CN115046296A - Household dynamic humidification method and device integrating thermal comfort and sensible temperature - Google Patents

Abstract

The invention discloses a home dynamic humidification method and a home dynamic humidification device integrating thermal comfort and somatosensory temperature, wherein the method comprises the following steps: monitoring indoor temperature and relative humidity in real time, and setting equivalent air flow rate; is calculated to bekThe instantaneous equivalent thermal comfort index and the sensible temperature; setting initial assignment weight coefficient and calculating the secondkOf time of dayPT ^k _int A value; according toPT ^k _int Value sumRH ^k _air Interval of value, set the second of the intelligent humidifierk+1The control mode of the moment comprises a non-starting humidifying mode, a conventional humidifying mode and a rapid excessive humidifying mode; entering the k +1 th moment, recalculating the equivalent thermal comfort index and the somatosensory temperature, and calculating the weight of the new momentA coefficient; repeating steps 5-7 above until the humidifier is turned off. The invention adopts an equivalent thermal comfort algorithm and a fusion algorithm, and a control method of dynamic humidification, conventional humidification and rapid over-humidification, thereby improving the comfort of human body.

Description

Household dynamic humidification method and device integrating thermal comfort and sensible temperature

Technical Field

The invention belongs to the technical field of air conditioning, and particularly relates to a household dynamic humidification method and device integrating thermal comfort and sensible temperature.

Background

The humidification modes of the traditional humidifier are generally manual switch humidification, timed humidification and automatic humidification. The traditional humidifier is provided with a humidity sensor, and the start and stop of the humidifier are controlled by monitoring indoor real-time humidity in real time and according to set upper and lower limit values of the humidity.

Above-mentioned traditional humidifier operation control mode can not carry out developments and accurate humidification control according to the interior space personnel travelling comfort demand in real time effectually, and the indoor dry bulb temperature of actual humidification effect has not been considered, whether indoor have other air conditioning equipment to operate, and final humidification effect is poor and more people's intention. In addition, the evaluation index of the existing human thermal comfort is not accurate enough, and dynamic adjustment can not be carried out according to the actual situation, so that the humidification effect is not ideal.

Disclosure of Invention

In view of this, the invention provides a home dynamic humidification method integrating thermal comfort and body-sensing temperature.

The invention discloses a home dynamic humidification method integrating thermal comfort and body-sensing temperature, which comprises the following steps:

the method comprises the following steps: after the intelligent household dynamic humidifier device is started, the first step iskAt any moment, the dry bulb temperature of the indoor air is monitored in real time through the built-in air dry bulb temperature sensor, the built-in relative humidity sensor and the infrared induction sensorT ^k _air Relative humidity, relative humidityRH ^k _air And monitoring whether other air conditioning devices are started or not and setting equivalent air flow rate through the infrared induction sensorv ^k _air,eqt ；

Step two: calculating the parameters measured in real time in the step onekThe instantaneous equivalent thermal comfort index;

step three: calculating the parameters measured in real time in the step onekBody sensing temperature at any moment;

step four: setting an initial assignment weight coefficient if other air conditioning devices in the room are startedW ₁ ^k AndW ₂ ^k ；

step five: weighting coefficient of k-th timeW ₁ ^k 、W ₂ ^k Substitute into formula and calculatekOf time of dayPT ^k _int A value;

step six: when in usePT ^k _int Is of the value [ -1, 1 [)]A section andRH ^k _air the values of (A) are [35%, 65%]During interval, the first of the intelligent humidifierk+1Control mode of time of dayH ^k+1 _mode Adjusting to be 0, namely not starting humidification; when in usePT ^k _int When the value of (A) is less than-1, orRH ^k _air Is less than 35%, the intelligent humidifierk+1Control mode of time of dayH ^k+1 _mode Adjusting to be 1, and starting a conventional humidification mode for the room by the humidifier; when in usePT ^k _int Is less than-1, andRH ^k _air when the value of (A) is also less than 35%, the second step of the intelligent humidifierk+1Control mode of time of dayH ^k+1 _mode The humidification mode is adjusted to be 2, and the humidifier is opened to the room to quickly exceed the humidification mode;

step seven: and (4) at the k +1 th moment, the intelligent humidifier acquires the air temperature and the relative humidity at the new moment again, calculates the equivalent thermal comfort index and the sensible temperature again, and calculates the weight coefficient of the new momentW ₁ ^k 、W ₂ ^k ；

Step eight: and repeating the fifth step, the sixth step and the seventh step until the intelligent humidifier is manually turned off or is turned off regularly.

