Printed supercapacitor as hybrid device with an enzymatic power source

Keskinen Jari; Sivonen Eino; Mikael Bergelin; Jan-Erik Eriksson; Pia Sjöberg-Eerola; Valkiainen Matti; Smolander Maria; Vaari Anu; Uotila Johanna; Boer Harry; Tuurala Saara

doi:10.4028/www.scientific.net/AST.72.331

Printed supercapacitor as hybrid device with an enzymatic power source

Keskinen Jari, Sivonen Eino, Mikael Bergelin, Jan-Erik Eriksson, Pia Sjöberg-Eerola, Valkiainen Matti, Smolander Maria, Vaari Anu, Uotila Johanna, Boer Harry, Tuurala Saara

Research output: Chapter in Book/Conference proceeding › Conference contribution › Scientific › peer-review

Abstract

Low cost printable power sources are needed e.g. in sensors and RFID applications. As manufg. method, printing is preferred to keep the costs low. The materials should also be easily disposable. Enzymic bio-fuel cells are an alternative for printable primary batteries. Since one drawback of bio-fuel cells is their low power, the authors have developed supercapacitors that can be combined with enzymic bio-fuel cells to provide the power peaks necessary in the applications. The materials for the supercapacitors have been chosen to be compatible with the fuel cell and with printing methods, e.g. the activated C powder in the electrodes was bound with chitosan. As printing substrates the authors used paperboards. The current collectors have been made of graphite and metal inks. Since the voltage requirement is limited to ∼1 V, aq. electrolytes have been used. Printed supercapacitors of various sizes have been prepd. The geometrical electrode areas have been between 0.5 and 2 cm2. The max. feasible output current was in the order of 50 mA corresponding to ∼50 mW power. When the capacitor is used together with an enzymic power source, the leakage current must be as low as possible. Typical leakage current values have been in the order of 10 μA.

Original language	Undefined/Unknown
Title of host publication	Advances in Science and Technology
Editors	Trans Tech Publications Ltd.
Pages	331–336
DOIs	https://doi.org/10.4028/www.scientific.net/AST.72.331
Publication status	Published - 2010
MoE publication type	A4 Article in a conference publication
Event	conference - Duration: 1 Jan 2010 → …

Conference

Conference	conference
Period	01/01/10 → …

Access to Document

10.4028/www.scientific.net/AST.72.331

Cite this

@inproceedings{192fc598145746729cced552267090c1,

title = "Printed supercapacitor as hybrid device with an enzymatic power source",

abstract = "Low cost printable power sources are needed e.g. in sensors and RFID applications. As manufg. method, printing is preferred to keep the costs low. The materials should also be easily disposable. Enzymic bio-fuel cells are an alternative for printable primary batteries. Since one drawback of bio-fuel cells is their low power, the authors have developed supercapacitors that can be combined with enzymic bio-fuel cells to provide the power peaks necessary in the applications. The materials for the supercapacitors have been chosen to be compatible with the fuel cell and with printing methods, e.g. the activated C powder in the electrodes was bound with chitosan. As printing substrates the authors used paperboards. The current collectors have been made of graphite and metal inks. Since the voltage requirement is limited to ∼1 V, aq. electrolytes have been used. Printed supercapacitors of various sizes have been prepd. The geometrical electrode areas have been between 0.5 and 2 cm2. The max. feasible output current was in the order of 50 mA corresponding to ∼50 mW power. When the capacitor is used together with an enzymic power source, the leakage current must be as low as possible. Typical leakage current values have been in the order of 10 μA.",

author = "Keskinen Jari and Sivonen Eino and Mikael Bergelin and Jan-Erik Eriksson and Pia Sj{\"o}berg-Eerola and Valkiainen Matti and Smolander Maria and Vaari Anu and Uotila Johanna and Boer Harry and Tuurala Saara",

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AU - Jari, Keskinen

AU - Eino, Sivonen

AU - Bergelin, Mikael

AU - Eriksson, Jan-Erik

AU - Sjöberg-Eerola, Pia

AU - Matti, Valkiainen

AU - Maria, Smolander

AU - Anu, Vaari

AU - Johanna, Uotila

AU - Harry, Boer

AU - Saara, Tuurala

PY - 2010

Y1 - 2010

N2 - Low cost printable power sources are needed e.g. in sensors and RFID applications. As manufg. method, printing is preferred to keep the costs low. The materials should also be easily disposable. Enzymic bio-fuel cells are an alternative for printable primary batteries. Since one drawback of bio-fuel cells is their low power, the authors have developed supercapacitors that can be combined with enzymic bio-fuel cells to provide the power peaks necessary in the applications. The materials for the supercapacitors have been chosen to be compatible with the fuel cell and with printing methods, e.g. the activated C powder in the electrodes was bound with chitosan. As printing substrates the authors used paperboards. The current collectors have been made of graphite and metal inks. Since the voltage requirement is limited to ∼1 V, aq. electrolytes have been used. Printed supercapacitors of various sizes have been prepd. The geometrical electrode areas have been between 0.5 and 2 cm2. The max. feasible output current was in the order of 50 mA corresponding to ∼50 mW power. When the capacitor is used together with an enzymic power source, the leakage current must be as low as possible. Typical leakage current values have been in the order of 10 μA.

AB - Low cost printable power sources are needed e.g. in sensors and RFID applications. As manufg. method, printing is preferred to keep the costs low. The materials should also be easily disposable. Enzymic bio-fuel cells are an alternative for printable primary batteries. Since one drawback of bio-fuel cells is their low power, the authors have developed supercapacitors that can be combined with enzymic bio-fuel cells to provide the power peaks necessary in the applications. The materials for the supercapacitors have been chosen to be compatible with the fuel cell and with printing methods, e.g. the activated C powder in the electrodes was bound with chitosan. As printing substrates the authors used paperboards. The current collectors have been made of graphite and metal inks. Since the voltage requirement is limited to ∼1 V, aq. electrolytes have been used. Printed supercapacitors of various sizes have been prepd. The geometrical electrode areas have been between 0.5 and 2 cm2. The max. feasible output current was in the order of 50 mA corresponding to ∼50 mW power. When the capacitor is used together with an enzymic power source, the leakage current must be as low as possible. Typical leakage current values have been in the order of 10 μA.

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