37 / 2021-10-01 19:56:27
Reliability and Multi-scale Design Optimization of Fiber-reinforced Composite Structures with Manufacturing Constraints
Marine Engineering,Concurrent Multi-scale Design Optimization,Reliability-based Design Optimization,Discrete Material Optimization,Single Loop Single Vector
Abstract Pending
DuanZunyi / Northwestern Polytechnical University
军阎 / 大连理工大学
Fiber-reinforced composite material has been widely used in marine engineering, especially for wind turbine blades, advanced ship structure, and offshore structure. The paper proposes an efficient methodology for concurrent reliability-based multi-scale design optimization (RBMDO) of composite frames to minimize structural cost subjecting to compliance constraint. Two types of variables are systematically considered in RBMDO, which are deterministic design variables of the frame components, the discrete fiber winding angles at the two geometrical scales, and random parameters of material properties and loading conditions in both magnitude and direction. To overcome the difficulty of highly nonlinear compliance constraint when using fiber winding angles as design variables and improve efficiency and accuracy of RBMDO of composite frames, the improved single loop and single vector (SLSV) approach based on modified chaos control (MCC) scheme, which is abbreviated hereafter as SLSV-MCC, is proposed, and sensitivities at the current design point are utilized to further increase accuracy of the proposed SLSV-MCC. Six types of specific manufacturing constraints are explicitly considered in the proposed RBMDO to reduce the risk of local failure in the laminated composite. The deterministic multi-scale design optimization (DMDO) model is also presented and utilized for comparison to distinguish differences between deterministic and reliability-based optimization results. Efficiency and accuracy of the proposed SLSV-MCC are compared with the first order reliability method (FORM) and conventional SLSV approach. Meanwhile, the Monte Carlo simulation (MCS) method is further utilized to validate the accuracy of the proposed RBMDO. The discrete material optimization (DMO) approach is utilized to couple two geometrical scales: macroscopic topology and microscopic material selection. Capabilities of the proposed RBMDO are demonstrated by optimization of 2D and 3D composite frames. Numerical study reveals that the uncertainties in material properties and loading conditions will lead to different macroscopic sizing and topology configurations for deterministic and reliability-based solutions.
Important Date
  • Conference Date

    Oct 22

    2021

    to

    Oct 25

    2021

  • Sep 15 2021

    Early Bird Registration

  • Oct 25 2021

    Registration deadline

Sponsored By
SUT 中国分会
大连理工大学
中国石油大学(北京)
Supported By
辽宁省力学学会
大连市科学技术协会
工业装备结构分析国家重点实验室
海岸和近海工程国家重点实验室
橡塑制品成型数值模拟与优化学科创新引智基地
大连理工大学宁波研究院
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