CN105339742B - Air conditioner - Google Patents
Air conditioner Download PDFInfo
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- CN105339742B CN105339742B CN201580000700.3A CN201580000700A CN105339742B CN 105339742 B CN105339742 B CN 105339742B CN 201580000700 A CN201580000700 A CN 201580000700A CN 105339742 B CN105339742 B CN 105339742B
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/30—Control or safety arrangements for purposes related to the operation of the system, e.g. for safety or monitoring
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/50—Control or safety arrangements characterised by user interfaces or communication
- F24F11/52—Indication arrangements, e.g. displays
- F24F11/523—Indication arrangements, e.g. displays for displaying temperature data
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/50—Control or safety arrangements characterised by user interfaces or communication
- F24F11/56—Remote control
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/62—Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/62—Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
- F24F11/63—Electronic processing
- F24F11/64—Electronic processing using pre-stored data
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/70—Control systems characterised by their outputs; Constructional details thereof
- F24F11/72—Control systems characterised by their outputs; Constructional details thereof for controlling the supply of treated air, e.g. its pressure
- F24F11/74—Control systems characterised by their outputs; Constructional details thereof for controlling the supply of treated air, e.g. its pressure for controlling air flow rate or air velocity
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/70—Control systems characterised by their outputs; Constructional details thereof
- F24F11/72—Control systems characterised by their outputs; Constructional details thereof for controlling the supply of treated air, e.g. its pressure
- F24F11/74—Control systems characterised by their outputs; Constructional details thereof for controlling the supply of treated air, e.g. its pressure for controlling air flow rate or air velocity
- F24F11/76—Control systems characterised by their outputs; Constructional details thereof for controlling the supply of treated air, e.g. its pressure for controlling air flow rate or air velocity by means responsive to temperature, e.g. bimetal springs
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/70—Control systems characterised by their outputs; Constructional details thereof
- F24F11/72—Control systems characterised by their outputs; Constructional details thereof for controlling the supply of treated air, e.g. its pressure
- F24F11/79—Control systems characterised by their outputs; Constructional details thereof for controlling the supply of treated air, e.g. its pressure for controlling the direction of the supplied air
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/70—Control systems characterised by their outputs; Constructional details thereof
- F24F11/80—Control systems characterised by their outputs; Constructional details thereof for controlling the temperature of the supplied air
- F24F11/86—Control systems characterised by their outputs; Constructional details thereof for controlling the temperature of the supplied air by controlling compressors within refrigeration or heat pump circuits
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2110/00—Control inputs relating to air properties
- F24F2110/10—Temperature
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2120/00—Control inputs relating to users or occupants
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2120/00—Control inputs relating to users or occupants
- F24F2120/20—Feedback from users
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2130/00—Control inputs relating to environmental factors not covered by group F24F2110/00
- F24F2130/30—Artificial light
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- Engineering & Computer Science (AREA)
- General Engineering & Computer Science (AREA)
- Chemical & Material Sciences (AREA)
- Combustion & Propulsion (AREA)
- Mechanical Engineering (AREA)
- Physics & Mathematics (AREA)
- Signal Processing (AREA)
- Human Computer Interaction (AREA)
- Fuzzy Systems (AREA)
- Mathematical Physics (AREA)
- Fluid Mechanics (AREA)
- Thermal Sciences (AREA)
- Air Conditioning Control Device (AREA)
- Radiation Pyrometers (AREA)
- User Interface Of Digital Computer (AREA)
Abstract
A kind of air conditioner for carrying out the airconditioning control in space, and has thermal image acquisition unit, operational part and control unit.Thermal image acquisition unit obtains the thermal image of the Temperature Distribution of representation space.Operational part determines the region for being equivalent to people in thermal image acquired in thermal image acquisition unit, the temperature i.e. human body temperature that the people in space is determined based on the Temperature Distribution in the region for being equivalent to people, the temperature in the region based on human body temperature and other than in addition to the region for being equivalent to people and the difference value of ambient temperature that obtains infer the warm-cold sensitivity of the people in space.The warm-cold sensitivity for the people in space that control unit is inferred based on operational part controls at least one of the air quantity of air conditioner, wind-warm syndrome, wind direction.
Description
Technical field
The invention mainly relates to air conditioner and it is used in the thermal image sensor system of air conditioner, which is equipped with
The infra red thermograph (thermal image acquisition unit) of two-dimensional Temperature Distribution can be measured.
Background technique
In recent years, exploitation has the various application programs for having used infrared ray.The near infrared region that wavelength is 0.7~2.5 micron
The infrared ray in domain is used in night viewing camera, TV remote controller etc..In addition, the mid infrared region that wavelength is 2.5~4.0 microns
Infrared ray be often used in the identification of substance.The identification of substance is to irradiate survey obtained by infrared ray by opposite measurement object
The transmitted spectrum of amount object carries out spectroscopic measurements, to what is carried out by the judgement of the intrinsic absorption spectrum of the measurement object.And
And wavelength is used to the surface temperature of measurement of species for the infrared ray in 4.0~10 microns of far infrared region.Since there are room temperature
The peak value of neighbouring blackbody radiation spectrum, therefore by detecting the infrared ray from matter-radiation, it can be in a non-contact manner
The surface temperature of measurement of species.Its generally as infra red thermograph, effectively utilize in two-dimensionally obtain substance surface temperature
Degree.So far, infra red thermograph is mainly used for the plant maintenance of heat distributional analysis, factory in research and development etc., life
The industrial uses such as the qualitative control in producing line.At these on the way, the infrared heat with relatively more pixel numbers is used mostly
As instrument.
On the other hand, recently, as patent document 1, occur for infra red thermograph being installed on the trend of air conditioner.
In the patent document 1, position, the activity of people are inferred according to indoor Temperature Distribution, and the result of deduction feedback is arrived
The movement of air conditioner.In such manner, it is possible to realize more comfortable and efficient air conditioner.
Moreover, in patent document 2, the skin temperature of measurement face etc. and infer heat dissipation capacity and Depth of sleep, carry out with
The control of the corresponding air conditioner of the result of the deduction.It comfortably falls asleep in such manner, it is possible to provide.
Moreover, in patent document 3, detecting the surface temperature of human body, and carry out corresponding with the result detected empty
The control of tune machine.In such manner, it is possible to further increase bathroom, indoor comfort of changing one's clothes, mitigate thermal shock.
Existing technical literature
Patent document
Patent document 1: Japanese Unexamined Patent Publication 2001-304655 bulletin
Patent document 2: Japanese Unexamined Patent Publication 7-225042 bulletin
Patent document 3: Japanese Unexamined Patent Publication 2002-22240 bulletin
Summary of the invention
Problems to be solved by the invention
As patent document 2, use infra red thermograph as the extremely office of the human bodies such as detection face in air conditioner
In the case where the mechanism of the temperature in portion, since measurement object region is relatively narrow, it is therefore desirable to use the infrared heat picture of high pixel number
Instrument.Accordingly, there exist the costs of air conditioner to increase this project.Moreover, in patent document 3, for how to measure the table of human body
How face temperature can be realized comfortable environment and does not also carry out open or provide enlightenment.
The application is mainly used for solving the above subject, even if being to provide a kind of less using pixel number and inexpensively infrared
Line thermal imaging system also can conclude that people feel heat still feel cold warm-cold sensitivity, to realize comfortable environment temperature air conditioner,
And it is used in the thermal image sensor system of air conditioner.
The means to solve the problem
To achieve the goals above, air conditioner has: thermal image acquisition unit obtains the thermal map of the Temperature Distribution of representation space
Picture;Operational part, (i) determines the region for being equivalent to people in thermal image acquired in thermal image acquisition unit, and (ii) is based on being equivalent to
The Temperature Distribution in the region of people determines the temperature i.e. human body temperature of the people in space, (iii) be based on human body temperature and according in addition to
It is equivalent to the temperature in the region other than the region of people and the difference value of ambient temperature that obtains infers that the people's in space is cold and hot
Sense;And control unit, the warm-cold sensitivity of the people in space inferred based on operational part, control air quantity, wind-warm syndrome, the wind direction of air conditioner
At least one of.
The effect of invention
In accordance with the invention it is possible to inexpensively provide the warm-cold sensitivity of deducibility people a kind of and realize the sky of comfortable environment temperature
Tune machine.
Detailed description of the invention
Figure 1A is the figure that outlined the appearance of air conditioner 100 of the 1st embodiment of the invention.
Figure 1B is an example of the thermal image used in air conditioner 100.
Fig. 2 is the configuration example of the air conditioner 100 of the 1st embodiment.
Fig. 3 is the figure for illustrating set point Tc.
Fig. 4 A is the configuration example of the air conditioner 100 about variation 1.
Fig. 4 B is the configuration example of the air conditioner 100 about variation 1.
Fig. 4 C is the configuration example of the air conditioner 100 about variation 1.
Fig. 5 is the figure for illustrating an example of circadian rhythm.
Fig. 6 is the configuration example of the air conditioner 100 about variation 2.
Fig. 7 is an example of the thermal image used in variation 2.
Fig. 8 A is the configuration example of the air conditioner 100 about variation 3.
Fig. 8 B is the configuration example of the air conditioner 100 about variation 3.
Fig. 8 C is the configuration example of the air conditioner 100 about variation 3.
Fig. 9 is the configuration example of the air conditioner 100 about variation 4.
Figure 10 is an example of the thermal image used in variation 4.
Figure 11 is an example of the thermal image used in variation 4.
Figure 12 is the configuration example of the air conditioner 100 about variation 4.
Figure 13 is an example of the thermal image used in variation 4.
Figure 14 is the configuration example of the air conditioner 100 about variation 4.
Figure 15 A is the configuration example of the air conditioner 100 about variation 5.
Figure 15 B is the configuration example of the air conditioner 100 about variation 6.
Figure 16 is the configuration example of the air conditioner 100 about variation 7.
Figure 17 is an example of the thermal image used in variation 7 and Temperature Distribution.
Figure 18 is an example of thermal image used in variation 9 etc..
Figure 19 is an example of thermal image used in variation 10 etc..
Figure 20 A is the configuration example of the air conditioner 100 about variation 10.
Figure 20 B is the configuration example of the air conditioner 100 about variation 10.
Figure 21 is an example of the thermal image used in variation 11.
Figure 22 is the configuration example of the air conditioner 100 about variation 11.
Figure 23 is the configuration example of the air conditioner 100 about variation 12.
Figure 24 is an example of the Temperature Distribution used in variation 12.
Figure 25 is an example of thermal image used in variation 13 etc..
Figure 26 is the configuration example of the air conditioner 100 about variation 13.
Figure 27 is an example of thermal image used in variation 14 etc..
Figure 28 is the configuration example of the air conditioner 100 about variation 14.
Figure 29 is the figure that outlined the appearance of air conditioner 200 of the 2nd embodiment of the invention.
Figure 30 is the configuration example of the air conditioner 200 of the 2nd embodiment.
Figure 31 is the picture example of the remote controler used in air conditioner 200.
Figure 32 is the configuration example of the air conditioner 200 of the 2nd embodiment.
Figure 33 is the picture example of the remote controler used in air conditioner 200.
Figure 34 is the configuration example of the air conditioner 200 of the 2nd embodiment.
Figure 35 is the picture example of the remote controler used in air conditioner 200.
Figure 36 is the configuration example of the thermal image sensor system 300 of application mode of the invention.
Specific embodiment
The summary > of each mode of < invention
Air conditioner in a mode of the invention is the air conditioner for carrying out the airconditioning control in space, is had: thermal image
Acquisition unit obtains the thermal image of the Temperature Distribution of representation space;Operational part (i) determines thermal map acquired in thermal image acquisition unit
The region for being equivalent to people as in, (ii) determines the temperature i.e. people of the people in space based on the Temperature Distribution in the region for being equivalent to people
Temperature, (iii) is based on human body temperature and according to temperature around the acquisition of the temperature in the region other than the region for being equivalent to people
The difference value of degree infers the warm-cold sensitivity of the people in space;And control unit, the people's in space inferred based on operational part
Warm-cold sensitivity controls at least one of the air quantity of air conditioner, wind-warm syndrome, wind direction.Thermal image acquisition unit and operational part can also be with structures
At the thermal image sensor system separated with air conditioner.
