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Journal articles on the topic 'Product engineering design'

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Published: 10 December 2022
Last updated: 28 January 2023

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1

hashemi, Seyed mehdi golestan, bijan khaiambashi, alireza mansoorian, and Maryam heidari. "Presenting a Consolidated Model of Bionic Product Design Engineering and Systems Engineering, New Approach in Product Design Engineering." International Academic Journal of Science and Engineering 05, no. 02 (December 19, 2018): 111–24. http://dx.doi.org/10.9756/iajse/v5i1/1810030.

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2

Bodratti, Andrew M., Zhiqi He, Marina Tsianou, Chong Cheng, and Paschalis Alexandridis. "Product Design Applied to Formulated Products." International Journal of Quality Assurance in Engineering and Technology Education 4, no. 3 (July 2015): 21–43. http://dx.doi.org/10.4018/ijqaete.2015070102.

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Product development is a multi-faceted role that a growing number of engineers are tasked with. This represents a significant shift in career paths for those employed in the chemical and materials engineering disciplines, who typically were concerned with bulk commodity manufacturing. This paradigm shift requires the undergraduate curriculum to be adapted to prepare students for these new responsibilities. The authors present here on a product design capstone course developed for chemical engineering seniors at the University at Buffalo (UB), The State University of New York (SUNY). The course encompasses the following themes: a general framework for product design and development (identify customer needs, convert needs to specifications, create ideas/concepts, select concept, formulate/test/manufacture product; and (nano)structure-property relations that guide the search for smart/tunable/functional materials for contemporary needs and challenges. These two main themes are enriched with case studies of successful products. Students put the course material into practice by working through formulated product design projects that are drawn from real-world problems. The authors begin by presenting the course organization, teaching techniques, and assessment strategy. They then discuss examples of student work to show how students apply the course material to solve problems. Finally, they present an analysis of historical student performance in the course. The analysis seeks to identify correlation between related student deliverables, and also between the Product Design course and a prerequisite materials science and engineering course.
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3

Zapanta, Conrad, Wayne Chung, and Joanna Dickert. "Interdisciplinary Design Teams for Biomedical Engineering Design." CUR Quarterly 37, no. 4 (July 1, 2017): 12–13. http://dx.doi.org/10.18833/curq/37/4/17.

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In the Biomedical Engineering (BME) Design course sequence at Carnegie Mellon University, BME students from the College of Engineering and product design students from the College of Fine Arts are introduced to the development of useful biomedical products in a one-year, research-based experience.
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4

Chakrabarti, Amaresh. "Engineering design methods: Strategies for product design." Materials & Design 16, no. 2 (January 1995): 122–23. http://dx.doi.org/10.1016/0261-3069(95)90023-3.

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5

Folkes, M. J. "Plastics product design engineering handbook." Materials Science and Engineering 83, no. 1 (October 1986): 161–62. http://dx.doi.org/10.1016/0025-5416(86)90184-9.

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6

Seider, Warren D., and Soemantri Widagdo. "Teaching chemical engineering product design." Current Opinion in Chemical Engineering 1, no. 4 (November 2012): 472–75. http://dx.doi.org/10.1016/j.coche.2012.08.003.

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7

Elvekrok, Dag Runar. "Concurrent Engineering in Ship Design." Journal of Ship Production 13, no. 04 (November 1, 1997): 258–69. http://dx.doi.org/10.5957/jsp.1997.13.4.258.

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Concurrent engineering is a systematic approach for integration and concurrent design of products. The systematic approach intends to consider all elements influencing the products and their related processes during the product life-cycle, such as manufacturing, support, costs, quality, user requirements etc. Especially the engineering design phase should be considered for improvements. This paper presents some of the major and most acknowledged concepts, ideas and principles of concurrent engineering. They are among others:trends and demands to product development time and product life-timeintroduction of a concurrent engineering environment, including the forces, dimensions, mechanisms and targets of concurrent engineeringthe design process, including considerations regarding to the quality and extent of iteration loops and construction of improved design processesquality function deployment, a method for identifying and managing requirements which is based on interfunctionality and interdisciplinary project-teams. The paper also discusses concurrent engineering in proportion to traditional design theories. The human and organization aspects in concurrent engineering are treated superficially. Finally, some applied concepts, principles and methods are briefly presented. This paper gives an overview and introduction to concurrent engineering.
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Prilutskaya, Maria, Anastasia Murukina, and Tatiana Dashkova. "Mechanical Engineering Product Value Design Applying the Value Engineering Method." MATEC Web of Conferences 346 (2021): 03038. http://dx.doi.org/10.1051/matecconf/202134603038.

