Revisiting the origin to bridge a gap between topology and topography optimisation of fluid flow problems

This paper revisits the origin of topology optimisation for fluid flow problems, namely the Poiseuillebased frictional resistance term used to parametrise regions of solid and fluid. The traditional model only works for true topology optimisation, where it is used to approximate solid regions as areas with very small channel height and, thus, very high frictional resistance. It will be shown that if the channel height is allowed to vary continuously and/or the minimum channel height is relatively large and/or meaning is attributed to intermediate design field values, then the predictions of the traditional model are wrong. To remedy this problem, this work introduces an augmentation of the mass conservation equation to allow for continuously varying channel heights. The proposed planar model accurately describes fully-developed flow between two plates of varying channel height. It allows for a significant reduction in the number of degrees-of-freedom, while generally ensuring a high accuracy for low-to-moderate Reynolds numbers in the laminar regime. The accuracy and limitations of both the traditional and proposed models are explored using in-depth parametric studies. The proposed model is used to optimise the height of the fluid channel between two parallel plates and, thus, the topography of the plates for a flow distribution problem. Lastly, it is observed that the proposed model actually produces better topological designs than This paper is dedicated to two pioneers of fluid flow topology optimisation: Joakim Petersson (1968-2002) and Allan Roulund Gersborg (1976-2020). J. Alexandersen Department of Mechanical and Electrical Engineering University of Southern Denmark Campusvej 55, DK-5230 Odense M Tel.: +45 65507465 E-mail: joal@sdu.dk the traditional model when applied to the topology optimisation of a flow manifold.

[1]  O. SIAMJ.,et al.  A CLASS OF GLOBALLY CONVERGENT OPTIMIZATION METHODS BASED ON CONSERVATIVE CONVEX SEPARABLE APPROXIMATIONS∗ , 2002 .

[2]  Joe Alexandersen,et al.  A Review of Topology Optimisation for Fluid-Based Problems , 2020, Fluids.

[3]  Bayram Kılıç,et al.  Experimental investigation of heat transfer and effectiveness in corrugated plate heat exchangers having different chevron angles , 2017 .

[4]  Muhyiddine Jradi,et al.  NeGeV: next generation energy efficient ventilation system using phase change materials , 2019 .

[5]  P. Lee,et al.  Topology optimization of liquid-cooled microchannel heat sinks: An experimental and numerical study , 2019, International Journal of Heat and Mass Transfer.

[6]  Kikuo Fujita,et al.  Freeform winglet design of fin-and-tube heat exchangers guided by topology optimization , 2019, Applied Thermal Engineering.

[7]  Poh Seng Lee,et al.  Experimental and numerical investigation of a mini channel forced air heat sink designed by topology optimization , 2018 .

[8]  O. Sigmund,et al.  Topology optimization of channel flow problems , 2005 .

[9]  Yuchen Guo,et al.  Design Applicable 3D Microfluidic Functional Units Using 2D Topology Optimization with Length Scale Constraints , 2020, Micromachines.

[10]  Wenzhe Li,et al.  Single-phase flow distribution in plate heat exchangers: Experiments and models , 2021, International Journal of Refrigeration.

[11]  Alberto Pizzolato,et al.  Topology optimization as a powerful tool to design advanced PEMFCs flow fields , 2019, International Journal of Heat and Mass Transfer.

[12]  J. Petersson,et al.  Topology optimization of fluids in Stokes flow , 2003 .

[13]  A. Evgrafov The Limits of Porous Materials in the Topology Optimization of Stokes Flows , 2005 .

[14]  O. Sigmund,et al.  Topology optimization of a pseudo 3D thermofluid heat sink model , 2018, International Journal of Heat and Mass Transfer.

[15]  Spiros V. Paras,et al.  Flow and Heat Transfer Prediction in a Corrugated Plate Heat Exchanger using a CFD Code , 2006 .

[16]  Rakotobe Michael,et al.  Modelling of flow through spatially varying porous media with application to topology optimization , 2020 .

[17]  A. Evgrafov Topology optimization of slightly compressible fluids , 2006 .

[18]  Georg Pingen,et al.  Multi-Layer, Pseudo 3D Thermal Topology Optimization of Heat Sinks , 2012 .

[19]  Y. Tsai,et al.  Investigations of the pressure drop and flow distribution in a chevron-type plate heat exchanger , 2009 .

[20]  Alain Bastide,et al.  Penalization model for Navier–Stokes–Darcy equations with application to porosity-oriented topology optimization , 2018, Mathematical Models and Methods in Applied Sciences.

[21]  M. Zhang,et al.  Topology optimization of planar cooling channels using a three-layer thermofluid model in fully developed laminar flow problems , 2021, Structural and Multidisciplinary Optimization.

[22]  O. Sigmund,et al.  Filters in topology optimization based on Helmholtz‐type differential equations , 2011 .

[23]  L. H. Olesen,et al.  A high‐level programming‐language implementation of topology optimization applied to steady‐state Navier–Stokes flow , 2004, physics/0410086.

[24]  K. B. Nakshatrala,et al.  On Optimal Designs Using Topology Optimization for Flow Through Porous Media Applications , 2021, Transport in Porous Media.