JP6053440B2 - Temperature adjustment system, temperature adjustment method, system controller, and program - Google Patents

Description

  The present invention relates to a technique for adjusting the air temperature in a residence.

  In general, even in the same residence, air temperature varies depending on the location, such as bedrooms, corridors, living rooms, kitchens, toilets, dressing rooms, bathrooms, toilets, etc. Especially in summer or winter, air conditioning equipment etc. This tendency is noticeable in the season in which the temperature is adjusted using.

  When moving between places with a significant temperature difference in a house (for example, from a bedroom to a toilet, from a bedroom to a bathroom) , Heat shock) is known.

  For example, Patent Document 1 proposes a system aimed at suppressing the occurrence of such a heat shock. In this system, when the temperature difference between the bedroom and the hallway is larger than a threshold value (for example, 6 ° C.) during the nighttime period, the air conditioner provided in each of the hallway and the toilet performs cooling or heating operation, and the hallway And make the temperature of the toilet close to the temperature of the bedroom.

JP 2011-69539 A

  By operating an air conditioner installed in a corridor or toilet as in the system proposed in Patent Document 1, it becomes possible to reliably bring the temperature of the corridor or toilet close to the temperature of the bedroom. However, since a plurality of air conditioners are operated, power consumption increases, and it cannot be denied that there are disadvantages from the viewpoint of energy saving.

  The present invention has been made in view of the above circumstances, and a temperature adjustment system and a temperature adjustment that keep the difference in air temperature between predetermined locations in a residence within an allowable range while suppressing an increase in power consumption. It is an object to provide a method, a system controller, and a program.

In order to achieve the above object, a temperature control system according to the present invention includes:
A temperature adjustment system including a first temperature measurement unit, a second temperature measurement unit, an air supply unit, an exhaust unit, a system controller, and a portable terminal,
The first temperature measurement means measures the air temperature at the first location in the building, and outputs first temperature data including the measured air temperature to the system controller,
The second temperature measuring means measures an air temperature at a second location in the building, and outputs second temperature data including the measured air temperature to the system controller,
The air supply means supplies air in the first place into a duct disposed in the building,
The exhaust means exhausts air sent from the first place through the duct to the second place,
The system controller is
Communication means for communicating with the portable terminal;
Temperature data acquisition means for acquiring the first temperature data and the second temperature data respectively output from the first temperature measurement means and the second temperature measurement means;
An air supply control means for controlling the operation of the air supply means;
Exhaust control means for controlling the operation of the exhaust means;
Learning means for generating the user by learning from the user's life pattern the scheduled movement time zone information relating to the time zone in which the user is scheduled to move from the first location to the second location;
Time zone information storage means for storing the scheduled movement time zone information generated by the learning means;
The first temperature data when a predetermined time before the start time of the time zone indicated by the scheduled time zone information stored in the time zone information storage means and when the user requests temperature adjustment from the portable terminal And adjustment necessity determination means for determining whether or not adjustment of the air temperature between the first location and the second location is based on the second temperature data,
When it is determined by the adjustment necessity determination means that the air temperature needs to be adjusted, the air supply control means immediately causes the air supply means to perform an air supply operation, and the exhaust control means to perform the exhaust operation means.

  According to the present invention, it is possible to keep the difference in air temperature between predetermined locations in a building within an allowable range while suppressing an increase in power consumption.

It is a figure which shows the whole structure of the temperature control system which concerns on embodiment of this invention. It is a figure for demonstrating the duct in this embodiment, the air supply fan by the bedroom side, the exhaust fan by the corridor side, and the exhaust fan by the toilet side. It is a block diagram which shows the structure of the system controller of this embodiment. It is a block diagram which shows the functional structure of the control part with which the system controller of this embodiment is provided. It is a flowchart which shows the procedure of the temperature adjustment process of this embodiment.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a diagram showing an overall configuration of a temperature adjustment system 1 according to an embodiment of the present invention. This temperature adjustment system 1 is introduced into a residence in a general household so that the difference in air temperature between predetermined locations in the residence (in this embodiment, between the bedroom and the corridor and between the bedroom and the toilet) is within an allowable range. It is a system to do. As shown in the figure, the temperature adjustment system 1 includes a system controller 10, temperature sensors 11, 13, 15, an air supply fan 12, and exhaust fans 14, 16. These are connected to a home network 17 constructed in the house so that they can communicate with each other by wire or wirelessly. The home network 17 is, for example, a network conforming to ECHONET.

