation (input of humidification control setting information), and the user interface unit 110 acquires the input content. In addition, the user can perform an input operation on the user interface unit 110 for operating or stopping the heating device 230 during a set time period (that is, an operation for selecting whether to perform heating for humidification). . When the control device 100 includes a display device and an input device, the user interface unit 110 may display information on the display device and acquire information related to a user operation from the input device.

  The storage unit 120 is realized in one area of the memory 102 and has a function of storing space information, a set time zone, target temperature specifying information, and the like. FIG. 4 shows an example of predetermined target temperature specifying information. In order to set the space to be humidified to an appropriate humidity (relative humidity) by the humidification control system 10, the temperature to be heated by the heating device 230 varies depending on the size of the space. A suitable relative humidity is, for example, a value in the range of 40-60% which is generally comfortable for humans. The target temperature specifying information is information in which each of a plurality of spaces is associated with a target temperature. The larger the space, the higher the target temperature. The target temperature specifying information is used by the temperature specifying unit 160 to specify the target temperature.

  The spatial information acquisition unit 130 is realized by the processor 103 or the like that executes a control program, and has a function of acquiring spatial information input by the user via the user interface unit 110 and storing the spatial information in the storage unit 120.

  The time zone information acquisition unit 140 is realized by the processor 103 or the like that executes the control program, acquires time zone information indicating the set time zone input by the user via the user interface unit 110, and sets the set time zone. It has a function of storing in the storage unit 120.

  The weather forecast information acquisition unit 150 is realized by the communication I / F 101, the processor 103 that executes a control program, and the like. For example, the weather forecast information acquisition unit 150 refers to the identification information of the location area of the house 20 preset in the control device 100, accesses the server device 30, and receives the weather forecast information corresponding to the area. It has a function of acquiring weather forecast information and transmitting it to the cost calculation unit 170. Access to the server device 30 of the weather forecast information acquisition unit 150 is performed via the network 31. FIG. 5 shows an example of weather forecast information. As shown in the figure, the weather forecast information is information indicating the outside air temperature in each future time zone, and may include, for example, the weather in addition to the outside air temperature.

  The temperature specifying unit 160 is realized by the processor 103 or the like that executes the control program, and based on the target temperature specifying information and the space information stored in the storage unit 120, the target temperature when the outside air is heated by the heating device 230 It has a function to specify.

  The cost calculation unit 170 is realized by the processor 103 or the like that executes a control program. The cost calculating unit 170 has a function of calculating the cost required for the operation of the heating device 230 in the set time zone (future set time zone) based on the outside air temperature before the set time zone stored in the storage unit 120 arrives. . The cost is, for example, the amount of power that will be consumed by the heating device 230 in the set time period in the future (the amount of power required to operate the heating device 230), or a power charge corresponding to the amount of power. Here, description will be made assuming that the cost is the amount of power and the power charge. The cost calculation unit 170 obtains the outside air temperature from the weather forecast information transmitted from the weather forecast information acquisition unit 150. The cost calculation unit 170 includes a heating device load calculation unit 171 and an electric energy calculation unit 172.

  The heating device load calculation unit 171 calculates the load of the heating device 230 according to the temperature difference between the target temperature specified by the temperature specification unit 160 and the outside air temperature in the set time period. Specifically, the heating device load calculation unit 171 adds the specific heat of air (J / (kg · K)) and the size of the space indicated by the spatial information to the temperature difference (° C., K) between the target temperature and the outside air temperature. The load (J) is calculated by multiplying the amount of air (cubic meter) corresponding to 1 and the density of air (kg / cubic meter). In the heating device load calculation unit 171, for example, the outside air temperature for each unit time (for example, 1 hour) in the set time period is specified based on the weather forecast information, and the temperature difference from the target temperature is determined for each unit time. Thus, the load of the heating device 230 can be calculated. The unit time may be the same as the certain time when the outside air temperature is predicted every certain time in the weather forecast information, or may be a time different from the certain time. When the unit time is different from the certain time, the heating device load calculating unit 171 estimates the outside air temperature per unit time from, for example, the outside air temperature per certain time in the weather forecast information.

  The power amount calculation unit 172 multiplies the load (J) calculated for each unit time by the heating device load calculation unit 171 by, for example, the energy consumption efficiency (COP: Coefficient Of Performance) of the heating device 230, so The amount of power (kWh) is calculated. And the electric energy calculation part 172 calculates the total of the calculated electric energy for every unit time as an electric energy which the heating apparatus 230 consumes in a setting time slot | zone. Moreover, the electric energy calculation part 172 calculates an electric power charge from the electric energy of the set time slot | zone. The unit price used for deriving the power rate from the amount of power may be a fixed value corresponding to a predetermined general unit price, or may be a value input by the user or obtained from a server of the electric power company, etc. It may be a value. That is, the cost calculation unit 170 calculates the cost related to the power consumption of the heating device 230 in the set time period by the heating device load calculation unit 171 and the electric energy calculation unit 172. The cost calculation unit 170 causes the user interface unit 110 to output the calculated cost (power amount and power charge).

