Piezoresistive strain sensor array using polydimethylsiloxane-based conducting nanocomposites for electronic skin application
Purpose This paper aims to report a stretchable piezoresistive strain sensor array that can detect various static and dynamic stimuli, including bending, normal force, shear stress and certain range of temperature variation, through sandwiching an array of conductive blocks, made of multiwalled carb...
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| Veröffentlicht in: | Sensor review 2018-07, Vol.38 (4), p.494-500 |
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| creator | Chong, Yung Sin Yeoh, Keat Hoe Leow, Pei Ling Chee, Pei Song |
| description | Purpose
This paper aims to report a stretchable piezoresistive strain sensor array that can detect various static and dynamic stimuli, including bending, normal force, shear stress and certain range of temperature variation, through sandwiching an array of conductive blocks, made of multiwalled carbon nanotubes (MWCNTs) and polydimethylsiloxane (PDMS) composite. The strain sensor array induces localized resistance changes at different external mechanical forces, which can be potentially implemented as electronic skin.
Design/methodology/approach
The working principle is the piezoresistivity of the strain sensor array is based on the tunnelling resistance connection between the fillers and reformation of the percolating path when the PDMS and MWCNT composite deforms. When an external compression stimulus is exerted, the MWCNT inter-filler distance at the conductive block array reduces, resulting in the reduction of the resistance. The resistance between the conductive blocks in the array, on the other hand, increases when the strain sensor is exposed to an external stretching force. The methodology was as follows: Numerical simulation has been performed to study the pressure distribution across the sensor. This method applies two thin layers of conductive elastomer composite across a 2 × 3 conductive block array, where the former is to detect the stretchable force, whereas the latter is to detect the compression force. The fabrication of the strain sensor consists of two main stages: fabricating the conducting block array (detect compression force) and depositing two thin conductive layers (detect stretchable force).
Findings
Characterizations have been performed at the sensor pressure response: static and dynamic configuration, strain sensing and temperature sensing. Both pressure and strain sensing are studied in terms of the temporal response. The temporal response shows rapid resistance changes and returns to its original value after the external load is removed. The electrical conductivity of the prototype correlates to the temperature by showing negative temperature coefficient material behaviour with the sensitivity of −0.105 MΩ/°C.
Research limitations/implications
The conductive sensor array can potentially be implemented as electronic skin due to its reaction with mechanical stimuli: compression and stretchable pressure force, strain sensing and temperature sensing.
Originality/value
This prototype enables various static and dynamic stimulus detec |
| doi_str_mv | 10.1108/SR-11-2017-0238 |
| format | Article |
| fullrecord | <record><control><sourceid>proquest_emera</sourceid><recordid>TN_cdi_emerald_primary_10_1108_SR-11-2017-0238</recordid><sourceformat>XML</sourceformat><sourcesystem>PC</sourcesystem><sourcerecordid>2063171861</sourcerecordid><originalsourceid>FETCH-LOGICAL-c308t-319f3d2b7adb80d3779a3ae4e612fab40f4b039cb6658d1ffc2d7df7dabdf27e3</originalsourceid><addsrcrecordid>eNptkUtLAzEUhYMoWKtrtwOuU_Ook3QpxRcIStX1kEluNDpNxtxUrOB_d0rdCK7O5jvnwncJOeZswjnTpw8LyjkVjCvKhNQ7ZMTVmaa1FnqXjJioGRVC631ygPjKGBfTWo7I932Ar5QBA5bwARWWbEKsECKmXJmczbpaYYjPVZ-6tQtLKC_rDkOXPk0E2hoEV9kU3cqWDRVNTDYt-4ShAFZ-GIEObMkpBlvh27Bt-r4L1pSQ4iHZ86ZDOPrNMXm6vHicX9Pbu6ub-fkttZLpQiWfeelEq4xrNXNSqZmRBqZQc-FNO2V-2jI5s21dn2nHvbfCKeeVM63zQoEck5Ptbp_T-wqwNK9pleNwshGsllxxXfOBOt1SNifEDL7pc1iavG44azaOm4fFkM3GcbNxPDQm2wYsIZvO_VP48xT5A0CVgiw</addsrcrecordid><sourcetype>Aggregation Database</sourcetype><iscdi>true</iscdi><recordtype>article</recordtype><pqid>2063171861</pqid></control><display><type>article</type><title>Piezoresistive strain sensor array using polydimethylsiloxane-based conducting nanocomposites for electronic skin application</title><source>Emerald A-Z Current Journals</source><creator>Chong, Yung Sin ; Yeoh, Keat Hoe ; Leow, Pei Ling ; Chee, Pei Song</creator><creatorcontrib>Chong, Yung Sin ; Yeoh, Keat Hoe ; Leow, Pei Ling ; Chee, Pei Song</creatorcontrib><description>Purpose
This paper aims to report a stretchable piezoresistive strain sensor array that can detect various static and dynamic stimuli, including bending, normal force, shear stress and certain range of temperature variation, through sandwiching an array of conductive blocks, made of multiwalled carbon nanotubes (MWCNTs) and polydimethylsiloxane (PDMS) composite. The strain sensor array induces localized resistance changes at different external mechanical forces, which can be potentially implemented as electronic skin.
