JP2016017656A - Air conditioning controller, air conditioning control method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioning controller, an air conditioning control method, and a program capable of controlling an air conditioner while ensuring the comfort of a person in a room.SOLUTION: An air conditioning controller in an embodiment comprises: an acquisition unit; an operation mode determination unit; a temperature setting arithmetic unit; and a setting transmission unit. The operation mode determination unit performs one of processing for determining that an operation mode of an air conditioner is a cooling operation mode if a value of an indoor temperature and a value of an indoor humidity acquired by the acquisition unit do not fall in temperature and humidity ranges corresponding to comfort ranges, respectively and the value of the indoor temperature is higher than the range, and processing for determining that the operation mode of the air conditioner is a heating mode if the value of the indoor temperature and the value of the indoor humidity acquired by the acquisition unit do not fall in the temperature and humidity ranges corresponding to the comfort ranges, respectively and the value of the indoor temperature is lower than the range. The setting transmission unit transmits the operation mode determined by the operation mode determination unit.SELECTED DRAWING: Figure 2

Description

  Embodiments described herein relate generally to an air conditioning control device, an air conditioning control method, and a program.

  In an office building or the like, the operation mode and the indoor temperature set value of the air conditioner installed in each room are centrally controlled by an air conditioning control device. For this reason, the air conditioning control device may be required to control each air conditioner so as to ensure the comfort of the occupants in the room.

JP 2009-174825 A JP 2007-285579 A JP-A-4-347437

  The problem to be solved by the present invention is to provide an air conditioning control device, an air conditioning control method, and a program capable of controlling an air conditioner while ensuring the comfort of a room occupant.

  The air conditioning control device of the embodiment includes an acquisition unit, an operation mode determination unit, a temperature setting determination unit, and a setting transmission unit. The acquisition unit acquires a room temperature value and a room humidity value. The operation mode determination unit acquires the comfort range indicating the comfort that is the control target of the air conditioner by the range of the comfort index that expresses comfort as a quantitative value, and the indoor temperature value acquired by the acquisition unit and A process for determining that the operation mode of the air conditioner is cooling when the value of the room humidity is not included in the temperature and humidity range corresponding to the comfort range and the value of the room temperature is higher than the range; The room temperature value and the room humidity value acquired by the acquisition unit are not included in the temperature and humidity range corresponding to the comfort range, and the room temperature value is lower than the above range. At least one of the process of determining the operation mode as heating is performed. The setting transmission unit transmits the operation mode determined by the operation mode determination unit.

The lineblock diagram of the air-conditioning control system of a 1st embodiment. The functional block diagram of the air-conditioning control apparatus of the embodiment. The flowchart which shows the air-conditioning control process of the air-conditioning control apparatus of the embodiment. The figure for demonstrating the determination method of the operation mode and temperature setting value of the air conditioner of the embodiment. The block diagram of the air-conditioning control system of the modification of the embodiment. The block diagram of the air-conditioning control system of the other modification of the embodiment. The functional block diagram of the air-conditioning control apparatus of 2nd Embodiment. The figure for demonstrating the determination method of the operation mode of the air conditioner of the embodiment. The functional block diagram of the air-conditioning control apparatus of 3rd Embodiment. The functional block diagram of the air-conditioning control apparatus of 4th Embodiment. The functional block diagram of the air-conditioning control apparatus of 5th Embodiment. The functional block diagram of the air-conditioning control apparatus of 6th Embodiment.

Hereinafter, an air conditioning control device, an air conditioning control method, and a program according to embodiments will be described with reference to the drawings.
Below, the case where the air conditioner controlled by the air conditioning control device is a building multi-system will be described as an example. This is because in recent years, the introduction of building multi-systems to office buildings has increased, and the operation mode has been changed by the operation of a room occupant or a building manager.
In the following, an example will be described in which the comfort index is used when calculating the operation mode of the air conditioner and the temperature setting value, which is the indoor temperature targeted by the air conditioner. The comfort index is a quantitative value representing the comfort felt by humans. For example, PMV (Predicted Mean Vote), effective temperature, modified effective temperature, new effective temperature, new standard effective temperature, working temperature, etc. can be used as the comfort index. A combination of these may also be used. Hereinafter, a case where PMV is used as the comfort index will be described as an example.

(First embodiment)
FIG. 1 is a configuration diagram of an air conditioning control system according to the present embodiment. As shown in the figure, the air conditioning control system includes an air conditioning control device 1, a relay device 2, and a building multi-system 10. The building multi-system 10 includes an outdoor unit 11, an indoor unit 12, and a driving device 13. The indoor unit 12 is installed in the living room 31. The living room 31 is an air-conditioned room that is a control target of the air conditioner. In the living room 31, an indoor thermometer 41 and an indoor hygrometer 42 are further installed.

  The building multi-system 10 is a single-type air conditioner having one outdoor unit 11 and one indoor unit 12. Here, for simplification of description, the building multi-system 10 is configured to include one outdoor unit 11 and one indoor unit 12. However, the building multi-system 10 may be a multi-type having one outdoor unit 11 and a plurality of indoor units 12.

  The air conditioning control device 1 acquires the current value of the indoor temperature measured by the indoor thermometer 41 and the current value of the indoor humidity measured by the indoor hygrometer 42. The air conditioning control device 1 determines the operation mode and the temperature set value of the building multi-system 10 using the acquired current value of the indoor temperature and the current value of the indoor humidity. The air conditioning control device 1 transmits the determined operation mode and temperature setting value to the relay device 2. The relay device 2 receives the operation mode and temperature setting value of the building multi-system 10 from the air conditioning control device 1, and transmits the received operation mode and temperature setting value to the operation device 13 of the building multi-system 10.

  The building multi-system 10 receives the operation mode and the temperature set value from the air conditioning control device 1 via the relay device 2. The outdoor unit 11 sends the refrigerant 14 controlled to a predetermined temperature according to the received operation mode and temperature set value to the indoor unit 12. At this time, the operating device 13 acquires the current value of the return air thermometer 18. The return air thermometer 18 measures the temperature of the return air 32 from the living room 31. The operating device 13 outputs an opening degree control signal to the refrigerant valve 16 based on the temperature set value received from the air conditioning control device 1 and the current value acquired from the return air thermometer 18. The cooling coil 15 of the indoor unit 12 sets the temperature of the return air 32 to a set temperature by heat exchange between the refrigerant 14 and the return air 32 from the living room 31. The return air 32 from the living room 31 is taken into driving the air supply fan 17. At this time, the operating device 13 outputs an air volume control signal to the air supply fan 17 so that the current value of the return air thermometer 18 matches the received temperature setting value.

  FIG. 2 is a functional block diagram of the air-conditioning control apparatus 1, and shows only functional blocks related to the present embodiment. The air conditioning control device 1 is realized by a computer device, for example. The air conditioning control device 1 includes a current value acquisition unit 51, a current comfort calculation unit 52, a comfort range setting unit 53, an operation mode determination unit 54, a temperature setting calculation unit 55, and a setting transmission unit 56. Configured.