  The control unit 180 is realized by, for example, the communication I / F 101, the processor 103 that executes a control program, and the like. When a selection regarding whether the user activates or stops the heating device 230 is received from the user interface unit 110, the user interface unit 110 has a function of performing control for operating or stopping the heating device 230 in a set time period according to the selection. When operating the heating device 230 in the set time period, the control unit 180 controls the heating device 230 to heat to the target temperature specified by the temperature specifying unit 160. For example, when receiving the instruction of the target temperature from the control device 100, the heating device 230 adjusts the degree of heating with the heater according to the temperature measured by the temperature sensor and heats the target temperature closer to the target temperature. The humidification control of the living room 21 by the humidification control system 10 is mainly performed by the control of the heating device 230 by the control device 100.

  The control device 100 including the above functional components calculates the cost required for the operation of the heating device 230 in the future set time zone based on the outside air temperature, and uses the calculation result to operate the heating device 230 in the set time zone. Predetermined processing related to (output of calculation results) is executed.

(Operation)
Hereinafter, an operation example of the humidification control system 10 having the above-described configuration will be described focusing on the operation of the control device 100.

  FIG. 6 is a flowchart illustrating an example of a control process performed by the control device 100. The control process will be described below with reference to FIG. This control process is executed, for example, once a day in the evening.

  In response to a user operation on the information terminal 50, the spatial information acquisition unit 130 of the control device 100 acquires the spatial information via the user interface unit 110 and stores it in the storage unit 120 (step S11). Spatial information indicates the size of the space to be humidified, and is, for example, the entire space of the living room 21 or a partial size (the number of tatami mats) of the living room 21 divided by partitions (see FIG. 3). Similarly, the time zone information acquisition unit 140 of the control device 100 acquires time zone information indicating a time zone (set time zone) for humidification via the user interface unit 110 and stores the set time zone in the storage unit 120. (Step S12).

  Moreover, the weather forecast information acquisition part 150 of the control apparatus 100 acquires the weather forecast information which shows external temperature etc. from the server apparatus 30 (step S13).

  Next, the temperature specifying unit 160 of the control device 100 specifies a target temperature related to heating by the heating device 230 according to the spatial information in the storage unit 120 (step S14).

  Subsequently, the control device 100 uses the cost calculation unit 170 (heating device load calculation unit 171) to calculate the heating device load (heating) from the temperature difference between the outside air temperature (predicted value) and the target temperature in the set time zone based on the weather forecast information. The load of the device 230 is calculated (step S15). In Step S15, heating device load calculation part 171 specifies outside temperature (for example, outside temperature for every unit time) in a set time zone based on weather forecast information as mentioned above. And the cost calculation part 170 (electric energy calculation part 172) calculates the electric energy required for operation | movement of the heating apparatus 230 in a setting time slot | zone from a heating apparatus load (step S16). Further, the power amount calculation unit 172 calculates a power charge corresponding to the power amount (step S17).

  Next, the cost calculation unit 170 of the control device 100 causes the user interface unit 110 to output the calculated cost (power amount and power charge) required for the heating by the heating device 230 (step S18). Thereby, for example, the information on the power amount and the power charge is transmitted from the control device 100 to the information terminal 50 and displayed on the information terminal 50. FIG. 7 shows an example of a display screen that displays on the information terminal 50 the cost calculated by the cost calculation unit 170 of the control device 100. The screen 52 shown in the figure includes a display element 52a representing the amount of power and a power charge, and selection buttons 52b and 52c. The user selects and presses either the selection button 52b or the selection button 52c to determine whether or not to operate the heating device 230 in the set time period (tonight) (that is, whether or not to perform humidification). ) Is specified. Then, the user interface unit 110 notifies the control unit 180 of the user's designation (whether or not the heating device 230 is operated during the set time period).

  When an operation for designating the operation of the heating device 230 in the set time zone is performed (step S19), the control device 100 controls the control unit 180 to operate the heating device 230 in the set time zone (step S20). . Specifically, control unit 180 causes heating device 230 to perform heating so as to achieve the target temperature specified in step S14. For example, the control part 180 can implement | achieve control by step S20 by transmitting the signal which instruct | indicates operation | movement including target temperature to the heating apparatus 230. FIG.

  On the other hand, when an operation for designating non-execution (stop) of the operation of the heating device 230 in the set time zone is performed (step S21), the control device 100 stops the heating device 230 in the set time zone by the control unit 180. Control is performed (that is, operation is not performed) (step S22). For example, the control unit 180 may realize the control in step S22 by transmitting a signal instructing the stop to the heating device 230, or suppress transmission of a signal instructing the heating device 230 to operate. Thus, the control in step S22 may be realized. The control device 100 is also set by the control unit 180 when a certain time (for example, several tens of minutes) has passed without the user specifying whether or not to operate the heating device 230 during the set time period. Control is performed to stop the heating device 230 in the time zone (step S22).

  By performing the control process in this way, the humidification control system 10 can calculate and display the cost required for the operation of the heating device 230 that heats the outside air for humidification prior to the operation. For this reason, when it is predicted that the operating cost of the heating device 230 is higher than a certain limit due to the fact that the outside air temperature is predicted to be relatively low, for example, the option of not operating the heating device 230 is selected. , Users will be able to do it.

