|
[1] 王思凱,2010年,“中碳鋼 S45C 感應熱處理製程之研究”,國立台北科技大學 材料科學與工程研究所碩士學位論文。 [2] 陳詠任,2022年,“以高週波進行中碳鋼熱處理操作參數分析”,國立中興大 學機械工程學系研究所碩士學位論文。 [3] 鄭鐵樹,呂理得,劉如真,林宜永,2012年,“中碳鋼軸件經過高週波熱處理 後之拉伸破壞特性之研究”,黎明學報,23卷,1期,頁161~167,1月。 [4] 林國維,2020年,“高周波表面感應硬化與前熱處理對 AISI 1045與 AISI 5140鋼料之影響”,國立虎尾科技大學材料科學與工程系材料 科學與綠色 能源工程碩士班碩士學位論文。 [5] 張易中,2022年,“高周波表面感應硬化與前熱處理對 AISI 6140與 AISI 5140 鋼料表面硬化特性之影響”,國立虎尾科技大學材料科學與工程系材料科學與 綠色能源工程碩士班碩士學位論文。 [6] Abbasi,E.,Luo,Q.,Owens,D.,2018,“A Comparison of Microstructure and Mechanical Properties of Low-Alloy-Medium-Carbon Steels after Quench-hardening”,Materials Science and Engineering,A 725,pp.65-75. [7] Ismail, R., Prasetyo, D. I., Tauviqirrahman, M., Yohana, E., Bayuseno, A.P. 2014. ''Induction hardening of carbon steel material: the effect of specimen diameter''. Advanced Materials Research ,Vol. 911, pp. 210-214,March. [8] Choi,J., Lee,S., 2020,''High-frequency heat treatment of AISI 1045 specimens and current calculations of the induction heating coil using metal phase transformation simulations'', Metals, 10(11), 1484. [9] Parthasarathi,V.,2014,''Study of fatigue properties, residual stresses and fine microstructural features of induction and furnace tempered barsteels'',Doctoral dissertation, Colorado School of Mines. [10] Ismail,N.M.,Khatif,N.A.A.,Kecik,M.A.K.A.,Shaharudin,M.A.H.2016,''The effect of heat treatment on the hardness and impact properties of medium carbon steel''.In IOP conference series: materials science and engineering,Vol. 114, No. 1,p. 012108. IOP Publishing,February. [11] Yuan, J., Kang, J., Rong, Y., & Sisson, R. D. ,2003, "FEM modeling of induction hardening processes in steel." Journal of materials engineering and performance ,12,pp. 589-596. [12] Totik, Y., Sadeler, R., Altun, H., & Gavgali, M. 2003. ''The effects of induction hardening on wear properties of AISI 4140 steel in dry sliding conditions''. Materials & Design, 24(1), pp.25-30. [13] 朱興元等編著,2006,金屬學與熱處理,中國林業出版社,北京大學出版社, 中國北京。 [14] 郝建民、王利捷,2003,機械工程材料,西北工業大學出版社,中國西安。 [15] 黃振賢,2004,金屬熱處理,新文京開發出版,台灣新北。 [16] JIS G 3507-2: 冷間圧造用炭素鋼−第2部:線(Carbon steels for cold heading -- Part 2: Wires)。 [17] JB/T 5074-2007 低、中碳鋼球化體評級。 [18] ASTM A892-88 Standard Guide for Defining and Rating the Microstructure of High Carbon Bearing Steels. [19] Bay.F,Labbe.V,Favennec.Y,Chenot.J.L, 2003, “A numerical model for induction heating processes coupling electromagnetism and thermomechanics”, International Journal for Numerical Methods in Engineering, Vol.58, pp. 839~841. [20] Totten.G.E, 2007, “Steel Heat Treatment Equipment and Process Design” in Steel Heat Treatment Handbook 2rd, CRC Press, London,pp. 304~308. [21] Zeng.Z.W,Ding.P.C,Li.J.Y, etal., 2019, “Characteristics of Eddy Current Attenuation and Thickness Measurement of Metallic Plate”,Chinese Journal of Mechanical Engineering, Vol. 32, pp. 1~9. [22] Curtis.F.W, 1987, “Heat contribution from eddy currents and hysteresis losses below the Curie temperature as a function of frequency”, Lindsay Publications Inc., Illinois. [23] ISO 6507-1, 2018 Metallic materials - Vickers hardness test Part 1: Test method. [24] JIS G0559:2019 Steel-Determination of case depth after flame hardening or induction hardening. [25] Hassell.P.A and Ross.N.V, 1991, “Introduction to Surface Hardening of Steels” in ASM Handbook Vol. 4 Heat Treating Edited by ASM International Handbook Committee,Materials Park, OH: ASM International, pp. 442~446.
|