The current value acquisition unit 51 is an acquisition unit that acquires the indoor temperature value of the living room 31 and the indoor humidity value from the indoor hygrometer 42. The current value acquisition unit 51 acquires the current value of the room temperature from the indoor thermometer 41 and acquires the current value of the room humidity from the indoor hygrometer 42.
The current comfort calculation unit 52 calculates the current comfort index of the living room 31 using the current value of the room temperature and the current value of the room humidity acquired by the current value acquisition unit 51. In the present embodiment, the current comfort calculation unit 52 calculates the current PMV.
For example, the comfort calculation unit 52 calculates the PMV by applying a technique disclosed in Japanese Patent Application Laid-Open No. 2002-21375 (reference document 1). The comfort index PMV is defined by ISO 7730 as an index representing a human thermal sensation, and is calculated using six variables of temperature, humidity, average radiation temperature, airflow velocity, activity amount, and clothing amount. If the technique of Reference Document 1 is used, PMV, which is a comfort index, can be obtained easily and accurately. Specifically, among the known variables necessary for the PMV calculation, independent variables are derived from variables excluding predetermined variables to create a simple PMV calculation formula. And each coefficient of the PMV linear model used for this PMV simple arithmetic expression is previously calculated | required using the method of multiple regression analysis. The current comfort calculation unit 52 calculates the PMV by substituting the current value of the room temperature and the current value of the room humidity into the PMV simple calculation formula.

  The comfort range setting unit 53 sets the comfort range of the living room 31 according to the user's input. The comfort range indicates the comfort that is the control target of the building multi-system 10 in the range of the comfort index. In the present embodiment, the comfort range setting unit 53 sets the PMV range as the comfort range. PMV ranges from -3 (cold) to +3 (hot). It is said that 95% of people feel comfortable when the value of PMV is 0, and 90% of people feel comfortable when the value of PMV is within the range of -0.5 to +0.5. ing. Based on such criteria, the user determines the PMV range to be set. In the present embodiment, the range of PMV input by the user is assumed to be −0.5 to +0.5.

  The operation mode determination unit 54 uses the current value of the room temperature and the current value of the room humidity acquired by the current value acquisition unit 51 and the PMV range set by the comfort range setting unit 53 according to the user's input. The operation mode of the multi-system 10 is determined. In this embodiment, as an example, the operation modes of the building multi-system 10 are three types of cooling, heating, and air blowing. In the case of ventilation, the building multi-system 10 drives the air supply fan 17 without performing heat exchange of the return air 32.

The temperature setting calculation unit 55 uses the operation mode determined by the operation mode determination unit 54, the current value of the indoor temperature and the current value of the indoor humidity acquired by the indoor hygrometer 42, and the temperature of the building multi-system 10. Calculate the set value.
More specifically, the technique disclosed in Reference Document 1 can be applied in the same manner as the comfort calculation unit 52 at present. According to this technique, the indoor temperature set value can be calculated by giving the target PMV to the above-described PMV simple arithmetic expression and performing the reverse calculation. The target PMV is the upper limit value of the set comfort range when the operation mode of the building multi-system 10 is cooling, the lower limit value of the comfort range when heating, and the comfort range when blowing. The intermediate value of Here, the target PMV when the operation mode is air blowing is an intermediate value in the comfort range, but may be an upper limit value or a lower limit value, and the temperature set value may not be calculated. This is because in the case of ventilation, the operation is performed regardless of the temperature set value. Hereinafter, a description will be given of a case where the current comfort calculation unit 52 does not calculate a temperature set value when the operation mode is air blowing.

  The setting transmission unit 56 transmits the operation mode determined by the operation mode determination unit 54 and the temperature setting value calculated by the temperature setting calculation unit 55 to the relay device 2. The relay device 2 transmits the received operation mode and temperature set value to the operation device 13 of the building multi-system 10.

Next, the operation of the air conditioning control device 1 will be described.
FIG. 3 is a flowchart showing the air conditioning control processing of the air conditioning control device 1. The air-conditioning control device 1 executes the air-conditioning control process shown in the figure for each outdoor unit 11 for each air-conditioning control period. The comfort range setting unit 53 of the air conditioning control device 1 sets the comfort range in advance according to the user's input. For example, the user accesses a website provided by the air conditioning control device 1 from a computer terminal via a network such as the Internet, and transmits the comfort range. Alternatively, the user may access a website provided by the relay device 2 via a network from a computer terminal, transmit the comfort range, and notify the air conditioning control device 1 of the comfort range received by the relay device 2. Good. The comfort range can be changed at any time.

  First, the current value acquisition unit 51 of the air conditioning control device 1 acquires the current value of the room temperature from the indoor thermometer 41 installed in the living room 31, and acquires the current value of the room humidity from the indoor hygrometer 42 (step). S1). Subsequently, the current comfort calculation unit 52 calculates the current comfort index of the living room 31 from the current values of the room temperature and the room humidity acquired by the current value acquisition unit 51 (step S2). The current comfort calculation unit 52 displays the comfort index of the calculation result on a display included in the air conditioning control device 1 or a computer terminal connected via a network.

  The operation mode determination unit 54 operates the building multi-system 10 using the current values of the room temperature and the room humidity acquired by the current value acquisition unit 51 and the comfort range acquired from the comfort range setting unit 53. A mode is determined (step S3). The temperature setting calculation unit 55 calculates the temperature setting value of the building multi-system 10 (step S4). By this calculation, the temperature setting calculation unit 55 determines the temperature within the temperature and humidity ranges corresponding to the comfort range as the temperature setting value. The temperature setting calculation unit 55 calculates the temperature setting value by calculating the operation mode determined by the operation mode determination unit 54, the current values of the indoor temperature and indoor humidity acquired by the current value acquisition unit 51, and the comfort range setting unit 53. The comfort range set by is used. Details of the processes in steps S3 and S4 will be described later with reference to FIG.

  The setting transmission unit 56 transmits the operation mode determined by the operation mode determination unit 54 and the temperature setting value calculated by the temperature setting calculation unit 55 to the relay device 2 (step S5). However, the setting transmission unit 56 does not transmit the temperature set value when the operation mode is air blowing. The current value acquisition unit 51 or the operation mode determination unit 54 determines whether or not to continue the process (step S6). When the current value acquisition unit 51 or the operation mode determination unit 54 determines that the process is to be continued (step S6: NO), the air conditioning control device 1 returns to step S1. When the current value acquisition unit 51 or the operation mode determination unit 54 determines that the process is not continued (step S6: YES), the air conditioning control device 1 ends the process.

  As a result, the air conditioning control device 1 transmits a setting for reducing energy consumption to the operating device 13 in consideration of comfort according to the received current values of the room temperature and the room humidity.

