JP2015117933A - Air-conditioning system and building - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air-conditioning system which can perform efficient automatic control of underfloor air-conditioning and above-floor air-conditioning.SOLUTION: In a building 1 with an indoor space thereof divided into an above-floor space 6 and an underfloor space 3 by a floor section 1a, an air-conditioning system can perform: above-floor air-conditioning by blowing air-conditioning air into the above-floor space 6 through above-floor blow-out sections 52 and 52 of an indoor unit 5 of an air-conditioner installed in the building 1 as an air-conditioning device capable of heating operation; and underfloor air-conditioning by blowing the air-conditioning air into the underfloor space 3 through an underfloor blow-out section 53 of the indoor unit 5 of the air-conditioner. A control device S of the air-conditioning system has a control section 54 which controls: an operation condition of the above-floor air-conditioning according to a result of detecting whether or not a human is present in the above-floor space 6 using a human detection sensor 12 installed therein; and the operation condition of the underfloor air-conditioning on the basis of operation time schedule data stored in a storage section 55.

Description

  The present invention relates to an air conditioning system capable of underfloor air conditioning and above floor air conditioning, and a building including the air conditioning system.

  Conventionally, many control devices that automatically and efficiently control an air conditioning system in a building using a human sensor or the like have been proposed (see, for example, Patent Document 1).

  Further, in Patent Document 2, an air conditioner is installed in an underfloor space of a building, and an on-floor air conditioner that blows air-conditioned air from the air-conditioner to the above-floor space and an underfloor air conditioner that blows conditioned air from the air-conditioner to the under-floor space are possible. There is disclosed an air conditioning system capable of performing comfortable air conditioning of a floor space.

JP 2013-36678 A Japanese Patent No. 4595021

  However, in the air conditioning system capable of underfloor air conditioning and underfloor air conditioning as described above in Patent Document 2, a resident or the like still operates the controller manually to set a comfortable state, or time schedule data stored in advance It was only possible to control based on.

  Therefore, an object of the present invention is to provide an air conditioning system capable of automatically and efficiently controlling underfloor air conditioning and above floor air conditioning, and a building including the air conditioning system.

  In order to achieve the above object, the air conditioning system of the present invention is configured such that the interior of a building is partitioned into an upper floor space and an under floor space at the floor, and conditioned air is blown out from the air conditioner installed in the building to the above floor space. An air conditioning system capable of underfloor air conditioning and underfloor air conditioning that blows conditioned air from the air conditioner to the underfloor space, wherein the air conditioner is capable of at least heating operation, and a control unit is provided in the underfloor space. The installed human sensor is in the case where the detection result shows that the absence of a person continues for a predetermined time or more, and the driving condition is set to the economic priority mode, and the situation where the person is present continues for a predetermined time or more. The control unit controls the driving condition to be the comfort priority mode, and the control unit controls the underfloor air conditioning based on the driving time schedule data stored in the storage unit. And controlling switching between sexual priority mode.

  Here, the upper limit temperature is a temperature that is controlled to be lower than the temperature in the mode, and the lower limit temperature is a temperature that is controlled to be higher than the temperature in the mode. .

  The relationship between the lower limit temperature of the economy priority mode and the lower limit temperature of the comfort priority mode during heating and the relationship between the upper limit temperature of the economy priority mode and the upper limit temperature of the comfort priority mode during cooling are the same time. Therefore, the lower limit temperature of the economy priority mode during heating is lower than the lower limit temperature of the comfort priority mode, and the upper limit temperature of the economy priority mode during cooling is higher than the upper limit temperature of the comfort priority mode.

  That is, the lower temperature limit of the economy priority mode during heating is higher than the lower limit temperature of the comfort priority mode compared to different times, and the upper limit temperature of the economy priority mode during cooling is the upper limit temperature of the comfort priority mode. Lower ones are also included.

  Further, the control of the floor air conditioning and the floor air conditioning by the control unit is control by standard specification setting, and it is preferable that the standard specification setting can be turned on / off, adjusted, or changed by the controller.

