A Methodology to Control the Microstructure of Plasma Sprayed Coatings

Martin Friis

A Methodology to Control the Microstructure of Plasma Sprayed Coatings

Martin Friis

Research output: Thesis › Doctoral Thesis (compilation)

Abstract

The aim of this thesis is to enhance the overall understanding of the plasma spray process and increase control and reproducibility of the coating properties. This was performed by establishment of relationships between controllable process parameters, in-flight properties of the injected particles (velocity and temperature), and microstructure properties. The relationships were used to establish a process control strategy. The research was performed in two areas. The first area is numerical simulation using computational fluid dynamics to model the plasma, the particle in-flight properties, and the plasma particle interactions. The second area is applied experimental research, focused on observations, measurements and statistical modeling techniques. The experimental work included measurements of particle properties, and evaluation of coating microstructures, using scanning electron microscopy and an in-house image analysis code. It was shown that the relationships were satisfactorily modeled by statistical linear regression. Particle velocity and temperature could be independently controlled by the arc current and the primary gas flow rate. The variables having the largest influence on the microstructure were found to be particle velocity, particle temperature, substrate temperature, and spray angle. The process control strategy was developed by creation of process maps, describing individual microstructure features, and deposition efficiency, as functions of particle velocity and temperature. Based on these maps a process control methodology, called process windows, was established. In this method each desired coating criteria are specified and corresponding particle velocity and particle temperature ranges determined. Keeping the particle properties within these ranges ensures the coating to meet its requirements. It was also shown that prior to implementation of the process window methodology, enhanced reproducibility can be achieved by reduction of spray gun tolerance limits. This work should be regarded as a foundation for a process control tool by which coating properties can be controlled and optimized on-line in industrial production.

Original language	English
Qualification	Doctor
Awarding Institution
Supervisors/Advisors	[unknown], [unknown], Supervisor, External person
Award date	2003 Jan 24
Publisher	Martin Friis, University of Trollhättan/Uddevalla, P.O. Box 957, SE-461 29,
ISBN (Print)	91-628-5502-6
Publication status	Published - 2002

Bibliographical note

Defence details

Date: 2003-01-24
Time: 10:15
Place: Lund, LTH, M-huset, M:B, kl.10.15

External reviewer(s)

Name: Sampath, Sanjay
Title: Professor
Affiliation: Center for Thermal Spray Research, Department of Materials Science and Engineering, State University of New York, Stony Brook, NY 11794-2275

---

Article: M. Friis, P. Nylén, C. Persson, J. WigrenInvestigation of particle in-flight characteristics during atmospheric plasmaspraying of yttria stabilized ZrO2: Part 1. ExperimentalPublished in Journal of Thermal Spray Technology, 2001, vol. 10 (2), pp. 301-310.

Article: P. Nylén, M. Friis, A. Hansbo, L. PejrydInvestigation of particle in-flight characteristics during atmospheric plasmaspraying of yttria stabilized ZrO2: Part 2. ModelingPublished in Journal of Thermal Spray Technology, 2001, vol. 10 (2), pp. 359-366.

Article: M. Friis, C. Persson, J. WigrenInfluence of particle in-flight characteristics on the microstructure of atmosphericplasma sprayed yttria stabilized ZrO2Published in Surface and Coatings Technology, 2001, vol. 141 (2-3), pp. 115-127.

Article: M. Friis, C. PerssonControl of thermal spray processes by means of process maps and process windowsAccepted for publication in Journal of Thermal Spray Technology.

Article: M. Friis, C. PerssonProcess window for plasma spray processesPublished in Thermal Spray 2001: New Surfaces for a New Millennium, Ed. C.C.Berndt, K.A. Khor, E. Lugscheider, Pub. ASM International, Materials Park, OH,USA, 2001, pp. 1313-1319.

Article: M. Friis, P. NylénA Numerical Study of the Sources of Variation in Particle In-Flight Characteristicsin Atmospheric Plasma SprayingAccepted for publication in Thermal Spray 2003: Recognizing the Past, Supportingthe Future and Nuturing Prosperity, Ed. C.C. Berndt, Pub. ASM International,Materials Park, OH, USA, 2003.

