Gas-Substrate Heat Exchange During Cold-Gas Dynamic Spraying

A.G. McDonald, A.N. Ryabinin, E. Irissou, J.-G. Legoux

Research output

18 Citations (Scopus)

Abstract

In this study, the temperature distribution of the surfaces of several substrates under an impinging gas jet from a cold spray nozzle was determined. A low-pressure cold-gas dynamic spraying unit was used to generate a jet of hot compressed nitrogen that impinged upon flat substrates. Computer codes based on a finite differences method were used to solve a simplified 2D temperature distribution equation for the substrate to produce nondimensional relationships between the surface temperature and the radius of the impinging fluid jet, the axial velocity of the cold spray nozzle, the substrate thickness, and the heating time. It was found that a single profile of the transient nondimensional maximum surface temperature could be used to estimate the dimensional maximum surface temperature, regardless of the value of the compressed gas temperature. It was found further that, as the thermal conductance of the substrate increased, the maximum surface temperature of the substrate beneath the gas jet decreased. Heat
Original languageEnglish
Pages (from-to)391-397
JournalJournal of Thermal Spray Technology
Volume22
Issue number2-3
DOIs
Publication statusPublished - 2013

Fingerprint

cold gas
Gas dynamics
gas dynamics
spraying
Spraying
Gases
spray nozzles
surface temperature
heat
Spray nozzles
Substrates
gases
temperature distribution
fluid jets
Temperature distribution
gas jets
gas temperature
Temperature
low pressure
computer programs

Cite this

McDonald, A.G. ; Ryabinin, A.N. ; Irissou, E. ; Legoux, J.-G. / Gas-Substrate Heat Exchange During Cold-Gas Dynamic Spraying. In: Journal of Thermal Spray Technology. 2013 ; Vol. 22, No. 2-3. pp. 391-397.
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Gas-Substrate Heat Exchange During Cold-Gas Dynamic Spraying. / McDonald, A.G.; Ryabinin, A.N.; Irissou, E.; Legoux, J.-G.

In: Journal of Thermal Spray Technology, Vol. 22, No. 2-3, 2013, p. 391-397.

Research output

TY - JOUR

T1 - Gas-Substrate Heat Exchange During Cold-Gas Dynamic Spraying

AU - McDonald, A.G.

AU - Ryabinin, A.N.

AU - Irissou, E.

AU - Legoux, J.-G.

PY - 2013

Y1 - 2013

N2 - In this study, the temperature distribution of the surfaces of several substrates under an impinging gas jet from a cold spray nozzle was determined. A low-pressure cold-gas dynamic spraying unit was used to generate a jet of hot compressed nitrogen that impinged upon flat substrates. Computer codes based on a finite differences method were used to solve a simplified 2D temperature distribution equation for the substrate to produce nondimensional relationships between the surface temperature and the radius of the impinging fluid jet, the axial velocity of the cold spray nozzle, the substrate thickness, and the heating time. It was found that a single profile of the transient nondimensional maximum surface temperature could be used to estimate the dimensional maximum surface temperature, regardless of the value of the compressed gas temperature. It was found further that, as the thermal conductance of the substrate increased, the maximum surface temperature of the substrate beneath the gas jet decreased. Heat

AB - In this study, the temperature distribution of the surfaces of several substrates under an impinging gas jet from a cold spray nozzle was determined. A low-pressure cold-gas dynamic spraying unit was used to generate a jet of hot compressed nitrogen that impinged upon flat substrates. Computer codes based on a finite differences method were used to solve a simplified 2D temperature distribution equation for the substrate to produce nondimensional relationships between the surface temperature and the radius of the impinging fluid jet, the axial velocity of the cold spray nozzle, the substrate thickness, and the heating time. It was found that a single profile of the transient nondimensional maximum surface temperature could be used to estimate the dimensional maximum surface temperature, regardless of the value of the compressed gas temperature. It was found further that, as the thermal conductance of the substrate increased, the maximum surface temperature of the substrate beneath the gas jet decreased. Heat

KW - cold spraying

KW - heat transfer

KW - jet impingement

KW - Pecle´ t number

KW - temperature distribution

U2 - 10.1007/s11666-012-9828-0

DO - 10.1007/s11666-012-9828-0

M3 - Conference article

VL - 22

SP - 391

EP - 397

JO - Journal of Thermal Spray Technology

JF - Journal of Thermal Spray Technology

SN - 1059-9630

IS - 2-3

ER -