  Although details will be described later, the system controller 10 monitors the difference in air temperature between the bedroom and the corridor and between the bedroom and the toilet from the measurement results of the temperature sensors 11, 13, and 15. When the threshold value is exceeded, the air supply fan 12, the exhaust fan 14, and / or the exhaust fan 16 are controlled so that the difference in air temperature between the locations is reduced.

  The temperature sensor 11 (first temperature measuring means) is installed on a wall or ceiling of a bedroom, measures the air temperature in the bedroom, and stores data (temperature data) storing the measured results at a predetermined timing. 17 to the system controller 10. The temperature sensor 13 (second temperature measuring means) is installed on the wall or ceiling of the hallway, measures the air temperature in the hallway (the space above), and stores temperature data storing the measured results at a predetermined timing. The data is transmitted to the system controller 10 via the home network 17. The temperature sensor 15 (second temperature measuring means) is installed on the wall or ceiling of the toilet, measures the air temperature in the toilet, and stores temperature data storing the measured result via the home network 17 at a predetermined timing. To the system controller 10.

  As shown in FIG. 2, the air supply fan 12 (air supply means) is provided in the vicinity of the air supply port 18 a of the duct 18 disposed on the ceiling or the like of the residence. The air supply fan 12 is an electric fan for taking in the air in the bedroom from an air supply port 18 a provided on the ceiling of the bedroom, and the number of rotations (rotation speed) is the control data from the system controller 10. Adjusted according to.

  The exhaust fan 14 (exhaust means) is provided in the duct 18 in the vicinity of the exhaust port 18b provided in the ceiling of the hallway, and the exhaust fan 16 (exhaust means) is provided in the ceiling of the toilet. It is provided in the vicinity of the exhaust port 18c. The exhaust fans 14 and 16 are electric fans for exhausting air sent from the bedroom via the duct 18, and the number of rotations (rotation speed) is adjusted according to control data from the system controller 10. Is done.

  The system controller 10 is installed at a predetermined location in a residence, and includes a communication unit 100, a display unit 101, an input unit 102, a data storage unit 103, and a control unit 104, as shown in FIG. .

  The communication unit 100 includes, for example, a communication interface such as a LAN card, and is connected to the home network 17 so as to be capable of wired or wireless communication. Under the control of the control unit 104, the temperature sensors 11, 13, 15, Data communication is performed with the air supply fan 12 and the exhaust fans 14 and 16 via the home network 17.

  The display unit 101 is configured by a liquid crystal display or the like, and displays a screen showing the temperature of each place and various screens for user operation under the control of the control unit 104. The input unit 102 includes a touch panel, a touch pad, and the like, and performs processing for receiving an operation input from a user.

  The data storage unit 103 plays a role as a so-called secondary storage device (auxiliary storage device), and includes, for example, a readable / writable nonvolatile semiconductor memory or the like such as a flash memory. The data storage unit 103 stores data and programs for controlling the temperature sensors 11, 13, 15, the supply fan 12, and the exhaust fans 14, 16.

  The control unit 104 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like, and controls the entire system controller 10. As shown in FIG. 4, the control unit 104 functionally includes a temperature data acquisition unit 1040, an adjustment necessity determination unit 1041, an air supply fan control unit 1042, and an exhaust fan control unit 1043. Prepare. The functions of these components are realized by a CPU or the like executing a predetermined program (temperature adjustment program) stored in the data storage unit 103.

  The temperature data acquisition unit 1040 acquires temperature data from the temperature sensors 11, 13, and 15 at a predetermined timing. In the present embodiment, the temperature data acquisition unit 1040 requests the temperature sensors 11, 13, and 15 to transmit temperature data 10 minutes before the start of the toilet time zone set by the user in advance. In response to this, when temperature data is transmitted from each of the temperature sensors 11, 13, and 15 and received by the communication unit 100, the temperature data acquisition unit 1040 receives the temperature data from the received temperature sensors 11, 13, and 15. Each temperature data is supplied to the adjustment necessity determination unit 1041.

