中国有色金属学报
中國有色金屬學報
중국유색금속학보
THE CHINESE JOURNAL OF NONFERROUS METALS
2013年
11期
3107-3113
,共7页
GH4169合金%冷却速度%微观偏析%糊状区稳定性
GH4169閤金%冷卻速度%微觀偏析%糊狀區穩定性
GH4169합금%냉각속도%미관편석%호상구은정성
GH4169 alloy%cooling rate%microsegregation%mush zone stability
通过不同冷却速度下的凝固重熔试验,结合SEM微观分析及电子探针成分分析,研究GH4169合金凝固过程微观偏析的演化规律,分析凝固前沿液相区的密度变化规律,并提出基于相对Rayleigh数的凝固前沿糊状区的稳定性判据。结果表明:冷却速度低于0.05℃/s时,液相中的Nb含量随出炉温度的下降很快升高到一个较高值,在较低温度出炉冷却时,Nb含量迅速升高到14%以上,可达合金名义成分中Nb元素含量的3倍;提高冷却速度至0.1℃/s,高温出炉时,Nb含量升高很慢,当出炉温度低于1310℃时, Nb含量迅速升高到10%以上;进一步提高冷却速度,残余液相中Nb元素含量变化不大,与合金的名义成分接近。当冷却速度较高时(大于0.1℃/s), GH4169合金凝固过程凝固前沿糊状区的稳定性较好,相对Rayleigh数较低;而当冷却速度较低时,即低于0.02℃/s时,凝固前沿糊状区稳定性判据R v值比较高,而且在1330℃附近出炉冷却时,存在一个峰值区,最大峰值接近7.5×10-13。说明当凝固过程冷却速度较低时,元素的微观偏析使得GH4169合金凝固前沿糊状区的稳定性降低,可能导致微观偏析向宏观偏析转变。
通過不同冷卻速度下的凝固重鎔試驗,結閤SEM微觀分析及電子探針成分分析,研究GH4169閤金凝固過程微觀偏析的縯化規律,分析凝固前沿液相區的密度變化規律,併提齣基于相對Rayleigh數的凝固前沿糊狀區的穩定性判據。結果錶明:冷卻速度低于0.05℃/s時,液相中的Nb含量隨齣爐溫度的下降很快升高到一箇較高值,在較低溫度齣爐冷卻時,Nb含量迅速升高到14%以上,可達閤金名義成分中Nb元素含量的3倍;提高冷卻速度至0.1℃/s,高溫齣爐時,Nb含量升高很慢,噹齣爐溫度低于1310℃時, Nb含量迅速升高到10%以上;進一步提高冷卻速度,殘餘液相中Nb元素含量變化不大,與閤金的名義成分接近。噹冷卻速度較高時(大于0.1℃/s), GH4169閤金凝固過程凝固前沿糊狀區的穩定性較好,相對Rayleigh數較低;而噹冷卻速度較低時,即低于0.02℃/s時,凝固前沿糊狀區穩定性判據R v值比較高,而且在1330℃附近齣爐冷卻時,存在一箇峰值區,最大峰值接近7.5×10-13。說明噹凝固過程冷卻速度較低時,元素的微觀偏析使得GH4169閤金凝固前沿糊狀區的穩定性降低,可能導緻微觀偏析嚮宏觀偏析轉變。
통과불동냉각속도하적응고중용시험,결합SEM미관분석급전자탐침성분분석,연구GH4169합금응고과정미관편석적연화규률,분석응고전연액상구적밀도변화규률,병제출기우상대Rayleigh수적응고전연호상구적은정성판거。결과표명:냉각속도저우0.05℃/s시,액상중적Nb함량수출로온도적하강흔쾌승고도일개교고치,재교저온도출로냉각시,Nb함량신속승고도14%이상,가체합금명의성분중Nb원소함량적3배;제고냉각속도지0.1℃/s,고온출로시,Nb함량승고흔만,당출로온도저우1310℃시, Nb함량신속승고도10%이상;진일보제고냉각속도,잔여액상중Nb원소함량변화불대,여합금적명의성분접근。당냉각속도교고시(대우0.1℃/s), GH4169합금응고과정응고전연호상구적은정성교호,상대Rayleigh수교저;이당냉각속도교저시,즉저우0.02℃/s시,응고전연호상구은정성판거R v치비교고,이차재1330℃부근출로냉각시,존재일개봉치구,최대봉치접근7.5×10-13。설명당응고과정냉각속도교저시,원소적미관편석사득GH4169합금응고전연호상구적은정성강저,가능도치미관편석향굉관편석전변。
The microsegregation behaviors of GH4169 alloy during its solidification process were investigated by remelting tests, SEM and EMPA analysis. Furthermore, the density variation for the solidification front of this alloy was analyzed and a stability criterion based on relative Rayleigh number model was put forward. The results show that, when the cooling rate is lower than 0.05 ℃/s, Nb content in the residual liquid phase increases with decreasing the pouring temperature, it can reach 14%, three times of the designed Nb content for this alloy. When the cooling rate increases to 0.1 ℃/s and the pouring temperature is lower than 1 310 ℃, Nb content in the residual liquid phase reaches 10%promptly, while when the pouring temperature is higher than 1 310 ℃, Nb content in the residual liquid phase varies slowly. With the increase of cooling rate during the solidification process, Nb content in the residual liquid phase can decrease to the designed value gradually. At the same time, a heavier microsegregation of Nb element may occur at lower cooling rate in the mush zone for GH4169 during its solidifying process, resulting in the bigger relative Rayleigh number and the worse stability of mush zone, which may increase the probability of freckle formation.