Furthermore, if no other air conditioner is found to be started, the equivalent air flow rate is setv ^k _air,eqt The equivalent is 0 m/s; if other air-conditioning devices are found to be started, setting the equivalent air flow rate according to the monitored air-conditioning air speed modev ^k _air,eqt ；

If the wind speed mode of the air conditioner is three-gear, the equivalent air flow rate at low speedv ^k _air,eqt 0.1m/s, equivalent air flow rate at medium speed and automatic gearv ^k _air,eqt 0.2m/s, equivalent air flow rate at high speedv ^k _air,eqt The equivalent is 0.3 m/s;

if the wind speed mode of the air conditioner is five gears, the equivalent air flow rate is 1 latticev ^k _air,eqt 0.1m/s, equivalent air flow rate at 2 gridsv ^k _air,eqt 0.15m/s, 3 grids and the equivalent air flow rate in the automatic gearv ^k _air,eqt Equivalent is 0.2m/s, equivalent air flow rate at 4 latticesv ^k _air,eqt Equivalent is 0.25m/s, equivalent air flow rate at 5 latticesv ^k _air,eqt The equivalent is 0.3 m/s.

Further, the firstkThe equivalent thermal comfort index at a moment is calculated as follows:

PMV _eqt is an equivalent thermal comfort index, the range of which is equivalent to the average index of seven levels of thermal sensing votes.

Further, the firstkThe sensible temperature at that moment is calculated as follows:

is thatkBody sensing temperature at any moment;

is thatkThe indoor air temperature at that moment;

is thatkIndoor relative humidity at all times;

is thatkThe indoor equivalent air flow rate at that moment.

Further, if the condition that other air conditioners in the room are not started is not monitored, the weight coefficient is initially assignedW ₁ ^k =W ₂ ^k = 0.5; if the situation that other air conditioners in the room are started and are in a refrigeration mode or a dehumidification mode is monitored, the weight coefficient is initially assignedW ₁ ^k =0.2，W ₂ ^k = 0.8; if the situation that other air conditioners in the room are started and the heating mode is detected, the weight coefficient is initially assignedW ₁ ^k =0.8，W ₂ ^k =0.2。

Further, the weight coefficient of the k-th time is determinedW ₁ ^k 、W ₂ ^k Substituting the following formula to calculatekFusion value of equivalent thermal comfort and sensible temperature at momentPT ^k _int ；

。

Further, the method comprisesWeight coefficient of new timeW ₁ ^k+1 、W ₂ ^k+1 The calculation is as follows:

wherein the content of the first and second substances,

and

is thatkThe weight factor of the time of day is,

is thatkThe equivalent thermal comfort index at time +1,

is thatkThe equivalent thermal comfort index at a moment,

is thatkThe sensible temperature at the moment +1,

is thatkThe sensible temperature at that moment.

The invention discloses a household dynamic humidifying device integrating thermal comfort and sensible temperature, which comprises:

a processor;

and a memory for storing executable instructions of the processor;

wherein the processor is configured to execute the above-mentioned home dynamic humidification method integrating thermal comfort and sensible temperature via executable instructions.

The invention has the following beneficial effects:

meanwhile, the thermal comfort and the body sensing temperature of an indoor human body are considered, an equivalent thermal comfort algorithm is innovatively adopted, and a fusion algorithm gives consideration to the thermal comfort requirement and the appropriate body sensing temperature;

the intelligent humidifier is different from a traditional humidifier in manual starting and stopping, timing starting and stopping or height limiting starting and stopping, and an innovative control method of dynamic humidification, conventional humidification and rapid over-volume humidification is adopted according to indoor temperature and humidity conditions monitored in real time;

the invention innovatively adopts the infrared inductor to monitor whether other air conditioning devices exist in the indoor space, and simultaneously brings the indoor air flow rate into the consideration range of humidification comfort.

Drawings

FIG. 1 is a flow chart of the method of the present invention.

Detailed Description

The invention is further described with reference to the accompanying drawings, but the invention is not limited in any way, and any alterations or substitutions based on the teaching of the invention are within the scope of the invention.

