LIFE CYCLE ASSESSMENT AND SIMULATION: ENABLERS OF SUSTAINABLE PRODUCT DESIGN

Purpose – The purpose of this paper is to present an integrated technical and economic model to evaluate the reusability of products or components. Design/methodology/approach – Life cycle assessment (LCA) methodology is applied to obtain the product’s environmental performance. Monte Carlo simulation is utilized for enabling sustainable product design. Findings – The results show that the model is capable of assessing the potential reusability of used products, while the usage of simulation significantly increases the effectiveness of the model in addressing uncertainties. Research limitations/implications – The case study has been conducted in a single manufacturing organization. The implications derived from the study are found to be practical and useful to the organization. Practical implications – The paper reports a case study carried out for an Indian rotary switches manufacturing organization. Hence, the model is practically feasible. Originality/value – The article presents a study that investigates LCA and simulation as enablers of sustainable product design. Hence, the contributions of this article are original and valuable.

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Integration between Green Quality Function Deployment, Modularity Concept and Life Cycle Assessment Toward Sustainable Product Design

MATEC Web of Conferences ◽

10.1051/matecconf/201815902070 ◽

2018 ◽

Vol 159 ◽

pp. 02070

Author(s):

Heru Prastawa ◽

Sri Hartini ◽

Mohamat Anshori ◽

Siechara Hans ◽

Christoper Wimba

Keyword(s):

Life Cycle Assessment ◽

Life Cycle ◽

Product Design ◽

Quality Function Deployment ◽

Sustainable Manufacturing ◽

Sustainable Product Design ◽

Quality Function ◽

Technical Parameters ◽

Sustainable Product ◽

The Impact

The design phase is recognized as a key phase in the application of sustainable manufacturing concepts. Green Quality Function Deployment (GQFD) and modularity play an important role in product design. Green Quality Function Deployment produces technical parameters that represent the needs of consumers while taking into account environmental aspects. Modularity benefits manufacturing and flexibility in facing adjustments and changes. Integration of GQFD and modularity is expected to generate synergistic gains from both. The results are measured by life cycle assessment (LCA) to determine the impact of the product on the environment. This study shows that GQFD, modularity and LCA integration in realizing sustainable product design is worthy of consideration. The case study was conducted with the fan because the product is very needed in the tropics, such as Indonesia.

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Sustainable product design: A life-cycle approach

Chemical Engineering Science ◽

10.1016/j.ces.2020.115508 ◽

2020 ◽

Vol 217 ◽

pp. 115508

Author(s):

Xiang Zhang ◽

Lei Zhang ◽

Ka Yip Fung ◽

Bhavik R. Bakshi ◽

Ka Ming Ng

Keyword(s):

Life Cycle ◽

Product Design ◽

Life Cycle Approach ◽

Sustainable Product Design ◽

Sustainable Product

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Tools for Sustainable Product Design: Review and Expectation

Volume 4: 18th Design for Manufacturing and the Life Cycle Conference; 2013 ASME/IEEE International Conference on Mechatronic and Embedded Systems and Applications ◽

10.1115/detc2013-13350 ◽

2013 ◽

Author(s):

Qingjin Peng ◽

Arash Hosseinpour ◽

Peihua Gu ◽

Zhun Fan

Keyword(s):

Life Cycle ◽

Product Design ◽

Computer Aided Design ◽

Product Life Cycle ◽

Material Selection ◽

Raw Material ◽

Design Tools ◽

Sustainable Product Design ◽

Structural Formation ◽

Sustainable Product

Sustainable product design plans the entire life cycle of a product from its raw material selection, conceptual and structural formation, manufacturing processing, and usage to its end-of-life, reuse, and recycle. The product design needs the sustainable knowledge and proper tools. Current computer-aided design systems are insufficient to represent complex relationships of product functions, structures and life cycle options. It is required for design tools to support product life cycle planning with multi-objective optimal solutions. In this paper, our experience in design of a wheelchair is used as an example to discuss the need of design tools. The aim is to define ideal tools for design of sustainable products.

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Review of sustainable product design from life cycle perspectives

International Journal of Precision Engineering and Manufacturing ◽

10.1007/s12541-012-0169-1 ◽

2012 ◽

Vol 13 (7) ◽

pp. 1259-1272 ◽

Cited By ~ 64

Author(s):

Ming-Chuan Chiu ◽

Chih-Hsing Chu

Keyword(s):

Life Cycle ◽

Product Design ◽

Sustainable Product Design ◽

Sustainable Product

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Sustainability in the Product Design: A Review of Recent Development Based on LCA

International Journal of Engineering & Technology ◽

10.14419/ijet.v7i3.7.16208 ◽

2018 ◽

Vol 7 (3.7) ◽

pp. 54

Author(s):