Moreover, it can be, operational part is based on the difference of difference value and defined threshold value, to infer the warm-cold sensitivity of people, difference
Value is the difference value of human body temperature and ambient temperature.
Moreover, it can be, the case where difference value obtained by ambient temperature is greater than defined threshold value is subtracted in human body temperature
Under, control unit is controlled in a manner of increasing ambient temperature, is subtracted difference value obtained by ambient temperature in human body temperature and is less than
In the case where defined threshold value, control unit is controlled in a manner of reducing ambient temperature.
Moreover, it can be, operational part corrects defined threshold value based on the activity of people.
Moreover, it can be, operational part is carrying out refrigeration operation or heating operation based on air conditioner to correct regulation
Threshold value.
Moreover, it can be, defined threshold value is corrected based on ambient temperature.
Moreover, it can be, the temperature-averaging of whole pixels of the operational part based on the region for being equivalent to people in thermal image
Value determines human body temperature.
Moreover, it can be, operational part will be equivalent to the region division of people into multiple human bodies, and to multiple human body
Each of position is weighted, and determines people based on the temperature averages of whole pixels in the region for being equivalent to people after weighting
Temperature.
Moreover, it can be, operational part compares other people for the human body that the skin in multiple human bodies exposes
Body region reduces weighting.
Moreover, it can be, operational part will be equivalent to the region division of people into multiple temperature ranges, and to multiple temperature
Each of range is weighted, and determines people based on the temperature averages of whole pixels in the region for being equivalent to people after weighting
Temperature.
Moreover, it can be, operational part reduces the weighting of the lower sides of temperature in multiple temperature ranges, and increases
The weighting of the higher side of temperature.
Moreover, it can be, the temperature-averaging of whole pixels of the operational part based on the region for being equivalent to people in thermal image
Temperature maximum in value and whole pixel determines human body temperature.
Moreover, it can be, temperature of the operational part based on the pixel in the region other than the region for being equivalent to people
Mode value determines ambient temperature.
Moreover, it can be, operational part determines floor area that the space in thermal image is included or/and ceiling
Region, and ambient temperature is determined based on the temperature of the temperature of floor area or/and ceiling region.
Moreover, it can be, operational part will be worn over by the people in space with or be installed on be worn over object temperature
The value for spending sensor measurement is used as ambient temperature.
Moreover, it can be, operational part will be by being set to air conditioner and obtaining the temperature of the temperature around air conditioner
The value of the value of sensor measurement or the temperature sensor measurement by being installed on the remote controler that can remotely operate air conditioner
As ambient temperature.
Moreover, it can be, operational part is using the region of the temperature of range as defined in the expression in thermal image as being equivalent to
The region of people and determine.
Moreover, it can be, operational part by the region of the temperature of range as defined in the expression in thermal image and is regulation
Quantity more than continuous region determined as the region for being equivalent to people.
In addition, being a kind of for carrying out the air conditioner of the airconditioning control in space, having: thermal image as other modes
Acquisition unit obtains the thermal image of the Temperature Distribution of representation space;Operational part determines in thermal image acquired in thermal image acquisition unit
Be equivalent to the region of people, and infer the warm-cold sensitivity of the people in the space in the region of the determination;And notification unit, by operational part
The warm-cold sensitivity of the people in space inferred is notified to the people in space.
Moreover, it can be, notification unit is by making the image, character or symbol of the warm-cold sensitivity of the people in representation space
It is shown in set on the display unit of air conditioner main body or on the display unit of the remote controler of air conditioner, so that notice is in space
People.
Moreover, it can be, notification unit by make the display discoloration of display unit more and people into space notifies in space
People warm-cold sensitivity.
Moreover, it can be, operational part generates correction image, and which seems operational part being equivalent in thermal image
Made of the periphery of the coordinate in the region of people makes the character or Overlapping Symbol of the warm-cold sensitivity of the people in representation space, notification unit is logical
Cross the warm-cold sensitivity for making that display unit display corrects image and the people into space notifies the people in space.
Moreover, it can be, notification unit via network to the terminal notification other than air conditioner by the people's in representation space
Image, character or the symbol of warm-cold sensitivity are shown in the instruction of the display unit of the terminal.
Moreover, it can be, notification unit is related to terminal transmission (i) thermal image, (ii) other than air conditioner via network
The information and (iv) of the warm-cold sensitivity of information, (iii) in relation to deduction of the coordinate in the region of people are equivalent to determined by operational part
The periphery of the coordinate in the region for being equivalent to people in operational part thermal image generated makes to the people's in representation space is cold and hot
Correction image made of the character or Overlapping Symbol of sense is shown in the instruction of the display unit of terminal.
Moreover, it can be, operational part generates following correction images, and which seems phase of the operational part in thermal image
Made of the periphery of the coordinate in the region of people makes the character or Overlapping Symbol of the warm-cold sensitivity of the people in representation space, notice
Portion is shown in the instruction of the display unit of the terminal via network to terminal notification high-ranking officers' positive image other than air conditioner.
Moreover, it can be, operational part determines the temperature of the people in space based on the Temperature Distribution in the region for being equivalent to people
Degree is human body temperature, and based on human body temperature and according to temperature around the acquisition of the temperature in the region in addition to the region for being equivalent to people
The difference value of degree infers the warm-cold sensitivity of the people in space.
Moreover, it can be, air conditioner is also equipped with the modified amendment receiving portion for receiving inferred warm-cold sensitivity, operational part
The warm-cold sensitivity of deduction is corrected based on the information that amendment receiving portion is received.
Moreover, it can be, air conditioner is also equipped with the modified amendment receiving portion for receiving inferred warm-cold sensitivity, operational part
Difference based on difference value and defined threshold value, to infer the warm-cold sensitivity of people, which is the difference of human body temperature and ambient temperature
Score value, and defined threshold value is changed based on correcting the information that receiving portion is received.
In addition, as other modes, be it is a kind of for carrying out the air conditioner of the airconditioning control in space, have: thermal image
Acquisition unit obtains the thermal image of the Temperature Distribution of representation space;Temperature sensor obtains the temperature around air conditioner;Operation
Portion determines acquired in thermal image acquisition unit in the case that the ambient temperature acquired in temperature sensor is defined temperature field
Thermal image in be equivalent to the region of people, and infer the warm-cold sensitivity of the people in the space in the region of the determination;And control
Inferred in the case that ambient temperature acquired in temperature sensor is defined temperature field based on above-mentioned operational part in portion
The warm-cold sensitivity of people in space controls at least one of the air quantity of air conditioner, wind-warm syndrome, wind direction.
Moreover, it can be, in the case where ambient temperature is not defined temperature field, operational part without operation,
In the case that ambient temperature is not defined temperature field, control unit correspond to ambient temperature judge air quantity in relation to air conditioner,
The control content of at least one of wind-warm syndrome, wind direction is simultaneously controlled.
In addition, being a kind of thermal image sensor system, having as other modes: thermal image acquisition unit, obtaining indicates
The thermal image of the Temperature Distribution in space;And operational part, (i) determine being equivalent in thermal image acquired in thermal image acquisition unit
The region of people, (ii) determine the temperature i.e. human body temperature of the people in space, (iii) based on the Temperature Distribution in the region for being equivalent to people
Based on human body temperature and according to the temperature in the region other than the region for being equivalent to people obtain ambient temperature difference value come
Infer the warm-cold sensitivity of the people in space.
In addition, being a kind of warm-cold sensitivity estimating method as other modes, by computer, according to by acquisition thermal image
Thermal image sensor obtain thermal image infer people warm-cold sensitivity, in the warm-cold sensitivity estimating method, computer determines thermal map
The region for being equivalent to people as in, the temperature i.e. human temperature of the people in space is determined based on the Temperature Distribution in the region for being equivalent to people
Degree, and the difference value based on human body temperature and the ambient temperature obtained according to the temperature in the region in addition to the region for being equivalent to people
To infer the warm-cold sensitivity of the people in space.
In addition, program is inferred as other modes for a kind of warm-cold sensitivity, according to the thermal image sensing by acquisition thermal image
The thermal image that device obtains infers that the warm-cold sensitivity of people, the warm-cold sensitivity infer that program includes: (i) is determined acquired in thermal image acquisition unit
The region for being equivalent to people in thermal image, (ii) determine the temperature of the people in space based on the Temperature Distribution in the region for being equivalent to people
That is human body temperature, (iii) is based on human body temperature and the week obtained according to the temperature in the region other than the region for being equivalent to people
The difference value of temperature is enclosed to infer calculation process as the warm-cold sensitivity of the people in space.
Hereinafter, illustrating embodiments of the present invention while referring to attached drawing.In addition, marking phase to identical element sometimes
Same appended drawing reference simultaneously omits the description.In addition, for ease of understanding attached drawing, it is respectively that each constituent element is schematic as main body
Ground is indicated.
In addition, embodiments described below indicates a concrete example of the invention.Show in the following embodiments
Numerical value, shape, constituent element, step, sequence of step out etc. are an examples, and non-limiting purport of the invention.In addition,
The composition recorded for independent claims in the constituent element of following implementation, not being expressed upper concept is wanted
Element is illustrated as arbitrary constituent element.In addition, in all embodiments, can also combine each content.In addition,
The composition being recorded in each variation of each embodiment be also it is identical, the structure for being recorded in each variation can be respectively combined
At.
The detailed description > of each mode of < invention
[the 1st embodiment]
It is illustrated using air conditioner 100 of the attached drawing to the 1st embodiment of the invention.
In Fig. 2, the air conditioner 100 of this 1st embodiment has thermal image acquisition unit 110, temperature sensor 120, fortune
Calculation portion 130, control unit 160, shutter 171, compressor 172 and fan 173.Operational part 130 include position determining portions 131,
Human body temperature calculation part 132, temperature difference value calculation part 133, warm-cold sensitivity inferring portion 134 and set point configuration part 135.It should
Each constitute of air conditioner 100 also can be only fitted to times for being set to indoor indoor unit and being set in outdoor outdoor unit
Meaning one.In addition, air conditioner 100 can also have the composition except these in addition to constituting.
Thermal image acquisition unit 110 is mounted to the so-called infra red thermograph before air conditioner 100.Thermal image obtains
Portion 110 has the field angle Φ of left and right directions, can obtain the two-dimensional heat of the object for the front space for being present in air conditioner 100
Image.In addition, thermal image acquisition unit 110 also has field angle in the up-down direction, the front space of air conditioner 100 can be known
The presence of interior people 102.Thermal image acquisition unit 110 be for example in two-dimensional-matrix-like arrangement pixel group and can be primary
Property obtains the construction of two-dimensional thermal image.Other than the construction, thermal image acquisition unit 110 is also possible to for example in one-dimensional
The pixel group (line sensor) of shape arrangement and one-dimensionally scanning element group and obtain the construction of two-dimensional thermal image, or can also
To be that there is more than one pixel and two-dimensionally scan more than one pixel and obtain the construction of two-dimensional thermal image.This
Place, the composition of thermal image acquisition unit 110 are not limited.
In this 1st embodiment, when as Figure 1A in the space of the field angle Φ in the front of air conditioner 100
There are when people 102, thermal image acquisition unit 110 can obtain the thermal image 103a of the such Temperature Distribution comprising people 102 of Figure 1B.
Hereinafter, being illustrated to thermal image 103a.
In thermal image 103a, the high part of the temperature of the object in space (pixel), it is higher to be more shown as concentration.
In fig. ib, the high pixel of temperature is more shown with connecing pullous color.In addition, the display about thermal image is not
It is limited to this.