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Today mechanical engineering is one of the most dynamically developing industries. The products of this industry are becoming more and more complex, requiring the continuous introduction of new high technologies into the production process. In addition, the change in the preferences of consumers of mechanical engineering products associated with an increase in the degree of automation and robotization of their production processes leads to the need to apply more flexible product design approaches. These approaches should allow the manufacturer to respond quickly to changing customer needs. Thus, machine-building enterprises need to provide not only the best price-quality ratio, but also to offer a unique set of product functions - a concept that satisfies all the needs of target consumers. In other words, the ability to create product value based on the individual needs of customers is a competitive advantage for a company in the struggle for market share. The application of Value Engineering Method is able to solve these problems.
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Duan, Wen Xin. "Application of Value Engineering in Industrial Product Design." Advanced Materials Research 591-593 (November 2012): 191–95. http://dx.doi.org/10.4028/www.scientific.net/amr.591-593.191.

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High-value products is the goal what to go after for consumer and the designer of industrial product must have a sense of value first. Value engineering is a creative activity which increase product value by optimizing the relationship between the function of product and its’ cost. It is a very effective way that the idea and methods of the value engineering are engaged in the product design, that is a effective measures for improving product value and its innovation design. The core of industrial product design is to carry out the functional and cost analysis of the product design in engineering activities.
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10

Yusuf, Muhammad, Cyrilla Indri Parwati, and Amelia Rachmi Nasution. "Value Engineering Analysis of Decorative Lightning in Product Development." Tekinfo: Jurnal Ilmiah Teknik Industri dan Informasi 9, no. 2 (August 10, 2021): 159–66. http://dx.doi.org/10.31001/tekinfo.v9i2.1161.

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Currently, the sales of decorative lighting products are very low because the design of decorative lights are less attractive to consumers. Therefore, the company must develop the product to produce quality products that are updated and attractive to consumers. This research aims to develop the decorative light products using value engineering. Value engineering was used to increase benefits withoutt increasing costs, reducing costs without reducing benefits, or a combination of both. This research was conducted to find out the level of efficiency that can be achieved from several recommended alternatives. Research results showed that the value of the initial design (Product A) was 3,48 x 10-7; product B was 3,16 x 10-7; and product C was 8,83 x 10-7. The use of raw materials has also changed from its initial design which was using a mixture of copper and brass with a thickness of 0,8 mm to an alternative design by using a mixture of copper and brass with a thickness of 0,5 mm. In addition, the study showed that product C are more preferable for consumers. Keywords: decorative lighting, product development, pairwise comparison, value engineering
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11

Kim, KwanMyung, and Kun-pyo Lee. "Collaborative product design processes of industrial design and engineering design in consumer product companies." Design Studies 46 (September 2016): 226–60. http://dx.doi.org/10.1016/j.destud.2016.06.003.

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12

Nagamachi, Mitsuo. "Kansei Engineering in Consumer Product Design." Ergonomics in Design: The Quarterly of Human Factors Applications 10, no. 2 (April 2002): 5–9. http://dx.doi.org/10.1177/106480460201000203.

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13

Broekhuis, Ton. "Special Issue – Product Design and Engineering." Chemical Engineering Research and Design 82, no. 11 (November 2004): 1409–10. http://dx.doi.org/10.1205/cerd.82.11.1409.52029.

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14

Altland, Henry W. "Engineering Methods for Robust Product Design." Technometrics 38, no. 3 (August 1996): 286–87. http://dx.doi.org/10.1080/00401706.1996.10484511.

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15

Hedlind, Mikael, and Torsten Kjellberg. "Kinematical product specifications in engineering design." CIRP Annals 63, no. 1 (2014): 197–200. http://dx.doi.org/10.1016/j.cirp.2014.03.097.

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16

Hu, Xiao Qing, and Yun Fang Gao. "Investigation of Consumer-Oriented Product System Design." Advanced Materials Research 317-319 (August 2011): 254–57. http://dx.doi.org/10.4028/www.scientific.net/amr.317-319.254.

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This paper deeply discussed consumer kansei system and demand, based on Kansei Engineering system; it researched method of product system design. This method used application theory of Kansei Engineering: consumer decision-aid system and designer decision-aid system, which investigated consumers’ preference adjectives in terms of kansei image, then used product system design, and outputted corresponding specific form of product system. On the other hand, product system designed by designers would induce the awareness of consumers for products, thus it affected consumers’ preferences, finally it worked out with product system which matched with consumer demand, and guided follow-up product design.
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17

Lian, Wenwu, Kun-Chieh Wang, Youchang Li, Hong-Yi Chen, and Chi-Hsin Yang. "Affective-Blue Design Methodology for Product Design Based on Integral Kansei Engineering." Mathematical Problems in Engineering 2022 (April 27, 2022): 1–12. http://dx.doi.org/10.1155/2022/5019588.

