Friction Riveting of FR4 substrates for printed circuit boards: Influence of process parameters on process temperature development and joint properties

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Friction Riveting of FR4 substrates for printed circuit boards: Influence of process parameters on process temperature development and joint properties. / Rodrigues, Camila.F.; Blaga, Lucian; Klusemann, Benjamin.
In: Journal of Materials Research and Technology, Vol. 24, 01.05.2023, p. 4639-4649.

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@article{cd1e23d4e2394b56a76e64bf05c38d8a,
title = "Friction Riveting of FR4 substrates for printed circuit boards: Influence of process parameters on process temperature development and joint properties",
abstract = "This work investigates the influence of Friction Riveting processing conditions on FR4-PCB substrate/AA2024 rivet joints in terms of process temperature evolution, joint formation, and joint physical-chemical and mechanical properties. The joints were manufactured using 4 mm diameter AA-2024-T3 rivets and FR4 laminates of 1.5 mm thickness with single or double copper-clad layers. The evolution of process temperature evolution was recorded on the FR4 substrate surface and correlated with the resulting joint formation. Most joints obtained with double copper clad layers developed process temperatures above 300 °C, whereas joints produced with a single copper clad presented slightly lower temperatures, but still above 250 °C. Rivet anchoring was achieved for both FR4 material combinations in the configuration of a single-base laminate, as well as two and even three overlapped laminates. Thermogravimetric analyses revealed that above 300 °C intensive thermal degradation occurs on FR4 materials (with 30% mass change), followed by decomposition, resulting in non-uniform heat distribution throughout the thickness. The joint ultimate tensile force was higher for double copper-clad layers and the joints achieved within more than one laminate, showing higher anchoring efficiency.",
keywords = "Printed circuit board, FR4, friction riveting, hybrid materials, joint formation, Engineering",
author = "Camila.F. Rodrigues and Lucian Blaga and Benjamin Klusemann",
note = "Funding Information: This work is supported by the Helmholtz-Zentrum Hereon technology transfer fund in cooperation with Panasonic Industrial Devices Europe GmbH within the “FricBoard” project. This support is gratefully acknowledged. Publisher Copyright: {\textcopyright} 2023 The Authors",
year = "2023",
month = may,
day = "1",
doi = "10.1016/j.jmrt.2023.04.092",
language = "English",
volume = "24",
pages = "4639--4649",
journal = "Journal of Materials Research and Technology",
issn = "2238-7854",
publisher = "Elsevier B.V.",

}

RIS

TY - JOUR

T1 - Friction Riveting of FR4 substrates for printed circuit boards

T2 - Influence of process parameters on process temperature development and joint properties

AU - Rodrigues, Camila.F.

AU - Blaga, Lucian

AU - Klusemann, Benjamin

N1 - Funding Information: This work is supported by the Helmholtz-Zentrum Hereon technology transfer fund in cooperation with Panasonic Industrial Devices Europe GmbH within the “FricBoard” project. This support is gratefully acknowledged. Publisher Copyright: © 2023 The Authors

PY - 2023/5/1

Y1 - 2023/5/1

N2 - This work investigates the influence of Friction Riveting processing conditions on FR4-PCB substrate/AA2024 rivet joints in terms of process temperature evolution, joint formation, and joint physical-chemical and mechanical properties. The joints were manufactured using 4 mm diameter AA-2024-T3 rivets and FR4 laminates of 1.5 mm thickness with single or double copper-clad layers. The evolution of process temperature evolution was recorded on the FR4 substrate surface and correlated with the resulting joint formation. Most joints obtained with double copper clad layers developed process temperatures above 300 °C, whereas joints produced with a single copper clad presented slightly lower temperatures, but still above 250 °C. Rivet anchoring was achieved for both FR4 material combinations in the configuration of a single-base laminate, as well as two and even three overlapped laminates. Thermogravimetric analyses revealed that above 300 °C intensive thermal degradation occurs on FR4 materials (with 30% mass change), followed by decomposition, resulting in non-uniform heat distribution throughout the thickness. The joint ultimate tensile force was higher for double copper-clad layers and the joints achieved within more than one laminate, showing higher anchoring efficiency.

AB - This work investigates the influence of Friction Riveting processing conditions on FR4-PCB substrate/AA2024 rivet joints in terms of process temperature evolution, joint formation, and joint physical-chemical and mechanical properties. The joints were manufactured using 4 mm diameter AA-2024-T3 rivets and FR4 laminates of 1.5 mm thickness with single or double copper-clad layers. The evolution of process temperature evolution was recorded on the FR4 substrate surface and correlated with the resulting joint formation. Most joints obtained with double copper clad layers developed process temperatures above 300 °C, whereas joints produced with a single copper clad presented slightly lower temperatures, but still above 250 °C. Rivet anchoring was achieved for both FR4 material combinations in the configuration of a single-base laminate, as well as two and even three overlapped laminates. Thermogravimetric analyses revealed that above 300 °C intensive thermal degradation occurs on FR4 materials (with 30% mass change), followed by decomposition, resulting in non-uniform heat distribution throughout the thickness. The joint ultimate tensile force was higher for double copper-clad layers and the joints achieved within more than one laminate, showing higher anchoring efficiency.

KW - Printed circuit board

KW - FR4

KW - friction riveting

KW - hybrid materials

KW - joint formation

KW - Engineering

UR - http://www.scopus.com/inward/record.url?scp=85153315323&partnerID=8YFLogxK

U2 - 10.1016/j.jmrt.2023.04.092

DO - 10.1016/j.jmrt.2023.04.092

M3 - Journal articles

VL - 24

SP - 4639

EP - 4649

JO - Journal of Materials Research and Technology

JF - Journal of Materials Research and Technology

SN - 2238-7854

ER -

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