Design/methodology/approach
The working principle is the piezoresistivity of the strain sensor array is based on the tunnelling resistance connection between the fillers and reformation of the percolating path when the PDMS and MWCNT composite deforms. When an external compression stimulus is exerted, the MWCNT inter-filler distance at the conductive block array reduces, resulting in the reduction of the resistance. The resistance between the conductive blocks in the array, on the other hand, increases when the strain sensor is exposed to an external stretching force. The methodology was as follows: Numerical simulation has been performed to study the pressure distribution across the sensor. This method applies two thin layers of conductive elastomer composite across a 2 × 3 conductive block array, where the former is to detect the stretchable force, whereas the latter is to detect the compression force. The fabrication of the strain sensor consists of two main stages: fabricating the conducting block array (detect compression force) and depositing two thin conductive layers (detect stretchable force).
Findings
Characterizations have been performed at the sensor pressure response: static and dynamic configuration, strain sensing and temperature sensing. Both pressure and strain sensing are studied in terms of the temporal response. The temporal response shows rapid resistance changes and returns to its original value after the external load is removed. The electrical conductivity of the prototype correlates to the temperature by showing negative temperature coefficient material behaviour with the sensitivity of −0.105 MΩ/°C.
Research limitations/implications
The conductive sensor array can potentially be implemented as electronic skin due to its reaction with mechanical stimuli: compression and stretchable pressure force, strain sensing and temperature sensing.
Originality/value
This prototype enables various static and dynamic stimulus detections, including bending, normal force, shear stress and certain range of temperature variation, through sandwiching an array of conductive blocks, made of MWCNT and PDMS composite. Conventional design might need to integrate different microfeatures to perform the similar task, especially for dynamic force sensing.</description><identifier>ISSN: 0260-2288</identifier><identifier>EISSN: 1758-6828</identifier><identifier>DOI: 10.1108/SR-11-2017-0238</identifier><language>eng</language><publisher>Bradford: Emerald Publishing Limited</publisher><subject>Carbon ; Computer simulation ; Curing ; Deformation ; Design ; Detection ; Elastomers ; Electrical resistivity ; Electrodes ; Fillers ; Gallium arsenide ; Mathematical analysis ; Multi wall carbon nanotubes ; Nanocomposites ; Piezoresistivity ; Polydimethylsiloxane ; Polymers ; Pressure distribution ; Sensor arrays ; Sensors ; Shear stress ; Silicone resins ; Stimuli ; Strain ; Stress concentration ; Thin films</subject><ispartof>Sensor review, 2018-07, Vol.38 (4), p.494-500</ispartof><rights>Emerald Publishing Limited</rights><rights>Emerald Publishing Limited 2018</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c308t-319f3d2b7adb80d3779a3ae4e612fab40f4b039cb6658d1ffc2d7df7dabdf27e3</citedby><cites>FETCH-LOGICAL-c308t-319f3d2b7adb80d3779a3ae4e612fab40f4b039cb6658d1ffc2d7df7dabdf27e3</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktohtml>$$Uhttps://www.emerald.com/insight/content/doi/10.1108/SR-11-2017-0238/full/html$$EHTML$$P50$$Gemerald$$H</linktohtml><link.rule.ids>314,780,784,967,11635,27924,27925,52689</link.rule.ids></links><search><creatorcontrib>Chong, Yung Sin</creatorcontrib><creatorcontrib>Yeoh, Keat Hoe</creatorcontrib><creatorcontrib>Leow, Pei Ling</creatorcontrib><creatorcontrib>Chee, Pei Song</creatorcontrib><title>Piezoresistive strain sensor array using polydimethylsiloxane-based conducting nanocomposites for electronic skin application</title><title>Sensor review</title><description>Purpose
This paper aims to report a stretchable piezoresistive strain sensor array that can detect various static and dynamic stimuli, including bending, normal force, shear stress and certain range of temperature variation, through sandwiching an array of conductive blocks, made of multiwalled carbon nanotubes (MWCNTs) and polydimethylsiloxane (PDMS) composite. The strain sensor array induces localized resistance changes at different external mechanical forces, which can be potentially implemented as electronic skin.
