Theoretical and Experimental Study of Active Magnetic Bearing Control Integrated on Bently's Rotor Kit

Flores, Arturo Mario

01 August 2023

This thesis focuses on the comprehensive study of controlling a customized Active Magnetic Bearing (AMB) installed on Bently Nevada’s RK4 rotor kit in Cal Poly’s Vibrations and Rotordynamics Lab. The AMB was uniquely designed and manufactured by a Cal Poly senior project team to fit Bently’s rotor kit and the results of this research are distinctive to the custom system. To achieve practical functionality of the AMB system, we designed a controller a Virtual Instrument (VI) using the National Instrument software, LabVIEW. From the experimental study, we calibrated the programming to find unknown parameters of the AMB system and validated the design using a well-established industrial rotordyanmics software, Bentley Nevada System 1. The development of the control programming consists of theoretical analysis (MATLAB/ Simulink) and simulation validation (MSC ADAMS View). Both linear and non-linear models were implemented in MATLAB and Simulink to effectively tune a Proportional-Integral-Derivative (PID) control developed for various AMB models. To validate the theoretical results, we compared them to results from a co-simulation using MSC Adams VIEW, a multi-body dynamics simulation, and Simulink. From experimental trial and error at a shaft rotational speed of 2800 rpm, a 16% decrease in shaft orbit was achieved. These results demonstrate the practicality of the control program and custom AMB rotor kit that can be used for further research.

AMB Rotor

Bently Nevada

LabVIEW

Computer-Aided Engineering and Design

Dynamics and Dynamical Systems

Integrated Rotor Air Cooling System Design in Axial Flux Permanent Magnet Machines for Aerospace Applications

Zaher, Islam

January 2022

A Thesis Submitted to the School of Graduate Studies in Partial Fulfillment of the Requirements for the Degree of Master of Applied Science in Mechanical Engineering / In the wake of the rising global demand for more electric transportation, aerospace electrification is becoming a highly active research area as commercial fully electric aircrafts are becoming a reality. The transportation electrification industry is challenged to develop powerful, safe, and compact-sized machines that can replace fossil fuel powered engines in aircrafts. Axial Flux Permanent Magnets (AFPM) machines are currently being intensively developed as a great candidate for this purpose due to their inherently higher power density compared to other machine electric machines topologies. The efforts of further increasing AFPM machines power density add more thermal challenges as intensive cooling is required at a relatively small machine package to avoid machine failure. One of the most concerning failure modes in these machines is power output reduction due to overheating of the rotor-mounted permanent magnets or even complete failure due to irreversible demagnetization. This research discusses the design process of an integrated rotor air cooling system for a 100 kW AFPM machine designed for an electric aircraft propulsion system. The embedded cooling system allows the rotor to be self-cooled at a sufficient cooling rate while minimizing the impact on machine efficiency due to windage power losses. The presented design process includes several stages of cooling enhancement including the addition and fine-tuning of rotor fan blades and rotor vents design. These enhancements are done by studying the air flow over the rotor surfaces in conjunction with heat transfer through Conjugate Heat Transfer (CHT) Computational Fluid Dynamics (CFD) analyses. In an initial study, different rotors with different combinations of rotor cooling features are studied and their thermal performance is compared. The results show that using rotor embedded fan blades in throughflow ventilated rotor geometry offers the best performance balance, achieving sufficient rotor cooling rate within a reasonable increase of windage power loss. A parametric study is performed to improve the rotor blade geometry for a higher ratio of heat transfer to windage losses. Another study is performed where the rotor and the enclosure geometries are fine-tuned simultaneously to reduce the negative effect on rotor heat transfer imposed by the enclosure. The final geometry of the rotor enclosure assembly is generated based on the research results and the design is integrated into the final machine prototype to be tested. / Thesis / Master of Applied Science (MASc) / Axial-flux permanent magnets (AFPM) machines are gaining the transportation electrification industy attention as a greener alternative to combustion engines in aircraft propulsion systems due to their high power and torque density. The intense endeavors of the current research to further improve AFPM machines power densities brings thermal design challenges to ensure the safe operation of the machine. Rotor permanent magnets failure due to demagnetization as a result of overheating can impose a great risk to the machine operation and safety. Accordingly, special attention should be paid to rotor thermal management. This research discusses the design process of an integrated rotor air cooling system for an AFPM machine designed for an electric aircraft. The machine mechanical and thermal design parameters are used to set an initial rotor design with different rotor cooling features based on literature findings. Rotor fan blades and air vents are selected as the main rotor cooling features for the design. Several design iterations are then made to fine-tune the rotor geometry targeting low operating temperature of the permanent magnets at a low cost of windage losses. The thermal performance of the different designs is assessed and compared to each other using conjugate heat transfer (CHT) computational fluid dynamics (CFD) analyses. Safe operating temperature of the magnets is achieved at an acceptable windage losses value with the final design, and it is selected for prototyping.

Axial-flux permanent magnet machines

Aerospace Electrification

CFD

Rotor Cooling

Thermal Management

Turbomachinery

Characteristics of the nonlinear hysteresis loop for rotor-bearing instability

Guo, Jenq-Shan

January 1995

No description available.

Engineering, Aerospace

Nonlinear hysteresis loop

Instability threshold speed

Rotor-bearing instability

Exploratory Research on a Method for Detecting Shaft Radial Cracks: Severity, Location, and Feasibility

LaBerge, Kelsen

04 December 2008

No description available.

Engineering

Mechanical Engineering

crack

rotor

rotating machinery

elastic waves

crack detection

Dynamic Analysis Of A Rotor Bearing System

ElHibir, Sandi

29 June 2009

No description available.

Mechanical Engineering

Rotor bearing system

FEA

finite element analysis

permanent magnet alternator

PMA

Identification of Unmodeled Dynamics in Rotor Systems Using Mu-Synthesis Approach

Madden, Ryan J.

January 2010

No description available.

Mechanical Engineering

Model-Based Identification

ROTOR

Controller

UNMODELED DYNAMICS

¿¿¿¿-Synthesis

crack

Position, Attitude, and Fault-Tolerant Control of Tilting-Rotor Quadcopter

Kumar, Rumit

16 June 2017

No description available.

Aerospace Materials

Quadcopter

Fault Tolerance

Tilt-Rotor

Differential Flatness

PD Control

Stability

Modeling of Ground Effect Benefits for Multi-Rotor Small Unmanned Aerial Systems at Hover

Eberhart, Gina M.

January 2017

No description available.

Aerospace Engineering

Fluid Dynamics

Mechanical Engineering

sUAS

Ground Effect

VTOL

Multi-Rotor

BEMT

Aerodynamics

Coupled Multi-body Dynamic and Vibration Analysis of Hypoid and Bevel Geared Rotor System

Peng, Tao

06 December 2010

No description available.

Mechanical Engineering

Gear Dynamics

Hypoid Gear

Bevel Gear

Multi-body

Vibration

Rotor

Stochastic Mistuning Simulation of Integrally Bladed Rotors using Nominal and Non-Nominal Component Mode Synthesis Methods

Beck, Joseph A.

09 July 2010

No description available.

Engineering

Mechanical Engineering

Mistuning

Geometric Mistuning

Mistuning Simulation

Integrally Bladed Rotor

Nominal Component Mode Synthesis