Transitioning additive manufacturing from rapid prototyping to high‐volume production: A case study of complex final products

Roscoe, Samuel; Cousins, Paul D.; Handfield, Robert

doi:10.1111/jpim.12673

Cited by 6 publications

(2 citation statements)

References 54 publications

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“…In addition to influencing product design, additive manufacturing technology affords a high degree of customization for products [39]. Rapid prototyping and other processing techniques accelerate the product development cycle, thereby reducing the costs associated with design iterations [40]. The findings of this cluster emphasize that, in the Industry 4.0 era, significant attention should be directed toward the application of intelligent materials and innovative technologies like additive manufacturing in industrial design.…”

Section: Cluster 3: Additive Manufacturing and Materials Processesmentioning

confidence: 94%

Charting the Path of Technology-Integrated Competence in Industrial Design during the Era of Industry 4.0

Zhang,

Chen

et al. 2024

Sustainability

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The fusion of emerging technologies with industrial design has catalyzed a fundamental shift in the aesthetics, user experiences, and service frameworks of products in the Industry 4.0 era. Simultaneously, this convergence has heightened the demands placed on the technological integration competencies of designers. Consequently, there exists a necessity to articulate a precise developmental trajectory for proficiency in industrial design that incorporates these novel technologies. This study initiates with a bibliometric analysis to quantify the scholarly literature relevant to this research domain. Subsequently, leveraging the insights from this analysis, semi-structured interviews were conducted with 15 experts spanning the United States, Europe, South Korea, and China. Our conclusions show the following: (1) Co-word analysis and cluster analysis techniques are applied to identify 80 technologies and four technological clusters that demonstrate strong associations with industrial design in the Industry 4.0 era. (2) Employing coding techniques and thematic analysis, four distinct skill domains emerge for technology-integrated industrial design: Industrial Design Skills, Industrial Design Knowledge, Ethical Considerations in Industrial Design, and Industrial Design Industry Insight. Furthermore, a limitation that affects these competencies is identified. (3) A recommended methodology for assessing these competencies is proposed. This study represented an expansion upon existing industrial design competencies. The empirical data generated herein serves as a valuable resource for practitioners and educators within the field of industrial design. Furthermore, it provides a theoretical groundwork for future models addressing technology-infused industrial design capabilities.

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Section: Cluster 3: Additive Manufacturing and Materials Processesmentioning

confidence: 94%

Charting the Path of Technology-Integrated Competence in Industrial Design during the Era of Industry 4.0

Zhang,

Chen

et al. 2024

Sustainability

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“…While BJAM and other additive manufacturing processes have been widely used for rapid prototyping [ 13 , 14 ], some of its constraints revolve around reliability and control [ 15 , 16 ]. Compared to subtractive manufacturing procedures, AM creates objects with poor surface smoothness [ 9 , 17 ].…”

Section: Introductionmentioning

confidence: 99%

Machine Learning-Enabled Quantitative Analysis of Optically Obscure Scratches on Nickel-Plated Additively Manufactured (AM) Samples

Mengesha,

Grizzle,

Demisse

et al. 2023

Materials

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Additively manufactured metal components often have rough and uneven surfaces, necessitating post-processing and surface polishing. Hardness is a critical characteristic that affects overall component properties, including wear. This study employed K-means unsupervised machine learning to explore the relationship between the relative surface hardness and scratch width of electroless nickel plating on additively manufactured composite components. The Taguchi design of experiment (TDOE) L9 orthogonal array facilitated experimentation with various factors and levels. Initially, a digital light microscope was used for 3D surface mapping and scratch width quantification. However, the microscope struggled with the reflections from the shiny Ni-plating and scatter from small scratches. To overcome this, a scanning electron microscope (SEM) generated grayscale images and 3D height maps of the scratched Ni-plating, thus enabling the precise characterization of scratch widths. Optical identification of the scratch regions and quantification were accomplished using Python code with a K-means machine-learning clustering algorithm. The TDOE yielded distinct Ni-plating hardness levels for the nine samples, while an increased scratch force showed a non-linear impact on scratch widths. The enhanced surface quality resulting from Ni coatings will have significant implications in various industrial applications, and it will play a pivotal role in future metal and alloy surface engineering.

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Application of Artificial Intelligence in Aerospace Engineering and Its Future Directions: A Systematic Quantitative Literature Review

Hassan,

Thakur,

Singh

et al. 2024

Arch Computat Methods Eng

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Transitioning additive manufacturing from rapid prototyping to high‐volume production: A case study of complex final products

Cited by 6 publications

References 54 publications

Charting the Path of Technology-Integrated Competence in Industrial Design during the Era of Industry 4.0

Charting the Path of Technology-Integrated Competence in Industrial Design during the Era of Industry 4.0

Machine Learning-Enabled Quantitative Analysis of Optically Obscure Scratches on Nickel-Plated Additively Manufactured (AM) Samples

Application of Artificial Intelligence in Aerospace Engineering and Its Future Directions: A Systematic Quantitative Literature Review

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