Subject classification (UKÄ)

Materials Engineering

Free keywords

materialteknik
Materiallära
Process map
Plasma spraying
process window
Thermal Barrier Coating
Zirconia
DPV2000
particle temperature
Material technology
particle velocity

Cite this

@phdthesis{258ad5510f5043aebe77e7b1e61f35e9,

title = "A Methodology to Control the Microstructure of Plasma Sprayed Coatings",

abstract = "The aim of this thesis is to enhance the overall understanding of the plasma spray process and increase control and reproducibility of the coating properties. This was performed by establishment of relationships between controllable process parameters, in-flight properties of the injected particles (velocity and temperature), and microstructure properties. The relationships were used to establish a process control strategy. The research was performed in two areas. The first area is numerical simulation using computational fluid dynamics to model the plasma, the particle in-flight properties, and the plasma particle interactions. The second area is applied experimental research, focused on observations, measurements and statistical modeling techniques. The experimental work included measurements of particle properties, and evaluation of coating microstructures, using scanning electron microscopy and an in-house image analysis code. It was shown that the relationships were satisfactorily modeled by statistical linear regression. Particle velocity and temperature could be independently controlled by the arc current and the primary gas flow rate. The variables having the largest influence on the microstructure were found to be particle velocity, particle temperature, substrate temperature, and spray angle. The process control strategy was developed by creation of process maps, describing individual microstructure features, and deposition efficiency, as functions of particle velocity and temperature. Based on these maps a process control methodology, called process windows, was established. In this method each desired coating criteria are specified and corresponding particle velocity and particle temperature ranges determined. Keeping the particle properties within these ranges ensures the coating to meet its requirements. It was also shown that prior to implementation of the process window methodology, enhanced reproducibility can be achieved by reduction of spray gun tolerance limits. This work should be regarded as a foundation for a process control tool by which coating properties can be controlled and optimized on-line in industrial production.",

keywords = "materialteknik, Materiall{\"a}ra, Process map, Plasma spraying, process window, Thermal Barrier Coating, Zirconia, DPV2000, particle temperature, Material technology, particle velocity",

author = "Martin Friis",

note = "Defence details Date: 2003-01-24 Time: 10:15 Place: Lund, LTH, M-huset, M:B, kl.10.15 External reviewer(s) Name: Sampath, Sanjay Title: Professor Affiliation: Center for Thermal Spray Research, Department of Materials Science and Engineering, State University of New York, Stony Brook, NY 11794-2275 --- Article: M. Friis, P. Nyl{\'e}n, C. Persson, J. WigrenInvestigation of particle in-flight characteristics during atmospheric plasmaspraying of yttria stabilized ZrO2: Part 1. ExperimentalPublished in Journal of Thermal Spray Technology, 2001, vol. 10 (2), pp. 301-310. Article: P. Nyl{\'e}n, M. Friis, A. Hansbo, L. PejrydInvestigation of particle in-flight characteristics during atmospheric plasmaspraying of yttria stabilized ZrO2: Part 2. ModelingPublished in Journal of Thermal Spray Technology, 2001, vol. 10 (2), pp. 359-366. Article: M. Friis, C. Persson, J. WigrenInfluence of particle in-flight characteristics on the microstructure of atmosphericplasma sprayed yttria stabilized ZrO2Published in Surface and Coatings Technology, 2001, vol. 141 (2-3), pp. 115-127. Article: M. Friis, C. PerssonControl of thermal spray processes by means of process maps and process windowsAccepted for publication in Journal of Thermal Spray Technology. Article: M. Friis, C. PerssonProcess window for plasma spray processesPublished in Thermal Spray 2001: New Surfaces for a New Millennium, Ed. C.C.Berndt, K.A. Khor, E. Lugscheider, Pub. ASM International, Materials Park, OH,USA, 2001, pp. 1313-1319. Article: M. Friis, P. Nyl{\'e}nA Numerical Study of the Sources of Variation in Particle In-Flight Characteristicsin Atmospheric Plasma SprayingAccepted for publication in Thermal Spray 2003: Recognizing the Past, Supportingthe Future and Nuturing Prosperity, Ed. C.C. Berndt, Pub. ASM International,Materials Park, OH, USA, 2003.",

year = "2002",

language = "English",

isbn = "91-628-5502-6",

publisher = "Martin Friis, University of Trollh{\"a}ttan/Uddevalla, P.O. Box 957, SE-461 29,",

type = "Doctoral Thesis (compilation)",

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T1 - A Methodology to Control the Microstructure of Plasma Sprayed Coatings