The invention provides a novel fusion control algorithm based on equivalent thermal comfort and somatosensory temperature, which aims at the problems that the traditional humidifier is simple in operation control mode, the dry bulb temperature of a humidified indoor space is not considered, whether the humidified indoor space is operated by other air conditioning devices (such as a refrigeration air conditioner) or not is not considered, and more importantly, the traditional air conditioner almost never considers the actual thermal feeling (such as the thermal comfort and the somatosensory temperature) of a human body.

The human thermal comfort takes the basic equation of human thermal balance and the grade of psychophysiological subjective thermal sensation as starting points, and takes the comprehensive evaluation indexes of a plurality of relevant factors of the human thermal comfort into consideration. The human thermal comfort index indicates the average index of the population for seven levels of thermal sensing votes (+ 3 to-3), as shown in table 1 below.

TABLE 1 thermal comfort and thermal sensation staff gauge for human body

Thermal sensation	Cold	Cool down	Slight cool	Is moderate	Micro-heating	Heating device	Heat generation
								Index value	-3	-2	-1	0	1	2	3

Sensible temperature refers to the degree of temperature change sensed by a human body, which is converted into the same temperature, and is influenced by the temperature, wind speed and relative humidity.

The control algorithm and the control device not only mainly consider the real-time thermal comfort and the somatosensory temperature of an indoor human body, but also consider whether other air conditioning devices (such as a household conventional air conditioner) in the indoor space are started to operate or not by means of intelligent home furnishing identification, dynamic humidification control (such as humidification time and humidification quantity) is carried out by monitoring air necessary parameters such as air dry bulb temperature, relative humidity, air flow rate and the like of the indoor humidification space in real time, temperature and humidity organic linkage control can be realized on the technical level, humidification on demand can be realized on the humidification effect level, and the thermal comfort and the somatosensory requirements of the human body are met to the maximum extent.

As shown in fig. 1, the control steps of the present invention are as follows:

the method comprises the following steps: after the intelligent household dynamic humidifier device is started, the first step iskAt any moment, the dry bulb temperature of the indoor air is monitored in real time through the built-in air dry bulb temperature sensor, the built-in relative humidity sensor and the infrared induction sensorT ^k _air Relative Humidity (RH)RH ^k _air And monitoring whether other air conditioning devices are started and in a mode (refrigerating or heating mode) in the room through the infrared induction sensor, and if the other air conditioning devices are not found to be started, setting an equivalent air flow ratev ^k _air,eqt The equivalent is 0 m/s; if other air conditioning devices are found to be started, setting the equivalent air flow rate according to the monitored air speed modev ^k _air,eqt (third gear: low speed equivalent is 0.1m/s, medium speed equivalent is 0.2m/s with automatic gear, high speed equivalent is 0.3 m/s; fifth gear: 1 case equivalent is 0.1m/s, 2 case equivalent is 0.15m/s, 3 case equivalent is 0.2m/s with automatic gear, 4 case equivalent is 0.25m/s, 5 case equivalent is 0.3m/s, other gear average style equivalent, low speed lower limit is 0.1m/s, high speed upper limit is 0.3m/s, and the rest are analogized in sequence);

step two: substituting the real-time measured parameters in the step one to calculate the second stepkThe instantaneous equivalent thermal comfort index;

(1)

PMV _eqt is an equivalent thermal comfort index, and the range of the equivalent thermal comfort index is equivalent to the average index of the seven levels of thermal sensing votes (+ 3 to-3) in the table.

Currently, ASHRAE Standard 55-2010 defines comfort as a state of consciousness that a human body is satisfied with a thermal environment, applicable to a typical indoor environment, namely: the personnel are in a sitting state (1.1 met), the indoor wind speed is less than or equal to 0.2m/s, and the clothing thermal resistance of the personnel is 1.0 clo (typical clothing in winter) or 0.5 clo (typical clothing in summer). For the case of a garment thermal resistance between 0.5 clo and 1.0 clo, the thermal comfort region can be determined by interpolation. The method can only look up a table, and presumes or assumes some parameters without the operability of landing control, such as considering the dressing coefficient of people, the radiation temperature of a room and the metabolic rate of a human body, but the radiation temperature of the room is difficult to measure, and people of all ages and both sexes have different motion states and different metabolic rates of the human body, and the calculation of thermal comfort has no operability.

