JP2014142098A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce power consumption and maintain comfort in relation to an air conditioner, particularly to a thermo-off operation thereof.SOLUTION: An air conditioner includes: an indoor unit; an outdoor unit; a control unit that performs a thermo-off operation for stopping a compressor if a temperature of indoor air falls below a predetermined value during a cooling operation; and an air-conditioning-load sensing unit sensing an air conditioning load. The control unit has a normal mode for terminating thermo-off when a room temperature reaches a thermo-on temperature, and a thermo-off-time extension mode for making longer a thermo-off duration than that of the normal mode in response to the air conditioning load sensed by the air-conditioning-load sensing unit. In the thermo-off-time extension mode, the thermo-off continues for time of a thermo-off-time extension shift value since the room temperature during the thermo-off reaches a thermo-on condition.

Description

  The present invention relates to an air conditioner.

  For air conditioners that perform air conditioning such as cooling and heating, the compressor operation is stopped when the room temperature reaches a preset temperature set by the occupant, and indoor ventilation is minimized. It is often equipped with a thermo-off control. Further, the thermo-on control for restarting the operation of the compressor when the room temperature reaches a predetermined temperature due to the air conditioning load during the thermo-off is mounted together with the thermo-off control.

  As background art in this technical field, there is JP-A-10-185283 (Patent Document 1). In this publication, “When the operation is stopped by an air conditioner switching timer (nighttime timer) or the like, the room temperature detector 13b corrects the current room temperature set value according to the detected outside air temperature in the outside air temperature detector 11a, and sets the new room temperature. In this case, the on / off state is determined by the compressor on / off determination unit 11c, the off ratio is calculated by the compressor off ratio calculation unit 11d, and these are transferred to the indoor unit control unit 13 by the transfer unit 11e. When the ratio exceeds a predetermined value, the power relay that supplies AC power to the outdoor unit control unit 11 is turned off, the indoor fan is stopped at the same time, the timer counter unit 13a is started, and the room temperature after the predetermined time has reached the predetermined value "If the room temperature has not reached the predetermined value, start again and proceed, and if it has reached, turn on the power relay." .

  Japanese Patent Laid-Open No. 2004-144323 (Patent Document 2) is available. In this publication, “the air conditioner includes an indoor heat exchanger, a compressor, and a controller. The indoor heat exchanger exchanges heat between the refrigerant and the indoor air, The control section performs a thermo-off operation to stop the compressor when the indoor air temperature falls below a predetermined lower limit value, and the control section monitors the rise in the indoor air temperature after the thermo-off operation. In addition, the controller detects or estimates an increase in the relative humidity of the room air after the thermo-off operation, and the control unit restarts the compressor based on both conditions of the temperature increase and the relative humidity increase. “Thermo-on operation to be started is performed.”

JP 10-185283 A JP2004-144323

  Patent Document 1 is intended to control the room temperature for the purpose of maintaining comfort even after the occupants set the operation stop. That is, the power consumption when the control of Patent Document 1 is used for a long time is larger than the power consumption at the time of operation stop set by the occupant.

  Patent Document 2 attempts to perform a thermo-on operation for the purpose of maintaining comfort in accordance with the degree of increase in room temperature during thermo-off during cooling operation and the relative humidity in the room. That is, when the temperature rise is large during cooling operation and the relative humidity in the room is high, the thermo-off time is shortened. Compared with the power consumption when using the normal thermo-off control in which the thermo-off time is controlled only by room temperature for a long time, the power consumption when using the control of Patent Document 2 for a long time is greater. .

  The present invention relates to an air conditioner, and more particularly to a thermo-off operation, and reduces power consumption and maintains comfort.

  The present application includes a plurality of means for solving the above-described problems. For example, “the indoor unit, the outdoor unit, and the compressor is stopped when the temperature of the indoor air falls below a predetermined value during cooling operation. A control unit that performs a thermo-off operation and an air-conditioning load sensing unit that senses an air-conditioning load. The control unit senses the normal mode in which the thermo-off ends when the room temperature reaches the thermo-on temperature, and the air-conditioning load sensing unit. There is a thermo-off time extension mode that extends the duration of thermo-off longer than the normal mode according to the air conditioning load, and the thermo-off time extension mode is only for the time of the shift value for extending the thermo-off time after reaching the condition that the room temperature at thermo-off is thermo-on It is characterized by "continuing thermo-off".

  The present invention relates to an air conditioner, and more particularly to a thermo-off operation, and reduces power consumption and maintains comfort.

It is an example of the front view of an indoor unit, an outdoor unit, and a remote control. It is an example of the side sectional view of an indoor unit. It is an example of the left view of an outdoor unit. It is an example of a block diagram which shows the structure of an air-conditioning load sensing part and a control part. It is an example of the block diagram which shows the structure containing a human sensor. It is an example of a lens. It is an example of the flowchart which a human sensor estimates the number of people in a room, a position, and an active mass. It is an example of the flowchart in which a human sensor detects a human body. It is an example of the flowchart in which a human sensor detects a face. It is an example of the flowchart in which a human sensor detects the movement amount. It is an example of the process image which a human sensor detects a human body and a face. It is an example of the process image which a human sensor detects a human body and a face. It is an example of the figure in which a human sensor converts activity amount from movement amount. It is an example of the time-dependent change of room temperature of normal mode and ON / OFF of a compressor. It is an example of the time-dependent change of room temperature of a thermo-off time extension mode, and ON / OFF of a compressor.

  Hereinafter, examples will be described with reference to the drawings.

