5. System Design and Control Development for an Active Onboard Refueling Vapor Recovery System of Scooter

Abstract—This paper aims at developing a system design and control development for an active onboard refueling vapor recovery (ORVR) system of scooter. As recommended by the literatures, if the percentage of the ORVR-equipped scooters is higher than 70%, gas recovery system for gas stations is not required.

Step 1. Install ORVR on a scooter, and then compare its emission control performance with Stage II vapor recovery system.

Step 2. Develop passive ORVR components for scooter, including fuel tank, carbon canister, vapor pipe, fuel limit vent valve (FLVV), and surge protector.

Step 3. Develop active ORVR components for scooter, combining step 2. with electronic control, includes: solenoid valve, electronic control module (ECM), related connectors and consumables, follow-up will be planning motorcycle vapor pollution test of American.

2. System Design and Control Development for an Air/Electric Hybrid Scooter

Abstract— This paper aimed at developed a power source with the combination of an air motor and a servo motor. The test bench was used to measure the performance curves and characteristics. The Matlab/Simulink software package was to establish the simulator of the air/electric hybrid powertrain while to analyze the vehicle performance. This research studied the air motor module, the servo motor module, the lithium battery module, the transmission, the energy management strategy, and the driving patterns. The rule-based control strategy was developed; the parameter calibration and rule modification were conducted. The results of simulation and data from the real test were consistent, which indicated that this simulation platform and this approach of performance verification reduces the development period and the cost of trial-and-error experiments.

1. Rapid-Prototyping Designs for the Three-Power-Source Hybrid Electric Scooter with a Fuzzy-Control Energy Management 

Abstract—This study mainly develops a hardware-in-the-loop (HIL) platform for a hybrid electric scooter (HES). The fuzzy control strategy is utilized for the energy management among three power sources. A low-order scooter dynamics is constructed including subsystems such as the spark-ignition engine, high-power traction motor, integrated starter-generator (ISG), high-power battery module, transmission, longitudinal vehicle dynamics, etc.. For energy management of three power sources, the 73-rule fuzzy control is designed and compared to the traditional rule-based control. Three inputs are the battery state-of-charge (SOC), required torque and engine speed. Three outputs are torque commands for the engine, the motor, and the ISG. The system model and the energy management system are integrated for off-line simulation then. The verified models of control strategy and the vehicle dynamics are downloaded to two real-time simulators for the close-loop control with A/D D/A interface. Simulation results show that the vehicle model details the dynamics of key components, while the energy consumptions of these two control modes are nearly 170kJ under ECE40 driving cycle. This HIL platform can be used for rapid prototyping for vehicle control unit (VCU) designs of HES. The general vehicle model can be extended to various power-level hybrid vehicles with three power sources.