Adhesion Optimization between Incompatible Polymers through Interfacial Engineering

Mashayekhi, Fatemeh; Bardon, Julien; Westermann, Stephan; Addiego, Frédéric

doi:10.3390/polym13244273

Cited by 8 publications

(3 citation statements)

References 41 publications

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“…Samples overprinted at substrates with varied surface roughnesses had tear-off strengths in a range of around 0.3 MPa to 0.4 MPa, with the highest value associated with the sample with the lowest surface roughness. Higher surface roughness should lead to better adhesion between the polymer surfaces due to a higher specific surface area and additional mechanical interlocking, which was not the case in our study [ 33 ]. Possible explanations for this are that the material viscosity being too high to effectively fill the pits of the rougher surface, the peaks melting due to heat transfer from the extruder material or the effect being so small that it was not visible due to high deviations in the measured values.…”

Section: Resultsmentioning

confidence: 78%

Overprinting of TPU onto PA6 Substrates: The Influences of the Interfacial Area, Surface Roughness and Processing Parameters on the Adhesion between Components

Slapnik,

Lorber,

Pulko

et al. 2024

Polymers

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The hybridisation of injection moulding (IM) and additive manufacturing (AM) offers the opportunity to combine the high productivity of IM and the high flexibility of AM into a single process. IM parts can be overprinted through fused filament fabrication (FFF) to allow for the customisation of parts or to add new functionalities. However, the right material pair must be chosen, and processing parameters must be optimised to achieve suitable adhesion between the components. The present study dealt with the investigation of the influence of the interfacial area, substrate surface roughness and overprinting processing parameters on the adhesion between the polyamide 6 (PA6) substrate and thermoplastic polyurethane (TPU) rib overprinted via FFF. PA6 substrates were produced through the IM of plates into a mould with different textures to obtain substrates with three different surface roughnesses. The ribs with varied interfacial areas were overprinted onto produced substrates using a desktop FFF 3D printer. To study the effect of overprinting processing parameters, the ribs were overprinted under varying printing and substrate temperatures and printing speeds according to the Box–Behnken design of experiments (DoE). The chemical composition and thermal properties of used materials were determined via attenuated total reflectance–Fourier transform infrared spectroscopy (ATR-FTIR), thermogravimetric analysis (TGA), differential scanning calorimetry (DSC) and dynamic mechanical analysis (DMA). The surface properties of prepared substrates were studied via digital optical microscopy (OM), through surface roughness measurements using a confocal microscope, through contact angle (CA) measurements and through the determination of free surface energy (SFE). The adhesion between the components was determined by evaluating the tear-off strength using a universal testing machine (UTM). With an increasing interfacial area, the tear-off strength decreased, while substrate surface roughness had no statistically significant effect. Overprinting parameters influenced the tear-off strength in the order of printing speed > printing temperature > substrate temperature. High values of tear-off strength were found for the lowest printing speed, while there were no important differences found between the middle and upper values. With increasing printing and substrate temperatures, the tear-off strength increased linearly. The highest value of tear-off strength (0.84 MPa) was observed at a printing temperature, substrate temperature and printing speed of 250 °C, 80 °C and 2 mm/s, respectively.

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Section: Resultsmentioning

confidence: 78%

Overprinting of TPU onto PA6 Substrates: The Influences of the Interfacial Area, Surface Roughness and Processing Parameters on the Adhesion between Components

Slapnik,

Lorber,

Pulko

et al. 2024

Polymers

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“…Very recently, Mashayekhi et al used coating of PDA to bind polyimide (PI) and polylactide (PLA), which are well-known to be incompatible with each other. 113 Han et al synthesized a polydopamine-claypolyacrylamide (PDA-clay-PAM) hydrogel adhesive film, capable of demonstrating strong adhesion with robust mechanical strength (Figure 15b). 114 The catechol groups generated by PDA in the composite hydrogel adhesive was responsible for the enhanced adhesion strength.…”

Section: Mussels Inspired Adhesivesmentioning

confidence: 99%

Biomimetic Polymer Adhesives

Dwivedi

Singh

Chaudhary

et al. 2022

ACS Appl. Polym. Mater.

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Nature is filled with various living organisms, ranging from micron scale fungi to large scale vertebrates, which possess unique adhesion characteristics, including self-cleaning, antifouling, and reusability in both wet and dry environments. Inspired from the natural adhesives, humans have endeavored to mimic and acquire those adhesion characteristics in artificially designed adhesives. Over several decades, researchers have employed various fabrication techniques and have used a variety of materials, predominantly polymers, to manufacture artificial adhesives which emulate the fundamental design aspects of the bioadhesion to match their adhesion performance. In this review, we briefly discuss the fundamentals aspects of adhesion, biomimetic design principles (derived from geckos, mussels, octopuses, and tree frogs), state of the art adhesion performance of the fabricated adhesives, their applications, and future outlook for the polymer-based adhesives both under dry and wet conditions.

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“…In recent years, the fabrication of sensory elements using additive manufacturing techniques received significant scientific attention [ 1 , 2 ]. The research of 3D-printed dynamic sensors is important since complex sensor shapes can be fabricated and embedded within structures already in the manufacturing stages [ 3 ].…”

Section: Introductionmentioning

confidence: 99%

Modeling of Single-Process 3D-Printed Piezoelectric Sensors with Resistive Electrodes: The Low-Pass Filtering Effect

Košir

Slavič

2022

Polymers

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Three-dimensional printing by material extrusion enables the production of fully functional dynamic piezoelectric sensors in a single process. Because the complete product is finished without additional processes or assembly steps, single-process manufacturing opens up new possibilities in the field of smart dynamic structures. However, due to material limitations, the 3D-printed piezoelectric sensors contain electrodes with significantly higher electrical resistance than classical piezoelectric sensors. The continuous distribution of the capacitance of the piezoelectric layer and the resistance of the electrodes results in low-pass filtering of the collected charge. Consequently, the usable frequency range of 3D-printed piezoelectric sensors is limited not only by the structural properties but also by the electrical properties. This research introduces an analytical model for determining the usable frequency range of a 3D-printed piezoelectric sensor with resistive electrodes. The model was used to determine the low-pass cutoff frequency and thus the usable frequency range of the 3D-printed piezoelectric sensor. The low-pass electrical cutoff frequency of the 3D-printed piezoelectric sensor was also experimentally investigated and good agreement was found with the analytical model. Based on this research, it is possible to design the electrical and dynamic characteristics of 3D-printed piezoelectric sensors. This research opens new possibilities for the design of future intelligent dynamic systems 3D printed in a single process.

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Adhesion Optimization between Incompatible Polymers through Interfacial Engineering

Cited by 8 publications

References 41 publications

Overprinting of TPU onto PA6 Substrates: The Influences of the Interfacial Area, Surface Roughness and Processing Parameters on the Adhesion between Components

Overprinting of TPU onto PA6 Substrates: The Influences of the Interfacial Area, Surface Roughness and Processing Parameters on the Adhesion between Components

Biomimetic Polymer Adhesives

Modeling of Single-Process 3D-Printed Piezoelectric Sensors with Resistive Electrodes: The Low-Pass Filtering Effect

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