An investigation of fracture and fatigue in a metal/polymer composite

Kung, Edward; Mercer, C.; Allameh, Seyed M.; Soboyejo, Winston O.; Popoola, Oludele O.

doi:10.1007/s11661-001-0012-2

Cited by 17 publications

(7 citation statements)

References 14 publications

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“…At the same time, the amount of alloying elements in the austenite rises leading to its stabilisation [1][2][3]. The martensite start temperature (M S ) is consequently lowered, which may result in the formation of soft retained austenite [1,2,4]. However, the corrosion resistance increases with carbide dissolution, which is also due to enrichment of alloying elements in the austenitic parent phase [5,6].…”

Section: Introductionmentioning

confidence: 99%

Corrosion properties of a complex multi‐phase martensitic stainless steel depending on the tempering temperature

Seifert

Wieskämper

Tonfeld

et al. 2015

Materials & Corrosion

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In this work, the corrosion resistance of X190CrVMo20‐4‐1 martensitic stainless steel and the hardness are correlated with the tempering temperature. The steel was hardened from a typical austenitisation temperature, quenched in oil and tempered up to 600 °C. The corrosion resistance was investigated by means of electrochemical tests, in both 5% sulphuric acid and in 3% sodium chloride. Static immersion tests were performed in H2SO4 only. The best compromise for a high hardness and corrosion resistance is found for tempering between 100 and 200 °C. The data obtained can be used for designing and application of this steel.

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Section: Introductionmentioning

confidence: 99%

Corrosion properties of a complex multi‐phase martensitic stainless steel depending on the tempering temperature

Seifert

Wieskämper

Tonfeld

et al. 2015

Materials & Corrosion

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“…where a is the constraint/triaxiality factor (theoretically between 1 and 3 and taken as $ 3 in this study), 36 V f is the volume fraction of the reinforcement phase, L is the bridging length (the distance from the crack-tip to the last unfractured reinforcement), y is the uniaxial yield stress, and x is the distance from the crack face behind the crack-tip as described by Savastano et al 37 For large-scale crack bridging (LSB) conditions, the contribution to composite toughness due to crack bridging was also modeled 38,39 using a weighting function by Fett and Munz to estimate the weighted distributions of bridging traction across the crack faces. 40 The shielding from large scale bridging, ÁK lsb , is given by 38…”

Section: Methodsmentioning

confidence: 99%

Pull-out behavior of natural fiber from earth-based matrix

Mustapha

Azeko

Annan

et al. 2016

Journal of Composite Materials

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This paper presents the results of a combined experimental and analytical study of the pull-out behavior of natural fiber (grass straw) from an earth-based matrix. A single fiber pull-out approach was used to measure interfacial properties that are significant to toughening brittle materials via fiber reinforcement. This was used to study the interfacial shear strengths of straw fiber-reinforced earth-based composites with a matrix that consists of 60 vol. % laterite, 20 vol. % clay and 20 vol. % cement. The composites that were used in the pull-out tests included composites reinforced with 0, 5, 10 and 20 vol. % of straw fibers. The toughening behavior of fiber-reinforced earth-based matrix was analyzed in terms of their interfacial shear strengths and bridging zones, immediately behind the crack tip. This approach is consistent with microscopic observations that reveal intact bridging fibers behind the crack tip, as a result of debonding of the fiber–matrix interface. Analytical models were used to study the debonding of fiber from the matrix materials, as well as the toughening due to crack-tip shielding via bridging. The results show that increasing the fiber embedment length and the fiber volume fraction (in the earth/cement matrix) increases the peak pull-out load. The debonding process was also found to be associated with a constant friction stress. The combined effects of multiple toughening mechanisms (debonding and crack bridging) are elucidated along with the implications of the results for the design of earth-based composites for potential applications in robust building materials for sustainable eco-friendly homes.

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“…where is the constraint/triaxiality factor (theoretically between 1 and 3 and taken as $3 in this study), 31 V f is the volume fraction of the reinforcement phase, L is the bridging length (the distance from the crack tip to the last unfractured reinforcement), y is the uniaxial yield stress, and x is the distance from the crack face behind the crack tip as described by Savastano et al 32 For LSB conditions, the contribution to composite toughness due to crack bridging 30,33 can be modeled. The model uses a weighting function by Fett and Munz 34 to estimate the weighted distributions of bridging traction across the reinforcements as shown schematically in Figure 1.…”

Section: Toughening Due To Crack Bridgingmentioning

confidence: 99%

“…where is the constraint/triaxiality factor (theoretically between 1 and 3 and taken as $3 in this study), 31 V f is the volume fraction of the reinforcement phase, L is the bridging length, y is the uniaxial yield stress, and x is the distance from the last unfractured fiber to the crack tip. Also, h a, x ð Þ is the weighting function given by Fett and Munz as 34 where ''a'' is the crack length and ''w'' is the specimen width.…”

Section: Toughening Due To Crack Bridgingmentioning

confidence: 99%

Strength and fracture toughness of earth-based natural fiber-reinforced composites

Mustapha

Annan

Azeko

et al. 2015

Journal of Composite Materials

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This paper presents the results of a combined experimental and theoretical study of the strength, fracture toughness, and resistance-curve behavior of natural fiber-reinforced earth-based composite materials. The composites, which consist of mixtures of laterite, clay, and straw, are stabilized with controlled levels of Ordinary Portland cement. The compositional dependence of compressive, flexural/bend strength, and fracture toughness are explored for different proportions of the constituent materials using composites and crack-tip shielding models. The underlying crack-microstructure interactions associated with resistance-curve behavior were also studied using in situ/ex situ optical microscopy. This revealed evidence of crack bridging by the straw fibers. The measured resistance-curve behavior is also shown to be consistent with predictions from small-and large-scale bridging models. The implications of the results are then discussed for potential applications in the design of robust earth-based building materials for sustainable eco-friendly homes.

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An investigation of fracture and fatigue in a metal/polymer composite

Cited by 17 publications

References 14 publications

Corrosion properties of a complex multi‐phase martensitic stainless steel depending on the tempering temperature

Corrosion properties of a complex multi‐phase martensitic stainless steel depending on the tempering temperature

Pull-out behavior of natural fiber from earth-based matrix

Strength and fracture toughness of earth-based natural fiber-reinforced composites

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