Currently, the dress of people 102 shown in figure 1A has jacket 102a and trousers 102b.The surface of jacket 102a, trousers 102b
Temperature is close to ambient temperature.Thus, for example in the case where the room temperature that ambient temperature is 25 DEG C or so, about by thermal image acquisition unit
The surface temperature of 110 people 102 detected, jacket 102a, trousers 102b part than other positions that skin exposes (face,
Head, both hands, both feet) it is low.The surface temperature for the part exposed as a result, compared to skin, with relatively low concentration (with surrounding
The close color of the color of pixel) display jacket 102a, trousers 102b surface temperature.In addition, in above-mentioned temperature environment, by
It is lower than the temperature for wearing surface clothes in ambient temperature, therefore the feelings of ambient temperature object below are not present in the inside of field angle Φ
Under condition, the concentration in the region in addition to people of thermal image 103a becomes minimum.For example, when room temperature is 25 DEG C or so, in face
Skin temperature be average 33 DEG C or so, the temperature of jacket 102a is 27 DEG C or so, the temperature of both hands (exposed division) is 30 DEG C of left sides
In the case that right, trousers 102b temperature is 28 DEG C or so, the temperature of double-legged (exposed division) is 29 DEG C or so, become thermal image
That Temperature Distribution shown in 103a.But since the temperature-independent on the clothing surface of jacket 102a, trousers 102b etc. is in clothing
Material, thickness etc., therefore sometimes up to other temperature.In addition, the surface temperature of skin is also due tos individual differences, activity etc.
It is inconsistent.In addition, when people 102 is not present and under being to be present in the uniform situation of temperature of the object in field angle Φ, such as
Become uniform distribution shown in the thermal image 103b of Figure 1B like that.
Next, each composition to air conditioner 100 is illustrated with function.
The Temperature Distribution obtained by thermal image acquisition unit 110 is sent to operational part 130 as thermal image.Temperature sensor
120 be thermistor, this point or parts surface that can be measured in space of thermocouple a point temperature sensing
Device.Temperature sensor 120 measures ambient temperature such as the air suction inlet for being configured at air conditioner 100.In addition, warm
Even the position of degree sensor 120 is configured at the place other than air suction inlet etc., here, the position is not limited.By temperature
The ambient temperature that degree sensor 120 detects is sent to operational part 130.
In operational part 130, position determining portions 131 analyzes the thermal image sent from thermal image acquisition unit 110, in sky
The position of interior people 102 is determined.The method for determining position of people is described later.Human body temperature calculation part 132 analysis from
The thermal image that thermal image acquisition unit 110 is sent, judges the region for being inferred as being equivalent to people 102.Then, human body temperature meter
The region judged is cut in calculation portion 132, and the average value of the temperature in the region of cutting is determined as human body temperature and (found out).It
The calculation method of the determination method in the region of people, the average value of temperature is described afterwards.Temperature difference value calculation part 133 is obtained by human body
The calculated human body temperature in temperature computation portion 132 (A value) and the ambient temperature (B value) detected by temperature sensor 120, find out
The temperature difference value (C value) (that is, C=A-B) of the two.
Warm-cold sensitivity inferring portion 134 is obtained by 133 calculated temperature difference value (C value) of temperature difference value calculation part.In addition,
Warm-cold sensitivity inferring portion 134 obtains the set point Tc set by set point configuration part 135.Then, warm-cold sensitivity inferring portion 134 passes through ratio
Compared with temperature difference value (C value) and set point Tc, judge that people 102 feels that heat still feels cold and (is referred to as warm-cold sensitivity later).
Here, the set point Tc set by set point configuration part 135 refer to people feel it is not hot it is not cold just when temperature
It spends difference value (C value) [=human body temperature (A value)-ambient temperature (B value)].That is, as shown in figure 3, if difference value compares set point
Tc is small, if in other words ambient temperature rises relative to human body temperature, correspondingly with the amount of the rising, people basks, heat.
On the other hand, if difference value is bigger than set point Tc, in other words ambient temperature relative to human body temperature decline, then with the decline
Amount correspondingly, people feels to feel nice and cool, is cold.The value of set point Tc can for example be found out by experiment, can also pass through simulation
And it calculates.
In this way, can conclude that position and the warm-cold sensitivity of the people 102 being present in field angle Φ in operational part 130.Infer
The position of people 102 out and warm-cold sensitivity are input into control unit 160.Control unit 160 is according to the warm-cold sensitivity deduction in operational part 130
The warm-cold sensitivity judged in portion 134 controls shutter 171, compressor 172 and fan 173.For example, being that people 102 feels in judgement
In the case where heat, control unit 160 carries out making shutter 171 towards the direction at 102 place of people and makes compressor 172 and fan
173 act and generate the control of cold wind.In this way, the ambient temperature due to people 102 declines, because this person 102 no longer feels heat, but
It can be in comfortable.
In this way, by finding out around the mean temperature i.e. human body temperature (A value) and people 102 in the region for being equivalent to people 102
The temperature difference value (C value) of temperature (B value) infers warm-cold sensitivity, has the effect of as follows.
Although cannot be set for the amount of the clothing of people in general, room temperature can be set using air conditioner.Such as
In the case where summer, even identical set temperature, if clothing Bao Zeren feels nice and cool, people feels heat if wearing thickness clothes
Deng feeling way difference.Such as in winter in the case where, even identical set temperature, if clothing Bao Zeren feel cold,
People basks if wearing thickness clothes, and feeling way is different.That is, if clothing amount is different, even if ambient temperature is identical, people's
Warm-cold sensitivity also becomes different.As a result, only by the way that ambient temperature is maintained identical temperature, warm-cold sensitivity also can be dependent on clothing
It measures and changes, to need to change the set temperature of air conditioner.
As in the present embodiment, the average temperature in the region for the people 102 being equivalent to including the region also comprising clothing is found out
Degree is the temperature difference value (C value) of the ambient temperature (B value) of human body temperature (A value) and people 102, exactly to from also considering
The heat dissipation capacity of the body of clothing is inferred.It is roughly the same degree generally, due to the energy that people absorbs daily, therefore
The heat distributed from body is also preferably maintained constant.As a result, by relative to be based on ideal heat dissipation capacity and
Pre-determined set point Tc compares the index i.e. temperature difference value (C value) of the heat dissipation capacity from body, cold so as to infer
Thermal sensation.If can conclude that warm-cold sensitivity, even if changing the amount of clothing, without the amount for for example deliberately informing clothing by people 102,
Warm-cold sensitivity can be persistently inferred with high precision in operational part 130.As a result, having regardless of the amount worn clothes, all it is not necessarily to
Change set temperature one by one and is just capable of providing this effect of comfortable space.
As effect in addition to this, following effect can be expected.In the present embodiment, as from thermal image 103a
The value of extraction finds out the average value for being equivalent to the region of people 102.Therefore, even enumerate the lower image of resolution also without
The case where harm.For example, if temperature in order to infer warm-cold sensitivity and nose to be measured, need with to indoor several square centimeters of region
Carry out the resolution of the corresponding thermal image of amount of solution picture.But according to the present embodiment, as long as being equivalent to people 102 due to finding out
Region average value, therefore do not need resolution high in this way.There is the heat lower and cheap using resolution as a result,
Image acquiring unit 110 is also sufficient to infer this effect of the warm-cold sensitivity of people 102.
Certainly, control unit 160 both can be with temperature difference to the drive volume of shutter 171, compressor 172 and fan 173
The bias for being equivalent to set point Tc of score value (C value) it is unrelated and be it is constant, can also correspondingly change with offset.For example,
In the biggish situation of offset, the drive volume of compressor 172, fan 173 can be increased, in the lesser situation of offset,
It can reduce the drive volume of compressor 172, fan 173.
In addition, several variations further explained below.
(variation 1)
In variation 1, (commonly referred to as " circadian rhythm (circadian is changed in one day based on the deep body temperature of people
Rhythm) ") the case where, changes set point Tc correspondingly with the time.
Fig. 4 A is the figure for indicating the composition of the air conditioner 100 about variation 1.Variation shown in Fig. 4 A about operation
Portion 130 is also equipped with the composition of circadian rhythm storage unit 136 and clock 137.In circadian rhythm storage unit 136, such as with table
Form is stored with the representative circadian rhythm (deep body temperature of the people changed in one day) such as shown in Fig. 5 (a).Clock
137 be the internal clocking of air conditioner 100, and assigns the information in relation to the moment to set point configuration part 135.Set point configuration part
At the time of 135 reference clock 137, based on the deep body temperature for being stored in circadian rhythm storage unit 136, to having carried out and the moment phase
The set point Tc for the correction answered is set.As the variation, school has been carried out in set point configuration part 135 by being based on
Positive set point Tc infers warm-cold sensitivity, so as to maintain the sense with the intraday people according to circadian rhythm to ambient temperature
By the corresponding comfortable environment of variation of mode.
In addition, usually deep body temperature is higher than in the morning in the afternoon, even it may thus be appreciated that identical temperature, compared to upper
Noon relatively feels warmer in the afternoon.As long as the set point Tc in afternoon is set as higher as a result, as long as and with
The proportional form calibration setup point Tc of the body temperature variation of circadian rhythm.
In addition, Fig. 4 B is other figures constituted for indicating the air conditioner 100 about variation 1.Variation shown in Fig. 4 B
It is the composition for replacing internal clock 137 with external clock 190.In the variation, consider get up the time, the bedtime because
People and it is different, referring to possessed by people at the time of clock 190 (such as alarm clock) and clock that not air conditioner 100 has.For example,
The reference position of the circadian rhythm of circadian rhythm storage unit 136 can be stored in based on the time changing of getting up for being set in clock 190
It sets.As clock 190, illumination, the sleep meter in bedroom etc. are also possible to other than alarm clock.Sleep meter is being capable of root
The deductions such as the body movement according to people are fallen asleep the metrical instrument of moment, the moment of getting up, sleeping time, Depth of sleep etc..That is, according to sleeping
At the time of the illumination ON/OFF of room, sleep meter value, can conclude that get up time and bedtime.Such as the variation that
Sample is capable of providing for everyone optimized comfortable air conditioner.
In addition, Fig. 4 C is another figure that other are constituted for indicating the air conditioner 100 about variation 1.Become shown in Fig. 4 C
Shape example is the structure for storing multiple circadian rhythms in circadian rhythm storage unit 136 and being further equipped with circadian rhythm determination unit 138
At.For circadian rhythm, the temperature variation amplitude of the people to live a regular life is larger, and live irregular people, and temperature becomes
Dynamic amplitude is smaller.For example, as shown in Fig. 5 (b), round the clock by the circadian rhythm (rhythm and pace of moving things 1) of regular people and irregular people
The rhythm and pace of moving things (rhythm and pace of moving things 2) is stored in circadian rhythm storage unit 136.Circadian rhythm determination unit 138 based on getting up of being obtained from clock 190 with
And it go to bed and determines to be regular or irregular constantly, and judging result is notified to set point configuration part 135.Set point setting
Portion 135 selects some circadian rhythm in the rhythm and pace of moving things 1 or the rhythm and pace of moving things 2 according to the judgement notified by circadian rhythm determination unit 138,
Set point Tc is set.It is also regular or irregular with the living habit of people by being capable of providing as the variation
Accordingly, for everyone optimized comfortable air conditioner.
In addition, here, as an example, circadian rhythm is divided into and is lived a regular life or irregular this two progress
It indicates, naturally it is also possible to further refinement.In addition, circadian rhythm shown in fig. 5 is a schematical example, can also appoint
Meaning ground setting body temperature amplitude of fluctuation etc., here, and is not limited thereof.
(variation 2)
In variation 2, based on if cause the heat dissipation capacity from body to increase because of movement, if compared to peace and quiet when feel temperature
Warm this point, changes set point Tc correspondingly with activity.
