278 工程科学学报，第43卷，第2期 社，2002) (赵志刚，仇圣桃，朱荣.水冷铜模与砂模铸造M2钢显微组织对 [9]Siddique R,Singh G.Utilization of waste foundry sand (WFS)in 比.工程科学学报，2016,38(6)：787) concrete manufacturing.Resour Conserv Recycl,2011,55(11): [21]Xie Z X,Xiang Q C,Mao P L,et al.Comparison and analysis of 885 the springback for twotypes of high compacted sand molds. [10]Sun S H,Koizumi Y,Kurosu S,et al.Build direction dependence Fo1d,2004,53(9):705 of microstructure and high-temperature tensile property of Co-Cr- (谢祖锡，向青春，毛萍莉，等.两种高紧实度砂型回弹的检测与 Mo alloy fabricated by electron beam melting.Acta Mater,2014, 分析.铸造，2004,53(9)：705) 64:154 [22]Peyre P,Rouchausse Y,Defauchy D,et al.Experimental and [11]Snelling D,Li Q,Meisel N,et al.Lightweight metal cellular numerical analysis of the selective laser sintering (SLS)of PA12 structures fabricated via 3D printing of sand cast molds.Adv Eng and PEKK semi-crystalline polymers.J Mater Process Technol, Mater,2015,17(7):923 2015,225:326 [12]Vandenbroucke B,Kruth J P.Selective laser melting of [23]Liu L M,Shan Z D,Liu F.FEM analysis and optimization on biocompatible metals for rapid manufacturing of medical parts casting process for large aluminum castings.Foundry Technol, Rapid Proto0p.J,2007,13(4):196 2012,33(8):978 [13]Zocca A,Gomes C M,Bernardo E,et al.LAS glass-ceramic (刘丽敏，单忠德，刘丰.大型铸铝件铸造工艺有限元分析与优 scaffolds by three-dimensional printing.J Eur Ceram Soc,2013, 化.铸造技术，2012,33(8)：978) 33(9):1525 [24]Cheng R,Wu X Y,Zheng J P.The optimization design study of [14]Butscher A,Bohner M,Roth C,et al.Printability of calcium selective laser sintering process parameters on the pro-coated sand phosphate powders for three-dimensional printing of tissue mold.Appl Mech Mater,2011,55-57:853 engineering scaffolds.Acta Biomater,2012,8(1):373 [25]Senthilkumaran K,Pandey P M,Rao P V M.Influence of building [15]Almaghariz E S,Conner B P,Lenner L,et al.Quantifying the role strategies on the accuracy of parts in selective laser sintering. of part design complexity in using 3D sand printing for molds and Mater Des,2009,30(8):2946 cores.Int/Metalcast,2016,10(3):240 [26]Bemnard S A,Balla V K,Bose S,et al.Direct laser processing of [16]Li E Q,Xu Q,Sun J,et al.Design and fabrication of a PET/PTFE- bulk lead zirconate titanate ceramics.Mater Sci Eng B,2010, based piezoelectric squeeze mode drop-on-demand inkjet printhead with interchangeable nozzle.Sens Actuators A,2010, 172(1):85 163(1):315 [27]Zhu Y,Ji D S,Bo W.Composition and preparation of surface [17]Dobosz S M,Grabarczyk A.Major-Gabrys K.et al.Influence of stabilizer for green sang mold.Foundry Eng,2009,33(3):5 quartz sand quality on bending strength and thermal deformation (朱筠，季敦生，卜伟.黏土湿型表面稳定剂的组成及制备工艺 of moulding sands with synthetic binders.Arch Foundry Eng 铸造工程，2009,33(3)：5) 2015,15(2):9 [28]Li H,Du J H,Wang H X,et al.Effect of molding process on [18]Dong X L,Li X Y,Shan Z D,et al.Rapid manufacturing of sand tribological characteristics of friction materials based on resin. molds by direct milling.Tsinghua Sci Technol,2009,14(Suppl 1): Chin J Eng,2017,39(8):1182 212 (李辉，杜建华，王浩旭，等.成型工艺对树脂基摩擦材料及其摩 [19]Ayoola W A,Adeosun S O,Sanni O S,et al.Effect of casting 擦学性能的影响.工程科学学报，2017,39(8)：1182) mould on mechanical properties of 6063 aluminum alloy.J Eng [29]Sun Q C,Jin F,Wang G Q,et al.Force chains in a uniaxially Sci Technol,2012,7(1):89 compressed static granular matter in 2D.Acta Phys Sin,2010. [20]Zhao Z G,Qiu S T,Zhu R.Comparison between the 59(1):30 microstructures of M2 steel cast by the water-cooled copper mould (孙其诚，金峰，王光谦，等.二维颗粒体系单轴压缩形成的力链 and the sand mould.Chin J Eng,2016,38(6):787 结构.