Review of magnetostrictive transducers (MsT) utilizing reversed Wiedemann effect
Magnetostrictive transduction has been widely utilized in NDE applications, specifically for generation and reception of guided waves for long-range inspection of components such as pipes, vessels, and small tubes. Transverse-motion guided wave modes (e.g., torsional vibrations in pipes) are the mos...
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| description | Magnetostrictive transduction has been widely utilized in NDE applications, specifically for generation and reception of guided waves for long-range inspection of components such as pipes, vessels, and small tubes. Transverse-motion guided wave modes (e.g., torsional vibrations in pipes) are the most typical choice for long-range inspection applications because the wave motion is in the plane of the structure. Magnetostrictive-based sensors have been available for several years for these wave modes based on the Wiedemann effect. For these sensors, a permanent magnetic bias is applied that is perpendicular to the direction of the propagated guided wave. This bias field strains the material that the guided wave is generated in preferentially in the desired particle motion direction. A time-varying magnetic field oriented parallel to the direction of guided wave propagation is also induced in the material. This time-varying field is induced using an electric coil located near the material surface. The interaction of these two fields produces the guided waves; an inverse effect is used for the receive process. An alternative configuration of a sensor for generating and receiving these traverse-motion guided waves is to swap the biasing and time-varying magnetic fields directions. Since transverse-motion guided wave sensors are typically much longer in the particle motion direction than in the bias field direction, the net effect of this alternative design is that the magnetic biasing length is shorter and different coil designs can be used. Because of this, the alternative design, known as a magnetostrictive transducer (MsT), exhibits a number of unique features compared to the Wiedemann sensor described above, such as: 1) the ability to use smaller rare earth permanent magnets and achieve uniform and self-sustained bias field strengths, 2) the choice of more efficient electric coil arrangements to induce a stronger time-varying magnetic field for a given coil impedance, 3) more easily exhibit nonlinear operating characteristics given the efficiency improvements in both magnetic fields, and 4) the ability to generate unidirectional guided waves when the field arrangement is combined with a magnetically soft ferromagnetic strip (patch). MsT designs will be presented that are suitable for different inspection applications, one using electromagnetic generation and reception directly in a ferromagnetic material and another design that integrates a magnetostrictive |
| doi_str_mv | 10.1063/1.4974549 |
| format | Conference Proceeding |
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Transverse-motion guided wave modes (e.g., torsional vibrations in pipes) are the most typical choice for long-range inspection applications because the wave motion is in the plane of the structure. Magnetostrictive-based sensors have been available for several years for these wave modes based on the Wiedemann effect. For these sensors, a permanent magnetic bias is applied that is perpendicular to the direction of the propagated guided wave. This bias field strains the material that the guided wave is generated in preferentially in the desired particle motion direction. A time-varying magnetic field oriented parallel to the direction of guided wave propagation is also induced in the material. This time-varying field is induced using an electric coil located near the material surface. The interaction of these two fields produces the guided waves; an inverse effect is used for the receive process. An alternative configuration of a sensor for generating and receiving these traverse-motion guided waves is to swap the biasing and time-varying magnetic fields directions. Since transverse-motion guided wave sensors are typically much longer in the particle motion direction than in the bias field direction, the net effect of this alternative design is that the magnetic biasing length is shorter and different coil designs can be used. Because of this, the alternative design, known as a magnetostrictive transducer (MsT), exhibits a number of unique features compared to the Wiedemann sensor described above, such as: 1) the ability to use smaller rare earth permanent magnets and achieve uniform and self-sustained bias field strengths, 2) the choice of more efficient electric coil arrangements to induce a stronger time-varying magnetic field for a given coil impedance, 3) more easily exhibit nonlinear operating characteristics given the efficiency improvements in both magnetic fields, and 4) the ability to generate unidirectional guided waves when the field arrangement is combined with a magnetically soft ferromagnetic strip (patch). MsT designs will be presented that are suitable for different inspection applications, one using electromagnetic generation and reception directly in a ferromagnetic material and another design that integrates a magnetostrictive patch to improve the efficiency and allow special operating characteristics.