(Modification of Embodiment 1)
In the first embodiment described above, when the control device 100 operates the heating device 230 during the set time period, one power amount and one power charge are displayed as the cost of the heating device 230 (cost related to power consumption). An example is shown (see FIG. 7). In addition, the control device 100 may be modified so as to display a range (for example, a minimum value and a maximum value) for the cost related to power consumption.

  The deformed control device 100 is the same as the control device 100 shown in the first embodiment in the points not described here. The modified control device 100 specifies the maximum value and the minimum value of the outside air temperature for each unit time in the set time zone based on, for example, weather forecast information. For example, the result obtained by adding a prediction error determined in advance according to the weather indicated by the weather forecast information to the outside temperature indicated by the weather forecast information is specified as the maximum value of the outside air temperature, and the result obtained by subtracting the prediction error is excluded. Identified as the minimum temperature. For example, when the weather is clear, the prediction error is large, and when the weather is cloudy, the prediction error is small. Then, the deformed control device 100 causes the cost calculation unit 170 to reduce the cost according to the temperature difference between the maximum value of the outside air temperature and the target temperature and the temperature difference between the specified minimum value of the outside air temperature and the target temperature. The range of electricity (range of electric energy and range of electricity charges) is calculated. The method of calculating each cost (minimum value and maximum value of the cost range) from each temperature difference is the same as the method shown in the first embodiment. Then, the cost calculation unit 170 of the modified control device 100 causes the user interface unit 110 to output the calculated cost range. With the output of the user interface unit 110, for example, information indicating the range of the electric energy and the electric power charge is transmitted from the modified control device 100 to the information terminal 50 and displayed on the information terminal 50. FIG. 8 shows an example of a display screen that displays the cost calculated by the cost calculation unit 170 of the modified control device 100 on the information terminal 50. The screen 53 shown in the figure includes a display element 53a indicating the range of the electric energy and the electric charge, and selection buttons 53b and 53c. The user designates whether or not to stop the heating device 230 in the set time period (tonight) by selecting and pressing either the selection button 53b or the selection button 53c. Then, the user interface unit 110 informs the control unit 180 of the user's designation (whether to stop the heating device 230 during the set time period). The modified control device 100 can also perform the control process shown in FIG. 6 except that the range is calculated for the cost (amount of electric power and electric power charge). When a certain time (for example, several tens of minutes) has passed without the user specifying whether or not to operate the heating device 230 during the set time period (step S23), the processing procedure shown in FIG. It is good also as controlling so that the heating apparatus 230 may be operated by the control part 180 by a setting time slot | zone by deform | transforming a part (step S20).

(Embodiment 2)
Hereinafter, a part of the humidification control system 10 is modified so that the cost required for heating by the heating device 230 for humidification can be calculated and output without receiving weather forecast information from the server device 30. The humidification control system 10a will be described.

  FIG. 9 is a diagram showing a schematic configuration of a humidification control system 10a according to the present embodiment. Among the constituent elements of the humidification control system 10a shown in the figure, the same constituent elements as those of the humidification control system 10 described above are denoted by the same reference numerals as those in FIG.

  The humidification control system 10a is a system for taking in outside air and humidifying each indoor area, and includes a control device 100a, a moisture absorption / release unit 200, a blower 220, a heating device 230, a measuring device 240, and an information terminal 50. Consists of.

  The control device 100a is a computer obtained by partially modifying the control device 100 shown in the first embodiment and having a function of controlling the heating device 230 and the like. Similar to the control device 100, the control device 100 a includes a communication I / F 101, a memory 102, and a processor 103. For example, the control device 100 a is different from the control device 100 in the content of a control program stored in the memory 102 and executed by the processor 103. The control device 100 a may include a storage device such as a hard disk device in addition to the memory 102. The control device 100a may include a display device (display) and an input device (keyboard, touch panel, etc.) as user interfaces. Here, like the control device 100, the control device 100a communicates with the information terminal 50 using the communication I / F 101, thereby using the information terminal 50 as a user interface (display device and input device) of the control device 100a. I decided to.

  The measuring device 240 includes a temperature sensor and has a function of measuring the temperature of the outside air (outside air temperature). The measuring device 240 is installed and used at a position where the outside air temperature can be measured.

  The control device 100a executes a control process for controlling the heating device 230. For this purpose, as shown in FIG. 10, the control device 100a has a user interface unit 110, a storage unit 120, a spatial information acquisition unit 130, a time zone information acquisition unit 140, an outside air temperature measurement result acquisition unit 151, and a temperature specification unit as shown in FIG. 160, a cost calculation unit 170a and a control unit 180. Of the components of the control device 100a shown in FIG. 10, the same components as those of the control device 100 described above are denoted by the same reference numerals as those in FIG. The control device 100a is the same as the control device 100 with respect to points not specifically described here.

  The outside air temperature measurement result acquisition unit 151 is realized by the communication I / F 101, the processor 103 that executes the control program, and the like, and has a function of acquiring the outside air temperature measured by the measurement device 240 and transmitting it to the cost calculation unit 170a.

  The cost calculation unit 170a is a partial modification of the cost calculation unit 170 shown in the first embodiment, and is realized by the processor 103 or the like that executes a control program. The cost calculation unit 170a has a function of calculating the cost required for the operation of the heating device 230 in the set time zone (future set time zone) based on the outside air temperature before the set time zone stored in the storage unit 120 arrives. . The cost calculation unit 170 a is notified of the outside air temperature from the outside air temperature measurement result acquisition unit 151. The cost calculation unit 170a includes a heating device load calculation unit 171a and an electric energy calculation unit 172.