  FIG. 4 is a diagram for explaining a method of determining the operation mode and temperature set value of the air conditioner. A method for determining the operation mode by the operation mode determination unit 54 and determining the temperature setting value by the temperature setting calculation unit 55 will be specifically described using the air diagram shown in FIG. In the figure, only the scales of relative temperature, relative humidity, and absolute temperature are shown in a general air diagram, and other scales are omitted. Here, as an example, a case where the user sets the PMV range as −0.5 to +0.5 in the summer will be described. At this time, the PMV becomes −0.5 to +0.5 when the indoor humidity is in the range of 10% to 90% is the area A1 in the air diagram shown in FIG. The indoor humidity is indicated by relative humidity. In general, there is no case where the indoor humidity is 10% or less or 90% or more in an office building, and therefore it is excluded from the area A1 here. The operation mode determination unit 54 calculates the range of the room temperature and the room humidity that become the PMV range input by the user, and sets the range where the room humidity is 10% to 90% of the calculated range as the area A1. The operation mode determination unit 54 may calculate the region A1 when the PMV range is newly set or changed by the user.

Point B1 is a point when the current indoor temperature 28 ° C. and indoor humidity 60% of the living room 31 are plotted on an air diagram. The point B1 is not in the area A1 corresponding to the PMV range set by the user. And the temperature of the point B1 is higher than the temperature range L1 of the same absolute humidity as the point B1 in area | region A1, and the living room 31 is hot. For this reason, the operation mode determination unit 54 determines that the operation mode is cooling in order to be within the set PMV range.
When the operation mode is cooling, the temperature setting calculation unit 55 sets the temperature corresponding to a value within a predetermined range from the value when the heat is felt most in the comfort range as the temperature setting value. In the present embodiment, a temperature corresponding to +0.5 that is the upper limit value of the comfort range is set as the temperature set value. Thereby, the temperature setting calculation unit 55 uses the highest temperature in the temperature range L1 in the region A1 having the same absolute humidity as that of the point B1, that is, the temperature closest to the point B1 in the temperature range L1 as the temperature setting value. decide.

Point B2 is a point when the current indoor temperature 22 ° C. and indoor humidity 40% of the living room 31 are plotted on an air diagram. The point B2 is not in the area A1 corresponding to the PMV range set by the user. And the temperature of the point B2 is lower than the temperature range L2 of the same absolute humidity as the point B2 in the area A1, and the living room 31 is cold. For this reason, the operation mode determination part 54 judges that an operation mode is heating in order to make it into the set PMV range.
When the operation mode is heating, the temperature setting calculation unit 55 sets a temperature corresponding to a value within a predetermined range from a value when the coldest feeling is felt in the comfort range as the temperature setting value. In the present embodiment, a temperature corresponding to −0.5 which is the lower limit value of the comfort range is set as the temperature set value. Thereby, the temperature setting calculation unit 55 uses the lowest temperature in the temperature range L2 in the region A1 having the same absolute humidity as that of the point B2, that is, the temperature closest to the point B2 in the temperature range L2 as the temperature setting value. decide.

Point B3 is a point when the current indoor temperature of the living room 31 is 25 ° C. and the indoor humidity is 60% plotted on the air diagram. The point B3 is in an area A1 corresponding to the PMV range set by the user. For this reason, the building multi-system 10 does not need to be cooled or heated. Therefore, the operation mode determination unit 54 determines that the operation mode is air blowing.
When the operation mode is air blowing, the temperature setting calculation unit 55 determines that there is no temperature setting, and does not calculate a temperature setting value.

As described above, the operation mode determination unit 54 determines the operation mode such as cooling, heating, and air blowing of the building multi-system 10 according to the current room temperature and room humidity of the living room 31 and the PMV range set by the user. To do. Then, the temperature setting calculation unit 55 determines the temperature setting value based on the PMV range set by the user, the operation mode determined by the operation mode determination unit 54, and the current indoor temperature and indoor humidity of the living room 31.
In addition, the operation mode determination part 54 may determine only some operation modes among cooling, heating, and ventilation.

The air conditioning control device of the present embodiment calculates the temperature and humidity ranges corresponding to the target range of the comfort index, and in each control cycle, the calculated range, the indoor temperature and the indoor humidity of the current room, The operation mode is determined according to the relationship. Therefore, the air conditioning control device of the present embodiment can determine the operation mode of the air conditioner according to the environment of the room with a small amount of calculation. Also, the operation mode switching operation by the occupants and the building manager as in the conventional case becomes unnecessary.
In addition, when the determined operation mode is an operation mode for controlling the temperature of the room temperature, the air conditioning control device of the present embodiment determines the temperature setting value so that the room is within the target range of the comfort index, and operates It is transmitted to the air conditioner via the relay device together with the mode. Therefore, the energy consumption can be reduced by controlling the air conditioner so as not to perform excessive cooling or heating. In office buildings, the energy consumption of air conditioning accounts for a large proportion of the energy consumption of the entire building. The air conditioning control device of the present embodiment promotes energy saving of air conditioning and greatly contributes to energy saving of office buildings.
Moreover, the air-conditioning control apparatus of this embodiment can calculate a temperature setting value by one operation by using the determined operation mode. Therefore, the air-conditioning control apparatus of this embodiment can determine the temperature setting value of an air conditioner according to the environment of a living room with a small amount of calculations.

  A building multi-system which is one of air conditioners composed of an outdoor unit and an indoor unit controls the indoor temperature setting value and the operation mode for each indoor unit. However, if the amount of calculation for controlling each indoor unit is large, the amount of calculation is enormous because all air conditioners are controlled, particularly in a large-scale building. In order to maintain the comfort of the occupants, it is desirable to control each air conditioner at a predetermined control cycle. However, if the air conditioning control device cannot complete the calculation for controlling all the air conditioners within one control cycle, there is a possibility that the comfort cannot be maintained. According to the air conditioning control device of this embodiment, the amount of calculation in each control cycle is suppressed as described above, and even if there are many air conditioners to be controlled as in a building multi-system, all the rooms are reduced while reducing energy. It becomes possible to control without taking time so as to maintain comfort. And since the air conditioner can be automatically controlled by the operation mode and temperature setting value, even those who are not familiar with the operation of the air conditioner in the building can easily adjust the living room environment simply by changing the comfort range be able to.

  Further, the air conditioning control device 1 transmits a room temperature set value for each indoor unit 12 of the building multi-system 10 via the relay device 2. For this reason, even when a conference room or a private room is created due to tenant construction in a large-scale building or the like, an operation mode and a room temperature set value that can reduce energy consumption can be transmitted for each indoor unit in the conference room or private room. In this way, it is possible to flexibly cope with changes in partition due to tenant construction or the like.

  In the air conditioning control system shown in FIG. 1, one indoor thermometer and one indoor hygrometer are installed in the living room 31. However, even in the same room, the current values of the indoor thermometer and the indoor hygrometer may differ depending on the location. Therefore, a modified example in which a plurality of indoor thermometers and indoor hygrometers are installed in the living room 31 will be described.

