- 【Updated on May 12, 2025】 Integration of CiNii Dissertations and CiNii Books into CiNii Research
- Trial version of CiNii Research Knowledge Graph Search feature is available on CiNii Labs
- 【Updated on June 30, 2025】Suspension and deletion of data provided by Nikkei BP
- Regarding the recording of “Research Data” and “Evidence Data”
Corrosion Resistance of Metallic Materials in High Temperature Gases Composed of Iodine, Hydrogen Iodide and Water (Environment of the 3rd and 4th Stage Reactions)
-
- Imai Yoji
- National Chemical Laboratory for Industry
-
- Kanda Yukio
- National Chemical Laboratory for Industry
-
- Sasaki Hidetsugu
- National Chemical Laboratory for Industry
-
- Togano Hideo
- National Chemical Laboratory for Industry
Bibliographic Information
- Other Title
-
- ヨウ素, ヨウ化水素及び水を含む高温ガス (第3, 4段反応環境) に対する金属材料の耐食性
- ヨウソ ヨウカ スイソ オヨビ ミズ オ フクム コウオン ガス ダイ 3 4
- マグネシウム-ヨウ素サイクルによる熱化学的水素製造法の装置材料研究 (第4報)
- Study on Construction Materials for the Magnesium-Iodine Cycle of Thermochemical Hydrogen Production Process (Part 4)
Search this article
Description
In order to select candidate materials for the equipment of the 3rd and 4th reaction of Mg-I thermochemical hydrogen production cycle, screening test of metallic materials was conducted. The corrosive constituents concerned in the 3rd reaction are hydrogen iodide, iodine, and water, and in the 4th reaction, hydrogen iodide, iodine, water, and hydrogen. Therefore, for the 1st screening test, the testing environment was made up of hydrogen iodide, iodine, and water under the condition of linearly increasing temperature from 250°C to 700°C. The several materials which passed the 1st screening test were examined isothermally for 200hrs in the iodide and iodine atmosphere with and without hydrogen. The results are as follows: (1) Common engineering materials, such as the austenitic and ferritic stainless steels, nickel-base alloys, and cobalt-base alloys are unsuitable because of their inability to resist the high corrosive atmosphere. (2) Corrosion rates of niobium, zirconium, and tantalum are very low in the atmosphere at 200°C, but they absorb hydrogen to some degree and then may be sensitive to hydrogen brittleness. (3) Corrosion rates of titanium and its alloys are negligible at 350°C, but also may be sensitive to hydrogen brittleness. (4) Molybdenum is the best choice below 450°C at present, because its corrosion rate is very low, and it does not absorb hydrogen. The oxide scale on the molybdenum shows the tendency of evaporation at 450°C, but the rate is extremely low. (5) Chromium, tungusten, aluminum, gold, and platinum can withstand the corrosive atmosphere at higher temperature also. It is, however, impossible to use them because of expensiveness (Au, Pt), low tensile strength in high temperature (Al), or brittleness (Cr, W). (b) Several surface treatments such as plasmaspray coating of oxides, electroplating of chromium, and diffusion coating of aluminum and chromium are yet incredible at present.
Journal
-
- CORROSION ENGINEERING
-
CORROSION ENGINEERING 31 (11), 714-721, 1982
Japan Society of Corrosion Engineering
- Tweet
Details 詳細情報について
-
- CRID
- 1390282681236837376
-
- NII Article ID
- 130006024625
- 130004731477
-
- NII Book ID
- AN00225595
-
- ISSN
- 18841155
- 00109355
-
- NDL BIB ID
- 2470927
-
- Data Source
-
- JaLC
- NDL Search
- Crossref
- CiNii Articles
-
- Abstract License Flag
- Disallowed