  Here, the above-mentioned toilet time zone is a time zone in which the user (the resident of this residence) is likely to go to the toilet at night, and such information (scheduled time zone information) is input by the user in advance. It is assumed that it is set via the unit 102 and stored in the data storage unit 103.

  Based on the temperature data from the temperature sensors 11, 13, and 15, the adjustment necessity determination unit 1041 determines whether it is necessary to adjust the temperature between the bedroom and the hallway and / or between the bedroom and the toilet. More specifically, the adjustment necessity determination unit 1041 determines the temperature indicated by the temperature data from the temperature sensor 11 (ie, the air temperature in the bedroom) and the temperature indicated by the temperature data from the temperature sensor 13 (ie, the air temperature in the hallway). The temperature difference between the bedroom and the hallway is determined to be necessary when the obtained temperature difference exceeds a preset threshold value (for example, 5 ° C.).

  Further, the adjustment necessity determination unit 1041 is a temperature between the temperature indicated by the temperature data from the temperature sensor 11 (air temperature in the bedroom) and the temperature indicated by the temperature data from the temperature sensor 15 (that is, the air temperature in the toilet). A difference is obtained, and when the obtained temperature difference exceeds the above threshold, it is determined that temperature adjustment between the bedroom and the toilet is necessary.

  The supply air fan control unit 1042 generates control data for rotating the supply air fan 12 when the adjustment necessity determination unit 1041 determines that the temperature adjustment is necessary, and communicates the generated control data. This is transmitted to the air supply fan 12 via the unit 100. At this time, the air supply fan control unit 1042 adjusts the rotation speed of the air supply fan 12 using the temperature difference between the locations, the air temperature at each location, and the like as parameters.

  The exhaust fan control unit 1043 generates control data for rotating the exhaust fan 14 when the adjustment necessity determination unit 1041 determines that the temperature adjustment between the bedroom and the hallway is necessary. Control data is transmitted to the exhaust fan 14 via the communication unit 100. At this time, the exhaust fan control unit 1043 adjusts the rotational speed of the exhaust fan 14 using the temperature difference between the bedroom and the hallway, the air temperature of each of these as parameters, and the like.

  The exhaust fan control unit 1043 generates control data for rotating the exhaust fan 16 when the adjustment necessity determination unit 1041 determines that temperature adjustment between the bedroom and the toilet is necessary. The generated control data is transmitted to the exhaust fan 16 via the communication unit 100. At this time, the exhaust fan control unit 1043 adjusts the rotational speed of the exhaust fan 16 using the temperature difference between the bedroom and the toilet, the air temperature of each of these as parameters, and the like.

  FIG. 5 is a flowchart showing the procedure of the temperature adjustment process executed by the control unit 104 of the system controller 10 configured as described above. This temperature adjustment process is executed every predetermined time (10 minutes in the present embodiment) at night (for example, from 8:00 pm to 6:00 am on the next day).

  First, the temperature data acquisition unit 1040 acquires the current time (step S101). For example, the temperature data acquisition unit 1040 acquires the current time from a clock function unit (not shown) included in the system controller 10.

  The temperature data acquisition unit 1040 reads information indicating the toilet time zone described above from the data storage unit 103 (step S102). In the present embodiment, for example, information on two time zones from 10 to 11 pm and from 2 to 3 am is set in advance as information indicating the toilet time zone and stored in the data storage unit 103 by the user, for example. It is assumed that Hereinafter, the previous toilet time zone is referred to as the first toilet time zone, and the later toilet time zone is referred to as the second toilet time zone.

  The temperature data acquisition unit 1040 determines whether or not the acquired current time corresponds to about 10 minutes before the start time of any of the read first and second toilet time zones (step S103). . For example, when the current time is in the range of 9:47 pm to 10:53 pm, the temperature data acquisition unit 1040 corresponds to about 10 minutes before the start time of the first toilet time zone. judge. Further, when the current time is in the range of 1:47 am to 1:53, the temperature data acquisition unit 1040 corresponds to about 10 minutes before the start time of the second toilet time zone. judge.

  As a result of the above determination, when the acquired current time does not correspond to about 10 minutes before the start time of any of the read first and second toilet time zones (step S103; NO), this process ends. To do.

