JP2023155986A - Air conditioner and control method for the same - Google Patents

Abstract

To provide an air conditioner capable of reducing possibilities of giving discomfort feeling to a resident, and to provide a control method for the same.SOLUTION: An air conditioner 10 includes: a heat exchanger 11; a blower fan 12; a calculation part 14 for calculating a value of a thermal index of at least one of an estimated average hot-cold sense declaration and a standard new effective temperature; and a control part 15 for receiving cold heat in the heat exchanger 11 and controlling a blast volume in the blower fan 12 based on the value of the thermal index calculated by the calculation part 14. The control part 15 operates the blower fan 12 in a state of receiving cold heat by the heat exchanger 11 when the value of the thermal index calculated by the calculation part 14 exceeds the predetermined value, and operates the blower fan 12 in a state of not receiving cold heat by the heat exchanger 11 when the value of the thermal index calculated by the calculation part 14 becomes the predetermined value or less from a state of exceeding the predetermined value.SELECTED DRAWING: Figure 2

Description

The present invention relates to an air conditioner and a control method thereof.

BACKGROUND ART Conventionally, an air conditioner has been proposed that performs air conditioning based on a thermal index indicating the comfort of occupants in a room (see Patent Documents 1 and 2).

JP2021-139511A Japanese Patent Application Publication No. 2019-148350

Here, regarding the expected average thermal sensation report, which is one of the thermal indicators, the degree of contribution of the airflow velocity tends to be large. For this reason, when cooling the air conditioner is controlled based on the predicted average thermal sensation report, for example, if the value of the predicted average thermal sensation report becomes an appropriate value and the air conditioner stops and the airflow velocity disappears, This may cause the value of the average thermal sensation report to rise and become outside the appropriate value relatively quickly. If the value falls outside of the appropriate value, cooling operation is restarted. Therefore, the air conditioner is frequently turned on and off, causing frequent fluctuations in the value of the predicted average thermal sensation report, which may even cause discomfort to the occupants. Note that this problem occurs not only when the thermal index is the predicted average thermal sensation report but also when the thermal index is the standard new effective temperature.

The present invention was made to solve such problems, and its purpose is to provide an air conditioner and its control method that can reduce the possibility of causing discomfort to occupants. It is about providing.

The air conditioner according to the present invention includes a cold heat receiving section that receives cold heat based on a refrigerant supplied from the outside, and a blower that supplies cold air indoors by blowing air into the room via the cold heat receiving section that receives the cold heat. a calculation unit that calculates a thermal index value of at least one of the expected average thermal sensation report or the standard new effective temperature; and a control unit that controls the amount of air blown in the air blowing unit, and the control unit is configured to receive cold heat by the cold heat receiving unit when the value of the thermal index calculated by the calculation unit exceeds a predetermined value. When the temperature index value calculated by the calculating section changes from exceeding a predetermined value to being below a predetermined value, the cooling heat receiving section operates the air blowing section in a state where cold heat is not received. The air blower is operated.

The control method for an air conditioner according to the present invention includes a cold heat receiving section that receives cold heat based on a refrigerant supplied from the outside, and a cold heat receiving section that receives the cold heat to blow the cold air into the room. A method for controlling an air conditioner equipped with an air blowing unit that supplies air, the method comprising: calculating a value of a thermal index of at least one of an expected average thermal sensation report or a standard new effective temperature; a control step of controlling the reception of cold heat in the cold heat receiving section and the amount of air blown in the blowing section based on the value of the thermal index, and in the control step, the thermal index calculated in the calculation step If the value exceeds a predetermined value, the blowing section is operated in a state where the cold heat is received by the cold heat receiving section, and the value of the thermal index calculated in the calculation step changes from a state exceeding a predetermined value to a predetermined value or less. In this case, the air blowing section is operated in a state where the cold heat receiving section does not receive cold heat.

According to the present invention, it is possible to provide an air conditioner and a control method thereof that can reduce the possibility of causing discomfort to occupants.

