Component size and effective thermal conductivity of printed circuit boards

被引:17
|
作者
Shabany, Y [1 ]
机构
[1] Appl Thermal Technol LLC, Santa Clara, CA 95051 USA
来源
ITHERM 2002: EIGHTH INTERSOCIETY CONFERENCE ON THERMAL AND THERMOMECHANICAL PHENOMENA IN ELECTRONIC SYSTEMS, PROCEEDINGS | 2002年
关键词
printed circuit board; thermal conductivity; thermal modeling; compact model;
D O I
10.1109/ITHERM.2002.1012496
中图分类号
O414.1 [热力学];
学科分类号
摘要
Numerical solutions of the three-dimensional heat conduction equation were used to study variation of the effective thermal conductivity of printed circuit boards (PCBs) with component size. Solutions were obtained for two PCB thicknesses, three numbers of internal copper layers, and different size components. Cases with and without a copper layer on the component side were investigated. It was shown that the effective thermal conductivity of a PCB with/without a copper layer on the component side would be larger/smaller than the values given by the one-dimensional effective thermal conductivity model if the components mounted on the PCB were smaller than the PCB itself. The difference was more pronounced for smaller components. Correlations were obtained for the effective thermal conductivity of PCBs.
引用
收藏
页码:489 / 494
页数:6
相关论文
共 50 条
  • [41] DYE PENETRANTS - AN AID TO CONDUCTIVITY FAULT LOCATION ON PRINTED-CIRCUIT BOARDS
    JOHN, EG
    [J]. BRITISH JOURNAL OF NON-DESTRUCTIVE TESTING, 1993, 35 (05): : 247 - 248
  • [42] Component temperature prediction in printed circuit boards with boundary integral method.
    Bambace, LAW
    Garcia, EC
    Melo, C
    [J]. ITHERM 2000: SEVENTH INTERSOCIETY CONFERENCE ON THERMAL AND THERMOMECHANICAL PHENOMENA IN ELECTRONIC SYSTEMS, VOL 2, PROCEEDINGS, 2000, : 94 - 101
  • [43] Keypoint-Based Automated Component Placement Inspection for Printed Circuit Boards
    Chung, Si-Tung
    Hwang, Wen-Jyi
    Tai, Tsung-Ming
    Oh, Ki-Yong
    [J]. APPLIED SCIENCES-BASEL, 2023, 13 (17):
  • [44] Hydrometallurgical treatment of used printed circuit boards after thermal treatment
    Havlik, T.
    Orac, D.
    Petranikova, M.
    Miskufova, A.
    [J]. WASTE MANAGEMENT, 2011, 31 (07) : 1542 - 1546
  • [45] Applying strain gauges to measuring thermal warpage of printed circuit boards
    Huang, Chien-Yi
    Ying, Kuo-Ching
    [J]. MEASUREMENT, 2017, 110 : 239 - 248
  • [46] Thermal stability analysis of passive components embedded into printed circuit boards
    Steplewski, Wojciech
    Dziedzic, Andrzej
    Janeczek, Kamil
    Arazna, Aneta
    Lipiec, Krzysztof
    Borecki, Janusz
    Serzysko, Tomasz
    [J]. CIRCUIT WORLD, 2018, 44 (01) : 29 - 36
  • [47] Selection of appropriate thermal model for printed circuit boards in CFD analysis
    Shankaran, Gokul V.
    Singh, Rahul K.
    [J]. 2006 PROCEEDINGS 10TH INTERSOCIETY CONFERENCE ON THERMAL AND THERMOMECHANICAL PHENOMENA IN ELECTRONICS SYSTEMS, VOLS 1 AND 2, 2006, : 234 - +
  • [48] Asymptotic thermal analysis of electronic packages and printed-circuit boards
    Liu, DG
    Phanilatha, V
    Zhang, QJ
    Nakhla, MS
    [J]. IEEE TRANSACTIONS ON COMPONENTS PACKAGING AND MANUFACTURING TECHNOLOGY PART A, 1995, 18 (04): : 781 - 787
  • [49] Polyetheretherketone films with low thermal expansion for flexible printed circuit boards
    Seidel, C.
    Muenstedt, H.
    [J]. INTERNATIONAL POLYMER PROCESSING, 2008, 23 (01) : 103 - 109
  • [50] Thermal Considerations of a Power Converter With Components Embedded in Printed Circuit Boards
    Caillaud, Remy
    Buttay, Cyril
    Mrad, Roberto
    Le Lesle, Johan
    Morel, Florent
    Degrenne, Nicolas
    Mollov, Stefan V.
    [J]. IEEE TRANSACTIONS ON COMPONENTS PACKAGING AND MANUFACTURING TECHNOLOGY, 2020, 10 (02): : 230 - 239
12345