Parameter identification of piezoelectric bimorphs for dynamic applications considering strain and velocity dependent effects

Research output: Chapter in book/report/conference proceedingConference contributionResearchpeer review

Authors

  • Björn Richter
  • Jens Twiefel

Research Organisations

External Research Organisations

  • Paderborn University
View graph of relations

Details

Original languageEnglish
Title of host publicationActive and Passive Smart Structures and Integrated Systems 2009
Publication statusPublished - 6 Apr 2009
EventActive and Passive Smart Structures and Integrated Systems 2009 - San Diego, CA, United States
Duration: 9 Mar 200912 Mar 2009

Publication series

NameProceedings of SPIE - The International Society for Optical Engineering
Volume7288
ISSN (Print)0277-786X

Abstract

Piezoelectric bimorph elements are commonly used in a wide area of applications, among them various actuator applications in textile machines, applications in sensing like medical tissue identification, or the use in energy harvesting systems. Especially the last field may create a mass market for piezoelectric elements. Due to their easy use and low resonance frequency, bimorphs seem to fit energy harvesting demands quite well. To get the best possible power output, the element has to be designed as good as possible to fit the environmental excitation characteristics as excitation frequency and amplitude. Due to the need of a good understanding of the resulting system, a model based approach is desirable for the design of the used bimorphs. This is the case not only in Energy Harvesting systems but in most of the mentioned applications. A typical modeling technique is the utilization of modal models using electro-mechanical analogies. The needed parameters can either be identified by measurements of the piezoelectric system or they can be calculated using a dynamic mechanical model. This kind of modeling is well known for a good approximation of the behavior of piezoelectric transducers - as long as they are driven in the linear range. Unlike most Langevin transducers, piezoelectric bimorph elements show a smaller range of linearity in experimental investigations. Obviously, the bimorph elements have a big shift of resonance frequency and a considerable increase of damping with increasing excitation. The change in frequency and damping leads to complications in system design. It is hypothesized that the nonlinear behavior mainly depends on the strain level of the bending element. Considering that strain is proportional to the velocity amplitude of the free end of the bimorph around the first mode, measurements with constant strain levels are performed. Experiments verify the relationship between the appearing nonlinearities and strain as well as velocity of the bending element. Furthermore, measurement results of electrical excited bimorphs with different constant strain levels are used to identify parameter sets. Gained data allows the phenomenological definition of the behavior of the modal model parameters according to excitation levels. This enables the derivation of strain dependent parameter sets for specific materials. The measurement data is also used to enhance the well known lumped parameter model for piezoelectric systems to handle the nonlinear behavior using the strain dependent parameter sets. The enhancement of the model allows the correct description and simulation of piezoelectric bending elements like bimorphs for different mechanic as well as electric excitation levels. This leads to a suitable design procedure to reduce development efforts.

Keywords

    Bimorph actuator, Energy harvesting, Equivalent circuit models, Modeling, Non-linear modeling, Piezoelectric material

ASJC Scopus subject areas

Cite this

Parameter identification of piezoelectric bimorphs for dynamic applications considering strain and velocity dependent effects. / Richter, Björn; Twiefel, Jens.
Active and Passive Smart Structures and Integrated Systems 2009. 2009. 72881K (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 7288).

Research output: Chapter in book/report/conference proceedingConference contributionResearchpeer review

