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Static Mixers for High-Viscosity Systems: From Classical Helices to Machine-Learning-Optimized Geometries

Shicong Luo, Cong Wang

2025ACS Omega5 citationsDOIOpen Access PDF

Abstract

Static mixers are widely used in chemical, polymer, and process industries to handle high-viscosity media, such as polymer melts, yield-stress resins, and particle-laden suspensions, where conventional mixing is inefficient. By inducing chaotic advection through fixed internal geometries, they offer compact, low-maintenance solutions compatible with continuous production. This review charts the progression from classical helical ribbons to advanced, application-specific elements optimized by using computational fluid dynamics (CFD) and machine learning (ML). Design strategies for viscoelastic and yield-stress fluids are critically assessed, with attention to balancing mixing intensity against hydraulic losses. Remaining challenges include the scale-up of complex ML-derived designs, mitigation of viscoelastic instabilities, integration of multifunctional features, and further gains in energy efficiency. Advances in these areas will enhance the role of static mixers in sustainable, high-performance industrial processes.

Topics & Concepts

Mixing (physics)ChaoticViscoelasticityProcess (computing)MechanicsAdvectionMechanical engineeringComputer scienceChaotic mixingControl theory (sociology)Energy (signal processing)EngineeringDynamics (music)Static mixerControl engineeringFlow (mathematics)Classical mechanicsIntensity (physics)Computational fluid dynamicsInternal flowPhysicsStatistical physicsFluid dynamicsConvergence (economics)Materials scienceSimulationRheology and Fluid Dynamics StudiesFluid Dynamics and Thin FilmsModel Reduction and Neural Networks
Static Mixers for High-Viscosity Systems: From Classical Helices to Machine-Learning-Optimized Geometries | Litcius