  On the other hand, when the acquired current time corresponds to about 10 minutes before the start time of any one of the read first and second toilet time zones (step S103; YES), the temperature data acquisition unit 1040 Data requesting transmission of measurement results (transmission request data) is transmitted to the temperature sensors 11, 13, and 15 via the communication unit 100 (step S104). Each of the temperature sensors 11, 13 and 15 receives the transmission request data and transmits temperature data storing the measurement result to the system controller 10.

  When the temperature data transmitted from each of the temperature sensors 11, 13, and 15 is received by the communication unit 100 (step S <b> 105; YES), the adjustment necessity determination unit 1041 performs the temperature sensor 11, Based on the temperature data from 13, 15, it is determined whether it is necessary to adjust the temperature between at least one of the bedroom and the corridor or between the bedroom and the toilet (step S106).

  In the summer and winter seasons when consumers feel hot or cold at outside temperatures, it can often be said that in the bedroom at night, air conditioning equipment is operated with emphasis on comfort. On the other hand, in corridors and toilets, it is not often the case that air conditioning is used to maintain the space temperature at an appropriate temperature. As a result, in the season such as summer and winter, there may occur a situation in which the difference between the air temperature in the bedroom and the air temperature in the corridor or toilet greatly widens. In the situation where the above temperature adjustment is required, air conditioning is performed in the bedroom, while air conditioning is not performed in the corridor or toilet. The case where the difference in the air temperature in the interior has widened greatly applies.

  As a result of the above determination, if temperature adjustment is not required between the bedroom and the corridor or between the bedroom and the toilet (step S106; NO), this process ends.

  On the other hand, as a result of the above determination, if temperature adjustment is required between the bedroom and the corridor or between the bedroom and the toilet (step S106; YES), the air supply fan control unit 1042 turns the air supply fan 12 on. Control data for rotation is generated, and the generated control data is transmitted to the air supply fan 12 via the communication unit 100 (step S107). When such control data is received, the air supply fan 12 starts to rotate, whereby air in the bedroom (here, air that is air-conditioned at an appropriate temperature) is taken into the duct 18 from the air supply port 18a. (Inflow).

  The air supply fan control unit 1042 sends control data for stopping the rotation of the air supply fan 12 to the air supply fan 12 when a predetermined time (for example, 1 hour) elapses after the transmission of the control data. Send. Thereby, the rotation of the air supply fan 12 is stopped.

  If the temperature adjustment is required between the bedroom and the hallway as a result of the determination by the adjustment necessity determination unit 1041 (step S108; YES), the exhaust fan control unit 1043 rotates the exhaust fan 14. Control data is generated, and the generated control data is transmitted to the exhaust fan 14 via the communication unit 100 (step S109). When such control data is received, the exhaust fan 14 starts to rotate, whereby the air sent from the bedroom via the duct 18 is exhausted from the exhaust port 18b.

  After that, when the control data for stopping the rotation of the air supply fan 12 is transmitted by the air supply fan control unit 1042, the exhaust fan control unit 1043 synchronizes with this and the exhaust fan control unit 1043 Control data for stopping the rotation of the engine 14 is transmitted to the exhaust fan 14. As a result, the rotation of the exhaust fan 14 stops.

  In addition, as a result of the determination by the adjustment necessity determination unit 1041 described above, when the temperature adjustment is necessary between the bedroom and the toilet (step S110; YES), the exhaust fan control unit 1043 rotates the exhaust fan 16. Control data is generated, and the generated control data is transmitted to the exhaust fan 16 via the communication unit 100 (step S111). When such control data is received, the exhaust fan 16 starts to rotate, whereby the air sent from the bedroom through the duct 18 is exhausted from the exhaust port 18c.

  After that, when the control data for stopping the rotation of the air supply fan 12 is transmitted by the air supply fan control unit 1042, the exhaust fan control unit 1043 synchronizes with this and the exhaust fan control unit 1043 Control data for stopping the rotation of 16 is transmitted to the exhaust fan 16. As a result, the rotation of the exhaust fan 16 stops.