  A first embodiment will be described. In the present embodiment, an indoor unit, an outdoor unit, a control unit that performs a thermo-off operation that stops the compressor when the temperature of the indoor air falls below a predetermined value during cooling operation, and an air conditioning load sensing unit that senses an air conditioning load The control unit has a normal mode that ends the thermo-off when the room temperature reaches the thermo-on temperature, and a thermo-off time extension that extends the duration of the thermo-off longer than the normal mode according to the air-conditioning load sensed by the air-conditioning load sensing unit An example of an air conditioner having a mode, wherein the thermo-off time extension mode continues the thermo-off only for the time of the shift value for extending the thermo-off time after the room temperature at the time of the thermo-off reaches the condition that the thermo-on is reached. .

<Configuration of air conditioner>
<Overall>
FIG. 1 is a front view of an indoor unit, an outdoor unit, and a remote controller of an air conditioner according to the present embodiment. As shown in FIG. 1, the air conditioner includes an indoor unit, an outdoor unit, and a remote controller. The indoor unit and the outdoor unit are connected by a refrigerant pipe and air-condition the room where the indoor unit is installed by a known refrigerant cycle. The indoor unit and the outdoor unit transmit and receive information to and from each other via a communication cable (not shown).

  The remote controller is operated by the user and transmits an infrared signal to the remote control receiver of the indoor unit. The contents of the signal are commands such as an operation request, a change in set temperature, a timer, an operation mode change, and a stop request. Based on these signals, the air conditioner performs air conditioning operations such as a cooling mode, a heating mode, and a dehumidifying mode.

<Indoor unit>
FIG. 2 is a side sectional view of the indoor unit. The housing base accommodates internal structures such as a heat exchanger, a blower fan, electrical components, and various sensors.

  The heat exchanger has a plurality of heat transfer tubes, and is configured to heat or cool the air taken into the indoor unit by the blower fan with a refrigerant flowing through the heat transfer tubes. . The heat transfer tube communicates with the above-described refrigerant pipe (not shown) and constitutes a part of a known refrigerant cycle (not shown).

  The left and right wind direction plates are rotated by a left and right wind direction plate motor (not shown) using a rotation shaft (not shown) provided at the lower portion as a fulcrum according to an instruction from an indoor unit microcomputer (not shown).

  The vertical wind direction plate is rotated by a vertical wind direction plate motor (not shown) using pivot shafts (not shown) provided at both ends as fulcrums according to instructions from the indoor unit microcomputer.

  The front panel is installed so as to cover the front surface of the indoor unit, and is configured to be rotatable by a front panel motor (not shown) with the lower end as an axis. Incidentally, you may comprise a front panel as what is fixed to a lower end.

  When the blower fan shown in FIG. 2 rotates, the room air is taken in through the air suction port and the filter, and the air heat-exchanged by the heat exchanger is guided to the blowing air path. Further, the air guided to the blowing air passage is adjusted in air direction by the left and right wind direction plates and the upper and lower air direction plates, and is sent to the outside from the air blowing port to air-condition the room.

  Various sensors in the indoor unit include a room temperature sensor that measures the temperature in the room, a humidity sensor that measures the humidity in the room, a human sensor that estimates the number, position, and amount of activity in the room, and an outside air temperature sensor that measures the outdoor temperature.

<Outdoor unit>
FIG. 3 is a plan view and a front view of the outdoor unit. The housing base accommodates internal structures such as a heat exchanger, a compressor, an electrical component, a blower fan, and various sensors.

  The heat exchanger has a plurality of heat transfer tubes, and is configured to take in air from the back side of the outdoor unit by a blower fan, exchange heat with a refrigerant flowing through the heat transfer tubes, and cool or heat the air. . The heat transfer tube communicates with the above-described refrigerant pipe (not shown) and constitutes a part of a known refrigerant cycle (not shown).

  Various sensors in the outdoor unit include an outside air temperature sensor that measures the outdoor temperature.

<Air conditioning load sensing unit>
FIG. 4 is a block diagram illustrating a configuration of the air conditioning load sensing unit.

  The air conditioning load sensing unit includes various sensors. Various sensors in the air conditioning load sensing unit include room temperature sensors that measure indoor temperature, humidity sensors that measure indoor humidity, human sensors that estimate the number, position, and amount of activity in the room, and outdoor temperature sensors that measure outdoor temperature. Including.

  The air conditioning load sensing unit outputs room temperature, humidity, the number of occupants, the position of occupants, and the amount of activity of occupants to the control unit as the indoor air conditioning load. The air conditioning load sensing unit outputs the outside air temperature as a load on the outdoor side to the control unit.

  FIG. 5 is a block diagram illustrating a configuration including a human sensor included in the air conditioner.

  The imaging means is, for example, a CCD (Charge Coupled Device) camera, and is installed at the lower part of the center of the front panel in the left-right direction as described above (see FIG. 1). Further, the imaging means is installed such that the optical axis of the lens (see FIG. 6) is directed downward by a predetermined angle with respect to the horizontal line, so that the room in which the indoor unit is installed can be appropriately imaged. Yes. The imaging means images the air-conditioned room over time and outputs the captured image as image information to the A / D converter. The A / D converter is an electronic circuit that converts image information input as an analog signal from the imaging unit into a digital signal and outputs the digital signal to the human body detection unit and the face detection unit of the control unit. An A / D converter may be built in the imaging means.

  The control unit performs overall control of the operation of the air conditioner in accordance with image information input from the imaging unit, command signals input from the remote controller, sensor signals input from various sensors (not shown), and the like.

