Investigation of the impact of splitter rotation speed on mode transition characteristics of an over-under turbine-based combined cycle inlet

This paper presents the findings of a wind tunnel experiment aimed at investigating the mode transition process of a two-dimensional over-under turbine-based combined cycle inlet at an incoming flow Mach number of 2.9. The study utilized high-speed schlieren and dynamic pressure acquisition systems...

Full description

Saved in:
Bibliographic Details
Published in:Physics of fluids (1994) 2024-08, Vol.36 (8)
Main Authors: Chen, Liang, Zhang, Yue, Yi-Xuan, Xu, Hui-Jun, Tan, Hong-Chao, Xue, Zi-Yun, Wang
Format: Article
Language:English
Subjects:
Air flow
Dynamic pressure
High speed
Hysteresis
Impact analysis
Mach number
Response time
Separation
Two dimensional flow
Unstart (engines)
Wind tunnel testing
Wind tunnels
Wind turbines
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:This paper presents the findings of a wind tunnel experiment aimed at investigating the mode transition process of a two-dimensional over-under turbine-based combined cycle inlet at an incoming flow Mach number of 2.9. The study utilized high-speed schlieren and dynamic pressure acquisition systems to examine the evolution process of the shock-dominated flow structure of the high-speed duct during the mode transition process. Additionally, the impact of mode transition speed on the unstart/restart characteristics of the high-speed duct was analyzed. The results indicate that, during the forward mode transition process, the increasing captured airflow of the high-speed duct leads to a higher number of shock reflections and the shock train moves forward in the duct, ultimately resulting in unstart. The unstarting flow field exhibits a small oscillation characteristic dominated by the separation bubble located at the entrance. However, evident hysteresis characteristics were observed in the restart process during the reverse transition. Furthermore, a higher mode transition speed delays the unstart and restart of the high-speed duct, consequently increasing the hysteresis interval. Theoretical analysis suggests that a larger mode transition speed leads to lower mass accumulation efficiency in the high-speed duct, thereby slowing the pressure response and causing the shock train to lag forward, resulting in delayed unstart. The delay in the restart process is attributed to the relative slip motion of the separation bubble with the upper surface of the splitter, in addition to its forced motion.
ISSN:1070-6631
1089-7666
DOI:10.1063/5.0218003