Fig. 6 is the figure for indicating the composition of the air conditioner 100 about variation 2.In variation shown in Fig. 6, operational part
130 are also equipped with the composition of activity operational part 139 and buffer 140.For example, in Fig. 7, if thermal image 103c is moment T1
Thermal image, if thermal image 103d be the stipulated time more late than moment T1 at the time of T2 thermal image.At this point, position determining portions 131
The position of the people 102 of moment T1 is determined according to thermal image 103c, or determines according to thermal image 103d the position of the people 102 of moment T2
It sets.Buffer 140 stores the position of the people determined at various moments by position determining portions 131.Activity operational part 139 is according to depositing
The variation for being stored in the position of the people of buffer 140 infers the activity of people 102, and is sent to set point configuration part 135.Setting
Point configuration part 135 is corrected set point Tc based on the activity inferred by activity operational part 139.According to the variation,
It can conclude that warm-cold sensitivity corresponding with the activity of people.Based on by inferring the warm-cold sensitivity obtained, control unit 160 can be with people's
Activity correspondingly controls compressor 172, fan 173.Thereby, it is possible to provide the surrounding's ring that can be felt comfortable activity
Border.
In addition, quantitative change of usually radiating is more, therefore correspondingly raises set point with activity in the biggish situation of activity
The case where Tc, increases.In addition, here, be conceived to the variation of the position of people and infer activity, but can also to and inhuman position
The position for the high-temperature portion such as hand set is monitored and infers activity.In this way, even if at seat when such as ironing
The case where upper progress operation, is inferior, also can conclude that activity, therefore be capable of providing more comfortable air conditioner.
In addition, as an example for inferring activity, being illustrated using the people's in thermal image in the variation 2
The method of change in location.But as long as can conclude that activity, so that it may be its other party in addition to the method for using thermal image
The estimating method of method, activity is not specifically limited.
(variation 3)
In variation 3, even based on identical temperature, in the feeling way in summer and winter also different this point,
Change set point Tc correspondingly with season.
Especially since the temperature difference in the four seasons of Japan understand it is discernable, even it may thus be appreciated that identical temperature, in the summer
The feeling way in season and winter is also different.In general, in the hot season of summer etc., due to bodily habit sweltering heat, i.e.,
Keep ambient temperature higher (such as 28 DEG C), can also feel proper temperature.On the contrary, cold season is waited in winter, since body is practised
It has been used to cold, therefore even if ambient temperature is lower (such as 20 DEG C), can have also felt proper temperature.As a result, in summer, even if surrounding
The temperature difference value of temperature and the mean temperature of people is smaller than other seasons, can also feel comfortable, in winter, ambient temperature and people's
The temperature difference value of mean temperature can feel comfortable when bigger than other seasons.
Fig. 8 A is the figure for indicating the composition of the air conditioner 100 about variation 3.In the variation shown in Fig. 8 A, operation
Portion 130 is also equipped with heating/refrigeration judging part 141 composition.Heating/refrigeration judging part 141 judges that air conditioner 100 is being made
Control model as heat run or refrigeration operation.Set point configuration part 135 is based on the control in heating/refrigeration judging part 141
The judging result of molding formula carrys out calibration setup point Tc.For example, set point Tc is set as if control model is refrigeration operation
3.0 DEG C, if control model is heating operation, set point Tc is set as 4.0 DEG C.In such manner, it is possible to provide also and based on season
Complying with for the warm-cold sensitivity of the body of section be adaptable, comfortable air conditioner.
In addition, Fig. 8 B is other figures constituted for indicating the air conditioner 100 about variation 3.Variation shown in Fig. 8 B
It is not heat/freeze the composition of judging part 141 but the ambient temperature detected by temperature sensor 120 is input to and is set
The composition in fixed-point settings portion 135.Set point configuration part 135 (utilizes sky according to the ambient temperature detected by temperature sensor 120
Adjust the temperature made before indoor become comfortably) infer current season, carry out the correction of set point Tc.Certainly, set point is set
Portion 135 can not also infer season, but based on the direct calibration setup point of ambient temperature detected by temperature sensor 120
Tc.In addition, ambient temperature is also possible to ambient temperature that warm-cold sensitivity inferring portion 134 is inferred from thermal image (later in variation 7
Narration).
Further, Fig. 8 C is another figure that other are constituted for indicating the air conditioner 100 about variation 3.Shown in Fig. 8 C
Variation in, operational part 130 is also equipped with the composition in calendar portion 142.Calendar portion 142 has dated information.Set point setting
Portion 135 infers current season according to the date obtained from calendar portion 142, carries out the correction of set point Tc.In such manner, it is possible to provide
Also with the body based on season is adaptable to complying with for warm-cold sensitivity, comfortable air conditioner.
(variation 4)
In variation 4, though based in identical environment, warm-cold sensitivity that people is experienced there is also individual differences this
A bit, discrimination corporally changes set point Tc.
As the method for distinguishing individual from thermal image, such as it is able to detect height.For example, the heat of X is shown in FIG. 10
The thermal image 103f of image 103e and Y.About the height of people, can be passed through according to standing place and the height of the people on image
Calculating is simply found out.That is, distance of the people away from air conditioner 100 is learnt upper or under according to the standing place on image, into
And the height of the people according to acquisition, height can be calculated.It, can be according to body for the Y of the X and thermal image 103f of thermal image 103e
High different discriminations are personal.
Fig. 9 is the figure for indicating the composition of the air conditioner 100 about variation 4.In variation shown in Fig. 9, operational part
130 are also equipped with the composition of people's discrimination section 143 and buffer 144.The analysis of people's discrimination section 143 is obtained by thermal image acquisition unit 110
Thermal image, individual is distinguished according to height as described above.Buffer 144 is previously stored with everyone (in the example
In be X and Y) set point Tc.The buffer 144 inputs personal discrimination results from people's discrimination section 143, will be directed to the individual
The set point Tc of storage is sent to set point configuration part 135.
Here, everyone set point Tc can be determined as follows.For example, can be by thermal image acquisition unit
The position of 110 acquisition thermal images makes personal standing, makes temperature change and acts air conditioner 100.Then, feeling not hot
At the time of not cold, specific signal (such as being sent with remote controler (not shown)) is inputted from individual to air conditioner 100.Air-conditioning
The ambient temperature obtained by temperature sensor 120 when machine 100 is entered according to specific signal, by human body temperature calculation part
132 human body temperatures etc. determined calculate set point, by the set point and the personal height information that is obtained by people's discrimination section 143
It is stored in buffer 144 together.In addition, can also be added when setting everyone set point Tc by oneself personal informing
Information (cold, To Be Protected from Heat, sympotoms caused by cold factors (Japanese: cold え disease, English: sensitivity to cold) etc.).For example, oneself is informed
The set point of the Y of sympotoms caused by cold factors is set as lower.It sets in this way, due to control heat dissipation capacity to the direction of relative drop
Mode function, even therefore have can sympotoms caused by cold factors be also difficult to such effect that feels cold.
In this way, set point configuration part 135 obtains from buffer 144 and sets setting for the individual distinguished by people's discrimination section 143
Pinpoint Tc.Then, warm-cold sensitivity inferring portion 134 judges warm-cold sensitivity based on the set point Tc of the individual.It can be to a thereby, it is possible to realize
People realizes the air conditioner of optimized ambient temperature.
In addition, in the above-described embodiments, calculating height according to the thermal image obtained by thermal image acquisition unit 110 and carrying out a
The discrimination of people.But method for distinguishing is not limited to this method for personal distinguishing, is also possible to other methods.For example, both can root
It distinguishes personal according to the difference of Temperature Distribution, can also distinguish personal based on the image of CCD camera set in addition etc..
[the determination method of human body temperature (A value)]
Next, the 1 mean temperature i.e. human temperature for illustrating region in operational part 130, being equivalent to people 102 referring to Fig.1
Spend the calculation method of (A value).
For example, as described above, in the case where room temperature is 25 DEG C or so, the skin temperature of face is average 33 DEG C of left sides
The right side, the temperature of jacket 102a are 27 DEG C or so, and the temperature of both hands (exposed division) is 30 DEG C or so, and the temperature of trousers 102b is 28 DEG C
Left and right, the temperature of double-legged (exposed division) are 29 DEG C or so.Thereby, it is possible to by with by temperature sensor 120 detect around temperature
Degree compares and is the region of predetermined temperature or more as the region for being equivalent to people 102.In this way, operational part 130 calculate it is related
For calculate the region of the people of human body temperature (A value) or be output to control unit 160 people 102 position information.
For example, if in this case inferring pixel portion of high 1 DEG C or more than ambient temperature (25 DEG C) for people 102,
The region that the thick line as shown in Figure 11 (a) can be surrounded is as the region for being equivalent to people.In this way, can also be above by regulation
Pixel portion is determined as being equivalent to the region of people.It in addition to this, can also will be more than 26 DEG C or more of pixel portion specified quantity
Continuous situation is added as the condition for determining the region of people.Such as Figure 11 (b) like that, in thermal image, sometimes
The region of the luminaire to be generated heat when including lighting with 26 DEG C or more etc..It in this case, as long as will for example 26 DEG C or more
10 pixel of continuous pixels more than region as people identify, would not using the thermal objects of these luminaires etc. as people and
It detects.It thereby, it is possible to accurately detect people, therefore can reliably infer warm-cold sensitivity, comfortable ambient enviroment is provided.
Moreover, in the above-described embodiments, will be equivalent to the region that ambient temperature is 1 DEG C or more and be set as being equivalent to the area of people
Domain however, you can also not only set lower limit temperature, but also sets ceiling temperature.For example, ceiling temperature can be also set as to 40 DEG C,
It is not set as the region higher than 40 DEG C to be equivalent to the region of people.In this case, such as Figure 11 (c) is such, it is assumed that in chest
Pocket in there are the principal element other than metabolism of human body etc. of smart phone etc. due to the object that generates heat and the region than 40
In the case where DEG C height, which can also be removed from the region for be equivalent to people.In such manner, it is possible to which accurately prediction people is because of metabolism
The amount of heat dissipation, therefore can more precisely infer warm-cold sensitivity, more comfortable ambient enviroment is provided.
In addition, in this embodiment, by whether 1 DEG C higher than ambient temperature or more as threshold value set the area for being equivalent to people
Domain, but can certainly independently be determined as such as 26 DEG C with ambient temperature, it is free to set.In addition, as continuous
Pixel number is set as 10 pixels herein as an example, is not limited to 10 pixels certainly, as long as obtaining with the thermal image used
The specification etc. of mechanism is correspondingly suitably set.In addition, being set as 40 DEG C as ceiling temperature, but this is also an example certainly
Son also can be set as other temperature, be not limited to 40 DEG C.In addition to this, can also compare according to time series acquisition
Thermal image will be present movable part as the region for being equivalent to people 102, herein, not limit its mode.
In addition, herein, as optimal composition, will be equivalent to people's 102 according to thermal image in the inside of operational part 130
The temperature averages in region are determined and (are found out) as human body temperature (A value), infer the warm-cold sensitivity of people 102.But it as long as can
Inferred by the difference value between acquisition and ambient temperature comprising the heat dissipation capacity including clothing, others can also be worth
As human body temperature.For example, it may be being equivalent to the integrated value of the temperature in the region of people 102, equally it is also possible to maximum value, also
It can be other mode values, median etc., herein and be not limited thereof.
In addition, so far, describing the case where related ambient temperature is 25 DEG C or so.But in ambient temperature height to for example
In the case where 33 DEG C or so, the skin temperature relative to face is average 33 DEG C or so, jacket 102a, trousers 102b temperature also with
Ambient temperature is very nearly the same, both reaches 33 DEG C or so.In addition, due to both hands (exposed division), both feet temperature also with surrounding
Temperature is same, and therefore, it is difficult to the region of people 102 is detected on thermal image.
But in general, if ambient temperature is 33 DEG C or so, not feel sultry from the heat dissipation of skin etc., body
Situation.Therefore, at this point, can also not have to operational part 130 judges (operation) warm-cold sensitivity and the position of people, but by control unit
160 directly judge ambient temperature and start refrigeration operation.Composition at this time is indicated in Figure 12.In this way, being in ambient temperature
In the case where more than predetermined temperature, with warm-cold sensitivity it is irrelevant start to freeze, so that ambient temperature is become predetermined temperature (such as 33
DEG C) below.If ambient temperature reaches predetermined temperature or less (defined temperature field), the region of people, therefore energy can be distinguished
Enough operational parts 130 infer warm-cold sensitivity to provide comfortable ambient enviroment.
