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Online since: January 2012
Authors: James C. Williams, Dipankar Banerjee, Adam L. Pilchak
The Cast Structure
A typical phase diagram associated with engineering titanium alloys is shown in Figure 1 along with a broad alloy classification.
Lath Figure 12: a) starting lamellar structure of IMI834 alloy deformed at 950C,10-2s-1 to a strain of 0.4 b) starting lamellar structure of IMI834 alloy deformed at 1000C,10-3s-1 to a strain of 0.4 [44].
References 1.
Gogia, Microstructure and texture of rolled and annealed b titanium alloy Ti–10V–4.5Fe–1.5Al, Mater.
Raabe, Texture inhomogeneity in a Ti–Nb-based b-titanium alloy after warm rolling and recrystallization, Materials Science and Engineering A 479 (2008) 236–247. 17.
Lath Figure 12: a) starting lamellar structure of IMI834 alloy deformed at 950C,10-2s-1 to a strain of 0.4 b) starting lamellar structure of IMI834 alloy deformed at 1000C,10-3s-1 to a strain of 0.4 [44].
References 1.
Gogia, Microstructure and texture of rolled and annealed b titanium alloy Ti–10V–4.5Fe–1.5Al, Mater.
Raabe, Texture inhomogeneity in a Ti–Nb-based b-titanium alloy after warm rolling and recrystallization, Materials Science and Engineering A 479 (2008) 236–247. 17.
Online since: June 2025
Authors: B. Ratna Sunil, Yerra Narendra Babu, Seelam Krugon, P. Umamaheswarrao, D. Vijay Praveen
Table 1.
Fig. 1.
Sci., 1(9), 977
Silicon, 1-9
In 2021 IEEE 8th International Workshop on Metrology for AeroSpace (MetroAeroSpace) (pp. 479-484).
Fig. 1.
Sci., 1(9), 977
Silicon, 1-9
In 2021 IEEE 8th International Workshop on Metrology for AeroSpace (MetroAeroSpace) (pp. 479-484).
Online since: July 2022
Authors: Michael F. Zaeh, Thomas Merk, Avelino Zapata, Christian Bernauer
The experimental setup is depicted in Figure 1.
References [1] A.
Eng. 34 (2021) 1
Schulz, Additive Manufacturing of H11 with Wire-Based Laser Metal Deposition, Soldagem & Inspeção 22 (2017) 4, pp. 466–479
Eng. 59 (2020) 07, pp. 1
References [1] A.
Eng. 34 (2021) 1
Schulz, Additive Manufacturing of H11 with Wire-Based Laser Metal Deposition, Soldagem & Inspeção 22 (2017) 4, pp. 466–479
Eng. 59 (2020) 07, pp. 1
Online since: December 2014
Authors: Jatinder Kumar, Ravinder Kataria
Table: 1 Properties of different compositions of cemented carbide [7, 15].
Author Work Material Input parameters and range Optimized Results 1.
Jangra et al. [31] WC-6%Co Taper angle (3-1.3 degree) Peak current (80-120A) Pulse on time (108-122µs) Pulse off time (30-50µs) Wire tension (6-10N) Dielectric flow rate (4-10LM-1) MRR: 2.52 mm/min.
References [1] R.M.
Tomadi, Surface integrity study in WEDM of tungsten carbide, Solid State Science and Technology, 16 (1) (2008), 1-11
Author Work Material Input parameters and range Optimized Results 1.
Jangra et al. [31] WC-6%Co Taper angle (3-1.3 degree) Peak current (80-120A) Pulse on time (108-122µs) Pulse off time (30-50µs) Wire tension (6-10N) Dielectric flow rate (4-10LM-1) MRR: 2.52 mm/min.
References [1] R.M.
Tomadi, Surface integrity study in WEDM of tungsten carbide, Solid State Science and Technology, 16 (1) (2008), 1-11
Online since: December 2024
Authors: Ángel de Jesús Morales-Ramírez, Ruben Cuamatzi-Melendez, Fernando Juárez-López, Enrique Flores-Cuamatzi
Fig. 1.
Table 1.
References [1] V.M.
Johnsen, Materials and corrosion trends in offshore and subsea oil and gas production, Materials Degradation 1 (2017) 1-11
Carrera-Jota, Microstructural evolution and densification of Co-based alloy powder by spark plasma sintering for high-hardness applications, Coatings 14 4 (2024) 479
Table 1.
