基於三維流場模擬之同向雙螺桿混合效率預測

Chun-Liang Tan; 陳春良

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/71044

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	趙修武
dc.contributor.author	Chun-Liang Tan	en
dc.contributor.author	陳春良	zh_TW
dc.date.accessioned	2021-06-17T04:50:06Z	-
dc.date.available	2023-08-06
dc.date.copyright	2018-08-06
dc.date.issued	2018
dc.date.submitted	2018-07-31
dc.identifier.citation	[1] M. L. Booy, Isothermal Flow of Viscous Liquids in Corotating Twin Screw Devices, Polymer Engineering and Science, Vol.20, No.18, pp.1220-1228, 1980. [2] T. Sastrohartono, M. Esseghir, T. H. Kwon and V. Sernas, Numerical and Experimental Studies of the Flow in the Nip Region of a Partially Intermeshing Co‐Rotating Twin‐Screw Extruder, Polymer Engineering and Science, Vol.30, No.21, pp.1382-1398, 1990. [3] T. Sastrohartono, Y. Jaluria, and M. V. Karwe, Numerical Simulation of Fluid Flow and Heat Transfer in Twin‐Screw Extruders for Non‐Newtonian Materials, Polymer Engineering and Science, Vol.35, No.15, pp.1213-1221, 1995. [4] A. Shah and M. Gupta, Comparison of The Flow in Co-Rotating and Counter-Rotating Twin-Screw Extruders, ANTEC Conference Proceedings, Vol.1, pp.443-447, 2004. [5] T. Kajiwara, Y. Nagashima, Y. Nakano, and K. Funatsu, Numerical Study of Twin‐Screw Extruders by Three‐Dimensional Flow Analysis—Development of Analysis Technique and Evaluation of Mixing Performance for Full Flight Screws, Polymer Engineering and Science, Vol.36, No.16, pp.2142-2152, 1996. [6] N. Kim, H. Kim and J. Lee, Numerical Analysis of Internal Flow and Mixing Performance in Polymer Extruder II: Twin Screw Element, Korea-Australia Rheology Journal, Vol.18, No.3, pp.153-160, 2006. [7] C. H. Yao and I. Manas‐Zloczower, Influence of Design on Dispersive Mixing Performance in an Axial Discharge Continuous Mixer—LCMAX 40, Polymer Engineering and Science, Vol.38, No.6, pp.936-946, 1998. [8] V. L. Bravo, A. N. Hrymak and J. D. Wright, Numerical Simulation of Pressure and Velocity Profiles in Kneading Elements of a Co‐Rotating Twin Screw Extruder, Polymer Engineering and Science, Vol.40, No.2, pp.525-541, 2000. [9] S. Fard and P. D. Anderson, Simulation of distributive mixing inside mixing elements of co-rotating twin-screw extruders, Computers and Fluids, Vol.87, pp.79-91, 2013. [10] B. Alsteens, V. Legat and T. Avalosse, Parametric Study of the Mixing Efficiency in a Kneading Block Section of a Twin-Screw Extruder, International Polymer Processing, Vol.19, No.3, pp.207-217, 2004. [11] S. A. Jaffer, V. L. Bravo, P. E. Wood, A. N. Hrymak and J. D. Wright, Experimental Validation of Numerical Simulations of the Kneading Disc Section in a Twin Screw Extruder, Polymer Engineering and Science, Vol.40, No.4, pp.892-901, 2000. [12] V. L. Bravo, A. N. Hrymak and J. D. Wright, Study of Particle Trajectories, Residence Times and Flow Behavior in Kneading Discs of Intermeshing Co‐Rotating Twin‐Screw Extruders, Polymer Engineering and Science, Vol.44, No,4, pp.779-793, 2004. [13] A. Lawal and D. M. Kalyon, Mechanisms of Mixing in Single and Co‐Rotating Twin Screw Extruders, Polymer Engineering and Science, Vol.35, No.17, pp.1325-1338, 1995. [14] R. K. Connelly and J. L. Kokini, Examination of the Mixing Ability of Single and Twin Screw Mixers Using 2D Finite Element Method Simulation with Particle Tracking, Journal of Food Engineering, Vol.79, No.3, pp.956-969, 2007. [15] J. Diemer, C. Chilles, J. Colbert, T. Miri, A. Ingram, P. David, A. S. Fard and P. D. Anderson, Flow Visualisation in Co-Rotating Twin Screw Extruders: Positron Emission Particle Tracking and Numerical Particle Trajectories, International Polymer Processing, Vol.26, No.5, pp.540-550, 2011. [16] K. T. Lee, A. Ingram and