  The recording unit includes, for example, a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. Then, the program recorded in the ROM is read out by a CPU (Central Processing Unit) of the control means, developed in the RAM, and executed.

  7 to 13 are diagrams in which the human sensor estimates the number, position, and amount of activity of people in the room.

  As shown in FIG. 4, the human sensor of the air conditioning load sensing unit includes a human body detection unit, a face detection unit, an integrated processing unit, a number of people calculation unit, a movement amount calculation unit, and an activity amount calculation unit. ing.

  The human body detection unit detects the human body including the head of the occupant at predetermined time intervals based on the image information input from the imaging unit, and records information related to the human body (hereinafter referred to as human body information). To store. Incidentally, “detecting a human body including a head” includes a case where the whole body including a head (head region), a shoulder (shoulder region), and a foot (foot region) is detected.

  Note that the processing of the human body detection unit is executed at a rough pixel interval as compared with the processing of the face detection unit described later.

  The face detection unit detects the face of the occupant every predetermined time based on the image information input from the imaging unit, and stores information related to the face (hereinafter referred to as face information) in the recording unit.

  In the following, a case will be described in which human body detection processing for detecting a human body with a coarse pixel interval and processing for detecting a face with a fine pixel interval are performed while being switched over time.

  The integrated processing unit switches the processing of the human body detection unit and the processing of the face detection unit over time and executes the human body detected by the human body detection unit and the face detected by the face detection unit. And is stored in the recording means.

  For example, when a human body is detected at a certain time and a face is detected at a time later than the time, it is necessary to determine whether or not the detected human body and the face belong to the same person. When the integrated processing unit determines that the detected human body and face belong to the same person, the integration processing unit associates each piece of image information with a labeling value that is identification information.

  The movement amount calculation unit associates with the labeling value based on the position and size of the human body detected by the human body detection unit or the temporal change of the position and size of the face detected by the face detection unit. Calculate the amount of movement of the occupants. Then, the movement amount calculation unit outputs the calculated movement amount to the activity amount calculation unit in association with the labeling value.

  The “movement amount” means a distance estimated that the occupant has moved within a predetermined time in the real world space.

  The activity amount calculation unit calculates the activity amount of the occupant based on the movement amount calculated by the movement amount calculation unit. Then, the activity amount calculation unit outputs the calculated activity amount to the correction value calculation unit in association with the labeling value described above.

The “activity amount” means a metabolic amount [W / m ² ] per unit surface area of the human body, and has a positive correlation with the amount of movement described above.

  In addition, although the air-conditioning load sensing part comprised by the room temperature sensor, the humidity sensor, the external temperature sensor, and the human sensor was demonstrated, the air-conditioning load sensing part should just be provided with at least one of these.

  Although the CCD camera has been described as an example of the imaging unit, the imaging unit may be a sensor such as a thermopile that can estimate the number, position, and amount of activity in the room, and an infrared sensor.

<Control unit>
FIG. 14 is a block diagram of the control unit.

  The control unit is disposed in the electrical equipment of the indoor unit and the outdoor unit. The control unit is connected to a compressor, an indoor fan motor, an outdoor fan motor, a four-way valve, an electric valve, and a remote control receiving unit, and performs these controls.

  In addition, the control unit is connected to the air conditioning load sensing unit. From the air conditioning load sensing unit, the indoor load and the outdoor load such as room temperature, humidity, number of people in the room, position of the room, activity amount of the room, outdoor temperature, etc. Is sent.

  Specifications for operating the air conditioner such as operation / stop, set room temperature, set humidity, set wind direction, and set wind speed are transmitted from the remote control to the control unit.

  The control unit controls the air conditioner according to the output from the air conditioning load sensing unit and the output from the remote control.

<Normal mode>
FIG. 14 shows changes over time in room temperature during cooling in the normal mode and ON / OFF of the compressor.

  In the normal mode at the time of cooling, the compressor is stopped and the thermo is turned off when the room temperature by the room temperature sensor becomes the following equation during the thermo on.

Room temperature T _IN ≤Set room temperature T _SET -ΔT _OFF formula (1)
Further, when the room temperature by the room temperature sensor becomes the following equation during the thermo-off, the compressor is started and the thermo-on is performed.

Room temperature T _IN ≥Set room temperature T _SET -ΔT _ON formula (2)
The left and right wind directions during the thermo-off are the same as the left and right wind directions during the thermo-on or the front direction.

  The vertical wind direction during the thermo-off is the same as or the horizontal direction as the vertical wind direction during the thermo-on.

  The wind speed of the blown air during the thermo-off is lower than the wind speed during the thermo-on.

<Thermo-off time extension mode>
FIG. 15 shows changes over time in room temperature during cooling and ON / OFF of the compressor in the thermo-off time extension mode.

  In the thermo-off time extension mode during cooling, the compressor is stopped when the room temperature by the room temperature sensor becomes the following equation during the thermo-on, and the thermo-off is performed.

Room temperature T _IN ≤Set room temperature T _SET -ΔT _OFF formula (1)
Up to this point, the control is the same as in the normal mode.

  When at least one of the following conditions is satisfied when the thermo is turned off, the thermo-off time extension mode is applied.

Outside temperature T _OUT ≤ Thermo-off time extension mode upper limit outside temperature T _C-LIMIT expression (3)
Humidity RH _IN ≤ Thermo-off time extension mode during cooling Upper limit humidity RH _C-LIMIT type (4)
When at least one of the above conditions is satisfied and the thermo-off time extension mode is applied, the thermo-off is continued for the time of the shift value for extending the thermo-off time after reaching the condition that the room temperature becomes thermo-on.

