Session: DAC-10-4: Design of Engineering Materials and Structures

Paper Number: 146350

146350 - Topology Optimization of Multibody Systems Undergoing Dynamic Loading Using an Equivalent Static Displacement Method 

Structural topology optimization for vehicle structures under static loading is a well-established practice. Unfortunately, extending these methods to components subjected to dynamic loading is challenged by the absence of sensitivity coefficients: analytical expressions are unavailable and numerical approximations are computationally impractical. To alleviate this problem, researchers have proposed methods such as hybrid cellular automata (HCA) and equivalent static load (ESL). This work introduces a new approach based on equivalent static displacement (ESD). The proposed ESD method utilizes the nodal displacement of the dynamic analysis at various simulation times to define the boundary conditions for corresponding models--one model per simulation time. A scalarized multi-objective function is defined considering all the models. A gradient-based optimizer is incorporated to find the optimal topology. Then, a new dynamic analysis is performed, the new ESD is defined for each model, and a new topology is obtained. The iterative process continues until convergence. Furthermore, this work also demonstrates the extension of the proposed ESD method in the topology optimization of multibody systems. To this end, the result shows an internal combustion engine's iterative topology optimization of the connecting rod and piston. Additionally, results from multiple load case problems have been presented to prove the effectiveness of the ESD methodology.

Presenting Author: Aakash Gupta Purdue University

Presenting Author Biography: Aakash Gupta is an Engineering Team Lead and Assistant System Validation Leader at Cummins, leading power cylinder and engine system-level design and validation developments for the high-volume medium duty engine series for the automotive and industrial applications. He is a PhD candidate in Mechanical Engineering at the Purdue University, West Lafayette. He obtained his MS in Aerospace and Mechanical Engineering, and BS in Mechanical Engineering from the Saint Louis University, in 2019 and 2016, respectively. His research and interest areas are product design and development, mechanical validation and testing, computation/analysis of mechanical systems, topology optimization, and tribology of advanced materials and coatings.

Authors:

Aakash Gupta Purdue University
Andres Tovar Indiana University–Purdue University Indianapolis