Application of fuzzy axiomatic design methodology for selection of design alternatives

Purpose – The purpose of this paper is to report a research conducted to apply fuzzy axiomatic design approach for selecting the design alternatives of an overflow valve. Design/methodology/approach – The approach started with the identification of functional requirements (FRs) and design parameters...

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Bibliographic Details
Published in:Journal of engineering, design and technology design and technology, 2015-03, Vol.13 (1), p.2-22
Main Authors: Vinodh, S, Kamala, V, Jayakrishna, K
Format: Article
Language:English
Subjects:
Alternatives
Analytic hierarchy process
Axioms
Design
Design analysis
Design engineering
Design for manufacturability
Design parameters
Designers
Feasibility studies
Fuzzy logic
Fuzzy sets
Linguistics
Literature reviews
Manufacturability
Materials selection
Materials substitution
Parameter identification
Principles
Product development
Product life cycle
Reliability
Studies
Values
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Summary:Purpose – The purpose of this paper is to report a research conducted to apply fuzzy axiomatic design approach for selecting the design alternatives of an overflow valve. Design/methodology/approach – The approach started with the identification of functional requirements (FRs) and design parameters (DPs) and the relationship between them to select the best design alternative. Fuzzy analytical hierarchy process was used to calculate the weightage of FRs. The independence and information axioms were being deployed to validate the selection process. Findings – The most important FRs being identified include “improve manufacturability and adaptability”, “improve ease of operation” and “provide strength and reliability”. The most important DPs are design unification on washer and outlet valve, material selection for improving the strength and reliability and pressure change to check whether the valve is withstanding the pressure using flow analysis. The best design alternative (A1) which deals with material substitution is being implemented in the case organization. The proposed methodology also enables contemporary design engineers to effectively select the best design among a set of alternatives in a fuzzy environment. Research limitations/implications – This paper presents the application of fuzzy axiomatic design for selecting the best design alternative of an overflow valve. The identified best design is being subjected to implementation in the case organization. Practical implications – The industry decision makers were involved throughout the conduct of the study. Hence, the inferences derived from the study possess practical feasibility. Originality/value – The application of the fuzzy axiomatic design approach for selecting the best design alternative of an overflow valve is the original contribution of the authors. Also, the practical feasibility of the approach is also being exemplified.
ISSN:1726-0531
1758-8901
DOI:10.1108/JEDT-02-2013-0017