Method and apparatus for calculating thermal sensitivity
First Claim
1. A method of calculating thermal sensitivity felt by a person in an environment using an environment measuring section disposed in the environment, the environment measuring section disposed in the environment, the environment measuring section having an associated temperature sensor for detecting a surface temperature Tcr of the environment measuring section and an associated heating means for adjusting the surface temperature Tcr, comprising the steps of:
- calculating a set temperature q.sub.(th) on the basis of an air temperature Ta and a clothing thermal resistance Icl input to a thermal sensitivity calculating section;
supplying thermal energy information Hq.sub.(th) from a thermal energy control section to the associated heating means for heating the associated sensor;
heating the associated sensor to set the surface temperature Tcr of the associated sensor to be equal to the set temperature q.sub.(th) ;
supplying a thermal energy information value representing an amount of power H supplied to the heating means to maintain the surface temperature Tcr substantially the same as the set temperature q.sub.(th) from the thermal energy control section to the thermal sensitivity calculating section; and
calculating an equivalent temperature Teq* on the basis of the air temperature Ta, the set temperature q.sub.(th), the thermal energy information value, and coefficients b1 to b4, according to the following equation (a), when the sensor temperature Tcr is lower than the set temperature q.sub.(th), and calculating the equivalent temperature Teq* on the basis of the air temperature Ta, the set temperature q.sub.(th), a difference Δ
Tcr between the sensor temperature Tcr and the set temperature q.sub.(th), an air velocity Vair, the thermal energy information Hq.sub.(th) representing the amount of power H supplied to the heating means, a coefficient c1 expressed in consideration of the clothing thermal resistance Icl, coefficients c2 to c6, and a coefficient n, according to the following equation (b), when the sensor temperature Tcr is higher than the set temperature q.sub.(th),
space="preserve" listing-type="equation">Teq.sup.* =b.sub.1 +b.sub.2 ×
θ
.sub.(th) +b.sub.3 ×
Ta-b.sub.4 ×
Hθ
.sub.(th) (a)
space="preserve" listing-type="equation">Teq.sup.* =c.sub.1 +c.sub.2 ×
θ
.sub.(th) +c.sub.3 ×
Ta+c.sub.4 ×
(1+c.sub.5 +Vair.sup.n)×
Δ
Tcr-c.sub.6 ×
Hθ
.sub.(th) (b)where ##EQU19##
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Abstract
The present invention provides a method and apparatus for calculating thermal sensitivity and predicted mean thermal sensitivity felt by a person in an environment. According to the apparatus of the present invention, an air temperature Ta, a clothing thermal resistance Icl, and a sensor temperature Tcr of a sensor within the environment are provided as input to an input section of the apparatus. Upon receiving these values, a set temperature calculating section of the apparatus calculates a set temperature θ.sub.(th). A thermal energy control means supplies thermal energy information Hθ.sub.(th) to a heater so as to heat the sensor in order to maintain the sensor temperature Tcr at the calculated set temperature θ.sub.(th). An equivalent temperature calculating section then calculates an equivalent temperature Teq* so that a predicted mean thermal sensitivity PMV* can then calculated on the basis of the obtained equivalent temperature Teq*.
17 Citations
13 Claims
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1. A method of calculating thermal sensitivity felt by a person in an environment using an environment measuring section disposed in the environment, the environment measuring section disposed in the environment, the environment measuring section having an associated temperature sensor for detecting a surface temperature Tcr of the environment measuring section and an associated heating means for adjusting the surface temperature Tcr, comprising the steps of:
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calculating a set temperature q.sub.(th) on the basis of an air temperature Ta and a clothing thermal resistance Icl input to a thermal sensitivity calculating section; supplying thermal energy information Hq.sub.(th) from a thermal energy control section to the associated heating means for heating the associated sensor; heating the associated sensor to set the surface temperature Tcr of the associated sensor to be equal to the set temperature q.sub.(th) ; supplying a thermal energy information value representing an amount of power H supplied to the heating means to maintain the surface temperature Tcr substantially the same as the set temperature q.sub.(th) from the thermal energy control section to the thermal sensitivity calculating section; and calculating an equivalent temperature Teq* on the basis of the air temperature Ta, the set temperature q.sub.(th), the thermal energy information value, and coefficients b1 to b4, according to the following equation (a), when the sensor temperature Tcr is lower than the set temperature q.sub.(th), and calculating the equivalent temperature Teq* on the basis of the air temperature Ta, the set temperature q.sub.(th), a difference Δ
