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  • 2019InghamMRes

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Surface temperature equalisation through automated laser vaporisation of thick film electrical heating elements

Research output: ThesisMaster's Thesis

Published

Standard

Surface temperature equalisation through automated laser vaporisation of thick film electrical heating elements. / Ingham, Joshua.
Lancaster University, 2019. 195 p.

Research output: ThesisMaster's Thesis

Harvard

Ingham, J 2019, 'Surface temperature equalisation through automated laser vaporisation of thick film electrical heating elements', Masters by Research, Lancaster University. https://doi.org/10.17635/lancaster/thesis/612

APA

Ingham, J. (2019). Surface temperature equalisation through automated laser vaporisation of thick film electrical heating elements. [Master's Thesis, Lancaster University]. Lancaster University. https://doi.org/10.17635/lancaster/thesis/612

Vancouver

Ingham J. Surface temperature equalisation through automated laser vaporisation of thick film electrical heating elements. Lancaster University, 2019. 195 p. doi: 10.17635/lancaster/thesis/612

Author

Ingham, Joshua. / Surface temperature equalisation through automated laser vaporisation of thick film electrical heating elements. Lancaster University, 2019. 195 p.

Bibtex

@mastersthesis{be5270b5b1634154b2a1f7da20c775fe,
title = "Surface temperature equalisation through automated laser vaporisation of thick film electrical heating elements",
abstract = "The increasing proportion of energy used by electric heating devices creates an ever-growing demand for more efficient heating technology. This research project investigated the CO2 laser ablation of partially oxidised Ni-Fe-Cr-NiO flame sprayed electrical heating elements in order to develop an automated system to optimise the surface temperature profile of thin film electrical heating elements. The optimisation technique used was the targeted local resistance change across the surface of a heating element{\textquoteright}s film so that the element temperature profile produced through the joule heating of the conductor is uniform and evenly distributed. Various surface treatment processing methods were developed that were used for the automated treatment of the element. These processing methods were compared and analysed through the standard deviation and kurtosis of the element{\textquoteright}s surface temperature distribution, the greatest improvement of all the processing methods showed a 71% reduction in standard deviation of the surface temperature distribution of the heating element.",
author = "Joshua Ingham",
year = "2019",
doi = "10.17635/lancaster/thesis/612",
language = "English",
publisher = "Lancaster University",
school = "Lancaster University",

}

RIS

TY - THES

T1 - Surface temperature equalisation through automated laser vaporisation of thick film electrical heating elements

AU - Ingham, Joshua

PY - 2019

Y1 - 2019

N2 - The increasing proportion of energy used by electric heating devices creates an ever-growing demand for more efficient heating technology. This research project investigated the CO2 laser ablation of partially oxidised Ni-Fe-Cr-NiO flame sprayed electrical heating elements in order to develop an automated system to optimise the surface temperature profile of thin film electrical heating elements. The optimisation technique used was the targeted local resistance change across the surface of a heating element’s film so that the element temperature profile produced through the joule heating of the conductor is uniform and evenly distributed. Various surface treatment processing methods were developed that were used for the automated treatment of the element. These processing methods were compared and analysed through the standard deviation and kurtosis of the element’s surface temperature distribution, the greatest improvement of all the processing methods showed a 71% reduction in standard deviation of the surface temperature distribution of the heating element.

AB - The increasing proportion of energy used by electric heating devices creates an ever-growing demand for more efficient heating technology. This research project investigated the CO2 laser ablation of partially oxidised Ni-Fe-Cr-NiO flame sprayed electrical heating elements in order to develop an automated system to optimise the surface temperature profile of thin film electrical heating elements. The optimisation technique used was the targeted local resistance change across the surface of a heating element’s film so that the element temperature profile produced through the joule heating of the conductor is uniform and evenly distributed. Various surface treatment processing methods were developed that were used for the automated treatment of the element. These processing methods were compared and analysed through the standard deviation and kurtosis of the element’s surface temperature distribution, the greatest improvement of all the processing methods showed a 71% reduction in standard deviation of the surface temperature distribution of the heating element.

U2 - 10.17635/lancaster/thesis/612

DO - 10.17635/lancaster/thesis/612

M3 - Master's Thesis

PB - Lancaster University

ER -