ヘルプ

詳細検索

論文検索サイト

トップ
鉄と鋼
Vol. 86 (2000), No. 8

鉄と鋼 Vol. 86 (2000), No. 8

Grid List Abstracts

オンライン版ISSN:	1883-2954
冊子版ISSN:	0021-1575
発行機関:	The Iron and Steel Institute of Japan

Backnumber

Vol. 110 (2024)
1. No.15
2. No.14
3. No.13
4. No.12
5. No.11
6. No.10
7. No.9
8. No.8
9. No.7
10. No.6
11. No.5
12. No.4
13. No.3
14. No.2
15. No.1
Vol. 109 (2023)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 108 (2022)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 107 (2021)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 106 (2020)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 105 (2019)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 104 (2018)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 103 (2017)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 102 (2016)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 101 (2015)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 100 (2014)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 99 (2013)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 98 (2012)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 97 (2011)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 96 (2010)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 95 (2009)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 94 (2008)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 93 (2007)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 92 (2006)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 91 (2005)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 90 (2004)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 89 (2003)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 88 (2002)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 87 (2001)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 86 (2000)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 85 (1999)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 84 (1998)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 83 (1997)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 82 (1996)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 81 (1995)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 80 (1994)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 79 (1993)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 78 (1992)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 77 (1991)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 76 (1990)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 75 (1989)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 74 (1988)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 73 (1987)
1. No.16
2. No.15
3. No.14
4. No.13
5. No.12
6. No.11
7. No.10
8. No.9
9. No.8
10. No.7
11. No.6
12. No.5
13. No.4
14. No.3
15. No.2
16. No.1
Vol. 72 (1986)
1. No.16
2. No.15
3. No.14
4. No.13
5. No.12
6. No.11
7. No.10
8. No.9
9. No.8
10. No.7
11. No.6
12. No.5
13. No.4
14. No.3
15. No.2
16. No.1
Vol. 71 (1985)
1. No.16
2. No.15
3. No.14
4. No.13
5. No.12
6. No.11
7. No.10
8. No.9
9. No.8
10. No.7
11. No.6
12. No.5
13. No.4
14. No.3
15. No.2
16. No.1
Vol. 70 (1984)
1. No.16
2. No.15
3. No.14
4. No.13
5. No.12
6. No.11
7. No.10
8. No.9
9. No.8
10. No.7
11. No.6
12. No.5
13. No.4
14. No.3
15. No.2
16. No.1
Vol. 69 (1983)
1. No.16
2. No.15
3. No.14
4. No.13
5. No.12
6. No.11
7. No.10
8. No.9
9. No.8
10. No.7
11. No.6
12. No.5
13. No.4
14. No.3
15. No.2
16. No.1
Vol. 68 (1982)
1. No.16
2. No.15
3. No.14
4. No.13
5. No.12
6. No.11
7. No.10
8. No.9
9. No.8
10. No.7
11. No.6
12. No.5
13. No.4
14. No.3
15. No.2
16. No.1
Vol. 67 (1981)
1. No.16
2. No.15
3. No.14
4. No.13
5. No.12
6. No.11
7. No.10
8. No.9
9. No.8
10. No.7
11. No.6
12. No.5
13. No.4
14. No.3
15. No.2
16. No.1
Vol. 66 (1980)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 65 (1979)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 64 (1978)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 63 (1977)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 62 (1976)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 61 (1975)
1. No.15
2. No.14
3. No.13
4. No.12
5. No.11
6. No.10
7. No.9
8. No.8
9. No.7
10. No.6
11. No.5
12. No.4
13. No.3
14. No.2
15. No.1
Vol. 60 (1974)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 59 (1973)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 58 (1972)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 57 (1971)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 56 (1970)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 55 (1969)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 54 (1968)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 53 (1967)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 52 (1966)
1. No.13
2. No.12
3. No.11
4. No.10
5. No.9
6. No.8
7. No.7
8. No.6
9. No.5
10. No.4
11. No.3
12. No.2
13. No.1
Vol. 51 (1965)
1. No.13
2. No.12
3. No.11
4. No.10
5. No.9
6. No.8
7. No.7
8. No.6
9. No.5
10. No.4
11. No.3
12. No.2
13. No.1
Vol. 50 (1964)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 49 (1963)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 48 (1962)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 47 (1961)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 46 (1960)
1. No.14
2. No.13
3. No.12
4. No.11
5. No.10
6. No.9
7. No.8-supl
8. No.7
9. No.6
10. No.5
11. No.4
12. No.3
13. No.2
14. No.1
Vol. 45 (1959)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 44 (1958)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 43 (1957)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 42 (1956)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 41 (1955)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1

