Surface tailoring and design-driven prototyping of fabrics with 3D-printing: An all-cellulose approach

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Surface tailoring and design-driven prototyping of fabrics with 3D-printing : An all-cellulose approach. / Tenhunen, Tiia Maria; Moslemian, Oldouz; Kammiovirta, Kari; Harlin, Ali; Kääriäinen, Pirjo; Österberg, Monika; Tammelin, Tekla; Orelma, Hannes.

In: Materials and Design, Vol. 140, 2018, p. 409-419.

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Tenhunen, Tiia Maria ; Moslemian, Oldouz ; Kammiovirta, Kari ; Harlin, Ali ; Kääriäinen, Pirjo ; Österberg, Monika ; Tammelin, Tekla ; Orelma, Hannes. / Surface tailoring and design-driven prototyping of fabrics with 3D-printing : An all-cellulose approach. In: Materials and Design. 2018 ; Vol. 140. pp. 409-419.

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@article{21a1429c4a4744d1ab3756240c669bea,
title = "Surface tailoring and design-driven prototyping of fabrics with 3D-printing: An all-cellulose approach",
abstract = "In this work, we present a new all-cellulose approach for modifying and functionalizing textiles. The use of 3D-printing and two acetylated cellulose derivatives, rigid cellulose acetate (CA) and flexible acetoxypropyl cellulose (APC), on cellulosic fabrics were studied. In addition, prototypes were generated using a design-driven approach. The interactions of cellulose derivatives with cellulose were assessed by quartz crystal microbalance with dissipation monitoring (QCM-D). 3D-printing of cellulosic materials on cellulosic fabrics was performed using a direct-write method by printing cellulose derivatives on woven and knitted cotton and woven viscose fabrics. The adhesion of the printed structures was evaluated via peeling and washability tests. The results indicated that although both cellulose derivatives had a positive attraction towards the cellulose substrate, CA had higher affinity and good adhesion properties, whereas the more branched molecular structure of APC was less firmly attached to cellulosic material. The applicability of 3D-printing cellulosic materials for textile modification and functionalization was assessed through iterative prototyping. Visual effects and functional surface structures were demonstrated. Utilization of 3D-printing of cellulosic materials for surface tailoring of cellulosic textiles, eliminates labour intensive processing or external glues and may enable new and simple customization processes with minimized material usage.",
keywords = "3D-printing, Acetoxypropyl cellulose, Cellulose acetate, Cellulose derivatives, Design-driven, Prototyping",
author = "Tenhunen, {Tiia Maria} and Oldouz Moslemian and Kari Kammiovirta and Ali Harlin and Pirjo K{\"a}{\"a}ri{\"a}inen and Monika {\"O}sterberg and Tekla Tammelin and Hannes Orelma",
year = "2018",
doi = "10.1016/j.matdes.2017.12.012",
language = "English",
volume = "140",
pages = "409--419",
journal = "Materials and Design",
issn = "0264-1275",
publisher = "Elsevier BV",

}

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TY - JOUR

T1 - Surface tailoring and design-driven prototyping of fabrics with 3D-printing

T2 - An all-cellulose approach

AU - Tenhunen, Tiia Maria

AU - Moslemian, Oldouz

AU - Kammiovirta, Kari

AU - Harlin, Ali

AU - Kääriäinen, Pirjo

AU - Österberg, Monika

AU - Tammelin, Tekla

AU - Orelma, Hannes

PY - 2018

Y1 - 2018

N2 - In this work, we present a new all-cellulose approach for modifying and functionalizing textiles. The use of 3D-printing and two acetylated cellulose derivatives, rigid cellulose acetate (CA) and flexible acetoxypropyl cellulose (APC), on cellulosic fabrics were studied. In addition, prototypes were generated using a design-driven approach. The interactions of cellulose derivatives with cellulose were assessed by quartz crystal microbalance with dissipation monitoring (QCM-D). 3D-printing of cellulosic materials on cellulosic fabrics was performed using a direct-write method by printing cellulose derivatives on woven and knitted cotton and woven viscose fabrics. The adhesion of the printed structures was evaluated via peeling and washability tests. The results indicated that although both cellulose derivatives had a positive attraction towards the cellulose substrate, CA had higher affinity and good adhesion properties, whereas the more branched molecular structure of APC was less firmly attached to cellulosic material. The applicability of 3D-printing cellulosic materials for textile modification and functionalization was assessed through iterative prototyping. Visual effects and functional surface structures were demonstrated. Utilization of 3D-printing of cellulosic materials for surface tailoring of cellulosic textiles, eliminates labour intensive processing or external glues and may enable new and simple customization processes with minimized material usage.

AB - In this work, we present a new all-cellulose approach for modifying and functionalizing textiles. The use of 3D-printing and two acetylated cellulose derivatives, rigid cellulose acetate (CA) and flexible acetoxypropyl cellulose (APC), on cellulosic fabrics were studied. In addition, prototypes were generated using a design-driven approach. The interactions of cellulose derivatives with cellulose were assessed by quartz crystal microbalance with dissipation monitoring (QCM-D). 3D-printing of cellulosic materials on cellulosic fabrics was performed using a direct-write method by printing cellulose derivatives on woven and knitted cotton and woven viscose fabrics. The adhesion of the printed structures was evaluated via peeling and washability tests. The results indicated that although both cellulose derivatives had a positive attraction towards the cellulose substrate, CA had higher affinity and good adhesion properties, whereas the more branched molecular structure of APC was less firmly attached to cellulosic material. The applicability of 3D-printing cellulosic materials for textile modification and functionalization was assessed through iterative prototyping. Visual effects and functional surface structures were demonstrated. Utilization of 3D-printing of cellulosic materials for surface tailoring of cellulosic textiles, eliminates labour intensive processing or external glues and may enable new and simple customization processes with minimized material usage.

KW - 3D-printing

KW - Acetoxypropyl cellulose

KW - Cellulose acetate

KW - Cellulose derivatives

KW - Design-driven

KW - Prototyping

UR - http://www.scopus.com/inward/record.url?scp=85038031466&partnerID=8YFLogxK

U2 - 10.1016/j.matdes.2017.12.012

DO - 10.1016/j.matdes.2017.12.012

M3 - Article

VL - 140

SP - 409

EP - 419

JO - Materials and Design

JF - Materials and Design

SN - 0264-1275

ER -

ID: 17421989