Binder jet additive manufacturing method to fabricate near net shape crack-free highly dense Fe-6.5 wt.% Si soft magnets

Additive Manufacturing (AM) capabilities in terms of product customization, manufacture of complex shape, minimal time, and low volume production those are very well suited for medical implants and biological models. AM technology permits the fabrication of physical object based on the 3D CAD model through layer by layer manufacturing method. AM use Magnetic Resonance Image (MRI), Computed Tomography (CT), and 3D scanning images and these data are converted into surface tessellation language (STL) file for fabrication. The applications of AM in ophthalmology includes diagnosis and treatment planning, customized prosthesis, implants, surgical practice/simulation, pre-operative surgical planning, fabrication of assistive tools, surgical tools, and instruments. In this article, development of AM technology in ophthalmology and its potential applications is reviewed. The aim of this study is nurturing an awareness of the engineers and ophthalmologists to enhance the ophthalmic devices and instruments. Here some of the 3D printed case examples of functional prototype and concept prototypes are carried out to understand the capabilities of this technology. This research paper explores the possibility of AM technology that can be successfully executed in the ophthalmology field for developing innovative products. This novel technique is used toward improving the quality of treatment and surgical skills by customization and pre-operative treatment planning which are more promising factors.

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Microstructure and high-temperature wear behaviour of Inconel 625 multi-layer cladding prepared on H13 mould steel by a hybrid additive manufacturing method

Journal of Materials Processing Technology ◽

10.1016/j.jmatprotec.2020.117036 ◽

2021 ◽

Vol 291 ◽

pp. 117036

Author(s):

Jingbin Hao ◽

Fangtao Hu ◽

Xiawei Le ◽

Hao Liu ◽

Haifeng Yang ◽

...

Keyword(s):

High Temperature ◽

Additive Manufacturing ◽

Inconel 625 ◽

Wear Behaviour ◽

Manufacturing Method ◽

High Temperature Wear

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Measuring the Complexity of Additive Manufacturing Supply Chains

Volume 2: Additive Manufacturing; Materials ◽

10.1115/msec2017-2871 ◽

2017 ◽

Author(s):

Ardeshir Raihanian Mashhadi ◽

Sara Behdad

Keyword(s):

Supply Chain ◽

Additive Manufacturing ◽

Supply Chains ◽

Product Complexity ◽

Information Theoretic ◽

Manufacturing Method ◽

Management Domain ◽

Information Theoretic Measures ◽

Production Cycles ◽

Supply Planning

Complexity has been one of the focal points of attention in the supply chain management domain, as it deteriorates the performance of the supply chain and makes controlling it problematic. The complexity of supply chains has been significantly increased over the past couple of decades. Meanwhile, Additive Manufacturing (AM) not only revolutionizes the way that the products are made, but also brings a paradigm shift to the whole production system. The influence of AM extends to product design and supply chain as well. The unique capabilities of AM suggest that this manufacturing method can significantly affect the supply chain complexity. More product complexity and demand heterogeneity, faster production cycles, higher levels of automation and shorter supply paths are among the features of additive manufacturing that can directly influence the supply chain complexity. Comparison of additive manufacturing supply chain complexity to its traditional counterpart requires a profound comprehension of the transformative effects of AM on the supply chain. This paper first extracts the possible effects of AM on the supply chain and then tries to connect these effects to the drivers of complexity under three main categories of 1) market, 2) manufacturing technology, and 3) supply, planning and infrastructure. Possible impacts of additive manufacturing adoption on the supply chain complexity have been studied using information theoretic measures. An Agent-based Simulation (ABS) model has been developed to study and compare two different supply chain configurations. The findings of this study suggest that the adoption of AM can decrease the supply chain complexity, particularly when product customization is considered.

