Xuất bản

Sách và giáo trình

[1]	Bơm quạt cánh dẫn
[2]	Cơ học chất lỏng ứng dụng
[3]	Cở sở năng lượng mới và năng lượng tái tạo
[4]	Hệ thống lái tầu thủy
[5]	Máy nén khí
[6]	Máy thủy lực thể tích
[7]	Truyền động khí nén
[8]	Truyền động thủy động
[9]	Tua bin nước

Tạp chí Quốc tế ISI

2019

1. [21]     T.-V. Vu, T. V. Vu, and D. T. Bui, “Numerical study of deformation and breakup of a multi-core compound droplet in simple shear flow,” Int. J. Heat Mass Transfer, vol. 131, pp. 1083–1094, Mar. 2019 (IF2017 = 3.891, MECHANICS: 9 of 134, Q1).

2018

1. [20]    I. L. Ngo, H. Jang, C. Byon, and B. J. Lee, “Experimental study on thermal performance of SMD-LED chips under the effects of electric wire pattern and LED arrangement,” International Journal of Heat and Mass Transfer, vol. 127, pp. 746–757, Dec. 2018 (IF2017 = 3.891, MECHANICS: 9 of 134, Q1).
2. [19]     V. N. Duy and T. V. Vu, “A numerical study of a liquid drop solidifying on a vertical cold wall,” International Journal of Heat and Mass Transfer, vol. 127, pp. 302–312, Dec. 2018 (IF2017 = 3.891, MECHANICS: 9 of 134, Q1).
3. [18]     Ngoc T. B. Hoang, “Computational investigation of the variation in wing aerodynamic load under the effect of aeroelastic deformations,” Journal of Mechanical Science and Technology, vol. 32(10), pp. 4665–4673, Oct. 2018 (IF2017 = 1.194, ENGINEERING, MECHANICAL: 85 of 128, Q3).
4. [17]      I. L. Ngo, C. Byon, and B. J. Lee, “Analytical study on thermal conductivity enhancement of hybrid-filler polymer composites under high thermal contact resistance,” International Journal of Heat and Mass Transfer, vol. 126, pp. 474–484, Nov. 2018.
5. [16]      T. V. Vu, “Axisymmetric Forced Convection Solidification of a Liquid Drop on a Cold Plate,” Int. J. Multiphase Flow, p. in press, 2018.
6. [15]      T. V. Vu, L. V. Vu, B. D. Pham, and Q. H. Luu, “Numerical investigation of dynamic behavior of a compound drop in shear flow,” J. Mech. Sci. Technol., vol. 32, no. 5, pp. 2111–2117, May 2018.
7. [14]      T. V. Vu, K. V. Dao, and B. D. Pham, “Numerical simulation of the freezing process of a water drop attached to a cold plate,” J Mech Sci Technol, vol. 32, no. 5, pp. 2119–2126, May 2018.
8. [13]      T. V. Vu, “Fully resolved simulations of drop solidification under forced convection,” Int. J. Heat Mass Transfer, vol. 122, pp. 252–263, Jul. 2018.
9. [12]      T. V. Vu, “Deformation and breakup of a pendant drop with solidification,” Int. J. Heat Mass Transfer, vol. 122, pp. 341–353, Jul. 2018.
10. [11]      T. V. Vu, C. T. Nguyen, and D. T. Khanh, “Direct numerical study of a molten metal drop solidifying on a cold plate with different wettability,” Metals, vol. 8, no. 1, p. 47, Jan. 2018.

2017

1. [10]      V.-T. Truong and Y.-L. Hwang, “A New Approach for Dynamic Analysis and Driving Control of CNC Machine Tool,” Journal of the Chinese Society of Mechanical Engineers, vol. 38, pp. 165–171, Apr. 2017.
2. [9]        T. V. Vu, “Three-phase numerical simulations of solidification with natural convection in a vertical cylindrical annulus,” Int. J. Multiphase Flow, vol. 95, pp. 120–134, Oct. 2017.
3. [8]        T. V. Vu, “Three-phase computation of solidification in an open horizontal circular cylinder,” Int. J. Heat Mass Transfer, vol. 111, pp. 398–409, Aug. 2017.
4. [7]        T. V. Vu and J. C. Wells, “Numerical simulations of solidification around two tandemly-arranged circular cylinders under forced convection,” Int. J. Multiphase Flow, vol. 89, pp. 331–344, Mar. 2017.

2016

1. [6]        X. Tran, H. Dao, and K. Tran, “A new mathematical model of friction for pneumatic cylinders,” Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, vol. 230, no. 14, pp. 2399–2412, Aug. 2016.
2. [5]        T. Soriano, N. V. Hien, K. M. Tuan, and T. V. Anh, “An object-unified approach to develop controllers for autonomous underwater vehicles,” Mechatronics, vol. 35, pp. 54–70, May 2016.
3. [4]        T. V. Vu, A. V. Truong, N. T. B. Hoang, and D. K. Tran, “Numerical investigations of solidification around a circular cylinder under forced convection,” J. Mech. Sci. Technol., vol. 30, no. 11, pp. 5019–5028, 2016.
4. [3]        T. V. Vu, “Numerical simulation of inward solidification with volume change in cylindrical containers,” J. Chem. Eng. Jpn., vol. 49, no. 10, pp. 904–908, 2016.

2015

1. [2]        T. V. Vu, G. Tryggvason, S. Homma, and J. C. Wells, “Numerical investigations of drop solidification on a cold plate in the presence of volume change,” Int. J. Multiphase Flow, vol. 76, pp. 73–85, Nov. 2015.

2014

1. [1]        X. Tran, W. Khaing, H. Endo, and H. Yanada, “Effect of friction model on simulation of hydraulic actuator,” Proceedings of the IMechE, vol. 228, no. 9, pp. 690–698, Oct. 2014.

 

Tạp chí Quốc tế non-ISI

1. T. V. Vu, G. Tryggason, S. Homma, J. Wells, H. Takakura, Front tracking computation of trijunction solidification with volume change, Procedia IUTAM, 15, (2015), pp. 14–17.
2. M. Shintani, T. A. Viet, Y. Iga, T. Ikohagi, Investigation of Deflector Effect on Cavitation in an Axisymmetric Gate Slot by Means of AE Measurement, TRANSACTIONS OF THE JAPAN SOCIETY OF MECHANICAL ENGINEERS Series B, 77, (2011), pp. 1210–1218.