Dynamic Capillary-Driven Additive Manufacturing of Continuous Carbon Fiber Composite

Shi, Baohui; Shang, Yuanyuan; Zhang, Ping; Cuadros, Angela P.; Qu, Jing; Sun, Bin; Gu, Bohong; Chou, Tsu‐Wei; Fu, Kun

doi:10.1016/j.matt.2020.04.010

Cited by 71 publications

(36 citation statements)

References 37 publications

(39 reference statements)

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“…On the other hand, the use of low volume fraction (i.e., 10 wt%) enables a complex component additive manufacturing (Figure 3 (C)), establishing the challenge of optimizing the AM process for high fiber content, suitable for structural applications. [36] Based on Shi et al, [12] Sanei et al [27] , and Van de Werken et al, [7,39] Figure 4 exhibits the mechanical property variation associated with the fiber size and the working temperature based on the glass transition temperature (T g ) of the matrix. As previously mentioned, the increase in fiber size increases the mechanical behavior; meanwhile, the working temperature is governed mainly by the matrix (thermoplastic or thermoset).…”

Section: Additive Manufacturing Of Fiber-reinforced Polymer Compositesmentioning

confidence: 99%

“…The thermoset matrices allow the material application at higher glass transition due to the strong molecular cross-link interaction compared with thermoplastic matrices used for AM. [12] The fiber size used also limits the AM method to be employed, in which the fused filament fabrication (FFF) and localized in-plane thermal assisted (LITA) present methods of impregnating long fibrous reinforcement. [12,32] On the other hand, direct ink writing (DIW) and stereolithography (SLA) processing are useful for short fibers.…”

Section: Additive Manufacturing Of Fiber-reinforced Polymer Compositesmentioning

confidence: 99%

“…[12] The fiber size used also limits the AM method to be employed, in which the fused filament fabrication (FFF) and localized in-plane thermal assisted (LITA) present methods of impregnating long fibrous reinforcement. [12,32] On the other hand, direct ink writing (DIW) and stereolithography (SLA) processing are useful for short fibers. [15,36] AM composites aim to achieve similar properties as those produced via conventional manufacturing processes with high fiber volume fraction and low defects.…”

Section: Additive Manufacturing Of Fiber-reinforced Polymer Compositesmentioning

confidence: 99%

“…[8][9][10][11] However, there is a considerable difficulty in controlling viscosity for deposition and curing the printed material, maintaining its complex threedimensional geometry-an essential factor for AM. [12,13] As a response, a significant number of studies have been developed aiming at improving the processability, such as the optimal set of printing speed/thickness, printing direction, thermoset matrix, and fiber used, AM type, among others. [14][15][16] Thermoset matrices application through AM relies on a new horizon in terms of efficiently processing parts and components with the advantages of possessing suitable mechanical properties while having complex geometries and little tooling.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

A systematic review on high‐performance fiber‐reinforced 3D printed thermoset composites

et al. 2021

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High-performance fiber-reinforced thermoset composites processed by additive manufacturing (3D printing) are attracting substantial attention in both academic and industrial fields in a market currently dominated by thermoplastic matrices. Thermoset polymers have, nevertheless, several advantages over thermoplastic ones. This study aims at recommending suitable fibers and processing conditions that effectively improve the mechanical properties of thermoset composites produced by additive manufacturing. The influence of void content is also highlighted. A systematic review is performed here using the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (P.R.I.S.M.A.) protocol as a guide aiming to identify the main findings recently studied. A total of 147 studies are initially identified within 2014-2020 using three scientific databases. Then, 29 articles are selected and described respecting several inclusion and exclusion criteria. The main findings are presented and discussed, and the gaps are identified to open up further investigations yet to be understood and exploited.

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Section: Additive Manufacturing Of Fiber-reinforced Polymer Compositesmentioning

confidence: 99%

Section: Additive Manufacturing Of Fiber-reinforced Polymer Compositesmentioning

confidence: 99%

Section: Additive Manufacturing Of Fiber-reinforced Polymer Compositesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A systematic review on high‐performance fiber‐reinforced 3D printed thermoset composites

et al. 2021

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“…It also reduces warping and enables a larger build envelope [121]. Shi et al [122] reported a dynamic capillary-driven additive manufacturing approach for manufacturing of continuous carbon fiber composites. This approach offers control over viscosity and degree of curing of carbon fiber composites.…”

Section: Fiber Reinforced Polymer Compositesmentioning

confidence: 99%

Additive Manufacturing of Polymer Materials: Progress, Promise and Challenges

et al. 2021

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The use of additive manufacturing (AM) has moved well beyond prototyping and has been established as a highly versatile manufacturing method with demonstrated potential to completely transform traditional manufacturing in the future. In this paper, a comprehensive review and critical analyses of the recent advances and achievements in the field of different AM processes for polymers, their composites and nanocomposites, elastomers and multi materials, shape memory polymers and thermo-responsive materials are presented. Moreover, their applications in different fields such as bio-medical, electronics, textiles, and aerospace industries are also discussed. We conclude the article with an account of further research needs and future perspectives of AM process with polymeric materials.

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Phase Change Materials for Life Science Applications

Zare

Mikkonen

2023

Adv Funct Materials

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reported the comparison results in the range of 0-10 based on the equations. The ideal case demonstrates the highest possible level of efficiency, and lifespan, specific power and energy, energy and power density, technical maturity, and the lowest possible power and energy capital cost, self-discharge rate, and environmental impact. [13] Figure 1c represents the PCMs' characteristics.In a previous review, Sadeghi (2022), discussed the thermal energy management of batteries and high-heat-flux electronic devices, and the capability of the TES systems. [2] Costa and Kenisarin (2022) produced a database of metallic PCM's thermophysical features and potential impact in diverse fields, for instance, bioengineering, electronics, solar energy storage, cooling and heating, and beyond. [8] Chavan (2022) covered the recent progress in TES and its usages such as waste heat recovery, solar-based TES, building applications, thermal comfort, heavy electronic equipment cooling, vapor absorption refrigeration (VAR), and Heating, ventilating, and air-conditioning (HVAC) applications. [14] An increasing number of recent research addresses the use of PMCs in human body, detection or sensing, biological, barcoding, drug delivery, and medical applications. However, there is no review comprehensively discussing the life science applications of TES and PMCs materials. Based on our literature survey we concluded that a review of the life science applications of PCMs is a required reference. Besides, the evaluation and safety aspects of TES will be explored in this review. Furthermore, the challenges and recommendations of PCM applications will be addressed in order to assist energy technologists and streamline future research.

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Dynamic Capillary-Driven Additive Manufacturing of Continuous Carbon Fiber Composite

Cited by 71 publications

References 37 publications

A systematic review on high‐performance fiber‐reinforced 3D printed thermoset composites

A systematic review on high‐performance fiber‐reinforced 3D printed thermoset composites

Additive Manufacturing of Polymer Materials: Progress, Promise and Challenges

Phase Change Materials for Life Science Applications

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