</description><identifier>ISSN: 0094-243X</identifier><identifier>EISSN: 1551-7616</identifier><identifier>DOI: 10.1063/1.4974549</identifier><identifier>CODEN: APCPCS</identifier><language>eng</language><publisher>Melville: American Institute of Physics</publisher><subject>Bias ; Coils (strip) ; Ferromagnetic materials ; Inspection ; Magnetic fields ; Magnetostriction ; Nondestructive testing ; Particle motion ; Permanent magnets ; Pipes ; Rare earth elements ; Sensors ; Transducers ; Tubes ; Wave propagation ; Waves</subject><ispartof>AIP conference proceedings, 2017, Vol.1806 (1)</ispartof><rights>Author(s)</rights><rights>2017 Author(s). Published by AIP Publishing.</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c328t-ecebe5a0bc7398aee4b769f7614b5d2f62e905870413655c40a1db35c43f62773</citedby></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktohtml>$$Uhttps://pubs.aip.org/acp/article-lookup/doi/10.1063/1.4974549$$EHTML$$P50$$Gscitation$$H</linktohtml><link.rule.ids>309,310,314,780,784,789,790,794,4510,23929,23930,25139,27923,27924,76155</link.rule.ids></links><search><contributor>Chimenti, Dale E.</contributor><contributor>Bond, Leonard J.</contributor><creatorcontrib>Vinogradov, Sergey</creatorcontrib><creatorcontrib>Cobb, Adam</creatorcontrib><creatorcontrib>Light, Glenn</creatorcontrib><title>Review of magnetostrictive transducers (MsT) utilizing reversed Wiedemann effect</title><title>AIP conference proceedings</title><description>Magnetostrictive transduction has been widely utilized in NDE applications, specifically for generation and reception of guided waves for long-range inspection of components such as pipes, vessels, and small tubes. Transverse-motion guided wave modes (e.g., torsional vibrations in pipes) are the most typical choice for long-range inspection applications because the wave motion is in the plane of the structure. Magnetostrictive-based sensors have been available for several years for these wave modes based on the Wiedemann effect. For these sensors, a permanent magnetic bias is applied that is perpendicular to the direction of the propagated guided wave. This bias field strains the material that the guided wave is generated in preferentially in the desired particle motion direction. A time-varying magnetic field oriented parallel to the direction of guided wave propagation is also induced in the material. This time-varying field is induced using an electric coil located near the material surface. The interaction of these two fields produces the guided waves; an inverse effect is used for the receive process. An alternative configuration of a sensor for generating and receiving these traverse-motion guided waves is to swap the biasing and time-varying magnetic fields directions. Since transverse-motion guided wave sensors are typically much longer in the particle motion direction than in the bias field direction, the net effect of this alternative design is that the magnetic biasing length is shorter and different coil designs can be used. Because of this, the alternative design, known as a magnetostrictive transducer (MsT), exhibits a number of unique features compared to the Wiedemann sensor described above, such as: 1) the ability to use smaller rare earth permanent magnets and achieve uniform and self-sustained bias field strengths, 2) the choice of more efficient electric coil arrangements to induce a stronger time-varying magnetic field for a given coil impedance, 3) more easily exhibit nonlinear operating characteristics given the efficiency improvements in both magnetic fields, and 4) the ability to generate unidirectional guided waves when the field arrangement is combined with a magnetically soft ferromagnetic strip (patch). MsT designs will be presented that are suitable for different inspection applications, one using electromagnetic generation and reception directly in a ferromagnetic material and another design that integrates a magnetostrictive patch to improve the efficiency and allow special operating characteristics.</description><subject>Bias</subject><subject>Coils (strip)</subject><subject>Ferromagnetic materials</subject><subject>Inspection</subject><subject>Magnetic fields</subject><subject>Magnetostriction</subject><subject>Nondestructive testing</subject><subject>Particle motion</subject><subject>Permanent magnets</subject><subject>Pipes</subject><subject>Rare earth elements</subject><subject>Sensors</subject><subject>Transducers</subject><subject>Tubes</subject><subject>Wave propagation</subject><subject>Waves</subject><issn>0094-243X</issn><issn>1551-7616</issn><fulltext>true</fulltext><rsrctype>conference_proceeding</rsrctype><creationdate>2017</creationdate><recordtype>conference_proceeding</recordtype><recordid>eNp9kE1LAzEQhoMoWKsH_0HAiwpb87nZPUrxCyqKVPQWstlJSWl3a5Jd0V_vSgvePM0w87zzDi9Cp5RMKMn5FZ2IUgkpyj00olLSTOU030cjQkqRMcHfD9FRjEtCWKlUMULPL9B7-MStw2uzaCC1MQVvk-8Bp2CaWHcWQsTnj3F-gbvkV_7bNwscoB_GUOM3DzWsTdNgcA5sOkYHzqwinOzqGL3e3syn99ns6e5hej3LLGdFysBCBdKQyipeFgZAVCov3fCtqGTNXM6gJLJQRFCeS2kFMbSu-NDwYacUH6Oz7d1NaD86iEkv2y40g6VmlAkpiWR8oC63VLQ-meTbRm-CX5vwpfs2aKp3aelN7f6DKdG_8f4J-A_kXmxq</recordid><startdate>20170216</startdate><enddate>20170216</enddate><creator>Vinogradov, Sergey</creator><creator>Cobb, Adam</creator><creator>Light, Glenn</creator><general>American