Abstract
A one-dimensional infrared radiation heating simulation method was developed that considers chemical changes in materials to be heated. The simulation method analyzes processes to heat polyethylene glycol with far infrared radiation and near infrared radiation, and compares the results with experimental results. The analytical results indicated relatively well the trends of temperature rise in parts of a material to be heated, proving the suitability of this method as a simplified method to investigate heating internal to a material. Identical result was obtained in heating the white of egg. As a result of using this method to calculate infrared radiation energy absorption in parts of the material being heated, it was found that heating with far infrared radiation has its energy absorbed in the vicinity of the surface of the heated material, and the trend would not change even if chemical change has been caused in the heated material. In addition, the present method can estimate complex infrared radiation heating processes in materials to be heated and the required amount of infrared ray irradiation relatively easily. The method can also be utilized for selection of infrared radiating bodies suitable for particular materials to be heated, as well as for rational designs
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Miyanaga, T;
Onuma, T;
Nakano, Y
[1]
- Central Research Institute of Electric Power Industry, Tokyo (Japan)
Citation Formats
Miyanaga, T, Onuma, T, and Nakano, Y.
Analysis of infrared radiation heating process considering chemical reaction of material to be heated; Hikanetsubutsu no kagaku henka wo koryoshita sekigaisen kanetsu simulation.
Japan: N. p.,
1993.
Web.
Miyanaga, T, Onuma, T, & Nakano, Y.
Analysis of infrared radiation heating process considering chemical reaction of material to be heated; Hikanetsubutsu no kagaku henka wo koryoshita sekigaisen kanetsu simulation.
Japan.
Miyanaga, T, Onuma, T, and Nakano, Y.
1993.
"Analysis of infrared radiation heating process considering chemical reaction of material to be heated; Hikanetsubutsu no kagaku henka wo koryoshita sekigaisen kanetsu simulation."
Japan.
@misc{etde_10128517,
title = {Analysis of infrared radiation heating process considering chemical reaction of material to be heated; Hikanetsubutsu no kagaku henka wo koryoshita sekigaisen kanetsu simulation}
author = {Miyanaga, T, Onuma, T, and Nakano, Y}
abstractNote = {A one-dimensional infrared radiation heating simulation method was developed that considers chemical changes in materials to be heated. The simulation method analyzes processes to heat polyethylene glycol with far infrared radiation and near infrared radiation, and compares the results with experimental results. The analytical results indicated relatively well the trends of temperature rise in parts of a material to be heated, proving the suitability of this method as a simplified method to investigate heating internal to a material. Identical result was obtained in heating the white of egg. As a result of using this method to calculate infrared radiation energy absorption in parts of the material being heated, it was found that heating with far infrared radiation has its energy absorbed in the vicinity of the surface of the heated material, and the trend would not change even if chemical change has been caused in the heated material. In addition, the present method can estimate complex infrared radiation heating processes in materials to be heated and the required amount of infrared ray irradiation relatively easily. The method can also be utilized for selection of infrared radiating bodies suitable for particular materials to be heated, as well as for rational designs of heating furnaces. 8 refs., 23 figs.}
place = {Japan}
year = {1993}
month = {Apr}
}
title = {Analysis of infrared radiation heating process considering chemical reaction of material to be heated; Hikanetsubutsu no kagaku henka wo koryoshita sekigaisen kanetsu simulation}
author = {Miyanaga, T, Onuma, T, and Nakano, Y}
abstractNote = {A one-dimensional infrared radiation heating simulation method was developed that considers chemical changes in materials to be heated. The simulation method analyzes processes to heat polyethylene glycol with far infrared radiation and near infrared radiation, and compares the results with experimental results. The analytical results indicated relatively well the trends of temperature rise in parts of a material to be heated, proving the suitability of this method as a simplified method to investigate heating internal to a material. Identical result was obtained in heating the white of egg. As a result of using this method to calculate infrared radiation energy absorption in parts of the material being heated, it was found that heating with far infrared radiation has its energy absorbed in the vicinity of the surface of the heated material, and the trend would not change even if chemical change has been caused in the heated material. In addition, the present method can estimate complex infrared radiation heating processes in materials to be heated and the required amount of infrared ray irradiation relatively easily. The method can also be utilized for selection of infrared radiating bodies suitable for particular materials to be heated, as well as for rational designs of heating furnaces. 8 refs., 23 figs.}
place = {Japan}
year = {1993}
month = {Apr}
}