Analysis and Design of Maximum Power Point Tracking Scheme for Thermoelectric Battery Energy Storage System

Author

Kim, Rae-young ; Lai, Jih-Sheng ; York, B. ; Koran, Ahmed

Author_Institution

Future Energy Electron. Center, Virginia Polytech. Inst. & State Univ., Blacksburg, VA, USA

Volume

56

Issue

9

fYear

2009

Firstpage

3709

Lastpage

3716

Abstract

The analysis and design of an adaptive maximum power point tracking (MPPT) scheme using incremental impedance are presented. A small-signal model is mathematically derived, and the impact of two major design parameters, which are scaling factor and sampling interval, is analyzed in the frequency domain. Four factors which specifically affect the MPPT response are also clearly addressed. Based on this analysis, a design methodology to achieve a desirable transient response, while retaining system stability, is developed. The design methodology is implemented and verified with hardware experiments on a thermoelectric generator battery energy storage system, which indicate agreement between dynamic response and target bandwidth.

Keywords

energy storage; frequency-domain analysis; sampling methods; thermoelectric conversion; transient response; MPPT design methodology; frequency domain analysis; incremental impedance; maximum power point tracking scheme; sampling interval; scaling factor; small-signal model; system stability; thermoelectric battery energy storage system; transient response; Battery energy storage system (BESS); frequency-domain design; maximum power point tracking (MPPT); thermoelectric generator (TEG);

fLanguage

English

Journal_Title

Industrial Electronics, IEEE Transactions on

Publisher

ieee

ISSN

0278-0046

Type

jour

DOI

10.1109/TIE.2009.2025717

Filename

5130124