  FIG. 5 is a configuration diagram of an air conditioning control system according to a modification of the present embodiment. In this figure, the same parts as those in the air conditioning control system shown in FIG. In the figure, an indoor thermometer 43 and an indoor hygrometer 44 are further installed in the living room 31. By installing two indoor thermometers and two indoor hygrometers in this way, the indoor environment of the living room 31 can be acquired more accurately.

  When two indoor thermometers and two indoor hygrometers are installed, the current value acquisition unit 51 acquires the current value of the indoor temperature from the indoor thermometer 41 and the indoor thermometer 43 in step S1 of FIG. The current value of indoor humidity is acquired from the indoor hygrometer 42 and the indoor hygrometer 44. The current value acquisition unit 51 acquires the current value of the indoor temperature from the indoor thermometer 41 and the indoor thermometer 43, and acquires the current value of the indoor humidity from the indoor hygrometer 42 and the indoor hygrometer 44. The current value acquisition unit 51 averages the current value of the indoor temperature acquired from the indoor thermometer 41 and the indoor thermometer 43, and the average value of the current value of the indoor humidity acquired from the indoor hygrometer 42 and the indoor hygrometer 44. Is output. In the processing after step S2, the current comfort calculation unit 52, the operation mode determination unit 54, and the temperature setting calculation unit 55 acquire the average value of the current value of the room temperature output by the current value acquisition unit 51 and the current value. An average value of the current values of the indoor humidity output by the unit 51 is used for the calculation.

  When three or more indoor thermometers and indoor hygrometers are installed in the living room 31, the current value acquisition unit 51 may output an average value of the current values of the room temperature and the room humidity, and may be an intermediate value. May be output. By using the intermediate value, for example, even when a certain indoor thermometer or indoor hygrometer fails and an abnormal value is measured, an operation that does not consider the abnormal value can be performed. Thus, by using the present value of the indoor thermometer and the present value of the room humidity measured at a plurality of locations, a more reliable air conditioning control device can be realized.

  In the air conditioning control system shown in FIG. 1, the operating device 13 of the building multi-system 10 returns the temperature setting value received from the relay device 2 and the return air thermometer 18 that measures the temperature of the return air 32 from the living room 31. And the opening degree control signal is output to the refrigerant valve 16. However, the case where the return air thermometer 18 is not installed in the indoor unit of the building multi-system 10 can be considered. Therefore, a modified example in which the return air thermometer 18 is not installed in the indoor unit will be described.

FIG. 6 is a configuration diagram of an air conditioning control system according to another modification of the present embodiment. In this figure, the same parts as those in the air conditioning control system shown in FIG. In the figure, the return air thermometer 18 is not installed in the indoor unit 12a of the building multi-system 10. The operating device 13 of the air conditioning control system shown in FIG. 1 outputs an opening degree control signal to the refrigerant valve 16 based on the temperature set value received from the air conditioning control device 1 and the current value acquired from the return air thermometer 18. . In the present modification, the operating device 13 acquires the current value of the indoor thermometer 41 of the living room 31 instead of the current value acquired from the return air thermometer 18. Then, the operating device 13 outputs an opening degree control signal of the refrigerant valve 16 based on the temperature set value received from the relay device 2 and the current value of the indoor thermometer 41 of the living room 31.
Thereby, even when the indoor unit 12a of the building multi-system 10 cannot measure the temperature of the return air 32 from the living room 31, the same effect as the air conditioning control system shown in FIG. 1 can be obtained.

(Second Embodiment)
In this embodiment, the comfort humidity is further set. The present embodiment will be described with a focus on differences from the first embodiment. The air conditioning control system of the present embodiment has a configuration in which the air conditioning control device 1 included in the air conditioning control system of the first embodiment is replaced with an air conditioning control device 1a shown in FIG.

  FIG. 7 is a configuration diagram of the air conditioning control device 1a according to the present embodiment. In the figure, the same parts as those in the air conditioning control apparatus 1 according to the first embodiment shown in FIG. The air conditioning control device 1a shown in the figure includes a current value acquisition unit 51, a current comfort calculation unit 52, a comfort range setting unit 53, a comfort humidity setting unit 61, an operation mode determination unit 54a, and a temperature setting. A calculation unit 55 and a setting transmission unit 56 are provided.

The comfort humidity setting unit 61 sets a comfort humidity range that is a comfortable humidity range in accordance with a user input.
The operation mode determination unit 54a operates the building multi-system 10 using the comfort humidity range set by the comfort humidity setting unit 61 in addition to the current value of the room temperature, the current value of the room humidity, and the PMV range. Determine the mode. In this embodiment, as an example, the operation modes of the building multi-system 10 are five types in which dehumidification and humidification are added to cooling, heating, and ventilation. Thereby, the operation mode which does not perform temperature control of room temperature becomes ventilation, dehumidification, and humidification. The temperature setting calculation unit 55 determines the temperature set value when the operation mode determined by the operation mode determination unit 54a is cooling or heating.

The air conditioning control process of the air conditioning control device 1a is the same as that of the first embodiment shown in FIG. However, in step S3, the operation mode determination unit 54a determines the operation mode of the air conditioner as follows.
FIG. 8 is a diagram for explaining a method of determining the operation mode of the air conditioner. A method for determining the operation mode by the operation mode determination unit 54a will be specifically described using the air diagram shown in FIG. In the drawing, only the relative temperature, relative humidity, and absolute temperature scales are shown in the general air diagram, and other scales are omitted. Here, a case where the user sets the PMV range to −0.5 to +0.5 and the comfort humidity range to 40% to 70% in summer will be described. Similarly to the first embodiment, the operation mode determination unit 54a calculates the range of the room temperature and the room humidity that are the PMV range input by the user. Since the case where the indoor humidity is 10% or less or 90% or more does not generally exist in an office building, the operation mode determination unit 54a sets the range where the indoor humidity is 10% to 90% in the calculated range as the area A1. And
The operation mode determination unit 54a sets a region of the comfort humidity range 40% to 70% set by the comfort humidity setting unit 61 in the region A1 as the region A11. Moreover, the operation mode determination part 54a makes area | region A12 the area | region higher than the upper limit 70% of comfort humidity range among area | region A1, and makes area | region A13 lower than the minimum 40% of comfort humidity range.

  When the indoor temperature is 28 ° C. and the indoor humidity is 60% indicated by the point B1, and when the indoor temperature is 22 ° C. and the indoor humidity is 40% indicated by the point B2, the operation mode determination unit 54a determines the operation mode according to the first embodiment. The operation mode is determined in the same manner as the unit 54. And the temperature setting calculating part 55 determines a temperature setting value similarly to 1st Embodiment.

