Optimization of Tungsten Content of ASME Gr.92 for the High Creep Rupture Strength

机译：优化ASME GR.92钨含量为高蠕变破裂力量

获取原文

页面导航

摘要
著录项
相似文献
相关主题

摘要

Tungsten containing ferritic creep resistant steels are the candidate materials for Ultra-Super-Cretical fossil power plant because of their high creep rupture strength. But the strengthening mechanisms by tungsten addition have not yet been completely studied. In this report, creep rupture time and creep strain rate measurement decided the optimum tungsten content in 9 to 12% chromium ferritic steels. The precipitation behavior of Laves phase and the precise discussion of creep strain rate analyses explain the contribution of Laves phase at the lath boundary and the contribution of tungsten in solid solution. P92 contains the optimum amount of tungsten and chromium, 1.8 mass% and 9 mass% respectively judging from the creep rupture strength point of view.

机译：含有铁素体蠕变抗性钢的钨是超级奇数化石发电厂的候选材料，因为它们的蠕变破裂强度高。但钨的加强机制尚未完全研究。在本报告中，蠕变破裂时间和蠕变应变速率测量决定了9至12％的铁素体钢中的最佳钨含量。 Laves阶段的降水行为及蠕变应变率的精确讨论分析解释了Laves阶段在Lath边界的贡献以及钨在固溶体中的贡献。 P92含有钨和铬的最佳量，分别从蠕变破裂强度的角度来判断1.8质量％和9质量％。

著录项

来源
《Conference on advances in materials technology for fossil power plants》|2001年||共9页
会议地点
作者
YASUSHI HASEGAWA; TARO MURAKI; MASAHIRO OHGAMI; HIROYUKI MIMURA;
展开▼
作者单位

展开▼
会议组织
原文格式 PDF
正文语种
中图分类发电厂;
关键词
laves phase; creep strain rate; transient creep; acclelrating creep; ASME-P92;

机译：疏浚阶段;蠕变应变率;瞬态蠕变;Acclelrating Creep;Asme-P92;

相似文献

外文文献
中文文献
专利

1. Effect of carbon content on creep rupture strength and microstructure in heat affected zone of heat resistant ferritic steel: alleviation of decrease in creep rupture strength in heat affected zone of heat resistant ferritic steel [J] . Hirata H., Ogawa K. Science and Technology of Welding & Joining . 2008,第6期

机译：碳含量对耐热铁素体钢热影响区蠕变断裂强度和显微组织的影响：减轻耐热铁素体钢热影响区蠕变断裂强度的降低
2. Evaluation of Long-Term Creep Rupture Strength of Tungsten- Strengthened Advanced 9-12Cr Steels [J] . F. Masuyama, N. Komai Key Engineering Materials . 2000,第期

机译：钨强化高级9-12Cr钢的长期蠕变断裂强度评估
3. Interconnection between Short-Term Strength, Static Stress-Rupture Strength, and Creep Resistance of Tungsten, Molybdenum, and Alloys Based on them [J] . V.V.Bukhanovskii Powder Metallurgy and Metal Ceramics . 1999,第7a8期

机译：基于它们的钨，钼和合金的短期强度，静应力断裂强度和抗蠕变性之间的相互关系
4. Optimization of Tungsten Content of ASME Gr.92 for the High Creep Rupture Strength [C] . YASUSHI HASEGAWA, TARO MURAKI, MASAHIRO OHGAMI, Advances in Materials Technology for Fossil Power Plants . 2001

机译：高蠕变断裂强度的ASME Gr.92钨含量的优化
5. A Probabilistic Creep Constitutive Model for Creep Deformation, Damage, and Rupture [D] . ?Hossain, Md Abir 2020

机译：蠕变变形，损伤和破裂的概率蠕变本构模型
6. Creeping Motion of Self Interstitial Atom Clusters in Tungsten [O] . Wang Huai Zhou, Chuan Guo Zhang, Yong Gang Li, -1

机译：钨自填隙原子团的蠕变运动
7. Effect of Carbon content on Creep Rupture Strength and Microstructure in Heat Affected Zone of Heat Resistant Ferritic Steel [O] . Hiroyuki Hirata, Kazuhiro Ogawa 2007

机译：碳含量对耐热铁素体钢热影响区蠕变破裂强度和微观结构的影响
8. CREEP-RUPTURE PROPERTIES OF TUNGSTEN AND TUNGSTEN-BASE ALLOYS [R] . H. E. McCoy 1966

机译：钨和钨基合金的蠕变破坏特性

Optimization of Tungsten Content of ASME Gr.92 for the High Creep Rupture Strength

摘要

著录项

相似文献

相关主题

期刊订阅