キーワードランキング

21 Nov. (Last 30 Days)

鉄と鋼 Vol. 86 (2000), No. 8

Rate of Reduction of Chromium Ore by Liquid Iron Containing Carbon and Silicon

Takamitsu NAKASUGA, Haiping SUN, Kunihiko NAKASHIMA, Katsumi MORI

pp. 499-506

抄録

The rate of smelting reduction of top-added chromium ore with fluxes such as SiO₂, CaO-SiO₂ and Na₂B₄O₇ by liquid iron containing carbon and silicon was measured at 14001600°C under an argon atmosphere. Experiments were carried out to examine effects of initial silicon content, temperature, kind of flux additive and amount of flux addition.
The rate of reduction increased remarkably with an increase of silicon content in liquid iron. It also increased with the addition of various fluxes. Na₂B₄O₇ was found to have the largest promoting effect on the reduction. When fluxes were added, it was observed that they reacted with chromium ore to form liquid slag. Therefore, it was estimated that the reduction took place mainly at the interface between slag and metal. The initial rate of reduction is not affected by the amount of fluxes addition. However, the chromium yield increased with increased amount of fluxes. The effect of temperature on the rate of reduction was significant. The apparent activation energies were about 217320kJ/mol in the case of formation of liquid slag. The reduction mechanism and the rate-controlling steps were discussed, finally.

ブックマーク

詳細

PDFダウンロード

SNSによる共有

論文タイトル

Bibtex

Ris

Effect of Volume Change of Coal during Plastic and Resolidifying Phase on the Internal Gas Pressure in Coke Ovens

Seiji NOMURA, Takashi ARIMA

pp. 507-513

抄録

The coking pressure in coke oven, which is caused by the internal gas pressure in the coal plastic layer, is determined by the gas permeability of the layer. The gas permeability of the plastic layer depends on its density as well as the physical property of the plastic coal itself. The plastic layer is between the coke layer and the coal layer and the effect of the volume change of these outer layers, i.e. contraction and compression, on the density and the internal gas pressure of the plastic layer was studied. Sandwich carbonization test, where different coals were charged in the test coke oven, showed that the internal gas pressure in the plastic layer depends not only on the one kind of coal in plastic phase but also on the other kind of coal in resolidifying phase near the oven walls. The relative volume of coke transformed from the unit volume of coal was measured using X-ray CT scanner and it varied greatly across the coke oven width depending on the kinds of coals. The volume change of coal during plastic and resolidifying phase affects the density and the internal gas pressure of the plastic layer. The relative volume of semicoke and coke transformed from the unit volume of coal near the oven walls is higher for a high coking pressure coal than that for a low coking pressure coal. This leads to the high density of the plastic layer and the generation of dangerously high internal gas pressure in the oven centre.

他の人はこちらも検索

最適造粒水分に及ぼす鉄鉱石中微粒子の定量的影響

鉄と鋼 Vol.94(2008), No.11

The Current Status and Future of Iron Ore and Coal Resources for Japanese Steel Mills

鉄と鋼 Vol.90(2004), No.2

Effect of Hot Briquetting of Preheated Coal on Carry-over during Charging

鉄と鋼 Vol.90(2004), No.9

ブックマーク

詳細

PDFダウンロード

SNSによる共有

論文タイトル

Bibtex

Ris

Direct Observation of the Free Surface Behavior of a Molten Metal under the Imposition of an Intermittent Alternating Magnetic Field