  As described above, according to the temperature control system 1 of the present embodiment, before the start of the time zone (toilet time zone) in which the user is expected to go to the toilet at night, the bedroom and the corridor and the bedroom and the toilet If the air temperature difference between at least one of the locations exceeds a preset threshold, the air temperature in the bedroom is used to reduce the air temperature difference between the locations. Adjust the temperature to (narrow). Specifically, when the difference in air temperature between the bedroom and the hallway exceeds a threshold value, the bedroom air is sent to the hallway side through the duct 18. When the difference in air temperature between the bedroom and the toilet exceeds the threshold value, the bedroom air is sent into the toilet through the duct 18.

  Thereby, in the hallway and the toilet, the air temperature difference between the bedroom and the hallway and between the bedroom and the toilet can be within an allowable range without operating the air conditioner. As a result, it is possible to effectively suppress the occurrence of a so-called heat shock caused by a rapid temperature change during movement between different places in the residence while suppressing an increase in power consumption.

  In addition, this invention is not limited to the said embodiment, Of course, the various change in the range which does not deviate from the summary of this invention is possible.

  For example, the system controller 10 performs data communication among the temperature sensors 11, 13, 15, the air supply fan 12, and the ventilation fans 14, 16 via the home network 17. The temperature sensor 11, 13, 15, the air supply fan 12, and the ventilation fans 14, 16 may be connected to each other via a separate dedicated communication line so that data communication is possible.

  In the above embodiment, temperature data is sent from the temperature sensors 11, 13, and 15 in response to a request from the system controller 10, but is sent spontaneously from the temperature sensors 11, 13, and 15. You may do it. In this case, the temperature sensors 11, 13, and 15 transmit temperature data to the system controller 10 at intervals of 1 minute, for example, and the system controller 10 is executed every predetermined time (for example, every 10 minutes). In the temperature adjustment process described above (see FIG. 5), the temperature data sent first from the temperature sensors 11, 13, and 15 may be used to obtain the difference in air temperature between the locations.

  Further, in the above embodiment, the supply air fan control unit 1042 stops the rotation of the supply air fan 12 after a predetermined time (for example, 1 hour) has elapsed since the rotation control of the supply air fan 12 was started. However, the timing for stopping the rotation of the air supply fan 12 is an arbitrary design matter. For example, you may stop according to the end time of the 1st or 2nd toilet time slot | zone, and you may stop when the difference of the air temperature between the said locations becomes smaller than the preset threshold value.

  Moreover, the place where the air-conditioned air from the bedroom can be sent is not limited to the hallway or the toilet. For example, air conditioned air can be sent to various places such as a dressing room and a bathroom. Also in this case, as in a corridor or toilet, an exhaust port connected to the duct 18 is provided on the ceiling of each place, and an exhaust fan is installed near each exhaust port so that the system controller 10 can control. That's fine. Then, a temperature sensor may be installed at each location, and the measurement result of each temperature sensor may be configured to be notified to the system controller 10 by data communication. Then, similarly to the toilet time zone, for example, the user presets a time zone scheduled to go to the place, such as a bathing time zone, and information about the time zone (scheduled time zone information) is stored in the data storage unit 103. You should keep it.

  Further, the location of the air-conditioned air source is not limited to the bedroom, but may be, for example, a living room, or may be configured such that a plurality of locations can be the source. Also in this case, as in the bedroom, an air supply port connected to the duct 18 is provided on the ceiling or the like of each place, and an air supply fan is installed near each air supply port so that the system controller 10 can control it. do it. Then, a temperature sensor may be installed at each location, and the measurement result of each temperature sensor may be configured to be notified to the system controller 10 by data communication.

  In addition, when there are a plurality of places where air-conditioned air can be sent, the place of the sending source may be selected according to the time zone. For example, the living room may be selected as the source location in the time zone from 18:00 to 22:00, and the bedroom may be selected as the source location in the time zone from 22:00 to 6 o'clock the next day. Alternatively, the system controller 10 is configured such that the air conditioner currently performing the air conditioning operation is configured such that the air conditioner installed in each of the places that can be the source and the system controller 10 are connected so as to be able to perform data communication. The installed location may be selected as the location of the air source.

  Further, for example, the system controller 10 is configured to be remotely operated using a portable terminal such as a tablet terminal, and the user is forced to execute the temperature adjustment process from the portable terminal. May be. In this way, it is possible to cope with the case where it is desired to go to the toilet at a time away from the preset toilet time zone, so that convenience is improved.