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Sustainable product designs always draw much attention. However, sustainable or green products are usually costly. This contradiction can be solved via blue design. The concept of blue design originates from the blue economy which is a popular strategy for providing sustainable, healthy, but cheap socioeconomic activities. This study innovatively implements the ideas of sustainability and economy from the blue economy, and the affection (or Kansei in Japanese) from the Kansei engineering into a product design process to become a novel affective-blue design methodology of a product form. The proposed methodology mainly contains three aspects. The first aspect is the merge of a novel Kansei blue model with the traditional Kansei engineering to deal with the semantic space and form decomposition issues encountered in the product form designing process. The second aspect is the adoption of proper data mining schemes to optimally trim and obtain the kernel information from the Kansei evaluation data of products. The third aspect is the usage of appropriate machine learning schemes to establish a precise relationship between product images and design elements from the kernel information. A case study was conducted for the form design of a computer-numerical-control lathe to evaluate the effectiveness of our proposed methodology. The verification results, that all predictive errors are within 4.5% for test samples, show that our blue-affective design methodology is quite satisfying. Through applying this proposed methodology, designers may correctly evaluate and easily catch the essential blue and affective design factors for designing a good industrial product, such as a computer-numerical-control machine tool.
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18

Azman, M. A., M. R. M. Asyraf, A. Khalina, Michal Petrů, C. M. Ruzaidi, S. M. Sapuan, W. B. Wan Nik, M. R. Ishak, R. A. Ilyas, and M. J. Suriani. "Natural Fiber Reinforced Composite Material for Product Design: A Short Review." Polymers 13, no. 12 (June 9, 2021): 1917. http://dx.doi.org/10.3390/polym13121917.

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Natural fibers have attracted great attention from industrial players and researchers for the exploitation of polymer composites because of their “greener” nature and contribution to sustainable practice. Various industries have shifted toward sustainable technology in order to improve the balance between the environment and social and economic concerns. This manuscript aims to provide a brief review of the development of the foremost natural fiber-reinforced polymer composite (NFRPC) product designs and their applications. The first part of the manuscript presents a summary of the background of various natural fibers and their composites in the context of engineering applications. The behaviors of NFPCs vary with fiber type, source, and structure. Several drawbacks of NFPCs, e.g., higher water absorption rate, inferior fire resistance, and lower mechanical properties, have limited their applications. This has necessitated the development of good practice in systematic engineering design in order to attain optimized NRPC products. Product design and manufacturing engineering need to move in a mutually considerate manner in order to produce successful natural fiber-based composite material products. The design process involves concept design, material selection, and finally, the manufacturing of the design. Numerous products have been commercialized using natural fibers, e.g., sports equipment, musical instruments, and electronic products. In the end, this review provides a guideline for the product design process based on natural fibers, which subsequently leads to a sustainable design.
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19

Hinckeldeyn, Johannes, Rob Dekkers, and Jochen Kreutzfeldt. "Productivity of product design and engineering processes." International Journal of Operations & Production Management 35, no. 4 (April 2, 2015): 458–86. http://dx.doi.org/10.1108/ijopm-03-2013-0101.

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Purpose – Maintaining and improving productivity of product design and engineering processes has been a paramount challenge for design-driven companies, which are characterised a high degree of development of products and processes in order to meet particular customer requirements. Literature on this issue is fragmented and dispersed and a concise and systematic overview is lacking. Hence, it remains unclear, which methods are applicable for design-driven companies to improve the productivity of limitedly available engineering resources (a challenge companies and nations face currently). The purpose of this paper is to develop such a systematic overview. Design/methodology/approach – An unusual approach was utilised by combining the outcomes from a systematic literature review and the results of a Delphi study. From both research approaches complementary and overlapping methods for improving the productivity of product design and engineering processes could be drawn. Findings – The unique systematic overview presents 27 methods to increase the productivity, effectiveness and efficiency of product design and engineering processes of design-driven companies. Moreover, the study finds that methods for improving effectiveness are preferred over methods for improving efficiency and that limitations with regard to the availability of resources are often not considered. Research limitations/implications – During the development of the systematic overview, a lack of empirical evidence to assess the actual impact of productivity improvement methods was discovered. This shortcoming demonstrates the need for more conceptual and empirical work in this domain. More studies are needed to test and confirm the usefulness of the proposed methods. Practical implications – Nevertheless, design-driven companies, which struggle to increase the productivity of their product design and engineering processes, can systematically select improvement methods from the overview according to their impact on productivity, effectiveness and efficiency. However, companies should keep in mind, whether effectiveness of product design and engineering can really be increased without considering limitations in engineering resources. Originality/value – Therefore, the systematic overview provides a valuable map of the unexplored territory of productivity improvement methods for product design and engineering for both practitioners and researchers. For the latter ones, it creates directions for empirical investigations in order to explore and to compare methods for the improvement of productivity of product design and engineering processes.
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20

Niu, Xiaojing, Shengfeng Qin, Haizhu Zhang, Meili Wang, and Rose Wong. "Exploring product design quality control and assurance under both traditional and crowdsourcing-based design environments." Advances in Mechanical Engineering 10, no. 12 (December 2018): 168781401881439. http://dx.doi.org/10.1177/1687814018814395.

