TY - GEN
T1 - REDUCING WARPAGE IN A HYBRID LARGE-SCALE ADDITIVE MANUFACTURING AND COMPRESSION MOLDING PROCESS
AU - Garg, Nikhil
AU - Jo, Eonyeon
AU - Pokkalla, Deepak Kumar
AU - Kumar, Vipin
AU - Nuttall, David
AU - Hassen, Ahmed A.
AU - Ogle, Ryan
AU - Vaidya, Uday
AU - Kim, Seokpum
N1 - Publisher Copyright:
Copyright © 2023. Used by CAMX - The Composites and Advanced Materials Expo. CAMX Conference Proceedings.
PY - 2023
Y1 - 2023
N2 - In recent years, a hybrid manufacturing process, developed by combining extrusion-based large-scale additive manufacturing (AM) and compression molding (CM) techniques, has shown promising outcomes for producing structurally functional parts. The process can be used with both short fiber-reinforced composites and neat polymers and hence, even multi-material parts can be manufactured easily. This process offers the advantages of structural enhancement by having a desired fiber orientation using a large-scale AM process, as well as rapid manufacturing capability using a CM process. In the large-scale AM process, the alignment of fibers in the deposition direction enables significant improvement in the mechanical properties of the manufactured parts. However, the anisotropy resulting from the directional arrangement of fibers also introduces challenges related to warpage in the produced parts. This study aims to identify the causes of warpage and propose strategies to mitigate it. The research involves the use of preforms manufactured through the large-scale AM, which are then combined with the neat resin for CM manufacturing. A finite element-based numerical simulation model is developed, employing a sequentially coupled thermomechanical approach. Through a parametric study using the simulation models, optimization of printing direction and preform geometry is performed to minimize warpage. This contributes to the advancement and wider adoption of AM/CM hybrid manufacturing to produce structurally functional parts.
AB - In recent years, a hybrid manufacturing process, developed by combining extrusion-based large-scale additive manufacturing (AM) and compression molding (CM) techniques, has shown promising outcomes for producing structurally functional parts. The process can be used with both short fiber-reinforced composites and neat polymers and hence, even multi-material parts can be manufactured easily. This process offers the advantages of structural enhancement by having a desired fiber orientation using a large-scale AM process, as well as rapid manufacturing capability using a CM process. In the large-scale AM process, the alignment of fibers in the deposition direction enables significant improvement in the mechanical properties of the manufactured parts. However, the anisotropy resulting from the directional arrangement of fibers also introduces challenges related to warpage in the produced parts. This study aims to identify the causes of warpage and propose strategies to mitigate it. The research involves the use of preforms manufactured through the large-scale AM, which are then combined with the neat resin for CM manufacturing. A finite element-based numerical simulation model is developed, employing a sequentially coupled thermomechanical approach. Through a parametric study using the simulation models, optimization of printing direction and preform geometry is performed to minimize warpage. This contributes to the advancement and wider adoption of AM/CM hybrid manufacturing to produce structurally functional parts.
KW - Large-scale additive manufacturing
KW - compression molding
KW - fiber orientation
KW - hybrid manufacturing
KW - short fiber reinforcement composites
KW - warpage
UR - http://www.scopus.com/inward/record.url?scp=85188507101&partnerID=8YFLogxK
U2 - 10.33599/nasampe/c.23.0098
DO - 10.33599/nasampe/c.23.0098
M3 - Conference contribution
AN - SCOPUS:85188507101
T3 - Composites and Advanced Materials Expo, CAMX 2023
BT - Composites and Advanced Materials Expo, CAMX 2023
PB - The Composites and Advanced Materials Expo (CAMX)
T2 - 9th Annual Composites and Advanced Materials Expo, CAMX 2023
Y2 - 30 October 2023 through 2 November 2023
ER -