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
3期
363-367
,共5页
杨剑%郭志猛%杨薇薇%罗骥%郭烽%吴成义
楊劍%郭誌猛%楊薇薇%囉驥%郭烽%吳成義
양검%곽지맹%양미미%라기%곽봉%오성의
SPS%收缩动力学曲线%9Cr-ODS%等轴铁素体钢
SPS%收縮動力學麯線%9Cr-ODS%等軸鐵素體鋼
SPS%수축동역학곡선%9Cr-ODS%등축철소체강
SPS%shrinkage kinetic curves%9Cr-ODS%equiaxed ferritic steels
以 N2气雾化的9CrW铁基合金粉末和纳米 Y2O3粉末为原料,采用放电等离子烧结(SPS)工艺制备9Cr-ODS钢。通过 SPS 温度和位移测量单元研究烧结压力、升温速率和 Y2O3含量对烧结过程中9Cr-ODS 钢烧结收缩动力学曲线的影响,并对其显微组织和力学性能进行观察和测试。结果表明,增加烧结压力能够使9CrW 铁基合金粉末在较低的温度下完成烧结收缩过程。升温速率增大时,收缩曲线向高温区移动,剧烈收缩温度、最大收缩速率和密度均有所提高。Y2O3的加入可阻碍收缩致密化过程,导致曲线的最大收缩速率降低,并且力学性能测试结果表明 Y2O3的加入可提高材料的拉伸性能,通过添加质量分数为0.35%的 Y2O3可使得材料的抗拉强度和屈服强度分别提高到1653 MPa 和1405 MPa。
以 N2氣霧化的9CrW鐵基閤金粉末和納米 Y2O3粉末為原料,採用放電等離子燒結(SPS)工藝製備9Cr-ODS鋼。通過 SPS 溫度和位移測量單元研究燒結壓力、升溫速率和 Y2O3含量對燒結過程中9Cr-ODS 鋼燒結收縮動力學麯線的影響,併對其顯微組織和力學性能進行觀察和測試。結果錶明,增加燒結壓力能夠使9CrW 鐵基閤金粉末在較低的溫度下完成燒結收縮過程。升溫速率增大時,收縮麯線嚮高溫區移動,劇烈收縮溫度、最大收縮速率和密度均有所提高。Y2O3的加入可阻礙收縮緻密化過程,導緻麯線的最大收縮速率降低,併且力學性能測試結果錶明 Y2O3的加入可提高材料的拉伸性能,通過添加質量分數為0.35%的 Y2O3可使得材料的抗拉彊度和屈服彊度分彆提高到1653 MPa 和1405 MPa。
이 N2기무화적9CrW철기합금분말화납미 Y2O3분말위원료,채용방전등리자소결(SPS)공예제비9Cr-ODS강。통과 SPS 온도화위이측량단원연구소결압력、승온속솔화 Y2O3함량대소결과정중9Cr-ODS 강소결수축동역학곡선적영향,병대기현미조직화역학성능진행관찰화측시。결과표명,증가소결압력능구사9CrW 철기합금분말재교저적온도하완성소결수축과정。승온속솔증대시,수축곡선향고온구이동,극렬수축온도、최대수축속솔화밀도균유소제고。Y2O3적가입가조애수축치밀화과정,도치곡선적최대수축속솔강저,병차역학성능측시결과표명 Y2O3적가입가제고재료적랍신성능,통과첨가질량분수위0.35%적 Y2O3가사득재료적항랍강도화굴복강도분별제고도1653 MPa 화1405 MPa。
9Cr oxide-dispersion-strengthened (ODS) steels were prepared by the 9CrW iron-based powders atomized in nitrogen gas with nanometer Y2O3 powders consolidated by spark plasma sintering (SPS). Effects of sintering pressure, heating rate and Y2O3 content on the shrinkage kinetic curves were investigated by SPS temperature and displace measurement; moreover, microstructure and mechanical properties of 9Cr-ODS steels were also characterized and measured. The results show that the shrinkage densification of 9CrW iron-based alloyed powders can complete at low temperature with increasing sintering pressure. Increasing heating rate, the shrinkage curves translate to high temperature region; in addition, the sharp shrinkage temperature, maximum shrinkage rate and density increase. Shrinkage densification is hindered by adding Y2O3 powders, which makes the maximum shrinkage rate decrease. Electronic tensile test shows that tensile properties can be improved by adding Y2O3. The ultimate tensile strength and yield strength increase to 1 653 MPa and 1 405 MPa when adding 0.35% (mass fraction) Y2O3.