Point B3 is a point when the current indoor temperature of the living room 31 is 25 ° C. and the indoor humidity is 60% plotted on the air diagram. Point B3 is in region A11. For this reason, the building multi-system 10 does not need to be cooled or heated. Therefore, the operation mode determination unit 54a determines that the operation mode is air blowing.
Point B4 is a point when the current indoor temperature of the living room 31 is 24 ° C. and the indoor humidity is 80% plotted on an air diagram. Point B4 is in the area A1 of the PMV range set by the user, but is in the area A12 where the humidity is high. Therefore, the operation mode determination unit 54a determines that the operation mode of the building multi-system 10 is dehumidification.
Point B5 is a point when the current room temperature 25 ° C. and room humidity 20% of the living room 31 are plotted on an air diagram. Point B5 is in the area A1 of the PMV range set by the user, but is in the area A13 where the humidity is low. Therefore, the operation mode determination unit 54a determines that the operation mode of the building multi-system 10 is humidification.

As described above, when the operation mode of the building multi-system 10 includes dehumidification and humidification in addition to cooling, heating, and ventilation, the operation mode determination unit 54a performs PMV and comfort humidity range set by the user, The operation mode is determined based on the current indoor temperature and indoor humidity.
According to this embodiment, the same effect as the first embodiment can be obtained. Furthermore, the comfort humidity can be set, and the operation mode can be dehumidified or humidified. Therefore, compared with the first embodiment, it is possible to realize an air conditioning control device that satisfies the comfort expected by the user regarding humidity.

(Third embodiment)
In the present embodiment, the temperature setting value is corrected according to the number of people in the room. Here, the description will focus on the differences from the first embodiment, but the present invention can also be applied to the second embodiment. The air conditioning control system of this embodiment has a configuration in which the air conditioning control device 1 included in the air conditioning control system of the first embodiment is replaced with an air conditioning control device 1b shown in FIG.

  FIG. 9 is a configuration diagram of the air conditioning control device 1b according to the present embodiment. In the figure, the same parts as those in the air conditioning control apparatus 1 according to the first embodiment shown in FIG. The air conditioning control device 1b shown in the figure includes a current value acquisition unit 51, a current comfort calculation unit 52, a comfort range setting unit 53, an operation mode determination unit 54, a temperature setting calculation unit 55, and a person number threshold setting. The unit 72, the number information acquisition unit 73, the temperature setting correction unit 74, and the setting transmission unit 56 are configured.

The number-of-people threshold setting unit 72 sets a threshold for correcting the temperature setting value transmitted to the relay device 2. This threshold is a threshold relating to the number of people in the room.
The number information acquisition unit 73 acquires the number of people in the room 31. Specifically, the number-of-persons information acquisition unit 73 receives occupancy number information indicating the number of occupants in the room measured by the number-of-people measuring means 71 installed in the room 31. The person counting means 71 may be, for example, an infrared sensor, a sensor using a camera, or a device that estimates the number of people in a room from the CO ₂ concentration.
The temperature setting correction unit 74 uses the number of people in the room acquired by the number of people information acquisition unit 73 and the threshold set by the number of people threshold setting unit 72 to calculate the temperature setting value calculated by the temperature setting calculation unit 55, It corrects to the temperature set value transmitted to the relay apparatus 2.

The operation of the air conditioning control device 1b will be described.
First, the number-of-persons threshold setting unit 72 sets in advance a threshold for the number of people in the room to be used when correcting the temperature setting value. The air conditioning control device 1b executes the processing from step S1 to step S4 of the first embodiment shown in FIG. In step S4, the number information acquisition unit 73 further performs the following processing.

The number-of-persons information acquisition unit 73 receives the number-of-rooms information in which the number of people in the room 31 is set from the number-of-people measuring means 71 installed in the room 31 and outputs the information to the temperature setting correction unit 74. The temperature setting correction unit 74 acquires the threshold set by the number of people threshold setting unit 72.
For example, it is assumed that the occupancy number indicated by the occupancy number information is “10” and the threshold set by the number threshold setting unit 72 is “5”. Since the number of people in the room exceeds the threshold value, the temperature setting correction unit 74 outputs the temperature setting value acquired from the temperature setting calculation unit 55 to the setting transmission unit 56 as it is.
On the other hand, it is assumed that the number of people in the room is “1 person” and the threshold is “5 people”. The temperature setting correction unit 74 corrects the temperature setting value acquired from the temperature setting calculation unit 55 and outputs it to the setting transmission unit 56 because the number of people in the room is equal to or less than the threshold value. For example, when the operation mode is cooling, the temperature setting correction unit 74 performs correction to increase the temperature setting value by a predetermined temperature such as 1 ° C. Moreover, the temperature setting correction | amendment part 74 performs correction | amendment which lowers | hangs a temperature setting value only by predetermined temperature, such as 1 degreeC, when an operation mode is heating.

  Or the temperature setting correction | amendment part 74 may designate the temperature setting value after correction | amendment. For example, when the number of people in the room is equal to or less than the threshold value, the temperature setting correction unit 74 corrects the temperature setting value to a predetermined temperature corresponding to cooling, such as 28 ° C., when the operation mode is cooling. For example, when the number of people in the room is equal to or less than the threshold value, the temperature setting correction unit 74 corrects the temperature setting value to a predetermined temperature corresponding to heating, such as 20 ° C., when the operation mode is heating.

  As another correction, a function table indicating the correspondence between the number of people in the room and the temperature correction value is registered in advance in the number-of-people threshold setting unit 72, and the temperature setting correction unit 74 reads out from this function table according to the number of people in the room. The temperature set value may be corrected using the temperature correction value. The function table may indicate the correspondence between the number of people in the room and the temperature correction value for each operation mode. The temperature setting correction unit 74 reads the temperature correction value from the function table according to the operation mode and the number of people in the room.

When the setting transmission unit 56 receives the temperature set value from the temperature setting correction unit 74, the air conditioning control device 1b performs the processing from step S5 onward in FIG.
According to this embodiment, the same effect as the first embodiment can be obtained. Furthermore, since the temperature setting value is corrected according to the number of people in the current room, it is possible to realize an air conditioning control device capable of further reducing energy consumption compared to the first embodiment.

(Fourth embodiment)
In the present embodiment, when a load adjustment execution instruction is received, the temperature set value is corrected. Here, the description will focus on the differences from the first embodiment, but the present invention can also be applied to the second and third embodiments. The air conditioning control system of this embodiment has a configuration in which the air conditioning control device 1 included in the air conditioning control system of the first embodiment is replaced with an air conditioning control device 1c shown in FIG.

  FIG. 10 is a configuration diagram of the air conditioning control device 1c according to the present embodiment. In the figure, the same parts as those in the air conditioning control apparatus 1 according to the first embodiment shown in FIG. The air-conditioning control apparatus 1c shown in the figure includes a current value acquisition unit 51, a current comfort calculation unit 52, a comfort range setting unit 53, an operation mode determination unit 54, a temperature setting calculation unit 55, a DR (Demand). (Response) signal receiving unit 81, temperature setting correction unit 82, and setting transmission unit 56. DR is a load adjustment based on a command / request from the power system.