In addition, here, making 33 DEG C of predetermined temperature and being illustrated, but not limited to this.As long as than the face of people
Predetermined temperature can also be set as lower by the low temperature of the surface temperature of the extending part in portion etc., here, not limit its temperature
Degree, range.Using the warm-cold sensitivity inferring portion 134 that so far describes infer warm-cold sensitivity and to the processing that control unit 160 is controlled, with
Execute to ambient temperature unrelated (not limiting temperature range).But such as ambient enviroment be 10 DEG C when, whoso can all be felt
To cold, if ambient enviroment is 30 DEG C, whoso can all feel heat.Accordingly it is also possible to be limited to by temperature sensor 120
The ambient temperature of measurement within the limits prescribed the case where, using warm-cold sensitivity inferring portion 134 infer warm-cold sensitivity and to control unit 160
It is controlled.Moreover, can all feel cold in the case where defined range ambient temperature below as whoso, it can
To infer without warm-cold sensitivity but heating operation is carried out, in the case where ambient temperature more than the range, as either
Everybody can feel heat, can infer without warm-cold sensitivity but carry out refrigeration operation.It is brought in such manner, it is possible to reduce operational part 130
Calculating load, provide consumption electric power less air conditioner.In addition, here, as the ambient temperature for carrying out warm-cold sensitivity deduction
Range be set as 10 DEG C to 30 DEG C, but the range is not limited certainly, can be set freely in the range of not departing from purport.
Additionally, it is not necessary to be mentioned that, it is above-mentioned be defined in carried out within the scope of predetermined temperature warm-cold sensitivity deduction effect be not rely on it is cold
Thermal sensation estimating method, even method in addition to the warm-cold sensitivity estimating method described in the present embodiment also effect having the same
Fruit.
In addition, the thermal image (benchmark thermal image) when people is not present in the range of field angle Φ is obtained in advance, in operation
The difference value of the thermal image and benchmark thermal image actually obtained is obtained in portion 130, so as to directly find out as human body temperature
The temperature difference value (C value) of the difference value of (A value) and ambient temperature (B value).It is explained using Figure 13 and Figure 14.Figure
Thermal image 103g shown in 13 (a) is the benchmark thermal image obtained in the case where people 102 is not present in field angle Φ.Due to
There are luminaires in field angle Φ, therefore there are the higher regions of temperature in the region of luminaire.Shown in Figure 14
Composition in, which is stored in background data buffer 145.Next, thermal image 103h shown in Figure 13 (b)
It is the thermal image obtained in the case where people 102 is present in field angle Φ.Thermal image 103h is output to difference value processing unit
146.Difference value processing unit 146 obtains the difference of thermal image 103h with the thermal image 103g for being stored in background data buffer 145
Value.The image becomes thermal image 103i shown in Figure 13 (c).Since the thermal image has been subtracted the part of ambient temperature,
C value is found out without carrying out subtraction process the composition such as Fig. 2 in operational part 130.For the thermal image 103i of acquisition, lead to
The average value for obtaining each pixel using region more than predetermined temperature as the region for being equivalent to people 102 is crossed, temperature can be found out
Difference value (C value).Then, based on the temperature difference value (C value) found out, warm-cold sensitivity can be inferred in warm-cold sensitivity inferring portion 134.
In this way, this effect of air conditioner can more inexpensively be constituted by having due to no longer needing temperature sensor 120
Fruit.In addition, can also be reliably detected out and be equivalent to by acquisition difference value even if there are the thermal objects of luminaire etc.
The region of people.In addition, here, in field angle Φ whether someone, the thermal map of acquisition can also be compared according to time series
Picture, there is no be judged as nobody in the case where variation more than the stipulated time.Stipulated time is, for example, 5 minutes or so appropriate,
Both it can suitably be set according to specification, and also can be set to and be able to carry out adjustment.
In addition, air conditioner 100 is typically found in the position higher than the position of people 102, in general, the high temperature in position become compared with
High temperature.Accordingly it is also possible to which the value of certain temperature lower than the value measured by temperature sensor 120 is set as ambient temperature
(B value).Alternatively, it is also possible to be provided with air conditioner 100 height, position and other conditions correspondingly, make by temperature sensing
The value that device 120 measures deviates certain temperature to be set as ambient temperature (B value).
In addition, variation further explained below.
Here, air conditioner 100 also has receiver 180.In the above-described embodiments, installation has been used as temperature sensor
In the temperature sensor 120 of air conditioner 100, here, about being carried out with being different from the temperature sensor set in addition of air conditioner 100
The case where measurement, is illustrated.
(variation 5)
Figure 15 A is the figure for indicating the composition of the air conditioner 100 about variation 5.Variation shown in Figure 15 A is to be different from
100 ground of air conditioner is additionally provided with the composition of remote controler 191.Remote controler 191 has temperature sensor 193 and transmitter 194.It is logical
Often, remote controler 191 is used in the opening and close of the movement of air conditioner 100, the adjustment of wind direction, air quantity, temperature etc., in the variation 5
In, temperature sensor 193 is added in remote controler 191 to measure ambient temperature.
Transmitter 194 is output to by the ambient temperature that temperature sensor 193 measures, and from there in air conditioner
Receiver 180 in 100 is transmitted wirelessly.Movement after this is identical as above content.In general, the position of remote controler 191
In the main body than air conditioner 100 close to the position of indoor people, therefore become by the temperature that remote controler 191 measures closer to room
The temperature of the ambient temperature of interior people.The warm-cold sensitivity inferred in operational part 130 as a result, also further improves precision, can
More comfortable ambient enviroment is provided.
(variation 6)
Figure 15 B is the figure for indicating the composition of the air conditioner 100 about variation 6.
Variation shown in Figure 15 B is the composition for being different from 100 ground of air conditioner and being additionally provided with wearable terminal 192.With it is distant
Control device 191 is identical, and wearable (wearable) terminal 192 has temperature sensor 193 and transmitter 194.Wearable terminal 192
It is dressed by indoor people.As wearable terminal 192, the e.g. activities meter (active amount meter) of bracelet type
Etc. various terminals either smart phone, is also possible to the smartwatch etc. of Wristwatch-type, can also be intelligence in addition to this
The others terminal such as glasses.By by be installed on ambient temperature that this temperature sensor 193 for being worn over device at one's side measures from
Transmitter 194 is sent to the receiver 180 of air conditioner 100.Movement later is identical as above content.
In this way, for the ambient temperature of the device measurement being worn at one's side by wearable terminal 192 etc., due to directly measuring
The ambient temperature of people, therefore the precision for the warm-cold sensitivity inferred in operational part 130 further increases, and is capable of providing more comfortable week
Collarette border.
(variation 7)
The case where inferring ambient temperature to according to thermal image and not temperature sensor is illustrated.Figure 16 be indicate about
The figure of the composition of the air conditioner 100 of variation 7.Replace temperature sensor 120 in the composition of Figure 16 and has ambient temperature deduction
This point of portion 147, it is different from the composition of Fig. 2.Ambient temperature inferring portion 147 inputs thermal image from thermal image acquisition unit 110, and calculates
Ambient temperature (B value) out.Here, the processing in ambient temperature inferring portion 147 is illustrated.
Figure 17 (a) is the thermal image 103j shot by thermal image acquisition unit 110, and is set as comprising being equivalent to people 102 and shining
The region of funerary objects tool.In addition, setting ambient temperature as 23 DEG C or so, the skin temperature of face is averagely 33 DEG C or so, jacket 102a's
Temperature is 27 DEG C or so, and the temperature of both hands (exposed division) is 30 DEG C or so, and the temperature of trousers 102b is 28 DEG C or so, both feet (dew
Portion out) temperature be 29 DEG C or so.
Statistical chart (the histogram: histogram, column of thermal image 103j is calculated in ambient temperature inferring portion 147
Figure).The statistical chart is indicated in Figure 17 (b).Example as described above is such, and consideration sets 26 DEG C to 40 DEG C among this
For the region for being equivalent to people, and it will in addition to this be set as indoor background area.It then, will be other than being equivalent to the people 102
23 DEG C of mode value detected as ambient temperature (B value).In thermal image 103j, other than being equivalent to people
In region, there is also the regions for being equivalent to luminaire, but the ratio of the usually heater in addition to indoor people is smaller,
Therefore by obtaining the mode value in the region other than being equivalent to people, ambient temperature can accurately be found out.In this way, energy
Temperature sensor 120 is enough omitted, therefore is capable of providing more cheap air conditioner.
(variation 8)
It can also be answered in by the temperature for temperature sensor 120 (such as Fig. 2 the constitute) measurement for being installed on air conditioner 100
It is calculated with statistical chart.For example, being measured in temperature accuracy ± 2 DEG C of temperature sensor 120, in turn by temperature sensor 120
Temperature such as Figure 17 (c), can also will be in the statistical chart of the thermal image 103j in 24 DEG C ± 2 DEG C like that in the case where 24 DEG C
Mode value (in Figure 17 (c) be 23 DEG C) be used as ambient temperature (B value).In such manner, it is possible to more precisely infer ambient temperature
(B value).In addition, in general, air conditioner is also installed on higher position, therefore the temperature measured by temperature sensor 120 indoors
It is mostly higher than the ambient temperature of people.It as a result, can also will be in the temperature of predetermined temperature lower than temperature measured by temperature sensor 120
It joined existence range of the range of measured deviation etc. as ambient temperature (B value) in degree.
(variation 9)
Infer that the other methods of ambient temperature are illustrated to according to thermal image.Figure 18 (a) indicates that air conditioner 100 is installed on
The state of indoor wall surface, thermal image acquisition unit 110 have the field angle θ of up and down direction.In the field angle θ of the up and down direction
Among, thermal image acquisition unit 110 is configured with comprising indoor ceiling 104 and the mode on floor 105.In addition, indoors, people
102 stand and enter the inside of the field angle θ of the up and down direction of thermal image acquisition unit 110.It will be obtained in this state by thermal image
The thermal image for taking portion 110 to obtain is shown schematically in Figure 18 (b) as thermal image 103k.In thermal image 103k, remove
Be equivalent to except the region of people 102, there is also be equivalent to the region of ceiling 104 be equivalent to floor 105 region this two
Person.Here, the also temperature of the temperature in the available region for being equivalent to floor 105 and the region for being equivalent to ceiling 104, and general
Ambient temperature of the average value as people 102.Rise generally, due to warm air, therefore the temperature of ceiling is than the temperature on floor
Degree is high.It is located at the substantially centre on ceiling and floor around position as where people, is equivalent to smallpox by obtaining
The average value of the temperature in the region of plate 104 and the temperature for being equivalent to floor 105, can accurately infer ambient temperature.In this way,
Since temperature sensor 120 can be omitted, it is capable of providing more cheap air conditioner.
In addition, being equivalent to the region on floor 105 can also be used as temperature near the standing place of people 102, it is equivalent to day
The temperature in the region of card 104 can also be extracted among the pixel of the most uplink of thermal image 103k, selection method not by
It limits.In addition, here, using temperature and the temperature in the region for being equivalent to floor 105 in the region for being equivalent to ceiling 104
Average value is but it is also possible to be value except the average, and for example, it can be in the case where inferring the temperature of lower position
It improves the ratio for the temperature in region for being equivalent to floor 105, improve phase in the case where inferring the temperature of higher position on the contrary
When the ratio of the temperature in the region of ceiling 104 calculates, which is not limited.
(variation 10)
So far, describing for people 102 is common positive thermal image, actual indoor situation, in addition to this
Also consider other various situations.Here, as other situations, the case where to towards rear and just in and out of the shape in cold place
The operation method of the relevant operational part of condition is illustrated.
The thermal image 103m of Figure 19 (a) is directed towards the thermal image of positive people 102.The thermal image 103n of Figure 19 (b) is court
The thermal image of people 102 rearward.The thermal image 103p of Figure 19 (c) is after just entering the room from cold place towards positive people
102 thermal image.Figure 20 A is the figure for indicating the composition of the air conditioner 100 about variation 10.The variation shown in Figure 20 A
In, the composition of the human body temperature calculation part 148 of operational part 130 is different from the composition of Fig. 2.
