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Volume 5, Issue 5

Res. Rev. J Mat. Sci. 2017

ISSN: 2321-6212

Advanced Materials 2017

September 07-08, 2017

September 07-08, 2017 | Edinburgh, Scotland

Advanced materials & Processing

11

th

International Conference on

Study of electrically conductive water-based polyurethane

Valentina Caba, Ferrari srl, Laura Borgese

and

Laura E. Depero

University of Brescia, Italy

E

lectrically conductive polymers have shown great potential for several applications in electronic, environmental, and

biomedical fields. In particular, polyurethane is used in electromagnetic shields1, in electrodes for capacitive deionization in the

desalination process of brackish water4, and in electrodes for electrocardiography2 and electroencephalography monitoring3, and

electrostimulation5. Conductive composite materials can be realized as compact (film) or porous (foam) layers, depending on the

process. For polyurethane, literature reports different recipes depending on the final material features. This implies the use of a wide

range of reagents and additives, and it goes against the tendency of manufacturing companies focusing on the reduction of chemical

products and raw materials in their processes. The purpose of this study is the industrial development of electrically conductive

water-based polyurethane, suitable both for foam and film casting. In this study, polyether, polyester, and polycarbonate based

polyurethane is used and mixed with different cross-linkers and conductive fillers. Five different compounds in similar concentration

are compared as cross-linkers. Different loadings of silver based conductive fillers are used. The foam is obtained by mechanical

frothing from the mixture of components used for the film. Paper transfer coating process is used to realize both films and foams

for testing. Different paper release materials are considered. Surface resistivity is measured by two-point probes method. Results

show that the conductivity of the material depends on all the considered variables in different ways. The main contribution is given

by the conductive filler loading, with a percolation threshold about 45% wt. The surface resistivity increases about three orders of

magnitudes from film to foam. This loss of conductivity can be recovered by increasing the filler loading. The water-based conductive

polyurethane prepared in this work, can be successfully realized in porous or compact layers by industrial process manufacturing,

with a cost-saving formula using reduced number of components.

Biography

Valentina Caba has her expertise in waterborne and solventborne polyurethane coating. She has developed this formula of conductive polyurethane after years of

experience in research and developing of polymer coating on paper release. The conductive polyurethane formula could be incorporated into the production of the

textile coating, which leads to the broadening of synthetic leather application. With her interest in eco-friendly components she is looking for improvement of raw

materials quality and the use of chemicals with low or zero volatile organic compounds.

v.caba@unibs.it

Valentina Caba et al., Res. Rev. J Mat. Sci. 2017, 5:5

DOI: 10.4172/2321-6212-C1-006

Figure1:

SEM images of the shell/core connection in A)

sandwich structured, B) layered composite