  Based on the outside air temperature (measurement result) transmitted from the outside air temperature measurement result acquisition unit 151, the heating device load calculation unit 171a uses, for example, data related to temporal changes in the past outside air temperature in the set time period. The outside air temperature per unit time (for example, 1 hour) is estimated. Note that any conventional method may be used as a method for estimating (specifying) the outside air temperature per unit time in the set time period from the measurement result of the outside air temperature. For example, the difference between the measurement result of the outside air temperature immediately before the past (previous day etc.) set time zone and the measurement result of the outside air temperature per unit time in the past (previous day etc.) set time zone By adding to the measurement result of the outside air temperature immediately before, the outside air temperature for each unit time in the set time zone in the future may be specified. The heating device load calculation unit 171a calculates the load of the heating device 230 per unit time according to the temperature difference between the target temperature specified by the temperature specification unit 160 and the outside air temperature per unit time in the set time period. . Specifically, the heating device load calculation unit 171a adds the specific heat of air (J / (kg · K)) and the size of the space indicated by the spatial information to the temperature difference (° C., K) between the target temperature and the outside air temperature. The load (J) is calculated by multiplying the amount of air (cubic meter) corresponding to 1 and the density of air (kg / cubic meter).

  Based on the load (J) calculated for each unit time by the heating device load calculation unit 171a, the power amount calculation unit 172 calculates the power amount (kWh) per unit time as shown in the first embodiment. The calculated total amount of power per unit time is calculated as the amount of power consumed by the heating device 230 in the set time period. Moreover, the electric energy calculation part 172 calculates an electric power charge from the electric energy of the set time slot | zone. As described above, the cost calculation unit 170a calculates the cost related to the power consumption of the heating device 230 in the set time period by the heating device load calculation unit 171a and the electric energy calculation unit 172. The cost calculation unit 170a causes the user interface unit 110 to output the calculated cost (power amount and power charge).

  The control device 100a operates in the control process shown in FIG. 6 in that the weather forecast information acquisition unit 150 of the control device 100 acquires the weather forecast information in step S13, and the outside air temperature measurement result acquisition unit 151 uses the measurement device 240. It will be changed to acquire the measurement result of the outside temperature. As described above, in the control device 100a, instead of specifying the outside air temperature in the set time zone from the weather forecast information, the outside air temperature in the set time zone is estimated and heated from the measurement result of the outside air temperature by the measuring device 240. Costs such as the amount of power required to operate the device 230 are calculated.

  By performing the control process in this manner, the humidification control system 10a can calculate and display the cost required for the operation of the heating device 230 that heats the outside air for humidification prior to the operation.

(Embodiment 3)
Hereinafter, a control device 100b obtained by modifying a part of the control device 100 in the humidification control system 10 shown in the first embodiment will be described.

(Constitution)
In the humidification control system according to the present embodiment, the components other than the control device 100b are the same as the humidification control system 10 (see FIG. 1) shown in the first embodiment, and the same reference numerals as those in the first embodiment are used. Represent.

  The control device 100b has a function of determining whether or not to operate the heating device 230 based on the cost condition input by the user and controlling the operation and stop of the heating device 230.

  The control device 100b is the same as the control device 100 in hardware (see FIG. 1) and is a computer having a function of controlling the heating device 230 and the like. The control device 100b differs from the control device 100 in the content of a control program stored in the memory 102 and executed by the processor 103, for example. Similarly to the control device 100, the control device 100b can use the information terminal 50 as a user interface (display device and input device) of the control device 100a by communicating with the information terminal 50 using the communication I / F 101.

  The control device 100b executes a control process for controlling the heating device 230. Therefore, in terms of functions, the control device 100b has a user interface unit 110, a storage unit 121, a spatial information acquisition unit 130, a time zone information acquisition unit 140, a weather forecast information acquisition unit 150, and a temperature specification unit 160 as shown in FIG. , A cost calculation unit 170, a control unit 181, and an upper limit information acquisition unit 190. Among the components of the control device 100b shown in FIG. 11, the components that are substantially the same as the components of the control device 100 described above are denoted by the same reference numerals as those in FIG. The control device 100b is the same as the control device 100 in points not specifically described here.

  The storage unit 121 is realized in one area of the memory 102 and has a function of storing spatial information, a set time zone, target temperature specifying information, upper limit information, and the like. The upper limit information is information indicating the upper limit of the cost required for performing humidification (that is, the cost required for heating the heating device 230).

  The upper limit information acquisition unit 190 is realized by the processor 103 or the like that executes a control program, and has a function of acquiring upper limit information input by the user via the user interface unit 110 and storing the upper limit information in the storage unit 121.