  Furthermore, in the above-floor space and the under-floor space of the building, temperature sensors that send temperature data in these spaces to the control unit are provided, respectively, and based on these temperature data, the control unit The above-described air conditioning on the floor and the air conditioning on the floor may be controlled.

  The storage unit may have a learning function.

  Furthermore, the air conditioner may be installed in the underfloor space.

  The building of the present invention includes the above-described air conditioning system of the present invention.

  Such an air conditioning system according to the present invention includes an air conditioner on the floor and an air conditioner that divides the interior of the building into an above floor space and an under floor space at the floor, and blows conditioned air from the air conditioner installed in the building to the above floor space. This is an air conditioning system capable of underfloor air conditioning that blows conditioned air into the underfloor space.

  The air conditioner can at least perform a heating operation, and the control unit can operate the human sensor provided in the space above the floor when the detection result indicates that a person is absent for a predetermined time or longer. When the condition is set to the economy priority mode and the situation where the person is present continues for a predetermined time or longer, the driving condition is controlled to the comfort priority mode, and the control unit stores the underfloor air conditioning in the storage unit. Based on the driving time schedule data, the economy priority mode and the comfort priority mode are switched and controlled.

  With the above-described configuration, floor-based air conditioning distinguishes between the presence and absence of people in the floor space and performs operation without waste, so it automatically and efficiently controls an air-conditioning system that can perform under-floor air conditioning and above-floor air conditioning. be able to.

  In addition, especially during heating operation, underfloor air conditioning heats the floor space almost uniformly and evenly, but lacks immediate effectiveness compared to underfloor air conditioning heating. Although it warms up instantly, the space above the floor cannot be heated evenly compared to heating by under-floor air conditioning, so it can take advantage of the advantages of under-floor air conditioning and under-floor air conditioning and perform efficient control that compensates for the shortcomings. .

  In addition, in the air conditioning on the floor, the operating condition is set to the economic priority mode when the presence of the person is absent for a predetermined time or more as a result of detection by the human sensor, so there is no person in the space on the floor for a long time. It is possible to reduce unnecessary air conditioning even if it is in a state.

  In addition, in the air conditioning on the floor, the operating condition is set to the comfort priority mode when the presence of the person continues for a predetermined time or more as a result of detection by the human sensor, so as much as possible when there is a person in the floor space. Comfortable air conditioning can be performed.

  In addition, when the control unit controls the operating conditions based on the operation time schedule data stored in the storage unit during the predetermined time period, this control is performed especially in the midnight time period when the electricity rate is low. If done, it is economical and, in addition, the comfort during and before and after sleeping can be increased, and especially during heating operation, it also prevents heat shock due to temperature differences between rooms.

  In addition, the control of the floor air conditioning and the floor air conditioning by the control unit is based on the standard specification setting, and if the standard specification setting can be turned on / off, adjusted or changed by the controller, the intention of the occupants of the building, etc. Can be easily interrupted to control by standard specification setting.

  Furthermore, temperature sensors that send temperature data in these spaces to the control unit are provided in the above-floor space and under-floor space of the building, respectively. Based on these temperature data, the control unit performs on-floor air conditioning and under-floor space. When the air conditioning is controlled, the control is based on the temperature data, so that efficient control can be performed with a simple configuration.

  In addition, when the storage unit has a learning function, it is possible to reflect a suitable temperature environment in time series according to the preference of the resident or the action pattern or the like in the control based on the standard specification setting.

  Furthermore, when the air conditioner is installed in the underfloor space, the temperature environment is stable throughout the year, and the underfloor space, which is usually a dead space, can be effectively used.

  Such a building of the present invention is configured to include the above-described air conditioning system of the present invention.

  Since it is an above-mentioned composition, it can be considered as a building which has an effect of an above-mentioned air-conditioning system of the present invention.

It is explanatory drawing which shows schematic structure of the building provided with the air conditioning system of the Example. It is a block diagram which shows schematic structure of the control apparatus of the air conditioning system of an Example. It is a time table which shows the specific example of the standard specification setting by the control apparatus of the air conditioning system of an Example.

  DESCRIPTION OF EMBODIMENTS Hereinafter, modes for carrying out the present invention will be described based on examples shown in the drawings.

