TY - GEN
T1 - Insertion behavior study of multi-material self-piercing rivet joints by means of finite element simulation
AU - Varela, Sonia
AU - Mangas, Ángela
AU - Kotercova, Zuzana
AU - Briskham, Paul
AU - Giménez, María
AU - Muñoz, Carlos
AU - Molina, Ricardo
AU - Santos, Maite
N1 - Publisher Copyright:
© 2019 Author(s).
PY - 2019/7/2
Y1 - 2019/7/2
N2 - Over the last few years, fuel economy improvement has driven the use of efficient multi-material structures in the car industry. The combination of dissimilar materials, such as metal-metal and metal-polymer, is a complex issue that requires the use of different and emerging joining techniques. In this context, self-pierce riveting (SPR) is an extremely suitable technique for joining two or more metal sheets, particularly when other techniques are not applicable. SPR requires short manufacturing times and provides both high strength and high fatigue resistance. Yet, this technique still faces some hurdles, such as joining Ultra High Strength Steels (UHSS) with high strength low ductility aluminum alloys, which can result in rivet cracking or aluminum button tearing. Suitable process parameters, including the rivet size and the die profile, are usually obtained through a physical testing procedure to satisfy the required joint specification. This is both expensive and time consuming. Finite element simulations of SPR are being increasingly used to reduce the number of physical tests and to estimate the tensile strength of the joint. The capability to accurately simulate aluminum to aluminum riveting has been demonstrated in recent studies. However, very few simulation studies have been conducted on the riveting of UHSS to aluminum, mainly because this type of joint is a relatively new customer demand driven by the rapid adoption of mixed material car body structures. New rivet designs have recently been developed for joining UHSS to aluminum, these rivets have increased column strength and increased stiffness to enable piercing through UHSS materials. In this study the insertion behavior of these higher strength rivets has been simulated and numerical analysis has been conducted to investigate the influence of the key process parameters on the joining result. The simulation results were compared to physical experimental results and good correlation was achieved.
AB - Over the last few years, fuel economy improvement has driven the use of efficient multi-material structures in the car industry. The combination of dissimilar materials, such as metal-metal and metal-polymer, is a complex issue that requires the use of different and emerging joining techniques. In this context, self-pierce riveting (SPR) is an extremely suitable technique for joining two or more metal sheets, particularly when other techniques are not applicable. SPR requires short manufacturing times and provides both high strength and high fatigue resistance. Yet, this technique still faces some hurdles, such as joining Ultra High Strength Steels (UHSS) with high strength low ductility aluminum alloys, which can result in rivet cracking or aluminum button tearing. Suitable process parameters, including the rivet size and the die profile, are usually obtained through a physical testing procedure to satisfy the required joint specification. This is both expensive and time consuming. Finite element simulations of SPR are being increasingly used to reduce the number of physical tests and to estimate the tensile strength of the joint. The capability to accurately simulate aluminum to aluminum riveting has been demonstrated in recent studies. However, very few simulation studies have been conducted on the riveting of UHSS to aluminum, mainly because this type of joint is a relatively new customer demand driven by the rapid adoption of mixed material car body structures. New rivet designs have recently been developed for joining UHSS to aluminum, these rivets have increased column strength and increased stiffness to enable piercing through UHSS materials. In this study the insertion behavior of these higher strength rivets has been simulated and numerical analysis has been conducted to investigate the influence of the key process parameters on the joining result. The simulation results were compared to physical experimental results and good correlation was achieved.
KW - Car industry
KW - Fuel economy improvement
KW - Self-pierce riveting
KW - SPR
KW - Car industry
KW - Fuel economy improvement
KW - Self-pierce riveting
KW - SPR
UR - http://www.scopus.com/inward/record.url?scp=85068867858&partnerID=8YFLogxK
U2 - 10.1063/1.5112592
DO - 10.1063/1.5112592
M3 - Conference contribution
VL - 2113
T3 - 0094-243X
SP - 50028
BT - unknown
A2 - Arrazola, Pedro
A2 - Saenz de Argandona, Eneko
A2 - Otegi, Nagore
A2 - Mendiguren, Joseba
A2 - Saez de Buruaga, Mikel
A2 - Madariaga, Aitor
A2 - Galdos, Lander
PB - American Institute of Physics Inc.
T2 - 22nd International ESAFORM Conference on Material Forming, ESAFORM 2019
Y2 - 8 May 2019 through 10 May 2019
ER -