Power Systems Infrastructure of Hybrid Electric Fuel Cell Competition Go Kart

Joel Berry; Abdrahamane Traore; Aravind Krishna; Pavankumar Gangadhar; Allan Taylor

doi:10.4271/2017-01-2452

Power Systems Infrastructure of Hybrid Electric Fuel Cell Competition Go Kart

Joel Berry, Abdrahamane Traore, Aravind Krishna, Pavankumar Gangadhar, Allan Taylor

Kettering University

Research output: Contribution to journal › Article › peer-review

Abstract

This paper documents the electrical infrastructure design of a Hybrid Go Kart competition vehicle which includes a dual Fuel Cell power system, Ultra Capacitors for energy storage, and a dual AC induction motor capable of independent drive. The Kart was built primarily to compete in the 2009 Formula Zero international event. This paper emphasized the vehicle model and control strategy as a result of three (3) graduate student research projects. The vehicle was fabricated and tested but did not participate in the race competition since the race organization folded. The vehicle model was developed in Simulink to determine whether the fuel cell and ultra-capacitor combination will be sufficient for peak transient power requirement of 14 kW. The vehicle’s functional description and performance specifications are documented including the integration of the fuel cell power modules, energy storage system, power converters, and AC motor and motor controllers.

Original language	American English
Journal	SAE Technical Paper
DOIs	https://doi.org/10.4271/2017-01-2452
State	Published - Oct 8 2017

Keywords

Fuel cells
Energy storage systems

Disciplines

Electrical and Computer Engineering

Access to Document

10.4271/2017-01-2452License: CC BY

http://papers.sae.org/2017-01-2452

Cite this

@article{5b614854ff6e4cf59362bfb295ddc4ba,

title = "Power Systems Infrastructure of Hybrid Electric Fuel Cell Competition Go Kart",

abstract = " This paper documents the electrical infrastructure design of a Hybrid Go Kart competition vehicle which includes a dual Fuel Cell power system, Ultra Capacitors for energy storage, and a dual AC induction motor capable of independent drive. The Kart was built primarily to compete in the 2009 Formula Zero international event. This paper emphasized the vehicle model and control strategy as a result of three (3) graduate student research projects. The vehicle was fabricated and tested but did not participate in the race competition since the race organization folded. The vehicle model was developed in Simulink to determine whether the fuel cell and ultra-capacitor combination will be sufficient for peak transient power requirement of 14 kW. The vehicle{\textquoteright}s functional description and performance specifications are documented including the integration of the fuel cell power modules, energy storage system, power converters, and AC motor and motor controllers.",

keywords = "Fuel cells, Energy storage systems",

author = "Joel Berry and Abdrahamane Traore and Aravind Krishna and Pavankumar Gangadhar and Allan Taylor",

year = "2017",

month = oct,

day = "8",

doi = "10.4271/2017-01-2452",

language = "American English",

journal = "SAE Technical Paper",

}

TY - JOUR

T1 - Power Systems Infrastructure of Hybrid Electric Fuel Cell Competition Go Kart

AU - Berry, Joel

AU - Traore, Abdrahamane

AU - Krishna, Aravind

AU - Gangadhar, Pavankumar

AU - Taylor, Allan

PY - 2017/10/8

Y1 - 2017/10/8

N2 - This paper documents the electrical infrastructure design of a Hybrid Go Kart competition vehicle which includes a dual Fuel Cell power system, Ultra Capacitors for energy storage, and a dual AC induction motor capable of independent drive. The Kart was built primarily to compete in the 2009 Formula Zero international event. This paper emphasized the vehicle model and control strategy as a result of three (3) graduate student research projects. The vehicle was fabricated and tested but did not participate in the race competition since the race organization folded. The vehicle model was developed in Simulink to determine whether the fuel cell and ultra-capacitor combination will be sufficient for peak transient power requirement of 14 kW. The vehicle’s functional description and performance specifications are documented including the integration of the fuel cell power modules, energy storage system, power converters, and AC motor and motor controllers.

AB - This paper documents the electrical infrastructure design of a Hybrid Go Kart competition vehicle which includes a dual Fuel Cell power system, Ultra Capacitors for energy storage, and a dual AC induction motor capable of independent drive. The Kart was built primarily to compete in the 2009 Formula Zero international event. This paper emphasized the vehicle model and control strategy as a result of three (3) graduate student research projects. The vehicle was fabricated and tested but did not participate in the race competition since the race organization folded. The vehicle model was developed in Simulink to determine whether the fuel cell and ultra-capacitor combination will be sufficient for peak transient power requirement of 14 kW. The vehicle’s functional description and performance specifications are documented including the integration of the fuel cell power modules, energy storage system, power converters, and AC motor and motor controllers.

KW - Fuel cells

KW - Energy storage systems

UR - https://digitalcommons.kettering.edu/electricalcomp_eng_facultypubs/4

UR - http://papers.sae.org/2017-01-2452

U2 - 10.4271/2017-01-2452

DO - 10.4271/2017-01-2452

M3 - Article

JO - SAE Technical Paper

JF - SAE Technical Paper

ER -

Power Systems Infrastructure of Hybrid Electric Fuel Cell Competition Go Kart

Abstract

Keywords

Disciplines

Access to Document

Other files and links

Cite this