BS ISO 16063-34:2019
Methods for the calibration of vibration and shock transducers Testing of sensitivity at fixed temperatures
| Standard number: | BS ISO 16063-34:2019 |
| Pages: | 24 |
| Released: | 2020-04-09 |
| ISBN: | 978 0 539 00756 5 |
| Status: | Standard |
BS ISO 16063-34:2019 - Methods for the Calibration of Vibration and Shock Transducers
Discover the essential standard for ensuring the accuracy and reliability of vibration and shock transducers with the BS ISO 16063-34:2019. This comprehensive document provides detailed methodologies for testing the sensitivity of these transducers at fixed temperatures, ensuring that your equipment performs optimally under specified conditions.
Overview
The BS ISO 16063-34:2019 is a crucial standard for professionals in industries where precise measurement of vibration and shock is critical. Released on April 9, 2020, this standard is the latest in the series, reflecting the most up-to-date practices and technologies in the field. With 24 pages of in-depth information, it serves as an authoritative guide for calibration processes.
Key Features
- Standard Number: BS ISO 16063-34:2019
- Pages: 24
- Release Date: April 9, 2020
- ISBN: 978 0 539 00756 5
- Status: Standard
Why Choose BS ISO 16063-34:2019?
In the realm of precision engineering and testing, the accuracy of your measurements can significantly impact the quality and safety of your products. The BS ISO 16063-34:2019 standard provides a robust framework for calibrating vibration and shock transducers, ensuring that they deliver reliable and consistent results. By adhering to this standard, you can enhance the credibility of your testing processes and maintain compliance with international best practices.
Comprehensive Calibration Methods
This standard outlines a variety of methods for calibrating transducers, focusing on testing their sensitivity at fixed temperatures. This is particularly important for applications where temperature variations can affect measurement accuracy. By following the guidelines set out in this document, you can ensure that your transducers are calibrated to perform accurately across a range of environmental conditions.
Industry Applications
The methodologies detailed in the BS ISO 16063-34:2019 are applicable across a wide range of industries, including automotive, aerospace, manufacturing, and any other sector where vibration and shock measurements are critical. Whether you are involved in product development, quality assurance, or research, this standard provides the tools you need to achieve precise and reliable measurements.
Benefits of Compliance
Adhering to the BS ISO 16063-34:2019 standard offers numerous benefits, including:
- Enhanced Measurement Accuracy: Ensure that your transducers provide precise readings, reducing the risk of errors in your data.
- Improved Product Quality: Accurate measurements contribute to higher quality products, enhancing customer satisfaction and reducing the likelihood of costly recalls.
- Regulatory Compliance: Meet industry regulations and standards, avoiding potential legal and financial penalties.
- Competitive Advantage: Demonstrate your commitment to quality and precision, setting your business apart from competitors.
Conclusion
The BS ISO 16063-34:2019 is an indispensable resource for any organization that relies on accurate vibration and shock measurements. By implementing the methods outlined in this standard, you can ensure that your transducers are calibrated to the highest standards, providing reliable data that supports your business objectives. Invest in this standard to enhance your measurement capabilities and maintain your position as a leader in your industry.
BS ISO 16063-34:2019
This standard BS ISO 16063-34:2019 Methods for the calibration of vibration and shock transducers is classified in these ICS categories:
- 17.160 Vibrations, shock and vibration measurements
This document details specifications for the instrumentation and methods to be used for testing fixed temperature sensitivity of vibration transducers. It applies to rectilinear velocity and acceleration transducers.
The methods specified use both a comparison to a reference transducer and an absolute measurement by laser interferometer.
This document is applicable for a frequency range from 10 Hz to 3 kHz (method-dependent), a dynamic range from 1 m/s2 to 100 m/s2 (frequency-dependent) and a temperature range from –1 90 °C to 800 °C (method-dependent). Although it is possible to achieve these ranges among all the described systems, generally each has limitations within them.
Method 1 (using a laser interferometer) is applicable to magnitude of sensitivity and phase calibration in the frequency range 10 Hz to 3 kHz at fixed temperatures (see Clause 7). Method 2 (using a reference transducer inside a chamber whose temperature limit is –70 °C to 500 °C) can be used for magnitude of sensitivity and phase calibration in the frequency range 10 Hz to 1 kHz at fixed temperatures (see Clause 8). Method 3 (using a reference transducer outside the chamber) can only be used for the determination of the temperature response of complex sensitivity over a certain temperature range (see Clause 9).
Method 1 and Method 2 can provide the deviation of complex sensitivity over a certain temperature range if the calibration is also done at the reference temperature (room temperature 23 °C ± 5 °C).
To ensure the consistency of the use and test condition, the transducer, its cable and the conditioning amplifier are intended to be considered as a single unit and tested together.