Realization of Anti-Lock Braking Strategy for Electric Scooters

Author

Weng-Ching Lin ; Chun-Liang Lin ; Ping-Min Hsu ; Wu, Meng-tzong

Author_Institution

Dept. of Electr. Eng., Nat. Chung Hsing Univ., Taichung, Taiwan

Volume

61

Issue

6

fYear

2014

fDate

Jun-14

Firstpage

2826

Lastpage

2833

Abstract

This research studies a novel method of realizing a nonmechanical antilock braking system (ABS) controller for electric scooters (ESs) based on regenerative, kinetic, and short-circuit braking mechanisms. In which, a boundary layer speed control is proposed for a guarantee of the optimal slip ratio between tires and road surface. The antilock braking controller, combined with this controller, drives a low-side driving circuit to induce either an open-circuit or a short-circuit loop on the motor stator´s coil to a load; it thus produces braking actions analogous to those in the conventional ABS control. The proposed ABS controller is practically realized. Improvement of the braking performance for the ABS action is further addressed via real-world experiments.

Keywords

angular velocity control; braking; motorcycles; ES; antilock braking strategy; boundary layer speed control; conventional ABS control; electric scooters; kinetic braking mechanism; low-side driving circuit; motor stator coil; nonmechanical ABS controller; nonmechanical antilock braking system controller; open-circuit loop; optimal slip ratio; regenerative braking mechanism; road surface; short-circuit braking mechanism; short-circuit loop; tires; Batteries; Digital signal processing; Kinetic theory; Roads; Torque; Vehicles; Wheels; Antilock braking system (ABS); boundary layer control; electric vehicle (EV); short circuit braking;

fLanguage

English

Journal_Title

Industrial Electronics, IEEE Transactions on

Publisher

ieee

ISSN

0278-0046

Type

jour

DOI

10.1109/TIE.2013.2276775

Filename

6603352