A green productivity model for manufacturing processes using life cycle assessment and analytic hierarchy process

A green productivity model for manufacturing processes using life cycle assessment and analytic hierarchy process

There is an increasing awareness of issues related to sustainable development and environmental considerations are becoming a source of competitive advantage for industries in the global market. Many concepts and strategies in improving product and process performance have evolved over time from the...

Full description

Saved in:
Bibliographic Details
Main Author: Henson, Ruby P.
Format: text
Language:English
Published: Animo Repository 2005
Subjects:
Manufacturing processes
Process control
Assembly-line methods
Production engineering
Industrial Engineering
Online Access:https://animorepository.dlsu.edu.ph/etd_doctoral/79
https://animorepository.dlsu.edu.ph/context/etd_doctoral/article/1078/viewcontent/CDTG003846_P.pdf
Tags: Add Tag
No Tags, Be the first to tag this record!
Institution: De La Salle University
Language: English
id oai:animorepository.dlsu.edu.ph:etd_doctoral-1078
record_format eprints
spelling oai:animorepository.dlsu.edu.ph:etd_doctoral-10782023-07-14T01:36:36Z A green productivity model for manufacturing processes using life cycle assessment and analytic hierarchy process Henson, Ruby P. There is an increasing awareness of issues related to sustainable development and environmental considerations are becoming a source of competitive advantage for industries in the global market. Many concepts and strategies in improving product and process performance have evolved over time from the interaction of environmental and resource parameters in product development, process technology, and systems management. Green Productivity (GP), a new paradigm in sustainable manufacturing, integrates environmental protection and productivity where the former serves as the foundation for sustainability and the latter, the framework for continuous improvement (APO, 2000). This productivity approach to the sustainability of industries requires the adoption of cleaner production techniques and the development of appropriate indicators and instruments to measure economic and ecological efficiency or ecoefficiency (WBCSD, 2001). The study presents a methodology for the GP diagnosis of manufacturing processes that integrates life cycle assessment (LCA) and the analytic hierarchy process (AHP). LCA sets the goal of the systems analysis methodology that includes inventory, impact and improvement assessment from which the decision parameters are scoped out. The AHP provides the decision framework and the valuation tool in impact and improvement assessment to obtain priority weights for decision making leading to systematic improvement along the product life cycle. An input-output material flow analysis serves as the basis of the indicator system for GP performance measurement in the scenario analysis. The diagnostic model was applied on a semiconductor assembly/packaging operation. From the streamlined life cycle inventory, the significant impact factors derived were water resource depletion (WRD), energy resource depletion (ERD), human toxicity3 air (HTA), human toxicity-land (HTL), human toxicity-water (HTW), aquatic ecotoxicity (ETA) and terrestrial ecotoxicity (ETT). Valuation of impact factors using the AHP prioritized ETT, HTL, WRD and ERD in The AHP procedure also prioritized material-based and process-based techniques for GP improvement. In the scenario analysis, the highest values in GP improvement indices were noted for energy utilization, water utilization and terrestrial ecotoxicity with the implementation of a process-based improvement technique on a product-specific operation. Expert system technology was explored in developing a diagnostic prototype that emulates how human experts diagnose green productivity of manufacturing processes. Using CLIPS (C Language Integrated Production System), rule-based knowledge processing is made on the parameters derived from the application of the LCA-based model to generate the diagnostic interpretation and advice on the priority weights for the impact factors and improvement options obtained using the analytic hierarchy process and green productivity assessment based on performance indicators. The study also demonstrated the viability of merging database management system with expert system technology into an intelligent decision support system for GP assessment of manufacturing performance. 2005-01-01T08:00:00Z text application/pdf https://animorepository.dlsu.edu.ph/etd_doctoral/79 https://animorepository.dlsu.edu.ph/context/etd_doctoral/article/1078/viewcontent/CDTG003846_P.pdf Dissertations English Animo Repository Manufacturing processes Process control Assembly-line methods Production engineering Industrial Engineering