Human body temperature calculation part 148 analyzes the thermal image sent from thermal image acquisition unit 110, finds out and is equivalent to people's 102
The average value (A value) of the temperature in region.In addition, human body temperature calculation part 148, which is found out, is equivalent to the temperature in the region of people 102 most
Big value (D value).Then, in human body temperature calculation part 148, according to the maximum value (D value) of the average value (A value) of temperature and temperature
Distinguish what state the people 102 in thermal image is now arranged in.For example, the average value (A value) in temperature does not enter defined range
Interior (such as 25 DEG C ± 3 DEG C) but in 22 DEG C of situations below, be judged as and just enter the room from cold place and whole body is cold.Together
Sample is judged as and just enters the room from hot place in the case where 28 DEG C or more.25 DEG C ± 3 are in the average value (A value) of temperature
DEG C range and temperature maximum value (D value) be such as 31 DEG C of situations below under, be judged as towards rear.This is because logical
Often, the temperature of face is 33 DEG C or so, if this temperature below, then it is assumed that be not capable of measuring the temperature of face, therefore be judged as
Towards rear.
In this way, can conclude that shape people 102 is in by the average value (A value) and maximum value (D value) of combination temp
State.Accordingly, for thermal image 103p shown in Figure 19 (c), as shown in Figure 19 (d), the average value (A value) of temperature is in 25
Outside DEG C ± 3 DEG C of range, therefore it is judged as the state entered the room from cold place.Although temperature is put down for thermal image 103n
Mean value (A value) is in the range of 25 DEG C ± 3 DEG C, but since the maximum value of temperature (D value) is 31 DEG C hereinafter, being therefore judged as not
It is in an interim state and be directed towards rear.For thermal image 103m, the average value (A value) of temperature is in 25 DEG C ± 3 DEG C of range
Interior, the maximum value (D value) of temperature is also 31 DEG C or more, therefore is judged as and is not at transition state and is directed towards front.
For being judged as towards positive thermal image 103m, it regard the average value (A value) of temperature as human body temperature calculation part
Calculated result, i.e. human body temperature (E value) in 148.On the other hand, it is being judged as from cold as thermal image 103p
In the case where the state that place is entered the room, infer without warm-cold sensitivity but directly issue and instruct to control unit 160, makes one 102 temperature
It is warm.In addition, in the case where being judged as thermal image 103n towards rear, by the rule of the average value (A value) of temperature
Corrected value as the constant times of definite value is as human body temperature (E value).Obtain the human body temperature (E value) that sets in this way with from
The difference value for the ambient temperature (B value) that temperature sensor 120 obtains is inferred so as to find out temperature difference value (C value) in warm-cold sensitivity
Warm-cold sensitivity is inferred in portion 134 and is controlled.Even in this way, the transition state of people, not towards positive state, also can be into
Row is corresponding with the warm-cold sensitivity of people to be controlled.
In addition, as long as there is the body state judging part 149 for the state that can judge human body as the composition of Figure 20 B
, the average value (A value) that human body temperature calculation part 148 corrects temperature can also not had to.In other words, sentence with body state
The disconnected judgement of portion 149 is people 102 towards in the case where rear, can pass through the value with 135 calibration setup point Tc of set point configuration part
It carries out warm-cold sensitivity deduction, when judgement is the state entered the room from cold place, can also still infer without warm-cold sensitivity
But it is warm directly to make one 102 to the sending instruction of control unit 160.
In addition, among the above, as the putting down according to temperature in human body temperature calculation part 148, body state judging part 149
Mean value (A value), maximum value (D value) judge the benchmark of the state of people, and showing temperature range is 25 DEG C ± 3 DEG C, maximum value 31
DEG C this judgement benchmark.But these temperature certainly example, other values can also be used.
Moreover, judgement is that people 102 is continued towards rear specified time limit (such as 10 minutes in body state judging part 149
Left and right) more than in the case where, the thermal image that also can use alert mechanism (not shown) warning people 102 towards air conditioner 100 obtains
Take the direction in portion 110.In this way, without changing set point Tc or correcting the average value (A value) of temperature, it will be able to accurately infer
Warm-cold sensitivity, therefore it is capable of providing comfortable ambient enviroment.In addition, mechanism by way of caution, except being guided except through sound,
Both it can make to be installed on main body, display lamp (not shown) etc. and light, remote controler etc. can also be made to show its order, can also be
Other mechanisms are not defined the mechanism here.It, can be in addition, the specified time limit given a warning can not be 10 minutes
It is longer or shorter.
(variation 11)
So far, the entirety in the region for being equivalent to people in thermal image is summarized as one and is handled, in the deformation
In example, the example in the case that the region division that will be equivalent to people is handled for multiple human bodies is illustrated.Figure 22 is
Indicate the figure of the composition of the air conditioner 100 about variation 11.In the variation shown in Figure 22, operational part 130 has position
Discrimination section 150 and weighted addition portion 151.
For example, the temperature of the people of sympotoms caused by cold factors especially trick is easy to be become by external temperature influence close to ambient temperature
Temperature.In this case, the difference of the position as hand, foot and ambient temperature becomes smaller, and such case is judged as heat dissipation
It measures smaller.Therefore, in the variation, weighting is imposed to each human body.Shown in the such as Figure 21 of position discrimination section 150 that
Sample distinguishes head, body part, hand, the leg, foot being equivalent in the region of people 102, is divided into five human bodies.So
Afterwards, average value of the position discrimination section 150 to each calculating temperature of the multiple human bodies marked off.Weighted addition portion 151
The temperature averages by the calculated each human body of position discrimination section 150 are inputted, and flat to the temperature of each human body
Mean value assigns weighting.Temperature difference value calculation part 133 is according to the average value (F value) and ambient temperature (B value) of the temperature after weighting
Find out temperature difference value (C value).Alternatively, it is also possible to not calculate the temperature averages of everyone body region, respectively to each human body
The temperature for whole pixels that position is included assigns weighting, also can get identical temperature averages (F value) as a result.
Here, reduce the human body (exposed division) as exposing hand and foot weighting in the case where, energy
Enough warm-cold sensitivities for more accurately reflecting people, and can accurately infer warm-cold sensitivity.In addition, here, as human body, using
Head, body part, hand, leg, foot this five, but the discrimination of five human bodies is not limited, both can to more
More human bodies are distinguished, can also be distinguished less human body.Moreover, adding about each human body
Power, can also combine with that people's discrimination section 143 shown in Fig. 9 to carry out.It is distinguished that is, can also assign by people's discrimination section 143
, the weighting of each human body to vary with each individual.At this point, the coefficient in buffer 144 with weighting can also be made.
(variation 12)
Figure 23 is the figure for indicating the composition of the air conditioner 100 about variation 12.
In the variation shown in Figure 23, operational part 130 has weighted addition portion 151 and temperature range cutting part 152.
Temperature range cutting part 152 is as shown in Figure 24 by the region segmentation for being equivalent to people 102 in acquired thermal image
At multiple (being six in Figure 24) temperature ranges.In turn, temperature range cutting part 152 analyzes the pixel number in each temperature range
With how many a pixels.Weighted addition portion 151 assigns weighting to each range being partitioned by temperature range cutting part 152.For example,
Among the temperature range being partitioned into, the weighting of the range close to the relatively low temperature of external air temperature also can reduce.So
Afterwards, weighted addition portion 151 calculates the average value of each temperature range after weighting as human body temperature (F value).Temperature difference value
Calculation part 133 finds out temperature difference according to by the calculated human body temperature in weighted addition portion 151 (F value) and ambient temperature (B value)
It is worth (C value).Even if also can more accurately infer warm-cold sensitivity in the case where hand, foot are cold as a result,.
In addition, here, as the countermeasure of sympotoms caused by cold factors, the weighting of low temperature side is reduced among the region for being equivalent to people 102.But
It is that the weighting coefficient can also be changed according to purpose and arbitrarily, here, the coefficient and segmentation number is not defined.
(variation 13)
Next, processing when being sitting in the rear of table 106 to people 102 is illustrated.Figure 26 is indicated about variation 13
Air conditioner 100 composition figure.In the variation shown in Figure 26, operational part 130 has layout inferring portion 153.
It is shot due to the furniture configured with table, frame etc. by thermal image acquisition unit 110 in the interior in living room etc.
Thermal image in, the case where being blocked there are a part of body and carried out shooting.For example, if in the people as Figure 25 (a)
102 lower part of the body shoots thermal image in the case where being blocked by table 106, then as the thermal image 103r of Figure 25 (b), takes down
Half body is still blocked.In addition, the dotted line in Figure 25 (b) is supplemented to indicate the configuration of table 106, it is not offered as temperature letter
Breath.Therefore, layout inferring portion 153 infers the layout in room according to the thermal image obtained from thermal image acquisition unit 110, and according to
The layout of deduction is the temperature information of whole body or a part of body come the surface temperature information for inferring people 102 obtained
Temperature information.In the case where as thermal image 103r being only the image of the upper part of the body of body, in the region that judgement is people 102
Interior, the ratio in the region of the relatively high face of temperature becomes larger, because this person 102 surface temperature average value than body
The average value of surface temperature is high.Infer that thermal image 103r is only the image of the upper part of the body of body in layout inferring portion 153 as a result,
In the case of, improve the set point Tc set in set point configuration part 135.Even if as a result, in the family configured with table 106, frame etc.
In that case of tool, warm-cold sensitivity also can be accurately inferred.Thereby, it is possible to realize the control for being in the air conditioner of virtual condition
System.
Furthermore it is possible to be foot by the position prediction of lower side in thermal image, distinguishing region for people.Cloth as a result,
Position of office's inferring portion 153 for example in the thermal image obtained by thermal image acquisition unit 110 to the lower side for distinguishing the region for people
Lasting plotting (being in other words the track for finding out people's walking) is set, and by the region not being plotted in region as configured with table etc.
The region of furniture learn, so as to infer layout.The method of deduction is not limited to this method certainly, can also be with not scheming
The CCD camera etc. shown is shot, and is inferred by image recognition, here, is not defined to this method.
(variation 14)
Next, the warm-cold sensitivity deduction to the people towards horizontal side is illustrated.Figure 28 is the sky indicated about variation 14
The figure of the composition of tune machine 100.In the variation shown in Figure 28, operational part 130 has people towards inferring portion 154.
In the case where people is towards horizontal side, compared with towards in positive situation, the relatively high face portion of temperature
The ratio in region reduces, therefore the average value of the surface temperature of the people found out according to thermal image reduces.Therefore, people is towards inferring portion
154 infer the direction of people according to the thermal image obtained from thermal image acquisition unit 110.For example, being inferred as according to thermal image 103s
People 102 is towards in the case where right side, and people is towards inferring portion 154 as being averaged according to the calculated surface temperature of thermal image 103s
Value is lower calculated, and reduces the set point Tc set in set point configuration part 135.Even if as a result, in people not towards just
In the case where face, warm-cold sensitivity also can be accurately inferred.Thereby, it is possible to realize the control for being in the air conditioner of virtual condition.
In addition, using people towards inferring portion 154, learn for example in the case where people is towards horizontal side, as thermal image 103s that
It is not bilateral symmetry that sample, which is identified as the Temperature Distribution on the top of people 102,.Thereby, it is possible to be pushed away according to the Temperature Distribution on image top
The direction of disconnected people.In addition, here, being illustrated to towards the case where horizontal side, capable of being also directed towards the feelings at rear certainly
Condition.For example, although the temperature of the face of people is usually 33 DEG C or so, the Temperature Distribution on the top in the region for being equivalent to people
Maximum value be significantly lower than 33 DEG C in the case where, be inferred as being influenced by hair and temperature being caused lower to be measured.As a result,
In this case, it can conclude that as towards rear.Certainly, infer that the method for the direction of people is also possible to other methods, such as
It can be shot with CCD camera (not shown) etc., be inferred by identifying purpose position etc. by image recognition, it is here, not right
This method is defined.