  First, the configuration of the embodiment will be described.

  Drawing 1 shows the schematic structure of building 1 provided with the air-conditioning system of an example.

  The building 1 includes a foundation bottom concrete 1b constructed as a heat insulating foundation, a foundation side wall concrete 1c erected on the side edge, an outer wall part 1d erected on the foundation side concrete, and an upper end of the outer wall part 1d. It is mainly comprised from the ceiling part 1e which plugs up opening.

  The space surrounded by the ceiling portion 1e and the outer wall portion 1d has a configuration in which a floor space 1 and a floor space 6 used for a living room or the like are separated by a floor portion 1a.

  Further, a heat insulating material 2 such as glass wool is attached to the underfloor space 3 side of the foundation side wall concrete 1c so that heat in the underfloor space 3 is prevented from leaking to the outside as much as possible.

  In the underfloor space 3, an indoor unit 5 of an air conditioner as a blow-out type air conditioner is installed.

  Here, the indoor unit 5 of this air conditioner is a heat pump type, and is connected to the outdoor unit 4 installed outside the building 1 by a heat medium circulation conduit.

  Further, the indoor unit 5 of this air conditioner has a dehumidifying function and is provided with a drain 7 for drainage that penetrates from the underfloor space 3 to the outdoors.

  Furthermore, the indoor unit 5 of this air conditioner has a suction part 51, floor blowing parts 52, 52, and a floor blowing part 53.

  The indoor unit 5 of the air conditioner includes a fan (not shown) capable of blowing air with various strengths from the blowout units 52 and 52 and the blowout unit 53 under the floor, and a control unit 54. And a storage unit 55 are incorporated.

  Furthermore, on-floor blowing parts 52, 52 and under-floor blowing part 53 are provided with on-off valves 52a, 53a made of an electric damper or the like, respectively.

  The indoor unit 5 of the air conditioner is provided with a temperature sensor 5a that sends the temperature data of the underfloor space 3 to the control unit 54 by wire or wirelessly.

  Further, the floor portion 1a is provided with an exhaust port 9 and two types of air supply ports 10, 10, 11 with a grill.

  Here, the air inlets 10 and 10 are respectively connected to the blowout part 52 on the floor of the indoor unit 5 of the air conditioner by the duct 82, and the other air inlet 11 is not connected to the underfloor space 3 via the duct. Communicate directly with.

  Further, the duct 81 also connects between the suction portion 51 of the indoor unit 5 of the air conditioner and the exhaust port 9.

  Furthermore, a human sensor 12 is provided in the floor space 6, and the human sensor 12 is connected to the control unit 54 in a wired or wireless manner.

  A remote controller 13 as a controller is also provided in the floor space 6.

  Further, the remote controller 13 incorporates a temperature sensor 13 a that sends temperature data of the floor space 6 to the control unit 54 by wire or wirelessly.

  Next, the control apparatus S of the air conditioning system of an Example is demonstrated.

  FIG. 2 shows a schematic configuration of the control device S of the air conditioning system of the embodiment.

  The control device S of the air conditioning system of this embodiment includes a control unit 54 and a storage unit 55 built in the indoor unit 5 of the air conditioner as a blow-out type air conditioning device, a human sensor 12, and a temperature sensor 13a. And a remote controller 13 as a controller.

  The storage unit 55 stores an automatic control setting that is a standard specification setting and a control pattern at the time of the automatic control setting.

  Here, at the time of this automatic control setting, basically, when the human sensor 12 detects that a person is present and the state continues for a predetermined time, the detection result is sent to the control unit 54 as a detection signal, The control unit 54 controls to blow out the conditioned air (warm air or cold air) from the blowout units 52 and 52 on the floor of the indoor unit 5 of the air conditioner, and the conditioned air is blown out from the air supply ports 10 and 10 to the floor space 6. Air conditioning on the floor is performed.

  This control is performed based on the temperature data in the floor space 6 detected by the temperature sensor 13a. The opening with the lower limit (or upper limit) temperature set in advance for each mode is calculated, and the operation is turned on / off and Strength is controlled.