1 is a configuration diagram showing an air conditioning system including an air conditioner according to the present embodiment. FIG. 1 is a configuration diagram showing an air conditioner according to the present embodiment. 7 is a flowchart showing air volume control according to a comparative example. 7 is a flowchart showing valve control according to a comparative example. FIG. 7 is a diagram showing control logic according to a comparative example. It is a flow chart which shows stop flag control of an air conditioner concerning this embodiment. 3 is a flowchart showing air volume control of the air conditioner according to the present embodiment. It is a flow chart showing valve control of an air conditioner concerning this embodiment. FIG. 3 is a diagram showing control logic according to the present embodiment.

Hereinafter, the present invention will be explained along with preferred embodiments. Note that the present invention is not limited to the embodiments shown below, and can be modified as appropriate without departing from the spirit of the present invention. In addition, in the embodiments described below, illustrations and explanations of some components are omitted, but details of omitted technologies will be provided within the scope of not contradicting the content explained below. It goes without saying that publicly known or well-known techniques are applied as appropriate.

FIG. 1 is a configuration diagram showing an air conditioning system including an air conditioner according to this embodiment. As shown in FIG. 1, the air conditioning system 1 includes a plurality of air conditioners 10, an absorption chiller 20, a refrigerant outgoing pipe (refrigerant pipe) 11a, and a refrigerant return pipe (refrigerant pipe) 11b. There is.

Each of the plurality of air conditioners 10 air-conditions each room, and in this embodiment, performs a cooling operation that supplies cold air to the room. The absorption refrigerator 20 includes a regenerator, a condenser, an evaporator, and an absorber (not shown), and cools the refrigerant through a refrigeration cycle of the regenerator, condenser, evaporator, and absorber.

The refrigerant going pipe 11a and the refrigerant return pipe 11b are pipes that connect the plurality of air conditioners 10 and the absorption refrigerator 20. The refrigerant cooled by the absorption chiller 20 is supplied to each air conditioner 10 through the refrigerant outgoing pipe 11a, and after being used for cooling, returns to the absorption chiller 20 through the refrigerant return pipe 11b to be cooled again. .

A refrigerant valve V is provided in the refrigerant outgoing pipe 11a. One refrigerant valve V is provided for each air conditioner 10. Note that the refrigerant valve V may be provided not only in the refrigerant outgoing pipe 11a but also in the refrigerant return pipe 11b.

FIG. 2 is a configuration diagram showing the air conditioner 10 according to this embodiment. In addition to the refrigerant valve V shown in FIG. 1, the air conditioner 10 includes, as shown in FIG. It includes a sensor H, a camera 13, a calculation section 14, and a control section 15.

The heat exchanger 11 receives cold heat from the refrigerant supplied through the refrigerant pipe 11a. The heat exchanger 11 includes, for example, pipes connected to a refrigerant outgoing pipe 11a and a refrigerant return pipe 11b, and a large number of aluminum fins.

As described above, the refrigerant valve V is provided on the refrigerant outgoing pipe 11a, and is controlled to open and close by the control unit 15. When the refrigerant valve V is opened by the control unit 15, the cooled refrigerant reaches the heat exchanger 11, and the heat exchanger 11 is in a state of receiving cold heat. On the other hand, when the refrigerant valve V is closed by the control unit 15, the cooled refrigerant does not reach the heat exchanger 11, and the heat exchanger 11 is in a state of not receiving cold heat.

The blower fan 12 blows air into the room via the heat exchanger 11. Therefore, when the blower fan 12 is driven while the heat exchanger 11 is receiving cold heat, cold air is supplied indoors. On the other hand, when the blower fan 12 is driven in a state where the heat exchanger 11 is not receiving cold heat, wind is simply sent into the room (air is blown).

The temperature sensor T is for detecting the indoor temperature, and outputs a signal according to the indoor temperature to the control unit 15. The humidity sensor H is for detecting indoor humidity, and outputs a signal corresponding to the indoor humidity to the control unit 15. The camera 13 is, for example, a thermo camera for measuring the temperature of the wall surface of a living room, and outputs a signal of a temperature map image to the control unit 15.

