Hostname: page-component-586b7cd67f-r5fsc Total loading time: 0 Render date: 2024-11-27T13:26:24.107Z Has data issue: false hasContentIssue false
  • English
  • Français

Derivation of Criteria for Identifying Lightweight Potential – A Literature Review

Part of: Lightweight Design

Published online by Cambridge University Press:  26 July 2019

Felix Laufer ,
Daniel Roth  and
Hansgeorg Binz

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Lightweight potential is a powerful indicator – but not as powerful as it could be. Current methods for analyzing a product's potential to be reduced in mass only deal with a few of the most important criteria for lightweight design. The amount of literature dealing with lightweight design is significant, yet it can help to understand these versatile criteria. Firstly, the literature on this topic will therefore be reviewed to derive a broad set of criteria used in contemporary lightweight design. Secondly, a further review will reveal the criteria used to derive lightweight potential. Subsequently, both sets will be compared to identify the missing criteria used for the derivation of lightweight potential. This will support designers in two ways. On the one hand, matching and combining both criteria sets will enable the most representative criteria for a particular design case to be chosen, thus leading to a more comprehensible derivation of lightweight potential. On the other hand, the combination set will provide a basis for designers and design teams to refine their understanding of their own motivations for conducting lightweight design.

Keywords

Lightweight designDecision makingDesign for X (DfX)
Type
Article
Information
Proceedings of the Design Society: International Conference on Engineering Design , Volume 1 , Issue 1 , July 2019 , pp. 2677 - 2686
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - ND
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives licence (http://creativecommons.org/licenses/by-nc-nd/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the original work is unaltered and is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use or in order to create a derivative work.
Copyright
© The Author(s) 2019