Richter, B & Twiefel, J 2009, Parameter identification of piezoelectric bimorphs for dynamic applications considering strain and velocity dependent effects. in Active and Passive Smart Structures and Integrated Systems 2009., 72881K, Proceedings of SPIE - The International Society for Optical Engineering, vol. 7288, Active and Passive Smart Structures and Integrated Systems 2009, San Diego, CA, United States, 9 Mar 2009. https://doi.org/10.1117/12.815967
Richter, B., & Twiefel, J. (2009). Parameter identification of piezoelectric bimorphs for dynamic applications considering strain and velocity dependent effects. In Active and Passive Smart Structures and Integrated Systems 2009 Article 72881K (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 7288). https://doi.org/10.1117/12.815967
Richter B, Twiefel J. Parameter identification of piezoelectric bimorphs for dynamic applications considering strain and velocity dependent effects. In Active and Passive Smart Structures and Integrated Systems 2009. 2009. 72881K. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.815967
Richter, Björn ; Twiefel, Jens. / Parameter identification of piezoelectric bimorphs for dynamic applications considering strain and velocity dependent effects. Active and Passive Smart Structures and Integrated Systems 2009. 2009. (Proceedings of SPIE - The International Society for Optical Engineering).
Download
@inproceedings{ad0db98daf8d4de69b7c106a7f162c41,
title = "Parameter identification of piezoelectric bimorphs for dynamic applications considering strain and velocity dependent effects",
abstract = "Piezoelectric bimorph elements are commonly used in a wide area of applications, among them various actuator applications in textile machines, applications in sensing like medical tissue identification, or the use in energy harvesting systems. Especially the last field may create a mass market for piezoelectric elements. Due to their easy use and low resonance frequency, bimorphs seem to fit energy harvesting demands quite well. To get the best possible power output, the element has to be designed as good as possible to fit the environmental excitation characteristics as excitation frequency and amplitude. Due to the need of a good understanding of the resulting system, a model based approach is desirable for the design of the used bimorphs. This is the case not only in Energy Harvesting systems but in most of the mentioned applications. A typical modeling technique is the utilization of modal models using electro-mechanical analogies. The needed parameters can either be identified by measurements of the piezoelectric system or they can be calculated using a dynamic mechanical model. This kind of modeling is well known for a good approximation of the behavior of piezoelectric transducers - as long as they are driven in the linear range. Unlike most Langevin transducers, piezoelectric bimorph elements show a smaller range of linearity in experimental investigations. Obviously, the bimorph elements have a big shift of resonance frequency and a considerable increase of damping with increasing excitation. The change in frequency and damping leads to complications in system design. It is hypothesized that the nonlinear behavior mainly depends on the strain level of the bending element. Considering that strain is proportional to the velocity amplitude of the free end of the bimorph around the first mode, measurements with constant strain levels are performed. Experiments verify the relationship between the appearing nonlinearities and strain as well as velocity of the bending element. Furthermore, measurement results of electrical excited bimorphs with different constant strain levels are used to identify parameter sets. Gained data allows the phenomenological definition of the behavior of the modal model parameters according to excitation levels. This enables the derivation of strain dependent parameter sets for specific materials. The measurement data is also used to enhance the well known lumped parameter model for piezoelectric systems to handle the nonlinear behavior using the strain dependent parameter sets. The enhancement of the model allows the correct description and simulation of piezoelectric bending elements like bimorphs for different mechanic as well as electric excitation levels. This leads to a suitable design procedure to reduce development efforts.",
keywords = "Bimorph actuator, Energy harvesting, Equivalent circuit models, Modeling, Non-linear modeling, Piezoelectric material",
author = "Bj{\"o}rn Richter and Jens Twiefel",
year = "2009",
month = apr,
day = "6",
doi = "10.1117/12.815967",
language = "English",
isbn = "9780819475480",
series = "Proceedings of SPIE - The International Society for Optical Engineering",
booktitle = "Active and Passive Smart Structures and Integrated Systems 2009",
note = "Active and Passive Smart Structures and Integrated Systems 2009 ; Conference date: 09-03-2009 Through 12-03-2009",

}

Download

TY - GEN

T1 - Parameter identification of piezoelectric bimorphs for dynamic applications considering strain and velocity dependent effects