Tcr between the sensor temperature Tcr and the set temperature q.sub.(th), an air velocity Vair, the thermal energy information Hq.sub.(th) representing the amount of power H supplied to the heating means, a coefficient c1 expressed in consideration of the clothing thermal resistance Icl, coefficients c2 to c6, and a coefficient n, according to the following equation (b), when the sensor temperature Tcr is higher than the set temperature q.sub.(th),
space="preserve" listing-type="equation">Teq.sup.* =b.sub.1 +b.sub.2 ×
θ
.sub.(th) +b.sub.3 ×
Ta-b.sub.4 ×
Hθ
.sub.(th) (a)
space="preserve" listing-type="equation">Teq.sup.* =c.sub.1 +c.sub.2 ×
θ
.sub.(th) +c.sub.3 ×
Ta+c.sub.4 ×
(1+c.sub.5 +Vair.sup.n)×
Δ
Tcr-c.sub.6 ×
Hθ
.sub.(th) (b)where ##EQU19##
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2. A method of calculating predicted mean thermal sensitivity felt by a person in an environment using an environment measuring section disposed in the environment, the environment measuring section having an associated temperature sensor for detecting a surface temperature Tcr of the environment measuring section and an associated heating means for adjusting the surface temperature Tcr, comprising the steps of:
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calculating a set temperature q.sub.(th) on the basis of an air temperature Ta and a clothing thermal resistance Icl input to a thermal sensitivity calculating section; supplying thermal energy information Hq.sub.(th) from a thermal energy control section to the associated heating means for heating the associated sensor; heating the associated sensor to set the surface temperature Tcr of the associated sensor to be equal to the set temperature q.sub.(th) ; supplying a thermal energy information value representing an amount of power H supplied to the heating means to maintain the surface temperature Tcr substantially the same as the set temperature q.sub.(th) from the thermal energy control section to the thermal sensitivity calculating section; calculating an equivalent temperature Teq* on the basis of the air temperature Ta, the set temperature q.sub.(th), the thermal energy information value, and coefficients b1 to b4, according to the following equation (a), when the sensor temperature Tcr is lower than the set temperature q.sub.(th), and calculating the equivalent temperature Teq on the basis of the air temperature, the set temperature q.sub.(th), a difference Δ
Tcr between the sensor temperature Tcr and the set temperature q.sub.(th), an air velocity Vair, the thermal energy information Hq.sub.(th) representing the amount of power H supplied to the heating means, a coefficient c1 expressed in consideration of the clothing thermal resistance Icl, coefficients c2 to c6, and a coefficient n, according to the following equation (b), when the sensor temperature Tcr is higher than the set temperature q.sub.(th) ;supplying the equivalent temperature Teq* to a predicted mean thermal sensitivity calculating section; and calculating predicted mean thermal sensitivity PMV* on the basis of the obtained equivalent temperature Teq*, a humidity RH, an activity amount Met, a skin temperature Tsk (Tsk =35.7-0.0275×
Met ×
58.15), the air temperature Ta, an absolute water vapor pressure P(Ta) at the air temperature Ta, the clothing thermal resistance Icl, a thermal resistance effect Fcl (Fcl=E1 /(E2 +E3 ×
Icl)) based on coefficients E1 to E3, and coefficients D1 to D7, according to the following equation (c),
space="preserve" listing-type="equation">Teq.sup.* =b.sub.1 +b.sub.2 ×
θ
.sub.(th) +b.sub.3 ×
Ta-b.sub.4 ×
Hθ
.sub.(th) (a)
space="preserve" listing-type="equation">Teq.sup.* =c.sub.1 +c.sub.2 ×
θ
.sub.(th) +c.sub.3 ×
Ta+c.sub.4 ×
(1+c.sub.5 +Vair.sup.n)×
Δ
Tcr-c.sub.6 ×
Hθ
.sub.(th) (b)
space="preserve" listing-type="equation">PMV.sup.* =a×
LOAD.sup.* (c)where ##EQU20## a=0.303×
EXP(-0.036'"'"'Met ×
58.15)+0.028; and
E1 =8.976, E2 =1, and E3 =1.466;and if Met <
1.0, then
space="preserve" listing-type="equation">LOAD.sup.* =D.sub.1 +D.sub.2 ×
M.sub.et -D.sub.3 ×
T.sub.sk +D.sub.4 ×
M.sub.et ×
Ta+(D.sub.5 +D.sub.6 ×
M.sub.et)×
RH×
P(Ta)-Fcl×
(T.sub.sk -Teq.sup.*),where
space="preserve" listing-type="equation">D1=10.2895,D2=49.5152,D3=0.7808, D4-0.08142,D5=0.004067, D6=0.00133338 and D7=24.423;and if Met≧
1.0, then
space="preserve" listing-type="equation">LOAD.sup.* =D.sub.1 +D.sub.2 ×
M.sub.35 -D.sub.3 ×
T.sub.sk +D.sub.4 ×
M.sub.et ×
Ta+(D.sub.5 +D.sub.6 ×
M.sub.et)×
RH×
P(Ta)-D.sub.7 ×
(M.sub.et -1)-Fcl×
(T.sub.sk -Teq.sup.*),where
space="preserve" listing-type="equation">D1=10.2895, D2=49.5152, D3=0.7808, D4=0.08142, D5=0.004067, D6=0.00133338 and D7=24.423.