  In the control device 100b, the humidifying control setting information acquired by the user interface unit 110 receiving information related to the user operation received by the information terminal 50 from the information terminal 50 is spatial information and time zone information indicating the set time zone. In addition, upper limit information is included. When the user does not input each information of the humidification control setting information, a predetermined default value (default value) is used. FIG. 12 shows an example of an input screen for humidification control setting information. The screen 54 shown in the figure includes an input field 54a for input of the size of the space to be humidified, input fields 54b and 54c for input of a humidifying time zone (set time zone), and an upper limit of cost required for performing humidification (an example) As an input field 54d for inputting the upper limit of the power charge of the heating device 230, and a setting button 54e. The user inputs the humidification control setting information by inputting a numerical value in each input field and pressing the setting button 54e, and the user interface unit 110 acquires the input content.

  The weather forecast information acquisition unit 150 in the control device 100b acquires weather forecast information indicating the latest outside air temperature or the like from the server device 30 when the start time of the set time period comes.

  The cost calculation unit 170 calculates the cost related to the power consumption of the heating device 230 in the set time period by the heating device load calculation unit 171 and the electric energy calculation unit 172 as described in the first embodiment. However, the cost calculation unit 170 in the control device 100b does not have to output the calculated cost (power amount and power charge) to the user interface unit 110.

  The control unit 181 is realized by, for example, the communication I / F 101, the processor 103 that executes a control program, and the like. The control unit 181 performs control for operating or stopping the heating device 230 in the set time period depending on whether the cost calculated by the cost calculation unit 170 satisfies the condition indicated by the upper limit information stored in the storage unit 121. Has the function to perform. When operating the heating device 230 in the set time period, the control unit 181 controls the heating device 230 to heat to the target temperature specified by the temperature specifying unit 160. The humidification control of the living room 21 by the humidification control system 10 according to the present embodiment is performed mainly by the control of the heating device 230 by the control device 100b.

  The control device 100b including each functional component described above calculates the cost required for the operation of the heating device 230 in the future set time zone based on the outside air temperature, and uses the calculation result to operate the heating device 230 in the set time zone. A predetermined process related to the above (control to perform either operation or stop) is executed.

(Operation)
FIG. 13 is a flowchart illustrating an example of a control process performed by the control device 100b. The control process will be described below with reference to FIG. This control process is started, for example, when the user starts using the humidification control system 10. At the start of use of the humidification control system 10 according to the present embodiment, the user uses the information terminal 50 to input humidification control setting information on an input screen (screen 54) as illustrated in FIG.

  In response to a user operation on the information terminal 50, the spatial information acquisition unit 130 of the control device 100b acquires the spatial information via the user interface unit 110 and stores it in the storage unit 121 (step S31). Further, the time zone information acquisition unit 140 of the control device 100 b acquires time zone information indicating a time zone (set time zone) for humidification via the user interface unit 110 and stores the set time zone in the storage unit 121. (Step S32). Further, the upper limit information acquisition unit 190 of the control device 100b acquires upper limit information indicating the upper limit of the cost required for performing humidification (for example, the upper limit of the power charge) via the user interface unit 110, and stores it in the storage unit 121 (step S1). S33).

  When the set time period acquired in step S32 has arrived, the control device 100b executes the processes in and after step S35, and waits until the set time period has not arrived (step S34). Thereby, when the set time zone arrives every day, the processes in and after step S35 are repeated. The processing in steps S35 to S39 is the same as the processing in steps S13 to S17 shown in FIG.

  That is, in step S <b> 35, the weather forecast information acquisition unit 150 of the control device 100 b acquires weather forecast information indicating the outside temperature from the server device 30. In step S <b> 36, the temperature specifying unit 160 of the control device 100 b specifies a target temperature related to heating by the heating device 230 according to the spatial information in the storage unit 121. In step S <b> 37, the control device 100 b uses the cost calculation unit 170 (heating device load calculation unit 171) to calculate the heating device load (predicted value) and the target temperature from the temperature difference between the outside temperature (predicted value) and the target temperature based on weather forecast information. The load of the heating device 230 is calculated. In step S38, the cost calculation unit 170 (power amount calculation unit 172) calculates the amount of power required to operate the heating device 230 in the set time period from the heating device load. In step S39, the cost calculation unit 170 (power amount calculation unit 172) calculates a power charge corresponding to the power amount.

  Next, the control unit 181 of the control device 100b determines whether or not the power charge calculated by the cost calculation unit 170 exceeds the upper limit of the power charge indicated by the upper limit information in the storage unit 121 (step S40). When the calculated power charge (the power charge required for operating the heating device 230 during the set time period) does not exceed the upper limit, the control unit 181 controls to operate the heating device 230 during the set time period (step S41). ). Specifically, the control unit 181 causes the heating device 230 to perform heating so as to achieve the target temperature specified in step S36. For example, the control unit 181 can realize the control in step S41 by transmitting a signal including the target temperature and instructing operation to the heating device 230. On the other hand, when the calculated power charge (power charge required for operating the heating device 230 during the set time period) exceeds the upper limit, the control unit 181 stops the heating apparatus 230 during the set time period (that is, does not operate). Control is performed (step S42).

  With such a control process, the humidification control system 10 according to the present embodiment can calculate the cost required to operate the heating device 230 that heats the outside air for humidification prior to the operation. And according to the calculation result about the cost, it can be controlled to perform either of operating or stopping the heating device 230 during the set time period. For this reason, for example, if the user inputs the upper limit of the power charge once on the screen 54 shown in FIG. 12, for example, the power charge required for heating the heating device 230 overnight is particularly high on a day when the outside air temperature is particularly low. It is possible to prevent the occurrence of a situation exceeding.