  In addition, the system controller 10 may learn the toilet time zone, bathing time zone, and the like from the user's life pattern and set the toilet time zone and the like instead of an input operation by the user. For example, regarding the use of a toilet, a system is used to determine whether or not the toilet is used by installing a shock sensor outside the water supply pipe of the flush toilet and notifying the system controller 10 of the measurement result of the shock sensor via data communication. The controller 10 may be able to determine. Alternatively, the system controller 10 may be configured to determine whether the toilet door is opened or closed, or whether the toilet lighting is on or off. The system controller 10 collects the toilet use results (for example, toilet use start time) that can be obtained in this way for a predetermined period, and performs predetermined statistical processing on the collected history of use results. The normal toilet time zone of the dweller of the residence can be derived.

  For example, for bathing, a flow rate sensor that detects the amount of hot water supplied from the hot water storage tank unit to the bathtub is installed at a predetermined location of the hot water storage tank unit, and the measurement result of the flow rate sensor can be notified to the system controller 10 by data communication. It may be configured so that the system controller 10 can determine the presence or absence of bathing. Alternatively, the system controller 10 may be configured to determine whether the bathroom door is opened and closed, bathroom lighting ON / OFF, and the like. The system controller 10 collects bathing results (for example, bathing start time) that can be acquired in this way for a predetermined period, and applies predetermined statistical processing to the collected history of use results, thereby providing It is possible to derive a normal bathing time zone for a consumer.

  As described above, by deriving the toilet time zone and the like from the user's life pattern, the accuracy of temperature adjustment is improved, and as a result, it is possible to further suppress an increase in power consumption for temperature adjustment. .

  Further, the system controller 10 of the above embodiment may be integrated into a HEMS (Home Energy Management System). In this case, the HEMS controller may be configured to absorb the function of the system controller 10.

  In the above embodiment, the program executed by the system controller 10 is applied to an existing personal computer (PC), portable terminal, or the like, thereby causing the PC, portable terminal, or the like to function as the system controller according to the present invention. Is also possible.

  Such a program distribution method is arbitrary, for example, a computer-readable recording medium such as a CD-ROM (Compact Disk Read-Only Memory), a DVD (Digital Versatile Disk), an MO (Magneto Optical Disk), or a memory card. It may be stored and distributed in a network, or distributed via a communication network such as the Internet.

  DESCRIPTION OF SYMBOLS 1 Temperature control system, 10 System controller, 11, 13, 15 Temperature sensor, 12 Air supply fan, 14, 16 Exhaust fan, 17 Home network, 18 Duct, 18a Air supply port, 18b, 18c Exhaust port, 100 Communication Unit, 101 display unit, 102 input unit, 103 data storage unit, 104 control unit, 1040 temperature data acquisition unit, 1041 adjustment necessity determination unit, 1042 supply fan control unit, 1043 exhaust fan control unit

Claims (7)

