Effect of impact force for dual-hose dry blasting nozzle geometry for various pressure and distance: an experimental work
Tóm tắt
Dry ice blasting plays an essential role in today’s cleaning industry, where many industry players have used it after realizing its advantages. The disadvantage of dry ice blasting is relatively small kinetic energy and offer less aggressive clean effect, especially for dual-hose nozzle geometry. This project was mainly to study the impact force of nozzle geometry of dry ice blasting concerning pressure and distance variation. The nozzle geometries with optimum size and shape are fabricated based on a recent literature study. The experimental research on the effect of the impact forces on different pressures and distances has been conducted to validate the simulation study. The result shows that the optimum nozzle design gives better performance than a based model. Besides, the optimum distance for dry ice blasting operation is less than 400 mm for the pressure range of 2 bars to 4 bars. This distance gives the maximum value of the impacted force for dry ice blasting operation in the industry.
Tài liệu tham khảo
V. Máša, P. Kuba, J. Clean. Prod. 111, 76 (2016)
A.K. Witte et al., LWT 75, 735 (2017)
H.J. Cho et al., Nat. Rev. Mater. 2, 1 (2016)
Q. Blochet et al., J. Therm. Spray Technol. 26, 671 (2017)
M. Ansarizadeh et al., Oilfield Rev. 27, 36 (2015)
X. Guo et al., Appl. Energy 183, 1279 (2016)
R. Sherman, Developments in Surface Contamination and Cleaning (Elsevier, Amsterdam, 2016), p. 695
R. Kohli, Developments in Surface Contamination and Cleaning: Applications of Cleaning Techniques (Elsevier, New York, 2019), p. 117
O.P. Morris, Applications of emerging optoelectronic materials: lead sulphide quantum dots and steam cracker tar. Massachusetts Institute of Technology (2019)
C. Josserand, S.T. Thoroddsen, Annu. Rev. Fluid Mech. 48, 365 (2016)
W. Hoffman, L. King, Applications of emerging optoelectronic materials: lead sulphide quantum dots and steam cracker tar. International Journal Advanced Design and Manufacturing Technology (2019) p 101–114
P.A. Harris, N. Faucher, N. George, P.M. Eidam, B.W. King, G.V. White, S.B. Berger, Discovery and lead-optimization of 4, 5-dihydropyrazoles as mono-kinase selective, orally bioavailable and efficacious inhibitors of receptor interacting protein 1 (RIP1) kinase. J. Med. Chem. 62, 5096–5110 (2019)
J. Curlett, H. Wanlin, Google Patents (2019)
J.O. Morales, A.B. Watts, J.T. McConville, Formulating Poorly Water Soluble Drugs (Springer, Berlin, 2016), p. 165
V. Nguyen et al., Wear 348, 126 (2016)
A. Vardelle et al., J. Therm. Spray Technol. 25, 1376 (2016)
A. Shojaeizadeh et al., Measurement 122, 325–338 (2018)
H.L. Williams, UC Berkeley (2017)
R. Kohli, Developments in Surface Contamination and Cleaning: Applications of Cleaning Techniques (Elsevier, New York, 2019), p. 391
M.N.H. Mat et al., CFD Lett. 11, 18 (2019)
V. Ramji, R. Mukesh, I. Hasan, Applied Mechanics and Materials (Trans Tech Publ, Stafa, 2016), p. 617
M.N.H. Mat, N., Asmuin, Int. J. Integr. Eng. 10, 130–135 (2018).
A. Rudek, Development and validation of a numerical model of the CO2 dry-ice blasting process for aircraft engine cleaning applications. Technological University Dublin p 5096–5110 (2018)
N. Yuvaraj, M.P. Kumar, Mater. Manuf. Process 32, 162 (2017)
J.P. de Sousa Ferreira, Integration of design rules and process modelling within SPIF technology-a review on the industrial dissemination of single point incremental forming. International Journal Advance Manufacturing Technol p 4387–4399 (2017)
S. Dong et al., Surf. Coat. Technol. 268, 46 (2015)
K. Penttilä, (2017)
M. Askarishahi et al., Powder Technol. 274, 379 (2015)
A.M. Ganán-Calvo et al., J. Aerosol Sci. 125, 32 (2018)
G. Spur, E. Uhlmann, F. Elbing, Wear 233, 402 (1999)
S. Dong et al., Mater. Res. Innov. 16, 61 (2012)
J.Y. Yong et al., J. Clean. Prod. 111, 1 (2016)