Yueming ZHOU, Kazuhiko IWAI, Shigeo ASAI

pp. 514-518

抄録

In continuous casting, the free surface motion of a molten metal plays an important role for determining the surface quality of products. In order to clarify the free surface behavior of a molten metal under the imposition of an intermittent alternating magnetic field, free surface waves of a molten gallium were visualized and recorded by use of a high-speed video camera. It is noticed that the number of capillary waves generated in the radial direction increased with increase of the intermittent frequency and was decreased by inserting a copper shield between a coil and a mold. The number of the waves generated in the azimuthal direction decreased during propagating from the vicinity of a sidewall to the center. Asymmetric gravity waves were excited when the distribution of the magnetic field was non-uniform in the azimuthal direction or the intermittent frequency was adjusted near the resonance frequency.

ブックマーク

詳細

PDFダウンロード

SNSによる共有

論文タイトル

Bibtex

Ris

Effect of Differential Tin Coatings on Resistance Seam Weldability of Low Tin-coated Steel for Beverage Cans

Nobuyoshi SHIMIZU, Nobuyuki NISHIMOTO, Shun-ichi MORITA, Jun FUKAI, Shunichiro BABA, Osamu MIYATAKE

pp. 519-525

抄録

Under the intense competition among many packages, the welded can such as beverage can, food can and aerosol can occupies a dominant position owing to the rational manufucturing process of resistance seam welding. However, the seam welding process itself is further needed to increase the welding speed to improve the productivity without increasing the steel thickness and also the coating weight. To overcome this subject, the authors investigated the effect of main parameters on weldability and established two-dimensional model for calculation in the former reports. As a result, it was exemplified the importance of the current path length during welding at the interfaces.
The above result reminds us that the actual welding machine has a pair of different size electrode, therefore the current path length is considered to be different. The differencially coated tinplate sheet was prepared to change the current path length at the interfaces. Incidentally, tin free steel was prepared to change the current path lengths at the interfaces by pre-pressing of welding part. The same model was applied to compare the culculation results of the differentially coated tinplate with that of equally coated one. Finally, the calculation proved the results that the heat balance between two interfaces is very important and the weldability can be improved by the balance of current path lengths by decreasing the tin coating weight of upper side.

ブックマーク

詳細

PDFダウンロード

SNSによる共有

論文タイトル

Bibtex

Ris

The Effect of Temperature and Water Vapor on the Initial Stage of High Temperature Oxidation of an Fe-1.5mass% Si Alloy

Michihisa FUKUMOTO, Shigeru MAEDA, Shigenari HAYASHI, Toshio NARITA

pp. 526-533

抄録

The initial stage of oxidation (up to 600s) in air and air-H₂O atmospheres was investigated for Fe and an Fe-1.5mass%Si alloy at 1373 and 1473K. The oxidation kinetics of Fe was parabolic at both 1373 and 1473K and the parabolic rate constants are very similar in both air and air-H₂O. For the Fe-1.5Si, at 1373K the oxidation amounts increased rapidly after an incubation period (up to 400s) in air-H₂O, while at 1473K oxidation obeyed a linear rate law in both air and air-H₂O, because a liquid phase was formed with FeO and Fe₂SiO₄. The linear rate constants were very similar both in air and in air-H₂O. In Pt-marker experiments in air-H₂O for Fe-1.5Si it was found that the Pt-marker located between external Fe-oxide and inner FeO+Fe₂SiO₄ layers at 1373K, while at 1473K the Pt-marker located on the alloy surface. The thickness of each layer was measured as a function of time at 1373K in air-H₂O. It was found that after an Si-rich oxide (SiO₂+Fe₂SiO₄) layer at the initial stage of oxidation disappeared, a thick inner FeO+Fe₂SiO₄ layer formed, accompanied by the formation of Fe₃O₄inside the outer Fe₂O₃ scale. Rapid oxidation after 400s proceeded with the growth of an FeO layer in the surface scale. The change of the Si-rich oxide layer to an FeO+Fe₂SiO₄ mixture is due to penetration of water molecules. A combined process of perforating dissociation and transport of water molecules was suggested to be the cause of the rapid growth of the inner layer.