Design/methodology/approach
The working principle is the piezoresistivity of the strain sensor array is based on the tunnelling resistance connection between the fillers and reformation of the percolating path when the PDMS and MWCNT composite deforms. When an external compression stimulus is exerted, the MWCNT inter-filler distance at the conductive block array reduces, resulting in the reduction of the resistance. The resistance between the conductive blocks in the array, on the other hand, increases when the strain sensor is exposed to an external stretching force. The methodology was as follows: Numerical simulation has been performed to study the pressure distribution across the sensor. This method applies two thin layers of conductive elastomer composite across a 2 × 3 conductive block array, where the former is to detect the stretchable force, whereas the latter is to detect the compression force. The fabrication of the strain sensor consists of two main stages: fabricating the conducting block array (detect compression force) and depositing two thin conductive layers (detect stretchable force).
Findings
Characterizations have been performed at the sensor pressure response: static and dynamic configuration, strain sensing and temperature sensing. Both pressure and strain sensing are studied in terms of the temporal response. The temporal response shows rapid resistance changes and returns to its original value after the external load is removed. The electrical conductivity of the prototype correlates to the temperature by showing negative temperature coefficient material behaviour with the sensitivity of −0.105 MΩ/°C.
Research limitations/implications
The conductive sensor array can potentially be implemented as electronic skin due to its reaction with mechanical stimuli: compression and stretchable pressure force, strain sensing and temperature sensing.
Originality/value
This prototype enables various static and dynamic stimulus detections, including bending, normal force, shear stress and certain range of temperature variation, through sandwiching an array of conductive blocks, made of MWCNT and PDMS composite. Conventional design might need to integrate different microfeatures to perform the similar task, especially for dynamic force sensing.</description><subject>Carbon</subject><subject>Computer simulation</subject><subject>Curing</subject><subject>Deformation</subject><subject>Design</subject><subject>Detection</subject><subject>Elastomers</subject><subject>Electrical resistivity</subject><subject>Electrodes</subject><subject>Fillers</subject><subject>Gallium arsenide</subject><subject>Mathematical analysis</subject><subject>Multi wall carbon nanotubes</subject><subject>Nanocomposites</subject><subject>Piezoresistivity</subject><subject>Polydimethylsiloxane</subject><subject>Polymers</subject><subject>Pressure distribution</subject><subject>Sensor arrays</subject><subject>Sensors</subject><subject>Shear stress</subject><subject>Silicone resins</subject><subject>Stimuli</subject><subject>Strain</subject><subject>Stress concentration</subject><subject>Thin films</subject><issn>0260-2288</issn><issn>1758-6828</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><sourceid>AFKRA</sourceid><sourceid>AZQEC</sourceid><sourceid>BENPR</sourceid><sourceid>CCPQU</sourceid><sourceid>DWQXO</sourceid><sourceid>GNUQQ</sourceid><recordid>eNptkUtLAzEUhYMoWKtrtwOuU_Ook3QpxRcIStX1kEluNDpNxtxUrOB_d0rdCK7O5jvnwncJOeZswjnTpw8LyjkVjCvKhNQ7ZMTVmaa1FnqXjJioGRVC631ygPjKGBfTWo7I932Ar5QBA5bwARWWbEKsECKmXJmczbpaYYjPVZ-6tQtLKC_rDkOXPk0E2hoEV9kU3cqWDRVNTDYt-4ShAFZ-GIEObMkpBlvh27Bt-r4L1pSQ4iHZ86ZDOPrNMXm6vHicX9Pbu6ub-fkttZLpQiWfeelEq4xrNXNSqZmRBqZQc-FNO2V-2jI5s21dn2nHvbfCKeeVM63zQoEck5Ptbp_T-wqwNK9pleNwshGsllxxXfOBOt1SNifEDL7pc1iavG44azaOm4fFkM3GcbNxPDQm2wYsIZvO_VP48xT5A0CVgiw</recordid><startdate>20180703</startdate><enddate>20180703</enddate><creator>Chong, Yung Sin</creator><creator>Yeoh, Keat Hoe</creator><creator>Leow, Pei Ling</creator><creator>Chee, Pei Song</creator><general>Emerald Publishing Limited</general><general>Emerald Group Publishing Limited</general><scope>AAYXX</scope><scope>CITATION</scope><scope>0U~</scope><scope>1-H</scope><scope>7SP</scope><scope>7TB</scope><scope>7U5</scope><scope>7WY</scope><scope>7WZ</scope><scope>7XB</scope><scope>8AO</scope><scope>8FD</scope><scope>8FE</scope><scope>8FG</scope><scope>ABJCF</scope><scope>AFKRA</scope><scope>ARAPS</scope><scope>AZQEC</scope><scope>BENPR</scope><scope>BEZIV</scope><scope>BGLVJ</scope><scope>CCPQU</scope><scope>DWQXO</scope><scope>FR3</scope><scope>F~G</scope><scope>GNUQQ</scope><scope>HCIFZ</scope><scope>K6~</scope><scope>L.