November 24, 2024
Rouhollah Fatehi

Rouhollah Fatehi

Academic Rank: Associate professor
Address: School of Engineering
Degree: Ph.D in Mechanical Engineering
Phone: 07731222170
Faculty: Faculty of Engineering

Research

Title Fracture Analysis of Compressor Impellers in Olefin Units: Numerical and Metallurgical Approach
Type Article
Keywords
7175 aluminum alloy, compressor impellers, 3D point cloud data
Journal Advances in Materials Science and Engineering
DOI https://doi.org/10.1155/2022/5367695
Researchers Mojtaba Esmailzadeh (First researcher) , maryam delshe (Second researcher) , S Mina Amirsadat (Third researcher) , Ahmad Azari (Fourth researcher) , Rouhollah Fatehi (Fifth researcher) , Mohsen Rezaei (Not in first six researchers) , Hasan Bazai (Not in first six researchers) , Mohsen Sharifpur (Not in first six researchers)

Abstract

,is paper presents a failure analysis conducted in 7175 aluminum alloy compressor impellers used in olefin units which operate at 34500 rpm to compress gas in the process. Some characterizations such as chemical composition, microstructure, and hardness tests were conducted to obtain a detailed evaluation of the base alloy. Furthermore, a finite element method and a 3D point cloud data technique have used to determine critical stress points on the surface of impellers. ,e finite element result showed the root of blades has significant stress concentration. Moreover, the formed cyclic tension has led to a fatigue phenomenon in the root of the blade, so near this location, the local strain accumulation was visible in 3D points cloud data. ,e fractography results showed that the mode of crack progression and the fractured surface would change by changing the stress mode. In addition, CFD modeling for investigating the effect of flow hydrodynamics on the HP and LP compressor blades is analyzed. ,e results revealed that the maximum pressure of gas stream for the rotor speed of 34500 had taken place in the area of a blade that already breakdown took place, and the changes of pressure, stress, and temperature gradients of flow in the HP compressor were significantly higher than the LP compressor.