Exploring the influence of initial design domain dependencies in concurrent multiscale topology optimization for heat conductivity maximization

Abstract

Advancements in additive manufacturing have led to the widespread adoption of topology and shape optimization in the design process across various industrial applications. Topology optimization has emerged as a promising approach for creating ultra-lightweight structures with exceptional functionality. By designing porous structures and addressing the layout of pores, concurrent multiscale topology optimization schemes offer a means to achieve such outcomes. This paper focuses on the development of a multiscale topology optimization tool and presents a numerical investigation of the initial design domain's impact on maximizing heat conductivity through concurrent multiscale topology optimization. The study highlights the significant influence of the initial design domain in the microscale on the final microscale design. Moreover, modifying the initial micro design domain has a direct impact on the macro design domain. The findings underscore the importance of considering the initial design domain when aiming to maximize heat conductivity through concurrent multiscale topology optimization. To facilitate the replication of the results presented in this paper, comprehensive details regarding parameter settings and implementation aspects are provided.