A temperature adjustment system including a first temperature measurement unit, a second temperature measurement unit, an air supply unit, an exhaust unit, a system controller, and a portable terminal,
The first temperature measurement means measures the air temperature at the first location in the building, and outputs first temperature data including the measured air temperature to the system controller,
The second temperature measuring means measures an air temperature at a second location in the building, and outputs second temperature data including the measured air temperature to the system controller,
The air supply means supplies air in the first place into a duct disposed in the building,
The exhaust means exhausts air sent from the first place through the duct to the second place,
The system controller is
Communication means for communicating with the portable terminal;
Temperature data acquisition means for acquiring the first temperature data and the second temperature data respectively output from the first temperature measurement means and the second temperature measurement means;
An air supply control means for controlling the operation of the air supply means;
Exhaust control means for controlling the operation of the exhaust means;
Learning means for generating the user by learning from the user's life pattern the scheduled movement time zone information relating to the time zone in which the user is scheduled to move from the first location to the second location;
Time zone information storage means for storing the scheduled movement time zone information generated by the learning means;
The first temperature data when a predetermined time before the start time of the time zone indicated by the scheduled time zone information stored in the time zone information storage means and when the user requests temperature adjustment from the portable terminal And adjustment necessity determination means for determining whether or not adjustment of the air temperature between the first location and the second location is based on the second temperature data,
When it is determined by the adjustment necessity determination means that the air temperature needs to be adjusted, the air supply control means immediately causes the air supply means to perform an air supply operation, and the exhaust control means A temperature control system that allows the means to perform exhaust operation. The time zone in the scheduled travel time zone information is a time zone where the user is likely to go to the toilet,
The learning means determines whether or not the toilet is used based on at least one of information on whether or not water is used in the toilet, whether the toilet door is opened and closed, and whether or not the toilet is turned on / off. The temperature adjustment system according to claim 1, wherein the scheduled movement time zone information is generated from a use result of the toilet in a predetermined period. The time zone in the scheduled movement time zone information is a time zone where the user is likely to bathe,
The learning means determines whether or not the user has bathed based on at least one of the amount of hot water supplied to the bathtub, the opening / closing of a bathroom door, and the lighting of the bathroom. The temperature adjustment system according to claim 1, wherein the scheduled movement time zone information is generated from a bathing result in a predetermined period.   The adjustment necessity determination unit calculates a temperature difference between an air temperature indicated by the first temperature data and an air temperature indicated by the second temperature data, and the calculated temperature difference exceeds a predetermined threshold value. The temperature adjustment system according to any one of claims 1 to 3, wherein in this case, it is determined that adjustment of an air temperature between the first location and the second location is necessary. Learning from the user's life pattern information about a scheduled movement time zone regarding a time zone in which the user is scheduled to move from a first location in the building to a second location in the building;
Measuring the air temperature at the first location, measuring the air temperature at the second location,
The air temperature at the first location and the air temperature at the second location when the user requests temperature adjustment a predetermined time before the start time of the time zone indicated by the scheduled travel time zone information and from the mobile terminal And determining whether or not the air temperature needs to be adjusted between the first location and the second location ,
If it is determined that it is necessary to adjust the previous SL air temperature, immediately the air supply means, to perform an operation to supply the air in the first place in a duct disposed within the building, the exhaust A temperature adjustment method for causing a means to perform an operation of exhausting air sent from the first place to the second place through the duct. A communication means for communicating with the mobile terminal;
Air temperature acquisition means for acquiring a first air temperature measured at a first location in a building and a second air temperature measured at a second location in the building;
An air supply control means for controlling an operation of an air supply means for supplying air in the first place into a duct disposed in the building;
Exhaust control means for controlling the operation of the exhaust means for exhausting the air sent from the first place through the duct to the second place;
Learning means for generating the user by learning from the user's life pattern the scheduled movement time zone information relating to the time zone in which the user is scheduled to move from the first location to the second location;
Time zone information storage means for storing the scheduled movement time zone information generated by the learning means;
The first air temperature when a predetermined time before the start time of the time zone indicated by the scheduled time zone information stored in the time zone information storage means and when the user requests temperature adjustment from the portable terminal And adjustment necessity determination means for determining whether or not adjustment of the air temperature between the first location and the second location is based on the second air temperature,
When it is determined by the adjustment necessity determination means that the air temperature needs to be adjusted, the air supply control means immediately causes the air supply means to perform an air supply operation, and the exhaust control means A system controller that causes the means to perform an exhaust operation. A computer comprising a communication means for communicating with a portable terminal;
Air temperature acquisition means for acquiring a first air temperature measured at a first location in a building and a second air temperature measured at a second location in the building;
An air supply control means for controlling an operation of an air supply means for supplying air in the first place into a duct disposed in the building;
An exhaust control means for controlling the operation of the exhaust means for exhausting the air sent from the first place through the duct to the second place;
Learning means for generating a scheduled movement time zone information related to a time zone in which the user is scheduled to move from the first location to the second location by learning from the user's life pattern;
The first air temperature and the second air temperature when a predetermined time before the start time of the time zone indicated by the scheduled movement time zone information generated by the learning means and when the user requests temperature adjustment from the portable terminal On the basis of the air temperature, and function as adjustment necessity determination means for determining whether or not the adjustment of the air temperature between the first location and the second location,
When it is determined by the adjustment necessity determination means that the air temperature needs to be adjusted, the air supply control means immediately causes the air supply means to perform an air supply operation, and the exhaust control means A program that causes a means to perform an exhaust operation.

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