-</scope><scope>L.0</scope><scope>L6V</scope><scope>L7M</scope><scope>M0C</scope><scope>M2P</scope><scope>M7S</scope><scope>P5Z</scope><scope>P62</scope><scope>PQBIZ</scope><scope>PQEST</scope><scope>PQQKQ</scope><scope>PQUKI</scope><scope>PTHSS</scope><scope>Q9U</scope><scope>S0W</scope></search><sort><creationdate>20180703</creationdate><title>Piezoresistive strain sensor array using polydimethylsiloxane-based conducting nanocomposites for electronic skin application</title><author>Chong, Yung Sin ; Yeoh, Keat Hoe ; Leow, Pei Ling ; Chee, Pei Song</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c308t-319f3d2b7adb80d3779a3ae4e612fab40f4b039cb6658d1ffc2d7df7dabdf27e3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2018</creationdate><topic>Carbon</topic><topic>Computer simulation</topic><topic>Curing</topic><topic>Deformation</topic><topic>Design</topic><topic>Detection</topic><topic>Elastomers</topic><topic>Electrical resistivity</topic><topic>Electrodes</topic><topic>Fillers</topic><topic>Gallium arsenide</topic><topic>Mathematical analysis</topic><topic>Multi wall carbon nanotubes</topic><topic>Nanocomposites</topic><topic>Piezoresistivity</topic><topic>Polydimethylsiloxane</topic><topic>Polymers</topic><topic>Pressure distribution</topic><topic>Sensor arrays</topic><topic>Sensors</topic><topic>Shear stress</topic><topic>Silicone resins</topic><topic>Stimuli</topic><topic>Strain</topic><topic>Stress concentration</topic><topic>Thin films</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Chong, Yung Sin</creatorcontrib><creatorcontrib>Yeoh, Keat Hoe</creatorcontrib><creatorcontrib>Leow, Pei Ling</creatorcontrib><creatorcontrib>Chee, Pei Song</creatorcontrib><collection>CrossRef</collection><collection>Global News & ABI/Inform Professional</collection><collection>Trade PRO</collection><collection>Electronics & Communications Abstracts</collection><collection>Mechanical & Transportation Engineering Abstracts</collection><collection>Solid State and Superconductivity Abstracts</collection><collection>Access via ABI/INFORM (ProQuest)</collection><collection>ABI/INFORM Global (PDF only)</collection><collection>ProQuest Central (purchase pre-March 2016)</collection><collection>ProQuest Pharma Collection</collection><collection>Technology Research Database</collection><collection>ProQuest SciTech Collection</collection><collection>ProQuest Technology Collection</collection><collection>Materials Science & Engineering Collection</collection><collection>ProQuest Central UK/Ireland</collection><collection>Advanced Technologies & Aerospace Collection</collection><collection>ProQuest Central Essentials</collection><collection>ProQuest Central</collection><collection>Business Premium Collection</collection><collection>Technology Collection</collection><collection>ProQuest One Community College</collection><collection>ProQuest Central Korea</collection><collection>Engineering Research Database</collection><collection>ABI/INFORM Global (Corporate)</collection><collection>ProQuest Central Student</collection><collection>SciTech Premium Collection</collection><collection>ProQuest Business Collection</collection><collection>ABI/INFORM Professional Advanced</collection><collection>ABI/INFORM Professional Standard</collection><collection>ProQuest Engineering Collection</collection><collection>Advanced Technologies Database with Aerospace</collection><collection>ABI/INFORM Global</collection><collection>Science Database</collection><collection>Engineering Database</collection><collection>Advanced Technologies & Aerospace Database</collection><collection>ProQuest Advanced Technologies & Aerospace Collection</collection><collection>ProQuest One Business</collection><collection>ProQuest One Academic Eastern Edition (DO NOT USE)</collection><collection>ProQuest One Academic</collection><collection>ProQuest One Academic UKI Edition</collection><collection>Engineering Collection</collection><collection>ProQuest