Access the full text.
Sign up today, get DeepDyve free for 14 days.
V. Kosarev, S. Klinkov, A. Papyrin (2007)
Supersonic jet/substrate interaction in the cold spray process
D. Kotoban, S. Grigoriev, A. Okunkova, A. Sova (2017)
Influence of a shape of single track on deposition efficiency of 316L stainless steel powder in cold spraySurface & Coatings Technology, 309
M. Meyer, Shuo Yin, K. McDonnell, O. Stier, R. Lupoi (2016)
Feed rate effect on particulate acceleration in Cold Spray under low stagnation pressure conditionsSurface & Coatings Technology, 304
D. Gilmore, R. Dykhuizen, R. Neiser, M. Smith, T. Roemer (1999)
Particle velocity and deposition efficiency in the cold spray processJournal of Thermal Spray Technology, 8
Shuo Yin, Xiaofang Wang, Wenya Li, Yue Li (2012)
Numerical Study on the Effect of Substrate Size on the Supersonic Jet Flow and Temperature Distribution Within the Substrate in Cold SprayingJournal of Thermal Spray Technology, 21
X. Suo, M. Yu, W. Li, M. Planche, H. Liao (2012)
Effect of Substrate Preheating on Bonding Strength of Cold-Sprayed Mg CoatingsJournal of Thermal Spray Technology, 21
A. Papyrin, S. Klinkov, V. Kosarev (2005)
Effect of the Substrate Surface Activation on the Process of Cold Spray Coating FormationThermal Spray 2005: Proceedings from the International Thermal Spray Conference
V. Shikalov, S. Klinkov, V. Kosarev (2016)
Cold spraying on materials with low erosion resistance, 1770
S. Rech, A. Trentin, S. Vezzù, J. Legoux, E. Irissou, M. Guagliano (2011)
Influence of Pre-Heated Al 6061 Substrate Temperature on the Residual Stresses of Multipass Al Coatings Deposited by Cold SprayJournal of Thermal Spray Technology, 20
S. Klinkov, V. Kosarev, V. Shikalov (2019)
Influence of nozzle velocity and powder feed rate on the coating mass and deposition efficiency in cold sprayingSurface and Coatings Technology
R. Stephenson (1962)
A and VBritish Journal of Ophthalmology, 46
V. Varadaraajan, P. Mohanty (2017)
Design and optimization of rectangular cold spray nozzle: Radial injection angle, expansion ratio and traverse speedSurface & Coatings Technology, 316
(1998)
Kosarev, The study of the two-phase flow interaction with a heated surface
J. Legoux, E. Irissou, C. Moreau (2007)
Effect of Substrate Temperature on the Formation Mechanism of Cold-Sprayed Aluminum, Zinc and Tin CoatingsJournal of Thermal Spray Technology, 16
Yuta Watanabe, Chisato Yoshida, K. Atsumi, M. Yamada, M. Fukumoto (2014)
Influence of Substrate Temperature on Adhesion Strength of Cold-Sprayed CoatingsJournal of Thermal Spray Technology, 24
Chaoyue Chen, Yingchun Xie, C. Verdy, Renzhong Huang, H. Liao, Z. Ren, S. Deng (2017)
Numerical investigation of transient coating build-up and heat transfer in cold spraySurface & Coatings Technology, 326
Shuo Yin, X. Suo, Zhiwei Guo, H. Liao, Xiaofang Wang (2015)
Deposition features of cold sprayed copper particles on preheated substrateSurface & Coatings Technology, 268
Zhibo Zhao, B. Gillispie, John Smith (2006)
Coating deposition by the kinetic spray processSurface & Coatings Technology, 200
S. Klinkov, V. Kosarev (2006)
Measurements of cold spray deposition efficiencyJournal of Thermal Spray Technology, 15
(2007)
Papyrin, Supersonic jet/substrate interaction in the cold spray process, in: The Cold Spray Materials Deposition Process: Fundamentals and Applications, V.K
A. McDonald, A. Ryabinin, E. Irissou, J. Legoux (2013)
Gas-Substrate Heat Exchange During Cold-Gas Dynamic SprayingJournal of Thermal Spray Technology, 22
R. Maev, V. Leshchynsky (2007)
Introduction to Low Pressure Gas Dynamic Spray
Wenya Li, Shuo Yin, Xueping Guo, H. Liao, Xiaofang Wang, C. Coddet (2011)
An Investigation on Temperature Distribution Within the Substrate and Nozzle Wall in Cold Spraying by Numerical and Experimental MethodsJournal of Thermal Spray Technology, 21
K. Ernst, J. Braeutigam, F. Gaertner, T. Klassen (2012)
Effect of Substrate Temperature on Cold-Gas-Sprayed Coatings on Ceramic SubstratesJournal of Thermal Spray Technology, 22
A. Alkhimov, V. Kosarev, A. Papyrin (1990)
A method of "cold" gas-dynamic deposition, 35
V. Shikalov, S. Klinkov, V. Kosarev (2019)
Cold spray deposition of aluminum coating onto an erodible materialThermophysics and Aeromechanics, 26
O. Ozdemir, Christian Widener, M. Carter, Kyle Johnson (2017)
Predicting the Effects of Powder Feeding Rates on Particle Impact Conditions and Cold Spray Deposited CoatingsJournal of Thermal Spray Technology, 26
The influence of the stagnation temperature of the accelerating gas flow and that of nozzle travel speed on the deposition efficiency are studied when depositing single Cu-coating tracks by the cold spray technique. The experiments performed clearly show that the nozzle traverse speed substantially affects the value of measured deposition efficiency: the higher is the nozzle traverse speed, the lesser the measured deposition efficiency turns out to be at all other things being identical. Such a behavior can be explained by the fact that the first impacts of particles onto the substrate do not lead to their adhering to the surface and, hence, to coating deposition. It is known that, before the coating starts to grow, it is necessary for the substrate surface to be subjected to a sufficient number of particle impacts. This preparatory stage is called the activation stage, or the delay (induction) stage of the deposition process. It is shown for the first time that the specific (per unit area) mass of the powder consumed at the activation stage depends on the stagnation temperature of the accelerating gas flow: the higher is the stagnation temperature, the lower is the specific mass consumed.
Thermophysics and Aeromechanics – Springer Journals
Published: May 21, 2021
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.