  At the time of the automatic control setting, the control unit 54 controls the conditioned air (warm air) from the underfloor blowing unit 53 of the indoor unit 5 of the air conditioner based on the operation time schedule data stored in the storage unit 55 as a control pattern. (Or dehumidified air) is blown out, and conditioned air is blown into the underfloor space 3 to perform underfloor air conditioning.

  This control is performed based on the temperature data in the underfloor space 3 detected by the temperature sensor 5a. The opening with the lower limit (or upper limit) temperature set in advance for each mode is calculated, and the operation is turned on / off and Strength is controlled.

  Here, a part of the conditioned air blown into the underfloor space 3 is blown out from the air supply port 11 to the above-floor space 6.

  The standard setting can be turned on / off, adjusted, and changed by the remote controller 13. In particular, when there is an adjustment or change, the storage unit 55 stores it, and the storage unit 55 When the frequency is high, it has a learning function to be reflected in the standard specification setting.

  Next, the control by the control device S of the air conditioning system of the embodiment will be described more specifically.

  FIG. 3 is a time table showing a specific example (one day) of standard specification setting assuming winter heating by the control device S of the air conditioning system of the embodiment. In addition, the number in this time table has shown the minimum temperature of heating.

  First, in the air conditioning on the floor, from 6 o'clock to 23 o'clock, the human sensor 12 detects whether a person is present or absent, and is controlled to reflect this detection result.

  Here, if the presence sensor 12 is detected by the human sensor 12 and the state continues for a predetermined time (for example, 1 minute), the comfort priority mode is selected, and the lower limit temperature in the floor space 6 is 22 ° C. Driving is performed.

  That is, in order to maintain 22 ° C. or higher, the operation is turned off when the temperature sensor 13a detects a temperature of 22 ° C. or higher, and the operation is turned on when it is lower than 22 ° C.

  When the operation is turned on, the operation is weak when the temperature is slightly below 22 ° C., and the operation is strong when the temperature is greatly below.

  Further, when the presence sensor 12 detects that the person is absent and the state continues for a predetermined time (for example, 10 minutes), the economic priority mode is selected, and the lower limit temperature in the floor space 6 is set to 17 ° C. Driving is performed.

  That is, in order to keep 17 ° C. or higher, the operation is turned off when the temperature sensor 13a detects a temperature of 17 ° C. or higher, and the operation is turned on when it is lower than 17 ° C.

  When the operation is turned on, the operation is weak when it is slightly below 17 ° C., and the operation is strong when it is significantly below.

  Further, on-floor air conditioning is controlled from 23:00 to next 6 o'clock based on the operation time schedule data stored in the storage unit 55, and an operation is performed in which the lower limit temperature in the above-floor space 6 is 17 ° C.

  That is, in order to keep 17 ° C. or higher, the operation is turned off when the temperature sensor 13a detects a temperature of 17 ° C. or higher, and the operation is turned on when it is lower than 17 ° C.

  On the other hand, underfloor air conditioning is basically controlled based on operation time schedule data stored in the storage unit 55 throughout the day.

  First, from 6 o'clock to 10 o'clock, an operation in which the lower limit temperature in the underfloor space 3 is 25 ° C (operation in the comfort priority mode) is performed.

  That is, in order to maintain 25 ° C. or higher, the operation is turned off when the temperature sensor 5a detects a temperature of 25 ° C. or higher, and the operation is turned on when it is lower than 25 ° C.

  When the operation is turned on, the operation is weak when the temperature is slightly below 25 ° C., and the operation is strong when the temperature is greatly below.

  Further, from 10:00 to 12:00, an operation (operation in the economic priority mode) is performed in which the lower limit temperature in the underfloor space 3 is 20 ° C.

  That is, in order to keep 20 ° C. or higher, the operation is turned off when the temperature sensor 5a detects a temperature of 20 ° C. or higher, and the operation is turned on when the temperature sensor is lower than 20 ° C.

  When the operation is turned on, the operation is weak when the temperature is slightly below 20 ° C., and the operation is strong when the temperature is greatly below.

