Investigation of bending properties of E-Glass fiber reinforced polymer matrix composites for applications in micro wind turbine blades

Singh, Sachidanand; Hanumantharaju, H.G.; Yadla, Sai Ravi Teja; Yadav, S. Hemanth Rao; Srivatsa, Shreyas

doi:10.1088/1742-6596/1473/1/012047

Cited by 3 publications

(3 citation statements)

References 2 publications

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“…This research involved the manufacture of a wind turbine blade sandwiched E‐glass fiber/Balsa wood core composite to handle the maximum load; the peak load was 362.9 N to 510.0 N and the peak displacement was 1.935–3.16 mm (Singh et al., 2020). Five different concentration specimens of a unidirectional E‐glass fiber/ZnO nanofiller composite were tested.…”

Section: Introductionmentioning

confidence: 99%

Adsorption mechanism of E‐glass fiber/Aluminum particles/MWCNT filled epoxy matrix polymer composite in electronic applications

Senthilkumar

Naveen

2023

Environmental Quality Mgmt

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The main objective of the research is developed toward adsorption electronic devices (Interface material) with the performance examined by the physical, mechanical, and thermal properties of the E‐glass fiber reinforced with the epoxy composite and particulate dispersed into the matrix in partial fulfillment of tiny amount of aluminum powder particles and MWCNT. Composite membranes with 15 wt.% E‐glass fiber and 2 wt.%, 4 wt.%, and 6 wt.% fine aluminum powder particle concentrations were partially filled with 0 wt.%, 0.5 wt.%, and 1.0 wt.% MWCNTs. Vacuum lay‐up technique is used to create the better adhesive hybrid composite, which is then assessed of the characteristics of the materials. The maximum thermal conductivity of EAEM2 (E‐Epoxy, A‐Aluminum particle, E‐E‐glass fiber, M‐MWCNT) is 0.3057 W/mK. The tensile, bending, and impact strengths of EAEM1 composites are higher than those of EAEM2 and EAEM3 (average values of EAEM1 composites: 86 MPa, 123.33 MPa, and 90.66 J/m2). However, the Shore‐D hardness of EAEM3 is 95.33. The test findings demonstrate a significant improvement in thermal properties with minimal marginal decrements in mechanical capabilities when carbon allotropes are increased. The composite system's morphology (EAEM3) demonstrates a clustered distribution of aluminum powder particles in the matrix.

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Section: Introductionmentioning

confidence: 99%

Adsorption mechanism of E‐glass fiber/Aluminum particles/MWCNT filled epoxy matrix polymer composite in electronic applications

Senthilkumar

Naveen

2023

Environmental Quality Mgmt

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“…L1 was very attractive fiber than L3 [12]. Wind turbine blade fabrication sandwiched E-glass fiber/Balsa wood core composite to withstand maximum load, by the recording the experiment the peak load was 362.9 N to 510.0 N and peak displacement was 1.935 mm to 3.16 mm [13]. Unidirectional E-glass fiber/ZnO nano filler composite with five different concentrated specimens were examined.…”

Section: Introductionmentioning

confidence: 99%

Macrostructure and Fracture Behaviour of Rice Husk and MWCNT Dispersion Strengthened Alkali Treated Banana Fiber Matrix Hybrid Composites

Ramu

Senthilkumar

Rajendran³

2023

MSF

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The mechanical properties of natural fiber composites reinforced with rice husk and multi-walled carbon nanotubes are studied. Two different mixing concentrations are prepared: 5 wt.% and 10 wt. % rice husk and 0.5 wt.% and 1.0 wt.% multi-walled carbon nanotubes incorporating with the constant reinforcing phases of the banana fiber is 10 wt.%. (Specimens: NBRME1 and NBRME2, where, N-NaOH; B-Banana fiber; R-Rice husk; M-MWCNT; E-Epoxy). The effect of surface treatment of banana fiber bundles is reacted with a 6% sodium hydroxide solution. The surface-treated reinforcement results indicated higher tensile, bending, and impact strength of the 0.5% MWCNT composite (43.96 MPa, 60.62 MPa, and 46.5 J/m) compared with 1% MWCNT composite. High-resolution optical macroscopic images are revealed a variety of defects, including interface behaviour, fiber stretching, fracture, cracking, and agglomeration. Biodegradable organic rice husk-based epoxy resin composite is valuable for manufacturing electronic parts, chips and circuits.

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“…Sandwich structures with a balsa core are often used in engineering applications to exploit these high specific flexural properties. Hence, a large body of research on sandwich structures with an end-grain balsa core has focused on understanding and improving flexural performance[16,29,35,40,60,62,69,82,83,86,89,93,.…”

mentioning

confidence: 99%

Review of balsa core sandwich composite structures

et al. 2022

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Investigation of bending properties of E-Glass fiber reinforced polymer matrix composites for applications in micro wind turbine blades

Cited by 3 publications

References 2 publications

Adsorption mechanism of E‐glass fiber/Aluminum particles/MWCNT filled epoxy matrix polymer composite in electronic applications

Adsorption mechanism of E‐glass fiber/Aluminum particles/MWCNT filled epoxy matrix polymer composite in electronic applications

Macrostructure and Fracture Behaviour of Rice Husk and MWCNT Dispersion Strengthened Alkali Treated Banana Fiber Matrix Hybrid Composites

Review of balsa core sandwich composite structures

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