Search

DIGITAL LIBRARY: SAMPE 2024 | LONG BEACH, CA | MAY 20-23

Get This Paper

Thermal Modelling of The In-Situ Consolidation of Automated Fiber Placement of Thermoplastic Composites

Description

Title: Thermal Modelling of The In-Situ Consolidation of Automated Fiber Placement of Thermoplastic Composites

Authors: Christopher J. Stelter, Thammaia Sreekantamurthy, Tyler B. Hudson, Brian W. Grimsley

DOI: 10.33599/nasampe/s.24.0179

Abstract: NASA is developing carbon fiber reinforced thermoplastic composites processing methods under the Hi-rate Composites Aircraft Manufacturing (HiCAM) project. The in-situ consolidation automated fiber placement (AFP) of thermoplastics (ICAT) process has high potential to increase manufacturing throughput and lower costs as it combines the repeatability and fast lay down rates of AFP with the thermoformability of thermoplastic materials to achieve part consolidation out of the autoclave. Physics-based process models are employed in the ICAT process development to understand, fundamentally, the thermal response of the carbon fiber (CF)/polyaryletherketone (PAEK) material during the rapid heating and cooling associated with laser-assisted AFP. A one-dimensional (1-D) closed-form model was developed capable of predicting the temperature profile through-the-thickness of the tape material. In addition, a two-dimensional (2-D) model was developed to predict the heat transfer through-the-thickness and in the laydown x-direction of the AFP head motion. The solution of the Fourier heat-transfer equations in the 2-D model is approximated using the explicit finite difference numerical method. The temperature profile during placement of PAEK slit-tape materials at various laser target temperatures and placement speeds were measured during ICAT process development trials at Electroimpact®, Inc. †† and the resulting experimental data is compared with the predictions of the 1-D and 2-D models.

References: [1] B. W. Grimsley, R. J. Cano, T. B. Hudson, F. L. Palmieri, C. J. Wohl, R. I. Ledesma, T. Sreekantamurthy, C. J. Stelter, M. D. Assadi, R. F. Jordan, J. H. Rower, R. A. Edahl, J. C. Shiflett and J. W, ""In-Situ Consolidation Automated Fiber Placement of Thermoplastic Composites for High-Rate Aircraft Manufacturing,"" in SAMPE 2022, 2022. doi:10.33599/nasampe/s.22.0870. [2] J. Tierney and J. W. Gillespie, ""Modeling of In Situ Strength Development for the Thermoplastic Composite Tow Placement Process,"" Journal of Composite Materials, vol. 40, no. 16, pp. 1487-1506, January 2006. doi:10.1177/0021998306060162. [3] S. M. Grove, ""Thermal modelling of tape laying with continuous carbon fibre-reinforced thermoplastic,"" Composites, vol. 19, no. 5, p. 367–375, September 1988. doi:10.1016/0010-4361(88)90124-3. [4] M. D. Francesco, L. Veldenz, G. Dell’Anno and K. Potter, ""Heater power control for multi-material, variable speed Automated Fibre Placement,"" Composites Part A: Applied Science and Manufacturing, vol. 101, pp. 408-421, October 2017. doi:10.1016/j.compositesa.2017.06.015. [5] C. M. Stokes-Griffin and P. Compston, ""A combined optical-thermal model for near-infrared laser heating of thermoplastic composites in an automated tape placement process,"" Composites Part A: Applied Science and Manufacturing, vol. 75, pp. 104-115, August 2015. doi:10.1016/j.compositesa.2014.08.006. [6] T. Weiler, M. Emonts, L. Wollenburg and H. Janssen, ""Transient thermal analysis of laser-assisted thermoplastic tape placement at high process speeds by use of analytical solutions,"" Journal of Thermoplastic Composite Materials, vol. 31, no. 3, pp. 311-338, March 2017. doi:10.1177/0892705717697780. [7] B. Grimsley, T. Hudson, R. Cano, J. Shiflett, C. Stelter, C. Wohl, R. Ledesma, T. Sreekantamurthy, J. Kang, J. Nancarrow, R. Jordan and J. Rower, ""Laser Angle of Incidence Effects on In-situ Consolidation Automated Fiber Placement of Thermoplastics,"" in SAMPE Conference, May 2024 (in-press). [8] A. Bejan and A. D. Kraus, Eds., Heat transfer handbook, vol. 1, John Wiley & Sons, 2003. [9] F. Amir, Y. Zhang and J. R. Howell, Advanced heat and mass transfer, Global Digital Press, 2010, ISBN: 0984276009. [10] F. P. Incropera, Fundamentals of heat and mass transfer, vol. 6, New York: Wiley, 2006. [11] E. H. Smith, Ed., Mechanical engineer's reference book, 12th ed., Butterworth, 1994. [12] J. J. Fuller and E. E. Marotta, ""Thermal Contact Conductance of Metal/Polymer Joints: An Analytical and Experimental Investigation,"" Journal of Thermophysics and Heat Transfer, vol. 15, no. 2, pp. 228-238, April 2001. doi:10.2514/2.6598. [13] Mayahtt.com, ""Convection Wizard,"" [Online]. Available: https://thermal.mayahtt.com/tmwiz/convect/natural/hup-isot/hup-isot.htm. [Accessed 15 December 2023]. [14] J. Tierney and J. W. Gillespie, ""Modeling of Heat Transfer and Void Dynamics for the Thermoplastic Composite Tow-Placement Process,"" Journal of Composite Materials, vol. 37, no. 19, pp. 1745-1768, October 2003. doi:10.1177/002199803035188. [15] T. B. Hudson, C. T. Dolph, G. M. Grose, R. J. Cano, R. F. Jordan, C. J. Wohl, R. I. Ledesma and B. W. Grimsley, ""Thermal Response of Thermoplastic Composite Tape During In-situ Consolidation Automated Fiber Placement Using a Laser Heat Source,"" in SAMPE 2023, 2023. doi:10.33599/nasampe/s.23.0101.

Conference: SAMPE 2024

Publication Date: 2024/05/20

SKU: TP24-0000000179

Pages: 19

Price: $38.00

Get This Paper