Design for Reliability in Renewable Energy Systems

Frede Blaabjerg; Dao Zhou; Ariya Sangwongwanich; Huai Wang

doi:10.1109/PEE.2017.8171658

Design for Reliability in Renewable Energy Systems

Frede Blaabjerg, Dao Zhou, Ariya Sangwongwanich, Huai Wang

Research output: Contribution to book/anthology/report/conference proceeding › Article in proceeding › Research › peer-review

15 Citations (Scopus)

Abstract

Power electronics are widely used in renewable energy systems to achieve lower cost of energy, higher efficiency and high power density. At the same time, the high reliability of the power electronics products is demanded, in order to reduce the failure rates and ensure cost-effective operation of the renewable energy systems. This paper thus describes the basic concepts used in reliability engineering, and presents the status and future trends of Design for Reliability (DfR) in power electronics, which is currently undergoing a paradigm shift to a physics-of-failure approach. Two case studies of a 2 MW wind turbine system and a 6 kW photovoltaic system are presented to demonstrate the use of the DfR approach as a design tool to predict lifetime of components (e.g., power devices) as well as the overall systems (e.g., power converters) based on the required operating conditions (i.e., mission profile).

Original language	English
Title of host publication	Proceedings of 2017 International Symposium on Power Electronics (Ee)
Number of pages	6
Publisher	IEEE Press
Publication date	Oct 2017
ISBN (Electronic)	978-1-5386-3502-5
DOIs	https://doi.org/10.1109/PEE.2017.8171658
Publication status	Published - Oct 2017
Event	2017 International Symposium on Power Electronics (Ee) - Novi Sad, Serbia Duration: 19 Oct 2017 → 21 Oct 2017

Conference

Conference	2017 International Symposium on Power Electronics (Ee)
Country/Territory	Serbia
City	Novi Sad
Period	19/10/2017 → 21/10/2017

Keywords

Design for reliability
Physics of failure
Reliability
Power electronics
Renewable energy systems

Access to Document

10.1109/PEE.2017.8171658

AUB Link

Search for the material in Aalborg University Library's search engine

APETT: Advanced Power Electronic Technology and Tools
Blaabjerg, F. (PI), Munk-Nielsen, S. (CoI), Iannuzzo, F. (Project Participant), Wang, H. (Project Participant), Uhrenfeldt, C. (Project Participant), Beczkowski, S. (Project Participant), Zhou, D. (Project Participant), Choi, U. (Project Participant), Jørgensen, A. B. (Project Participant), Vernica, I. (Project Participant), Sangwongwanich, A. (Project Participant), Christensen, N. (Project Participant), Ceccarelli, L. (Project Participant), Nielsen, C. K. (Project Participant), Bahman, A. S. (Project Participant), Pedersen, K. (Project Participant), Pedersen, K. B. (Project Participant) & Kristensen, P. K. (Project Participant)
Innovation Fund Denmark
01/01/2017 → 30/06/2021
Project: Research
Center Of Reliable Power Electronics (CORPE)
Blaabjerg, F. (PI), Munk-Nielsen, S. (Project Participant), Pedersen, K. (Project Participant) & Popok, V. (Project Participant)
01/04/2011 → 31/12/2016
Project: Research

Cite this

@inproceedings{15ddc6758f20468b9dcdca16e3980197,

title = "Design for Reliability in Renewable Energy Systems",

abstract = "Power electronics are widely used in renewable energy systems to achieve lower cost of energy, higher efficiency and high power density. At the same time, the high reliability of the power electronics products is demanded, in order to reduce the failure rates and ensure cost-effective operation of the renewable energy systems. This paper thus describes the basic concepts used in reliability engineering, and presents the status and future trends of Design for Reliability (DfR) in power electronics, which is currently undergoing a paradigm shift to a physics-of-failure approach. Two case studies of a 2 MW wind turbine system and a 6 kW photovoltaic system are presented to demonstrate the use of the DfR approach as a design tool to predict lifetime of components (e.g., power devices) as well as the overall systems (e.g., power converters) based on the required operating conditions (i.e., mission profile).",

keywords = "Design for reliability, Physics of failure, Reliability , Power electronics, Renewable energy systems",

author = "Frede Blaabjerg and Dao Zhou and Ariya Sangwongwanich and Huai Wang",

year = "2017",

month = oct,

doi = "10.1109/PEE.2017.8171658",

language = "English",

booktitle = "Proceedings of 2017 International Symposium on Power Electronics (Ee)",

publisher = "IEEE Press",

note = "2017 International Symposium on Power Electronics (Ee) ; Conference date: 19-10-2017 Through 21-10-2017",

}

TY - GEN

T1 - Design for Reliability in Renewable Energy Systems

AU - Blaabjerg, Frede

AU - Zhou, Dao

AU - Sangwongwanich, Ariya

AU - Wang, Huai

PY - 2017/10

Y1 - 2017/10

N2 - Power electronics are widely used in renewable energy systems to achieve lower cost of energy, higher efficiency and high power density. At the same time, the high reliability of the power electronics products is demanded, in order to reduce the failure rates and ensure cost-effective operation of the renewable energy systems. This paper thus describes the basic concepts used in reliability engineering, and presents the status and future trends of Design for Reliability (DfR) in power electronics, which is currently undergoing a paradigm shift to a physics-of-failure approach. Two case studies of a 2 MW wind turbine system and a 6 kW photovoltaic system are presented to demonstrate the use of the DfR approach as a design tool to predict lifetime of components (e.g., power devices) as well as the overall systems (e.g., power converters) based on the required operating conditions (i.e., mission profile).

AB - Power electronics are widely used in renewable energy systems to achieve lower cost of energy, higher efficiency and high power density. At the same time, the high reliability of the power electronics products is demanded, in order to reduce the failure rates and ensure cost-effective operation of the renewable energy systems. This paper thus describes the basic concepts used in reliability engineering, and presents the status and future trends of Design for Reliability (DfR) in power electronics, which is currently undergoing a paradigm shift to a physics-of-failure approach. Two case studies of a 2 MW wind turbine system and a 6 kW photovoltaic system are presented to demonstrate the use of the DfR approach as a design tool to predict lifetime of components (e.g., power devices) as well as the overall systems (e.g., power converters) based on the required operating conditions (i.e., mission profile).

KW - Design for reliability

KW - Physics of failure

KW - Reliability

KW - Power electronics

KW - Renewable energy systems

U2 - 10.1109/PEE.2017.8171658

DO - 10.1109/PEE.2017.8171658

M3 - Article in proceeding

BT - Proceedings of 2017 International Symposium on Power Electronics (Ee)

PB - IEEE Press

T2 - 2017 International Symposium on Power Electronics (Ee)

Y2 - 19 October 2017 through 21 October 2017

ER -

Design for Reliability in Renewable Energy Systems

Abstract

Conference

Keywords

Access to Document

AUB Link

Fingerprint

Projects

APETT: Advanced Power Electronic Technology and Tools

Center Of Reliable Power Electronics (CORPE)

Cite this