Effect of Dynamic Center Region on the Flow and Mixing Efficiency in a New Tri-Screw Extruder Using 3D Finite Element Modeling

Zhu, Xiulin; He, Yu; Wang, G.

doi:10.1155/2013/258197

Cited by 5 publications

(4 citation statements)

References 17 publications

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“…Additionally, published data indicate that in triplescrew extruders the power consumption is 1.5 times higher than in co-rotating twin-screw extruders, while simultaneously their productivity increase around 1.3 times [34]. However, despite of above mentioned advantages of triple screw extrusion the research works about its application in polymer technology are still very limited [35][36][37], while its using during reactive processing is practically unknown. This is due to its high costs related to complicated screw geometry and barrel construction, comparing to single-or twin-screw extruders.…”

Section: Extruders As Chemical Reactors -Basic Conceptsmentioning

confidence: 99%

Reactive extrusion of bio-based polymer blends and composites – Current trends and future developments

Formela¹,

Zedler²,

Hejna³

et al. 2018

Express Polym. Lett.

108

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Abstract.Reactive extrusion is a cost-effective and environmentally-friendly method to produce new materials with enhanced performance properties. At present, reactive extrusion allows in-situ polymerization, modification/functionalization of polymers or chemical bonding of two (or more) immiscible phases, which can be carried out on commonly used extrusion lines. Although reactive extrusion has been known for many years, its application for processing of bio-based polymer blends and composites is a relatively new direction of scientific research. This work presents a literature review on recent advances in the processing of bio-based polymer blends and composites via reactive extrusion. We described compatibilization mechanisms for different types of biodegradable polymeric materials based on: (i) aliphatic polyesters, (ii) aliphatic polyesters/starch and (iii) aliphatic polyester/natural rubber systems. A special attention was focused on conventional and dynamic cross-linking of bio-based polymer blends and composites as an effective way to prepare new materials with unique properties e.g. biodegradable thermoplastic elastomers or shape-memory materials. Advantages and limitations affecting future trends in development of biodegradable polymer blends and composites reactive extrusion are also discussed.

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Section: Extruders As Chemical Reactors -Basic Conceptsmentioning

confidence: 99%

Reactive extrusion of bio-based polymer blends and composites – Current trends and future developments

Formela¹,

Zedler²,

Hejna³

et al. 2018

Express Polym. Lett.

108

View full text Add to dashboard Cite

show abstract

“…Uncomplicated screw mixers excel in axial mixing abilities but are insufficient in generating chaotic mixing effects, which are essential in FGM preparation. In response to this constraint, some researchers have employed more complex differential twin-screw or tri-screw structures to induce chaotic mixing and thereby enhance mixing efficiency [33][34][35][36][37][38][39]. Nevertheless, the resulting complexity in the mixing mechanism poses challenges in the accurate control of printed material components and leads to increased assembly requirements and an unwieldy printing system [40].…”

Section: Introductionmentioning

confidence: 99%

Optimization of Pin Type Single Screw Mixer for Fabrication of Functionally Graded Materials

Wang,

Zhou,

Duan

2024

Applied Sciences

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The direct ink writing (DIW) process, used for creating components with functionally graded materials, holds significant promise for advancement in various advanced fields. However, challenges persist in achieving complex gradient variations in small-sized parts. In this study, we have developed a customized pin shape for an active screw mixer using a combination of quadratic B-Spline, the response surface method, and global optimization. This tailored pin design was implemented in a two-material extrusion-based printing system. The primary objective is to facilitate the transformation of material components with shorter transition distances, overcoming size constraints and enhancing both printing flexibility and resolution. Moreover, we characterized the transition delay time for material component changes and the mixing uniformity of the extruded material by constructing a finite element simulation model based on computational fluid dynamics. Additionally, we employed a particle tracking method to obtain the Lyapunov exponent and Poincaré map of the mixing process. We employed these metrics to represent and compare the degree of chaotic mixing and dispersive mixing ability with two other structurally similar mixers. It was found that the optimized pin-type mixer can reduce the transition delay distance by approximately 30% compared to similar structures. Finally, comparative experiments were carried out to verify the printing performance of the optimized pin-type active mixer and the accuracy of the finite element model.

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“…Research inspired by in part by the findings of Kim and Kwon [ 10 , 11 ] in this field has led to some crucial findings: Zhu et al as well as Connely and Kokini observe that twin screw extruders show superior mixing compared to single-screw extruders [ 12 , 13 ]. Zhu et al also observe even better mixing in triple-screw extruders [ 14 ]. Xu et al confirm another important discovery in finding that distributive mixing performance depends on the initial location of the material that needs to be spread homogenously [ 15 ].…”

Section: Introductionmentioning

confidence: 99%

A Method for the Validation of Simulated Mixing Characteristics of Two Dynamic Mixers in Single-Screw Extrusion

et al. 2020

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The field of simulation and optimisation of dynamic mixing elements (‘mixers’) is lacking good methods for spatially resolved validation and flow visualisation. For this reason, the authors present an experimental setup that gives better insight into the thermal, distributive and dispersive mixing process by measuring melt temperatures upstream of the mixer and injecting a secondary, visually distinguishable stream of melt upstream. Running extrusion trials for a polyethylene on both a rhomboidal and a Maddock mixer, temperatures, gray scale distribution of images of extrudates and size of dispersed domains in incompatible polystyrene were measured. It was found that temperatures upstream and downstream of the mixer can be quantified. This was used to validate a simulation of thermal mixing. In distributive mixing, good agreement with simulation and an excellent spatial resolution were observed, thereby identifying an area of the rhomboidal mixer in need of geometric improvement. For dispersive mixing, a trend coherent with extrusion theory was found.

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Effect of Dynamic Center Region on the Flow and Mixing Efficiency in a New Tri-Screw Extruder Using 3D Finite Element Modeling

Cited by 5 publications

References 17 publications

Reactive extrusion of bio-based polymer blends and composites – Current trends and future developments

Reactive extrusion of bio-based polymer blends and composites – Current trends and future developments

Optimization of Pin Type Single Screw Mixer for Fabrication of Functionally Graded Materials

A Method for the Validation of Simulated Mixing Characteristics of Two Dynamic Mixers in Single-Screw Extrusion

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