The calculation unit 14 calculates the value of the predicted average thermal sensation report in the room. The expected average thermal sensation report is calculated based on six thermal elements (temperature, humidity, air velocity, heat radiation, metabolic rate, and amount of clothing). The calculation unit 14 according to the present embodiment calculates the temperature from the signal (temperature) from the temperature sensor T, the signal (humidity) from the humidity sensor H, the image signal (thermal radiation) from the camera 13, and the air blowing state by the blower fan 12. The predicted average thermal sensation report value is calculated based on the airflow velocity (described later). In this case, the calculation unit 14 uses fixed values for the metabolic rate and the amount of clothing to calculate the expected average thermal sensation declaration value, but the metabolic rate and the amount of clothing are not limited to fixed values. For example, the metabolic rate may be determined by detecting the skin temperature of a person present in the room using the camera 13, or the amount of clothing may be determined from an image captured by the camera 13 or seasonal information. In addition, if there is no problem with control, for example, the calculation unit 14 calculates the expected average thermal sensation report value based on the detected values of the three elements of temperature, humidity, and air velocity and the fixed values of the remaining three elements. may be equal.

The control unit 15 controls the reception of cold energy in the heat exchanger 11 (opening and closing of the refrigerant valve V) and the amount of air blown by the ventilation fan 12 based on the predicted average thermal sensation report value calculated by the calculation unit 14. It is something to do. To explain in more detail, the air conditioner 10 according to the present embodiment is capable of inputting a target value (predetermined value) of the expected average thermal sensation report that is preferred by the occupant in the room. The control unit 15 controls the reception of cold energy and the amount of air blown based on the difference between the calculated predicted average thermal sensation report value and the target value.

Further, the air conditioner 10 includes a human sensor (judgment means) S and a storage section 16. The human sensor S is for determining whether a person is present in the room, and for example, detects infrared rays from a living body and transmits a signal corresponding to this to the control unit 15. Note that the human sensor S is not limited to one that uses infrared rays, but may be one that detects a moving object using ultrasonic waves and determines that the moving object is a living body, for example.

The storage unit 16 provides various programs and work areas for controlling the air conditioner 10, and in this embodiment stores at least an operation schedule related to air conditioning. The operation schedule is, for example, such as starting the cooling operation at 8:00 a.m. from June to September and ending the cooling operation at 6:00 p.m. Further, the operation schedule may be such that cooling operation is not performed on holidays and public holidays.

Furthermore, the storage unit 16 stores information on the air flow velocity according to the air blowing state of the blower fan 12. Information on this airflow velocity can be obtained by installing a wind velocity sensor at a representative point, such as the center of the room, and operating the blower fan 12 at three levels of airflow (airflow status): "Low," "Middle," and "High." It is detected in each air blowing state. The storage unit 16 stores the air blowing states of "Low", "Middle", and "High" in association with the detected value by the wind speed sensor.

Here, the control unit 15 of the air conditioner 10 according to the present embodiment opens the refrigerant valve V to supply cold heat in the heat exchanger 11 when the predicted average thermal sensation report value exceeds the target value by the calculation unit 14. The air blowing fan 12 is operated in a receiving state. As a result, the air conditioner 10 brings the value of the expected average thermal sensation report closer to the target value, making the room comfortable.

On the other hand, the control unit 15 of the air conditioner 10 according to the present embodiment closes the refrigerant valve V when the predicted average thermal sensation report value changes from exceeding the target value to below the target value by the calculation unit 14. The heat exchanger 11 is brought into a state in which no cold heat is received, and the blower fan 12 is operated. That is, the air conditioner 10 does not stop the blower fan 12 even if the value of the predicted average thermal sensation report becomes less than the target value, and operates the blower fan 12 in a state where the heat exchanger 11 does not receive cold heat. As a result, the air conditioner 10 stops supplying cold air when the value of the predicted average thermal sensation report falls below the target value, but continues to blow air to prevent frequent fluctuations in the value of the predicted average thermal sensation report in the living room. I'm trying to keep it down.

Further, while performing the above control, if it is determined that there is no occupant in the room based on the signal from the human sensor S, the control unit 15 turns on the stop flag, closes the refrigerant valve V, and blows air. The operation of the fan 12 is stopped. That is, the air conditioner 10 not only stops supplying cold air but also stops blowing air when there is no occupant in the room. Note that it is preferable to provide a predetermined delay time before the blower fan 12 is stopped, assuming that the occupant temporarily leaves the room and returns relatively soon. Note that the delay time may not be provided.

