Subcommittee | Subcommittee Title | Published standards | Standards under development |
---|---|---|---|
ISO/TC 108/SC 2 | Measurement and evaluation of mechanical vibration and shock as applied to machines, vehicles and structures | 53 | 11 |
ISO/TC 108/SC 4 | Human exposure to mechanical vibration and shock | 32 | 10 |
ISO/TC 108/SC 5 | Condition monitoring and diagnostics of machine systems | 25 | 5 |
ISO/TC 108/SC 6 | Vibration and shock generating systems | 12 | 2 |
- Iso Vibration Severity Standards
- Iso Vibration Standards 10816
- Iso Vibration Standards Chart
- Iso Vibration Standards
- Filter:
2) Sohre-Erskine R/C Standards (shaft vibration, fluid film bearings) 3) ISO 7919 (shaft vibration, fluid film bearings) 4) OEM Specifications PROS: a) Can be applied to plant equipment from the beginning of a condition monitoring program. No prior machine history is necessary to make a basic assessment of a machine’s condition. Vibration Monitoring Non Rotating Machines VM - Vibration Monitoring (ISO 10816) - is it evidently shaking itself - monitor by operator or transducer. Vibration Monitoring has its roots in maintenance engineers inspecting machines during their traditional walk around. Human response to vibration — Guidance and terminology for instrumentation and equipment for the assessment of daily vibration exposure at the workplace according to the requirements of health and safety.
Standard and/or project under the direct responsibility of ISO/TC 108 Secretariat | Stage | ICS |
---|---|---|
Balancing — Vocabulary | 95.99 | |
Mechanical vibration — Balancing — Vocabulary | 95.99 | |
Mechanical vibration — Balancing — Vocabulary — Amendment 1 | 95.99 | |
Mechanical vibration — Balance quality requirements of rigid rotors — Part 1: Determination of permissible residual unbalance | 95.99 | |
Balance quality of rotating rigid bodies | 95.99 | |
Mechanical vibration and shock — Resilient mounting systems — Part 1: Technical information to be exchanged for the application of isolation systems | 90.93 | |
Mechanical vibration and shock — Resilient mounting systems — Part 2: Technical information to be exchanged for the application of vibration isolation associated with railway systems | 90.93 | |
Mechanical vibration and shock — Resilient mounting systems — Part 3: Technical information to be exchanged for application of vibration isolation to new buildings | 60.60 | |
Vibration and shock — Isolators — Procedure for specifying characteristics | 95.99 | |
Vibration and shock — Vocabulary | 95.99 | |
Vibration and shock — Vocabulary | 95.99 | |
Mechanical vibration, shock and condition monitoring — Vocabulary | 95.99 | |
Mechanical vibration, shock and condition monitoring — Vocabulary | 60.60 | |
Field balancing equipment — Description and evaluation | 95.99 | |
Balancing machines — Description and evaluation | 95.99 | |
Balancing machines — Description and evaluation | 95.99 | |
Mechanical vibration of rotating and reciprocating machinery — Requirements for instruments for measuring vibration severity | 95.99 | |
Mechanical vibration of rotating and reciprocating machinery — Requirements for instruments for measuring vibration severity | 90.93 | |
Guide for the mechanical balancing of marine main steam turbine machinery for merchant service | 95.99 | |
Balancing machines — Symbols for front panels | 95.99 | |
Mechanical vibration of large rotating machines with speed range from 10 to 200 rev/s — Measurement and evaluation of vibration severity in situ | 95.99 | |
Criteria for evaluating flexible rotor balance | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 0: Basic concepts | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 0: Basic concepts — Technical Corrigendum 1 | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 0: Basic concepts — Technical Corrigendum 2 | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 10: Primary calibration by high impact shocks | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 11: Testing of transverse vibration sensitivity | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 12: Testing of transverse shock sensitivity | 90.93 | |
Methods for the calibration of vibration and shock pick-ups — Part 13: Testing of base strain sensitivity | 90.93 | |
Methods for the calibration of vibration and shock pick-ups — Part 14: Resonance frequency testing of undamped accelerometers on a steel block | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 15: Testing of acoustic sensitivity | 90.93 | |
Methods for the calibration of vibration and shock pick-ups — Part 16: Testing of mounting torque sensitivity | 90.93 | |
Methods for the calibration of vibration and shock pick-ups — Part 17: Testing of fixed temperature sensitivity | 90.92 | |
Methods for the calibration of vibration and shock pick-ups — Part 18: Testing of transient temperature sensitivity | 90.93 | |
Methods for the calibration of vibration and shock pick-ups — Part 19: Testing of magnetic field sensitivity | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 1: Primary vibration calibration by laser interferometry | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 20: Primary vibration calibration by the reciprocity method | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 22: Accelerometer resonance testing — General methods | 90.93 | |