  Further, from 12 o'clock to 14 o'clock, as in the case from 6 o'clock to 10 o'clock, an operation is performed in which the lower limit temperature in the underfloor space 3 is 25 ° C (operation in the comfort priority mode).

  That is, in order to maintain 25 ° C. or higher, the operation is turned off when the temperature sensor 5a detects a temperature of 25 ° C. or higher, and the operation is turned on when it is lower than 25 ° C.

  When the operation is turned on, the operation is weak when the temperature is slightly below 25 ° C., and the operation is strong when the temperature is greatly below.

  Further, from 14:00 to 17:00, as in the case from 10:00 to 12:00, an operation (operation in the economic priority mode) is performed in which the lower limit temperature in the underfloor space 3 is 20 ° C.

  That is, in order to keep 20 ° C. or higher, the operation is turned off when the temperature sensor 5a detects a temperature of 20 ° C. or higher, and the operation is turned on when the temperature sensor is lower than 20 ° C.

  When the operation is turned on, the operation is weak when the temperature is slightly below 20 ° C., and the operation is strong when the temperature is greatly below.

  Further, from 17:00 to 23:00, as in the case from 12:00 to 14:00 and from 6:00 to 10:00, an operation is performed in which the lower limit temperature in the underfloor space 3 is 25 ° C. (operation in the comfort priority mode). .

  That is, in order to maintain 25 ° C. or higher, the operation is turned off when the temperature sensor 5a detects a temperature of 25 ° C. or higher, and the operation is turned on when it is lower than 25 ° C.

  When the operation is turned on, the operation is weak when the temperature is slightly below 25 ° C., and the operation is strong when the temperature is greatly below.

  In addition, from 23:00 to next 6 o'clock, an operation (operation in the comfort priority mode) in which the lower limit temperature in the underfloor space 3 is 28 ° C is performed.

  That is, in order to maintain 28 ° C. or higher, the operation is turned off when the temperature sensor 5a detects a temperature of 28 ° C. or higher, and the operation is turned on when it is lower than 28 ° C.

  When the operation is turned on, the operation is weak when the temperature is slightly below 28 ° C., and the operation is strong when the temperature is greatly below.

  Here, in the underfloor air conditioning from 23:00 to next 6 o'clock, the lower limit temperature is 3 ° C. higher than the operation in the other comfort priority mode. This is because the residual heat effect that plays the role of the tank is also aimed.

  Thereby, from 23:00 to the next 6 o'clock, the floor air conditioning is also controlled to set the lower limit temperature to 17 ° C. based on the operation time schedule data stored in the storage unit 55. , Driving can be turned off.

  In addition, this specific example is a thing when using the floor space 6 for a living room, a bedroom, etc., when it is assumed that there is no person, mainly when a person such as a resident suddenly returns. In order to prevent heat shock, the lower limit temperature in the space 6 on the floor is set to 17 ° C.

  Next, functions and effects of the embodiment will be described.

  The control device S of the air conditioning system of such an embodiment is an indoor unit of an air conditioner as an air conditioner installed in the building 1 in which the interior of the building 1 is partitioned into a floor space 6 and a floor space 3 by a floor portion 1a. The above-mentioned floor air-conditioning unit 52, 52 can blow off the air-conditioned air from the floor blowing unit 52 to the floor space 6, and the air-conditioner indoor unit 5 can blow the air-conditioned air from the floor blowing unit 53 to the under-floor space 3. It is a control device for an air conditioning system.

  And the control part 54 is set as the structure which controls the operating condition of floor air conditioning by the result of having detected whether the person is present or absent by the human sensitive sensor 12 provided in the floor space 6.

  With the above-described configuration, floor air conditioning distinguishes between the presence and absence of people in the floor space 6 and operates without waste, so the air conditioning system capable of underfloor air conditioning and floor air conditioning is automatically and efficiently controlled. can do.

  Here, when the situation in which the person is absent is continued for a predetermined time or more as a result of detection by the human sensor 12, the operating condition of the on-floor air conditioning is set to the economic priority mode.

