The Perceived Value of Additively Manufactured Digital Spare Parts in the Industry: An Empirical Investigation

Chekurov, Sergei; Metsä-Kortelainen, Sini; Salmi, Mika; Roda, Irene; Jussila, Ari

doi:10.1007/978-3-030-20704-5_16

Cited by 2 publications

(4 citation statements)

References 52 publications

(65 reference statements)

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“…Furthermore, the design initiates with the assumption that a digital model of the spare part exists or can be easily obtained. However, in practice, the design file may be unavailable (since it is the intellectual property of the supplier), nonexistent (as is often the case for obsolete spare parts), or insufficient (like in the case of 2D drawings) (Chekurov, Metsä‐Kortelainen, Salmi, Roda, & Jussila, ). In addition, new products require various product development activities, for example, master data, performance testing, and validation (Krishnan & Ulrich, ).…”

Section: Discussionmentioning

confidence: 99%

Assessing the potential of additive manufacturing for the provision of spare parts

Heinen

Hoberg

2019

J of Ops Management

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Spare parts are a particularly interesting application for switching production from traditional manufacturing (TM) to additive manufacturing (AM). Research assessing AM has primarily addressed cost models centering on the production process or the operations management of separate spare parts. By combining case study, modeling, and design science elements, we adopt a holistic perspective and develop a design to examine the systematic leverage of AM in spare parts operations. Contextually grounded in problems faced by a leading material handling equipment manufacturer that is challenged by common characteristics of after‐sales operations, we engage with practice to propose a portfolio level analysis examining the switchover share from TM to AM. Using a data set of 53,457 spare parts over 9 years, we find that up to 8% of stock keeping units (SKUs) and 2% of total units supplied could be produced using AM, even if unit production costs are four times those of TM. This result is driven by low demand, high fixed costs, and minimum order quantities in TM. Finally, we present the evaluation by the case company's management and highlight five areas of opportunity and challenge.

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Section: Discussionmentioning

confidence: 99%

Assessing the potential of additive manufacturing for the provision of spare parts

Heinen

Hoberg

2019

J of Ops Management

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“…The growth of intelligent product development and frameworks using AM has notably accelerated, spanning applications such as antenna structures corresponding electromagnetics in dependence to the components exclusively designed to be additively manufactured [27]; [28]. Various AM methods have been utilized for electromagnetic structures steering, using materials like filament, resin, powder, and nanoparticle inks adaptable to smart composites [27], characterized by lightness and ease of use.…”

Section: Building a Framework For Intelligent Production Managementmentioning

confidence: 99%

“…AM has evolved from a prototyping method to a valuable tool for manufacturing end-use components, presenting unprecedented design freedom and capabilities. However, the advantages of AM currently extend beyond design possibilities, with operational benefits like improved delivery times and reduced manufacturing costs playing an integral role [28]. In optimizing flow-level understanding of systems development opportunities on AM, it is recommended (also by [28] to classify end-user applications based on design case for each category segregated physics, what composite must be manufactured.…”

Section: Building a Framework For Intelligent Production Managementmentioning

confidence: 99%

“…However, the advantages of AM currently extend beyond design possibilities, with operational benefits like improved delivery times and reduced manufacturing costs playing an integral role [28]. In optimizing flow-level understanding of systems development opportunities on AM, it is recommended (also by [28] to classify end-user applications based on design case for each category segregated physics, what composite must be manufactured. In conjunction with AM advancements, artificial neural network algorithms such as learning vector quantization have emerged as potent tools for processing vast data volumes and enhancing system predictive abilities.…”

Section: Building a Framework For Intelligent Production Managementmentioning

confidence: 99%

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Additive manufacturing systems integration

Heilala,

Parchegani,

Piili

2023

IOP Conf. Ser.: Mater. Sci. Eng.

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This research explores real-time database systems’ evolution, focusing on unique features and the addressed challenges. It examines the role of multi-material additive manufacturing quality domain databases in innovation and maintaining standards. It also looks at the challenges of implementing quality manufacturing systems from a technology, organization, and people of European Manufacturing research perspective. The study offers a new perspective on reconfigurable intelligent surfaces with multi-material additive manufacturing with system integration, discussing its applications and digital products’ transformative potential. Enhancing multi-material additive manufacturing capabilities redefines the industries, creating a strong communication culture by adopting quality integration of quality and robotics while exploring the future of mathematics complexity in optimizing manufacturing education. The paper also explains the statistical classification of historical technology in manufacturing engineering education by flagging the platform‘s role of opportunities in secure research collaboration. The manufacturing horizontal is essential for effectively managing the multi-material additive manufacturing system through advanced technology to quality management integration. Certified advanced training and competency development econophysics show the multi-material additive manufacturing systems development influence on the production theories and mechanics of complex electronics. To enable, for example, communication links and cellural multi-material additive manufacturing integrations research for new technologies.

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The Perceived Value of Additively Manufactured Digital Spare Parts in the Industry: An Empirical Investigation

Cited by 2 publications

References 52 publications

Assessing the potential of additive manufacturing for the provision of spare parts

Assessing the potential of additive manufacturing for the provision of spare parts

Additive manufacturing systems integration

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