N. A. Rowson, Twin Screw Wet Granulation: The Study of a Continuous Twin Screw Granulator Using Positron Emission Particle Tracking (PEPT) Technique, European Journal of Pharmaceutics and Biopharmaceutics, Vol.81, No.3, pp.666-673, 2012. [17] M. Yoshinaga, S. Katsuki, M. Miyazaki, L. Liu, S. I. Kihara and K. Funatsu, Mixing Mechanism of Three‐Tip Kneading Block in Twin Screw Extruders, Polymer Engineering and Science, Vol.40, No.1, pp.168-178, 2000. [18] B. Xu, H. Yu and L. S. Turng, Distributive Mixing in a Corotating Twin Screw Channel Using Lagrangian Particle Calculations, Advances in Polymer Technology, 2017. [19] B. Xu, L. Yao, L. He, J. Chen and L. S. Turng, Numerical Study of Mixing Dynamics Inside the Novel Elements of a Corotating Nontwin Screw Extruder, Advances in Polymer Technology, 2017. [20] Y. Nakayama, H. Takemitsu, T. Kajiwara, K. Kimura, T. Takeuchi and H. Tomiyama, Improving Mixing Characteristics with a Pitched Tip in Kneading Elements in Twin‐Screw Extrusion, AIChE Journal, Vol.64, No.4, pp.1424-1434, 2018. [21] Y. Nakayama, N. Nishihira, T. Kajiwara, H. Tomiyama, T. Takeuchi and K. Kimura. Effects of Pitched Tips of Novel Kneading Disks on Melt Mixing in Twin-Screw Extrusion, 日本レオロジー学会誌, Vol.44, No.5, pp.281-288, 2017. [22] D. B. Todd, Residence Time Distribution in Twin‐Screw Extruders, Polymer Engineering and Science, Vol.15, No.6, pp.437-443, 1975. [23] S. V. Kao and G. R. Allison. Residence Time Distribution in a Twin Screw Extruder, Polymer Engineering and Science, Vol.24, No.9, pp.645-651, 1984. [24] J. Gao, G. C. Walsh, D. Bigio, R. M. Briber and M. D. Wetzel, Residence‐Time Distribution Model for Twin‐Screw Extruders, AIChE Journal, Vol.45, No.12, pp.2541-2549, 1999. [25] J. P. Puaux, G. Bozga and A. Ainser, Residence Time Distribution in a Corotating Twin-Screw Extruder, Chemical Engineering Science, Vol.55, No.9, pp.1641-1651, 2000. [26] H. H. Yang and I. Manas‐Zloczower, Flow Field Analysis of the Kneading Disc Region in a Co‐Rotating Twin Screw Extruder, Polymer Engineering and Science, Vol.32, No.19, pp.1411-1417, 1992. [27] Y. Nakayama, E. Takeda, T. Shigeishi, H. Tomiyama and T. Kajiwara, Melt-Mixing by Novel Pitched-tip Kneading Disks in a Co-Rotating Twin-Screw Extruder. Chemical Engineering Science, Vol.66, No.1, pp.103-110, 2011. [28] S. V. Patankar and D. B. Spalding, Numerical Prediction of Flow, Heat Transfer, Turbulence and Combustion, pp.54-73, 1983. [29] L. F. Richardson, The Approximate Arithmetical Solution by Finite Differences of Physical Problems Involving Differential Equations, with an Application to the Stresses in a Masonry Dam. Phil. Trans. R. Soc. Lond. Series A, Vol.210, pp.307-357, 1911. [30] T. Ishikawa, S. I. Kihara and K. Funatsu, 3‐D Non‐Isothermal Flow Field Analysis and Mixing Performance Evaluation of Kneading Blocks in a Co‐rotating Twin Screw Extruder. Polymer Engineering and Science, Vol.41, No.5, pp.840-849, 2001.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/71044	-
dc.description.abstract	本研究主要以數值模擬探討典型運輸和捏合元件在雙螺桿押出機內部流場特徵以及其混合效率。本研究在等溫和不可壓縮流的假設下，以Cross-WLF黏度修正模型描述高分子的流變性質，使用暫態三維模型求解連續和動量方程式，以描述雙螺桿流場的混煉行為。本研究首先使用STAR-CCM+軟體進行雙螺桿流場數值模擬計算，獲得流場剪切率、速度和壓力等物理量分佈，接著基於流場特性以四階Runge-Kutta方法預測虛擬粒子的軌跡。本研究以上述方法預測三種質量流率（10、20、40 kg/hr）和三種螺桿轉速（75、150、300 rpm）的雙螺桿元件混合能力。計算結果顯示，剪切率受螺桿轉速的影響大，而壓降則受流量影響較大。與捏合螺塊相比，在相同條件下運輸螺塊具有更大的壓降效果。轉速對於分散性影響較大，低轉速螺塊有更好的分散混合效率。相較於運輸螺塊，同條件下的捏合螺塊的分散混合效率較好。此外，高轉速捏合螺塊與低轉速運輸雙螺塊則具有較好的分配效率。	zh_TW