[the 2nd embodiment]
The air conditioner 200 of 2nd embodiment of the invention is in the air conditioner 100 shown in the 1st embodiment, can
Constituting for notification unit 210 is equipped with by the position of 102 visual confirmation of people.
Figure 29 is the figure that outlined the appearance of air conditioner 200 of the 2nd embodiment of the invention.It is empty in Figure 29
Tune machine 200 includes to be installed on thermal image acquisition unit 110 before shell, be installed on internal operational part 230 and control unit
160.Thermal image acquisition unit 110 is identical as the composition illustrated in the 1st embodiment, and the field angle Φ with left and right directions,
The two-dimensional thermal image of the object for the front space for being present in air conditioner 200 can be measured.The thermal image that can obtain with the 1st
The thermal image described in embodiment is identical, therefore omits explanation again here.
Next, being illustrated using composition of the Figure 30 to air conditioner 200 with function.Comprising by thermal image acquisition unit 110
The thermal image of the Temperature Distribution of the people of acquisition is sent to operational part 230.Operational part 230 is according to defeated from thermal image acquisition unit 110
The thermal image entered determines the position of people 102, and infers warm-cold sensitivity.About the deduction of the warm-cold sensitivity carried out by operational part 230,
It can be inferred as the first embodiment described above according to the difference value of human body temperature and ambient temperature, but as other methods,
It can also be inferred according to the temperature of the hand of the people obtained from thermal image, nose, furthermore, it is not necessary to inferred according to thermal image,
Here, this method is not defined.
Warm-cold sensitivity and position of the control unit 160 based on the people 102 inferred by operational part 230, control shutter 171, compression
Machine 172 and fan 173, in order to cosily keep people 102 ambient temperature act.In addition to this, in present embodiment
In, assign the warm-cold sensitivity of the people 102 inferred by operational part 230 to notification unit 210.Notification unit 210 includes set on air conditioner 200
The display unit of main body, such as LED.Warm-cold sensitivity of the LED based on the people 102 inferred by operational part 230 and be changed luminous
Color.For example, being with green emitting if people 102 is comfortable, if being inferred as heat with red, orange if inferring in operational part 230
Deng warm colour shine, if be inferred as it is cold if shone with blue, cool colour as water colour.
In this way, people 102 can judge how air conditioner 200 is inferring the warm-cold sensitivity of oneself immediately.Thereby, it is possible to predict
It will be carried out air conditioning strongly after this or because close to substantially comfortable the air conditioning after this subtracts
It is weak, therefore have and no longer feel effect as uneasiness.
In addition, if being had differences in the warm-cold sensitivity for being shown in notification unit 210 and the warm-cold sensitivity oneself currently experienced
In the case where, such as can be changed by that remote controler 291 shown in Figure 31 by the set point configuration part in operational part 230
The set point Tc (correction warm-cold sensitivity) of 135 settings.For example, in notification unit 210 just with green emitting (be inferred as comfortable) the case where
Under, but when people 102 feels heat, " heat " of remote controler 291 this button can be pressed to indicate to correct.It is corresponding to the pushing of button
Signal receiver 280 shown in the composition in Figure 32 that ground is sent from remote controler 291 is received as amendment receiving portion, is connect
The signal of receipts is transferred to the set point configuration part 135 in operational part 230.For example, in the base as shown in the 1st embodiment
In the case that the difference value of human body temperature and ambient temperature infers warm-cold sensitivity, it will be carried out slightly largerly as the set point Tc of threshold value
It sets (change).In this way, control unit 160 is by reducing the temperature of compressor 172, to make one 102 ambient temperature
It reduces, can be in comfortable.
As described above, by making the set point configuration part 135 in air conditioner 200 identify current sense with remote controler 291 etc.
The warm-cold sensitivity being subject to is capable of providing optimized comfortable ambient enviroment to everybody.In addition, at this point, can also be such as the 1st
As shown in Figure 9, the individual of determining setting simultaneously makes the setting of warm-cold sensitivity be stored in buffer 144 to embodiment, thereby, it is possible to
Realize the optimized comfortable air conditioner for used individual.
In addition, using three colors as luminous color, but also can of course be according to away from set point Tc among the above
The luminous color of offset simulation ground change, other colors can also be used.
In addition, in the above example, the notice of the warm-cold sensitivity of people is illustrated using the LED for being set to notification unit 210, except this with
Outside, display unit set by such as remote controler 291 can also be shown in character etc..That is, can also be as shown in Figure 34, it will be by transporting
The warm-cold sensitivity that calculation portion 230 infers is sent from transmitter 294 towards remote controler 291, and carry out such as Figure 33 of received remote controler 291 that
Sample is by received as the result is shown on the picture of display unit.In this way, people 102 can judge immediately air conditioner 200 currently as
What is inferred.Thereby, it is possible to predict that air conditioning will be carried out strongly after this or because close to substantially comfortable
So the air conditioning after this weakens, therefore has and no longer feel effect as uneasiness.In addition, can certainly be such as Figure 35
Like that, it according to the thermal image of acquisition, is shown in a manner of knowing the warm-cold sensitivity of more people.In addition, here, as notification unit
Warm-cold sensitivity is shown with character on 210 remote controler, shows warm-cold sensitivity, but the machine as notice with the color of LED on air conditioner
Structure is also possible to mechanism in addition to this, such as smart phone, tablet computer, is not defined here to the mechanism.
For example, it can be operational part 230 generates following correction images, which seems operational part in thermal image
The region for being equivalent to people coordinate periphery make the character or Overlapping Symbol of warm-cold sensitivity of the people in representation space made of,
And notification unit 210 makes correction image be shown in display unit, to notifying the warm-cold sensitivity of the people in space to the people in space.By
This, can show the warm-cold sensitivity inferred results in relation to the people in the lesser display area such as the display unit of remote controler.In addition, i.e.
Make to be the user for not knowing the function of being equipped with warm-cold sensitivity deduction in system for example, can also recognize the display is system to certainly
The display for the result that oneself warm-cold sensitivity is inferred.
In addition, notification unit 210 can also via network to the terminal notification other than air conditioner 200 by the people in representation space
Warm-cold sensitivity image, character or symbol be shown in the terminal display unit instruction.Here, the end other than air conditioner 200
As long as holding smart phone, hand-written panel etc. that there is display function, the terminal of communication function.User is without deliberately as a result,
Hold with a hand remote controler, it will be able to infer situation with the current warm-cold sensitivity of the grasps such as the smart phone held always.
In addition, notification unit 210 can also send thermal image and operational part to the terminal other than air conditioner 200 via network
Be equivalent to determined by 230 the region of people the related information of coordinate and will be in the thermal image generated of operational part 230
Be equivalent to the periphery of the coordinate in the region of people, make people in representation space warm-cold sensitivity character or Overlapping Symbol made of school
Positive image is shown in the instruction of the display unit of the terminal.That is, air conditioner 200 is only by sending required information to external end
End will be corrected the generation and display of image in external terminal.It is corrected as a result, without being generated with air conditioner 200
The important processing of image etc., therefore reduce the treating capacity of 200 side of air conditioner.
Alternatively, it is also possible to be, operational part 230 generates correction image, which seems phase of the operational part in thermal image
Made of the periphery of the coordinate in the region of people makes the character or Overlapping Symbol of the warm-cold sensitivity of the people in representation space, notice
Portion 210 is shown in this order of the display unit of the terminal to terminal notification high-ranking officers' positive image other than air conditioner 200 via network
Instruction.That is, air conditioner 200 generates required correction image, external terminal only carries out showing the processing of the correction image.By
This, without making external terminal storage be used to generate the special algorithm (algorithm) of correction image, user just be will appreciate that
Current warm-cold sensitivity infers situation.
Moreover, operational part 230 can also determine the temperature of the people in space based on the Temperature Distribution in the region for being equivalent to people
That is human body temperature, and around obtaining based on human body temperature and according to the temperature in the region other than the region for being equivalent to people
The difference value of temperature infers the warm-cold sensitivity of the people in space.
In addition, illustrating position determining portions 131 according to by thermal image acquisition unit in above-mentioned 1st and the 2nd embodiment
110 thermal images obtained determine the example of the position of people.But the method for determining the position of people is not limited to this method,
It can be other methods.For example, it is also possible to based on the sensor set in addition such as air conditioner 100 and 200 is different from, (heat releases biography
Sensor (pyroelectric sensor), video camera, millimetre-wave radar etc.) information determine the position of people.
In addition, in above-mentioned 1st and the 2nd embodiment, it can also be by people's determined by related position determining portions 131
The information of position is output to human body temperature calculation part 132.It is carried out thus, it is possible to reduce or omit human body temperature calculation part 132
" analysis thermal image and the region for being inferred as being equivalent to people 102 is judged " processing.
[application mode]
In above-mentioned 1st and the 2nd embodiment, illustrate to be assembled with the composition and/or deduction for obtaining thermal image
The air conditioner of the composition of the warm-cold sensitivity of people.However, it is also possible to will acquire the composition of thermal image and/or infer the warm-cold sensitivity of people
Composition modularization and form individual composition.
For example, can be as shown in figure 36, by thermal image acquisition unit 110, human body temperature calculation part 132, temperature difference value meter
135 modularization of calculation portion 133, warm-cold sensitivity inferring portion 134 and set point configuration part, to form the thermal image with versatility
Sensing system 300.If carrying out modularization like this, the air-conditioning for being equipped with thermal image sensor system 300 can be expected
It is the miniaturization of machine, cost effective.Like this with versatility thermal image sensor system 300 in, both can with air conditioner from
The temperature sensor that self or remote controler has supplies required ambient temperature to temperature difference value calculation part 133, can also
To be inferred including, for example, ambient temperature inferring portion 147 according to the thermal image obtained by thermal image acquisition unit 110 in composition
Ambient temperature needed for temperature difference value calculation part 133.Like this modularization and form individual composition, thermal image can be passed
Sensor system 300 is installed on the device other than air conditioner.Device other than air conditioner be, for example, video camera, lighting apparatus or
The mobile terminal etc. of smart phone etc., is not specifically limited.
In addition, can also will infer that the composition of the warm-cold sensitivity of people is formed as software individually constitutes (not shown).That is,
Be also possible to be written with related human body temperature calculation part 132, temperature difference value calculation part 133, warm-cold sensitivity inferring portion 134 and
The record media (including disk, external memory etc.) of the processing (program) of set point configuration part 135.In addition, being mentioned via network
For related human body temperature calculation part 132, temperature difference value calculation part 133, warm-cold sensitivity inferring portion 134 and set point configuration part
The behavior of 135 processing (program) is also included.In this case, the main body of the software is handled either being installed on air-conditioning
The operational part of machine is also possible to the operational part that PC (personal computer), smart phone etc. are included, can also be via network cloud
Server etc. is handled.In this case, the information in relation to thermal image is obtained from outside.
Modularization described herein forms the example individually constituted as software and is not limited to example described above
Son, if the composition modularization of a part in the composition for being included by operational part 130 or operational part 230 or as software and
It is formed and is individually constituted.
In addition, composition shown in embodiments described above is an example, it can be in the purport for not departing from invention
It is self-evident that various modifications this point is added in range.In addition, above-described each embodiment can also be applied in combination certainly
Or invention made of deforming them.
Industrial utilizability
Air conditioner in the present invention by accurately inferring the warm-cold sensitivity of people with cheap being constituted, thus even if without
Operation is also capable of providing comfortable ambient enviroment, more practical.