Further, the control unit 15 turns on the stop flag during a time period in which the operation schedule stored in the storage unit 16 indicates a stop, closes the refrigerant valve V, and stops the operation of the blower fan 12. That is, the air conditioner 10 stops not only the supply of cold air but also the blowing of air when it is determined that there is no need for air conditioning based on the schedule such as on holidays.

Next, a method for controlling the air conditioner 10 according to the present embodiment will be described. Prior to this, a method for controlling the air conditioner according to a comparative example will be described. In the following description of the comparative example, components having the same or similar configurations as those of the present embodiment will be described with the same reference numerals as those shown in FIGS. 1 and 2.

FIG. 3 is a flowchart showing air volume control according to a comparative example. As shown in FIG. 3, the control unit 15 first determines that the difference between the predicted average thermal sensation report value (hereinafter referred to as PMV) calculated by the calculation unit 14 and the target value (hereinafter referred to as Pset) is a first specified value ( In the present embodiment and the comparative example, it is determined whether it exceeds 0.25) (S101).

When the difference between PMV and Pset exceeds the first specified value (S101: YES), the control unit 15 sets the air volume of the blower fan 12 to "High" (S102). Next, the control unit 15 determines whether the difference between PMV and Pset exceeds a second specified value (a value lower than the first specified value, which is 0.20 in the present embodiment and the comparative example) (S103). .

When the difference between PMV and Pset exceeds the second specified value (S103: YES), the control unit 15 sets the air volume of the blower fan 12 to "High" (S102). That is, the air volume of the blower fan 12 is maintained at "High". On the other hand, if the difference between PMV and Pset does not exceed the second specified value (S103: NO), that is, if the difference between PMV and Pset is less than or equal to the second specified value, the process moves to step S101.

If the difference between PMV and Pset does not exceed the first specified value (S101: NO), that is, if the difference between PMV and Pset is less than or equal to the first specified value, the control unit 15 controls the difference between PMV and Pset. It is determined whether the second specified value is exceeded (S104).

If the difference between PMV and Pset exceeds the second specified value (S104: YES), the control unit 15 sets the air volume of the blower fan 12 to "Middle" (S105). Next, the control unit 15 determines whether the difference between PMV and Pset exceeds a third specified value (a value lower than the second specified value, which is 0.15 in the present embodiment and the comparative example) (S106). .

If the difference between PMV and Pset exceeds the third specified value (S106: YES), the control unit 15 sets the air volume of the blower fan 12 to "Middle" (S105). That is, the air volume "Middle" of the blower fan 12 is maintained. On the other hand, if the difference between PMV and Pset does not exceed the third specified value (S106: NO), that is, if the difference between PMV and Pset is less than or equal to the third specified value, the process moves to step S101.

If the difference between PMV and Pset does not exceed the second specified value (S104: NO), that is, if the difference between PMV and Pset is less than or equal to the second specified value, the control unit 15 controls the difference between PMV and Pset. It is determined whether the third specified value is exceeded (S107).

When the difference between PMV and Pset exceeds the third specified value (S107: YES), the control unit 15 sets the air volume of the blower fan 12 to "Low" (S108). Next, the control unit 15 determines whether PMV exceeds Pset (S109).

When the PMV exceeds Pset (S109: YES), the control unit 15 sets the air volume of the blower fan 12 to "Low" (S108). That is, the air volume of the blower fan 12 is maintained at "Low". On the other hand, if PMV does not exceed Pset (S109: NO), that is, if PMV is less than or equal to Pset, the process moves to step S101.

If the difference between PMV and Pset does not exceed the third specified value (S107: NO), that is, if the difference between PMV and Pset is equal to or less than the third specified value, the control unit 15 sets the air volume of the blower fan 12 to " Off” (S110). After that, FIG. 3 ends.

FIG. 4 is a flowchart showing valve control according to a comparative example. As shown in FIG. 4, the control unit 15 first determines whether the difference between PMV and Pset exceeds a third specified value (S111).

