Effect of Sanding and Plasma Treatment of 3D-Printed Parts on Bonding to Wood with PVAc Adhesive

Kariž, Mirko; Tomec, Daša Krapež; Dahle, Sebastian; Kuzman, Manja Kitek; Šernek, Milan; Žigon, Jure

doi:10.3390/polym13081211

Cited by 21 publications

(17 citation statements)

References 64 publications

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“…Comparable gains for plasma-treated PLA bonded to wood with a PVAc adhesive (0.55-3.72 MPa) were reported by Kariž at al. [40]. On the other hand, Mandolfino et al [41] observed increases of between 52.5% and 386.6% in lap-shear tests performed on a plasma-treated polypropylene film-epoxy adhesive.…”

Section: Effect Of Plasma Treatment On the Performance Of Adhesive Jointsmentioning

confidence: 97%

Discharge Plasma Treatment as an Efficient Tool for Improved Poly(lactide) Adhesive–Wood Interactions

et al. 2021

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Poly(lactide) (PLA) films obtained by thermoforming or solution-casting were modified by diffuse coplanar surface barrier discharge plasma (300 W and 60 s). PLA films were used as hot-melt adhesive in joints in oak wood. It was demonstrated that lap shear strength increased from 3.4 to 8.2 MPa, respectively, for the untreated and plasma-treated series. Pull-off tests performed on particleboard for the untreated and treated PLA films showed 100% cohesive failure. Pull-off strength tests on solid oak demonstrated adhesion enhancement from 3.3 MPa with the adhesion failure mode to 6.6 MPa with the cohesion failure mode for untreated and treated PLA. XPS revealed that carbonyl oxygen content increased by two-to-three-fold, which was confirmed in the Fourier-transform infrared spectroscopy experiments of the treated PLA. The water contact angle decreased from 66.4° for the pristine PLA to 49.8° after treatment. Subsequently, the surface free energy increased from 47.9 to 61.05 mJ/m2. Thus, it was clearly proven that discharge air plasma can be an efficient tool to change surface properties and to strengthen adhesive interactions between PLA and woody substrates.

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Section: Effect Of Plasma Treatment On the Performance Of Adhesive Jointsmentioning

confidence: 97%

Discharge Plasma Treatment as an Efficient Tool for Improved Poly(lactide) Adhesive–Wood Interactions

et al. 2021

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“…Among the three treatment regimes, the combination treatment of plasma and sanding produced superior outcomes with respect to improving adhesion strength. Microscopic visualization of thus-treated surfaces showed the development of significant roughness after sanding, with some of this topography lost when the surface was subsequently exposed to plasma-induced ion bombardment [ 91 ].…”

Section: Plasma For Modifying Mechanical Properties Of Polymer Compositesmentioning

confidence: 99%

“… ( a , b ) Plasma device used for the surface treatment of 3D-printed samples on a CNC positioning system (top left image) with a gliding arc plasma jet ( a ), and sample for testing the bond shear strength ( b ). Reproduced from Kariž et al (2018) [ 91 ] under conditions of the CC BY license. ( c , d ) Representation of the crack path in ABS-interleaved hybrid composites ( c ) with untreated ABS ( d ) with plasma-treated ABS.…”

Section: Figurementioning

confidence: 99%

“…Given that the improvements in the adhesion performance was similar for atmospheric pressure and low pressure plasma systems, there is a pathway to translate these findings into real-life applications. Figure 10a,b illustrates a plasma device used for the surface treatment of 3D-printed samples on a computerized numerical control (CNC) positioning system with a gliding arc plasma jet, and a sample for the testing of the bond shear strength developed by Kariž et al [91]. 3D printing, or additive manufacturing, enables the production of objects and structures with precise geometric shapes in prototyping and, increasingly, in the industrial scale production of goods.…”

Section: Plasma For Modifying Mechanical Properties Of Polymer Compositesmentioning

confidence: 99%

“…These may include roughening through physical means (e.g., sanding), chemical modification and fine etching (e.g., plasma treatment), and a combination of these treatments. When these treatments were applied to fused deposition modeling (FDM) 3Dprinted components fabricated from polylactic acid (PLA), polylactic acid with wood flour additive (Wood-PLA), or acrylonitrile-butadiene-styrene (ABS) polymers, exposure to Figure 10a,b illustrates a plasma device used for the surface treatment of 3D-printed samples on a computerized numerical control (CNC) positioning system with a gliding arc plasma jet, and a sample for the testing of the bond shear strength developed by Kariž et al [91]. 3D printing, or additive manufacturing, enables the production of objects and structures with precise geometric shapes in prototyping and, increasingly, in the industrial scale production of goods.…”

Section: Plasma For Modifying Mechanical Properties Of Polymer Compositesmentioning

confidence: 99%

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Plasma and Polymers: Recent Progress and Trends

Levchenko

Baranov

et al. 2021

Molecules

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Plasma-enhanced synthesis and modification of polymers is a field that continues to expand and become increasingly more sophisticated. The highly reactive processing environments afforded by the inherently dynamic nature of plasma media are often superior to ambient or thermal environments, offering substantial advantages over other processing methods. The fluxes of energy and matter toward the surface enable rapid and efficient processing, whereas the charged nature of plasma-generated particles provides a means for their control. The range of materials that can be treated by plasmas is incredibly broad, spanning pure polymers, polymer-metal, polymer-wood, polymer-nanocarbon composites, and others. In this review, we briefly outline some of the recent examples of the state-of-the-art in the plasma-based polymer treatment and functionalization techniques.

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Experimental and numerical study on mechanical behavior of 3D printed adhesive joints with polycarbonate substrates

Öztürk,

Marques,

Carbas

et al. 2024

J of Applied Polymer Sci

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Adhesive joints play a crucial role in enhancing the structural integrity and performance of 3D printed parts. The purpose of this study is to investigate the failure load and behavior of polycarbonate (PC) single lap joints (SLJs) produced by fused deposition modeling (FDM) using experimental and finite element analysis (FEA) methods. The FEA of joints presents a new approach by integrating PC substrates with Hill yield criterion, transversely isotropic material and adhesive layer with cohesive zone modeling (CZM). The study focused on the effect of printing angles (0°, 45°, and 90°) and overlap lengths (12.5 and 25 mm) on the performance of SLJs. The influence of 3D printing parameters on the mechanical behavior of PC joints was investigated by tensile testing of SLJs. The experimental failure load was 1586 N for a 12.5 mm joint at 90° and 4115 N for a 25.4 mm joint at 0°. Comparison of the experimental and FEA failure loads of the joints showed maximum and minimum differences of 11.98% and 1.34%, respectively. This result showed that the proposed model is applicable for determining the joint strength as a function of the printing angle and monitoring the joint damage behavior.

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Effect of Sanding and Plasma Treatment of 3D-Printed Parts on Bonding to Wood with PVAc Adhesive

Cited by 21 publications

References 64 publications

Discharge Plasma Treatment as an Efficient Tool for Improved Poly(lactide) Adhesive–Wood Interactions

Discharge Plasma Treatment as an Efficient Tool for Improved Poly(lactide) Adhesive–Wood Interactions

Plasma and Polymers: Recent Progress and Trends

Experimental and numerical study on mechanical behavior of 3D printed adhesive joints with polycarbonate substrates

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