饥饿喂料单螺杆挤压过程中填充水平和停留时间的数值建模:从三维 CFD 模型到二维对流扩散模型的降维研究

IF 2.9 3区 工程技术 Q2 AUTOMATION & CONTROL SYSTEMS
Erik Holmen Olofsson, Ashley Dan, Michael Roland, Ninna Halberg Jokil, Rohit Ramachandran, Jesper Henri Hattel
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引用次数: 0

摘要

这项研究深入探讨了单螺杆挤出系统中饥饿喂料的填充水平和停留时间分布(RTD)的数值预测。饥饿喂料主要用于陶瓷挤出,它带来了挑战,本研究试图解决这一问题。在物理工业系统的基础上,使用多孔介质表示复杂的多孔板模具,开发了一个全面的三维计算流体动力学(CFD)模型。使用真实传感器数据进行的验证显示,在不考虑螺杆磨损的情况下,误差约为 11%,而在考虑螺杆磨损的情况下,误差约为 6%。二维对流扩散模型作为降维阶次模型(ROM)被引入,目的是缩小综合 CFD 模拟与实时应用之间的差距。该模型预测能力的核心是 CFD 模型的速度场传输和 ROM 扩散系数的校准,从而获得精确一致的停留时间分布曲线(RTD)。我们观察到 CFD 和 ROM 之间存在一些差异,这是因为从保真度较高的 CFD 模型过渡到半机械 ROM 时,系统的物理信息会丢失,而且挤压机压缩区的饥饿流本身就很复杂。这项研究为饥饿喂料挤出系统的减阶建模提供了全面的方法和见解,为实时优化和增强工艺理解提供了机会。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Numerical modeling of fill-level and residence time in starve-fed single-screw extrusion: a dimensionality reduction study from a 3D CFD model to a 2D convection-diffusion model

Numerical modeling of fill-level and residence time in starve-fed single-screw extrusion: a dimensionality reduction study from a 3D CFD model to a 2D convection-diffusion model

This research delves into the numerical predictions of fill-level and residence time distribution (RTD) in starve-fed single-screw extrusion systems. Starve-feeding, predominantly used in ceramic extrusion, introduces challenges which this study seeks to address. Based on a physical industrial system, a comprehensive 3D computational fluid dynamics (CFD) model was developed using a porous media representation of the complex multi-hole plate die. Validations performed using real sensor data, accounting for partial wear on auger screw flights, show an ~11% discrepancy without accounting for screw wear and ~6% when considering it. A 2D convection-diffusion model was introduced as a dimensionality reduced order model (ROM) with the intention of bridging the gap between comprehensive CFD simulations and real-time applications. Central to this model’s prediction ability was both the velocity field transfer from the CFD model and calibration of the ROM diffusion coefficient such that a precise agreement of residence time distribution (RTD) curves could be obtained. Some discrepancies between the CFD and the ROM were observed, attributed to the loss of physical information of the system when transitioning from a higher fidelity CFD model to a semi-mechanistic ROM and the inherent complexities of the starved flow in the compression zone of the extruder. This research offers a comprehensive methodology and insights into reduced order modeling of starve-fed extrusion systems, presenting opportunities for real-time optimization and enhanced process understanding.

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来源期刊
CiteScore
5.70
自引率
17.60%
发文量
2008
审稿时长
62 days
期刊介绍: The International Journal of Advanced Manufacturing Technology bridges the gap between pure research journals and the more practical publications on advanced manufacturing and systems. It therefore provides an outstanding forum for papers covering applications-based research topics relevant to manufacturing processes, machines and process integration.
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