Global ETD Search

231	Development and Testing of Control Strategies for the Ohio State University EcoCAR Mobility Challenge Hybrid Vehicle Rangarajan, Hariharan January 2021 (has links) No description available. Automotive Engineering Mechanical Engineering
232	Multi Time-Scale Hierarchical Control for Connected and Autonomous Vehicles Boyle, Stephen January 2021 (has links) No description available. Automotive Engineering Engineering Mechanical Engineering Hierarchical Model Predictive Control MPC multi time-scale Connected and Autonomous Vehicles CAV Control Lagrange Multipliers Koopman Operator
233	Diagnosis of Evaporative Emissions Control System Using Physics-based and Machine Learning Methods Yang, Ruochen 24 September 2020 (has links) No description available. Automotive Engineering Mechanical Engineering Electrical Engineering Evaporative Emissions Control System Gasoline Evaporation Physics-based Model and Simulation Temporal Convolutional Network
234	”Feasibility-Labor”: erste Vorstellung neuer Ansätze zur Optimierung der Designumsetzung im Automobilbau Lender, Knut 03 January 2020 (has links) Premium- Automobile zu entwickeln, gehört zu den erklärten Unternehmenszielen der AUDI AG. Doch ein herausragendes Design und höchste Qualität in Serie zu bringen – wie funktioniert das eigentlich? [... aus der Einleitung] info:eu-repo/classification/ddc/620 ddc:620
235	Electrification of Diesel-Based Powertrains for Heavy Vehicles Tyler A Swedes (11153853) 22 July 2021 (has links) <div> In recent decades as environmental concerns and the cost and availability of fossil fuels have become more pressing issues, the need to extract more work from each drop of fuel has increased accordingly. Electrification has been identified as a way to address these issues in vehicles powered by internal combustion engines, as it allows existing engines to be operated more efficiently, reducing overall fuel consumption. Two applications of electrification are discussed in the work presented: a series-electric hybrid powertrain from an on-road class 8 truck, and an electrically supercharged diesel engine for use in the series hybrid power system of a wheel loader.</div><div> </div><div> The first application is an experimental powertrain developed by a small start-up company for use in highway trucks. The work presented in this thesis shows test results from routes along (1) Interstate 75 between Florence, KY, and Lexington, KY, and (2) Interstates 74 and 70 east of Indianapolis, during which tests the startup collected power flow data from the vehicle's motor, generator, and battery, and three-dimensional position data from a GPS system. Based on these data, it was determined that the engine-driven generator provided an average of 15% more propulsive energy than required due to electrical losses in the drivetrain. Some of these losses occured in the power electronics, which are shown to be 82% - 92% efficient depending on power flow direction, but the battery showed significant signs of wear, accounting for the remainder of these electrical losses. Overall, most of the system's fuel savings came from its regenerative braking capability, which recaptured between 3% and 12% of the total drive energy output. Routes with significant grade changes maximize this energy recapture percentage, but it is shown minimizing drag and rolling resistance with a more modern truck and trailer could further increase this energy capture to between 8% and 18%.</div><div> </div><div> In the second application, an electrified air handling system is added to a 4.5L engine, allowing it to replace the 6.8L engine in John Deere's 644K hybrid wheel loader. Most of the fuel savings arise from downsizing the engine, so in this case an electrically driven supercharger (eBooster) allows the engine to meet the peak torque requirements of the larger, original engine. In this thesis, a control-oriented nonlinear state space model of the modified 4.5L engine is presented and linearized for use in designing a robust, multi-input multi-output (MIMO) controller which commands the engine's fueling rate, eBooster, eBooster bypass valve, exhaust gas recirculation (EGR) valve, and exhaust throttle. This integrated control strategy will ultimately allow superior tracking of engine speed, EGR fraction, and air-fuel ratio (AFR) targets, but these performance gains over independent single-input single-output control loops for each component demand linear models that accurately represent the engine's gas exchange dynamics. To address this, a physics-based model is presented and linearized to simulate pressures, temperatures, and shaft speeds based on sub-models for exhaust temperature, cylinder charge flow, valve flow, compressor flow, turbine flow, compressor power, and turbine power. The nonlinear model matches the truth reference engine model over the 1200 rpm - 2000 rpm and 100 Nm - 500 Nm speed and torque envelope of interest within 10% in steady state and 20% in transient conditions. Two linear models represent the full engine's dynamics over this speed and torque range, and these models match the truth reference model within 20% in the middle of the operating envelope. However, specifically at (1) low load for any speed and (2) high load at high speed, the linear models diverge from the nonlinear and truth reference models due to nonlinear engine dynamics lost in linearization. Nevertheless, these discrepancies at the edges of the engine's operating envelope are acceptable for control design, and if greater accuracy is needed, additional linear models can be generated to capture the engine's dynamics in this region.</div> Hybrid Vehicles and Powertrains Automation and Control Engineering Internal combustion engines (ICEs) engine control Engine modeling Hybrid Powertrains
236	Investigating Surface Finish, Burr Formation and Tool Wear During Sustainable Machining of 3D Printed Carbon Fiber Reinforced Polymer (CFRP) Composites Cococcetta, Nicholas Michael 10 April 2020 (has links) No description available. Aerospace Engineering Mechanical Engineering Materials Science Polymers Automotive Engineering Automotive Materials Carbon fiber polymer CFRP 3D printed dry machining minimum quantity lubrication MQL cryogenic cooling aerospace automotive
237	Deep Learning Based Motion Forecasting for Autonomous Driving Dsouza, Rodney Gracian 07 October 2021 (has links) No description available. Artificial Intelligence Robotics Automotive Engineering Computer Science Electrical Engineering Autonomous Driving Motion Forecasting Motion Prediction Deep Learning Machine Learning Self-driving pipeline Autonomous Vehicles
238	Identifying Operating Conditions of Tires During Highway Driving Maneuvers Attravanam, Siddarth Kashyap January 2018 (has links) No description available. Automotive Engineering Mechanical Engineering tires tire testing wheel force transducer tire modeling pacejka scaling factors tire operating conditions track testing vehicle handling
239	Use of Connected Vehicle Technology for Improving Fuel Economy and Driveability of Autonomous Vehicles Tamilarasan, Santhosh 08 July 2019 (has links) No description available. Automotive Engineering Connected Vehicle V2X V2V Autonomous Vehicle Fuel Economy Optimal Control Fuel Economy Driveability Control Autonomous Vehicle Driveability Framework
240	Prediction of Aerodynamically Induced Hood Vibration of Trailing Vehicles Auza Gutierrez, Rodrigo 09 July 2019 (has links) No description available. Aerospace Engineering Automotive Engineering Engineering

Search results