Description of symbols
100,200 air conditioner
102 people
102a jacket
102b trousers
103a~103s thermal image
104 ceilings
105 floors
106 tables
110 thermal image acquisition units
120,193 temperature sensor
130,230 operational part
131 position determining portions
132,148 human body temperature calculation part
133 temperature difference value calculation parts
134 warm-cold sensitivity inferring portion
135 set point configuration parts
136 circadian rhythm storage units
137,190 clock
138 circadian rhythm determination units
139 activity operational parts
140,144 buffer
141 heatings/refrigeration judging part
142 calendar portions
143 people's discrimination sections
145 background data buffers
146 difference value processing units
147 ambient temperature inferring portion
149 body state judging parts
150 position discrimination sections
151 weighted addition portions
152 temperature range separation units
153 layout inferring portion
160 control units
171 shutters
172 compressors
173 fans
180,280 receiver
191,291 remote controler
192 wearable terminals
194,294 transmitter
210 notification units
300 thermal image sensor systems
Claims (28)
1. a kind of air conditioner, for carrying out the airconditioning control in space, which has:
Thermal image acquisition unit obtains the thermal image for indicating the Temperature Distribution in above-mentioned space;
Operational part, (i) in the above-mentioned thermal image acquired in above-mentioned thermal image acquisition unit, to the exposed portion comprising people and clothing
Partial, to be equivalent to people region is determined, and the Temperature Distribution of (ii) based on the above-mentioned region for being equivalent to people determines in space
People comprising clothing temperature, that is, human body temperature, (iii) is equivalent to people's based on above-mentioned human body temperature and according in addition to above-mentioned
The temperature in the region other than region and the difference value of ambient temperature that obtains infer the warm-cold sensitivity of the people in above-mentioned space;And
Control unit, the warm-cold sensitivity of the people in above-mentioned space inferred based on above-mentioned operational part, control above-mentioned air conditioner air quantity,
At least one of wind-warm syndrome, wind direction,
Above-mentioned operational part is based on the difference of above-mentioned difference value and defined threshold value, to infer the warm-cold sensitivity of above-mentioned people, above-mentioned difference value
It is the difference value of above-mentioned human body temperature Yu above-mentioned ambient temperature.
2. air conditioner as described in claim 1,
It is above-mentioned in the case that the difference value obtained by above-mentioned human body temperature subtracts above-mentioned ambient temperature is greater than above-mentioned defined threshold value
Control unit is controlled in a manner of increasing above-mentioned ambient temperature, and it is poor obtained by above-mentioned ambient temperature to subtract in above-mentioned human body temperature
In the case that score value is less than above-mentioned defined threshold value, above-mentioned control unit is controlled in a manner of reducing above-mentioned ambient temperature.
3. air conditioner as described in claim 1,
Above-mentioned operational part corrects above-mentioned defined threshold value based on the activity of people.
4. air conditioner as described in claim 1,
Above-mentioned operational part is carrying out refrigeration operation or heating operation based on above-mentioned air conditioner to correct above-mentioned defined threshold value.
5. air conditioner as described in claim 1,
Above-mentioned operational part corrects above-mentioned defined threshold value based on ambient temperature.
6. air conditioner as described in claim 1,
Above-mentioned operational part is determined based on the temperature averages of whole pixels in the region for being equivalent to people in above-mentioned thermal image
State human body temperature.
7. air conditioner as described in claim 1,
Above-mentioned operational part by the above-mentioned region division for being equivalent to people at multiple human bodies, and to each of multiple human body
It is a to be weighted, above-mentioned human body is determined based on the temperature averages of whole pixels in the above-mentioned region for being equivalent to people after weighting
Temperature.
8. air conditioner as claimed in claim 7,
The human body that above-mentioned operational part exposes the skin in above-mentioned multiple human bodies subtracts compared to other human bodies
Small weighting.
9. air conditioner as described in claim 1,
Above-mentioned operational part by the above-mentioned region division for being equivalent to people at multiple temperature ranges, and to each of multiple temperature range
It is a to be weighted, above-mentioned human body is determined based on the temperature averages of whole pixels in the above-mentioned region for being equivalent to people after weighting
Temperature.
10. air conditioner as claimed in claim 9,
Above-mentioned operational part reduces the weighting of the lower side of temperature in above-mentioned multiple temperature ranges, and increases the higher side of temperature
Weighting.
11. air conditioner as described in claim 1,
The temperature averages and whole of whole pixels of the above-mentioned operational part based on the region for being equivalent to people in above-mentioned thermal image
Temperature maximum in pixel determines above-mentioned human body temperature.
12. air conditioner as described in claim 1,
Above-mentioned operational part based in addition to it is above-mentioned be equivalent to the region of people other than region in pixel temperature mode value come really
Fixed above-mentioned ambient temperature.
13. air conditioner as described in claim 1,
Above-mentioned operational part carries out the floor area for being included by the space in above-mentioned thermal image or/and ceiling region true
It is fixed, and above-mentioned ambient temperature is determined based on the temperature of the temperature of above-mentioned floor area or/and above-mentioned ceiling region.
14. air conditioner as described in claim 1,
With above-mentioned operational part will be worn over by the people in above-mentioned space or it is installed on the temperature sensor of the object with being worn over
The value of measurement is used as above-mentioned ambient temperature.
15. air conditioner as described in claim 1,
Above-mentioned operational part by by be set to above-mentioned air conditioner and obtain the temperature around above-mentioned air conditioner temperature sensor survey
The value of amount or the value of the temperature sensor measurement by being installed on the remote controler that can remotely operate above-mentioned air conditioner are used as upper
State ambient temperature.
16. the air conditioner as described in any one of claims 1 to 15,
Above-mentioned operational part is using the region of the temperature of range as defined in the expression in above-mentioned thermal image as the above-mentioned area for being equivalent to people
Domain and determine.
17. the air conditioner as described in any one of claims 1 to 15,
Above-mentioned operational part is by the region of the temperature of range as defined in the expression in above-mentioned thermal image and is defined quantity or more
Continuous region is determined as the above-mentioned region for being equivalent to people.
18. air conditioner as described in claim 1, is also equipped with:
Notification unit notifies the warm-cold sensitivity of the people in above-mentioned space that above-mentioned operational part is inferred to the people in above-mentioned space.
19. air conditioner as claimed in claim 18,
Above-mentioned notification unit is set to by being shown in the image, character or symbol of the warm-cold sensitivity for indicating the people in above-mentioned space
On the display unit of above-mentioned air conditioner main body or the display unit of the remote controler set on above-mentioned air conditioner, so that notice is to above-mentioned space
Interior people.
20. air conditioner as claimed in claim 19,
Above-mentioned notification unit by make the display discoloration of above-mentioned display unit more and people into above-mentioned space notify in above-mentioned space
The warm-cold sensitivity of people.
21. air conditioner as claimed in claim 19,
Above-mentioned operational part generates correction image, and above-mentioned correction chart seems the above-mentioned region for being equivalent to people in above-mentioned thermal image
The periphery of coordinate makes made of indicating the character or Overlapping Symbol of the warm-cold sensitivity of the people in above-mentioned space,
People and above-mentioned notification unit shows above-mentioned correction image by making from above-mentioned display unit to above-mentioned space notifies above-mentioned space
The warm-cold sensitivity of interior people.
22. air conditioner as claimed in claim 18,
Above-mentioned notification unit will indicate the warm-cold sensitivity of the people in above-mentioned space via network to the terminal notification other than above-mentioned air conditioner
Image, character or symbol be shown in the terminal display unit instruction.
23. air conditioner as claimed in claim 18,
Above-mentioned notification unit sends (i) above-mentioned thermal image, (ii) related above-mentioned fortune to the terminal other than above-mentioned air conditioner via network
The information of the coordinate in the above-mentioned region for being equivalent to people, (iii) determined by calculation portion in relation to infer above-mentioned warm-cold sensitivity information, with
And the periphery of the coordinate in the above-mentioned region for being equivalent to people in above-mentioned thermal image that above-mentioned operational part generates is made to indicate by (iv)
Correction image made of the character or Overlapping Symbol of the warm-cold sensitivity of people in above-mentioned space is shown in the display unit of above-mentioned terminal
Instruction.
24. air conditioner as claimed in claim 18,
Above-mentioned operational part generates correction image, and above-mentioned correction chart seems the above-mentioned region for being equivalent to people in above-mentioned thermal image
The periphery of coordinate makes made of indicating the character or Overlapping Symbol of the warm-cold sensitivity of the people in above-mentioned space,
Above-mentioned correction image is shown in the terminal to the terminal notification other than above-mentioned air conditioner via network by above-mentioned notification unit
The instruction of display unit.
25. the air conditioner as described in any one of claim 18 to 24,
Above-mentioned air conditioner is also equipped with the modified amendment receiving portion for receiving inferred warm-cold sensitivity,
Above-mentioned operational part corrects the above-mentioned warm-cold sensitivity of deduction based on the information that above-mentioned amendment receiving portion is received.
26. the air conditioner as described in any one of claim 18 to 24,
Above-mentioned air conditioner is also equipped with the modified amendment receiving portion for receiving inferred warm-cold sensitivity,
Above-mentioned operational part is based on the difference of above-mentioned difference value and defined threshold value, to infer the warm-cold sensitivity of above-mentioned people, above-mentioned difference value
It is the difference value of above-mentioned human body temperature Yu above-mentioned ambient temperature, and is changed based on the information that above-mentioned amendment receiving portion is received
Threshold value as defined in above-mentioned.
27. air conditioner as described in claim 1, is also equipped with:
Temperature sensor obtains the temperature around above-mentioned air conditioner;
In the case that above-mentioned operational part ambient temperature acquired in above-mentioned temperature sensor is defined temperature field, determine above-mentioned
It is equivalent to the region of people in above-mentioned thermal image acquired in thermal image acquisition unit, and infers the above-mentioned sky in the region of the determination
The warm-cold sensitivity of interior people,
In the case that above-mentioned control unit ambient temperature acquired in above-mentioned temperature sensor is defined temperature field, based on above-mentioned
The warm-cold sensitivity for the people in above-mentioned space that operational part is inferred controls the air quantity of above-mentioned air conditioner, wind-warm syndrome, at least one in wind direction
Person.
28. air conditioner as claimed in claim 27,
In the case where above-mentioned ambient temperature is not defined temperature field, above-mentioned operational part without operation,
In the case where above-mentioned ambient temperature is not defined temperature field, above-mentioned control unit is correspondingly sentenced in above-mentioned ambient temperature
The control content of at least one of the disconnected air quantity in relation to above-mentioned air conditioner, wind-warm syndrome, wind direction is simultaneously controlled.
Priority Applications (4)
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CN201910289016.1A CN110081564B (en) | 2014-02-17 | 2015-02-17 | Thermal image sensor system and thermal sensation estimation method |
CN201910288510.6A CN110081566B (en) | 2014-02-17 | 2015-02-17 | Air conditioner, method for controlling same, thermal image sensor system, method for estimating thermal sensation, and recording medium |
CN201910288583.5A CN110081563B (en) | 2014-02-17 | 2015-02-17 | Recording medium having thermal sensation estimation program recorded thereon |
CN201910288426.4A CN109974244B (en) | 2014-02-17 | 2015-02-17 | Control method for air conditioner |
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JP2014027891 | 2014-02-17 | ||
PCT/JP2015/000714 WO2015122201A1 (en) | 2014-02-17 | 2015-02-17 | Air conditioner and thermal image sensor system |
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CN201910288583.5A Division CN110081563B (en) | 2014-02-17 | 2015-02-17 | Recording medium having thermal sensation estimation program recorded thereon |
CN201910289016.1A Division CN110081564B (en) | 2014-02-17 | 2015-02-17 | Thermal image sensor system and thermal sensation estimation method |
CN201910288510.6A Division CN110081566B (en) | 2014-02-17 | 2015-02-17 | Air conditioner, method for controlling same, thermal image sensor system, method for estimating thermal sensation, and recording medium |
CN201910288426.4A Division CN109974244B (en) | 2014-02-17 | 2015-02-17 | Control method for air conditioner |
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CN201910288583.5A Active CN110081563B (en) | 2014-02-17 | 2015-02-17 | Recording medium having thermal sensation estimation program recorded thereon |
CN201910288510.6A Active CN110081566B (en) | 2014-02-17 | 2015-02-17 | Air conditioner, method for controlling same, thermal image sensor system, method for estimating thermal sensation, and recording medium |
CN201910289016.1A Active CN110081564B (en) | 2014-02-17 | 2015-02-17 | Thermal image sensor system and thermal sensation estimation method |
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CN201910289016.1A Active CN110081564B (en) | 2014-02-17 | 2015-02-17 | Thermal image sensor system and thermal sensation estimation method |
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