Alloyed position determining method, alloyed position determining apparatus, and recording medium

The invention claimed is: 1. An alloyed position determining method comprising: a step for measuring, by each of a plurality of radiation thermometers, radiance of a steel sheet at positions at which the radiation thermometers are installed, the radiation thermometers being installed along a conveying direction of the steel sheet in a heat holding zone in a hot dip galvanizing line of the steel sheet, the radiation thermometers measuring radiance of the steel sheet conveyed; a radiance information acquiring step for acquiring, by a processor, information regarding a result of the measurement of radiance from each of the plurality of radiation thermometers; a steel sheet temperature estimating step for estimating, by the processor, steel sheet temperatures at the installation positions of the radiation thermometers by use of information regarding a temperature decreasing pattern of the steel sheet, accompanied by a position change in the conveying direction in the heat holding zone, and information regarding the installation positions of the radiation thermometers; an emissivity calculating step for calculating, by the processor, emissivity at the installation positions of the radiation thermometers by use of the estimated steel sheet temperatures estimated at the installation positions of the radiation thermometers and the information regarding the result of measurement of radiance; and an alloyed position determining step for determining, by the processor, an alloyed position of the steel sheet in the heat holding zone based on the calculated emissivity; wherein the information regarding the temperature decreasing pattern indicates a relationship between the installation positions of the radiation thermometers and a rate of temperature decrease, and is one of information stored in a storage unit for each manufacturing condition on the basis of past performance data or information in which results of heat transfer model simulation regarding extracted heat from the steel sheet due to an atmosphere in a furnace and an inner wall is stored in a storage unit. 2. The alloyed position determining method according to claim 1 , wherein, in the steel sheet temperature estimating step, an amount of temperature decrease in the steel sheet is calculated based on the information regarding the temperature decreasing pattern of the steel sheet and the information regarding the installation positions of the radiation thermometers, and the estimated steel sheet temperatures are calculated by subtracting the calculated amount of temperature decrease from a temperature of the steel sheet on an entry section of the heat holding zone. 3. The alloyed position determining method according to claim 2 , wherein, in the alloyed position determining step, when emissivity which is calculated in the emissivity calculating step and which corresponds to a position of an (n−1)(n≧2)-th radiation thermometer from the entry section of the heat holding zone is lower than a predetermined threshold value and emissivity which corresponds to a position of an n-th radiation thermometer is higher than or equal to the predetermined threshold value, it is determined that a position where alloying has occurred is a section between an installation position of an (n−1)-th radiation thermometer and an installation position of the n-th radiation thermometer in the heat holding zone. 4. The alloyed position determining method according to claim 1 , wherein, in the steel sheet temperature estimating step, the temperature decreasing pattern is calculated based on a measured temperature of the steel sheet before the steel sheet enters the heat holding zone, measured with a spectral radiation thermometer, and a measured temperature of the steel sheet in the heat holding zone, measured with a multicolor radiation thermometer, and the steel sheet temperature is estimated by use of the calculated temperature decreasing pattern and the information regarding the installation positions of the radiation thermometers. 5. The alloyed position determining method according to claim 4 , wherein, in the alloyed position determining step, when emissivity which is calculated in the emissivity calculating step and which corresponds to a position of an (n−1)(n≧2)-th radiation thermometer from the entry section of the heat holding zone is lower than a predetermined threshold value and emissivity which corresponds to a position of an n-th radiation thermometer is higher than or equal to the predetermined threshold value, it is determined that a position where alloying has occurred is a section between an installation position of an (n−1)-th radiation thermometer and an installation position of the n-th radiation thermometer in the heat holding zone. 6. The alloyed position determining method according to claim 1 , wherein, in the alloyed position determining step, when emissivity which is calculated in the emissivity calculating step and which corresponds to a position of an (n−1)(n≧2)-th radiation thermometer from the entry section of the heat holding zone is lower than a predetermined threshold value and emissivity which corresponds to a position of an n-th radiation thermometer is higher than or equal to the predetermined threshold value, it is determined that a position where alloying has occurred is a section between an installation position of an (n−1)-th radiation thermometer and an installation position of the n-th radiation thermometer in the heat holding zone. 7. An alloyed position determining apparatus comprising: a plurality of radiation thermometers configured to be installed along a conveying direction of a steel sheet in a heat holding zone in a hot dip galvanizing line of the steel sheet, the radiation thermometers measuring radiance of the steel sheet conveyed; a radiance information acquiring unit configured to acquire information regarding a result of measurement of radiance from each of the plurality of radiation thermometers; a steel sheet temperature estimating unit configured to estimate steel sheet temperatures at the installation positions of the radiation thermometers by use of information regarding a temperature decreasing pattern of the steel sheet, accompanied by a position change in the conveying direction in the heat holding zone, and information regarding the installation positions of the radiation thermometers; an emissivity calculating unit configured to calculate emissivity at the installation positions of the radiation thermometers by use of the estimated steel sheet temperatures estimated at the installation positions of the radiation thermometers, estimated by the steel sheet temperature estimating unit, and the information regarding the result of measurement of radiance; and an alloyed position determining unit configured to determine an alloyed position of the steel sheet in the heat holding zone based on the emissivity calculated by the emissivity calculating unit, wherein the information regarding the temperature decreasing pattern indicates a relationship between the installation positions of the radiation thermometers and a rate of temperature decrease, and is one of information stored in a storage unit for each manufacturing condition on the basis of past operation performance data or information in which results of heat transfer model simulation regarding extracted heat from the steel sheet due to an atmosphere in a furnace and an inner wall is stored in a storage unit. 8. The alloyed position determining apparatus according to claim 7 , wherein the steel sheet temperature estimating unit calculates an amount of temperature decrease in the steel sheet based on the information regarding the temperature decreasing pattern of the steel sheet and the information regarding the installation positi