(Other embodiments, etc.)
As mentioned above, although the humidification control systems 10 and 10a were demonstrated by Embodiment 1-3, it cannot be overemphasized that embodiment mentioned above is only an example and various changes, addition, omission, etc. are possible.

  In the above-described embodiment, the humidification control systems 10 and 10a include the information terminal 50, but the information terminal 50 may not be included. In this case, if the control devices 100, 100a, and 100b include a display device and an input device as user interfaces, the user interface unit 110 can accept display or input using the user interfaces. In addition, the humidification control systems 10 and 10a may constitute a part of the entire building air conditioning system, and the control devices 100, 100a, and 100b may be devices other than the heating device 230 (such as air conditioning devices that constitute the entire building air conditioning system). ) May be further controlled.

  In the above-described embodiment, the target temperature specifying information (see FIG. 4) is information in which the size of the space is associated with the target temperature. However, the target temperature specifying information is the size of the space. It may be information defining a target temperature with respect to a set of the humidifying time length. In this case, the target temperature becomes higher as the size of the space becomes larger, and becomes higher as the length of time for humidification becomes longer. Correspondingly, the temperature specifying unit 160 determines the target temperature for heating the outside air by the heating device 230 based on the target temperature specifying information, the size of the space indicated by the spatial information, and the length of the set time zone. It can be specified. It should be noted that the temperature specifying unit 160 uses a target temperature when the outside air is heated by the heating device 230 in order to make the humidification target region an appropriate humidity by another method (calculation or the like) instead of using the target temperature specifying information. May be specified.

  Moreover, in the above-mentioned embodiment, the example which outputs (transmits and displays) the cost (cost required for the operation of the heating device 230 in the set time zone) calculated by the control devices 100 and 100a is shown. However, the cost may be output by other methods, for example, a voice representing the cost may be output from a speaker or the like, or may be displayed or emitted in a manner previously associated with the size of the cost. Good.

  Moreover, in the above-mentioned Embodiment 3, the control apparatus 100b showed the example which performs control which performs operation | movement of the heating apparatus in the set time zone of the night in the range which does not exceed the upper limit of the electric power charge designated by the user. . In addition to this, the control device 100b may execute the operation of the heating device in the set time range overnight without exceeding the upper limit of the electric energy specified by the user.

  Moreover, the control devices 100, 100a, and 100b described above may have a function as a HEMS controller in a HEMS (Home Energy Management System) that manages energy such as electric power in the house 20, for example. When assuming the function as the HEMS controller, the control devices 100, 100a, and 100b are, for example, various HEMS devices (air conditioners, home appliances, power generation devices, power storage devices, and heating devices) in the house 20 in order to reduce power consumption. 230, etc.) are controlled via a HAN (Home Area Network). Further, the control devices 100, 100a, and 100b may measure the power supply / demand state of the HEMS device and display the power supply / demand state of the house 20 on the information terminal 50 or the like based on the measurement result.

  Further, in the above-described embodiment, the example in which the moisture absorption / release unit 200 is provided in the wall panel is shown, but the moisture absorption / release unit may be provided in another place, for example, on the ceiling or the like. May be. Moreover, the moisture absorption / release unit 200 should just include the moisture absorption / release material 210, and the passage path | route of the air in an inside is not restricted to the path | route from a lower part to an upper part. The moisture absorption / release unit 200 may have any shape and structure.

  Moreover, in the above-mentioned embodiment, although the humidification control systems 10 and 10a showed the example which humidifies one area | region (living room 21) of the house 20, it is good also as humidifying a some area | region. When humidifying a plurality of regions (such as a living room), the humidification control system 10, 10a may be configured to include a moisture absorption / release unit for each region, or one moisture absorption / release unit may be a plurality of regions. For example, it may be configured to include a branching air duct so that air can be blown out to each. Moreover, the humidification control systems 10 and 10a may be used in offices other than the house 20, buildings, and other facilities.

  In addition, another device (for example, a server outside the house 20) may share a part of the functions of the control devices 100, 100a, and 100b described in the above embodiment. Further, the execution order of the control processing procedure (see FIGS. 6 and 13) in the humidification control systems 10 and 10a is not necessarily limited to the order as described above, and does not depart from the gist of the invention. Thus, the execution order can be changed or a part thereof can be omitted. Further, all or part of the above-described control processing may be realized by hardware of the control devices 100, 100a, 100b or other devices, or may be realized by using software. Note that the processing by software is realized by a control program stored in a memory being executed by a processor included in the control device 100, 100a, 100b or another device. Further, the control program may be recorded on a recording medium and distributed or distributed. For example, by installing the distributed control program in the apparatus and causing the processor of the apparatus to execute it, it is possible to cause the apparatus to perform all or part of the control processing.

  In addition, embodiments realized by arbitrarily combining the constituent elements and functions shown in the above-described embodiments and modifications are also included in the scope of the present invention.

  Note that various general or specific aspects of the present invention include one or a plurality of combinations of an apparatus, a system, a method, an integrated circuit, a computer program, a computer-readable recording medium, and the like.

