Virtual Prototype Simulation of Fine-Adjustment System Kinematics for Segment Erector of Tunnel Boring Machine

Gang Li; Ya Dong Chen; Bo Wang; Wan Shan Wang

doi:10.4028/www.scientific.net/AMR.490-495.3883

Paper Titles

The Synthesis and Ion-Exchange Property of Li⁺ Memorized Inverse Spinel Al_0.75Fe_1.25(PO₄)₂
p.3864

Ti Microalloying Effect on Corrosion Resistance and Thermal Stability of Cu₄₅Zr₄₈A_l7 Bulk Metallic Glass
p.3868

Theoretical Investigations of the High-Pressure Optical Properties of γ-Si₃N₄
p.3874

Mold Material Selection and Development Trends
p.3878

Virtual Prototype Simulation of Fine-Adjustment System Kinematics for Segment Erector of Tunnel Boring Machine
p.3883

Use of Versatile Binaphthalene Derivative in Chromatic-Stability Non-Doped White Organic Light Emitting Diodes
p.3887

The Influence of Different Ph Values and High Concentrations of Na₂SO₄ and NaCl on the Photocatalytic Oxidation (PCO) of Methylene Blue (MB) by Aqueous Suspension of Nano-Sized TiO₂
p.3892

The Preparation of Al–Cu–Fe Quasicrystalline Coating by Low Power Plasma Spraying
p.3897

The Comparative Analysis of Cushion or Shock Absorption Characteristic of Commonly-Used Cushion Packaging Materials
p.3902

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 490-495Virtual Prototype Simulation of Fine-Adjustment...

Virtual Prototype Simulation of Fine-Adjustment System Kinematics for Segment Erector of Tunnel Boring Machine

Abstract:

In this paper, we present the modeling and kinematics simulation of fine-adjustment system for segment erector of tunnel boring machine (TBM), which is performed in the virtual prototype platform. The 3D virtual assembling model of fine-adjustment system is built with Pro/E software according to its design parameters such as structure and size. After the interference inspection, the model is imported into ADAMS through the interface module of Mech/Pro. The model is simplified and optimized reasonably and various constraints are applied under variety working conditions. The results of simulation show that the design has three degrees of freedom movement capacity which meets the design requirements. At the same time the kinematics characteristics of each part along three different directions are obtained and they will provide some references for the further optimal design.