The equivalent thermal comfort index provided by the invention normalizes and equates various factors, such as equivalent radiation temperature according to a static and long-term mixing mode, equivalent behaviors such as dressing, washing and the like according to 1 (equivalent behaviors such as covering quilt according to a sleep mode) and metabolic rate value as a sitting average value, and equivalent control of other factors, so that the thermal comfort can approach the perception of an actual human body. In the subsequent control process, a weight coefficient of the equivalent thermal comfort index is also set, and the weight coefficient is dynamically adjusted according to the actual control result, so that the thermal comfort index is closer to the feeling of a user.

Step three: substituting the real-time measured parameters in the step one to calculate the second stepkBody sensing temperature at any moment;

(2)

is thatkBody sensing temperature at any moment;

is thatkThe indoor air temperature at that moment;

is thatkIndoor relative humidity at all times;

is thatkThe indoor equivalent air flow rate at that moment.

Step four: if the situation that other air conditioners in the room are not started is not monitored, the weight coefficient is initially assignedW ₁ ^k =W ₂ ^k = 0.5; if the situation that other air conditioners in the room are started and are in a refrigeration mode or a dehumidification mode is monitored, the weight coefficient is initially assignedW ₁ ^k =0.2，W ₂ ^k = 0.8; if the situation that other air conditioners in the room are started and the heating mode is detected, the weight coefficient is initially assignedW ₁ ^k =0.8，W ₂ ^k =0.2；

Step five: as shown in equation (3), the weighting factor at the k-th time is determinedW ₁ ^k 、W ₂ ^k Substitute into formula and calculatekOf time of dayPT ^k _int A value;

(3)

wherein the content of the first and second substances,PT _int is a fusion value of equivalent thermal comfort and body sensing temperature,T _body is the sensible temperature;T _air is the indoor air temperature;RH _air is the indoor relative humidity;v _air,eqt is the indoor equivalent air flow rate; W ₁ 、W ₂ a weight coefficient for adjusting the control;kis as followskThe time of day, preferably, the time interval may be set to at least 30 seconds.

Step six: as shown in equation (4)When is coming into contact withPT ^k _int Is of the value [ -1, 1 [)]A section andRH ^k _air the values of (A) are [35%, 65%]During interval, the first of the intelligent humidifierk+1Control mode of time of dayH ^k+1 _mode Adjusting to be 0, namely not starting humidification, and enabling the humidification quantity of the humidifier to the room to be 0; when in usePT ^k _int When the value of (A) is less than-1, orRH ^k _air Is less than 35%, the intelligent humidifierk+1Control mode of time of dayH ^k+1 _mode Adjusting to be 1, namely starting humidification, and starting a conventional humidification mode for the room by the humidifier to increase the moisture content and the relative humidity of the air in the room; when in usePT ^k _int Is less than-1, andRH ^k _air when the value of (A) is also less than 35%, the second step of the intelligent humidifierk+1Control mode of time of dayH ^k+1 _mode Then the adjustment is "2", i.e. humidification is initiated and the humidifier is switched on to the room in a rapid over-humidification mode for rapidly and substantially increasing the moisture content and relative humidity of the air in the room.

(4)

H _mode The control mode of the intelligent humidifier is.

Step seven: and (3) at the k +1 th moment, the intelligent humidifier collects the air temperature and the relative humidity at the new moment again, calculates the equivalent thermal comfort index and the sensible temperature again, and substitutes the equivalent thermal comfort index and the sensible temperature into the formula (5) and the formula (6) to calculate the weight coefficient at the new momentW ₁ ^k 、W ₂ ^k ；

(5)

(6)

Step eight: and repeating the fifth step, the sixth step and the seventh step until the intelligent humidifier is manually turned off or is turned off regularly.

The invention has the following beneficial effects:

meanwhile, the thermal comfort and the body sensing temperature of an indoor human body are considered, an equivalent thermal comfort algorithm is innovatively adopted, and a fusion algorithm gives consideration to the thermal comfort requirement and the appropriate body sensing temperature;

the intelligent humidifier is different from a traditional humidifier in manual starting and stopping, timing starting and stopping or height limiting starting and stopping, and an innovative control method of dynamic humidification, conventional humidification and rapid over-volume humidification is adopted according to indoor temperature and humidity conditions monitored in real time;

the invention innovatively adopts the infrared inductor to monitor whether other air conditioning devices exist in the indoor space, and simultaneously brings the indoor air flow rate into the consideration range of humidification comfort.

