Approaches to understand and predict the influence of rapid heat-up on degradation and strength of carbon fibre polymer matrix composites

Wolfrum, Johannes; Whitney, Ellen A. Spotts; Eibl, Sebastian

doi:10.1177/0021998316671184

Cited by 21 publications

(27 citation statements)

References 22 publications

(26 reference statements)

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“…Long-term aging of composite material at a temperature below melting causes a change in glass transition temperature and strength [ 247 , 248 ]. During short-term aging, thermoplastic composite is sharply heated to thermal decomposition temperature; thus, rapid decrease in tensile and interlaminar shear strength is observed [ 249 , 250 ]. Apart from debonding and cracks, delamination and fiber failures can occur [ 251 , 252 ].…”

Section: Raw Materials and Properties Of Obtained Compositesmentioning

confidence: 99%

Thermoplastic Pultrusion: A Review

et al. 2021

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Pultrusion is one of the most efficient methods of producing polymer composite structures with a constant cross-section. Pultruded profiles are widely used in bridge construction, transportation industry, energy sector, and civil and architectural engineering. However, in spite of the many advantages thermoplastic composites have over the thermoset ones, the thermoplastic pultrusion market demonstrates significantly lower production volumes as compared to those of the thermoset one. Examining the thermoplastic pultrusion processes, raw materials, mechanical properties of thermoplastic composites, process simulation techniques, patents, and applications of thermoplastic pultrusion, this overview aims to analyze the existing gap between thermoset and thermoplastic pultrusions in order to promote the development of the latter one. Therefore, observing thermoplastic pultrusion from a new perspective, we intend to identify current shortcomings and issues, and to propose future research and application directions.

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Section: Raw Materials and Properties Of Obtained Compositesmentioning

confidence: 99%

Thermoplastic Pultrusion: A Review

et al. 2021

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“…1 However, polymer composite properties are heavily dependent upon the environment in which they operate and thus are susceptible to degradation at high temperatures and when exposed to fire. 1–38 Therefore, accurate thermal property characterization and behavior modeling for composites is critically important.…”

Section: Introductionmentioning

confidence: 99%

“…One typical focus of this research is on the resultant mechanical properties following high temperature exposure. 1–9 The effects of thermal degradation are also observed by measuring physical changes such as mass loss, delamination, or material surface deformation. 10–16 Further studies have focused on cyclic thermal loading 17,18 and accelerated thermal aging of composites.…”

Section: Introductionmentioning

confidence: 99%

Time to failure modeling of carbon fiber reinforced polymer composites subject to simultaneous tension and one-sided heat flux

Swanson¹,

Wolfrum²

2018

Journal of Composite Materials

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This study focuses on observing and analyzing the time to failure of carbon fiber reinforced polymers subject to mechanical loading and one-sided heat flux simulating fire damage. The purpose of this investigation is to understand the rate of thermal degradation and mechanical property loss from fire exposure, resulting in catastrophic failure under simultaneous tensile loading. Composite samples of varying thicknesses and layup patterns are subject to a constant tensile load below the ultimate strength of the material. A thermal load is applied to one side by an infrared band heater, emitting a constant heat flux. The time to failure is monitored to determine how long the material can withstand this combined loading condition. A consistent trend is observed for various heat flux settings. High mechanical loads contribute to a shorter time to failure, and low mechanical loads contribute to a longer time to failure. Similarly, higher heat flux settings result in shorter failure times, and lower heat flux settings result in longer failure times. Temperature profiles are created based on heat flux exposure time and position through the sample thickness, establishing failure criteria for different loading conditions. The resulting trends are observed and extrapolated to create a predictive model using an Arrhenius exponential decay function.

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“…One typical focus of this research is on the resultant mechanical properties following high-temperature exposure. 1–7 The effects of thermal degradation are also observed by measuring physical changes such as mass loss, delamination, or material surface deformation. 8–12 Further studies have focused on cyclic thermal loading 13,14 and accelerated thermal aging of composites, 15 each revealing different effects of thermal degradation.…”

Section: Introductionmentioning

confidence: 99%

“…However, polymer properties are highly susceptible to degradation at high temperatures, posing significant disadvantages in extreme environments. [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19] This is especially important within structural applications where materials can be exposed to fire while supporting simultaneous mechanical loads. In these cases, components can fail as the thermal load reduces the mechanical properties of the material over time.…”

Section: Introductionmentioning

confidence: 99%

Effects of simultaneous compression and one-sided heat flux on the time to failure of carbon fiber-reinforced polymer composites

Swanson¹,

Wolfrum²

2017

Journal of Composite Materials

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The time to failure of carbon fiber-reinforced polymer composites is investigated during simultaneous compression and one-sided thermal degradation from a constant heat flux. The purpose of this investigation is to determine the rate of thermal degradation and mechanical property loss from fire exposure by observing the time to failure during simultaneous compression loading. A custom compression test fixture is designed and validated for use under thermomechanical loading. Testing is conducted on CFRP samples of varying thicknesses and quasi-isotropic layups. Test conditions are adjusted for a range of heat fluxes and compressive loads. Test parameters are isolated to observe individual impacts on time to failure. In each case, decreasing exponential trends are observed. High heat fluxes and high compressive loads result in shorter failure times. Temperature profiles are created based on heat flux exposure time and the position through the material thickness in order to determine failure criteria for thermomechanical loading. An empirical model is created to extrapolate and predict failure times using a stretched exponential function, based on mechanical preload, heat flux, and material thickness.

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Approaches to understand and predict the influence of rapid heat-up on degradation and strength of carbon fibre polymer matrix composites

Cited by 21 publications

References 22 publications

Thermoplastic Pultrusion: A Review

Thermoplastic Pultrusion: A Review

Time to failure modeling of carbon fiber reinforced polymer composites subject to simultaneous tension and one-sided heat flux

Effects of simultaneous compression and one-sided heat flux on the time to failure of carbon fiber-reinforced polymer composites

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