  On the other hand, when the above conditions are not satisfied at the time when the thermo is turned off, the normal mode is applied.

  Note that switching between the normal mode and the thermo-off time extension mode is set by the occupant from the remote control.

<Effect>
FIG. 14 shows the room temperature, the set room temperature, and the compressor ON / OFF during the cooling operation in the normal mode, and FIG. 15 in the thermo-off time extension mode.

  Immediately after the start of cooling operation, there is no difference in room temperature and compressor ON / OFF in normal mode and thermo-off time extension mode.

  As the operation continues, the room temperature decreases.

  When the room temperature, which continues to decrease, reaches the following equation, the thermostat is turned off and the compressor stops.

Room temperature T _IN ≤Set room temperature T _SET -ΔT _OFF formula (1)
There is a difference between the normal mode and the thermo-off time extension mode in the control after the thermo-off and the compressor stop.

  In the normal mode, the compressor is stopped, the room temperature rises, and when the room temperature becomes the following equation, the thermo-off ends and the thermo-on is performed.

Room temperature T _IN ≥Set room temperature T _SET -ΔT _ON formula (2)
In the normal mode, when the thermo-on and the thermo-off are repeated and the operation is continued for a long time, the average room temperature is a temperature in the vicinity of the room temperature between the thermo-off and the thermo-on.

  On the other hand, in the thermo-off time extension mode, the compressor is stopped, the room temperature rises, and after reaching the condition that the room temperature becomes thermo-on, the thermo-off is continued for the time of the shift value for extending the thermo-off time.

  In normal mode and thermo-off time extension mode, the room temperature for thermo-off is the same, but the room temperature for thermo-on is higher in thermo-off time extension mode because the thermo-off time is extended by the shift value for thermo-off time extension. .

  Since the temperature of the thermo-on is different, the following equation holds for the average room temperature when the operation is continued for a long time.

_Room temperature T _AVE ≦ Room temperature T _{AVE '} formula (5)
here,
_Room temperature T _AVE : Average room temperature when operation is continued for a long time in normal mode Room temperature T _{AVE '} : Average room temperature when operation is continued for a long time in extended thermo-off time mode Focusing on the average room temperature, the operation in the thermo-off time extension mode can obtain the same power consumption reduction effect as the operation in which the set room temperature is higher than that in the normal mode.

  As described above, the power consumption can be reduced as compared with the normal mode by the operation in the thermo-off time extension mode.

Up to this point, the cooling operation has been described. However, by replacing the equations (1) to (7) as follows, the same effect as the cooling operation can be obtained in the heating operation.
Formula (1) Room temperature T _IN ≧ Set room temperature T _SET + ΔT _OFF
Formula (2) Room temperature T _IN ≦ Set room temperature T _{SET +} ΔT _ON
Expression (3) Outside air temperature T _OUT ≧ Cooling off time extension mode upper limit outside air temperature T _C-LIMIT
Equation (4) Humidity RH _IN ≥ Thermo-off time extension mode during cooling Upper limit humidity RH _C-LIMIT
Formula (5) _Room temperature T _AVE ≧ Room temperature T _{AVE '}
Next, a second embodiment will be described. In this embodiment, an example of an air conditioner that can improve the comfort when the thermo-off is performed will be described. In addition, description is abbreviate | omitted about the structure same as the already demonstrated part.

<Control unit>
<Normal mode>
The left and right wind directions during the thermo-off are the same as the left and right wind directions during the thermo-on or the front direction.

  The vertical wind direction during the thermo-off is the same as or the horizontal direction as the vertical wind direction during the thermo-on.

<Thermo-off time extension mode>
The left and right wind directions during the thermo-off may be blown to a region including a position estimated by a human sensor to be present.

  The up-and-down wind direction during the thermo-off may be blown to an area including a position estimated by the human sensor to be present.

<Effect>
There are four main types of heat transfer paths between the human body and the surrounding environment: convection, radiation, evaporation, and conduction. Of these, conduction is the movement of heat in the area where the surrounding solid and the surface of the human body are touching, such as the floor or chair seat or back. The area related to conduction is as small as about 8% of the body surface area. Therefore, the heat transfer due to conduction is ignored here.

  Also, during cooling, the larger the amount of heat transferred from the human body to the surrounding environment, the cooler and more comfortable it feels. On the other hand, during heating, the smaller the amount of heat transferred from the human body to the surrounding environment, the warmer and more comfortable it feels.

The amount of heat transfer between the human body and the surrounding environment due to convection is expressed by the following equation.
Q _C = H _C (T _S -T _A ) A _C
here,
Q _C : Heat transfer between human body and surrounding environment due to convection [W]
H _C : Convective heat transfer coefficient [W / m ² K]
T _S : Human body surface temperature [K]
T _A : Air temperature around the human body [K]
A _C : Body surface area of human body related to convective heat transfer [m ² ]
The convective heat transfer coefficient increases as the air velocity increases.

The amount of heat transfer between the human body and the surrounding environment due to radiation is expressed by the following equation.
Q _R = H _R (T _S -T _R ) A _R
here,
Q _R : Amount of heat transfer between human body and surrounding environment due to radiation [W]
H _R : Radiative heat transfer coefficient [W / m2K]
T _S : Human body surface temperature [K]
T _R : Average radiation temperature [K]
A _R : Human body surface area related to radiant heat transfer [m ₂ ]

The amount of heat transfer between the human body and the surrounding environment due to evaporation is expressed by the following equation.
Q _E = H _E (P _S -P _A ) A _E
here,
Q _E : Heat transfer between human body and surrounding environment due to evaporation [W]
H _E : Heat transfer coefficient accompanying evaporation [W / m ² kPa]
P _S : Saturated water vapor pressure at skin temperature [kPa]
P _A : Water vapor partial pressure at room temperature [kPa]
A _E : Human body surface area related to heat transfer during evaporation [m ² ]
The heat transfer between the human body and the surrounding environment during the thermo-on can be classified as follows.