The word "preferred" is used herein to mean serving as an example, instance, or illustration. Any aspect or design described herein as "preferred" is not necessarily to be construed as advantageous over other aspects or designs. Rather, use of the word "preferred" is intended to present concepts in a concrete fashion. The term "or" as used in this application is intended to mean an inclusive "or" rather than an exclusive "or". That is, unless specified otherwise or clear from context, "X employs A or B" is intended to include either of the permutations as a matter of course. That is, if X employs A; x is B; or X employs both A and B, then "X employs A or B" is satisfied in any of the foregoing examples.

Also, although the disclosure has been shown and described with respect to one or an implementation, equivalent alterations and modifications will occur to others skilled in the art based upon a reading and understanding of this specification and the annexed drawings. The present disclosure includes all such modifications and alterations, and is limited only by the scope of the appended claims. In particular regard to the various functions performed by the above described components (e.g., elements, etc.), the terms used to describe such components are intended to correspond, unless otherwise indicated, to any component which performs the specified function of the described component (e.g., that is functionally equivalent), even though not structurally equivalent to the disclosed structure which performs the function in the herein illustrated exemplary implementations of the disclosure. In addition, while a particular feature of the disclosure may have been disclosed with respect to only one of several implementations, such feature may be combined with one or other features of the other implementations as may be desired and advantageous for a given or particular application. Furthermore, to the extent that the terms "includes," has, "" contains, "or variants thereof are used in either the detailed description or the claims, such terms are intended to be inclusive in a manner similar to the term" comprising.

Each functional unit in the embodiments of the present invention may be integrated into one processing module, or each unit may exist alone physically, or a plurality of or more than one unit are integrated into one module. The integrated module can be realized in a hardware mode, and can also be realized in a software functional module mode. The integrated module, if implemented in the form of a software functional module and sold or used as a stand-alone product, may also be stored in a computer readable storage medium. The storage medium mentioned above may be a read-only memory, a magnetic or optical disk, etc. Each apparatus or system described above may execute the storage method in the corresponding method embodiment.

In summary, the above-mentioned embodiment is an implementation manner of the present invention, but the implementation manner of the present invention is not limited by the above-mentioned embodiment, and any other changes, modifications, substitutions, combinations, and simplifications which do not depart from the spirit and principle of the present invention should be regarded as equivalent replacements within the protection scope of the present invention.

Claims (8)

1. A home dynamic humidification method integrating thermal comfort and somatosensory temperature is characterized by comprising the following steps:

the method comprises the following steps: after the intelligent household dynamic humidifier device is started, the first step iskAt any moment, the dry bulb temperature of the indoor air is monitored in real time through the built-in air dry bulb temperature sensor, the built-in relative humidity sensor and the infrared induction sensorT ^k _air Relative Humidity (RH)RH ^k _air And monitoring whether other air conditioning devices are started or not and setting equivalent air flow rate through the infrared induction sensorv ^k _air,eqt ；

Step two: calculating the parameters measured in real time in the step onekThe instantaneous equivalent thermal comfort index;

step three: calculating the parameters measured in real time in the step onekBody sensing temperature at any moment;

step four: setting an initial assignment weight coefficient according to the starting conditions of other air conditioning devices in a roomW ₁ ^k AndW ₂ ^k ；

step five: according to the weight coefficient of the k-th timeW ₁ ^k 、W ₂ ^k Calculate the firstkOf time of dayPT ^k _int A value;

step six: when in usePT ^k _int Is of the value [ -1, 1 [)]A section andRH ^k _air the values of (A) are [35%, 65%]During interval, the first of the intelligent humidifierk+1Control mode of time of dayH ^k+1 _mode Adjusting to be 0, namely not starting humidification; when the temperature is higher than the set temperaturePT ^k _int When the value of (A) is less than-1, orRH ^k _air Is less than 35%, the intelligent humidifierk+1Control mode of time of dayH ^k+1 _mode Adjusting to be 1, and starting a conventional humidification mode for the room by the humidifier; when the temperature is higher than the set temperaturePT ^k _int Is less than-1, andRH ^k _air when the value of (A) is also less than 35%, the second step of the intelligent humidifierk+1Time control methodIs of the formulaH ^k+1 _mode The humidification mode is adjusted to be 2, and the humidifier is opened to the room to quickly exceed the humidification mode;

step seven: and (4) at the k +1 th moment, the intelligent humidifier acquires the air temperature and the relative humidity at the new moment again, recalculates the equivalent thermal comfort index and the sensible temperature, and calculates to obtain the weight coefficient of the new momentW ₁ ^k 、W ₂ ^k ；

Step eight: and repeating the fifth step, the sixth step and the seventh step until the intelligent humidifier is manually turned off or is turned off regularly.

