Influence of compaction and curing in the Automated Fiber Placement Process on the mechanical performance of composite laminates

被引:2
|
作者
Vogl, Sylvester [1 ]
Knott, Ralf [1 ]
Sommacal, Silvano [2 ]
Compston, Paul [2 ]
Drechsler, Klaus [1 ]
机构
[1] Tech Univ Munich, Chair Carbon Composites, Boltzmannstr 15, D-85748 Garching, Germany
[2] Australian Natl Univ, Res Sch Phys, Canberra, ACT 2600, Australia
来源
COMPOSITE STRUCTURES | 2024年 / 330卷
关键词
Automated fiber placement; TS-AFP; Thermoset; Compaction; Mechanical characterization; VOID CONTENT;
D O I
10.1016/j.compstruct.2023.117826
中图分类号
O3 [力学];
学科分类号
08 ; 0801 ;
摘要
This paper investigates the effect of compaction and curing states on the mechanical properties and void content of AFP-manufactured laminates. For the mechanical characterization, tensile tests, 4 -point -bending tests and interlaminar shear strength (ILSS) tests were applied. The internal structure was evaluated via micro CT. For the surface structure evaluation, an optical profilometer was used. The void content was determined via segmentation of the micro CT images. The paper is subdivided into the description of the applied materials and methods, the results and their discussion and a conclusion. The study showcases the potential of AFPmanufactured aerospace composites to attain high -quality results even without the need for an autoclave, making them well -suited for unmanned applications.
引用
收藏
页数:11
相关论文
共 50 条
  • [21] Effects of processing parameters of infrared-based automated fiber placement on mechanical performance of carbon fiber-reinforced thermoplastic composite
    Venkatesan, Chadurvedi
    Zulkifli, Faiz
    Silva, Arlindo
    COMPOSITE STRUCTURES, 2023, 309
  • [22] Study of the ultrasonic compaction process of composite laminates - part I: process modeling
    J. Justo
    E. Graciani
    F. París
    F. Chinesta
    R. Ávila
    International Journal of Material Forming, 2015, 8 : 613 - 623
  • [23] Study of the ultrasonic compaction process of composite laminates - part I: process modeling
    Justo, J.
    Graciani, E.
    Paris, F.
    Chinesta, F.
    Avila, R.
    INTERNATIONAL JOURNAL OF MATERIAL FORMING, 2015, 8 (04) : 613 - 623
  • [24] Influence of different composite curing agents on the rapid curing characteristics and mechanical performance of epoxy resins
    Xu, Ting
    An, Lizhou
    Yin, Qin
    Jiao, Yumin
    Zhou, You
    Tan, Yefa
    AIP ADVANCES, 2024, 14 (10)
  • [25] Mechanical performance of out-of-autoclave composites manufactured by automated fiber placement
    Dong, Anqi
    Zhao, Yan
    Zhao, Xinqing
    Fuhe Cailiao Xuebao/Acta Materiae Compositae Sinica, 2018, 35 (05): : 1095 - 1104
  • [26] ffect of automated fiber placement (AFP) manufacturing signature on mechanical performance of composite structures (vol 228, 111335, 2019)
    Minh Hoang Nguyen
    Vijayachandran, Avinkrishnan A.
    Davidson, Paul
    Call, Damon
    Lee, Dongyeon
    Waas, Anthony M.
    COMPOSITE STRUCTURES, 2020, 233
  • [27] Study on Mode I interlaminar fracture behavior of automated fiber placement in situ consolidation thermoplastic composite considering the influence of roller compaction pressure
    Liu, Chen
    He, Chen
    Zou, Zhongfeng
    Li, Yong
    POLYMER COMPOSITES, 2025, 46 (02) : 1454 - 1468
  • [28] Flexural response of composite beams made by Automated Fiber Placement process: Effect of fiber tow gaps
    Ghayour, Mohammadhossein
    Ganesan, Rajamohan
    Hojjati, Mehdi
    COMPOSITES PART B-ENGINEERING, 2020, 201
  • [29] Study on mode-I fracture toughness of composite laminates with curved plies applied by automated fiber placement
    Liu, Chen
    Bai, Ruixiang
    Lei, Zhenkun
    Di, Jianyu
    Dong, Dili
    Gao, Tiancheng
    Jiang, Hao
    Yan, Cheng
    MATERIALS & DESIGN, 2020, 195
  • [30] Modeling and experimental validation of compaction pressure distribution for automated fiber placement
    Jiang, Junxia
    He, Yuxiao
    Wang, Han
    Ke, Yinglin
    COMPOSITE STRUCTURES, 2021, 256
12345