  Hereinafter, a configuration, a modified mode, an effect, and the like of a humidification control system according to an aspect of the present invention and a control program used in the humidification control system will be described.

  (1) The humidification control system which concerns on 1 aspect of this invention is sent to the moisture absorption / release material 210 by the moisture absorption / release material 210, the air blower 220 which sends external air to the moisture absorption / release material 210, and the air blower 220. A humidification control system 10, 10a comprising a heating device 230 for heating the outside air and a control device 100, 100a, 100b for controlling the operation of the heating device 230, wherein the control devices 100, 100a, 100b are: A cost required for the operation of the heating device 230 in the future set time zone is calculated based on the outside air temperature, and a predetermined process related to the operation of the heating device 230 in the set time zone is executed using the calculation result. The predetermined process related to the operation of the heating device 230 in the set time zone is, for example, a display of the cost required for the operation, and for example, a control for operating or stopping (inhibiting the operation) in the set time zone. is there.

  With this configuration, costs such as power consumption of the heating device 230 required for humidification can be calculated. For this reason, for example, it is possible to select whether or not to operate the heating device 230 according to the cost.

  (2) For example, the cost is the amount of power required for the operation of the heating device 230 in the set time period or a power charge corresponding to the amount of power, and the control devices 100 and 100a calculate the cost as the predetermined process. The result may be output.

  Thereby, since the cost required for the operation of the heating device 230 in the set time zone is output, for example, by checking the output cost, the user can set the heating device 230 in the set time zone based on the cost. It can be decided whether to operate.

  (3) For example, the control devices 100 and 100a include a user interface unit 110 that displays a calculation result for the cost and receives an operation for specifying that the heating device 230 is to be operated or stopped in a set time period. The control devices 100 and 100a may perform control so that the heating device 230 is operated or stopped during a set time period in accordance with an operation received by the user interface unit 110.

  Thereby, since the cost required for the operation of the heating device 230 in the set time zone is displayed, the user operates based on the cost to instruct to operate or stop the heating device 230 in the set time zone. Can do.

  (4) For example, the control devices 100 and 100a have a spatial information acquisition unit 130 that acquires spatial information indicating the size of the humidification target space, and a target temperature when the outside air is heated by the heating device 230 based on the spatial information. The control device 100, 100a may calculate the cost according to the temperature difference between the outside air temperature and the target temperature in the set time zone. The outside air temperature in the set time period can be specified based on, for example, the measured outside air temperature or the outside air temperature indicated by the acquired weather forecast information.

  Accordingly, the cost can be appropriately calculated according to the size of the space to be humidified.

  (5) For example, the control device 100 includes a weather forecast information acquisition unit 150 that acquires weather forecast information indicating a future outside temperature, and the control device 100 specifies the outside temperature in the set time zone based on the weather forecast information. The cost may be calculated according to the temperature difference between the specified outside air temperature and the target temperature.

  Thereby, in the humidification control system 10, it becomes possible to calculate the cost without providing a measuring device or the like for measuring the outside air temperature.

  (6) For example, the control device 100 specifies the maximum value and the minimum value of the outside air temperature for each unit time in the set time zone based on the weather forecast information, and the temperature difference between the specified maximum value and the target temperature, In addition, the cost range may be calculated according to the temperature difference between the specified minimum value and the target temperature, and the user interface unit 110 may display a calculation result for the cost range. The calculation result for the cost range may reflect, for example, a prediction error for the outside temperature in the weather forecast information.

  Thereby, the user can grasp | ascertain the range of the said cost.

  (7) For example, the user interface unit 110 may further receive a setting operation for determining a set time period, and the control device 100 may determine the set time period according to the setting operation received by the user interface unit 110. .

  Thereby, a user can set a setting time slot | zone according to a user's lifestyle.

  (8) For example, the humidification control system 10a includes a measurement device 240 that measures the outside air temperature, and the control device 100a identifies the outside air temperature in a set time period in the future based on the outside air temperature measured by the measurement device 240. The cost may be calculated according to the temperature difference between the specified outside air temperature and the target temperature.

  As a result, the humidification control system 10a can calculate the cost without having, for example, a function of receiving weather forecast information from the server device 30 or the like (for example, a communication function with a wide area network).

  (9) For example, the control device 100b may perform control so that the heating device 230 is operated or stopped in a set time period according to the calculation result of the cost as the predetermined process. .

  Thus, for example, even if the user does not perform a special operation for each set time period according to the cost calculation result, the heating device 230 is controlled to operate and stop (automatic control) according to the cost. become.

  (10) For example, the control device 100b includes an upper limit information acquisition unit 190 that acquires upper limit information indicating the upper limit of the cost specified by the user, and the control device 100b indicates that the calculation result for the cost is indicated by the upper limit information. When the upper limit is not exceeded, the heating device 230 may be operated during the set time period, and when the calculation result exceeds the upper limit indicated by the upper limit information, the heating device 230 may be stopped during the set time period.

  Thereby, according to the conditions concerning the upper limit of the cost designated by the user, the control device 100b controls the operation and stop of the heating device 230 according to the cost.