ブックマーク

詳細

PDFダウンロード

SNSによる共有

論文タイトル

Bibtex

Ris

Corrosion Resistance and Protection Mechanism of Hot-dip Zn-Al-Mg Alloy Coated Steel Sheetunder Accelerated Corrosion Environment

Atsushi KOMATSU, Hidefusa IZUTANI, Takao TSUJIMURA, Atsushi ANDOH, Toshiharu KITTAKA

pp. 534-541

抄録

Corrosion behavior of hot-dip Zn-6%Al-03%Mg alloy coated steel sheets in cyclic corrosion test (CCT) has been investigated.
The corrosion resistance was improved with increasing Mg content in the coating layer, and the highest corrosion resistance was observed at 3% Mg. In Zn-6%Al-3%Mg alloy coated steel sheet, the formations of zinc carbonate hydroxide and zinc oxide were suppressed for longer duration compared with Zn-0.2%Al and Zn-4.5%Al-0.1%Mg alloy coated steel sheets. As a result, zinc chloride hydroxide existed stable on the surface of the coating layer. From the polarization behaviors in 5% NaCl aqueous solution after CCT, it was found that the corrosion current density of Zn-6%Al-3%Mg alloy coated steel sheet was much smaller than those of Zn-0.2%Al and Zn-4.5%Al-0.1%Mg alloy coated steel sheets. As zinc carbonate hydroxide and zinc oxide had poor adhesion to the coating layer and had porous structures, these corrosion products were considered to have little protective action for the coating layer. Therefore, it was concluded that Mg suppressed the formation of such nonprotective corrosion products, resulting in the remarkable improvement of corrosion resistance.

他の人はこちらも検索

Microstructure and Corrosion Behavior of Intermetallic Layer of Coating in Zn-Al Alloy Coated Steel Wire Manufactured by Double Hot-Dip Process

鉄と鋼 Vol.75(1989), No.2

塗装Zn および55%Al–Znめっき鋼板の端面腐食とクロメートの役割

鉄と鋼 Vol.95(2009), No.7

Approach to the Development of Corrosion Resistance of Fe-Zn Alloy Coating from Corrosion Science

鉄と鋼 Vol.72(1986), No.8

ブックマーク

詳細

PDFダウンロード

SNSによる共有

論文タイトル

Bibtex

Ris

Effect of Initial Microstructure on Long Term Creep Strength of a Low Alloy Ferritic Steel

Kazuhiro KIMURA, Hideaki KUSHIMA, Eiji BABA, Tetsuo SHIMIZU, Yoshikazu ASAI, Fujio ABE, Koichi YAGI

pp. 542-549

抄録

The effect of initial microstructure, martensite, tempered martensite, bainite and ferrite+pearlite, on long term creep strength property up to about 80000h at 848K has been investigated on a 0.5Cr-0.5Mo low alloy ferritic steel. No significant effect of tempering after quenching on the long term creep strength has been observed. However, strong effect of transformation process during cooling from austenite has been observed. Creep strength of bainite microstructure is higher than those of martensitic microstructure, independent of tempering after quenching. In the low stress condition in which applied stress is lower than proof stress, creep strength of full annealed microstructure which consists of ferrite and pearlite has been found to be higher than the others. The smallest creep rate of a full annealed microstructure in the long term creep region should be caused by both very low dislocation density of the initial microstructure and small amount of dislocations generated under the low stress condition.

ブックマーク

詳細

PDFダウンロード

SNSによる共有

論文タイトル

Bibtex

Ris

Heterogeneous Recovery and Precipitation of Z Phase during Long Term Creep Deformation of Modified 9Cr-1Mo Steel