物理学报，2010,59(1)：30)社, 2002） Siddique R, Singh G. Utilization of waste foundry sand (WFS) in concrete manufacturing. Resour Conserv Recycl, 2011, 55（11）: 885 [9] Sun S H, Koizumi Y, Kurosu S, et al. Build direction dependence of microstructure and high-temperature tensile property of Co-Cr￾Mo alloy fabricated by electron beam melting. Acta Mater, 2014, 64: 154 [10] Snelling D, Li Q, Meisel N, et al. Lightweight metal cellular structures fabricated via 3D printing of sand cast molds. Adv Eng Mater, 2015, 17（7）: 923 [11] Vandenbroucke B, Kruth J P. Selective laser melting of biocompatible metals for rapid manufacturing of medical parts. Rapid Prototyp J, 2007, 13（4）: 196 [12] Zocca A, Gomes C M, Bernardo E, et al. LAS glass –ceramic scaffolds by three-dimensional printing. J Eur Ceram Soc, 2013, 33（9）: 1525 [13] Butscher A, Bohner M, Roth C, et al. Printability of calcium phosphate powders for three-dimensional printing of tissue engineering scaffolds. Acta Biomater, 2012, 8（1）: 373 [14] Almaghariz E S, Conner B P, Lenner L, et al. Quantifying the role of part design complexity in using 3D sand printing for molds and cores. Int J Metalcast, 2016, 10（3）: 240 [15] Li E Q, Xu Q, Sun J, et al. Design and fabrication of a PET/PTFE￾based piezoelectric squeeze mode drop-on-demand inkjet printhead with interchangeable nozzle. Sens Actuators A, 2010, 163（1）: 315 [16] Dobosz S M, Grabarczyk A, Major-Gabryś K, et al. Influence of quartz sand quality on bending strength and thermal deformation of moulding sands with synthetic binders. Arch Foundry Eng, 2015, 15（2）: 9 [17] Dong X L, Li X Y, Shan Z D, et al. Rapid manufacturing of sand molds by direct milling. Tsinghua Sci Technol, 2009, 14（Suppl 1）: 212 [18] Ayoola W A, Adeosun S O, Sanni O S, et al. Effect of casting mould on mechanical properties of 6063 aluminum alloy. J Eng Sci Technol, 2012, 7（1）: 89 [19] Zhao Z G, Qiu S T, Zhu R. Comparison between the microstructures of M2 steel cast by the water-cooled copper mould and the sand mould. Chin J Eng, 2016, 38（6）: 787 [20] （赵志刚, 仇圣桃, 朱荣. 水冷铜模与砂模铸造 M2 钢显微组织对 比. 工程科学学报, 2016, 38（6）：787） Xie Z X, Xiang Q C, Mao P L, et al. Comparison and analysis of the springback for twotypes of high compacted sand molds. Foundry, 2004, 53（9）: 705 （谢祖锡, 向青春, 毛萍莉, 等. 两种高紧实度砂型回弹的检测与 分析. 铸造, 2004, 53（9）：705） [21] Peyre P, Rouchausse Y, Defauchy D, et al. Experimental and numerical analysis of the selective laser sintering (SLS) of PA12 and PEKK semi-crystalline polymers. J Mater Process Technol, 2015, 225: 326 [22] Liu L M, Shan Z D, Liu F. FEM analysis and optimization on casting process for large aluminum castings. Foundry Technol, 2012, 33（8）: 978 （刘丽敏, 单忠德, 刘丰. 大型铸铝件铸造工艺有限元分析与优 化. 铸造技术, 2012, 33（8）：978） [23] Cheng R, Wu X Y, Zheng J P. The optimization design study of selective laser sintering process parameters on the pro-coated sand mold. Appl Mech Mater, 2011, 55-57: 853 [24] Senthilkumaran K, Pandey P M, Rao P V M. Influence of building strategies on the accuracy of parts in selective laser sintering. Mater Des, 2009, 30（8）: 2946 [25] Bernard S A, Balla V K, Bose S, et al. Direct laser processing of bulk lead zirconate titanate ceramics. Mater Sci Eng B, 2010, 172（1）: 85 [26] Zhu Y, Ji D S, Bo W. Composition and preparation of surface stabilizer for green sang mold. Foundry Eng, 2009, 33（3）: 5 （朱筠, 季敦生, 卜伟. 黏土湿型表面稳定剂的组成及制备工艺. 铸造工程, 2009, 33（3）：5） [27] Li H, Du J H, Wang H X, et al. Effect of molding process on tribological characteristics of friction materials based on resin. Chin J Eng, 2017, 39（8）: 1182 （李辉, 杜建华, 王浩旭, 等. 成型工艺对树脂基摩擦材料及其摩 擦学性能的影响. 工程科学学报, 2017, 39（8）：1182） [28] Sun Q C, Jin F, Wang G Q, et al. Force chains in a uniaxially compressed static granular matter in 2D. Acta Phys Sin, 2010, 59（1）: 30 （孙其诚, 金峰, 王光谦, 等. 二维颗粒体系单轴压缩形成的力链 结构. 物理学报, 2010, 59（1）：30） [29] · 278 · 工程科学学报，第 43 卷，第 2 期