When the difference between PMV and Pset exceeds the third specified value (S111: YES), the control unit 15 turns the refrigerant valve V "On (open)" (S112). After that, the process moves to step S113. On the other hand, if the difference between PMV and Pset does not exceed the third specified value (S111: NO), that is, if the difference between PMV and Pset is less than or equal to the third specified value, the process moves to step S113.

In step S113, the control unit 15 determines whether PMV exceeds Pset (S113). If PMV exceeds Pset (S113: YES), the process shown in FIG. 4 ends. On the other hand, if the PMV does not exceed Pset (S113: NO), that is, if the PMV is less than or equal to Pset, the control unit 15 turns the refrigerant valve V "Off" (S114). Thereafter, the process shown in FIG. 4 ends.

FIG. 5 is a diagram showing control logic according to a comparative example. The processing shown in FIGS. 3 and 4 described above can be summarized as shown in FIG. 5. First, assume that the above difference exceeds the first specified value (0.25). In this case, the air conditioner 10 supplies cold air indoors at a high air volume. When the difference becomes equal to or less than the second specified value (0.20) from this state, the air conditioner 10 supplies cold air into the room at the air volume "Middle". Further, when the difference becomes equal to or less than the third specified value (0.15) from this state, the air conditioner 10 supplies cold air into the room at a low air volume.

Further, suppose that the difference becomes 0 or less from a state in which cold air is being supplied at an air volume of "Low". In this case, the air volume of the air conditioner 10 is set to "Off". Note that in this state, the refrigerant valve V will be closed.

Thereafter, the difference increases due to the stoppage of the air conditioner 10, but the air conditioner 10 maintains the air volume "Off" state until the difference exceeds the third specified value. Then, when the difference exceeds the third specified value, the refrigerant valve V is opened, and the air conditioner 10 supplies cold air into the room at a low air volume.

Then, when the difference exceeds the second specified value, the air conditioner 10 supplies cold air indoors at the air volume "Middle", and when the difference exceeds the first specified value, it supplies cold air indoors at the air volume "High".

Next, a method of controlling the air conditioner 10 according to this embodiment will be explained. FIG. 6 is a flowchart showing stop flag control of the air conditioner 10 according to the present embodiment. As shown in FIG. 6, the control unit 15 determines whether the current time is an operating time period based on the driving schedule (S1). If the current time is not the operating time zone (S1: NO), the control unit 15 turns on the stop flag (S2). Then, the process shown in FIG. 6 ends.

On the other hand, if the current time is a working time zone (S1: YES), the control unit 15 determines whether there is a person in the room based on the signal from the human sensor S (S3). If there is no occupant in the room (S3: NO), the control unit 15 determines whether the state in which there is no occupant continues for a predetermined period of time (S4). If the state in which no one is present in the room continues for a predetermined period of time (S4: NO), the process moves to step S3. If the state in which no one is present continues for a predetermined period of time (S4: YES), the control unit 15 turns on the stop flag (S2). Then, the process shown in FIG. 6 ends.

If there is a person in the room (S3: YES), the control unit 15 turns off the stop flag (S5), and the process shown in FIG. 6 ends.

FIG. 7 is a flowchart showing air volume control of the air conditioner 10 according to the present embodiment. First, as shown in FIG. 7, the control unit 15 determines whether the stop flag is on (S11). If the stop flag is on (S11: YES), the control unit 15 turns off the air volume of the blower fan 12 (S12), and the process moves to step S11.

If the stop flag is not on (S11: NO), the control unit 15 determines whether the difference between PMV and Pset exceeds the first specified value (S13). When the difference between PMV and Pset exceeds the first specified value (S13: YES), the control unit 15 sets the air volume of the blower fan 12 to "High" (S14). Next, the control unit 15 determines whether the difference between PMV and Pset exceeds the second specified value (S15).

If the difference between PMV and Pset exceeds the second specified value (S15: YES), the control unit 15 determines whether the stop flag is on (S16). If the stop flag is on (S16: YES), the control unit 15 turns off the air volume of the blower fan 12 (S12), and the process moves to step S11.

