Spreading Dynamics of Molten Polymer Drops on Glass Substrates

Zhang, Y.; Fuentes, C.A.; Koekoekx, Robin; Clasen, Christian; Vuure, Aart Willem Van; Coninck, J. De; Seveno, David

doi:10.1021/acs.langmuir.7b01500

Cited by 35 publications

(37 citation statements)

References 48 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Figure 10 shows the results, indicating that for paraffin oil this law fits quite well the experimental data at different temperatures and at Ca < 2 • 10 −3 , allowing to obtain the coefficient of contact line friction ξ (Blake and De Coninck, 2002), shown in Table 5. The coefficient of contact line friction decreases as the temperature is increased, and then it is higher when the viscosity is higher, according to the literature (Zhang et al, 2017).…”

Section: Mkt Predictionmentioning

confidence: 78%

“…Some works using microfluidic techniques proved that, with partially wetting liquids, established models in literature are no longer valid (Wielhorski et al, 2012;Abdelwahed et al, 2014). A recent work studied molten polymers but in a spontaneous regime of drop spreading (Zhang et al, 2017). This procedure has been applied to rods or fibers with a large diameter (Zhang et al, 2019) but it turns out to be more difficult for thinner fibers (Hansen et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Dynamic Wetting of Molten Polymers on Cellulosic Substrates: Model Prediction for Total and Partial Wetting

et al. 2020

View full text Add to dashboard Cite

This work consists in an experimental investigation of forced dynamic wetting of molten polymers on cellulosic substrates and an estimation of models describing this dynamic. A previous work of Pucci et al. (2018) showed that for totally wetting liquids (as paraffin oils), temperature-induced variations in dynamic wetting are included into the capillary number (Ca) and then a master curve of dynamic contact angle (θ d) as a function of Ca can be obtained. The hydrodynamic theory (HDT) correctly describes the dynamic wetting for Ca > 2 • 10 −3. For lower Ca, a change in the dynamic wetting behavior was observed. Here, partially wetting liquids (polyethylene glycols, a.k.a. PEGs) at different molecular weight (Mn) were used at temperatures above their melting point to investigate the dynamic wetting behavior on cellulosic substrates for a large range of Ca. It was found that the dynamic curves of θ d vs. Ca depend on Mn. Moreover, the HDT correctly describes the experimental measurements for Ca > 2 • 10 −3. Below this threshold the dynamic contact angle decreases toward the static one. A linear correlation between parameters obtained fitting the HDT and the molecular weight of polymer was found. The prediction of dynamic wetting for low Ca (Ca < 2 • 10 −3) with the molecular kinetic theory (MKT) was also evaluated and discussed.

show abstract

Section: Mkt Predictionmentioning

confidence: 78%

Section: Introductionmentioning

confidence: 99%

Dynamic Wetting of Molten Polymers on Cellulosic Substrates: Model Prediction for Total and Partial Wetting

et al. 2020

View full text Add to dashboard Cite

show abstract

“…Such liquids include hexadecane [25], dodecane [14], methanol [20], ethanol [20] and especially polydimethylsiloxane (PDMS) [17,23,26,14] due to ease of obtaining PDMS oils of different viscosities. One recent study considers wetting of molten thermoplastics [27], but still in a spontaneous drop spreading configuration on glass substrates, that could not represent forced dynamic wetting conditions on fibres during composite manufacturing [28].…”

Section: Introductionmentioning

confidence: 99%

Temperature effect on dynamic wetting of cellulosic substrates by molten polymers for composite processing

Pucci

Duchemin

Gomina

et al. 2018

Composites Part A: Applied Science and Manufacturing

View full text Add to dashboard Cite

Impregnation of plant fibre reinforcements by a molten polymer involves many phenomena still poorly understood, related to the solid morphology and its surface chemistry, but also to the temperature effect on liquid properties and solid/liquid interactions. The present work focuses on the temperature effect on forced dynamic wetting, using the Wilhelmy method and two model materials: a cellulosic film and two totally wetting paraffin oils. The results show that the dynamic contact angle vs. the capillary number (Ca) plot appears as a master curve. This curve is split in two domains. The domain associated with Ca>10 −3 is well described by the hydrodynamic approach. The domain with Ca<10 −3 corresponds to wetting processes operating on a smaller scale, which are more sensitive to the physico-chemical heterogeneities of the substrate. This study addresses the mechanisms governing the capillary pressure, void formation and interface generation during composite manufacturing.

show abstract

“…However, when the temperature rises continuously, the contact angle increases, indicating the gradual deterioration of the wettability, and at 380 °C, the contact angle is 93.3°, showing non-wettability at this condition. The contact angles are closely connected with the surface energy of melted PEEK and CFs, and the surface energy of PEEK differs with the changes of temperature [29], because CFs cannot change their shape when the surface energy of melted PEEK changes. Liquids can shrink or spread during the process to maintain the balance among gas, liquids (melted PEEK) and solids (CFs).…”

Section: Resultsmentioning

confidence: 99%

The Optimization of Process Parameters and Characterization of High-Performance CF/PEEK Composites Prepared by Flexible CF/PEEK Plain Weave Fabrics

Zheng

et al. 2018

Polymers

View full text Add to dashboard Cite

Continuous carbon fiber (CF)-reinforced poly (ether ether ketone) (PEEK) composites have excellent mechanical properties, but their processing techniques are limited. Therefore, we promoted a braiding method based on the hybrid fiber method by hot-compacting CF/PEEK plain weave fabrics to solve the problem of difficult wetting between CF and PEEK. Four parameters—melting temperature, molding pressure, crystallization temperature and the resin contents—were investigated for optimized fabrication. After studying the melting range, thermal stability and the contact angle of PEEK under different temperatures, the melting temperature was set at 370 °C. An ultra-depth-of-field 3D microscope was adopted to investigate the effects of molding pressure in the melting stage. The tensile strength or modulus along and perpendicular to the carbon fiber direction and crystallinity under different crystallization temperatures were analyzed. As a result, the sample crystalized at 300 °C showed an excellent tensile properties and crystallinity. The increased mass ratio of PEEK ranging from 50.45% to 59.07% allowed for much stronger interfacial strength; however, the higher resin content can lead to the dispersion of CFs, loss of resin and the formation of defects during processing. Finally, the optimal resin mass content was 59.07%, with a tensile strength of 738.36 ± 14.49 MPa and a flexural strength of 659.68 ± 57.53 MPa. This paper studied the optimized processing parameters to obtain better properties from CF/PEEK plain weave fabrics and to further broaden the specific applications of CF/PEEK composites, demonstrating a new direction for its fabrication.

show abstract

Spreading Dynamics of Molten Polymer Drops on Glass Substrates

Cited by 35 publications

References 48 publications

Dynamic Wetting of Molten Polymers on Cellulosic Substrates: Model Prediction for Total and Partial Wetting

Dynamic Wetting of Molten Polymers on Cellulosic Substrates: Model Prediction for Total and Partial Wetting

Temperature effect on dynamic wetting of cellulosic substrates by molten polymers for composite processing

The Optimization of Process Parameters and Characterization of High-Performance CF/PEEK Composites Prepared by Flexible CF/PEEK Plain Weave Fabrics

Contact Info

Product

Resources

About