Abstract
Additive manufacturing has attracted increasing attention worldwide, especially in the healthcare, biomedical, aerospace, and construction industries. In Malaysia, insufficient acceptance of this technology by local industries has resulted in a call for government and local practitioners to promulgate the development of this technology for various industries, particularly for biomedical products. The current study intends to frame the challenges endured by biomedical industries who use 3D printing technology for their manufacturing processes. Qualitative methods, particularly in-depth interviews, were used to identify the challenges faced by manufacturing firms when producing 3D printed biomedical products. This work was able to identify twelve key challenges when deploying additive manufacturing in biomedical products and these include issues related to binder selection, poor mechanical properties, low-dimensional accuracy, high levels of powder agglomeration, nozzle size, distribution size, limited choice of materials, texture and colour, lifespan of materials, customization of fit and design, layer height, and, lastly, build-failure. Furthermore, there also are six challenges in the management of manufacturing biomedical products using 3D printing technology, and these include staff re-education, product pricing, limited guidelines, cyber-security issues, marketing, and patents and copyright. This study discusses the reality faced by 3D printing players when producing biomedical products in Malaysia, and presents a primary reference for practitioners in other developing countries.
Highlights
Additive manufacturing (AM), known as 3D printing involves use of digital computer-aided drafting (CAD) modelling to build 3D objects by joining materials layer-by-layer [1]
This study has developed a conceptual framework related to the challenges faced by 3D printing technology based on previous studies
Materials Several challenges were identified after the interview sessions, with a primary focus on the selection of suitable binders, which vary according to the types of products
Summary
Additive manufacturing (AM), known as 3D printing involves use of digital CAD modelling to build 3D objects by joining materials layer-by-layer [1]. The future demand for this technology lies in its capability to perform different print functions and "print-it-all" structures. These functions are progressively perceived as the driving force for researchers and practitioners even though 3D printing technology has seen significant developments in the last three decades [2]. This technology has widely been applied towards the agricultural, biomedical, automotive, and aerospace industries [3]. The different methodologies used for additive manufacturing in the industry include fused deposition modelling (FDM), stereolithography (SLA), selective laser sintering (SLS), and bioprinting [5]
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