The DR signal receiving unit 81 is a signal receiving unit that receives a DR signal from the outside as a load adjustment execution signal that is a signal instructing execution of load adjustment.
When the DR signal receiving unit 81 receives the DR signal, the temperature setting correction unit 82 corrects the temperature setting value calculated by the temperature setting calculation unit 55 to a temperature setting value to be transmitted to the relay device 2.

The operation of the air conditioning control device 1c will be described.
The air conditioning control device 1c executes the processing from step S1 to step S4 of the first embodiment shown in FIG. In step S4, the DR signal receiver 81 further performs the following processing.
That is, when the DR signal receiving unit 81 has not received a DR signal, the temperature setting correction unit 82 outputs the temperature setting value acquired from the temperature setting calculation unit 55 to the setting transmission unit 56 as it is.
On the other hand, when the DR signal receiving unit 81 receives the DR signal, the reception of the DR signal is output to the temperature setting correction unit 82. When the reception of the DR signal is notified, when the operation mode is cooling, the temperature setting correction unit 82 corrects the temperature setting value acquired from the temperature setting calculation unit 55 by a predetermined temperature such as 1 ° C., and transmits the setting. To the unit 56. Further, when the reception of the DR signal is notified, when the operation mode is heating, the temperature setting correction unit 82 corrects the temperature setting value acquired from the temperature setting calculation unit 55 by a predetermined temperature such as 1 ° C. The data is output to the transmission unit 56.
When the setting transmission unit 56 receives the temperature set value from the temperature setting correction unit 82, the air conditioning control device 1c performs the processing from step S5 onward in FIG.

  According to this embodiment, the same effect as the first embodiment can be obtained. Furthermore, when receiving the DR signal, it is possible to realize an air conditioning control device that corrects the temperature setting value and can further reduce energy consumption as compared with the first embodiment.

(Fifth embodiment)
In the present embodiment, the comfort range is corrected according to the number of people in the room. Here, the description will focus on differences from the first embodiment, but the present invention can also be applied to the second to fourth embodiments. The air conditioning control system of this embodiment has a configuration in which the air conditioning control device 1 included in the air conditioning control system of the first embodiment is replaced with an air conditioning control device 1d shown in FIG.

  FIG. 11 is a configuration diagram of an air conditioning control device 1d according to the present embodiment. In the figure, the same parts as those in the air conditioning control apparatus 1 according to the first embodiment shown in FIG. The air conditioning control device 1d shown in the figure includes a current value acquisition unit 51, a current comfort calculation unit 52, a comfort range setting unit 53, a number of people threshold setting unit 92, a number of people information acquisition unit 93, and a comfort range. A correction unit 94, an operation mode determination unit 54, a temperature setting calculation unit 55, and a setting transmission unit 56 are provided.

The number-of-people threshold setting unit 92 sets a threshold for correcting the comfort range to be output to the operation mode determination unit 54. This threshold is a threshold relating to the number of people in the room.
The number-of-persons information acquisition unit 93 acquires the number of people in the room 31. Specifically, the number-of-persons information acquisition unit 93 receives the occupancy number information indicating the number of occupants in the room measured by the number-of-people measuring means 91 installed in the room 31. The number-of-people measuring means 91 may be, for example, an infrared sensor, a sensor using a camera, or a device that estimates the number of people in a room from the CO ₂ concentration.
The comfort range correction unit 94 uses the comfort range set by the comfort range setting unit 53 using the number of people in the room acquired by the number information acquisition unit 93 and the threshold set by the number threshold setting unit 92. And the corrected comfort range is output to the driving mode determination unit 54.

The operation of the air conditioning control device 1d will be described.
First, the number-of-persons threshold setting unit 92 previously sets a threshold for the number of people in the room to be used when correcting the comfort range. The number-of-persons information acquisition unit 93 receives the number-of-rooms information in which the number of people in the room 31 is set from the number-of-people measuring means 91 installed in the room 31 and outputs the information to the comfort range correction unit 94. The comfort range correction unit 94 acquires the threshold set by the number-of-people threshold setting unit 92.

For example, it is assumed that the occupancy number indicated by the occupancy number information is “10” and the threshold set by the number threshold setting unit 92 is “5”. The comfort range correction unit 94 outputs the comfort range acquired from the comfort range setting unit 53 to the operation mode determination unit 54 as it is because the number of people in the room exceeds the threshold.
On the other hand, it is assumed that the number of people in the room is “1 person” and the threshold is “5 people”. The comfort range correction unit 94 corrects the comfort range acquired from the comfort range setting unit 53 and outputs it to the operation mode determination unit 54 because the number of people in the room is equal to or less than the threshold value. For example, the comfort range correction unit 94 corrects the upper limit of the PMV range by a predetermined amount such as 0.2 when the operation mode is cooling. In addition, when the operation mode is heating, the comfort range correction unit 94 corrects the lower limit of the PMV range by a predetermined value such as 0.2.

Or the comfort range correction | amendment part 94 may designate the PMV range after correction | amendment. For example, when the number of people in the room is equal to or less than the threshold value, the comfort range correction unit 94 corrects the upper limit of the PMV range to a predetermined upper limit value such as 0.7 when the operation mode is cooling. In addition, for example, when the number of people in the room is equal to or less than the threshold value, the comfort range correction unit 94 corrects the lower limit of the PMV range to a predetermined lower limit value such as −0.7 when the operation mode is heating.
As other corrections, when the number of people in the room is equal to or less than the threshold, the comfort range correction unit 94 may expand the upper limit and the lower limit of the PMV range to a range in the uncomfortable direction by a predetermined amount regardless of the operation mode.

  The operation of the air conditioning control device 1d is the first implementation shown in FIG. 3 except that the operation mode determination unit 54 and the temperature setting calculation unit 55 use the comfort range output by the comfort range correction unit 94 by the above processing. It is the same as the form.

  According to this embodiment, the same effect as the first embodiment can be obtained. Furthermore, since the comfort range is corrected according to the number of people in the current room, it is possible to realize an air conditioning control device capable of further reducing energy consumption as compared with the first embodiment.

(Sixth embodiment)
The present embodiment corrects the comfort range when a load adjustment execution instruction is received. Here, the description will focus on the differences from the first embodiment, but the present invention can also be applied to the second to fifth embodiments. The air conditioning control system of this embodiment has a configuration in which the air conditioning control device 1 included in the air conditioning control system of the first embodiment is replaced with an air conditioning control device 1e shown in FIG.