AU - Richter, Björn

AU - Twiefel, Jens

PY - 2009/4/6

Y1 - 2009/4/6

N2 - Piezoelectric bimorph elements are commonly used in a wide area of applications, among them various actuator applications in textile machines, applications in sensing like medical tissue identification, or the use in energy harvesting systems. Especially the last field may create a mass market for piezoelectric elements. Due to their easy use and low resonance frequency, bimorphs seem to fit energy harvesting demands quite well. To get the best possible power output, the element has to be designed as good as possible to fit the environmental excitation characteristics as excitation frequency and amplitude. Due to the need of a good understanding of the resulting system, a model based approach is desirable for the design of the used bimorphs. This is the case not only in Energy Harvesting systems but in most of the mentioned applications. A typical modeling technique is the utilization of modal models using electro-mechanical analogies. The needed parameters can either be identified by measurements of the piezoelectric system or they can be calculated using a dynamic mechanical model. This kind of modeling is well known for a good approximation of the behavior of piezoelectric transducers - as long as they are driven in the linear range. Unlike most Langevin transducers, piezoelectric bimorph elements show a smaller range of linearity in experimental investigations. Obviously, the bimorph elements have a big shift of resonance frequency and a considerable increase of damping with increasing excitation. The change in frequency and damping leads to complications in system design. It is hypothesized that the nonlinear behavior mainly depends on the strain level of the bending element. Considering that strain is proportional to the velocity amplitude of the free end of the bimorph around the first mode, measurements with constant strain levels are performed. Experiments verify the relationship between the appearing nonlinearities and strain as well as velocity of the bending element. Furthermore, measurement results of electrical excited bimorphs with different constant strain levels are used to identify parameter sets. Gained data allows the phenomenological definition of the behavior of the modal model parameters according to excitation levels. This enables the derivation of strain dependent parameter sets for specific materials. The measurement data is also used to enhance the well known lumped parameter model for piezoelectric systems to handle the nonlinear behavior using the strain dependent parameter sets. The enhancement of the model allows the correct description and simulation of piezoelectric bending elements like bimorphs for different mechanic as well as electric excitation levels. This leads to a suitable design procedure to reduce development efforts.

AB - Piezoelectric bimorph elements are commonly used in a wide area of applications, among them various actuator applications in textile machines, applications in sensing like medical tissue identification, or the use in energy harvesting systems. Especially the last field may create a mass market for piezoelectric elements. Due to their easy use and low resonance frequency, bimorphs seem to fit energy harvesting demands quite well. To get the best possible power output, the element has to be designed as good as possible to fit the environmental excitation characteristics as excitation frequency and amplitude. Due to the need of a good understanding of the resulting system, a model based approach is desirable for the design of the used bimorphs. This is the case not only in Energy Harvesting systems but in most of the mentioned applications. A typical modeling technique is the utilization of modal models using electro-mechanical analogies. The needed parameters can either be identified by measurements of the piezoelectric system or they can be calculated using a dynamic mechanical model. This kind of modeling is well known for a good approximation of the behavior of piezoelectric transducers - as long as they are driven in the linear range. Unlike most Langevin transducers, piezoelectric bimorph elements show a smaller range of linearity in experimental investigations. Obviously, the bimorph elements have a big shift of resonance frequency and a considerable increase of damping with increasing excitation. The change in frequency and damping leads to complications in system design. It is hypothesized that the nonlinear behavior mainly depends on the strain level of the bending element. Considering that strain is proportional to the velocity amplitude of the free end of the bimorph around the first mode, measurements with constant strain levels are performed. Experiments verify the relationship between the appearing nonlinearities and strain as well as velocity of the bending element. Furthermore, measurement results of electrical excited bimorphs with different constant strain levels are used to identify parameter sets. Gained data allows the phenomenological definition of the behavior of the modal model parameters according to excitation levels. This enables the derivation of strain dependent parameter sets for specific materials. The measurement data is also used to enhance the well known lumped parameter model for piezoelectric systems to handle the nonlinear behavior using the strain dependent parameter sets. The enhancement of the model allows the correct description and simulation of piezoelectric bending elements like bimorphs for different mechanic as well as electric excitation levels. This leads to a suitable design procedure to reduce development efforts.

KW - Bimorph actuator

KW - Energy harvesting

KW - Equivalent circuit models

KW - Modeling

KW - Non-linear modeling

KW - Piezoelectric material

UR - http://www.scopus.com/inward/record.url?scp=69549096262&partnerID=8YFLogxK

U2 - 10.1117/12.815967

DO - 10.1117/12.815967

M3 - Conference contribution

AN - SCOPUS:69549096262

SN - 9780819475480

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Active and Passive Smart Structures and Integrated Systems 2009

T2 - Active and Passive Smart Structures and Integrated Systems 2009

Y2 - 9 March 2009 through 12 March 2009

ER -