References [1] V.M.
Johnsen, Materials and corrosion trends in offshore and subsea oil and gas production, Materials Degradation 1 (2017) 1-11
Carrera-Jota, Microstructural evolution and densification of Co-based alloy powder by spark plasma sintering for high-hardness applications, Coatings 14 4 (2024) 479
Online since: January 2009
Authors: Jun Wang
Table 4 Velocity combinations used in experiment
Combinations Traverse speed u (mm/s)
Pass 1 Pass 2 Pass 3
1 1
2 1 1
3 1 2
4 1 2 2
5 2
6 2 2
7 2 2 2
8 3
Depths of Cut in Multipass Operations.
Sd (mm) 4 4 4 Traverse speed u (mm/s) 1 1 2 (2 equal passes) Oscillation angle θ (degrees) - 6 6 Oscillation frequency F (Hz) - 9 9 Total depth of cut h (mm) 14.56 18.22 24.32 Increase in total depth of cut (%) - 25.1% 67.0% Table 5 shows some typical depths of cut produced by different cutting modes under the corresponding process conditions and with the same total cutting time.
Water Jet Technol., Vol. 1 (1991), pp. 65-71
Tools Manufact., Vol. 37 (1997), pp. 465-479
C1-1/C1-13
Sd (mm) 4 4 4 Traverse speed u (mm/s) 1 1 2 (2 equal passes) Oscillation angle θ (degrees) - 6 6 Oscillation frequency F (Hz) - 9 9 Total depth of cut h (mm) 14.56 18.22 24.32 Increase in total depth of cut (%) - 25.1% 67.0% Table 5 shows some typical depths of cut produced by different cutting modes under the corresponding process conditions and with the same total cutting time.
Water Jet Technol., Vol. 1 (1991), pp. 65-71
Tools Manufact., Vol. 37 (1997), pp. 465-479
C1-1/C1-13
Online since: June 2013
Authors: Guo Hua Chen, Qing Guang Chen, Wei Li Duan, Qing Ye
Reference
[1] Yumei Yang, Jiaxiang Chen, Qinghua Zhu.
Anim. 2003, 31(1): 7-20
[16] Saaty T L:International Journal of Services Sciences. 2008, 1(1): 83-98
[17] Guohua Chen, Tao Liang, Huawen Zhang: Safety Science, 2009, 47(1): 50-58
[24] Kalogirou S A, Bojic M: Energy. 2000, 25(5): 479-491
Anim. 2003, 31(1): 7-20
[16] Saaty T L:International Journal of Services Sciences. 2008, 1(1): 83-98
[17] Guohua Chen, Tao Liang, Huawen Zhang: Safety Science, 2009, 47(1): 50-58
[24] Kalogirou S A, Bojic M: Energy. 2000, 25(5): 479-491
Online since: January 2025
Authors: Abhishek Abhishek, Priyanka Shandil, R.K. Sharma
Table 1.
Table 1 shows the characteristics of CDW.
Fig. 1.
Environmental Earth Sciences, 75, 1-11
Scientific Reports, 14(1), 671
Table 1 shows the characteristics of CDW.
Fig. 1.
Environmental Earth Sciences, 75, 1-11
Scientific Reports, 14(1), 671
Online since: April 2021
Authors: Ashwin Kumar Devaraj, Kiran Kumar V Acharya, Raviraja Adhikari
Fig. 1.
Table 1.
References [1] A.
Dis., vol.70,no.1, pp. 74–79 ,January 1, 2011
Surg., vol.96,no.6, pp. 471–479 ,2014
Table 1.
References [1] A.
Dis., vol.70,no.1, pp. 74–79 ,January 1, 2011
Surg., vol.96,no.6, pp. 471–479 ,2014
Online since: June 2010
Authors: Julian R. Jones, Peter D. Lee
Fig. 1.
References 1.
Biotechnol. 65, 1-8 (2004). 4.
Solids 318, 1-13 (2003). 24.
Polak, Tissue Eng. 11, 479-488 (2005). 33.
References 1.
Biotechnol. 65, 1-8 (2004). 4.
Solids 318, 1-13 (2003). 24.
Polak, Tissue Eng. 11, 479-488 (2005). 33.