  For this reason, it is possible to reduce as much as possible the useless air-conditioning even when there is no person in the floor space 6 for a long time.

  Moreover, when the situation where the person is present continues for a predetermined time or more as a result of detection by the human sensor 12, the operation condition of the floor air conditioning is set to the comfort priority mode.

  For this reason, it is possible to perform air conditioning that is as comfortable as possible when there is a person in the floor space 6.

  Further, the control unit 54 controls the operating conditions based on the operation time schedule data stored in the storage unit 55 under the floor air conditioning.

  For this reason, in particular, when heating operation is performed, heating by the underfloor air conditioning heats the floor space 6 substantially uniformly and evenly, but lacks an immediate effect compared to heating by the underfloor air conditioning. The space 6 warms up immediately, but the floor space 6 cannot be heated evenly compared to heating by underfloor air conditioning. Therefore, efficient control that compensates for the shortcomings can be made by taking advantage of heating by underfloor air conditioning and heating by above floor air conditioning. It can be carried out.

  In addition, the control unit 54 controls the operating conditions on the floor based on the operation time schedule data stored in the storage unit 55 in the midnight time zone.

  For this reason, this control is performed especially in the late-night hours when the electricity rate is low, which is economical, and can increase comfort during and before and after sleep. It will also prevent heat shock due to temperature differences.

  Furthermore, the control of the floor air conditioning and the floor air conditioning by the control unit 54 is control by standard specification setting, and the standard specification setting can be turned on / off, adjusted, or changed by the remote controller 13 as a controller.

  For this reason, the intention of the resident etc. of the building 1 can be easily interrupted to control by standard specification setting.

  Further, in the floor space 6 and the floor space 3 of the building 1, temperature sensors 13a and 5a are provided to send temperature data in the spaces 6 and 3 to the control unit 54, respectively. Based on these temperature data. The control unit 54 controls the floor air conditioning and the floor air conditioning.

  For this reason, since control is based on temperature data, efficient control can be performed with a simple configuration.

  Furthermore, the storage unit 55 has a learning function.

  For this reason, it is possible to reflect a temperature environment suitable for the time series in accordance with the preference of the resident or the action pattern or the like in the control based on the standard specification setting.

  The air conditioning system of such an embodiment is configured to include the control device S for the air conditioning system of the above-described embodiment.

  Since it is an above-mentioned composition, it can be considered as an air-conditioning system which has an operation effect of control device S of an air-conditioning system of an above-mentioned example.

  Here, the indoor unit 5 of the air conditioner as an air conditioner is installed in the underfloor space 3.

  For this reason, the temperature environment is stable throughout the year, and the underfloor space 3 that is normally a dead space can be effectively used.

  The building 1 of such an example is configured to include the air conditioning system of the above-described example.

  Since it is an above-mentioned structure, it can be set as the building which show | plays the effect of the air conditioning system of an above-described Example.

  As mentioned above, although the form for implementing this invention was explained in full detail based on the Example with reference to drawings, the concrete structure is not limited to this Example, and is a grade which does not deviate from the summary of this invention. Design changes are included in the present invention.

  For example, in the above-described embodiment, the building 1 has a simple structure so that the description is easy. Of course, the building 1 is not limited to this and may be implemented as a more complicated structure.

  In the above-described embodiment, the two air supply ports 10 are provided. However, the present invention is not limited to this. The number of air supply ports 10 may be set according to the size of the space 6 on the floor.

  Further, in the above-described embodiments, only the heating operation has been described, but the present invention is not limited to this, and the present invention can also be applied to the cooling operation.

  For example, if the inside of the underfloor space 3 is taking measures against condensation, it may be carried out in substantially the same manner as in the heating operation, and if no measures against condensation are taken, the underfloor air conditioning will blow out dehumidified air. What is necessary is to lower the temperature of the body when it is hot, such as in summer.

  In this case, the temperature sensors 13a and 5a may have a humidity detection function.

  Further, at the time of cooling, the upper limit temperature of the economy priority mode is 28 to 31 ° C, and the upper limit temperature of the comfort priority mode is preferably 25 to 28 ° C.