"Convection"
Increased heat transfer due to lower air temperature around the human body Increased heat transfer due to increased convective heat transfer coefficient due to increased air velocity around the human body "Radiation"
Increase in heat transfer due to decrease in average radiation temperature due to decrease in temperature of floors, walls, ceilings, etc.
Increase in heat transfer due to increase in evaporation due to decrease in saturated water vapor pressure at room temperature The air flow blown out at the time of thermo-off is an air flow at room temperature that is not heat-exchanged. Therefore, the air flow velocity around the occupant is increased by blowing air to the region including the position where the occupant is estimated to be present, and the convective heat transfer coefficient is increased accordingly. The amount of heat released by can be increased. That is, coolness can be obtained by blowing air to a region including a position where it is estimated that a room occupant is present even at room temperature without heat exchange.

"Convection"
Increase in heat dissipation due to convection due to increase in convective heat transfer rate due to increase in air velocity. Also, when the left and right wind direction during thermo-off blows to an area including a position where a person is estimated to be present by a human sensor As described above, the air may be blown by swinging to an area including a position estimated by a human sensor to be present.

  Moreover, although the case where the up-and-down wind direction during a thermo-off ventilates the area | region containing the position in which it was estimated that the occupant was estimated by the human sensor was demonstrated, the area | region including the position in which the occupant was estimated by the human sensor You may make it swing and blow.

  Next, a third embodiment will be described. In the present embodiment, an example of an air conditioner that can ensure comfort by changing the wind speed of the blown air in the thermo-off time extension mode according to room temperature and / or humidity and / or outside temperature will be described. In addition, description is abbreviate | omitted about the structure same as the already demonstrated part.

<Control unit>
<Normal mode>
The wind speed of the blown air during the thermo-off is constant.
<Thermo-off time extension mode>
The wind speed of the blown air during the thermo-off may be corrected by room temperature and / or humidity and / or outside air temperature. In this case, in both cooling and heating, correction is performed in such a direction that the higher the room temperature, the higher the humidity, and the higher the outside air temperature, the higher the wind speed.

  That is, in the thermo-off time extension mode, the wind speed of the blown air in the thermo-off time extension mode may be changed according to the room temperature. In this case, the higher the room temperature, the larger the wind speed is changed.

  Alternatively, in the thermo-off time extension mode, the wind speed of the blown air in the thermo-off time extension mode may be changed according to the humidity. In this case, the higher the humidity, the larger the wind speed is changed.

  Alternatively, in the thermo-off time extension mode, the wind speed of the blown air in the thermo-off time extension mode may be changed according to the outside air temperature. In this case, the air speed is changed to increase as the outside air temperature increases.

<Effect>
As the room temperature is higher, the heat radiation from the human body is reduced as follows.

"radiation"
The higher the room temperature, the higher the surface temperature of floors, walls, and ceilings. As a result, the average radiation temperature rises, and the heat radiation due to radiation decreases.

"Convection"
The higher the room temperature, the smaller the difference between the surface temperature of the human body and the room temperature, and the smaller the amount of heat transferred from the human body to the surrounding environment.

  On the other hand, when the wind speed increases, the convective heat transfer coefficient increases, and the amount of heat transferred from the human body to the surrounding environment increases.

  Thus, by changing the wind speed according to the room temperature, it is possible to achieve both reduction in power consumption and comfort.

  Moreover, the higher the humidity, the smaller the heat release due to evaporation as described below.

"evaporation"
The difference between the saturated water vapor pressure at the skin temperature and the water vapor partial pressure in the surrounding environment due to the increase in the water vapor partial pressure is reduced, and the amount of heat transferred from the human body to the surrounding environment due to evaporation is reduced.

  On the other hand, when the wind speed increases, the convective heat transfer coefficient increases, and the amount of heat transferred from the human body to the surrounding environment increases.

  Further, by increasing the wind speed as the outside air temperature is higher, the amount of heat released by convection increases during cooling as follows.

"radiation"
When the outside air temperature is high, the amount of heat transferred due to the flow into the room decreases, and the temperature of the ceiling, walls, and floor becomes closer to room temperature. That is, when the outside air temperature is high, the temperature of the indoor walls and the like is high, and the difference between the surface temperature of the human body and the average radiation temperature is small. Thereby, the amount of heat released by radiation decreases as the outside air temperature increases.

  Thus, by changing the wind speed according to the outside air temperature, it is possible to achieve both reduction in power consumption and comfort.

  Next, a fourth embodiment will be described. In this embodiment, an example of an air conditioner that can improve the comfort when the thermo-off is performed will be described. In addition, description is abbreviate | omitted about the structure same as the already demonstrated part.

<Control unit>
<Normal mode>
The wind speed of the blown air during the thermo-off is lower than the wind speed during the thermo-on.

<Thermo-off time extension mode>
The wind speed of the blown air during the thermo-off may be corrected according to the number of people in the room and / or the position and / or the amount of activity. In this case, the correction is performed in such a direction that the wind speed increases as the number of people increases, the position increases, the activity increases.

<Effect>
The human body feels cool and cold due to an increase in the amount of heat released from the human body.