AU - Friis, Martin

N1 - Defence details Date: 2003-01-24 Time: 10:15 Place: Lund, LTH, M-huset, M:B, kl.10.15 External reviewer(s) Name: Sampath, Sanjay Title: Professor Affiliation: Center for Thermal Spray Research, Department of Materials Science and Engineering, State University of New York, Stony Brook, NY 11794-2275 --- Article: M. Friis, P. Nylén, C. Persson, J. WigrenInvestigation of particle in-flight characteristics during atmospheric plasmaspraying of yttria stabilized ZrO2: Part 1. ExperimentalPublished in Journal of Thermal Spray Technology, 2001, vol. 10 (2), pp. 301-310. Article: P. Nylén, M. Friis, A. Hansbo, L. PejrydInvestigation of particle in-flight characteristics during atmospheric plasmaspraying of yttria stabilized ZrO2: Part 2. ModelingPublished in Journal of Thermal Spray Technology, 2001, vol. 10 (2), pp. 359-366. Article: M. Friis, C. Persson, J. WigrenInfluence of particle in-flight characteristics on the microstructure of atmosphericplasma sprayed yttria stabilized ZrO2Published in Surface and Coatings Technology, 2001, vol. 141 (2-3), pp. 115-127. Article: M. Friis, C. PerssonControl of thermal spray processes by means of process maps and process windowsAccepted for publication in Journal of Thermal Spray Technology. Article: M. Friis, C. PerssonProcess window for plasma spray processesPublished in Thermal Spray 2001: New Surfaces for a New Millennium, Ed. C.C.Berndt, K.A. Khor, E. Lugscheider, Pub. ASM International, Materials Park, OH,USA, 2001, pp. 1313-1319. Article: M. Friis, P. NylénA Numerical Study of the Sources of Variation in Particle In-Flight Characteristicsin Atmospheric Plasma SprayingAccepted for publication in Thermal Spray 2003: Recognizing the Past, Supportingthe Future and Nuturing Prosperity, Ed. C.C. Berndt, Pub. ASM International,Materials Park, OH, USA, 2003.

PY - 2002

Y1 - 2002

N2 - The aim of this thesis is to enhance the overall understanding of the plasma spray process and increase control and reproducibility of the coating properties. This was performed by establishment of relationships between controllable process parameters, in-flight properties of the injected particles (velocity and temperature), and microstructure properties. The relationships were used to establish a process control strategy. The research was performed in two areas. The first area is numerical simulation using computational fluid dynamics to model the plasma, the particle in-flight properties, and the plasma particle interactions. The second area is applied experimental research, focused on observations, measurements and statistical modeling techniques. The experimental work included measurements of particle properties, and evaluation of coating microstructures, using scanning electron microscopy and an in-house image analysis code. It was shown that the relationships were satisfactorily modeled by statistical linear regression. Particle velocity and temperature could be independently controlled by the arc current and the primary gas flow rate. The variables having the largest influence on the microstructure were found to be particle velocity, particle temperature, substrate temperature, and spray angle. The process control strategy was developed by creation of process maps, describing individual microstructure features, and deposition efficiency, as functions of particle velocity and temperature. Based on these maps a process control methodology, called process windows, was established. In this method each desired coating criteria are specified and corresponding particle velocity and particle temperature ranges determined. Keeping the particle properties within these ranges ensures the coating to meet its requirements. It was also shown that prior to implementation of the process window methodology, enhanced reproducibility can be achieved by reduction of spray gun tolerance limits. This work should be regarded as a foundation for a process control tool by which coating properties can be controlled and optimized on-line in industrial production.

AB - The aim of this thesis is to enhance the overall understanding of the plasma spray process and increase control and reproducibility of the coating properties. This was performed by establishment of relationships between controllable process parameters, in-flight properties of the injected particles (velocity and temperature), and microstructure properties. The relationships were used to establish a process control strategy. The research was performed in two areas. The first area is numerical simulation using computational fluid dynamics to model the plasma, the particle in-flight properties, and the plasma particle interactions. The second area is applied experimental research, focused on observations, measurements and statistical modeling techniques. The experimental work included measurements of particle properties, and evaluation of coating microstructures, using scanning electron microscopy and an in-house image analysis code. It was shown that the relationships were satisfactorily modeled by statistical linear regression. Particle velocity and temperature could be independently controlled by the arc current and the primary gas flow rate. The variables having the largest influence on the microstructure were found to be particle velocity, particle temperature, substrate temperature, and spray angle. The process control strategy was developed by creation of process maps, describing individual microstructure features, and deposition efficiency, as functions of particle velocity and temperature. Based on these maps a process control methodology, called process windows, was established. In this method each desired coating criteria are specified and corresponding particle velocity and particle temperature ranges determined. Keeping the particle properties within these ranges ensures the coating to meet its requirements. It was also shown that prior to implementation of the process window methodology, enhanced reproducibility can be achieved by reduction of spray gun tolerance limits. This work should be regarded as a foundation for a process control tool by which coating properties can be controlled and optimized on-line in industrial production.

KW - materialteknik

KW - Materiallära

KW - Process map

KW - Plasma spraying

KW - process window

KW - Thermal Barrier Coating

KW - Zirconia

KW - DPV2000

KW - particle temperature

KW - Material technology

KW - particle velocity

M3 - Doctoral Thesis (compilation)

SN - 91-628-5502-6

PB - Martin Friis, University of Trollhättan/Uddevalla, P.O. Box 957, SE-461 29,

ER -

A Methodology to Control the Microstructure of Plasma Sprayed Coatings

Abstract

Bibliographical note

Subject classification (UKÄ)

Free keywords

Fingerprint

Cite this