If the stop flag is not on (S16: NO), the control unit 15 sets the air volume of the blower fan 12 to "High" (S14). That is, the air volume of the blower fan 12 is maintained at "High". On the other hand, if the difference between PMV and Pset does not exceed the second specified value (S15: NO), that is, if the difference between PMV and Pset is less than or equal to the second specified value, the process moves to step S11.

If the difference between PMV and Pset does not exceed the first specified value (S13: NO), that is, if the difference between PMV and Pset is less than or equal to the first specified value, the control unit 15 determines that the difference between PMV and Pset is It is determined whether the second specified value is exceeded (S17).

If the difference between PMV and Pset exceeds the second specified value (S17: YES), the control unit 15 sets the air volume of the blower fan 12 to "Middle" (S18). Next, the control unit 15 determines whether the difference between PMV and Pset exceeds a third specified value (S19).

If the difference between PMV and Pset exceeds the third specified value (S19: YES), the control unit 15 determines whether the stop flag is on (S20). If the stop flag is on (S20: YES), the control unit 15 turns off the air volume of the blower fan 12 (S12), and the process moves to step S11.

If the stop flag is not on (S20: NO), the control unit 15 sets the air volume of the blower fan 12 to "Middle" (S18). That is, the air volume "Middle" of the blower fan 12 is maintained. On the other hand, if the difference between PMV and Pset does not exceed the third specified value (S19: NO), that is, if the difference between PMV and Pset is equal to or less than the third specified value, the process moves to step S11.

If the difference between PMV and Pset does not exceed the second specified value (S17: NO), that is, if the difference between PMV and Pset is less than or equal to the second specified value, the control unit 15 sets the air volume of the blower fan 12 to " Low” (S21). After that, the process shown in FIG. 7 ends.

FIG. 8 is a flowchart showing valve control of the air conditioner 10 according to this embodiment. As shown in FIG. 8, the control unit 15 first determines whether the stop flag is on (S31). When the stop flag is in the on state (S31: YES), the control unit 15 turns the refrigerant valve V "Off (closed)" (S32). Thereafter, the process shown in FIG. 8 ends.

On the other hand, if the stop flag is not on (S31: NO), the control unit 15 determines whether the difference between PMV and Pset exceeds the third specified value (S33). When the difference between PMV and Pset exceeds the third specified value (S33: YES), the control unit 15 turns the refrigerant valve V "On (open)" (S34). After that, the process moves to step S35. On the other hand, if the difference between PMV and Pset does not exceed the third specified value (S33: NO), that is, if the difference between PMV and Pset is equal to or less than the third specified value, the process moves to step S35.

In step S35, the control unit 15 determines whether PMV exceeds Pset (S35). If PMV exceeds Pset (S35: YES), the process shown in FIG. 8 ends. On the other hand, if the PMV does not exceed Pset (S35: NO), that is, if the PMV is less than or equal to Pset, the control unit 15 turns the refrigerant valve V "Off" (blocked) (S32). Thereafter, the process shown in FIG. 8 ends.

FIG. 9 is a diagram showing the control logic according to this embodiment. The processing shown in FIGS. 6 to 8 described above can be summarized as shown in FIG. 9. First, when the difference decreases from the first specified value (0.25) to the third specified value (0.15), it is the same as the case described with reference to FIG. Cool air is supplied indoors at an air volume of "High," an air volume of "Middle," and an air volume of "Low."

Further, suppose that the difference becomes 0 or less from a state in which cold air is being supplied at an air volume of "Low". In this case, the air conditioner 10 maintains the air volume "Low" without turning the air volume "Off". On the other hand, the control unit 15 closes the refrigerant valve V. Therefore, the air conditioner 10 blows air into the room at a low air volume.

In this state, the refrigerant valve V is not opened until the difference exceeds the third specified value. Therefore, even if the difference becomes 0.10 or the like from this state, the air conditioner 10 will blow air into the room at a low air volume.