References

Ahn, H.-J., Lee, K.-H. and Lee, C.-H. (2017), “Design optimization of a knee joint for an active transfemoral pros-thesis for weight reduction”, Journal of Mechanical Science and Technology, Vol. 31 No. 12, pp. 59055913.Google Scholar
Albers, A., Wagner, D., Ruckpaul, A., Hessenauer, B., Burkardt, N. and Matthiesen, S. (2013), “Target Weighing- A New Approach for Conceptual Lightweight Design in Early Phases of Complex Systems Development”, Proceedings of the ICED 2013 / 19th International Conference on Engineering Design, Seoul, Korea, August 19-22, 2013, pp. 301310.Google Scholar
Albers, A., Revfi, S. and Spadinger, M. (2017), “Extended Target Weighing Approach - Identification of Lightweight Design Potential for New Product Generations”, Proceedings of the ICED 2017 / 21th International Conference on Engineering Design, Vancouver, USA, August 21-25, 2017, pp. 367376.Google Scholar
Albers, A., Moeser, G. and Revfi, S. (2018), “Synergy effects by using sysml models for the lightweight design method “extended target weighing approach”, Procedia CIRP, Vol. 70, pp. 434439.Google Scholar
Alonso, E., Lee, T.M., Bjelkengren, C., Roth, R. and Kirchain, R.E. (2012), “Evaluating the potential for secondary mass savings in vehicle lightweighting”, Environmental science & technology, Vol. 46 No. 5, pp. 28932901.Google Scholar
Bein, T., Mayer, D., Hagebeuker, L., Bachinger, A., Bassan, D., Pluymers, B. and Delogu, M. (2016), “Enhanced lightweight design – first results of the FP7 project ENLIGHT”, Transportation Research Procedia, Vol. 14, pp. 10311040.Google Scholar
Belingardi, G., Chiandussi, G., Gobetto, E. and Scattina, A. (2010), “Bonnet weight reduction and VRU protection. Design proposals implementing non-conventional materials”, International Journal of Automotive Technology, Vol. 11 No. 6, pp. 831842.Google Scholar
Blessing, L.T.M. and Chakrabarti, A. (2009), DRM, a Design Research Methodology, Springer, London. https://doi.org/10.1007/978-1-84882-587-1Google Scholar
Block, P., Schlueter, A., Veenendaal, D., Bakker, J., Begle, M., Hischier, I., Hofer, J., Jayathissa, P., Maxwell, I., Echenagucia, T.M., Nagy, Z., Pigram, D., Svetozarevic, B., Torsing, R., Verbeek, J., Willmann, A. and Lydon, G.P. (2017), “NEST HiLo. Investigating lightweight construction and adaptive energy systems”, Journal of Building Engineering, Vol. 12, pp. 332341.Google Scholar
Borazjani, S. and Belingardi, G. (2016), “Lightweight design. Detailed comparison of roof panel solutions at crash and stiffness analyses”, International Journal of Crashworthiness, Vol. 22 No. 1, pp. 4962.Google Scholar
Butterfield, J., Yao, H., Price, M., Armstrong, C. and Raghunathan, S. (2005), “Weight reduction methodologies for a thrust reverser cascade using aerodynamic and structural integration”, Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, Vol. 218 No. 5, pp. 301313.Google Scholar
Caldwell, B.W., Namouz, E.Z., Richardson, J.L., Sen, C., Rotenburg, T., Mocko, G.M., Summers, J.D. and Obieglo, A. (2013), “Automotive lightweight engineering. A method for identifying lazy parts”, International Journal of Vehicle Design, Vol. 63 No. 4, p. 364.Google Scholar
Cheah, L. and Heywood, J. (2011), “Meeting U.S. passenger vehicle fuel economy standards in 2016 and beyond”, Energy Policy, Vol. 39 No. 1, pp. 454466.Google Scholar
Choudry, S.A., Kaspar, J., Alber, U. and Landgrebe, D. (2018), “Integration of an assessment methodology for the selection of joining technologies in lightweight engineering”, Procedia CIRP, Vol. 70, pp. 217222.Google Scholar
Delogu, M., Del Pero, F. and Pierini, M. (2016), “Lightweight design solutions in the automotive field. Environmental modelling based on fuel reduction value applied to diesel turbocharged vehicles”, Sustainability, Vol. 8 No. 11, p. 1167.Google Scholar
Delogu, M., Zanchi, L., Dattilo, C.A. and Ierides, M. (2018), “Parameters affecting the sustainability tradeoff been production and use stages in the automotive lightweight design”, Procedia CIRP, Vol. 69, pp. 534539.Google Scholar
Friedrich, H. E. (2017), Leichtbau in der Fahrzeugtechnik, Springer Vieweg Verlag, Wiesbaden.Google Scholar
Hao, H., Wang, S., Liu, Z. and Zhao, F. (2016), “The impact of stepped fuel economy targets on automaker's light-weighting strategy. The China case”, Energy, Vol. 94, pp. 755765.Google Scholar
He, Y., Huang, T., Wang, Y., Nie, Y., Li, Y. and Wang, Y. (2017), “A new lightweight design method integrating shape optimization with life cycle assessment for extrusion dies”, Journal of Cleaner Production, Vol. 150, pp. 4757.Google Scholar
Hottle, T., Caffrey, C., McDonald, J. and Dodder, R. (2017), “Critical factors affecting life cycle assessments of material choice for vehicle mass reduction”, Transportation Research Part D: Transport and Environment, Vol. 56, pp. 241257.Google Scholar