dc.description.abstract	This research is to study the flow properties and mixing characteristics of a typical conveying and kneading element in a twin screw extruder via a numerical approach. An unsteady, three-dimensional model is implemented in this study under the assumptions of an isothermal and incompressible flow. By solving the continuity and momentum equation, physical quantities such as strain rate, velocity components and pressure, are obtained. The modified Cross-WLF model is employed to describe the rheological properties of the polymer adopted in this study. The commercial software, STAR-CCM+ is used for the numerical simulation of the twin screw extrusion flow. A Lagrangian description of particle tracing method is developed to predict the trajectory of pseudo particles of the twin screw extrusion flow based on a fourth-order Runge-Kutta method. Three mass flowrate, 10 kg/hr, 20 kg/hr, 40 kg/hr, as well as three screw speed, 75 rpm, 150 rpm, 300 rpm, are adopted to investigate the influence on the both screw elements. Numerical results show that the strain rate in the flow is mainly affected by the screw speed, while the pressure drop is substantially influenced by the mass flowrate. Under the same operation condition, the conveying element has a larger pressure drop when compared to the kneading one. Screw speed has a dominant effect on enhancing dispersion, where reducing the screw speed leads to a better dispersibility. The kneading element has a better dispersive mixing efficiency than the conveying counterpart under the same operation condition. However, the kneading element at high rotational speed and the conveying element at low rotational speed tend to deliver a better distributive mixing performance.	en
dc.description.provenance	Made available in DSpace on 2021-06-17T04:50:06Z (GMT). No. of bitstreams: 1 ntu-107-R05525095-1.pdf: 8355034 bytes, checksum: c9eab5600473da9994c900121160dd5d (MD5) Previous issue date: 2018	en
dc.description.tableofcontents	Abstract I 摘要 II Nomenclature IV List of Figures VII List of Tables X Chapter 1 Introduction 1 1.1. Overview 1 1.2. Literature Reviews 3 Chapter 2 Mathematical Model 6 2.1. Hypothesis 6 2.2. Governing Equations 7 2.3. Tracer Equation 8 2.4. Mixing Indices 9 2.5. Materials Properties 12 2.6. Numerical Method 14 Chapter 3 Geometry, Meshing and Boundary Conditions 16 3.1. Geometrical Parameters 16 3.2. Boundary Conditions 19 3.3. Meshing 21 3.4. Mesh Dependency 24 3.5. Tracer Particle Configuration 28 Chapter 4 Numerical Results 29 4.1. Case Description 29 4.2. Flow Field Distribution 30 4.3. Average Physical Quantities along Flow Direction 33 4.4. Volume Fraction Distribution of Physical Quantities 50 4.5. Volume Average of Physical Quantities in a Period 82 4.6. Particle Trajectory 100 4.7. Probability Distribution 104 4.8. Validation and Verification 133 Chapter 5 Conclusions and Future Work 136 5.1. Conclusions 136 5.2. Future Work 138 References 139
dc.language.iso	en
dc.subject	運輸元件	zh_TW
dc.subject	雙螺桿押出機	zh_TW
dc.subject	混合效率	zh_TW
dc.subject	捏合元件	zh_TW
dc.subject	分配	zh_TW
dc.subject	分散	zh_TW
dc.subject	twin screw extruder	en
dc.subject	kneading element	en
dc.subject	dispersion	en
dc.subject	distribution	en
dc.subject	mixing efficiency	en
dc.subject	conveying element	en
dc.title	基於三維流場模擬之同向雙螺桿混合效率預測	zh_TW
dc.title	Mixing Prediction of Co-Rotating Twin Screw Extruder via Three-Dimensional Flow Modeling	en
dc.type	Thesis
dc.date.schoolyear	106-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	江茂雄,芮祥鵬,陳夏宗,吳晉安
dc.subject.keyword	運輸元件,捏合元件,分散,分配,混合效率,雙螺桿押出機,	zh_TW
dc.subject.keyword	conveying element,kneading element,dispersion,distribution,mixing efficiency,twin screw extruder,	en
dc.relation.page	141
dc.identifier.doi	10.6342/NTU201802210
dc.rights.note	有償授權
dc.date.accepted	2018-07-31
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	工程科學及海洋工程學研究所	zh_TW
顯示於系所單位：	工程科學及海洋工程學系

文件中的檔案：

檔案	大小	格式
ntu-107-1.pdf 未授權公開取用	8.16 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。