Institute of Physics</general><scope>8FD</scope><scope>H8D</scope><scope>L7M</scope></search><sort><creationdate>20170216</creationdate><title>Review of magnetostrictive transducers (MsT) utilizing reversed Wiedemann effect</title><author>Vinogradov, Sergey ; Cobb, Adam ; Light, Glenn</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c328t-ecebe5a0bc7398aee4b769f7614b5d2f62e905870413655c40a1db35c43f62773</frbrgroupid><rsrctype>conference_proceedings</rsrctype><prefilter>conference_proceedings</prefilter><language>eng</language><creationdate>2017</creationdate><topic>Bias</topic><topic>Coils (strip)</topic><topic>Ferromagnetic materials</topic><topic>Inspection</topic><topic>Magnetic fields</topic><topic>Magnetostriction</topic><topic>Nondestructive testing</topic><topic>Particle motion</topic><topic>Permanent magnets</topic><topic>Pipes</topic><topic>Rare earth elements</topic><topic>Sensors</topic><topic>Transducers</topic><topic>Tubes</topic><topic>Wave propagation</topic><topic>Waves</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Vinogradov, Sergey</creatorcontrib><creatorcontrib>Cobb, Adam</creatorcontrib><creatorcontrib>Light, Glenn</creatorcontrib><collection>Technology Research Database</collection><collection>Aerospace Database</collection><collection>Advanced Technologies Database with Aerospace</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Vinogradov, Sergey</au><au>Cobb, Adam</au><au>Light, Glenn</au><au>Chimenti, Dale E.</au><au>Bond, Leonard J.</au><format>book</format><genre>proceeding</genre><ristype>CONF</ristype><atitle>Review of magnetostrictive transducers (MsT) utilizing reversed Wiedemann effect</atitle><btitle>AIP conference proceedings</btitle><date>2017-02-16</date><risdate>2017</risdate><volume>1806</volume><issue>1</issue><issn>0094-243X</issn><eissn>1551-7616</eissn><coden>APCPCS</coden><abstract>Magnetostrictive transduction has been widely utilized in NDE applications, specifically for generation and reception of guided waves for long-range inspection of components such as pipes, vessels, and small tubes. Transverse-motion guided wave modes (e.g., torsional vibrations in pipes) are the most typical choice for long-range inspection applications because the wave motion is in the plane of the structure. Magnetostrictive-based sensors have been available for several years for these wave modes based on the Wiedemann effect. For these sensors, a permanent magnetic bias is applied that is perpendicular to the direction of the propagated guided wave. This bias field strains the material that the guided wave is generated in preferentially in the desired particle motion direction. A time-varying magnetic field oriented parallel to the direction of guided wave propagation is also induced in the material. This time-varying field is induced using an electric coil located near the material surface. The interaction of these two fields produces the guided waves; an inverse effect is used for the receive process. An alternative configuration of a sensor for generating and receiving these traverse-motion guided waves is to swap the biasing and time-varying magnetic fields directions. Since transverse-motion guided wave sensors are typically much longer in the particle motion direction than in the bias field direction, the net effect of this alternative design is that the magnetic biasing length is shorter and different coil designs can be used. Because of this, the alternative design, known as a magnetostrictive transducer (MsT), exhibits a number of unique features compared to the Wiedemann sensor described above, such as: 1) the ability to use smaller rare earth permanent magnets and achieve uniform and self-sustained bias field strengths, 2) the choice of more efficient electric coil arrangements to induce a stronger time-varying magnetic field for a given coil impedance, 3) more easily exhibit nonlinear operating characteristics given the efficiency improvements in both magnetic fields, and 4) the ability to generate unidirectional guided waves when the field arrangement is combined with a magnetically soft ferromagnetic strip (patch). MsT designs will be presented that are suitable for different inspection applications, one using electromagnetic generation and reception directly in a ferromagnetic material and another design that integrates a magnetostrictive patch to improve the efficiency and allow special operating characteristics.</abstract><cop>Melville</cop><pub>American Institute of Physics</pub><doi>10.1063/1.4974549</doi><tpages>9</tpages><oa>free_for_read</oa></addata></record> |
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| subjects | Bias Coils (strip) Ferromagnetic materials Inspection Magnetic fields Magnetostriction Nondestructive testing Particle motion Permanent magnets Pipes Rare earth elements Sensors Transducers Tubes Wave propagation Waves |
| title | Review of magnetostrictive transducers (MsT) utilizing reversed Wiedemann effect |
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