Effect of different filler content of ABS–zinc ferrite composites on mechanical, electrical and thermal conductivity by using 3D printing

Aqzna, S. S.; Yeoh, Cheow Keat; Idris, Mohd Sobri; Teh, Pei Leng; Hamzah, Khairul Amali; Aw, Yah Yun; Atiqah, T. N.

doi:10.1002/vnl.21640

Cited by 28 publications

(13 citation statements)

References 54 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The Young’s modulus of the produced sample is higher compared to that of composite ones, presenting a value of 0.85 GPa, while for composite samples the Young’s modulus increases with increasing infill ratio, obtaining maximum value of 0.67 and 0.74 GPa for an infill ratio of 40 vol.% for F1 and F2 filler grades, respectively [ 20 ]. A significant reduction in Young’s modulus is observed for the sample with minimum infill ratio (5 vol.%); compared to the neat ABS sample, the obtained Young’s modulus values are reduced by 62.3 and 61.2% for F1 and F2 filler, respectively.…”

Section: Resultsmentioning

confidence: 99%

Methods of Preparation and Performance Evaluation of ABS/Mineral Microsphere Composites Produced through FDM and Compression Molding

et al. 2022

View full text Add to dashboard Cite

The use of amorphous microspheres as filler in composites is promising due to their light weight, low cost, incombustibility, and the ability to alter relevant properties of the final composite. Contrary to glass spheres, perlite microspheres are much cheaper and can be tailor-made to facilitate purpose-oriented alteration of the final composite. We report the use of perlite microspheres for the preparation of: (1) composites, through a compression molding (hot pressing) technique; and (2) composite filaments, in a single screw extruder, as well as their use for sample printing through Fused Deposition Modeling (FDM). Proper characterization of the produced composites allows for their evaluation in terms of physical, thermal, and mechanical properties and with regards to the manufacturing technique, the filler fraction, and size. Composite samples of acceptable quality in terms of filler survival and dispersion as well as mechanical properties were produced through compression molding using fine expanded perlite microspheres (<90 μm) up to an infill ratio of 40 vol.%. Fine fillers (<90 μm) performed well in FDM, allowing printing of composite dogbone samples with a higher Young’s modulus and elongation and similar ultimate tensile strength compared to benchmark, up to an infill ratio of 20 vol.%. Composite samples present a slightly lower burning rate compared to those produced solely by ABS. Perlite microspheres present good workability in both applications, possessing satisfactory performance as filler in the composites, and can thus be assumed a promising multifunctional filler for various thermoplastics considering their low price, environmental impact, and fire rating.

show abstract

Section: Resultsmentioning

confidence: 99%

Methods of Preparation and Performance Evaluation of ABS/Mineral Microsphere Composites Produced through FDM and Compression Molding

et al. 2022

View full text Add to dashboard Cite

show abstract

“…Improvements to thermal resistance may be achieved by addition of primary and secondary antioxidants and other stabilizers. [ 11 ] Further, useful thermal properties may be realized by incorporation of thermally conductive fillers such as zinc ferrite [ 43 ] and graphene. [ 44 ] Resistance to environmental exposure includes all the stressors that may be present in application for the AM‐built part, including high and low temperatures, temperature swings, moisture, chemicals, and UV and other radiation.…”

Section: Current Trends For Additives In Ammentioning

confidence: 99%

Current status and future roles of additives in 3D printing—A perspective

Thompson

2022

Vinyl Additive Technology

View full text Add to dashboard Cite

3D printing has evolved quickly from rapid prototyping to true mass production. This is reflected in the use of the term additive manufacturing (AM) to emphasize the use of the technology in actual manufacturing of high‐value products and finished goods. Consequentially, the requirements on the materials and processes have become more stringent and challenging to satisfy. Furthermore, various manufacturing industries have their own unique sets of requirements, and these are difficult if not impossible to satisfy with neat polymers alone. Therefore, additives are playing an increasingly critical role for satisfying material requirements for AM applications. In this article, challenges are identified that will need to be addressed as AM matures toward manufacturing applications. These include speed of production, mechanical performance and durability of the products, their interaction with the environment, and readiness for manufacturing. The use of additives to overcome these challenges is discussed in terms of current trends and with the help of specific examples. These include, but are not limited to, reinforcements, thermal stabilizers, antioxidants, and flame retardants to improve performance and meet thermal, environmental, and flammability requirements in demanding applications like aerospace, defense, and automotive. Further, colors, pigments, and dyes are needed for aesthetics. Bioactive or bioinert materials are needed for specific medical applications, and electrically dissipative or thermally conductive materials are often needed for electronics applications. This article provides a critical look at the current state of AM and how the roles of additives in AM are expected to expand, including identification of future opportunities.

show abstract

“…Compared with traditional subtractive manufacturing techniques, three-dimensional (3D) printing techniques are more flexible and convenient and can fabricate very complicated 3D structures at one time. The 3D printing technique has many advantages over traditional subtractive manufacturing techniques and has been widely used in medical, mechanical, construction, aerospace and nanotechnology (Aqzna et al, 2018;Xing et al, 2018;Hisham et al, 2018;Chen et al, 2018). The 3D printing technique can be applied to fabricate solid structures with complex curved surfaces at one time by layer-by-layer printing.…”

Section: Introductionmentioning

confidence: 99%

Research on the printing error of tilted vertical beams in delta-robot 3D printers

Wang

Liu

Guo

et al. 2021

RPJ

View full text Add to dashboard Cite

Purpose A three-dimensional (3D) printing error simulation approach is proposed to analyze the influence of tilted vertical beams on the 3D printing accuracy. The purpose of this study is to analyze the influence of such errors on printing accuracy and printing quality for delta-robot 3D printer. Design/methodology/approach First, the kinematic model of a delta-robot 3D printer with an ideal geometric structure is proposed by using vector analysis. Then, the normal kinematic model of a nonideal delta-robot 3D robot with tilted vertical beams is derived based on the above ideal kinematic model. Finally, a 3D printing error simulation approach is proposed to analyze the influence of tilted vertical beams on the 3D printing accuracy. Findings The results show that tilted vertical beams can indeed cause 3D printing errors and further influence the 3D printing quality of the final products and that the 3D printing errors of tilted vertical beams are related to the rotation angles of the tilted vertical beams. The larger the rotation angles of the tilted vertical beams are, the greater the geometric deformations of the printed structures. Originality/value Three vertical beams and six horizontal beams constitute the supporting parts of the frame of a delta-robot 3D printer. In this paper, the orientations of tilted vertical beams are shown to have a significant influence on 3D printing accuracy. However, the effect of tilted vertical beams on 3D printing accuracy is difficult to capture by instruments. To reveal the 3D printing error mechanisms under the condition of tilted vertical beams, the error generation mechanism and the quantitative influence of tilted vertical beams on 3D printing accuracy are studied by simulating the parallel motion mechanism of a delta-robot 3D printer with tilted vertical beams.

show abstract

Effect of different filler content of ABS–zinc ferrite composites on mechanical, electrical and thermal conductivity by using 3D printing

Cited by 28 publications

References 54 publications

Methods of Preparation and Performance Evaluation of ABS/Mineral Microsphere Composites Produced through FDM and Compression Molding

Methods of Preparation and Performance Evaluation of ABS/Mineral Microsphere Composites Produced through FDM and Compression Molding

Current status and future roles of additives in 3D printing—A perspective

Research on the printing error of tilted vertical beams in delta-robot 3D printers

Contact Info

Product

Resources

About