2. The home dynamic humidification method integrating thermal comfort and sensible temperature according to claim 1, wherein if no other air conditioning device is found to be turned on, an equivalent air flow rate is setv ^k _air,eqt The equivalent is 0 m/s; if other air conditioning devices are found to be started, setting the equivalent air flow rate according to the monitored air speed mode of the air conditionerv ^k _air,eqt ；

If the wind speed mode of the air conditioner is three-gear, the equivalent air flow rate at low speedv ^k _air,eqt 0.1m/s, medium speed and equivalent air flow rate at automatic gearv ^k _air,eqt 0.2m/s, equivalent air flow rate at high speedv ^k _air,eqt The equivalent is 0.3 m/s;

if the wind speed mode of the air conditioner is five gears, the equivalent air flow rate is 1 latticev ^k _air,eqt 0.1m/s, equivalent air flow rate at 2 gridsv ^k _air,eqt 0.15m/s, 3 grids and the equivalent air flow rate in the automatic gearv ^k _air,eqt Equivalent is 0.2m/s, equivalent air flow rate at 4 latticesv ^k _air,eqt Equivalent is 0.25m/s, equivalent air flow rate at 5 latticesv ^k _air,eqt The equivalent is 0.3 m/s.

3. The home dynamic humidification method integrating thermal comfort and sensible temperature according to claim 1, whereinkThe equivalent thermal comfort index at a moment is calculated as follows:

PMV _eqt is an equivalent thermal comfort index, the range of which is equivalent to the average index of seven levels of thermal sensing votes.

4. The home dynamic humidification method integrating thermal comfort and sensible temperature according to claim 1, whereinkThe sensible temperature at that moment is calculated as follows:

is thatkBody sensing temperature at any moment;

is thatkThe indoor air temperature at that moment;

is thatkIndoor relative humidity at all times;

is thatkThe indoor equivalent air flow rate at that moment.

5. The home dynamic humidification method integrating thermal comfort and sensible temperature according to claim 1, wherein the home dynamic humidification method is characterized in thatIf the condition that other air conditioners in the room are not started is not monitored, the weight coefficient is initially assignedW ₁ ^k =W ₂ ^k = 0.5; if the situation that other air conditioners in the room are started and are in a refrigeration mode or a dehumidification mode is monitored, the weight coefficient is initially assignedW ₁ ^k =0.2，W ₂ ^k = 0.8; if the situation that other air conditioners in the room are started and the heating mode is detected, the weight coefficient is initially assignedW ₁ ^k =0.8，W ₂ ^k =0.2。

6. The home dynamic humidification method integrating thermal comfort and sensible temperature according to claim 4, wherein a weighting coefficient at a k-th moment is usedW ₁ ^k 、W ₂ ^k Substituting the following formula to calculatekFusion value of equivalent thermal comfort and sensible temperature at momentPT ^k _int ；

。

7. The home dynamic humidification method integrating thermal comfort and sensible temperature according to claim 1, wherein the weight coefficient at a new momentW ₁ ^k+1 、W ₂ ^k+1 The calculation is as follows:

wherein the content of the first and second substances,

and

is thatkThe weight factor of the time of day is,

is thatkThe equivalent thermal comfort index at time +1,

is thatkThe equivalent thermal comfort index at the moment of time,

is thatkThe sensible temperature at the moment +1,

is thatkThe sensible temperature at that moment.

8. The utility model provides a fuse house developments humidification device of thermal comfort and body temperature, its characterized in that includes:

a processor;

and a memory for storing executable instructions of the processor;

wherein the processor is configured to execute, via executable instructions, the home dynamic humidification method fusing thermal comfort and sensible temperature according to any one of claims 1 to 7.

Images