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Small and medium-sized enterprises face the challenges that they do not have enough employees and related resources to produce high-quality products with limited budget and time. The emergence of crowdsourcing provides an opportunity for them to improve their products by leveraging the wisdom of a large community of crowds, including their potential customers. With this new opportunity, product design could be conducted partially in a traditional design environment (in-house design) and partially in a crowdsourcing environment. This article focuses on product design stages to investigate what key factors affect product design quality and how it can be controlled and assured. First, we define the concept of product design quality and then identify its attributes and sub-attributes. Second, we separately survey key factors affecting product design quality in traditional and crowdsourcing-based design environments, quality control approaches/theories and quality assurance policies in traditional design environment. Third, a comparison of product design quality issues between the traditional and crowdsourcing-based design environments is progressed focusing on various aspects influencing product design activity quality. Finally, we discuss product design quality control approaches and quality assurance policies, quality control challenges and corresponding solutions in crowdsourcing-based design environment.
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21

Zhang, Xin, and Shan Shan Wang. "Rearview Mirror Product Design Based on Reverse Engineering Technology." Advanced Materials Research 834-836 (October 2013): 1723–27. http://dx.doi.org/10.4028/www.scientific.net/amr.834-836.1723.

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Product design is successful or not, not only from the aspects of design concepts, ideas, manufacturability, cost and benefit considerations, the most important depends on the customer satisfaction after products is throw on the market. Many products only from the point of view of design are impeccable, but the user feedback is not good, in order to meet the demands of the market need, you need to constantly improve and innovate. For a certain brand rearview mirror product user feedback, the design of crank connecting part curvature has been modified using reverse technology.
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22

Francalanza, Emmanuel, Jonathan Borg, Alec Fenech, and Philip Farrugia. "Emotional Product Design: Merging industrial and engineering design perspectives." Procedia CIRP 84 (2019): 124–29. http://dx.doi.org/10.1016/j.procir.2019.03.263.

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23

Liu, H. G., Rong Mo, Qing Ming Fan, Zhi Yong Chang, and Y. Zhao. "A Fuzzy Set AHP-Based DFM Tool under Concurrent Engineering Environment." Applied Mechanics and Materials 10-12 (December 2007): 145–49. http://dx.doi.org/10.4028/www.scientific.net/amm.10-12.145.

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In the light of growing global competition, organizations around the world today are constantly under pressure to produce high-quality products at an economical price. The integration of design and manufacturing activities into one common engineering effort has been recognized as a key strategy for survival and growth. Design for manufacturability (DFM) is an approach to design that fosters the simultaneous involvement of product design and process design. The implementation of the DFM approach requires the collaboration of both the design and manufacturing functions within an organization. At present, For some reasons DFM approach is ineffectively including lack of interdisciplinary expertise of designers; inflexibility in organizational structure, which hinders interaction between design and manufacturing functions. Design for manufacture is the practice of designing products with manufacturing in mind. Early consideration of manufacturing issues can shorten product development cycle time, minimi overall development cost and ensure a smooth transition into production. In this paper, part manufacturability under Concurrent Engineering (CE) environment was analyzed in detail. An evaluation system of DFM was proposed according to CE ideas. A fuzzy set-based manufacturability evaluation algorithm is formulated to generate relative manufacturability indices to provide product designers with a better understanding of the relative ease or difficulty of machining the features in their designs. An analytic hierarchy process (AHP) method is introduced to assign weighting factors to features to reflect their functional importance. Results from the case studies show the method available and practicable.
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24

Zubarev, Yu M., N. N. Solntsev, A. V. Weber, V. N. Vedenov, and V. A. Barsukov. "ENGINEERING OF DESIGN AND TECHNOLOGICAL PREPARATION OF PRODUCTION." Spravochnik. Inzhenernyi zhurnal, no. 297 (December 2021): 28–31. http://dx.doi.org/10.14489/hb.2021.12.pp.028-031.

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The article deals with issues related to ensuring the quality of products and their reliability, which is provided, starting from the preliminary design, design, modeling, production and disposal. Thus, the reliability of the product design is evaluated at all stages of its life cycle. Two main periods of the life cycle are considered – the development and modeling of new products, the second - its development, production and implementation. When mastering the production of new equipment, an important place is given to the formation and development of technologies that also have their own life cycle and affect the profit and competitiveness of the manufactured product.
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25

Wen, Bang Chun, Xiao Peng Li, Shu Ying Liu, Wei Zhou Wang, and Zong Yan Wang. "Design Planning and Top-Layer Design of Products." Applied Mechanics and Materials 365-366 (August 2013): 1259–65. http://dx.doi.org/10.4028/www.scientific.net/amm.365-366.1259.

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The A new design method of the products named Top-layer Design has been proposed in this paper. From the view of the point of the system engineering, the planning of product design makes the product design qualities improve to a great extent. Besides the understanding of the client requirements, the design planning of products, the so-called 7Ds: Design ideas, Design environments, Design objective, Design process, Design contents, Design methods and the Design quality evaluation, should be considered completely and planned systematically.
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26

Wang, Shan, and Jing Ping Liu. "Concurrent Engineering and its Key Technologies of Product Design." Advanced Materials Research 510 (April 2012): 380–83. http://dx.doi.org/10.4028/www.scientific.net/amr.510.380.