Salwa Mahmood ◽

Mohd Fahrul Hassan ◽

Abdul Rahman Hemdi ◽

Muhamad Zameri Mat Saman

Keyword(s):

Life Cycle Assessment ◽

Life Cycle ◽

Product Design ◽

Design Process ◽

Social Life ◽

Social Life Cycle Assessment ◽

Environmental Aspects ◽

Product Design Process ◽

Sustainable Product ◽

Potential Impact

In order to achieve sustainable product design process, aspects such of environmental, economic and social should be balanced. This paper discussed on sustainability of product design, conceptual basis of life cycle assessment (LCA), review of LCA at several product design, methodology of proposed framework and discussion on strengths and limitations of LCA. This paper proposed to develop a framework for improving the product design process based on LCA tool. The aims is to calculate potential impact of environment, economic and social aspects during product design process. For environmental aspects, LCA tool will be used. For economic and social considerations, life cycle costing (LCC) and social life cycle assessment will be applied respectively. At the end, proposed framework are able to help designers to improve product design by considering all sustainability aspects.

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Design for Disassembly Method As Sustainable Product Evaluation Tool: Example of Underground Escalator

Volume 11: Systems, Design, and Complexity ◽

10.1115/imece2017-70462 ◽

2017 ◽

Author(s):

Devdas Shetty ◽

Jiajun Xu

Keyword(s):

Life Cycle ◽

Product Design ◽

Sustainable Design ◽

Product Evaluation ◽

Drive System ◽

Sustainable Product Design ◽

Original Design ◽

Design For Disassembly ◽

Sustainable Product ◽

The Impact

Sustainable design and manufacturing considers a product’s full life cycle and the impact that its design, manufacture, use, and retirement can have not only on business but also the environment and society. Designers are becoming steadily aware of this problem, and are employing techniques that allow them to design with greater responsibility – Sustainable Product Design; in particular, the Design for Disassembly (DFD) is recommended as a technique of sustainable product design. In the case of a durable good with a long-life cycle or a product with parts subject to wear, maintainability/serviceability may be more important than initial product acquisition cost, and the product must be designed for easy maintenance. The DFD principles identify the ease with which products can be fabricated, maintained, serviced, and recycled. This paper examines and identifies a “Rating Chart” technique which can be used to evaluate DFD. It is demonstrated through a case study of underground escalator housing, in which different types of failure modes and defects occur in the major components of escalator drive systems, such as the motor and its drive chain system, handrail and its drive system, bearings/lubrication systems that are in adjunct with the bearing shaft assembly. Through the Rating Chart method proposed for DFD, the deficiency of the original design of escalator drive system was accessed and compared with the proposed sustainable design approach, in which the product maintainability can be significantly improved and the maintenance time can be greatly reduced. The paper concludes by showing the importance of sustainable product design for products working under extreme working conditions.

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Eco-design case-based reasoning tool: The integration of ecological quality function deployment and case-based reasoning methods for supporting sustainable product design

Proceedings of the Institution of Mechanical Engineers Part B Journal of Engineering Manufacture ◽

10.1177/0954405416668928 ◽

2016 ◽

Vol 232 (10) ◽

pp. 1778-1797 ◽

Cited By ~ 4

Author(s):

Awanis Romli ◽

Rossitza Setchi ◽

Paul Prickett ◽

Miguel P de la Pisa

Keyword(s):

Life Cycle ◽

Product Design ◽

Quality Function Deployment ◽

Case Based Reasoning ◽

Ecological Quality ◽

Sustainable Product Design ◽

Quality Function ◽

Sustainable Product ◽

Design Case ◽

Case Based

Several methods and tools have been developed to facilitate sustainable product design, but they lack critical application of the ecological design (eco-design) process and economic costing, particularly during the conceptual design phase. This research study overcomes these deficiencies by integrating eco-design approaches across all phases of the product life cycle. It proposes an eco-design case-based reasoning tool that is integrated with the recently developed ecological quality function deployment method, which supports sustainable product design. The eco-design case-based reasoning tool is an intuitive decision-support tool that complements the ecological quality function deployment method and proposes solutions related to customers’ requirements and the environmental and economic impacts of the product. The ecological quality function deployment method ensures that customers’ needs are considered within the context of product sustainability. The novelty of this article is in the development of the eco-design case-based reasoning tool which is based on the premise that if experiences from the ecological quality function deployment process can be captured in some useful form, designers can refer to and learn from them. This approach helps industrial decision-makers propose solutions by reusing solutions from similar cases and from their past experiences. The novelty is in the way the cases are structured and new cases are generated, using life-cycle assessments, cost estimations, and information about related manufacturing processes and means of transportation. This article demonstrates the applicability of the proposed approach through an industrial case study.

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