  As the number of people in the room increases, the people in the room become heat sources for radiation by radiation as follows.

"radiation"
The occupants themselves become heat sources, the average radiation temperature rises, and the heat radiation due to radiation decreases.

  On the other hand, as the number of people in the room increases, the wind speed increases, and the amount of heat released by convection increases as follows. Even air flow at room temperature that is not heat-exchanged can obtain coolness by blowing more strongly as the number of people in the room increases.

"Convection"
Increase in heat dissipation due to convection due to increase in convective heat transfer rate due to increase in airflow velocity.In addition, the wind speed increased as the number of people in the room increases rather than continuously increased. It may be an increased wind speed.

  Moreover, the wind speed increased as the number of people in the room increases, may be increased periodically.

  Further, the wind speed that increases as the number of people in the room increases may fluctuate with a period of 1 / f and the wind speed.

  Next, a fifth embodiment will be described. In the present embodiment, an example of an air conditioner that can cope with the occupant's state will be described. In addition, description is abbreviate | omitted about the structure same as the already demonstrated part.

<Control unit>
The control unit may set a wind direction that is not directed toward the occupant when the thermo is off by setting from the remote controller.

<Effect>
By blowing air to the area including the position where it is estimated that the occupant is present when the thermo is off, the amount of heat released from the human body can be promoted and coolness can be obtained. However, there are cases where people who are reading books or newspapers, people who are working in precision, people who are cooking, etc. do not like being blown toward people in the room. .

  By setting from the remote controller, air can be blown outside the area including the position where the occupant is estimated to be present. At the time of cooling, by receiving an indirect air current that is reflected by hitting the surrounding ceiling, wall, or floor, it is possible to obtain coolness without receiving a direct air current from the indoor unit when the thermo is off. Further, during heating, the indoor unit serves as a circulator, and the warm air that has risen and stayed near the ceiling can be supplied again to the occupants.

  Next, a sixth embodiment will be described. In this embodiment, an example of an air conditioner that can ensure comfort by changing the thermo-off extension time in the thermo-off time extension mode according to the room temperature will be described. In addition, description is abbreviate | omitted about the structure same as the already demonstrated part.

<Thermo-off time extension mode>
In the case where the thermo-off is extended for a predetermined time from the time when the thermo-ON in the normal mode is reached in the thermo-off time extension mode, the extension time may be changed according to the room temperature. In this case, at the time of cooling, the extension time is changed to be shorter as the room temperature is higher. Also, in this case, during heating, the time to be extended is changed as the room temperature increases.

<Effect>
The greater the heat that flows from the outside to the room, the higher the surface temperature of the wall that separates the room from the outside. That is, the higher the outside air temperature, the higher the average radiation temperature, and the amount of heat released by radiation decreases as follows.

    The higher the room temperature, the less heat released by convection and radiation as follows.

"Convection"
Reduced heat dissipation due to the small temperature difference between the human body and the surrounding air "Radiation"
Decreasing the heat dissipation due to radiation from the human body due to the increase in the average radiation temperature.Therefore, when extending the thermo-off for a predetermined time from the time when the room temperature becomes the thermo-on in the normal mode in the thermo-off time extension mode during cooling, The longer the external temperature is, the shorter the extension time becomes, so that the room temperature after the thermo-off can be made constant. That is, it is possible to suppress an increase in discomfort due to the thermo-off by shortening the extension time as the outside air temperature is higher. In addition, when the thermo-off is extended for a predetermined time from the time when the thermo-off in the normal mode is reached in the thermo-off time extension mode during heating, the extension time becomes longer as the room temperature becomes higher. It becomes possible to make it constant.

  Next, a seventh embodiment will be described. In this embodiment, an example of an air conditioner that can ensure comfort by changing the thermo-off extension time in the thermo-off time extension mode according to the outside air temperature will be described. In addition, description is abbreviate | omitted about the structure same as the already demonstrated part.

<Thermo-off time extension mode>
In the thermo-off time extension mode, when the thermo-off is extended for a predetermined time from the time when the room becomes the thermo-on in the normal mode, the extension time may be changed according to the outside air temperature. In this case, at the time of cooling, the extension time is changed to be shorter as the outside air temperature is higher. Further, in this case, during heating, the extension time is changed to be longer as the outside air temperature is higher.

<Effect>
The greater the heat that flows from the outside to the room, the higher the surface temperature of the wall that separates the room from the outside. That is, the higher the outside air temperature, the higher the average radiation temperature, and the amount of heat released by radiation decreases as follows.

"radiation"
Reduced heat dissipation due to radiation from the human body due to higher average radiation temperature.Therefore, by reducing the shift value for extending the thermo-off time as the outside air temperature increases during cooling, power consumption is reduced and comfort is ensured. It can be compatible. Further, by increasing the thermo-off time extension shift value as the outside air temperature is higher during heating, it is possible to achieve both reduction of power consumption and ensuring comfort.

  Next, an eighth embodiment will be described. In the present embodiment, an example of an air conditioner that can ensure comfort by changing the thermo-off extension time in the thermo-off time extension mode according to the humidity in the room will be described. In addition, description is abbreviate | omitted about the structure same as the already demonstrated part.

<Thermo-off time extension mode>
In the thermo-off time extension mode, even if the thermo-off time extension shift value is changed according to the humidity in the room when the thermo-off is extended for a predetermined time from the time when the room temperature becomes the thermo-on in the normal mode in the thermo-off time extension mode. good. In this case, at the time of cooling, the extension time is changed to be shorter as the humidity is higher. In this case, the heating time is changed so that the extension time becomes shorter as the humidity is higher.

