The potential to enhance membrane module design with 3D printing technology

Lee, Jian‐Yuan; Tan, Wen See; An, Jia; Chua, Chee Kai; Tang, Chuyang Y.; Fane, Anthony G.; Chong, Tzyy Haur

doi:10.1016/j.memsci.2015.11.008

Cited by 256 publications

(155 citation statements)

References 50 publications

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“…[28][29][30][31] Furthermore with the increasing recent interest in 3-D printable materials and the need to control the rheology of the solution while printing 32, 33 the areas of potential usage of TRGs has increased since 3-D printing is applied to the manufacture of materials in various industries besides the medical industry, like aerospace, automotive, building and construction, marine, food industry and in manufacturing electronic and optical devices. [34][35][36] In TRGs applications it is highly important to be able to control the gelation point, i.e. the temperature that the polymer solution becomes a gel, T gel .…”

Section: Introductionmentioning

confidence: 99%

Tuning the gelation of thermoresponsive gels

Constantinou

Georgiou

2016

European Polymer Journal

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Thermoresponsive gels are exciting polymeric materials with many biomedical applications in medical devices, drug delivery, tissue engineering and bio-printing. Also, they have great potential to be used in 3-D printing and thus in the fabrication of many different devices and materials. As it is crucial for the application of these gels to be able to control and tailor the gelation temperature and concentration this was the main focus and point of discussion of this feature article. Thus, it is discussed in detail how by varying the molar mass, composition, stereochemistry and architecture the thermoresponsive properties of these gels are altered.

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Section: Introductionmentioning

confidence: 99%

Tuning the gelation of thermoresponsive gels

Constantinou

Georgiou

2016

European Polymer Journal

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“…In 2015, Carbon3D introduced a 3DP technique relying on continuous liquid interface production via UV irradiation of a photocurable polymer with build speeds of 500 mm/h (25‐100 times faster than existing 3D printers) and an XYZ resolution of 1 μm. Continuous liquid interface production technology does allow for build speeds in excess of 1000 mm/h but at a severe cost to resolution . Continuous liquid interface production offers an advantage in structural soundness over conventional 3DP techniques, as the finished product is 1 continuous structure instead of a series of 2D layers.…”

Section: D Processing Techniquesmentioning

confidence: 99%

Multifaceted polymeric materials in three‐dimensional processing (3DP) technologies: Current progress and prospects

Oderinde

Kang

et al. 2018

Polymers for Advanced Techs

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Three‐dimensional printing (3DP) technologies, which are sets of powerful deposition methods employed to fabricate 3D objects with materials in the fields of material sciences and engineering, biomedical and biocompatible structural components, automotive, aviation, and polymers, among others, are currently rapidly developing manufacturing technologies. The methods have significant advantages, which include designing flexibility, enhanced geometrical freedom, low cost, and net shape manufacture, among others, over the traditional “subtractive” method. This review highlights the major 3D printing techniques, especially in the fields of advanced polymeric material fabrication and engineering, as well as the synergy in the incorporation of different types of polymeric materials and composites in a process that will lead to an enhancement of dimensional accuracy for 3D technologies. Furthermore, composite ink systems especially polymer‐based and hydrogel‐based in tissue engineering applications are also discussed.

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“…One of the revolutionary manufacturing technologies is additive manufacturing (AM). Owing to its high design freedom, lighter parts with high functionality started to contribute in the advancement of a variety of industries such as aerospace [15,16] , automotive [17][18][19] , biomedical [20][21][22] , fashion and art [23] . Additive manufacturing, Rapid prototyping, and 3D printing are often taken as synonym.…”

Section: Introductionmentioning

confidence: 99%

Fused Deposition Modeling for Unmanned Aerial Vehicles (UAVs): A Review

et al. 2017

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Additive Manufacturing (AM) is a game changing production technology for aerospace applications. Fused deposition modelling is one of the most widely used AM technologies and recently has gained much attention in the advancement of many products. This paper introduces an extensive review of fused deposition modelling and its application in the development of high performance unmanned aerial vehicles. The process methodology, materials, post processing, and properties of its products are discussed in details. Successful examples of using this technology for making functional, lightweight and high endurance unmanned aerial vehicles are also highlighted. In addition, major opportunities, limitations, and outlook of fused deposition modelling are also explored. The paper shows that the emerge of fused deposition modelling as a robust technique for unmanned aerial vehicles represents a good opportunity to produce compact, strong, lightweight structures, and functional parts with embedded electronic.2

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The potential to enhance membrane module design with 3D printing technology

Cited by 256 publications

References 50 publications

Tuning the gelation of thermoresponsive gels

Tuning the gelation of thermoresponsive gels

Multifaceted polymeric materials in three‐dimensional processing (3DP) technologies: Current progress and prospects

Fused Deposition Modeling for Unmanned Aerial Vehicles (UAVs): A Review

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