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Under the intense market environment, concurrent engineering is considered to be an effective method to improve product competitiveness by more and more enterprises. As a new product development mode, it directly accelerates the design process of new products. Based on introducing the basic concepts of concurrent engineering, this paper discussed its key technologies in detail, such as process reconfiguration, DFX, PDM, CAX and TQM.
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27

Lou, Xi Yin. "Study on the Development Model of Green Products Based on Concurrent Engineering." Advanced Materials Research 1037 (October 2014): 540–43. http://dx.doi.org/10.4028/www.scientific.net/amr.1037.540.

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concurrent engineering product development from the beginning of the design requirements, it must consider the various factors in the product life cycle, to shorten product development cycle, improve product quality, reduce the green characteristics of product cost, product realization, enhancing the competition ability of the enterprise purpose. Because in the whole process of product lifecycle highly concurrent engineering station, effect that participants work together, reconstruction of product development process and using advanced design methods, contributes to the technical information, economic information, environmental information, energy and resource information and insurance information of organic integration of each stage in the life cycle of product green design, the realization of green products from a life-cycle perspective. Therefore, the concurrent engineering is the core of the design and development of green products.
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28

Aikhuele, Daniel. "A Study of Product Development Engineering and Design Reliability Concerns." International Journal of Applied Industrial Engineering 5, no. 1 (January 2018): 79–89. http://dx.doi.org/10.4018/ijaie.2018010105.

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This article explores the evolution of product development engineering by providing an overview of the different developmental stages from a historical perspective. Furthermore, design reliability evaluation which is a key component of product development engineering processes is studied by reflecting and providing guidance on how to sort and assess reliability information early at the product design stage, as well as how to account for flexibility and expert's attitudinal character (information), which have been found critical in the assessment of engineering products reliability.
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29

Li, Xiao Peng, Zhao Hui Ren, Wei Sun, C. F. Li, and Bang Chun Wen. "Harmonious Design Method for Product Development." Advanced Materials Research 44-46 (June 2008): 697–702. http://dx.doi.org/10.4028/www.scientific.net/amr.44-46.697.

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With the development of science and technology, harmonious design will be one of the latest trends in modern mechanical products development. Based on the harmonious design method, the well synthesized quality products will be invented. It will have little negative influence on society and the natural environment, and the high utilization rate of resources and the most comprehensive benefits in the full lifecycle from planning, designing, manufacturing, packaging, and discarded. The harmonious state can be obtained between products with political, economic, cultural, legal, scientific, natural and social environments. The harmonious design is investigated from the harmony of design methods; the harmony of product function with performance; and the harmony of product with product, with human, with technology, with society environment and with natural environment. And the evaluation of harmonious degree and management system are studied in this work, too. Based on system engineering and economic, cultural, legal, scientific, natural and social environment factors, the formula of the complete system of products design is established. Therefore, the new vitality and higher market competitiveness of product can be achieved. Not only the design is for human but also for nature, for the harmony of human and nature.
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Wen, Bang Chun, Xiao Peng Li, Gui Qiu Song, and Zong Yan Wang. "Top-Layer Design and Systematic Design of Products." Applied Mechanics and Materials 121-126 (October 2011): 1164–76. http://dx.doi.org/10.4028/www.scientific.net/amm.121-126.1164.

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The A new design method of the products named “Systematize Design” has been advanced in this paper. From the view of the point of the system engineering, the planning of product design makes the product design qualities improve to a great extent. Besides the understanding of the client requirements, the design planning of products, the so-called 7D’s: Design ideas, Design environments, Design objective, Design process, Design contents, Design methods and the Design quality evaluation, should be considered completely and planned systematically. Based on the previous work, the product design should be conducted according to the systematic design method. The paper makes a detailed expatiation of the systematic design method, viz. 1+3+X design method, in which 1 represents the optimal design for product functions, 3 means the design method synthesizing the dynamic optimization, intelligent optimization and visualized optimization combined organically, and X is the design method for the special requirements of the products.
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Liu, Hong Jun, Xiao Yan Tong, Sheng Li Lv, and Qing Ming Fan. "Design for Manufacture and Integrated Manufacturability Evaluation System." Advanced Materials Research 476-478 (February 2012): 2567–70. http://dx.doi.org/10.4028/www.scientific.net/amr.476-478.2567.

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In the light of growing global competition, organizations around the world today are constantly under pressure to produce high-quality products at an economical price. The integration of design and manufacturing activities into one common engineering effort has been recognized as a key strategy for survival and growth. Design for manufacturability (DFM) requires product designers to simultaneously consider the manufacturing issues of a product along with the geometrical and design aspects. In this paper, part manufacturability was analyzed in detail. An evaluation system of DFM was proposed. Product design can be guided according to feedback information by evaluating the part manufacturability.
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32

Brunsmann, Jörg, and Wolfgang Wilkes. "Enabling Product Design Reuse by Long-term Preservation of Engineering Knowledge." International Journal of Digital Curation 4, no. 3 (December 7, 2009): 17–28. http://dx.doi.org/10.2218/ijdc.v4i3.114.