Thereafter, when the difference exceeds the third specified value, the refrigerant valve V is opened, and the air conditioner 10 supplies cold air into the room at a low air volume. Then, when the difference exceeds the second specified value (0.20), the air conditioner 10 supplies cold air indoors at the air volume "Middle", and when the difference exceeds the first specified value, it supplies cold air indoors at the air volume "High". I will do it.

Note that in any case, if the stop flag is in the on state, the control unit 15 turns the air volume "off" and closes the refrigerant valve V.

In this way, according to the air conditioner 10 and its control method according to the present embodiment, when the PMV exceeds Pset, the blower fan 12 is operated while receiving cold heat from the heat exchanger 11, so that the PMV is set to Pset. can be approached. Furthermore, when the PMV is less than or equal to Pset, the blower fan 12 is operated without receiving cold heat from the heat exchanger 11. Therefore, even if the PMV reaches Pset, the air blowing itself will continue without being stopped. Therefore, the possibility that the air conditioner 10 repeatedly blows and stops air, causing fluctuations in PMV, does not occur frequently, and that the occupants feel uncomfortable can be reduced.

In addition, the air conditioner 10 receives cold heat from the refrigerant from the absorption chiller 20, and is brought into a state of receiving cold heat by opening the refrigerant valve V provided in the refrigerant pipe 11a, and closes the refrigerant valve V. By doing so, it is in a state where it does not receive cold or heat. Therefore, the state of the heat exchanger 11 can be controlled by opening and closing the refrigerant valve V.

Further, when it is determined that there is no occupant in the room based on the signal from the human sensor S, the operation of the ventilation fan 12 is stopped. Therefore, the operation of the blower fan 12 is stopped when there is no object to which the airflow is stopped, causing discomfort, and the blower fan 12 can be stopped at an appropriate timing.

In addition, since the operation of the ventilation fan 12 is stopped during a time period in which the operation schedule indicates that the operation is stopped, if it is inefficient to operate the ventilation fan 12, such as on a holiday in an office, the ventilation is not dependent on the PMV. The operation of the fan 12 is stopped, and inefficient air conditioning can be prevented.

Although the present invention has been described above based on the embodiments, the present invention is not limited to the above embodiments, and may be modified without departing from the spirit of the present invention, or may be modified as appropriate to the extent possible. You can also combine these techniques. Furthermore, known or well-known techniques may be combined to the extent possible.

For example, in the above embodiment, the air conditioner 10 is configured to receive refrigerant from the absorption refrigerator 20, but it is not limited to the absorption refrigerator 20, and may receive refrigerant from other equipment such as a gas heat pump. . Furthermore, the air conditioner 10 may be configured to receive refrigerant from an absorption chiller/heater that includes the function of the absorption chiller 20.

Furthermore, the process shown in the embodiment described above (the process shown in FIGS. 6 to 8) may be installed in the air conditioner 10 as one mode of the air conditioner 10. For this reason, for example, the air conditioner 10 controls the refrigerant valve V and the blower fan 12 based on the indoor temperature, and also executes the processes shown in FIGS. 6 to 8 when a specific operation mode is selected. It may be.

Further, the air conditioner 10 according to the present embodiment determines the presence or absence of a person in the room based on the signal from the human sensor S, but is not limited to the signal from the human sensor S, for example, an image captured by a camera. The presence or absence of a person in the room may be determined based on , or the presence or absence of a person in the room may be determined based on information from an entry/exit management system that manages entry and exit from the room.

In addition, in this embodiment, whether or not to receive cold heat is controlled by opening and closing the refrigerant valve V, but for example, by turning on and off the equipment that can generate cold heat, such as starting or stopping the outdoor unit. You may also do so. Further, although the refrigerant valve V has been described using a two-way valve as an example, it may be configured as a three-way valve that can be connected to the refrigerant outgoing pipe 11a and the refrigerant return pipe 11b while bypassing the air conditioner 10. It's okay.

In addition, in the present embodiment, the calculation unit 14 may calculate an expected average thermal sensation report by using fixed values for metabolic rate and amount of clothing, or may use fixed values for three elements other than temperature, humidity, and airflow velocity. Although an example has been described in which an expected average thermal sensation report is calculated using the above-mentioned method, the present invention is not limited to this example. ), the remaining thermal elements may have variable values or fixed values.

