2) austenizing
奥氏体化
1.
The quenching microstructure of low carbon steel after austenizing with and without DC electric field was studied.
研究了低碳钢在直流静电场中进行奥氏体化后淬火的显微组织。
2.
From the mechanics of steel austenizing ,a mathimatic model of austenizing process is set up.
从钢的奥氏体化机理入手,建立了加热奥氏体的数学模型;并对激光加热温度场和硬化带进行了估算。
3.
The microstructure of 45CrMoV steel after austenizing followed by air cooling and tempering at various temperatures have been studied, using TEM and SAD.
利用透射电镜和选区电子衍射研究了45CrMoV钢奥氏体化后空冷及其在不同温度回火的显微组织。
3) austenization
奥氏体化
1.
Effects of Nb on the austenization and static recrystallization behavior of 20MnSi steel;
铌对20MnSi钢奥氏体化和静态再结晶的影响
2.
Simulation of austenization during intercritical annealing for Fe-C-Mn cold rolling dual phase steel;
Fe-C-Mn系冷轧双相钢两相区奥氏体化过程模拟
3.
In this paper the quenching microstructure of the low carbon steel in the austenization with the application of an electric field 20kV/cm between the specimen and a companion electrode of an electrostatic circuit is studied.
研究了电场奥氏体化对低碳钢的淬火组织的影响。
4) austenitizing
['ɔ:stənə'taiziŋ]
奥氏体化
1.
The effect of austenitizing temperature and time on microstructure and property of 27SiMn steel was researched by the orthogonal regressive principle.
采用正交组合回归设计试验方法 ,研究了奥氏体化温度和时间对 2 7SiMn钢组织和性能的影响。
2.
The Ms points are 320℃,306℃,280℃ respectively when the austenitizing temperatures are 950℃,900℃ and 850℃ and rise with increasing of austenizing temperature.
测定了 45Si2Cr钢分别在 95 0℃和 90 0℃奥氏体化后的连续冷却转变曲线。
3.
The results show that carbon atoms diffuse in short distance and no austenite occurs when the testing steel is austenitized at 720~750 ℃; they diffuse in long distance and austenite occurs at 755℃ which is the turning point of austenitizing temperature.
利用光学显微镜、扫描电镜(SEM)、维氏硬度计以及thermo-calc和photoshop软件对经不同温度奥氏体化、淬火后的GCr15轴承钢试样的显微组织进行了分析研究。
5) Austenitization
奥氏体化
1.
Effect of Manganese on Austenitization of High Chromium Cast Iron;
锰对高铬铸铁奥氏体化过程的影响
2.
A mathematical model of heating austenitization process has been founded in this paper.
利用有限元数值方法模拟了9Cr2Mo冷轧辊加热过程中的瞬态温度场和奥氏体化进程,建立了加热奥氏体化过程的数学模型通过采样轧辊内部一些特定位置的加热曲线验证了模拟结果的准确性,根据模拟结果提出了优化的冷轧辊加热工艺,该工艺明显地缩短了加热时间,具有显著节能的效
3.
This paper gives a detailed analysis of the traditional austenitization theory.
本文通过对传统奥氏体化理论的详细分析,证明在这一理论指导下应用的淬火保温时间是保守的、不确切的,可以缩短为零。
6) precipitate strengthened austenite alloys
沉淀强化奥氏体合金
1.
Discrete Variational Method (DVM) was adopted in the first principles calculation of hydrogen occupation between γ and γ′ in precipitate strengthened austenite alloys to analysis the mechanism of hydrogen embrittlement of them.
本文针对沉淀强化奥氏体合金氢脆通常较单相奥氏体严重这一点,采用离散变分方法对氢在沉淀强化奥氏体合金中γ基体与γ′相之间占位进行了第一原理计算和分析。
补充资料:奥氏体-贝氏体球铁
分子式:
CAS号:
性质:又叫奥-贝球铁。基体组织为奥氏体加贝氏体组织的球墨铸铁。这类球铁硅含量一般在1.4%~3.8%。含锰量小于0.5%,与普通球铁比较硅偏高、锰偏低。通过调节化学成分与热处理获得理想的奥-贝球铁的基体组织为针状贝氏体或无碳贝氏体一富碳奥氏体。这类球铁具有优良的综合机械性能、强度高、耐磨性好、韧性好、特别是有高的缺口韧性,可代替钢,用于制作重要受力结构件,如曲轴、齿轮、凸轮轴等。
CAS号:
性质:又叫奥-贝球铁。基体组织为奥氏体加贝氏体组织的球墨铸铁。这类球铁硅含量一般在1.4%~3.8%。含锰量小于0.5%,与普通球铁比较硅偏高、锰偏低。通过调节化学成分与热处理获得理想的奥-贝球铁的基体组织为针状贝氏体或无碳贝氏体一富碳奥氏体。这类球铁具有优良的综合机械性能、强度高、耐磨性好、韧性好、特别是有高的缺口韧性,可代替钢,用于制作重要受力结构件,如曲轴、齿轮、凸轮轴等。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条