Central Basic</collection><collection>DELNET Engineering & Technology Collection</collection><jtitle>Sensor review</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Chong, Yung Sin</au><au>Yeoh, Keat Hoe</au><au>Leow, Pei Ling</au><au>Chee, Pei Song</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Piezoresistive strain sensor array using polydimethylsiloxane-based conducting nanocomposites for electronic skin application</atitle><jtitle>Sensor review</jtitle><date>2018-07-03</date><risdate>2018</risdate><volume>38</volume><issue>4</issue><spage>494</spage><epage>500</epage><pages>494-500</pages><issn>0260-2288</issn><eissn>1758-6828</eissn><abstract>Purpose
This paper aims to report a stretchable piezoresistive strain sensor array that can detect various static and dynamic stimuli, including bending, normal force, shear stress and certain range of temperature variation, through sandwiching an array of conductive blocks, made of multiwalled carbon nanotubes (MWCNTs) and polydimethylsiloxane (PDMS) composite. The strain sensor array induces localized resistance changes at different external mechanical forces, which can be potentially implemented as electronic skin.
Design/methodology/approach
The working principle is the piezoresistivity of the strain sensor array is based on the tunnelling resistance connection between the fillers and reformation of the percolating path when the PDMS and MWCNT composite deforms. When an external compression stimulus is exerted, the MWCNT inter-filler distance at the conductive block array reduces, resulting in the reduction of the resistance. The resistance between the conductive blocks in the array, on the other hand, increases when the strain sensor is exposed to an external stretching force. The methodology was as follows: Numerical simulation has been performed to study the pressure distribution across the sensor. This method applies two thin layers of conductive elastomer composite across a 2 × 3 conductive block array, where the former is to detect the stretchable force, whereas the latter is to detect the compression force. The fabrication of the strain sensor consists of two main stages: fabricating the conducting block array (detect compression force) and depositing two thin conductive layers (detect stretchable force).
Findings
Characterizations have been performed at the sensor pressure response: static and dynamic configuration, strain sensing and temperature sensing. Both pressure and strain sensing are studied in terms of the temporal response. The temporal response shows rapid resistance changes and returns to its original value after the external load is removed. The electrical conductivity of the prototype correlates to the temperature by showing negative temperature coefficient material behaviour with the sensitivity of −0.105 MΩ/°C.
Research limitations/implications
The conductive sensor array can potentially be implemented as electronic skin due to its reaction with mechanical stimuli: compression and stretchable pressure force, strain sensing and temperature sensing.
Originality/value
This prototype enables various static and dynamic stimulus detections, including bending, normal force, shear stress and certain range of temperature variation, through sandwiching an array of conductive blocks, made of MWCNT and PDMS composite. Conventional design might need to integrate different microfeatures to perform the similar task, especially for dynamic force sensing.</abstract><cop>Bradford</cop><pub>Emerald Publishing Limited</pub><doi>10.1108/SR-11-2017-0238</doi><tpages>7</tpages></addata></record> |
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| source | Emerald A-Z Current Journals |
| subjects | Carbon Computer simulation Curing Deformation Design Detection Elastomers Electrical resistivity Electrodes Fillers Gallium arsenide Mathematical analysis Multi wall carbon nanotubes Nanocomposites Piezoresistivity Polydimethylsiloxane Polymers Pressure distribution Sensor arrays Sensors Shear stress Silicone resins Stimuli Strain Stress concentration Thin films |
| title | Piezoresistive strain sensor array using polydimethylsiloxane-based conducting nanocomposites for electronic skin application |
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