Chapter 1 Introduction.- Chapter 2 Propulsion integration.- Chapter 3 A theoretical analysis of boundary layer ingestion and wake ingestion.- Chapter 4 Power based analysis of boundary layer ingestion through numerical simulations.- Chapter 5 Experimental study of the flow mechanisms associated with a propulsor ingesting a body wake.- Chapter 6 Conclusions and Recommendations.

Like many boys, Peijian Lv was fascinated with aircraft in his childhood. He was lucky enough to study aerospace engineering in universities. In 2007, Peijian Lv received his B.E. degree in flight vehicle propulsion engineering from Northwestern Polytechnical University, China. From the same university, he obtained his M.Sc. degree in flight vehicle design engineering in 2011. With the learned knowledge of aircraft propulsion and airframe aerodynamics, he decided to explore the domain where propulsion system and airframe are tightly integrated. Boundary Layer Ingestion is the topic for his Ph.D. study. In 2019, he obtained his Doctoral degree in aerospace engineering from Delft University of Technology, Delft, the Netherlands. Since 2020, he has been working as a postdoctoral researcher in the School of Aerospace Engineering, Beijing Institute of Technology, Beijing, China. His research interests focus on aircraft propulsion, aircraft aerodynamics, and airframe propulsion integration.

This book presents research on Boundary Layer Ingestion (BLI). BLI is an aircraft-engine integration technique that aims at integrating the aircraft and the propulsion system such that the overall aircraft fuel consumption can be reduced. In this research, theoretical analysis suggests that the minimization of total power consumption should be used as a design criterion for aircraft utilizing BLI rather than focusing on the minimization of drag. Numerical simulations are performed, and the simulation results are processed using the PBM to support the theoretical analysis. Furthermore, an experimental study is carried out with a focus on the power conversion processes involved for a propulsor operating in the wake. Stereoscopic PIV is employed in order to visualize the flow and understand the physics. The so-called Power-based Method is used to quantify the power conversion mechanisms. The results prove that the dominant mechanism responsible for the efficiency enhancement is due to the utilization of body wake energy by the wake ingesting propeller. In short, the importance of wake energy flow rate in understanding the BLI phenomenon is highlighted. This book will be useful for researchers in the field of aircraft propulsion, aircraft aerodynamics, and airframe propulsion integration.