Radiation temperature measuring device

The invention claimed is: 1. A method to measure a surface temperature of an object without contact using an infrared sensor, the method comprising: measuring an output of the infrared sensor to detect a wavelength including an absorption band by atmosphere existing between the infrared sensor and the object; calculating an absorption rate by the atmosphere at a wavelength of the absorption band when the surface temperature of the object is measured; storing in advance conversion information for converting the output of the infrared sensor into the surface temperature of the object; calculating the surface temperature of the object from the output of the infrared sensor, the calculated absorption rate, and the stored conversion information; storing in advance the absorption rate by the atmosphere at the wavelength of the absorption band depending on the stored conversion information; and correcting the calculated surface temperature of the object using the stored absorption rate, wherein the stored conversion information is a calculation equation for determining the surface temperature of the object, which is obtained by transforming a following calculation equation indicating the output of the infrared sensor: V=b [[(τ/τ0)· f ( Tb )+(1−(τ/τ0))· f ( Ta )]− f ( Tr )]+ c wherein V is the output of the infrared sensor, b is sensitivity of the infrared sensor, τ is a transmission rate obtained from the absorption rate (1−τ) calculated by the absorption rate calculating means, τ0 is a transmission rate obtained from the absorption rate (1−τ0) stored in the absorption rate storing means, Tb is the surface temperature of the object, Ta is a space temperature between the object and a radiation temperature measuring device, Tr is a temperature of the radiation temperature measuring device, c is an offset of the infrared sensor, and f( ) is an arbitrary function. 2. The method according to claim 1 , wherein the stored absorption rate is selected from a plurality of absorption rates set in a plurality of different temperature environments. 3. The method according to claim 2 , comprising: detecting a temperature of the radiation temperature measuring device, wherein correcting is performed using the stored absorption rate corresponding to the detected temperature of the radiation temperature measuring device. 4. The method according to claim 1 , wherein the atmosphere includes water vapor. 5. A method to measure a surface temperature of an object without contact using an infrared sensor, the method comprising: measuring an output of the infrared sensor to detect a wavelength including an absorption band by atmosphere existing between the infrared sensor and the object; calculating an absorption rate by the atmosphere at a wavelength of the absorption band when the surface temperature of the object is measured; storing a preset conversion equation for converting the output of the infrared sensor into the surface temperature of the object, which includes a coefficient indicating a characteristic of the infrared sensor, and a pre-detected value of the coefficient indicating the characteristic of the infrared sensor; calculating the surface temperature of the object from the output of the infrared sensor, the calculated absorption rate, and the conversion equation including the stored value of the coefficient indicating the characteristic of the infrared sensor; and storing in advance the absorption rate by the atmosphere at the wavelength of the absorption band when the value of the stored coefficient indicating the characteristic of the infrared sensor is detected, wherein calculating the surface temperature of the object uses the stored preset conversion equation corrected by the stored absorption rate, wherein the preset conversion equation is a calculation equation for determining the surface temperature of the object, which is obtained by transforming a following calculation equation indicating the output of the infrared sensor: V=b [[(τ/τ0)· f ( Tb )+(1−(τ/τ0))· f ( Ta )]− f ( Tr )]+ c wherein V is the output of the infrared sensor, b is sensitivity of the infrared sensor, τ is a transmission rate obtained from the absorption rate (1−τ) calculated by the absorption rate calculating means, τ0 is a transmission rate obtained from the absorption rate (1−τ0) stored in the absorption rate storing means, Tb is the surface temperature of the object, Ta is a space temperature between the object and a radiation temperature measuring device, Tr is a temperature of the radiation temperature measuring device, c is an offset of the infrared sensor, and f( ) is an arbitrary function. 6. A method to measure a surface temperature of an object without contact using an infrared sensor, the method comprising: measuring an output of the infrared sensor to detect a wavelength including an absorption band by atmosphere existing between the infrared sensor and the object; calculating an absorption rate by the atmosphere at a wavelength of the absorption band when the surface temperature of the object is measured; storing preset conversion information for converting the output of the infrared sensor into the surface temperature of the object; storing in advance the absorption rate by the atmosphere at the wavelength of the absorption band when the conversion information is set; and calculating the surface temperature of the object from the output of the infrared sensor, the calculated absorption rate, the stored absorption rate, and the stored preset conversion information, wherein the stored preset conversion information is a calculation equation for determining the surface temperature of the object, which is obtained by transforming a following calculation equation indicating the output of the infrared sensor: V=b [[(τ/τ0)· f ( Tb )+(1−(τ/τ0))· f ( Ta )]− f ( Tr )]+ c wherein V is the output of the infrared sensor, b is sensitivity of the infrared sensor, τ is a transmission rate obtained from the absorption rate (1−τ) calculated by the absorption rate calculating means, τ0 is a transmission rate obtained from the absorption rate (1−τ0) stored in the absorption rate storing means, Tb is the surface temperature of the object, Ta is a space temperature between the object and a radiation temperature measuring device, Tr is a temperature of the radiation temperature measuring device, c is an offset of the infrared sensor, and f( ) is an arbitrary function.