<Effect>
As the indoor humidity increases, the amount of heat transfer between the human body and the surrounding environment due to evaporation decreases as follows.

"evaporation"
Decrease in heat dissipation due to evaporation due to higher water vapor partial pressure as humidity increases.Therefore, during cooling, when the thermo-off is extended for a predetermined time from the time when the thermo-off in the normal mode is reached in the thermo-off time extension mode. By shortening the extension time as the humidity increases, it becomes possible to suppress an increase in discomfort due to a decrease in the amount of heat released by evaporation, and to achieve both reduction of power consumption and ensuring comfort it can. Also, during heating, when the thermo-off is extended for a predetermined time from the time when the thermo-off in the normal mode becomes the thermo-on in the thermo-off time extension mode, the amount of heat released by evaporation is increased by increasing the extension time as the humidity increases. It is possible to suppress an increase in discomfort due to the decrease in power consumption, and it is possible to achieve both reduction in power consumption and ensuring comfort.

  Next, a ninth embodiment will be described. In the present embodiment, an example of an air conditioner that can ensure comfort by changing the thermo-off extension time in the thermo-off time extension mode according to the number and / or position of the occupants and / or the amount of activity. explain. In addition, description is abbreviate | omitted about the structure same as the already demonstrated part.

<Thermo-off time extension mode>
In the thermo-off time extension mode, the shift value for extending the thermo-off time may be changed according to the number of people in the room. In this case, as the number of persons increases, the shift value for extending the thermo-off time is changed to be smaller.

  Alternatively, in the thermo-off time extension mode, the shift value for extending the thermo-off time may be changed according to the position of the occupant. In this case, the farther the position is, the smaller the thermo-off time extension shift value is changed.

Alternatively, in the thermo-off time extension mode, the shift value for extending the thermo-off time may be changed according to the amount of activity of the resident. In this case, the shift value for extending the thermo-off time is decreased as the activity amount increases.
<Effect>
As the number of occupants increases, the occupants become heat sources for radiation by radiation as follows.

"radiation"
The occupants themselves become heat sources, the average radiation temperature rises, and the heat radiation due to radiation decreases.

  On the other hand, as the number of people in the room increases, the shift value for extending the thermo-off time becomes smaller, so that the amount of heat released by convection increases as follows.

"Convection"
If the shift value for extending the thermo-off time is small, the extended time of the thermo-off time is shortened, and by increasing the thermo-on time for a longer time, the difference between the room temperature and the human body surface temperature due to the convection due to the decrease in the room temperature and the increase in the air velocity Increase in heat dissipation due to convection due to increase in convective heat transfer rate in this way As described above, by changing the shift value for extending the thermo-off time according to the number of people in the room, both reduction in power consumption and comfort are achieved. It becomes possible to do.

  Further, the farther the occupant is located, the lower the speed of wind supplied to the occupant, and the amount of heat released by convection decreases as follows.

"Convection"
Decrease in heat dissipation due to convection due to decrease in convective heat transfer rate due to decrease in airflow speed On the other hand, the shift value for extending the thermo-off time decreases as the occupant's position increases. Increase.

"Convection"
If the shift value for extending the thermo-off time is small, the extended time of the thermo-off time is shortened, and by increasing the thermo-on time for a longer time, the difference between the room temperature and the human body surface temperature due to the convection due to the decrease in the room temperature and the increase in the air velocity Increase in heat dissipation due to convection due to increase in convective heat transfer rate accompanying this change of the power consumption and comfort by changing the shift value for extending the thermo-off time according to the position of the occupant. It becomes possible to do.

Moreover, the greater the amount of activity of the occupants, the greater the amount of heat released from the human body, and the greater the indoor air conditioning load. In addition, based on the six elements of so-called thermal environment, the comfort of the occupants also decreases during cooling as follows.
Comfortable feeling = f (temperature, humidity, radiation temperature, air velocity, clothes, activity)
here,
Temperature: Higher comfort decreases lower Humidity: Higher comfort decreases Radiant temperature: Higher comfort decreases Airflow velocity: Higher comfort improves The amount of clothing: Higher comfort decreases : The higher the comfort level is, the lower the comfort level is. On the other hand, the greater the amount of activity of the occupant, the smaller the shift value for extending the thermo-off time.

"Convection"
If the shift value for extending the thermo-off time is small, the extended time of the thermo-off time is shortened, and by increasing the thermo-on time for a longer time, the difference between the room temperature and the human body surface temperature due to the convection due to the decrease in the room temperature and the increase in the air velocity Increase in heat dissipation due to convection due to increase in convective heat transfer coefficient in this way As described above, changing the shift value for extending the thermo-off time according to the amount of activity of the occupant reduces power consumption and comfort. It is possible to achieve both.

  Next, a tenth embodiment will be described. In the present embodiment, an example of an air conditioner in which the occupants themselves can set the degree of reduction in power consumption will be described. In addition, description is abbreviate | omitted about the structure same as the already demonstrated part.

<Control unit>
The control unit may set a reduction amount of power consumption in the thermo-off time extension mode from the remote controller.

<Effect>
Compared to the case where the occupant can set only ON / OFF of the thermo-off time extension mode by setting the amount of power consumption reduction in the thermo-off time extension mode by the occupant himself, the thermo-off time It becomes possible to accept the uncomfortable feeling caused by the extension of the That is, when the occupant can set only ON / OFF of the thermo-off time extension mode, the discomfort caused by extending the thermo-off time is the discomfort given from the air conditioner. On the other hand, the discomfort that occurs when the occupant himself sets the reduction amount of power consumption in the thermo-off time extension mode is the discomfort set by the occupant himself and can be accepted more convinced. Become.