Kenta SUZUKI, Shinji KUMAI, Hideaki KUSHIMA, Kazuhiro KIMURA, Fujio ABE

pp. 550-557

抄録

Degradation of 9Cr-1Mo-V-Nb steel during long term creep deformation is caused by a preferential recovery at the vicinity of prior austenite grain boundary (PAGB). Changes in microstructure, especially on precipitates have been investigated in order to understand a mechanism of such heterogeneous recovery. Heterogeneous recovery has been quantitatively demonstrated by the distribution of subgrain size. Three types of the precipitates, M₂₃C₆, V(C, N) and Nb (C, N), have been found in the as tempered condition. Precipitation of Laves phase and Z phase have been found in the creep ruptured specimen. Laves phase is found in all the creep ruptured specimen. On the other hand, Z phase is found in the specimens creep ruptured after more than 10000 h. Complex nitride phase of Z phase is rich in Cr, Nb and V of the form Cr(Nb, V)N. Precipitation of Z phase takes place in the long term region and coarsening rate of it is much faster than that of MX, such as V(C, N) and Nb(C, N). It has been concluded that a precipitation of Z phase in the long term region is one of the reason of preferential recovery at the vicinity of PAGB in 9Cr-1Mo-V-Nb steel.

ブックマーク

詳細

PDFダウンロード

SNSによる共有

論文タイトル

Bibtex

Ris

Effect of Solute Copper on Hardness and Ductile-to-Brittle Transition in α-Iron

Junaidi SYARIF, Toshiyuki HOSHINO, Toshihiro TSUCHIYAMA, Setsuo TAKAKI

pp. 558-562

抄録

Effects of solute Cu on strengthening and ductile-to-brittle transition (DBT) of α-iron have studied for Fe-(02)mass%Cu alloys. The Fe-Cu alloys exhibit massive ferritic transformation on water-quenching from solution treatment temperature. With increasing Cu content, the massive ferrite grains were refined and the hardness was raised. Effect of the solid solution hardening is predominant to the strengthening, but the refinement of massive ferrite grains does not affect so much. Charpy impact tests showed that Cu addition substantially lowers DBT temperature of α-iron. The embrittleness at low temperature was caused by the onset of cleavage cracks at ferrite grain boundaries where deformation twins impinged. Copper in solution suppresses the formation of deformation twins, and this results in the shift of DBT temperature to lower side.

他の人はこちらも検索

Effects of Cu and Ti-precipitates on Recrystallization Texture of Cu-precipitation Hardening Ultra Low Carbon Cold-rolled Steel Sheet

鉄と鋼 Vol.80(1994), No.1

Effect of the State of Cu in Hot-bands on r-value of Cu-added Extra Low Carbon Cold Rolled Steel Sheets

鉄と鋼 Vol.81(1995), No.7

Precipitation Strengthening at Elevated Temperature in Fe-Cu Alloys

鉄と鋼 Vol.89(2003), No.5

ブックマーク

詳細

PDFダウンロード

SNSによる共有

論文タイトル

Bibtex

Ris

Impact Properties of Low Alloy TRIP Steels

Sung-Moo SONG, Koh-ichi SUGIMOTO, Mitsuyuki KOBAYASHI, Hideyuki MATSUBARA, Takahiro KASHIMA

pp. 563-569

抄録

The impact properties of high-strength low alloy TRIP steels such as "TRIP-aided dual-phase steel" and "TRIP-aided bainitic steel" associated with the transformation-induced plasticity (TRIP) of retained austenite were investigated for some applications to the automotive impact members. The TRIP steels possessed far higher impact absorbed value and lower ductile-brittle transition temperature than the conventional ferrite-martensite and ferrite-pearlite steels. The stress relaxation resulting from the strain-induced transformation of retained austenite islands or films improved the impact properties in terms of suppressing void and/or crack initiation and these propagation. The best impact properties were completed in the steel composing of uniform fine bainitic lath structure and a large amount of stable interlath retained austenite films.

ブックマーク

詳細

PDFダウンロード

SNSによる共有

論文タイトル

Bibtex

Ris

論文アクセスランキング

21 Nov. (Last 30 Days)

In-situ Observation of Precipitation and Growth of MnS Inclusions during Solidification of a High Sulfur Steel

ISIJ International 早期公開
Measurement of Bubble Size Distribution and Generation Position of Bubbles Generated during Smelting Reduction of Iron Oxide-containing Slag

ISIJ International 早期公開
Injection of hydrogenous gases into the blast furnace tuyeres for reducing CO₂ emissions: a review

ISIJ International 早期公開
Development of a Low-carbon Sintering Process Technology and Its Application to a Pilot-scale Sintering Testing