  FIG. 12 is a configuration diagram of an air conditioning control device 1e according to the present embodiment. In the figure, the same parts as those in the air conditioning control apparatus 1 according to the first embodiment shown in FIG. The air conditioning control device 1e shown in the figure includes a current value acquisition unit 51, a current comfort calculation unit 52, a comfort range setting unit 53, a DR signal reception unit 101, a comfort range correction unit 102, and an operation mode. A determination unit 54, a temperature setting calculation unit 55, and a setting transmission unit 56 are provided.

The DR signal receiving unit 101 is a signal receiving unit that receives a DR signal from the outside as a load adjustment execution signal that is a signal instructing execution of load adjustment.
When the DR signal receiving unit 101 receives a DR signal, the comfort range correction unit 102 corrects the comfort range set by the comfort range setting unit 53 and outputs the correction to the operation mode determination unit 54.

The operation of the air conditioning control device 1e will be described.
When the DR signal receiving unit 101 has not received a DR signal, the comfort range correction unit 102 outputs the comfort range set by the comfort range setting unit 53 to the setting transmission unit 56 as it is.
On the other hand, when the DR signal receiving unit 101 receives the DR signal, the DR signal receiving unit 101 outputs the reception of the DR signal to the comfort range correction unit 102. When the reception of the DR signal is notified, the comfort range correction unit 102 performs correction to increase the upper limit of the PMV range by a predetermined value such as 0.2 when the operation mode is cooling. Moreover, the comfort range correction | amendment part 102 performs correction | amendment which lowers | hangs the lower limit of PMV range only predetermined | prescribed, such as 0.2, when an operation mode is heating. The comfort range correction unit 102 outputs the corrected PMV range to the operation mode determination unit 54.

  The operation of the air conditioning control device 1e is the first implementation shown in FIG. 3 except that the operation mode determination unit 54 and the temperature setting calculation unit 55 use the comfort range output from the comfort range correction unit 102 by the above processing. It is the same as the form.

  According to this embodiment, the same effect as the first embodiment can be obtained. Furthermore, since the comfort range is corrected when the DR signal is received, it is possible to realize an air conditioning control device capable of further reducing energy consumption as compared with the first embodiment.

In the embodiment described above, the operation mode determination units 54 and 54a may determine that the building multi-system 10 is powered off (power is cut off) instead of determining that the operation mode is air blowing. For example, the operation mode determination unit 54 determines that the air conditioner is powered off when the current value of the room temperature and the current value of the room humidity are within the area A1 in FIG. Further, the operation mode determination unit 54a determines that the air conditioner is powered off when the current value of the room temperature and the current value of the room humidity are within the area A11 of FIG. When the operation mode determination units 54 and 54a determine that the air conditioner is powered off, the setting transmission unit 56 transmits an instruction to turn off the building multi-system 10 to the driving device 13 via the relay device 2. In a comfortable state, there is no need to cool or heat the room. Therefore, energy consumption can be further reduced by stopping the building multi-system 10. The setting transmission unit 56 may transmit an instruction to turn off the power of the air conditioner only when the operation mode determination units 54 and 54a determine that the power supply is OFF in the next control cycle after determining an operation mode other than air blowing. .
In addition, when the setting transmission unit 56 determines an operation mode other than air blowing in the next control cycle determined by the operation mode determination units 54 and 54a to be turned off, the air conditioner power ON ( Send power on instruction. That is, when the operation mode determination unit 54 determines the cooling or heating operation mode after transmitting the air-conditioner power-off instruction, the setting transmission unit 56 sends the air-conditioner power-on instruction, the operation mode, and the temperature. Send the setting value. When the operation mode determination unit 54a determines an operation mode of cooling, heating, humidification or dehumidification after transmitting an instruction to turn off the power supply of the air conditioner, the setting transmission unit 56 When the operation mode is cooling or heating, the temperature setting value is transmitted.

According to at least one embodiment described above, by having the operation mode determination unit, it is possible to calculate the operation mode with a small amount of calculation and control the air conditioner while considering the comfort of the occupant. .
In addition, according to at least one embodiment described above, by having the temperature setting calculation unit, the temperature setting value is reduced so as to reduce the energy consumption of the air conditioner while considering the comfort of the occupant. The air conditioner can be controlled by calculating the quantity.

  You may make it implement | achieve the function of the air-conditioning control apparatus 1, 1a, 1b, 1c, 1d, 1e in embodiment mentioned above with a computer. In that case, a program for realizing this function may be recorded on a computer-readable recording medium, and the program recorded on this recording medium may be read into a computer system and executed. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory inside a computer system serving as a server or a client in that case may be included and a program held for a certain period of time. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Air conditioning control device, 1a ... Air conditioning control device, 1b ... Air conditioning control device, 1c ... Air conditioning control device, 1d ... Air conditioning control device, 1e ... Air conditioning control device, 2 ... Relay device, 10 ... Multi-system for buildings, 11 ... Outdoor unit, 12 ... indoor unit, 12a ... indoor unit, 13 ... operating device, 14 ... refrigerant, 15 ... cooling coil, 16 ... refrigerant valve, 17 ... air supply fan, 18 ... return air thermometer, 31 ... living room, 32 ... return air, 41 ... indoor thermometer, 42 ... indoor hygrometer, 43 ... indoor thermometer, 44 ... indoor hygrometer, 51 ... current value acquisition part (acquisition part), 52 ... current comfort calculation part, 53 ... comfort Sex range setting section, 54 ... operation mode determination section, 54a ... operation mode determination section, 55 ... temperature setting calculation section (temperature setting determination section), 56 ... setting transmission section, 61 ... comfort humidity setting section, 71 ... number measurement Means 72 ... Number of persons threshold setting section 73 ... Number of persons information Obtaining unit, 74 ... temperature setting correction unit, 82 ... temperature setting correction unit, 81 ... DR signal receiving unit (signal receiving unit), 91 ... number-of-people measuring means, 92 ... number-of-people threshold setting unit, 93 ... number-of-people information acquiring unit, 94 ... comfort range correction unit, 101 ... DR signal reception unit (signal reception unit), 102 ... comfort range correction unit

Claims (16)