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A novel friction and rolling based solid-state additive manufacturing method: Microstructure and mechanical properties evaluation

Materials Today Communications ◽

10.1016/j.mtcomm.2021.103005 ◽

2021 ◽

pp. 103005

Author(s):

Ruishan Xie ◽

Yanchao Shi ◽

Haibin Liu ◽

Shujun Chen

Keyword(s):

Mechanical Properties ◽

Additive Manufacturing ◽

Solid State ◽

Manufacturing Method ◽

Microstructure And Mechanical Properties

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Plasma Metal Deposition for Metallic Materials

10.5772/intechopen.101448 ◽

2021 ◽

Author(s):

Enrique Ariza Galván ◽

Isabel Montealegre Meléndez ◽

Cristina Arévalo Mora ◽

Eva María Pérez Soriano ◽

Erich Neubauer ◽

...

Keyword(s):

Additive Manufacturing ◽

Metal Deposition ◽

Welding Parameters ◽

Matrix Composites ◽

Large Size ◽

Wide Range ◽

Direct Energy ◽

Lightweight Alloys ◽

Near Net Shape ◽

Feedstock Material

Plasma metal deposition (PMD®) is a promising and economical direct energy deposition technique for metal additive manufacturing based on plasma as an energy source. This process allows the use of powder, wire, or both combined as feedstock material to create near-net-shape large size components (i.e., >1 m) with high-deposition rates (i.e., 10 kg/h). Among the already PMD® processed materials stand out high-temperature resistance nickel-based alloys, diverse steels and stainless steels commonly used in the industry, titanium alloys for the aerospace field, and lightweight alloys. Furthermore, the use of powder as feedstock also allows to produce metal matrix composites reinforced with a wide range of materials. This chapter presents the characteristics of the PMD® technology, the welding parameters affecting additive manufacturing, examples of different fabricated materials, as well as the challenges and developments of the rising PMD® technology.

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Thermoplastic 3D Printing-An Additive Manufacturing Method for Producing Dense Ceramics

International Journal of Applied Ceramic Technology ◽

10.1111/ijac.12306 ◽

2014 ◽

Vol 12 (1) ◽

pp. 26-31 ◽

Cited By ~ 66

Author(s):

Uwe Scheithauer ◽

Eric Schwarzer ◽

Hans-Jürgen Richter ◽

Tassilo Moritz

Keyword(s):

Additive Manufacturing ◽

3D Printing ◽

Manufacturing Method

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Anwendungszentrum für additive Fertigung/Center for Applied Additive Manufacturing – Influence of process parameters during high-speed laser direct energy deposition

wt Werkstattstechnik online ◽

10.37544/1436-4980-2021-06-12 ◽

2021 ◽

Vol 111 (06) ◽

pp. 368-371

Author(s):

Sebastian Greco ◽

Marc Schmidt ◽

Benjamin Kirsch ◽

Jan C. Aurich

Keyword(s):

Additive Manufacturing ◽

High Speed ◽

Energy Deposition ◽

Influence Of Process Parameters ◽

Direct Energy Deposition ◽

Additive Fertigung ◽

Powder Bed ◽

High Productivity ◽

Direct Energy ◽

Near Net Shape

Additive Fertigungsverfahren zeichnen sich durch die Möglichkeit der endkonturnahen Fertigung komplexer Geometrien aus. Die geringe Produktivität etablierter Verfahren wie etwa dem Pulverbettverfahren hemmen aktuell den wirtschaftlichen Einsatz additiver Fertigung. Das Hochgeschwindigkeits-Laserauftragschweißen (HLA) soll durch deutlich erhöhte Auftragsraten und somit bisher unerreicht hoher Produktivität bei der additiven Fertigung dazu beitragen, deren Wirtschaftlichkeit zu steigern.   Additive manufacturing enables the near-net-shape production of complex geometries. The low productivity of established processes such as powder bed processes is currently limiting the economic use of additive manufacturing. High-speed laser direct energy deposition (HS LDED) is expected to improve the economic efficiency of additive manufacturing by significantly increasing deposition rates and thus previously unattained high productivity.

