Purpose

This study aims to optimize the manufacturing process to improve the manufacturing quality, costs and delivering time with the help of multiscale multiphysics modelling and simulation. Multiscale multiphysics-based modelling and simulations are receiving more and more interest by research community and the industry particularly in the context of increasing demands for manufacturing high precision complex products and understanding the intrinsic complexity in associated manufacturing processes.

Design/methodology/approach

In this paper, some modelling and analysis techniques using multiscale multiphysics modelling are presented and discussed.

Findings

Furthermore, the possibility of adopting the multiscale multiphysics modelling and simulation to develop the virtual machining system is evaluated, and further supported with an industrial case study on abrasive flow machining (AFM) of integrally bladed rotors using the techniques and system developed.

Originality/value

With the development of multiscale multiphysics-based modelling and simulation, it will enable effective and efficient optimisation of manufacturing processes and further improvement of manufacturing quality, costs, delivery time and the overall competitiveness.

中文翻译：

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开发基于多尺度多物理场的建模和仿真，并应用于机翼结构的精密加工

目的

本研究旨在借助多尺度多物理场建模和仿真来优化制造过程，以提高制造质量、成本和交付时间。基于多尺度多物理场的建模和仿真越来越受到研究界和行业的关注，特别是在制造高精度复杂产品的需求不断增加和了解相关制造过程的内在复杂性的背景下。

设计/方法/方法

在本文中，介绍和讨论了一些使用多尺度多物理场建模的建模和分析技术。

发现

此外，还评估了采用多尺度多物理场建模和仿真来开发虚拟加工系统的可能性，并进一步支持使用开发的技术和系统对整体叶片转子进行磨粒流加工 (AFM) 的工业案例研究。

原创性/价值

随着基于多尺度多物理场的建模和仿真的发展，它将能够有效、高效地优化制造过程，进一步提高制造质量、成本、交货时间和整体竞争力。