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In the highly competitive engineering industry, product innovations are created with the help of a product lifecycle management (PLM) tool chain. In order to support fast-paced product development, a major company goal is the reuse of product designs and product descriptions. Due to the product’s complexity, the design of a product not only consists of geometry data but also of valuable engineering knowledge that is created during the various PLM phases. The need to preserve such intellectual capital leads engineering companies to introduce knowledge management and archiving their machine-readable formal representation. However, archived knowledge is in danger of becoming unusable since it is very likely that knowledge semantics and knowledge representation will evolve over long time periods, for example during the 50 operational years of some products. Knowledge evolution and knowledge representation technology changes are crucial issues since a reuse of the archived product information can only be ensured if its rationale and additional knowledge are interpretable with future software and technologies. Therefore, in order to reuse design data fully, knowledge about the design must also be migrated to be interoperable with future design systems and knowledge representation methods. This paper identifies problems, issues, requirements, challenges and solutions that arise while tackling the long-term preservation of engineering knowledge.
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33

Li, Jia, Yun Bing Yang, and Fa Yuan Wei. "Knowledge Based Engineering in Complicated Product Design." Advanced Materials Research 466-467 (February 2012): 1135–39. http://dx.doi.org/10.4028/www.scientific.net/amr.466-467.1135.

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Under the tendency of knowledge economy in the world, knowledge research becomes a hot subject. The analysis about the meanings, categories and characteristics of knowledge is presented at first. The concept and key techniques of Knowledge Based Engineering (KBE) are discussed. The differences and relationships among KBE, Expert System (ES) and CAD/CAE/CAPP/CAM (CAX) Systems are analyzed as well. An example on knowledge-based designing of one complicated product is provided. A product knowledge base is established by analyzing the structure and characteristics of product design knowledge. Product knowledge integration and management is fulfilled using Product Data Management (PDM) and dynamic database technique.
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34

Chapman, Lisa Parrillo, and Trevor Little. "Textile design engineering within the product shape." Journal of the Textile Institute 103, no. 8 (August 2012): 866–74. http://dx.doi.org/10.1080/00405000.2011.615491.

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35

Levy, S., J. H. DuBois, and H. Saunders. "Plastics Product Design Engineering Handbook (2nd Ed.)." Journal of Vibration and Acoustics 108, no. 1 (January 1, 1986): 112. http://dx.doi.org/10.1115/1.3269296.

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36

Karthik, K., and K. Janardhan Reddy. "Engineering Changes in Product Design - A Review." IOP Conference Series: Materials Science and Engineering 149 (September 2016): 012001. http://dx.doi.org/10.1088/1757-899x/149/1/012001.

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37

Mahmud, J. O., M. S. Mohd Ismail, and J. Mohd Taib. "Engineering Education and Product Design: Nigeria's Challenge." Procedia - Social and Behavioral Sciences 56 (October 2012): 679–84. http://dx.doi.org/10.1016/j.sbspro.2012.09.703.

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38

Wang, Shi Gang, Ze Xing Liu, and Xue Shan Gao. "The Innovative Product Design with Combining Engineering Science and "UCD"." Applied Mechanics and Materials 713-715 (January 2015): 255–58. http://dx.doi.org/10.4028/www.scientific.net/amm.713-715.255.

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This article propose a new design pattern with combining engineering science and "user-centered design". For the purpose of finding a new pattern to design a new product to meet the user needs, and to adapt the update rate of products under large industrial environments. This article through summarize and analyze the shortcoming of “user-centered” design pattern, and point out the significance of engineering science in product design. Finally the new pattern with combining engineering science and “user-centered design” has been proposed. Using this pattern to redesign the traditional pump, the result show that the new pump is efficient and fit for using than before, so the new design pattern could make sure the products meet the user needs and adapt the update rate of products.
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39

Guo, Heng Ya. "Plastic Mould Design Optimization Method Research Based on the Reverse Engineering Technology." Applied Mechanics and Materials 278-280 (January 2013): 2261–64. http://dx.doi.org/10.4028/www.scientific.net/amm.278-280.2261.

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Reverse engineering technology has been rapid development in complex product manufacturing sector because of its high efficiency and precision,etc. Compared with the traditional plastic mould CAD technology, using reverse engineering technology can further shorten product design cycle, improve the design efficiency of development, and it is the technical inheritance, application, reference and innovation product design to the existing product . This article integrated applies the reverse engineering technology to achieve product optimization design and corresponding plastic mold development based on the actual example.This technique can reduce the product design time, avoid repetition design, reduce the number of design and processing time, reduce the cost of each link, and can significantly improve the economic benefit of products.
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40

de Vere, Ian, Gavin Melles, and Ajay Kapoor. "Product design engineering – a global education trend in multidisciplinary training for creative product design." European Journal of Engineering Education 35, no. 1 (November 5, 2009): 33–43. http://dx.doi.org/10.1080/03043790903312154.