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A NOVEL, SCALABLE PRODUCTION OF MULTIFUNCTIONAL NANOCOMPOSITE POLYMER FILAMENTS FOR ADDITIVE MANUFACTURING

10.12783/asc36/35741 ◽

2021 ◽

Author(s):

MIA CARROLA ◽

AMIR ASADI

Keyword(s):

Mechanical Properties ◽

Thermal Conductivity ◽

Carbon Nanotubes ◽

Additive Manufacturing ◽

Aqueous Suspension ◽

Manufacturing Method ◽

Nanocomposite Polymer ◽

Water As Solvent ◽

Materials Used ◽

Scalable Production

Though a revolutionary process, additive manufacturing (AM) has left more to be desired from printed parts, specifically, improved interlayer strength and minimal defects such as porosity. To overcome these common issues, nanocomposites have become one of the most popular materials used in AM, with various nanoparticles used to achieve a variety of characteristics. The use of these technologies together allows for both to synergistically enhance the final printed parts by improving the process and products simultaneously. Here, we introduce a novel, scalable technique to coat ABS pellets with cellulose nanocrystal (CNC) bonded carbon nanotubes (CNT), to improve the adhesion between layers as well as the mechanical properties of printed parts. An aqueous suspension of CNT-CNC is used to coat ABS pellets before they are dried and extruded into filament for printing. The filament produced using this manufacturing method showed an increase in tensile and interlayer strength as well as improved thermal conductivity. This process uses water as solvent and pristine nanoparticles without the need for any functionalization or surfactants, promoting its scalability. This process has the potential to be used with various polymers and nanoparticles, which allows the materials to be specifically tailored to the end application, (i.e. strength, conductivity, antibacterial, etc.). These nanocomposite filaments have the potential to revolutionize the way that additive manufacturing is utilized in a variety of industries.

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Recent Patents in Additive Manufacturing of Continuous Fiber Reinforced Composites

Recent Patents on Mechanical Engineering ◽

10.2174/2212797612666190117131659 ◽

2019 ◽

Vol 12 (1) ◽

pp. 25-36 ◽

Cited By ~ 7

Author(s):

Chao Hu ◽

Zeyu Sun ◽

Yi Xiao ◽

Qinghua Qin

Keyword(s):

Additive Manufacturing ◽

Raw Materials ◽

Fiber Reinforced Composites ◽

Reinforced Composites ◽

Fiber Reinforced ◽

Continuous Fiber ◽

Manufacturing Method ◽

Carbon Fiber Reinforced Composites ◽

Bending Stresses ◽

Continuous Carbon Fiber

Background: Additive Manufacturing (AM) enables the accurate fabrication of designed parts in a short time without the need for specific molds and tools. Although polymers are the most widely used raw materials for AM, the products printed by them are inherently weak, unable to sustain large tension or bending stresses. A need for the manufacturing of fiber reinforced composites, especially continuous fiber as reinforcement, has attracted great attention in recent years. Objective: Identifying the progress of the AM of continuous carbon fiber reinforced composites over time and therefore establishing a foundation on which current research can be based. Methods: Elaborating the most related patents regarding the AM techniques for fabricating continuous fiber reinforced composites in the top three institutions, including Markforged company, Xi’an Jiaotong University and President and Fellows of Harvard College. Results: The recent patents in AM of continuous fiber reinforced composites are classified into two aspects: patents related to novel technique methods and patents related to novel structures. The current issues and future development of AM-based composites are given. Conclusion: New structures and techniques have been introduced into conventional 3D printers to enable the printing of continuous fiber reinforced composites. However, until now, Markforged is the only company commercializing the fabrication of this kind of composites based on AM technique. Numerous challenges and issues need to be solved so that AM of continuous fiber reinforced composites can be a new manufacturing method.

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