[1] 陈杰,王渠东,彭涛,等. 有色金属固态回收技术的研究进展[J]. 材料导报,2009,23(11):77-80. CHEN Jie,WANG Qudong,PENG Tao,et al. Research progress of solid-state recycling for non-ferrous metal alloys[J]. Materials Review,2009,23(11):77-80.
[2] KUBOTA M,WATANABE R. Properties of upgradable recycled Al-Mg-Si alloys fabricated from machined chips via mechanical milling and spark plasma sintering[J]. Journal of Japan Institute of Light Metals,2014,64:37-41.
[3] LELA B,KROLO J,JOZIC S. Mathematical modeling of solid-state recycling of aluminum chips[J]. International Journal of Advanced Manufacturing Technology,2016,87(1-4):1-9.
[4] 万兵兵,陈维平,刘健,等. 废铝屑回收利用技术进展[J]. 特种铸造及有色合金,2015(5):477-481. WAN Bingbing,CHEN Weiping,LIU Jian,et al. Technical progress in the recycling of aluminum and its alloys scrap chips[J]. Special Casting & Nonferrous Alloys,2015(5):477-481.
[5] BEHRENS B A,FRISCHKORN C,BONHAGE M. Reprocessing of AW2007,AW6082 and AW7075 aluminium chips by using sintering and forging operations[J]. Production Engineering,2014,8(4):443-451.
[6] HU Maoliang,JI Zesheng,CHEN Xiaoyu,et al. Solid-state recycling of AZ91D magnesium alloy chips[J]. Transactions of Nonferrous Metals Society of China,2012,22(10):68-73.
[7] AFSHARI E,GHAMBARI M. Characterization of pre-alloyed tin bronze powder prepared by recycling machining chips using jet milling[J]. Materials & Design,2016,103:201-208.
[8] SHI Q,TSE Y Y,HIGGINSON R L. Effects of processing parameters on relative density,microhardness and microstructure of recycled Ti-6Al-4V from machining chips produced by equal channel angular pressing[J]. Materials Science & Engineering A,2016,651:248-258.
[9] LIU Ying,LI Yuanyuan. Microstructure and properties of AZ80 magnesium alloy prepared by hot extrusion from recycled machined chips[J]. Transactions of Nonferrous Metals Society of China,2002,12(5):882-885.
[10] 黄宗经. 金属切屑回收再利用的研究与应用现状探讨[J]. 机械设计与制造,2015(12):269-272. HUANG Zongjing. Investigation and analysis on the application status of recycling and reutilization of metal cutting chips[J]. Machinery Design & Manufacture,2015(12):269-272.
[11] MOLOODI A,RAISZADEH R. Fabricating Al foam from turning scraps[J]. Materials & Manufacturing Processes,2011,26(7):890-896.
[12] ALWAELI M,NADZIAKIEWICZ J. Recycling of scale and steel chips waste as a partial replacement of sand in concrete[J]. Construction & Building Materials,2012,28(1):157-163.
[13] OMOREGIE A. Optimum compressive strength of hardened sandcrete building blocks with steel chips[J]. Buildings,2013,3(1):205-219.
[14] BERGLES A E. ExHFT for fourth generation heat transfer technology[J]. Experimental Thermal & Fluid Science,2002,26(2-4):335-344.
[15] DE CHIFFRE L. Extusion-cutting[J]. International Journal of Machine Tool Design and Research,1976,16(2):137-144.
[16] DE CHIFFRE L. Extrusion cutting of brass strips[J]. International Journal of Machine Tool Design and Research,1983,23(2):141-151.
[17] MOSCOSO W,SHANKAR M R,MANN J B,et al. Bulk nanostructured materials by large strain extrusion machining[J]. Journal of Materials Research,2007,22(1):201-205.
[18] SAGAPURAM D,KUSTAS A B,COMPTON W D,et al. Direct single-stage processing of lightweight alloys into sheet by hybrid cutting-extrusion[J]. Journal of Manufacturing Science & Engineering,2015,137(5).
[19] DENG Wenjun,LIN Ping,XIE Zichun,et al. Analysis of large-strain extrusion machining with different chip compression ratios[J]. Journal of Nanomaterials,2012,2012(11):5271-5282.
[20] DENG Wenjun,HE Yongtai,LIN Ping,et al. Investigation of the effect of rake angle on large strain extrusion machining[J]. Materials & Manufacturing Processes,2014,29(5):621-626.
[21] JOHNSON G R,COOK W H. A constitutive model and data for metals subjected to large strains,high strain rates and high temperatures[C]//Proceedings of the 7th International Symposium on Ballistics,1983,21:541-547.
[22] GUO Zhiyong,TIAN Yanling,LIU L,et al. Modeling and simulation of the probe tip based nanochannel scratching[J]. Precision Engineering,2017,49:136-145
[23] ZHAO Hongwei,LIU Chuang,CUI Tao,et al. Influences of sequential cuts on micro-cutting process studied by smooth particle hydrodynamic (SPH)[J]. Applied Surface Science,2013,284(11):366-371.
[24] ZHANG Bao,SHIM V P W. Determination of inelastic heat fraction of OFHC copper through dynamic compression[J]. International Journal of Impact Engineering,2010,37(1):50-68.
[25] SARTKULVANICH P,SAHLAN H,ALTAN T. A finite element analysis of burr formation in face milling of a cast aluminum alloy[J]. Machining Science & Technology,2007,11(2):157-181. |