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3. A thermal sensitivity calculating apparatus for calculating thermal sensitivity felt by a person in an environment arranged with respect to an environment measuring section having heating means capable of supplying heat to the environment to adjust a sensor temperature Tcr of an associated sensor, comprising:
-
set temperature calculating means for calculating a set temperature θ
.sub.(th) on the basis of an air temperature Ta and a clothing thermal resistance Icl;thermal energy control means for supplying thermal energy information Hθ
.sub.(th) to said heating means so as to set the sensor temperature Tcr to be equal to the set temperature θ
.sub.(th) ; andthermal sensitivity calculating means for calculating an equivalent temperature Teq* on the basis of the air temperature Ta, the set temperature θ
.sub.(th), the thermal energy information Hθ
.sub.(th) representing an amount of power H supplied to the heating means, and coefficients b1 to b4, according to the following equation (a), when the sensor temperature Tcr is lower than the set temperature θ
.sub.(th), and calculating the equivalent temperature Teq* on the basis of the air temperature Ta, the set temperature θ
.sub.(th), a difference Δ
Tcr between the sensor temperature Tcr and the set temperature θ
.sub.(th), an air velocity Vair, the thermal energy information Hθ
.sub.(th) representing the amount of power H supplied to the heating means, a coefficient c1 expressed in consideration of the clothing thermal resistance Icl, coefficients c2 to c6, and a coefficient n, according to the following equation (b), when the sensor temperature Tcr is higher than the set temperature θ
.sub.(th),
space="preserve" listing-type="equation">Teq.sup.* b.sub.1 +b.sub.2 ×
θ
.sub.(th) +b.sub.3 ×
Ta-b.sub.4 ×
Hθ
.sub.(th) (a)
space="preserve" listing-type="equation">Teq.sup.* -c.sub.1 +c.sub.2 ×
θ
.sub.(th) +c.sub.3 ×
Ta+c.sub.4 ×
(1+c.sub.5 ×
Vair.sup.n)×
Δ
Tcr-c.sub.6 ×
Hθ
.sub.(th) (b)where ##EQU21##
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4. A predicted mean thermal sensitivity calculating apparatus for calculating predicted mean thermal sensitivity felt by a person in an environment comprising:
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a thermal sensitivity calculating apparatus arranged with respect to an environment measuring section having heating means capable of supplying heat to the environment to adjust a sensor temperature Tcr of an associated sensor, said thermal sensitivity calculating apparatus including set temperature calculating means for calculating a set temperature θ
.sub.(th) on the basis of an air temperature Ta and a clothing thermal resistance Icl,thermal energy control means for supplying thermal energy information Hθ
.sub.(th) to said heating means so as to set the sensor temperature Tcr to be equal to the set temperature θ
.sub.(th) ; andthermal sensitivity calculating means for calculating an equivalent temperature Teq* on the basis of the air temperature Ta, the set temperature θ
.sub.(th), the thermal energy information Hθ
.sub.(th) representing an amount of power H supplied to the heating means, and coefficients b1 to b4, according to the following equation (q), when the sensor temperature Tcr is lower than the set temperature θ
.sub.(th), and calculating the equivalent temperature Teq* on the basis of the air temperature Ta, the set temperature θ
.sub.(th), a difference Δ
Tcr between the sensor temperature Tcr and the set temperature θ
.sub.(th), an air velocity Vair, the thermal energy information Hθ
.sub.(th) representing the amount of power H supplied to the heating means, a coefficient c1 expressed in consideration of the clothing thermal resistance Icl, coefficients c2 to c6, and a coefficient n, according to the following equation (b), when the sensor temperature Tcr is higher than the set temperature θ
