Residual Strength and Fracture Path for Drilled Epoxy-Glass Composites

Torres, Mauricio; González, Jeanette; Hernandez, Hilario

doi:10.4028/www.scientific.net/amr.65.89

Cited by 7 publications

(4 citation statements)

References 11 publications

(17 reference statements)

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“…The process implies destruction of fibre continuity with generation of large stress concentration in the material and delamination at the hole entry and exit [2][3][4][5][6][7]. The damage caused can significantly reduce the fatigue strength of the component, thus degrading the long-term performance of composite laminates [8][9]. Previous studies have shown that machining fibre-reinforced polymer (FRP) composites materials differs significantly in many aspects from machining conventional metals and alloys primarily due to the underlying heterogeneity and anisotropy of FRP materials [2][3][4][5][6][7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Drilling in carbon/epoxy composites: Experimental investigations and finite element implementation

Phadnis

Makhdum

Roy

et al. 2013

Composites Part A: Applied Science and Manufacturing

244

112

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Section: Introductionmentioning

confidence: 99%

Drilling in carbon/epoxy composites: Experimental investigations and finite element implementation

Phadnis

Makhdum

Roy

et al. 2013

Composites Part A: Applied Science and Manufacturing

244

112

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“…Conventional drilling (CD) implies large distribution of stress concentration in the materials and also delamination and surface quality degradation (Keonig, et al,1985;Davim and Reis, 2003;Zitoune et al, 2005). This reduces the fatigue strength of components, hence, the long-term performance decreases (Torres et al, 2009;Persson et al, 1997). Stress generated during drilling process can be reduced with the help of UAD because UAD lower level of drilling forces is encountered by workpiece and drill bit.…”

Section: ~ 6 ~mentioning

confidence: 99%

Ultrasonically Assisted Drilling of Carbon Fibre Reinforced Plastics

Makhdum

2012

SSP

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Carbon fibre-reinforced plastics (CFRPs) gained substantial acclaim in recent decades and are used in aerospace, automotive and structural applications due to their high strength-to-weight ratio, high stiffness, high fatigue and corrosion resistance. CFRPs are manufactured near to net shape but some machining processes such as drilling cannot be avoided. Drilling induces damage (delamination, matrix cracking, matrix burning, lamina cracking and fibre pull out) in CFRP because of high axial thrust forces and a temperature rise. In this research an attempt is made to use ultrasonically assisted drilling (UAD) to reduce the axial thrust forces. In UAD high frequency (~ 20 kHz) vibrations are superimposed on a drill bit, preferably in axial direction, to reduce the thrust forces. In this study, experiments are conducted in two stages. At the first stage an initial setup with an existing UAD transducer is used to compare UAD with conventional drilling (CD) of CFRP. A reduced thrust force is experienced in case of UAD when compared to CD. At the second stage, drilling dynamics, i.e. feed speed, is changed along with the improvement of the transducer, and an enormous amount of force reduction (>80%) is observed in case of UAD (as compared to CD).

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“…Even though the CM process is utilized very frequently in today's manufacturing by selecting suitable cutting parameters and tool geometry, but most of the problems mentioned above remain the major cause of producing surface damage [11]. Such damages can cause significant reduction in tensile and compressive strength and it also decreases stiffness [2], consequently reducing the performance of the entire structure [11] which adds to huge economic burden, as 60% of the rejected components during manufacturing owe to the inferior hole quality [1,11,18,20]. Nonoptimal cutting tool designs, rapid tool wear, and machining conditions can be considered for the above mentioned problems.…”

Section: Introductionmentioning

confidence: 99%

Analytical and experimental investigation of the effects of the machining processes on the mechanical behaviour of carbon epoxy composite laminates

Saleem¹

2021

Preprint

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To join various components, drilling is the most frequently used machining process for carbon fiber-reinforced polymer (CFRP) composites. However, it induces various defects such as microcracks, resin degradation and fiber pull-out. In order to eliminate these problems, an appropriate machining process must be employed. Therefore, the main objective of this research is to conduct an analytical and experimental study to investigate the influence of the machining process on the mechanical behaviour of a CFRP structural component and assembly drilled with conventional (CM) and abrasive water-jet machining (AWJM) processes. All CFRP composite laminates did not demonstrate any prominent change in the mechanical properties during static tests. However, fatigue tests showed that the damage accumulation in conventional machining was higher than that in AWJM specimens. Thus, in the case of CM specimens the endurance limit was less than AWJM specimens. The difference in the mechanical behaviour of the composite laminates can be related to the initial surface integrity induced by the difference in the mechanism of material removal of each machining process. This difference in surface texture was responsible for the initiation of stress concentration sites as evident from infrared thermographic stress and thermal analysis. The heat dissipated from all laminates was also correlated to the damage accumulation. It was identified that the surface roughness criterion (Ra) used for the characterization of the surface roughness for metals was not suitable for composites as roughness values of all specimens were same, however different mechanical behaviour was observed. An IR thermographic damage criterion (TDC) was developed which related the temperature threshold area with damage evolution. TDC further confirms the superiority of AWJM compared to CM process. Further it was identified that AWJM process was less sensitive to the composite's stacking sequence compared to conventional machining. The main conclusion of this research is that the failure modes of composite structure parts and assembly are highly affected by the choice of the machining process. This study therefore confirms that the machining process has an important contribution for the design of composite parts and assembly in order to improve the service life of the machined composite structures.

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Residual Strength and Fracture Path for Drilled Epoxy-Glass Composites

Cited by 7 publications

References 11 publications

Drilling in carbon/epoxy composites: Experimental investigations and finite element implementation

Drilling in carbon/epoxy composites: Experimental investigations and finite element implementation

Ultrasonically Assisted Drilling of Carbon Fibre Reinforced Plastics

Analytical and experimental investigation of the effects of the machining processes on the mechanical behaviour of carbon epoxy composite laminates

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