Source: http://www.npl.co.uk/science-technology/advanced-materials/materials-areas/functional/standards-for-piezoelectric-ceramic-materials
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Standards for Piezoelectric Ceramic Materials : National Physical Laboratory
Standards for Piezoelectric Ceramic Materials
EN 50324-1:2002 Piezoelectric properties of ceramic materials and components - Part 1: Definitions and Classifications
EN 50324-2:2002 Piezoelectric properties of ceramic materials and components - Part 2: Methods of measurement and properties - Low power
The methods of measurement described in this specification are for use with piezoelectric components produced from the ceramic materials described in EN 50324-1 "Definitions and classification". Methods of measurement for specific dielectric, piezoelectric and elastic coefficients are generally applicable to piezoelectric ceramics.
EN 50324-3:2002 Piezoelectric properties of ceramic materials and components - Part 3: Methods of measurement - High power
prEN 50ZZZ-1 (BTTF 63-2(CONV)12) Properties of multilayer actuators - Part 1: Terms and definitions
Multilayer actuators can be manufactured in a wide variety of sizes. The most common shape is the rectangular bar. Ring multilayer actuators exist also. The measurements under prestress apply to the stack actuators. This standard relates to "d33 actuators, which elongate in the direction of poling" and is limited to the static and quasistatic applications.
prEN 50ZZZ-2 (BTTF 63-2(CONV)12) Properties of multilayer actuators - Part 2: Methods of measurement
Multilayer actuators can be manufactured in a wide variety of sizes. The most common shape is the rectangular bar. Ring multilayer actuators exist also. The measurements under prestress apply to the stack actuators. This standard relates to "d33 actuators", which elongate in the direction of poling" and is limited to the static and quasistatic applications.
IEC 60642 (1979-01) Piezoelectric ceramic resonators and resonator units for frequency control and selection - Chapter I: Standard values and conditions - Chapter II: Measuring and test conditions
IEC 60642-2 (1994-02) Piezoelectric ceramic resonator units - Part 2: Guide to the use of piezoelectric ceramic resonator units
IEC 60642-3 (1992-03) Piezoelectric ceramic resonators - Part 3: Standard outlines
IEC 61253-1 (1993-12) Piezoelectric ceramic resonators - A specification in the IEC quality assessment system for electronic components (IECQ) - Part 1: Generic specification - Qualification approval
IEC 61253-2 (1993-12) Piezoelectric ceramic resonators - A Specification in the IEC quality assessment system for electronic components (IECQ) - Part 2: Sectional specification - Qualification approval
IEC 61253-2-1 (1993-12) Piezoelectric ceramic resonators - A specification in the IEC quality assessment system for electronic components (IECQ) - Part 2: Sectional specification - Qualification approval - Section 1: Blank detail specification - Assessment level E
IEC 61261-1 (1994-03) Piezoelectric ceramic filters for use in electronic equipment - A specification in the IEC quality assessment system for electronic components (IECQ) - Part 1: Generic specification - Qualification approval
IEC 61261-2 (1994-03) Piezoelectric ceramic filters for use in electronic equipment - A specification in the IEC quality assessment system for electronic components (IECQ) - Part 2: Sectional specification - Qualification approval
IEC 61261-2-1 (1994-03) Piezoelectric ceramic filters for use in electronic equipment - A specification in the IEC quality assessment system for electronic components (IECQ) - Part 2: Sectional specification - Qualification approval - Section 1: Blank detail specification - Assessment level E
IEC 61994-4-2 TS Ed. 1.0 B 1CD Piezoelectric and dielectric devices for frequency control and selection - Glossary - Part 4-2: Piezoelectric materials - Piezoelectric ceramics
IEC 60747-14-1 (2000-10) Semiconductor devices - Part 14-1: Semiconductor sensors - General and classification
176-1987 IEEE Standard on Piezoelectricity [Description]
Standards on Characterization of Losses in Electromechanical Materials coordinated by Dr Stewart Sherrit (JPL). The aim is to develop new ways of analysing loss through use of complex impedance and to write new IEEE standard based on the analysis. Details of this can be found at the UTMR website.
This is a definition of terms for ferroelctrics and is being developed by Susan Trolier-McKinstry. A draft of this standard has recently been published in the IEEE-UFFC journal, Volume: 50, Issue: 12, Year: Dec. 2003.
MIL-STD 1376B (SH) Piezoelectric Ceramic Material and Measurements - Guidelines for Sonar Transducers
There is also some standards development going on at the UTMR although it is not clear what form these standards will eventually be published as.
This is coordinated by Dr Lynn Ewart-Paine (NUWC) on behalf of Dr Wallace Smith - ONR and is aimed at producing a protocol for the calculation of the dielectric constant and piezoelectric coefficients for piezoelectric single crystals.
A new VAMAS project - An International Intercomparison of Direct Piezoelectric Coefficient using the Berlincourt Method, has just started. The objective is to determine the experimental variability in the measurement of the piezoelectric coefficient of electroceramic materials via the standard method described as the Berlincourt Method. See the TWA 24 home page for more details.
The VAMAS TWA-24 home page is hosted at NPL.
The International Organization for Standardization (ISO) is a worldwide federation of national standards bodies from some 140 countries, one from each country. ISO is a non-governmental organization established in 1947. The mission of ISO is to promote the development of standardization and related activities in the world with a view to facilitating the international exchange of goods and services, and to developing cooperation in the spheres of intellectual, scientific, technological and economic activity. ISO's work results in international agreements which are published as International Standards.
ASTM D 150-98 'Standard test methods for AC loss characteristics and permittivity (Dielectric Constant) of solid electrical insulation'.
ASTM D149-97a 'Standard Test Method for Dielectric Breakdown Voltage and Dielectric Strength of Solid Electrical Insulating Materials at Commercial Power Frequencies'
Note: The information in this document is based on information available to the author through the Web and other sources. If there are any errors or omissions that you think should be included, please inform the author.