Evolutionary topology optimization for structural compliance minimization considering design-dependent FSI loads

“…The Bi-directional Evolutionary Structural Optimisation (BESO) method is used in a soft-kill version, but the sensitivities of changing the fluid flow are neglected. Similarly, Picelli et al [169] also neglect the sensitivities of changing the fluid flow when updating the wet surface when applying a hard-kill BESO method to design various FSI problems.…”

“…Of these 31 papers, 11 use an Ersatz-material, 11 use an adapted approach and only nine use a surface-capturing discretisation method. Lastly, the rest of the papers are distributed as follows: 5 using BESO [168,169,172,173,177]; 2 using phase field [42,59]; 1 using a discrete surface representation [63]; 1 using a geometry-projection method [138]; and 2 utilising the topological gradient [46,74]. Figure 6 shows the distribution of papers in these overall methods.…”

“…The efforts within wet topology optimisation of FSI problems only cover 15 papers [161,[163][164][165][166][167][168][169][170][171][172][173][174], and these all remain restricted to small deformations and steady-state. Thus, the solution of the problems in the deformed state is either negligible or of minor importance to the optimisation procedure, at least if the design objective is minimum compliance.…”

A Review of Topology Optimisation for Fluid-Based Problems

“…The Bi-directional Evolutionary Structural Optimisation (BESO) method is used in a soft-kill version, but the sensitivities of changing the fluid flow are neglected. Similarly, Picelli et al [169] also neglect the sensitivities of changing the fluid flow when updating the wet surface when applying a hard-kill BESO method to design various FSI problems.…”

“…Of these 31 papers, 11 use an Ersatz-material, 11 use an adapted approach and only nine use a surface-capturing discretisation method. Lastly, the rest of the papers are distributed as follows: 5 using BESO [168,169,172,173,177]; 2 using phase field [42,59]; 1 using a discrete surface representation [63]; 1 using a geometry-projection method [138]; and 2 utilising the topological gradient [46,74]. Figure 6 shows the distribution of papers in these overall methods.…”

“…The efforts within wet topology optimisation of FSI problems only cover 15 papers [161,[163][164][165][166][167][168][169][170][171][172][173][174], and these all remain restricted to small deformations and steady-state. Thus, the solution of the problems in the deformed state is either negligible or of minor importance to the optimisation procedure, at least if the design objective is minimum compliance.…”

A Review of Topology Optimisation for Fluid-Based Problems

“…Despite the large research effort, only a small number of papers has been concerned with structural topology optimization of FSI problems, see e.g. Maute (2015, 2016), Kreissl et al (2010), Picelli et al ( , 2017, Yoon (2010Yoon ( , 2014a. The motivation and aim of the present study is to contribute to the development of the topology optimization approach for FSI problems, which in the future may be used to analyze and optimize industrially relevant problems, such as bridges, turbines or compliant component designs.…”

“…The topology of a valve flap was optimized with deformation dependency for two different Reynolds numbers. In the papers by Picelli et al ( , 2017, a bi-directional evolutionary (BESO) topology optimization method was used to optimize structural compliance problems under design-dependent pressure loads. In this framework the deformation dependency was neglected.…”

Revisiting density-based topology optimization for fluid-structure-interaction problems

Topology optimization of pressure structures based on regional contour tracking technology