  (11) The control program according to one aspect of the present invention includes a moisture absorbing / releasing material 210, a blower device 220 that sends outside air to the moisture absorbing / releasing material 210, and outside air that is sent to the moisture absorbing / releasing material 210 by the blowing device 220. In a humidification control system 10, 10a comprising a heating device 230 for heating the heating device and a control device 100, 100a, 100b having a microprocessor and controlling the operation of the heating device 230, the control devices 100, 100a, 100b Is a control program for causing a control process to be executed, and the control process includes an acquisition step (for example, steps S13, S35, etc.) for acquiring information related to outside air temperature, and a future based on the information acquired in the acquisition step. Outside air temperature specifying step (for example, steps S15, S37, etc.) for specifying the outside air temperature in the set time zone, and the set time zone The calculation step (for example, steps S16, S17, S38, S39, etc.) for calculating the cost required for the operation of the heating device 230 based on the outside air temperature specified in the outside air temperature specifying step was calculated in the calculating step. And a processing step (for example, steps S18, S40 to S42, etc.) for executing a predetermined process related to the operation of the heating device 230 in the set time period using the cost.

  If this control program is installed in the control devices 100, 100a, 100b, which are computers equipped with a microprocessor, the control devices 100, 100a, 100b perform control processing, such as the power consumption of the heating device 230 required for humidification. Cost can be calculated. For this reason, for example, it is possible to select whether or not to operate the heating device 230 according to the cost.

10, 10a Humidification control system 100, 100a, 100b Control device 103 Processor (microprocessor)
DESCRIPTION OF SYMBOLS 110 User interface part 130 Spatial information acquisition part 150 Weather forecast information acquisition part 160 Temperature specific | specification part 190 Upper limit information acquisition part 210 Moisture absorption / release material 220 Blower 230 Heating apparatus 240 Measuring apparatus

Claims (11)

A moisture absorbent material;
A blower for sending outside air to the moisture absorbing / releasing material;
A heating device for heating the outside air sent to the moisture absorbing / releasing material by the blower;
A humidification control system comprising a control device that performs control related to operation of the heating device,
The control device calculates a cost required for operation of the heating device in a set time zone in the future based on an outside air temperature, and executes a predetermined process related to the operation of the heating device in the set time zone using a calculation result. Humidification control system. The cost is the amount of power required for the operation of the heating device in the set time zone or a power charge corresponding to the amount of power,
The humidification control system according to claim 1, wherein the control device outputs a calculation result for the cost as the predetermined process. The control device includes a user interface unit that displays a calculation result for the cost and receives an operation for specifying that the heating device is operated or stopped in the set time period,
The humidification control system according to claim 2, wherein the control device controls the heating device to be operated or stopped during the set time period in accordance with an operation received by the user interface unit. The controller is
A spatial information acquisition unit that acquires spatial information indicating the size of the humidification target space;
A temperature specifying unit for specifying a target temperature when heating the outside air by the heating device based on the spatial information;
The humidification control system according to claim 2 or 3, wherein the control device calculates the cost according to a temperature difference between an outside air temperature and the target temperature in the set time period. The control device includes a weather forecast information acquisition unit that acquires weather forecast information indicating a future outside temperature,
The humidification control according to claim 4, wherein the control device specifies an outside air temperature in the set time zone based on the weather forecast information, and calculates the cost according to a temperature difference between the specified outside air temperature and the target temperature. system. The control device specifies a maximum value and a minimum value of an outside air temperature for each unit time in the set time zone based on the weather forecast information, a temperature difference between the specified maximum value and the target temperature, and The cost range is calculated according to the temperature difference between the specified minimum value and the target temperature,
The humidification control system according to claim 5. The user interface part displays a calculation result about the range of the cost. The user interface unit further accepts a setting operation for determining the set time period,
The humidification control system according to any one of claims 2 to 6, wherein the control device determines the set time period according to a setting operation received by the user interface unit. The humidification control system comprises a measuring device for measuring the outside air temperature,
The control device specifies an outside temperature in the set time period in the future based on the outside temperature measured by the measuring device, and calculates the cost according to a temperature difference between the specified outside temperature and the target temperature. The humidification control system according to claim 4. 2. The humidification control system according to claim 1, wherein the control device performs control so that the heating device is operated or stopped in the set time period according to a calculation result of the cost as the predetermined process. . The control device includes an upper limit information acquisition unit that acquires upper limit information indicating an upper limit of the cost specified by the user,
When the calculation result about the cost does not exceed the upper limit indicated by the upper limit information, the control device operates the heating device during the set time period, and the calculation result exceeds the upper limit indicated by the upper limit information. The humidification control system according to claim 9, wherein the heating device is stopped during the set time period. Moisture absorbing / releasing material, blower for sending outside air to the moisture absorbing / releasing material, heating device for heating the outside air sent to the moisture absorbing / releasing material by the blower, and a microprocessor In a humidification control system comprising a control device that performs control related to operation of the device, a control program for causing the control device to execute control processing,
The control process is
An acquisition step for acquiring information about the outside temperature;
An outside air temperature identifying step for identifying an outside air temperature in a set time period in the future based on the information obtained in the obtaining step;
A calculation step for calculating the cost required for the operation of the heating device in the set time period based on the outside air temperature specified in the outside air temperature specifying step;
And a processing step of executing a predetermined process related to the operation of the heating device in the set time period using the cost calculated in the calculation step.

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