Adhesion-cohesion balance of prepreg tack in thermoset automated fiber placement: Part 1: Adhesion and surface wetting

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • D. Budelmann
  • C. Schmidt
  • D. Meiners

Externe Organisationen

  • Technische Universität Clausthal
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Aufsatznummer100204
Seitenumfang12
FachzeitschriftComposites Part C: Open Access
Jahrgang6
PublikationsstatusVeröffentlicht - Okt. 2021

Abstract

The constitution of prepreg tack in automated fiber placement (AFP) is affected by a sensitive balance between adhesive interfacial bond strength and cohesive strength of the prepreg resin. In an effort to explore the role of interfacial liquid-solid interaction on the tack of commercial aerospace-grade epoxy prepreg, a surface wetting analysis was performed on AFP-related substrates. The standard test liquid combination water/diiodmethane and extracted neat epoxy resin were used for contact angle measurement employing the sessile drop method and the Owens-Wendt-Rabel-Kaelble (OWRK) model. Additional rheological and topographical analyses were carried out to account for viscous resin flow on surfaces of different roughness. The results from the material characterization are discussed against the background of tack measurement by probe tack testing utilizing a rheometer. Significant differences between the investigated surfaces in terms of both the maximum tack level and the onset temperatures of adhesion were found as a function of test parameters relevant for contact formation. General agreement with the experimental tack results was observed employing a topographically extended version of the Dahlquist criterion. For each substrate, a temperature-dependent critical storage modulus could be determined that conforms to the onset temperature of tackiness. Contact angle measurements revealed a correlation between the thermodynamic work of adhesion and maximum tack and, moreover, the tack onset in the adhesive regime when additionally incorporating surface topography. Matching ratios of polar and dispersive surface free energy and surface tension components were found to favor the molecular interaction at the interface between prepreg resin and substrate.

ASJC Scopus Sachgebiete

Zitieren

Adhesion-cohesion balance of prepreg tack in thermoset automated fiber placement: Part 1: Adhesion and surface wetting. / Budelmann, D.; Schmidt, C.; Meiners, D.
in: Composites Part C: Open Access, Jahrgang 6, 100204, 10.2021.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Budelmann D, Schmidt C, Meiners D. Adhesion-cohesion balance of prepreg tack in thermoset automated fiber placement: Part 1: Adhesion and surface wetting. Composites Part C: Open Access. 2021 Okt;6:100204. doi: 10.1016/j.jcomc.2021.100204, 10.15488/14547
Budelmann, D. ; Schmidt, C. ; Meiners, D. / Adhesion-cohesion balance of prepreg tack in thermoset automated fiber placement : Part 1: Adhesion and surface wetting. in: Composites Part C: Open Access. 2021 ; Jahrgang 6.
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abstract = "The constitution of prepreg tack in automated fiber placement (AFP) is affected by a sensitive balance between adhesive interfacial bond strength and cohesive strength of the prepreg resin. In an effort to explore the role of interfacial liquid-solid interaction on the tack of commercial aerospace-grade epoxy prepreg, a surface wetting analysis was performed on AFP-related substrates. The standard test liquid combination water/diiodmethane and extracted neat epoxy resin were used for contact angle measurement employing the sessile drop method and the Owens-Wendt-Rabel-Kaelble (OWRK) model. Additional rheological and topographical analyses were carried out to account for viscous resin flow on surfaces of different roughness. The results from the material characterization are discussed against the background of tack measurement by probe tack testing utilizing a rheometer. Significant differences between the investigated surfaces in terms of both the maximum tack level and the onset temperatures of adhesion were found as a function of test parameters relevant for contact formation. General agreement with the experimental tack results was observed employing a topographically extended version of the Dahlquist criterion. For each substrate, a temperature-dependent critical storage modulus could be determined that conforms to the onset temperature of tackiness. Contact angle measurements revealed a correlation between the thermodynamic work of adhesion and maximum tack and, moreover, the tack onset in the adhesive regime when additionally incorporating surface topography. Matching ratios of polar and dispersive surface free energy and surface tension components were found to favor the molecular interaction at the interface between prepreg resin and substrate.",
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AU - Budelmann, D.

AU - Schmidt, C.

AU - Meiners, D.

N1 - Publisher Copyright: © 2021 The Author(s)

PY - 2021/10

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AB - The constitution of prepreg tack in automated fiber placement (AFP) is affected by a sensitive balance between adhesive interfacial bond strength and cohesive strength of the prepreg resin. In an effort to explore the role of interfacial liquid-solid interaction on the tack of commercial aerospace-grade epoxy prepreg, a surface wetting analysis was performed on AFP-related substrates. The standard test liquid combination water/diiodmethane and extracted neat epoxy resin were used for contact angle measurement employing the sessile drop method and the Owens-Wendt-Rabel-Kaelble (OWRK) model. Additional rheological and topographical analyses were carried out to account for viscous resin flow on surfaces of different roughness. The results from the material characterization are discussed against the background of tack measurement by probe tack testing utilizing a rheometer. Significant differences between the investigated surfaces in terms of both the maximum tack level and the onset temperatures of adhesion were found as a function of test parameters relevant for contact formation. General agreement with the experimental tack results was observed employing a topographically extended version of the Dahlquist criterion. For each substrate, a temperature-dependent critical storage modulus could be determined that conforms to the onset temperature of tackiness. Contact angle measurements revealed a correlation between the thermodynamic work of adhesion and maximum tack and, moreover, the tack onset in the adhesive regime when additionally incorporating surface topography. Matching ratios of polar and dispersive surface free energy and surface tension components were found to favor the molecular interaction at the interface between prepreg resin and substrate.

KW - Adhesion

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KW - Carbon fiber

KW - Epoxy resin

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