[1] Skoglund P. High density PM components by high velocity compaction[C]// 2001 International Conference on Power Transmission Components. Ypsilanti: MPIE, 2001: 16-17.[2] Wang J Z, Qu X H, Yin H Q, et al. High velocity compaction of ferrous powder[J]. Powder Technology, 2008, 192(1): 131-136.[3] Yan Z, Chen F, Cai Y. High-velocity compaction of titanium powder and process characterization[J]. Powder Technology, 2011, 208(3): 596-599.[4] 李超杰, 肖志瑜, 林小为, 等. 316L不锈钢粉末高速压制行为[J]. 粉末冶金材料科学与工程, 2012, 17(3): 350-355.[5] Azhdar B, Stenberg B, Kari L. Determination of dynamic and sliding friction, and observation of stick-slip phenomenon on compacted polymer powders during high-velocity compaction[J]. Polymer Testing, 2006, 25(8):1069-1080.[6]Li H, Yin H, Khan D F, et al. High velocity compaction of 0.9Al2O3/Cu composite powder[J]. Materials & Design, 2014, 57(5):546-550.[7] Gustafsson G, Nishida M, H?ggblad H ?, et al. Experimental studies and modelling of high-velocity loaded iron-powder compacts[J]. Powder Technology, 2014, 268(1): 293-305.[8] 郑洲顺, 徐丹, 雷湘媛, 等. 粉末高速压制成形密度分布的数值模拟及影响因素分析[J]. 材料工程, 2012(7): 10-14.[9] Tanaka K, Nishida M, Kunimochi T, et al. Discrete element simulation and experiment for dynamic response of two-dimensional granular matter to the impact of a spherical projectile[J]. Powder Technology, 2002, 124(1-2):160-173.[10]Sadd M H, Tai Q, Shukla A. Contact law effects on wave propagation in particulate materials using distinct element modeling[J]. International Journal of Non-Linear Mechanics, 1993, 28(2):251-265.[11] Ransing R S, Gethin D T, Khoei A R, et al. Powder compaction modelling via the discrete and finite element method[J]. Materials & Design, 2000, 21(4):263-269.[12] Sand A, Rosenkranz J, Kuyumcu H Z. Modelling and simulation of stamp-charged coke making by 2-D discrete element method[J]. Advanced Powder Technology, 2013, 24(6):1039-1047.[13]郑洲顺, 王爽, 郑珊,等. 基于离散单元法的粉末高速压制流动过程模拟[J]. 稀有金属材料与工程, 2010, 39(12).[14] 郑洲顺, 岳书霞, 郑珊, 等. 高速压制成形金属粉末的本构关系[J]. 延边大学学报:自然科学版, 2009, 35(3):270-273.[15]迟悦, 果世驹, 孟飞, 等.粉末冶金高速压制成形技术[J] .粉末冶金工业, 2005, 15(6): 41-45 .[16]Souriou D, Goeuriot P, Bonnefoy O, et al. Influence of the formulation of an alumina powder on compaction[J]. Powder Technology, 2009, 190(1):152-159.[17] Wang J Z, Yin H Q, Qu X H, et al. Effect of multiple impacts on high velocity pressed iron powder[J]. Powder Technology, 2009, 195(3):184-189.[18] Yan Z, Chen F, Cai Y. High-velocity compaction of titanium powder and process characterization[J]. Powder Technology, 2011, 208(3):596-599.[19] Zhang H, Dong G, Zhang L, et al. Effects of annealing on high velocity compaction behavior and mechanical properties of iron-base PM alloy[J]. Powder Technology, 2015, 12(2):171-172.[21]果世驹,迟悦,孟飞,杨霞.粉末冶金高速压制成形的压制方程[J].粉末冶金材料科学与工程, 2006, 11(1):24-27.[22] 郑洲顺,朱远鹏,裴朝旭,曲选辉.高速压制成形中应力波传播的特征[J].系统仿真学报, 2009,21(2):226-229.[23] 易明军, 尹海清, 曲选辉,等. 力与应力波对高速压制压坯质量的影响[J]. 粉末冶金技术, 2009, 27(3):207-211.[24] 迟悦. 粉末冶金高速压制的研究[D]. 北京: 北京科技大学, 2006.[25] Sano T, Obinata A, Negishi H, et al. Effects of temperature rise on dynamic powder compaction[J]. Journal of Materials Processing Technology, 1997, 67(s 1–3):19–23.[26] Klinzing G R, Zavaliangos A, Cunningham J, et al. Temperature and density evolution during compaction of a capsule shaped tablet[J]. Computers & Chemical Engineering, 2010, 34(7):1082-1091.[27] 陈进. 粉末温高速压制成形装置、成形规律及其致密化机理研究[D].华南理工大学, 2011.[28]马斌斌,袁刘军,胡仙平.基于Johnson-Cook 模型对金属粉末高速压制温升影响因素的研究[J].热加工工艺, 2016, 45(1):91-95.[29] 谷成玲. 基于分形理论的高速压制粉末颗粒摩擦力分析[J]. 吉首大学学报:自然科学版, 2011, 32(4): 55-59.[30] 李俏杰, 郑洲顺, 王爽, 等. 高速压制成形粉末流动过程的格子Boltzmann方法数值模拟[J]. 中国有色金属学报, 2012, 22(6):1754-1762. |