.sub.(th) ; andpredicted means thermal sensitivity calculating means for calculating predicted mean thermal sensitivity PMV* on the basis of the equivalent temperature Teq* obtained by said thermal sensitivity calculating apparatus, a humidity RH, an activity amount Met, a skin temperature Tsk (Tsk =35.7-0.0275×
Met ×
58.15), the air temperature Ta, an absolute water vapor pressure P(Ta) at the air temperature Ta, the clothing thermal resistance Icl, a thermal resistance effect Fcl (Fcl=E1 /(E2 +E3 ×
Icl)) based on coefficients E1 to E3, and coefficients D1 to D7, according to the following equation (c),
space="preserve" listing-type="equation">Teq.sup.* =b.sub.1 +b.sub.2 ×
θ
.sub.(th) +b.sub.3 ×
Ta-b.sub.4 ×
Hθ
.sub.(th) (a)
space="preserve" listing-type="equation">Teq.sup.* =c.sub.1 +c.sub.2 ×
θ
.sub.(th) +c.sub.3 ×
Ta+c.sub.4 ×
(1+c.sub.5 ×
Vair.sup.n)×
Δ
Tcr-c.sub.6 ×
Hθ
.sub.(th) (b)
space="preserve" listing-type="equation">PMV.sup.* =α
×
LOAD.sup.* (c)where ##EQU22##
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5. α
- =0. 303×
EXP(-0.036×
Met ×
58.15)+0.028; and
E1 =8.976, E2 =1, and E3 =1.466;and if Met <
1.0, then
space="preserve" listing-type="equation">LOAD.sup.* =D.sub.1 +D.sub.2 ×
M.sub.et -D.sub.3 ×
T.sub.sk +D.sub.4 ×
M.sub.et ×
Ta+(D.sub.5 +D.sub.6 ×
M.sub.et)×
RH×
P(Ta)-Fcl×
(T.sub.sk -Teq.sup.*),where
space="preserve" listing-type="equation">D1=10.2895,D2=49.5152,D3=0.7808, D4-0.08142,D5=0.004067, D6=0.00133338 and D7=24.423;and if Met≧
1.0, then
space="preserve" listing-type="equation">LOAD.sup.* =D.sub.1 +D.sub.2 ×
M.sub.35 -D.sub.3 ×
T.sub.sk +D.sub.4 ×
M.sub.et ×
Ta+(D.sub.5 +D.sub.6 ×
M.sub.et)×
RH×
P(Ta)-D.sub.7 ×
(M.sub.et -1)-Fcl×
(T.sub.sk -Teq.sup.*),where
space="preserve" listing-type="equation">D1=10.2895, D2=49.5152, D3=0.7808, D4=0.08142, D5=0.004067, D6=0.00133338 and D7=24.423. - View Dependent Claims (7, 8, 9, 11, 12, 13)
- =0. 303×
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6. A thermal sensitivity calculating apparatus for calculating thermal sensitivity felt by a person in an environment, comprising:
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an environment measuring section disposed within the environment for integral detection of an air temperature Ta, a radiant temperature Tr and an air velocity Vair, the environment measuring section having an associated sensor for detecting a surface temperature Tcr of the environment measuring section and heating means capable of supplying heat to the environment measuring section to adjust the surface temperature Tcr; and a thermal sensitivity calculating section having set temperature calculating means for calculating a set temperature q.sub.(th) on the basis of the air temperature Ta and a clothing thermal resistance Icl, thermal energy control means for supplying thermal energy information Hq.sub.(th) to the heating means so as to set the surface temperature Tcr to be equal to the set temperature q.sub.(th), and thermal sensitivity calculating means for calculating an equivalent temperature Teq* on the basis of the air temperature Ta, the set temperature q.sub.(th), a thermal energy information value representing an amount of thermal energy information Hq.sub.(th) supplied to the heating means, and coefficients b1 to b4, according to the following equation (a), when the surface temperature Tcr is lower than the set temperature q.sub.(th), and calculating the equivalent temperature Teq* on the basis of the air temperature Ta, the set temperature q.sub.(th), a difference Δ
Tcr between the surface temperature Tcr and the set temperature q.sub.(th), the air velocity Vair, the thermal energy information Hq.sub.(th) representing the amount of power H supplied to the heating means, a coefficient C1 expressed in consideration of the clothing thermal resistance Icl, coefficients c2 to c6, and a coefficient n, according to the following equation (b), when the surface temperature Tcr is higher than the set temperature q.sub.(th),
space="preserve" listing-type="equation">Teq.sup.* =b.sub.1 +b.sub.2 ×
θ
.sub.(th) +b.sub.3 ×
Ta-b.sub.4 ×
Hθ
.sub.(th) (a)
space="preserve" listing-type="equation">Teq.sup.* =c.sub.1 +c.sub.2 ×
