粉末冶金材料科学与工程
粉末冶金材料科學與工程
분말야금재료과학여공정
POWDER METALLURGY MATERIALS SCIENCE AND ENGINEERING
2013年
6期
789-795
,共7页
316L不锈钢%复合材料%高温氧化
316L不鏽鋼%複閤材料%高溫氧化
316L불수강%복합재료%고온양화
316L stainless steel%composites%high temperature oxidation
采用粉末冶金法制备TiC/316L不锈钢复合材料(TiC质量分数为10%),研究该复合材料在700~900℃空气中的恒温氧化行为,分析氧化温度和氧化时间对其氧化行为的影响,并对氧化膜表面的相组成、形貌以及氧化机制进行分析。结果表明:在700~900℃氧化条件下,TiC/316L不锈钢复合材料表面形成的氧化膜以TiO2、Cr2O3、Fe3O4和FeCr2O4为主要组成相,且随氧化时间的延长,TiO2和FeCr2O4的衍射峰逐渐变强,试样在900℃氧化时,氧化膜中的Fe3O4会进一步与O2反应生成Fe2O3。温度从700℃升高至900℃,氧化膜表面铁的氧化物由细条状变为片状,继而发展成短柱状;而Ti的氧化物由大块结状发展成颗粒状,并且颗粒的尺寸随温度的升高而增大。
採用粉末冶金法製備TiC/316L不鏽鋼複閤材料(TiC質量分數為10%),研究該複閤材料在700~900℃空氣中的恆溫氧化行為,分析氧化溫度和氧化時間對其氧化行為的影響,併對氧化膜錶麵的相組成、形貌以及氧化機製進行分析。結果錶明:在700~900℃氧化條件下,TiC/316L不鏽鋼複閤材料錶麵形成的氧化膜以TiO2、Cr2O3、Fe3O4和FeCr2O4為主要組成相,且隨氧化時間的延長,TiO2和FeCr2O4的衍射峰逐漸變彊,試樣在900℃氧化時,氧化膜中的Fe3O4會進一步與O2反應生成Fe2O3。溫度從700℃升高至900℃,氧化膜錶麵鐵的氧化物由細條狀變為片狀,繼而髮展成短柱狀;而Ti的氧化物由大塊結狀髮展成顆粒狀,併且顆粒的呎吋隨溫度的升高而增大。
채용분말야금법제비TiC/316L불수강복합재료(TiC질량분수위10%),연구해복합재료재700~900℃공기중적항온양화행위,분석양화온도화양화시간대기양화행위적영향,병대양화막표면적상조성、형모이급양화궤제진행분석。결과표명:재700~900℃양화조건하,TiC/316L불수강복합재료표면형성적양화막이TiO2、Cr2O3、Fe3O4화FeCr2O4위주요조성상,차수양화시간적연장,TiO2화FeCr2O4적연사봉축점변강,시양재900℃양화시,양화막중적Fe3O4회진일보여O2반응생성Fe2O3。온도종700℃승고지900℃,양화막표면철적양화물유세조상변위편상,계이발전성단주상;이Ti적양화물유대괴결상발전성과립상,병차과립적척촌수온도적승고이증대。
Powder metallurgic method was used to prepare TiC/316L stainless steel composite (TiC mass fraction is 10%) and the high temperature oxidation behavior of the TiC/316L composite at 700~900 ℃ in air was investigated. The effects of oxidizing temperature and time on the oxidation behavior of the TiC/316L composite were studied, and the reaction products in the oxidation layer as well as the surface morphology of oxidation layer were analyzed. The results show that an oxidation film mainly consisting of TiO2, Cr2O3, Fe3O4 and FeCr2O4 has formed at 700~900 ℃, and the intensities of TiO2 and FeCr2O4 diffraction peaks increase gradually with increasing oxidation time;at 900℃in air, Fe3O4 reacts with O2 to form Fe2O3. From 700 ℃ to 900 ℃, the surface morphology of iron oxide in the oxidation film developes from thin strips, gradually to sheets, and finally forms short columns, while the shape of Ti oxide changed from large knot-shaped to grainy, and the size of particles increases with increasing oxidizing temperature.