  Next, an eleventh embodiment will be described. In the present embodiment, an example of an air conditioner capable of greatly reducing power consumption will be described. In addition, description is abbreviate | omitted about the structure same as the already demonstrated part.

<Thermo-off time extension mode>
The compressor may be stopped from the start to the end of the operation of the air conditioner in which the thermo-off time extension mode is set. That is, the thermo-off may be from the start of operation to the end of operation.

<Effect>
When the room temperature is lower than the set room temperature, the thermo is turned off at the start of operation. Even when the thermostat is off from the start of operation, it is possible to improve comfort by controlling the wind speed based on the air conditioning load by the air conditioning load sensing unit in the thermo-off time extension mode. Further, even when the thermostat is off from the start of operation, comfort can be greatly improved by controlling the wind speed and direction based on the air conditioning load.

  Furthermore, if the thermo-off time extension mode is set when the room temperature is higher than the set room temperature and the air-conditioning load is small, the thermo-off may occur until the operation is stopped. About 90% of the power consumption of the air conditioner is due to the operation of the compressor, and in the case of thermo-off from the start of operation to the end of operation, about 90% of the power consumption compared to the cooling operation that operates the compressor Can be reduced.

  In addition, this invention is not limited to an above-described Example, Various modifications are included.

  For example, the above-described embodiments have been described in detail for easy understanding of the present invention, and are not necessarily limited to those having all the configurations described. Further, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of one embodiment. Further, it is possible to add, delete, and replace other configurations for a part of the configuration of each embodiment.

  In addition, each of the above-described configurations, functions, processing units, and processing procedures may be realized by hardware, for example, by designing a part or all of them with an integrated circuit. Each of the above-described configurations, functions, and the like may be realized by software by interpreting and executing a program that realizes each function by the processor. Information such as programs, tables, and files that realize each function can be stored in a recording device such as a memory, a hard disk, or an SSD (Solid State Drive), or a recording medium such as an IC card, an SD card, or a DVD.

  Further, the control lines and information lines indicate objects that are considered necessary for the explanation, and not all control lines and information lines on the product are necessarily shown. Actually, it may be considered that almost all the components are connected to each other.

1 ... Indoor unit

Claims (15)

Indoor unit,
Outdoor unit,
A control unit that performs a thermo-off operation to stop the compressor when the temperature of the indoor air falls below a predetermined value during cooling operation;
An air conditioning load sensing unit for sensing the air conditioning load;
With
The control unit
Normal mode to end the thermo-off when the room temperature reaches the thermo-on temperature,
It has a thermo-off time extension mode that makes the thermo-off duration longer than the normal mode according to the air-conditioning load sensed by the air-conditioning load sensing unit,
The air conditioner is characterized in that in the thermo-off time extension mode, the thermo-off is continued for the time of the shift value for extending the thermo-off time after the room temperature at the time of the thermo-off reaches the condition that the thermo is turned on. The air conditioner according to claim 1,
The air conditioning load sensing unit
It is equipped with a room temperature sensor, humidity sensor, outside air temperature sensor and human sensor,
An air conditioner characterized in that the human sensor measures at least one of the number, position, and activity of people in the room. The air conditioner according to claim 1 or 2,
The air conditioner is characterized in that the thermo-off time extension mode is executed only when the condition of “outside temperature ≦ thermo-off time extension mode upper limit outside temperature” is satisfied. The air conditioner according to any one of claims 1 to 3,
The thermo-off time extension mode is executed only when the condition of “humidity ≦ thermo-off time extension mode upper limit humidity” is satisfied. The air conditioner according to any one of claims 2 to 4,
An air conditioner that blows air to a region including a position where the direction of the blown air in the thermo-off time extension mode is estimated to be present by a human sensor. The air conditioner according to any one of claims 2 to 5,
An air conditioner characterized in that the wind speed of the blown air during the thermo-off time extension mode is corrected according to the room temperature. The air conditioner according to any one of claims 2 to 6,
An air conditioner characterized in that the wind speed of blown air during the thermo-off time extension mode is corrected according to humidity. The air conditioner according to any one of claims 2 to 7,
An air conditioner characterized in that the wind speed of the blown air during the thermo-off time extension mode is corrected according to the outside air temperature. The air conditioner according to any one of claims 2 to 8,
An air conditioner characterized in that the wind speed of the blown-out air during the thermo-off time extension mode is corrected according to the number and / or position of people in the room and / or the amount of activity by a human sensor. The air conditioner according to any one of claims 2 to 9 and 6,
An air conditioner that blows air so as to avoid an area including a position where a occupant is present during the thermo-off time extension mode. The air conditioner according to any one of claims 2 to 10,
An air conditioner characterized by changing a shift value for extending a thermo-off time according to room temperature. The air conditioner according to any one of claims 2 to 11,
An air conditioner characterized by changing a shift value for extending a thermo-off time according to humidity. The air conditioner according to any one of claims 2 to 12,
An air conditioner characterized in that the shift value for extending the thermo-off time is changed according to the outside temperature. The air conditioner according to any one of claims 2 to 13,
An air conditioner characterized in that the shift value for extending the thermo-off time is changed according to at least one measurement result among the number, position, and amount of activity of people in the room. The air conditioner according to any one of claims 1 to 14,
An air conditioner characterized in that a reduction amount of power consumption in the thermo-off time extension mode is set.