Proposal of potted inductor with enhanced thermal transfer for high power boost converter in HEVs
- Authors
- You B.-G.[You B.-G.]; Ko J.-M.[Ko J.-M.]; Kim J.-H.[Kim J.-H.]; Lee B.-K.[Lee B.-K.]
- Issue Date
- May-2015
- Publisher
- 대한전기학회
- Keywords
- Mega Flux®; Potted structure inductor; Boost converter of HEV; High current inductor; Potting material.
- Citation
- Journal of Electrical Engineering and Technology, v.10, no.3, pp.1075 - 1080
- Indexed
- SCIE
SCOPUS
KCI
- Journal Title
- Journal of Electrical Engineering and Technology
- Volume
- 10
- Number
- 3
- Start Page
- 1075
- End Page
- 1080
- URI
- https://scholarworks.bwise.kr/skku/handle/2021.sw.skku/44045
- DOI
- 10.5370/JEET.2015.10.3.1075
- ISSN
- 1975-0102
- Abstract
- A hybrid electric vehicle (HEV) powertrain has more than one energy source including a high-voltage electric battery .However, for a high voltage electric battery, the average current is relatively low for a given power level. Introduced to increase the voltage of a HEV battery, a compact, high-efficiency boost converter, sometimes called a step-up converter, is a dc-dc converter with an output voltage greater than its input voltage. The inductor occupies more than 30% of the total converter volume making it difficult to get high power density. The inductor should have the characteristics of good thermal stability, low weight, low losses and low EMI. In this paper, Mega Flux ® was selected as the core material among potential core candidates. Different structured inductors with Mega Flux ® were fabricated to compare the performance between the conventional air cooled and proposed potting structure. The proposed inductor has reduced the weight by 75% from 8.8kg to 2.18kg and the power density was increased from 15.6W/cc to 56.4W/cc compared with conventional inductor. To optimize the performance of proposed inductor, the potting materials with various thermal conductivities were investigated. Silicone with alumina was chosen as potting materials due to the high thermo-stable properties. The proposed inductors used potting material with thermal conductivities of 0.7W/m·K, 1.0W/m·K and 1.6W/m·K to analyze the thermal performance. Simulations of the proposed inductor were fulfilled in terms of magnetic flux saturation, leakage flux and temperature rise. The temperature rise and power efficiency were measured with the 40kW boost converter. Experimental results show that the proposed inductor reached the temperature saturation of 107°C in 20 minutes. On the other hand, the temperature of conventional inductor rose by 138°C without saturation. And the effect of thermal conductivity was verified as the highest thermal conductivity of potting materials leads to the lowest temperature saturations. © 2015, The Korean Institute of Electrical Engineers.
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