ISIJ International Vol.64(2024), No.13
凝固過程における溶鋼中からAl₂O₃上へのMnSの晶出挙動

鉄と鋼早期公開
Molecular dynamics simulation of viscosity of the CaO, MgO and Al₂O₃ melts

ISIJ International 早期公開
Fe–(0.5–2.0)%Al–2.0%Mn合金の一方向凝固におけるAlNの晶出挙動に及ぼすAl濃度の影響

鉄と鋼早期公開
凝固過程のミクロ偏析による溶質濃度分布の定量的理解

鉄と鋼早期公開
SOKD: A soft optimization knowledge distillation scheme for surface defects identification of hot-rolled strip

ISIJ International 早期公開
Reduction and Carburization Behaviors of Iron Oxide Composite with Iron Carbide and Free Carbon

ISIJ International 早期公開

この機能はログイン後に利用できます。
下のボタンをクリックしてください。

鉄と鋼 Vol. 86 (2000), No. 8

キーワードランキング

reduction caco3 in electric furnace

kinetics of decarburization of liquid iron with high concentration ofcarbon

kinetics of decarburization of liquid iron by ar-coz gasmixture

ahss

charpy impact chemistry

dual phase steel

foamy slag in eaf

kinetics of decarburization of liquid iron by

ladle furnace flicker

scm440

鉄と鋼 Vol. 86 (2000), No. 8

Rate of Reduction of Chromium Ore by Liquid Iron Containing Carbon and Silicon

SNSによる共有

Effect of Volume Change of Coal during Plastic and Resolidifying Phase on the Internal Gas Pressure in Coke Ovens

SNSによる共有

Direct Observation of the Free Surface Behavior of a Molten Metal under the Imposition of an Intermittent Alternating Magnetic Field

SNSによる共有

Effect of Differential Tin Coatings on Resistance Seam Weldability of Low Tin-coated Steel for Beverage Cans

SNSによる共有

The Effect of Temperature and Water Vapor on the Initial Stage of High Temperature Oxidation of an Fe-1.5mass% Si Alloy

SNSによる共有

Corrosion Resistance and Protection Mechanism of Hot-dip Zn-Al-Mg Alloy Coated Steel Sheetunder Accelerated Corrosion Environment

SNSによる共有

Effect of Initial Microstructure on Long Term Creep Strength of a Low Alloy Ferritic Steel

SNSによる共有

Heterogeneous Recovery and Precipitation of Z Phase during Long Term Creep Deformation of Modified 9Cr-1Mo Steel

SNSによる共有

Effect of Solute Copper on Hardness and Ductile-to-Brittle Transition in α-Iron

SNSによる共有

Impact Properties of Low Alloy TRIP Steels

SNSによる共有

論文アクセスランキング

In-situ Observation of Precipitation and Growth of MnS Inclusions during Solidification of a High Sulfur Steel

Measurement of Bubble Size Distribution and Generation Position of Bubbles Generated during Smelting Reduction of Iron Oxide-containing Slag

Injection of hydrogenous gases into the blast furnace tuyeres for reducing CO2 emissions: a review

Development of a Low-carbon Sintering Process Technology and Its Application to a Pilot-scale Sintering Testing

凝固過程における溶鋼中からAl2O3上へのMnSの晶出挙動

Molecular dynamics simulation of viscosity of the CaO, MgO and Al2O3 melts

Fe–(0.5–2.0)%Al–2.0%Mn合金の一方向凝固におけるAlNの晶出挙動に及ぼすAl濃度の影響

凝固過程のミクロ偏析による溶質濃度分布の定量的理解

SOKD: A soft optimization knowledge distillation scheme for surface defects identification of hot-rolled strip

Reduction and Carburization Behaviors of Iron Oxide Composite with Iron Carbide and Free Carbon

詳細検索

Injection of hydrogenous gases into the blast furnace tuyeres for reducing CO₂ emissions: a review

凝固過程における溶鋼中からAl₂O₃上へのMnSの晶出挙動

Molecular dynamics simulation of viscosity of the CaO, MgO and Al₂O₃ melts