θ
.sub.(th) +c.sub.3 ×
Ta+c.sub.4 ×
(1+c.sub.5 ×
Vair.sup.n)×
Δ
Tcr-c.sub.6 ×
Hθ
.sub.(th) (b)where ##EQU23##
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10. A predicted thermal sensitivity calculating apparatus for calculating thermal sensitivity felt by a person in an environment, comprising:
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an environment measuring section disposed within the environment for integral detection of an air temperature Ta, a radiant temperature Tr and an air velocity Vair, the environment measuring section having an associated sensor for detecting a surface temperature Tcr of the environment measuring section and heating means capable of supplying heat to the environment measuring section to adjust the surface temperature Tcr; a thermal sensitivity calculating section having set temperature calculating means for calculating a set temperature q.sub.(th) on the basis of the air temperature Ta and a clothing thermal resistance Icl, thermal energy control means for supplying thermal energy information Hq.sub.(th) to the heating means so as to set the surface temperature Tcr to be equal to the set temperature q.sub.(th), and thermal sensitivity calculating means for calculating an equivalent temperature Teq* on the basis of the air temperature Ta, the set temperature q.sub.(th), a thermal energy information value representing an amount of thermal energy information Hq.sub.(th) supplied to the heating means, and coefficients b1 to b4, according to the following equation (a), when the surface temperature Tcr is lower than the set temperature q.sub.(th), and calculating the equivalent temperature Teq* on the basis of the air temperature Ta, the set temperature q.sub.(th), a difference Δ
Tcr between the surface temperature Tcr and the set temperature q.sub.(th), the air velocity Vair, the thermal energy information Hq.sub.(th) representing the amount of power H supplied to the heating means, a coefficient c1 expressed in consideration of the clothing thermal resistance Icl, coefficients c2 to c6, and a coefficient n, according to the following equation (b), when the surface temperature Tcr is higher than the set temperature q.sub.(th) ; andpredicted mean thermal sensitivity calculating section for calculating predicted mean thermal sensitivity PMV* on the basis of the equivalent temperature Teq* obtained by the thermal sensitivity calculating section, a humidity RH, an activity amount Met, a skin temperature Tsk (Tsk =35.7-0.0275×
Met ×
58.15), the air temperature Ta, an absolute water vapor pressure P(Ta) at the air temperature Ta, the clothing thermal resistance Icl, a thermal resistance effect Fcl (Fcl=E1 /(E2 +E3 ×
Icl)) based on coefficients E1 to E3, and coefficients D1 to D7, according to the following equation (c),
space="preserve" listing-type="equation">Teq.sup.* =b.sub.1 +b.sub.2 ×
θ
.sub.(th) +b.sub.3 ×
Ta-b.sub.4 ×
Hθ
.sub.(th) (a)
space="preserve" listing-type="equation">Teq.sup.* =c.sub.1 +c.sub.2 ×
θ
.sub.(th) +c.sub.3 ×
Ta+c.sub.4 ×
(1+c.sub.5 ×
Vair.sup.n)×
Δ
Tcr-c.sub.6 ×
Hθ
.sub.(th) (b)
space="preserve" listing-type="equation">PMV.sup.* =a×
LOAD.sup.* (c)where ##EQU24## a=0.303×
EXP(-0.036×
Met ×
58.15)+0.028; and
E1 =8.976, E2 =1, and E3 =1.466;and if Met <
1.0, then
space="preserve" listing-type="equation">LOAD.sup.* =D.sub.1 +D.sub.2 ×
M.sub.et -D.sub.3 ×
T.sub.sk +D.sub.4 ×
M.sub.et ×
Ta+(D.sub.5 +D.sub.6 ×
M.sub.et)×
RH×
P(Ta)-Fcl×
(T.sub.sk -Teq.sup.*),where
space="preserve" listing-type="equation">D1=10.2895, D2=49.5152, D3=0.7808, D4=0.08142, D5=0.004067, D6=0.00133338 and D7=24.423;and if Met≧
1.0, then
space="preserve" listing-type="equation">LOAD.sup.* =D.sub.1 +D.sub.2 ×
M.sub.35 -D.sub.3 ×
T.sub.sk +D.sub.4 ×
M.sub.et ×
Ta+(D.sub.5 +D.sub.6 ×
M.sub.et)×
RH×
P(Ta)-D.sub.7 ×
(M.sub.et -1)-Fcl×
(T.sub.sk -Teq.sup.*),where
space="preserve" listing-type="equation">D1=10.2895, D2=49.5152, D3=0.7808, D4=0.08142, D5=0.004067, D6=0.00133338 and D7=24.423.
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Specification