Modeling of the Strain Rate Dependency of Polycarbonate’s Yield Stress: Evaluation of Four Constitutive Equations

Al-Juaid, Abdullah A.; Othman, Ramzi

doi:10.1155/2016/6315421

Cited by 9 publications

(5 citation statements)

References 46 publications

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“…From this equation, the average activation volume of the T1 system was found to be ≈1.7 nm 3 (see Figure S12, Supporting Information), which is similar to the volume of one network strand between two centers of alkyne molecules covalently linked with one azide molecule, estimated to be ≈1.2 nm 3 . Furthermore, the activation volume obtained for the T1 polymer is comparable to that found for other glassy polymers (i.e., 1.5 nm 3 for anhydride cross-linked epoxy networks, [59] 2 nm 3 for amine-cross-linked epoxy networks, [58] and 1.9 nm 3 for polycarbonates [60] ).…”

Section: Resultssupporting

confidence: 73%

Photopolymerized Triazole‐Based Glassy Polymer Networks with Superior Tensile Toughness

Han

Baranek

Worrell

et al. 2018

Adv Funct Materials

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Photopolymerization is a ubiquitous, indispensable technique widely applied in applications from coatings, inks, and adhesives to thermosetting restorative materials for medical implants, and the fabrication of complex macro-scale, microscale, and nanoscale 3D architectures via additive manufacturing. However, due to the brittleness inherent in the dominant acrylate-based photopolymerized networks, a significant need exists for higher performance resin/oligomer formulations to create tough, defect-free, mechanically ductile, thermally and chemically resistant, high modulus network polymers with rapid photocuring kinetics. This study presents densely cross-linked triazole-based glassy photopolymers capable of achieving preeminent toughness of ≈70 MJ m−3 and 200% strain at ambient temperature, comparable to conventional tough thermoplastics. Formed either via photoinitiated copper(I)-catalyzed cycloaddition of monomers containing azide and alkyne groups (CuAAC) or via photoinitiated thiol-ene reactions from monomers containing triazole rings, these triazole-containing thermosets completely recover their original dimensions and mechanical behavior after repeated deformations of 50% strain in the glassy state over multiple thermal recovery–strain cycles.

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Section: Resultssupporting

confidence: 73%

Photopolymerized Triazole‐Based Glassy Polymer Networks with Superior Tensile Toughness

Han

Baranek

Worrell

et al. 2018

Adv Funct Materials

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“…The modified-Eyring model is developed by El-Qoubaa and Othman [18][19][20] based on the original work of Eyring [23] except that they used an activation volume decreasing with an increasing strain rate. The model works well here with copper and steel over the studied strain rate range ( Figure 6).…”

Section: Modified-eyring Modelmentioning

confidence: 99%

“…Couque [17] proposed a modified Johnson-Cook equation where the strain rate sensitivity is written in terms of a four-constant equation. El-Qoubaa and Othman [18,19] have proposed a modified-Eyring equation for polymers yield stress sensitivity to strain rates. This model was successfully applied to several metallic materials in [20].…”

Section: Introductionmentioning

confidence: 99%

Constitutive Equations of Yield Stress Sensitivity to Strain Rate of Metals: A Comparative Study

Salahi¹,

Othman²

2016

Journal of Engineering

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Several constitutive equations have proposed to model the strain rate sensitivity of metals to strain rate. This paper presents a comparative of six equations reported in the open literature. All equations are used to fit the yield stress of three copper materials and one steel material at two different temperatures. A specific cost function and an optimization problem are defined. The authors recommend the use of the Cowper-Symonds equation or a modified-Eyring equation as both of them fit well the experimental data while using only three material constants. A modified flow stress Johnson-Cook equation is then proposed for metallic materials.

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“…These theories have been validated for polymer solutions in the 1950s (Ref 17 , 18 ). In recent years, sophisticated measurement equipment allowed for the adaptation validation of these theories for several thermoplastic melts, i.e., polycarbonate (PC) (Ref 11 , 19 ), poly(methyl methacrylate) (PMMA) (Ref 11 ), polyamide-imide (PAI) (Ref 11 ), PEEK (Ref 20 ) polypropylene (PP) (Ref 21 ) and PA6 (Ref 22 ).…”

Section: Introduction and State Of The Artmentioning

confidence: 99%

Development of Thermal Spray Processes for Depositing Coatings on Thermoplastics

Bobzin¹,

Wietheger²,

Knoch³

2021

J Therm Spray Tech

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Thermoplastics combine high freedom of design with economical mass production. Metallic coatings on thermoplastics enable power and signal transmission, shield sensitive parts inside of housings and can reduce the temperature in critical areas by functioning as a heat sink. The most used technical thermoplastics are polyamides (PA), while the described use cases are often realized using Cu. Consequently, several studies tried to apply copper coatings on PA substrates via thermal spraying; so far, this combination is only feasible using an interlayer. In this study, a new approach to metallize thermoplastics via thermal spraying based on validated state-of-the-art predictions of the thermoplastics’ material response at relevant temperatures and strain rates is presented. Using these predictions, high velocity wire-arc spraying was selected as coating process. Furthermore, the process parameters were adapted to realize a continuous coating while also roughening the substrate during coating deposition. The resulting Cu coating on PA6 had a sufficiently high coating adhesion for post-treatment by grinding. The adhesion is achieved by in situ roughening during the coating application. The results indicate that different process parameters for initial layer deposition and further coating buildup are required due to the low thermal stability of PA6.

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Modeling of the Strain Rate Dependency of Polycarbonate’s Yield Stress: Evaluation of Four Constitutive Equations

Cited by 9 publications

References 46 publications

Photopolymerized Triazole‐Based Glassy Polymer Networks with Superior Tensile Toughness

Photopolymerized Triazole‐Based Glassy Polymer Networks with Superior Tensile Toughness

Constitutive Equations of Yield Stress Sensitivity to Strain Rate of Metals: A Comparative Study

Development of Thermal Spray Processes for Depositing Coatings on Thermoplastics

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