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41

Politis, John L., and Steven B. Shooter. "Enhancing Engineering Education." Industry and Higher Education 15, no. 5 (October 2001): 341–47. http://dx.doi.org/10.5367/000000001101295876.

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The Bucknell University Small Business Development Center (SBDC), home of the Product Development Center (PDC), assists inventors and small firms in transforming their ideas into marketable products. The PDC combines traditional management services with the resources and expertise of a top-notch engineering department. The PDC provides assistance on various types of projects, including product design, prototype development, product testing, feasibility analysis, and process improvements. In response to the increasing demand for these services, the PDC has increased the number of engineering students employed in the Center. Since the SBDC is housed in the College of Engineering, students and engineering faculty work closely with industry counterparts in the design and development of new products. The Stage-GateTM process has been successfully implemented to create a multidisciplinary team approach to product development. The results have been remarkable, with measurable benefit to the College's educational mission and to private enterprise. This paper highlights the Bucknell University Product Development Center and how industry and education can collaborate most effectively to achieve excellent results.
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Qin, Jian Jun, Yan An Yao, and Jian Wei Yang. "A User-Engineering Design Interaction Supporting Rational Product Cooperative Design." Applied Mechanics and Materials 155-156 (February 2012): 51–55. http://dx.doi.org/10.4028/www.scientific.net/amm.155-156.51.

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To input rational customer requirements into engineering design process more effectively and improve product design quality and market response efficiency, this paper focuses on the interaction between market analysis and engineering design decision for the modular product. While many researchers have successful evaluated and optimized the design schemes, few, if any, have provided a bridge the customer selection and firms product development decision. After a review of the literature we introduce the flow of user-engineering design interaction including both maximize the utility of customer and the profit of the firm. On the user and market analysis flow, customer requirements are defined according to the target market, then the customer selection possibility link to the product attributes by utility function. Accordingly, the alternatives are corresponding to the module different product, and then using decision support problem method to search the optimal design parameters. Two design domains can share the design information and realize the cooperative design process by computer computing platform.
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Zafirova, Koleta. "Total design for textile products." Chemical Industry 58, no. 4 (2004): 161–64. http://dx.doi.org/10.2298/hemind0404161z.

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Product development is less than 20-30 years old and a relatively new area of research compared to the other classic academic disciplines. Integrated product development is a philosophy that systematically employs the teaming of functional disciplines to integrate and concurrently apple all the necessary processes to produce an effective and efficient product that satisfies customer needs. Product development might also be understood as a multidisciplinary field of research. The disciplines directly participating in product development include engineering design, innovation, manufacturing, marketing and management. A background contribution is also generated by disciplines such as psychology, social sciences and information technology. This article is an overview that introduces this philosophy to textile product development.
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Aksoy, Günseli, Christian Raulf, and Thomas Vietor. "A Model-Based Design Method for the Correlation between Customer Feedback and Technical Design Parameters in the Context of Systems Engineering." Modelling 2, no. 4 (December 15, 2021): 795–820. http://dx.doi.org/10.3390/modelling2040042.

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Nowadays considering trends such as digitalization, automated driving as well as electric mobility in products in automotive development processes is a major challenge, which has led to an enormous increase in the number of product functions of technical systems. However, the recognized processes in automotive development are strongly component-oriented and such processes partially support the development of product functions. In order to meet future trends and ensure long term customer satisfaction, a transfer from component-oriented to function-oriented development is necessary. Accordingly, a holistic concept can be useful that enables the integration of customer feedback into the early phase of product development in the context of function-orientation. However, the customer feedback evaluation and their mapping with technical subsystems have been considered mainly in the context of component-oriented development. In this contribution, a method is proposed, which is generated in the context of a product model of product generation engineering. Product Generation Engineering enables the structuring of the development process of a product generation and supports function-oriented development. The Product Model provides customer- oriented development of mechatronic products. The proposed method is achieved in the sense of model-based systems engineering and validated by the exemplarily application of a case study of a specific vehicle. Both the past and current product generations of the specific vehicle are taken into account in the development of the subsequent product generation.
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Li, Xiang, and Jun Min Huang. "Application Research of Industrial Design Based on ALIAS Reverse Engineering." Applied Mechanics and Materials 651-653 (September 2014): 1531–34. http://dx.doi.org/10.4028/www.scientific.net/amm.651-653.1531.

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The product design of curved surface shape is fashionable in current industrial design region. Reverse engineering is one of the most frequently-used CAID methods in current industrial design. This article introduces the specific steps to do reverse engineering design applying to ALIAS software, emphasizes that the combination of reverse engineering and NC manufacturing technology or RP technology can greatly shorten the product developing and researching period of the enterprise so as to produce opportunity for new product to enter the market and bring huge economical benefit for enterprise. It is deeply paid attention by manufacturing industry.
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Sutono, Sugoro Bhakti, Zahari Taha, Salwa Hanim Abdul Rashid, Hideki Aoyama, and Subagyo Subagyo. "Application of Robust Design Approach for Design Parameterization in Kansei Engineering." Advanced Materials Research 479-481 (February 2012): 1670–80. http://dx.doi.org/10.4028/www.scientific.net/amr.479-481.1670.