Ibusuki, U. and Kaminski, P. C. (2007), “Product development process with focus on value engineering and target-costing: A case study in an automotive company: Scheduling in batch-processing industries and supply chains”, International Journal of Production Economics, Vol. 105 No. 2, pp. 459474.Google Scholar
Naji, S., Çelik, O.C., Johnson Alengaram, U., Jumaat, M.Z. and Shamshirband, S. (2014), “Structure, energy and cost efficiency evaluation of three different lightweight construction systems used in low-rise residential buildings”, Energy and Buildings, Vol. 84, pp. 727739.Google Scholar
Keane, R.G., Scher, R.M. and Piskorski, R. (2007), “Toward a lightweight design philosophy for high-speed sealift ships”, Naval Engineers Journal, Vol. 119 No. 4, pp. 37–63.Google Scholar
Kaspar, J. and Vielhaber, M. (2017), “Sustainable lightweight design – relevance and impact on the product development & lifecycle process”, Procedia Manufacturing, Vol. 8, pp. 409416.Google Scholar
Kaspar, J., Choudry, S.A. and Vielhaber, M. (2018), “Concurrent selection of material and joining technology – holistically relevant aspects and its mutual interrelations in lightweight engineering”, Procedia CIRP, Vol. 72, pp. 780785.Google Scholar
Kelly, J.C., Sullivan, J.L., Burnham, A. and Elgowainy, A. (2015), “Impacts of vehicle weight reduction via material substitution on life-cycle greenhouse gas emissions”, Environmental Science & Technology, Vol. 49 No. 20, pp. 1253512542.Google Scholar
Khode, A.P., Senthilkumar, K., Patil, B.S., Kulkarni, N. and Trikande, M.W. (2017), “Shape optimization and weight reduction of seat structure for wheeled armoured amphibious combat vehicle”, Materials Today: Proceedings, Vol. 4 No. 2, pp. 19171926.Google Scholar
Koenig, J. and Friedrich, H.E. (2011), “Integral consideration of the lightweight design for railway vehicles”, In: Conference Proceedings. Young Researchers Seminar, June, 8-10, 2011, Copenhagen, Denmark.Google Scholar
Koffler, C. and Rohde-Brandenburger, K. (2010), “On the calculation of fuel savings through lightweight design in automotive life cycle assessments”, The International Journal of Life Cycle Assessment, Vol. 15 No. 1, pp. 128135.Google Scholar
Kroll, L., Blau, P., Wabner, M., Frieß, U., Eulitz, J. and Klärner, M. (2011), “Lightweight components for energy-efficient machine tools”, CIRP Journal of Manufacturing Science and Technology, Vol. 4 No. 2, pp. 148160.Google Scholar
Laufer, F., Roth, D. and Binz, H. (2018), “Supporting engineers in lightweight design: The Energy Distribution Analysis (EDA)”, in 15th International Design Conference, May, 21-24, 2018, Croatia; The Design Society, Glasgow, UK, pp. 829840.Google Scholar
Lewis, A.M., Kelly, J.C. and Keoleian, G.A. (2014), “Vehicle lightweighting vs. electrification. Life cycle energy and GHG emissions results for diverse powertrain vehicles”, Applied Energy, Vol. 126, pp. 1320.Google Scholar
Li, A. and Liu, C. (2017), “Lightweight design of a crane frame under stress and stiffness constraints using super-element technique”, Advances in Mechanical Engineering, Vol. 9 No. 8, pp. 168781401771662.Google Scholar
Lowrie, J., Pang, H. and Ngaile, G. (2017), “Weight reduction of heavy-duty truck components through hollow geometry and intensive quenching”, Journal of Manufacturing Processes, Vol. 28, pp. 523530.Google Scholar
Luedeke, T. and Vielhaber, M. (2014), “Holistic Approach for Secondary Weight Improvements”, Procedia CIRP, Vol. 21, pp. 218223.Google Scholar
Maxwell, C. (1869), Scientific papers II, University Press, Cambridge.Google Scholar
Maier, J.R.A., McLellan, J.M., Mocko, G., Fadel, G.M. and Brudnak, M. (2009), “Lightweight Engineering of Military Vehicles Through Requirements Analysis and Function Integration”, In: ASME International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. August 30–September 2, 2009, San Diego, California, USA.Google Scholar
Mayyas, A., Omar, M., Hayajneh, M. and Mayyas, A.R. (2017), “Vehicle's lightweight design vs. electrification from life cycle assessment perspective”, Journal of Cleaner Production, Vol. 167, pp. 687701.Google Scholar
Nie, Y., Lin, Y.-J., Sun, W. and Huang, T. (2015), “A Methodology for Optimal Lightweight Design of Moulds and Dies: A Case Study”, In: Proceedings of the ASME International Mechanical Engineering Congress and Exposition - 2015, November 13-15, Houston, Texas, USA.Google Scholar
O'Reilly, C.J., Göransson, P., Funazaki, A., Suzuki, T., Edlund, S., Gunnarsson, C., Lundow, J.-O., Cerin, P., Cameron, C.J., Wennhage, P. and Potting, J. (2016), “Life cycle energy optimisation. A proposed methodology for integrating environmental considerations early in the vehicle engineering design process”, Journal of Cleaner Production, Vol. 135, pp. 750759.Google Scholar
