Novel thermally insulated ultra‐lightweight fireproof and high impact resistance advanced hybrid composite

Vinodhini, Jennifer; Sudheendra, K; AR, Srikrishnan; Trivedi, Prakash D.; Zaveri, Jaimin C.; Kundu, Amit

doi:10.1002/pen.26082

Cited by 10 publications

(13 citation statements)

References 28 publications

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“…In recent years, carbon fiber-reinforced polymer composites have been widely used in aerospace and vehicle industries. [1][2][3][4][5] With the development of high-performance composites, the application of aircraft structures has been developed from secondary load-bearing structures to primary ones, such as wing fixed leading edges, ribs, clips, and angled profiles in parts of Airbus and Boeing commercial aircraft. 6 Due to the service environment, low-velocity impact (LVI) damage is inevitable for thin composite laminated structures.…”

Section: Introductionmentioning

confidence: 99%

Experimental investigation of impact resistance and compression behavior of CF/PEEK laminates after hot‐press fusion repair with different stacking sequences

et al. 2023

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Unidirectional fiber‐reinforced composite laminates have limited resistance to out‐of‐plane impact and are prone to structural integrity damage during service due to low‐velocity impact (LVI). In this study, the hot‐press fusion method was employed to repair the impact‐damaged unidirectional carbon fiber‐reinforced poly‐ether‐ether‐ketone (CF/PEEK) thermoplastic composites. No delamination or matrix cracking induced by impact was observed in the repaired specimens, as confirmed by ultrasonic scanning and digital microscope. In addition, the hot pressing treatment enables the fibers to be covered again by the resin matrix, which eliminates fiber pull‐out and fiber/matrix debonding. Afterward, typical responses of CF/PEEK composite laminates to re‐impact and post‐repair compression are presented in a comprehensive and detailed manner, and compared with the initial impact response and compression after impact (CAI) behavior. The effects of three impact energies and two stacking sequences are considered. The results indicate that quasi‐isotropic laminates are more susceptible to localized fracture damage upon re‐impact as the impact energy increases, due to initial fiber breakage, compared to orthotropic laminates. The hot‐press treatment enhances the compression residual strength of the specimen by 20%–30% compared to its state before repair. These studies offer technical insights into the application of the hot‐press fusion method to enhance the mechanical properties of composite laminates post impact damage.

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Section: Introductionmentioning

confidence: 99%

Experimental investigation of impact resistance and compression behavior of CF/PEEK laminates after hot‐press fusion repair with different stacking sequences

et al. 2023

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“…[26][27][28][29] However, the research primarily focusses on: PEEK as the matrix, [30][31][32][33][34][35] hybrid yarns [30][31][32] or unidirectional CF/PEEK prepegs 33 as raw materials. There is limited studies on: PEK as the matrix component of the high performance composites, [36][37][38][39] in depth systematic analysis on the internal influence mechanisms of high performance composites fabricated through film fiber stacking and consolidation 5,40 and optimization of the properties of the same by statistical analysis. 33,41,42 There are no available studies exploring the effect of process parameters on the mechanism of internal influence of PEK based high performance composites and optimization of the subsequent film fiber stacking and consolidation process parameters.…”

Section: Introductionmentioning

confidence: 99%

Application of Box Behnken experimental design to analyze the influence mechanism of process parameters on mechanical properties of high-performance thermoplastic composites

Sudheendra

Vinodhini

Govindaraju

et al. 2023

Journal of Thermoplastic Composite Materials

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Composite processing relies heavily on process parameters, which are the key factors that determine the quality of the finished product. In this investigation, carbon fiber (CF)-reinforced polyetherketone (PEK) thermoplastic composites are fabricated through film-fiber stacking and consolidation process. In this method, carbon fabric and polymer film are alternately stacked, and the stacks are then consolidated via compression molding to create a laminate. The mechanical properties of CF/PEK composites are studied in relation to crucial process parameters such as molding temperature, molding pressure, and holding time. To identify the optimal process parameters for CF/PEK fabrication, the tensile and interlaminar shear strengths of these composites were evaluated. Non-linear quadratic equations employing Box-Behnken Design in Response Surface Methodology and validation trials were used to model these features. To obtain the optimal mechanical properties of fabricated composites, the combination of factor ranges was discovered by overlaying contour plots within the practical constraints. The ideal process parameters for achieving maximum mechanical qualities were determined to be around molding temperature of 400°C, a holding period of 60 min, and a molding pressure of 10 bar.

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“…Foam is characterized by light weight, good energy absorption, and excellent impact resistance. [17][18][19] Epoxy foam-filled threedimensional woven spacer fiberglass/epoxy composites exhibit higher flexural strength and excellent bending stiffness compared to unfilled. 20 Foam filling can effectively increase the peak load, average load, crushing rate efficiency and overall energy absorption of the structure, but the increase in mass will lead to a decrease in the specific energy absorption.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, a lightweight material is needed to reinforce, the foam is a better choice. Foam is characterized by light weight, good energy absorption, and excellent impact resistance 17–19 . Epoxy foam‐filled three‐dimensional woven spacer fiberglass/epoxy composites exhibit higher flexural strength and excellent bending stiffness compared to unfilled 20 .…”

Section: Introductionmentioning

confidence: 99%

Curved woven lattice truss sandwich panels strengthened by foams: Designing, manufacturing, and testing

Wang,

Bai,

Yan

et al. 2023

Polymer Composites

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The woven lattice truss sandwich panels (WLTSPs) have been studied much, and this article proposes a new structure (curved woven lattice truss sandwich [CWLTS] panels). CWLTS were designed, made, and tested. The foam‐filling technique was applied to strengthen the CWLTS. Curving and foam‐filling effects to the deformation, damage, failure, and energy absorption under cylindrical and plated loadings were revealed by three‐point bending experiments. Under cylindrical loading, foam‐filling can effectively increase the load capacity, especially the CWLTS‐A. The load‐bearing capacity of the plated loading is greater than that of the cylindrical loading, and the phenomenon is significantly improved after foam filling, except for the central angle of 60° and the CWLTS‐A of 44.05°. Foam‐filling changes failure from core‐shearing to face fracture. For foam‐filled panels, the change in loading pattern results in energy absorption increase of 2.45 times for CWLTS‐B and 2.86 times for CWLTS‐A. Plated loading approximately doubles the peak load and energy absorption with two plastic hinges. The effect of foam filling on the mean crush force of the CWLTS plated loading is greater. The mechanical and energy absorption properties of the CWLTS can be improved by changing the loading mode and using foam filling, effectively increasing the applicability.Highlights Curved woven lattice truss sandwich panels were designed, made, and tested. Foam‐filling method greatly improves the bearing capacity of the CWLTS panels. Plated loading much increases the bearing capacity and energy absorption. The impact of curvature on mechanical performances is not immediately apparent.

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Novel thermally insulated ultra‐lightweight fireproof and high impact resistance advanced hybrid composite

Cited by 10 publications

References 28 publications

Experimental investigation of impact resistance and compression behavior of CF/PEEK laminates after hot‐press fusion repair with different stacking sequences

Experimental investigation of impact resistance and compression behavior of CF/PEEK laminates after hot‐press fusion repair with different stacking sequences

Application of Box Behnken experimental design to analyze the influence mechanism of process parameters on mechanical properties of high-performance thermoplastic composites

Curved woven lattice truss sandwich panels strengthened by foams: Designing, manufacturing, and testing

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