institution De La Salle University
building De La Salle University Library
continent Asia
country Philippines
Philippines
content_provider De La Salle University Library
collection DLSU Institutional Repository
language English
topic Manufacturing processes
Process control
Assembly-line methods
Production engineering
Industrial Engineering
spellingShingle Manufacturing processes
Process control
Assembly-line methods
Production engineering
Industrial Engineering
Henson, Ruby P.
A green productivity model for manufacturing processes using life cycle assessment and analytic hierarchy process
description There is an increasing awareness of issues related to sustainable development and environmental considerations are becoming a source of competitive advantage for industries in the global market. Many concepts and strategies in improving product and process performance have evolved over time from the interaction of environmental and resource parameters in product development, process technology, and systems management. Green Productivity (GP), a new paradigm in sustainable manufacturing, integrates environmental protection and productivity where the former serves as the foundation for sustainability and the latter, the framework for continuous improvement (APO, 2000). This productivity approach to the sustainability of industries requires the adoption of cleaner production techniques and the development of appropriate indicators and instruments to measure economic and ecological efficiency or ecoefficiency (WBCSD, 2001). The study presents a methodology for the GP diagnosis of manufacturing processes that integrates life cycle assessment (LCA) and the analytic hierarchy process (AHP). LCA sets the goal of the systems analysis methodology that includes inventory, impact and improvement assessment from which the decision parameters are scoped out. The AHP provides the decision framework and the valuation tool in impact and improvement assessment to obtain priority weights for decision making leading to systematic improvement along the product life cycle. An input-output material flow analysis serves as the basis of the indicator system for GP performance measurement in the scenario analysis. The diagnostic model was applied on a semiconductor assembly/packaging operation. From the streamlined life cycle inventory, the significant impact factors derived were water resource depletion (WRD), energy resource depletion (ERD), human toxicity3 air (HTA), human toxicity-land (HTL), human toxicity-water (HTW), aquatic ecotoxicity (ETA) and terrestrial ecotoxicity (ETT). Valuation of impact factors using the AHP prioritized ETT, HTL, WRD and ERD in The AHP procedure also prioritized material-based and process-based techniques for GP improvement. In the scenario analysis, the highest values in GP improvement indices were noted for energy utilization, water utilization and terrestrial ecotoxicity with the implementation of a process-based improvement technique on a product-specific operation. Expert system technology was explored in developing a diagnostic prototype that emulates how human experts diagnose green productivity of manufacturing processes. Using CLIPS (C Language Integrated Production System), rule-based knowledge processing is made on the parameters derived from the application of the LCA-based model to generate the diagnostic interpretation and advice on the priority weights for the impact factors and improvement options obtained using the analytic hierarchy process and green productivity assessment based on performance indicators. The study also demonstrated the viability of merging database management system with expert system technology into an intelligent decision support system for GP assessment of manufacturing performance.
format text
author Henson, Ruby P.
author_facet Henson, Ruby P.
author_sort Henson, Ruby P.
title A green productivity model for manufacturing processes using life cycle assessment and analytic hierarchy process
title_short A green productivity model for manufacturing processes using life cycle assessment and analytic hierarchy process
title_full A green productivity model for manufacturing processes using life cycle assessment and analytic hierarchy process
title_fullStr A green productivity model for manufacturing processes using life cycle assessment and analytic hierarchy process
title_full_unstemmed A green productivity model for manufacturing processes using life cycle assessment and analytic hierarchy process
title_sort green productivity model for manufacturing processes using life cycle assessment and analytic hierarchy process
publisher Animo Repository
publishDate 2005
url https://animorepository.dlsu.edu.ph/etd_doctoral/79
https://animorepository.dlsu.edu.ph/context/etd_doctoral/article/1078/viewcontent/CDTG003846_P.pdf
_version_ 1772835427609214976

Similar Items