Pan, F., Zhu, P. and Zhang, Y. (2010), “Metamodel-based lightweight design of B-pillar with TWB structure via support vector regression”, Computers & Structures, Vol. 88 No. 1–2, pp. 3644.Google Scholar
Paquet, R., Lebaillif, D. and Petitpas, E. (2013), “Use of multi-scale approach for vehicle weight reduction study”, Procedia Engineering, Vol. 66, pp. 403414.Google Scholar
Peças, P., Ribeiro, I., Folgado, R, Henriques, E. (2009), “A life cycle engineering model for technology selection: a case study on plastic injection moulds for low production volumes”, J Clean Prod, Vol. 17 No. 9, pp. 846856.Google Scholar
Pine, T., Lee, M.M.K. and Jones, T.B. (1999), “Weight reduction in automotive structures—an experimental study on torsional stiffness of box sections”, Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, Vol. 213 No. 1, pp. 5971.Google Scholar
Posner, B., Binz, H., Roth, D. and others. (2014), “Supporting Lightweight Design Potential Assessment in the Conceptual Phase”, Marjanović, D., Štorga, M., Pavković, N. and Bojčetić, N. (Eds.), In: Proceedings of the DESIGN 2014, 13th International Design Conference. Zagreb, Croatia; The Design Society, Glasgow, UK, pp. 353362.Google Scholar
Prawoto, Y., Djuansjah, J., Tawi, K.B. and Fanone, M.M. (2013), “Tailoring microstructures. A technical note on eco-friendly approach to weight reduction through heat treatment”, Materials & Design, Vol. 50, pp. 635645.Google Scholar
Qin, C., Innes-Wimsatt, E. and Loth, E. (2016), “Hydraulic-electric hybrid wind turbines. Tower mass saving and energy storage capacity”, Renewable Energy, Vol. 99, pp. 6979.Google Scholar
Sakundarini, N., Taha, Z., Abdul-Rashid, S.H. and Ghazila, R.A.R. (2013), “Optimal multi-material selection for lightweight design of automotive body assembly incorporating recyclability”, Materials & Design, Vol. 50, pp. 846857.Google Scholar
Schleinkofer, U., Laufer, F., Zimmermann, M., Roth, D. and Bauernhansl, T. (2018), “Resource-efficient manufacturing systems through lightweight construction by using a combined development approach”, Procedia CIRP, Vol. 72, pp. 856861.Google Scholar
Shi, Y., Zhu, P., Shen, L. and Lin, Z. (2007), “Lightweight design of automotive front side rails with TWB concept”, Thin-Walled Structures, Vol. 45 No. 1, pp. 814.Google Scholar
Soanes, C. and Persall, J. (Eds.) (2005), Oxford dictionary of English, 2. ed., rev, Oxford Univ. Pr, Oxford.Google Scholar
Takahashi, T., Takemoto, M., Ogasawara, S., Hino, W. and Takezaki, K. (2017), “Size and Weight Reduction of an In-Wheel Axial-Gap Motor Using Ferrite Permanent Magnets for Electric Commuter Cars”, IEEE Transactions on Industry Applications, Vol. 53 No. 4, pp. 39273935.Google Scholar
Tawfik, B.E., Leheta, H., Elhewy, A. and Elsayed, T. (2017), “Weight reduction and strengthening of marine hatch covers by using composite materials”, International Journal of Naval Architecture and Ocean Engineering, Vol. 9 No. 2, pp. 185198.Google Scholar
Tornow, A., Raatz, A. and Dröder, K. (2014), “Battery system development – assembly planning between lightweight design and high volume production”, Procedia CIRP, Vol. 23, pp. 143148.Google Scholar
Tsai, W.-H., Chang, Y.-C., Lin, S.-J., Chen, H.-C. and Chu, P.-Y. (2014), “A green approach to the weight reduction of aircraft cabins”, Journal of Air Transport Management, Vol. 40, pp. 6577.Google Scholar
Viqaruddin, M. and Ramana Reddy, D. (2017), “Structural optimization of control arm for weight reduction and improved performance”, Materials Today: Proceedings, Vol. 4 No. 8, pp. 92309236.Google Scholar
Wang, D., Lv, T., Wang, C., Zhang, C., Wang, F. and Zhang, W. (2017a), “Multi-objective lightweight optimization and design for body-in-white frontal sub-module”, Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, Vol. 232 No. 11, pp. 14651480.Google Scholar
Wang, M., Liu, H. and Huang, T. (2017b), “An approach for the lightweight design of a 3-SPR parallel mechanism”, Journal of Mechanisms and Robotics, Vol. 9 No. 5, p. 51016.Google Scholar
Woodward, D.G. (1997), “Life cycle costing–theory, information acquisition and application”, International Journal of Project Management, Vol. 15 No. 6, pp. 335344.Google Scholar
Xu, D., Chen, J., Tang, Y. and Cao, J. (2012), “Topology optimization of die weight reduction for high-strength sheet metal stamping”, International Journal of Mechanical Sciences, Vol. 59 No. 1, pp. 7382.Google Scholar
Zhang, Y., Zhu, P. and Chen, G. (2007), “Lightweight design of automotive front side rail based on robust optimisation”, Thin-Walled Structures, Vol. 45 No. 7–8, pp. 670676.Google Scholar
Zhu, L., Li, N. and Childs, P. (2018), “Light-weighting in aerospace component and system design”, Propulsion and Power Research, Vol. 7 No. 2, pp. 103119.Google Scholar