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Nowadays, consumers have become more selective in choosing products not only deciding based on its functionality and its value but also on its aesthetic and emotional value. Aesthetic and emotional values have thus become important aspects in the success of a product in a competitive market. Consequently, recognizing the primary parameters used to generate combinative product shape which has the ability to evoke a particular emotion should be given strong consideration. This paper describes the application of robust design approach which allows the designer to determine the optimal design parameters to obtain form impression evoked by a product shape feature. A Taguchi’s orthogonal array method is applied to design the experiment and is analyzed to obtain the optimal parameters for each factor. ANOVA is then employed to identify the most significant factors. A Taguchi’s L18orthogonal array was adopted for an experiment on the design of an office chair. The case study contains six three-level factors, and 18 different combinative design samples created from shape parameters. The results of the experiment shows that it is possible to create a design support system that can facilitates the designer in the creative process by suggesting shape parameters relating to a specific form impression.
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Liu, Hong Jun, Xiao Yan Tong, and Sheng Li Lv. "A Fuzzy Set AHP-Based Design for Manufacture Method." Advanced Materials Research 548 (July 2012): 461–64. http://dx.doi.org/10.4028/www.scientific.net/amr.548.461.

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In the light of growing global competition, organizations around the world today are constantly under pressure to produce high-quality products at an economical price. The integration of design and manufacturing activities into one common engineering effort has been recognized as a key strategy for survival and growth. Design for manufacturability (DFM) requires product designers to simultaneously consider the manufacturing issues of a product along with the geometrical and design aspects. In this paper, part manufacturability was analyzed in detail. An evaluation system of DFM was proposed. Product design can be guided according to feedback information by evaluating the part manufacturability.
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Quan, Huafeng, Shaobo Li, and Jianjun Hu. "Product Innovation Design Based on Deep Learning and Kansei Engineering." Applied Sciences 8, no. 12 (November 26, 2018): 2397. http://dx.doi.org/10.3390/app8122397.

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Creative product design is becoming critical to the success of many enterprises. However, the conventional product innovation process is hindered by two major challenges: the difficulty to capture users’ preferences and the lack of intuitive approaches to visually inspire the designer, which is especially true in fashion design and form design of many other types of products. In this paper, we propose to combine Kansei engineering and the deep learning for product innovation (KENPI) framework, which can transfer color, pattern, etc. of a style image in real time to a product’s shape automatically. To capture user preferences, we combine Kansei engineering with back-propagation neural networks to establish a mapping model between product properties and styles. To address the inspiration issue in product innovation, the convolutional neural network-based neural style transfer is adopted to reconstruct and merge color and pattern features of the style image, which are then migrated to the target product. The generated new product image can not only preserve the shape of the target product but also have the features of the style image. The Kansei analysis shows that the semantics of the new product have been enhanced on the basis of the target product, which means that the new product design can better meet the needs of users. Finally, implementation of this proposed method is demonstrated in detail through a case study of female coat design.
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Isa, Indra Griha Tofik. "Kansei Engineering Approach in Software Interface Design." Journal of Science Innovare 1, no. 01 (March 13, 2018): 22–26. http://dx.doi.org/10.33751/jsi.v1i01.680.

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User satisfaction is a major factor in designing a product. Technically it can be realized explicitly how the product is designed according to the needs of its users. There are other factors that influence the success of the product, the psychological value of the user who can implicitly become a parameter in product design. But the thing that becomes a constraint is how to translate these psychological factors into the parameters of product design. Kansei Engineering (KE) is one approach in product design that involves the user's psychological side and how to translate the cognitive aspects of the user into the product of the design proposal. The KE methods, the one discussed in this study, is Kansei Engineering Type 1 (KEPack), which involves several multivariate analyzes. The conclusion of this research is how KE in designing a product, not only industrial product, but KE can be involved in matters related to Human Computer Interaction, especially interface design. Keywords: Product Development, Kansei Engineering, Kansei Engineering Type 1 (KEPack)
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Суслов, Анатолий, and Anatoliy Suslov. "Engineering product quality control at all stages of product life." Science intensive technologies in mechanical engineering 2018, no. 3 (February 22, 2018): 22–25. http://dx.doi.org/10.12737/article_5a8ef9cce19d80.89624845.

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In the paper it is shown that at quality control of engineering products particular attention should be paid to engineering and technological measures which exert basic influence upon assurance and quality increase. Technical and technological measures are shown at all stages of product life: marketing; design; technological pre-production; manufacturing materials, blanks, parts and their assembly; operation; repair and utilization. It is emphasized that still at the preliminary stages it is necessary that a factor of competitive ability of a product designed should be defined. It is shown convincingly that engineering product quality is formed at the stage of design and ensured at the stage of manufacturing. The realization of measures shown in the paper allows ensuring high-quality competitive engineering product manufacturing at enterprises.
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