An acquisition unit for acquiring a value of indoor temperature and a value of indoor humidity;
A comfort range indicating comfort that is a control target of the air conditioner is acquired from a comfort index range that expresses comfort as a quantitative value, and the indoor temperature value and the indoor humidity acquired by the acquisition unit are acquired. A process for determining that the operation mode of the air conditioner is cooling when a value is not included in the temperature and humidity ranges corresponding to the comfort range and the value of the room temperature is higher than the range; The room temperature value and the room humidity value acquired by the acquisition unit are not included in the temperature and humidity ranges corresponding to the comfort range, and the room temperature value is lower than the range. An operation mode determination unit that performs at least one of processing for determining heating as the operation mode of the air conditioner,
A setting transmission unit for transmitting the operation mode determined by the operation mode determination unit;
An air conditioning control device. The operation mode determination unit does not perform temperature control of the indoor temperature in the operation mode when the indoor temperature value and the indoor humidity value are included in a temperature and humidity range corresponding to the comfort range. Judge as driving mode,
The air conditioning control device according to claim 1.   The said operation mode determination part determines that the said operation mode is ventilation when the value of the said indoor temperature and the value of the said indoor humidity are contained in the range of the temperature and humidity corresponding to the said comfort range. The air conditioning control device described.   When the indoor temperature value and the indoor humidity value are included in a temperature and humidity range corresponding to the comfort range, the operation mode determination unit determines that the indoor humidity value is a predetermined comfort level. The air-conditioning control apparatus according to claim 2, wherein the operation mode is determined to be blown when the humidity is within a certain humidity range, dehumidification is determined to be higher than the humidity range, and humidification is determined to be humid when lower than the humidity range. . The operation mode determination unit determines that the air conditioner is powered off when the indoor temperature value and the indoor humidity value are included in a temperature and humidity range corresponding to the comfort range,
The setting transmission unit transmits an instruction to turn off the air conditioner when the operation mode determination unit determines that the air conditioner is powered off, and the operation mode determination unit transmits the instruction to turn off the air conditioner. The air conditioning control device according to claim 2, wherein when the cooling or heating operation mode is determined, an instruction to turn on the air conditioner is transmitted in addition to the operation mode determined by the operation mode determination unit. When the indoor temperature value and the indoor humidity value are included in a temperature and humidity range corresponding to the comfort range, the operation mode determination unit determines that the indoor humidity value is a predetermined comfort level. When it is included in a certain humidity range, it is determined that the air conditioner is turned off, when it is higher than the humidity range, it is determined as dehumidification, and when it is lower than the humidity range, it is determined as humidification,
The setting transmission unit transmits an instruction to turn off the air conditioner when the operation mode determination unit determines that the air conditioner is powered off, and the operation mode determination unit transmits the instruction to turn off the air conditioner. The air conditioning control device according to claim 2, wherein when an operation mode of cooling, heating, humidification, or dehumidification is determined, an instruction to turn on an air conditioner is transmitted in addition to the operation mode determined by the operation mode determination unit. When the operation mode determination unit determines that the operation mode is cooling or heating, a temperature setting within the temperature and humidity ranges corresponding to the comfort range is a temperature setting that is a target room temperature for the air conditioner temperature control. A temperature setting determining unit that determines the value;
The setting transmission unit further transmits the temperature setting value determined by the temperature setting determination unit when the operation mode determined by the operation mode determination unit is cooling or heating,
The air-conditioning control apparatus according to any one of claims 1 to 6. When the operation mode determined by the operation mode determination unit is cooling, the temperature setting determination unit determines, as a temperature setting value, a temperature corresponding to a value within a predetermined range from a value that feels the heat most in the comfort range. And, when the operation mode determined by the operation mode determination unit is heating, a temperature corresponding to a value within a predetermined range is determined as a temperature set value from a value that feels the coldest in the comfort range,
The air conditioning control device according to claim 7.   The acquisition unit receives indoor temperature values and indoor humidity values measured at a plurality of locations in the room, and based on the received plurality of indoor temperature values and the plurality of indoor humidity values, an operation mode is obtained. The air conditioning control device according to claim 7 or 8, wherein a value of an indoor temperature and a value of an indoor humidity used for determining the temperature and determining a temperature set value are acquired. Number of people information acquisition section for acquiring the number of people in the room,
A temperature setting correction unit that corrects the temperature setting value determined by the temperature setting determination unit according to the number of people in the room indicated by the number of people in the room acquired by the number of people information acquisition unit;
The said setting transmission part transmits the said operation mode determined by the said operation mode determination part, and the said temperature setting value which the said temperature setting correction | amendment part correct | amended, The any one of Claim 7-9 Air conditioning control device. A signal receiving unit that receives a load adjustment execution signal that instructs execution of load adjustment;
A temperature setting correction unit that corrects the temperature setting value determined by the temperature setting determination unit when the signal reception unit receives a load adjustment execution signal;
The said setting transmission part transmits the said operation mode determined by the said operation mode determination part, and the said temperature setting value which the said temperature setting correction | amendment part correct | amended, The any one of Claim 7-9 Air conditioning control device. Number of people information acquisition section for acquiring the number of people in the room,
A comfort range correction unit that corrects the comfort range according to the number of people in the room indicated by the number of people information acquired by the number of people information acquisition unit;
The driving mode determination unit determines the driving mode using the comfort range corrected by the comfort range correction unit,
The air conditioning control device according to any one of claims 7 to 9, wherein the temperature setting determination unit determines a temperature setting value using the comfort range corrected by the comfort range correction unit. A signal receiving unit that receives a load adjustment execution signal that instructs execution of load adjustment;
A comfort range correction unit that corrects the comfort range when the signal receiving unit receives a load adjustment execution signal;
The driving mode determination unit determines the driving mode using the comfort range corrected by the comfort range correction unit,
The air conditioning control device according to any one of claims 7 to 9, wherein the temperature setting determination unit determines a temperature setting value using the comfort range corrected by the comfort range correction unit.   The comfort index is any one or more of a predicted average thermal sensation report, an effective temperature, a corrected effective temperature, a new effective temperature, a new standard effective temperature, and an operating temperature. The air-conditioning control apparatus according to item 1. An air conditioning control method executed by an air conditioning controller,
An acquisition step of acquiring a value of indoor temperature and a value of indoor humidity;
A comfort range indicating comfort that is a control target of the air conditioner is acquired from a comfort index range that expresses comfort as a quantitative value, and the indoor temperature value and the indoor humidity acquired in the acquisition step are acquired. A process of determining that the operation mode of the air conditioner is cooling when the value of is not included in the temperature and humidity ranges corresponding to the comfort range and the value of the indoor temperature is higher than the range. The indoor temperature value and the indoor humidity value acquired in the acquiring step are not included in the temperature and humidity range corresponding to the comfort range, and the indoor temperature value is less than the range. An operation mode determination step for performing at least one of the process of determining the operation mode of the air conditioner as heating when
A setting transmission step for transmitting the operation mode determined in the operation mode determination step;
An air conditioning control method. On the computer,
An acquisition step of acquiring a value of indoor temperature and a value of indoor humidity;
A comfort range indicating comfort that is a control target of the air conditioner is acquired from a comfort index range that expresses comfort as a quantitative value, and the indoor temperature value and the indoor humidity acquired in the acquisition step are acquired. A process of determining that the operation mode of the air conditioner is cooling when the value of is not included in the temperature and humidity ranges corresponding to the comfort range and the value of the indoor temperature is higher than the range. The indoor temperature value and the indoor humidity value acquired in the acquiring step are not included in the temperature and humidity range corresponding to the comfort range, and the indoor temperature value is less than the range. An operation mode determination step for performing at least one of the process of determining the operation mode of the air conditioner as heating when
A setting transmission step for transmitting the operation mode determined in the operation mode determination step;
A program for running

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