DESCRIPTION OF SYMBOLS 1 Building 1a Floor part 1b Foundation bottom concrete 1c Foundation side wall concrete 1d Exterior wall part 1e Ceiling part 2 Thermal insulation material 3 Underfloor space 4 Outdoor unit of an air conditioner 5 Indoor unit of an air conditioner (air conditioner)
51 Suction Unit 52 Floor Blow Unit 52a Open / Close Valve 53 Underfloor Blow Unit 53a Open / Close Valve 54 Control Unit 55 Storage Unit 5a Temperature Sensor 6 Floor Space 7 Drain 81 Duct 82 Duct 9 Exhaust Port 10 Air Supply Port 11 Another Air Supply Port 12 Human sensor 13 Remote controller (controller)
13a Temperature sensor S controller

Claims (9)

The interior of the building is divided into an upper floor space and an underfloor space at the floor, and an on-floor air conditioner that blows conditioned air from the air conditioner installed in the building to the above-floor space, and conditioned air from the air conditioner to the underfloor space An air conditioning system capable of underfloor air conditioning
The air conditioner is capable of at least heating operation,
The control unit
The human sensor provided in the space above the floor is set to the economic priority mode when the situation in which the person is absent continues for a predetermined time or more in the detection result, and the situation in which the person is present is the predetermined time. When the above is continued, the driving condition is controlled to be the comfort priority mode,
By the control unit, the underfloor air conditioning is controlled to switch between the economic priority mode and the comfort priority mode based on the operation time schedule data stored in the storage unit,
During heating, the lower limit temperature of the economy priority mode of the underfloor air conditioning is set higher than the lower limit temperature of the economy priority mode of the underfloor air conditioning, and the lower limit temperature of the comfort priority mode of the underfloor air conditioning is also The air conditioning system is set higher than a lower limit temperature of the comfort priority mode of the floor air conditioning.   An air supply port that is different from an air supply port that blows conditioned air to the floor space during the air conditioning on the floor is provided in the floor portion, and the space above the floor communicates with the space below the floor. The air conditioning system according to claim 1. The interior of the building is divided into an upper floor space and an underfloor space at the floor, and an on-floor air conditioner that blows conditioned air from the air conditioner installed in the building to the above-floor space, and conditioned air from the air conditioner to the underfloor space An air conditioning system capable of underfloor air conditioning
The air conditioner is capable of at least heating operation,
The control unit
The human sensor provided in the space above the floor is set to the economic priority mode when the situation in which the person is absent continues for a predetermined time or more in the detection result, and the situation in which the person is present is the predetermined time. When the above is continued, the driving condition is controlled to be the comfort priority mode,
By the control unit, the underfloor air conditioning is controlled to switch between the economic priority mode and the comfort priority mode based on the operation time schedule data stored in the storage unit,
An air supply port that is different from an air supply port that blows conditioned air to the floor space during the air conditioning on the floor is provided in the floor portion, and the space above the floor communicates with the space below the floor. Air conditioning system.   During heating, the lower limit temperature of the economy priority mode of the underfloor air conditioning is set higher than the lower limit temperature of the economy priority mode of the underfloor air conditioning, and the lower limit temperature of the comfort priority mode of the underfloor air conditioning is also The air conditioning system according to claim 3, wherein the air conditioning system is set higher than a lower limit temperature of the comfort priority mode of the floor air conditioning.   The control of the floor air conditioning and the underfloor air conditioning by the control unit is control by standard specification setting, and the standard specification setting can be turned on / off, adjusted, or changed by a controller. The air conditioning system of any one of thru | or 4.   In the above-floor space and the under-floor space of the building, temperature sensors that send temperature data in these spaces to the control unit are provided, respectively, and based on these temperature data, the control unit The air conditioning system according to any one of claims 1 to 5, wherein the air conditioning on the floor and the air conditioning on the floor are controlled.   The air conditioning system according to any one of claims 1 to 6, wherein the storage unit has a learning function.   The air conditioning system according to any one of claims 1 to 7, wherein the air conditioner is installed in the underfloor space.   A building comprising the air conditioning system according to any one of claims 1 to 8.