Further, in the above embodiments, the air velocity information is a value detected by a wind velocity sensor at a representative point in the room, but the invention is not limited to this, and an average value of a plurality of points may be adopted. . Furthermore, if possible, the airflow velocity can be measured in advance at multiple points in the room, the position of the occupant can be determined using a motion sensor S, etc., and the airflow velocity at that position can be used. Good too. Further, the airflow velocity at the location of the occupant may be calculated by calculation. Moreover, although the ventilation fan 12 operates in three stages in the present embodiment, the fan 12 is not limited to this and may operate in more stages.

In addition, in the above embodiment, the predicted average thermal sensation declaration is used as an example of the thermal index. However, if the contribution of air velocity tends to be relatively large, the thermal index is not limited to the predicted average thermal sensation declaration. A standard new effective temperature may be adopted.

1: Air conditioning system 10: Air conditioner 11: Heat exchanger (cold heat receiving section)
11a: Refrigerant going pipe (refrigerant pipe)
11b: Refrigerant return piping (refrigerant piping)
12: Ventilation fan (ventilation part)
13: Camera 14: Calculation unit 15: Control unit 16: Storage unit 20: Absorption chiller H: Humidity sensor S: Human sensor (determination means)
T: Temperature sensor V: Refrigerant valve

Claims (5)

a cold heat receiving unit that receives cold heat based on a refrigerant supplied from the outside;
an air blowing unit that supplies cold air indoors by blowing air into the room via the cold heat receiving unit that receives cold heat;
a calculation unit that calculates the value of a thermal index of at least one of the predicted average thermal sensation declaration or the standard new effective temperature;
a control unit that controls the reception of cold heat in the cold heat receiving unit and the amount of air blown in the air blowing unit based on the value of the thermal index calculated by the calculation unit,
When the value of the thermal index calculated by the calculation unit exceeds a predetermined value, the control unit operates the blowing unit in a state in which the cold heat reception unit receives cold heat, and the temperature index calculated by the calculation unit operates. An air conditioner characterized in that when the value of the index changes from a state exceeding a predetermined value to a predetermined value or less, the air blowing section is operated in a state in which the cold heat receiving section does not receive cold heat. The cold heat receiving unit receives cold heat by a refrigerant cooled in an absorption refrigerator,
The control unit may open a refrigerant valve provided in a refrigerant pipe that supplies refrigerant from the absorption chiller to the cold heat receiving unit when the value of the thermal index calculated by the calculation unit exceeds a predetermined value. According to claim 1, the refrigerant valve is set to a state in which cold heat is received, and when the value of the thermal index calculated by the calculation unit is less than or equal to a predetermined value, the refrigerant valve is closed to enter a state in which cold heat is not received. air conditioner. It further includes a determination means for determining whether there is a resident in the room,
The air conditioner according to claim 1 or 2, wherein the control unit stops the operation of the ventilation unit when determining that there is no occupant in the room based on the determination means. Device. It is further equipped with a storage unit that stores operation schedules related to air conditioning.
The air conditioner according to any one of claims 1 to 3, wherein the control unit stops the operation of the air blower during a time period in which the operation schedule stored in the storage unit indicates stoppage. Device. An air conditioner comprising a cold heat receiving section that receives cold heat based on a refrigerant supplied from the outside, and a blowing section that supplies cold air indoors by blowing the cold air into the room via the cold heat receiving section that has received the cold heat. A control method,
a calculation step of calculating the value of a thermal index of at least one of the predicted average thermal sensation declaration or the standard new effective temperature;
a control step of controlling the reception of cold heat in the cold heat receiving section and the amount of air blown in the blowing section based on the value of the thermal index calculated in the calculation step,
In the control step, when the value of the thermal index calculated in the calculation step exceeds a predetermined value, the blowing section is operated in a state in which the cold heat receiving section receives cold heat, and the temperature index calculated in the calculation step is operated. A method for controlling an air conditioner, characterized in that when the value of the index changes from exceeding a predetermined value to being below a predetermined value, the air blowing section is operated in a state in which the cold heat receiving section does not receive cold heat.

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