Methods for the calibration of vibration and shock pick-ups — Part 2: Primary shock calibration by light cutting | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 3: Secondary vibration calibration | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 4: Secondary shock calibration | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 5: Calibration by Earth's gravitation | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 6: Primary vibration calibration at low frequencies | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 7: Primary calibration by centrifuge | 95.99 | |
Methods for the calibration of vibration and shock pick-ups — Part 8: Primary calibration by dual centrifuge | 90.93 | |
Methods for the calibration of vibration and shock pick-ups — Part 9: Secondary vibration calibration by comparison of phase angles | 95.99 | |
Mechanical vibration and shock — Mechanical mounting of accelerometers | 95.99 | |
Mechanical vibration and shock — Mechanical mounting of accelerometers | 90.92 | |
Mechanical vibration and shock — Mechanical mounting of accelerometers | 40.99 | |
The mechanical balancing of flexible rotors | 95.99 | |
Balancing machines — Enclosures and other safety measures | 95.99 | |
Balancing machines — Enclosures and other safety measures — Technical Corrigendum 1 | 95.99 | |
Vibration and shock — Experimental determination of mechanical mobility — Part 1: Basic definitions and transducers | 95.99 | |
Mechanical vibration and shock — Experimental determination of mechanical mobility — Part 1: Basic terms and definitions, and transducer specifications | 90.93 | |
Vibration and shock — Experimental determination of mechanical mobility — Part 2: Measurements using single-point translation excitation with an attached vibration exciter | 95.99 | |
Mechanical vibration and shock — Experimental determination of mechanical mobility — Part 2: Measurements using single-point translation excitation with an attached vibration exciter | 60.60 | |
Vibration and shock — Experimental determination of mechanical mobility — Part 5: Measurements using impact excitation with an exciter which is not attached to the structure | 90.92 | |
Mechanical vibration and shock — Experimental determination of mechanical mobility — Part 5: Measurements using impact excitation with an exciter which is not attached to the structure | 50.20 | |
Human response to vibration — Measuring instrumentation — Part 1: General purpose vibration meters | 60.60 | |
Human response to vibration — Measuring instrumentation | 95.99 | |
Human response to vibration — Measuring instrumentation — Amendment 1 | 95.99 | |
Human response to vibration — Measuring instrumentation — Technical Corrigendum 1 | 95.99 | |
Human response to vibration — Measuring instrumentation | 90.92 | |
Human response to vibration — Measuring instrumentation — Technical Corrigendum 1 | 95.99 | |
Human response to vibration — Measuring instrumentation — Part 2: Part 2: Personal vibration exposure meters | 30.60 | |
Shock and vibration measurements — Characteristics to be specified for seismic pick-ups | 90.93 | |
Mechanical shock — Testing machines — Characteristics and performance | 95.99 | |
Mechanical vibration and shock — Analytical methods of assessing shock resistance of mechanical systems — Information exchange between suppliers and users of analyses | 90.93 | |
Damping materials — Graphical presentation of the complex modulus | 90.93 | |
Rotating shaft vibration measuring systems — Part 1: Relative and absolute sensing of radial vibration | 90.93 | |
Mechanical vibration — Methods and criteria for the mechanical balancing of flexible rotors | 95.99 | |
Methods for the calibration of vibration and shock transducers — Part 11: Primary vibration calibration by laser interferometry | 90.93 | |
Methods for the calibration of vibration and shock transducers — Part 12: Primary vibration calibration by the reciprocity method | 90.93 | |
Methods for the calibration of vibration and shock transducers — Part 12: Primary vibration calibration by the reciprocity method — Technical Corrigendum 1 | 60.60 | |
Methods for the calibration of vibration and shock transducers — Part 13: Primary shock calibration using laser interferometry | 90.93 | |
Methods for the calibration of vibration and shock transducers — Part 15: Primary angular vibration calibration by laser interferometry | 90.93 | |
Methods for the calibration of vibration and shock transducers — Part 16: Calibration by Earth's gravitation | 90.93 | |
Methods for the calibration of vibration and shock transducers — Part 17: Primary calibration by centrifuge | 60.60 | |
Methods for the calibration of vibration and shock transducers — Part 1: Basic concepts | 90.93 | |
Methods for the calibration of vibration and shock transducers — Part 1: Basic concepts — Amendment 1 | 60.60 | |
Methods for the calibration of vibration and shock transducers — Part 1: Basic concepts — Amendment 2 | 30.00 | |
Methods for the calibration of vibration and shock transducers — Part 21: Vibration calibration by comparison to a reference transducer | 90.93 | |
Methods for the calibration of vibration and shock transducers — Part 21: Vibration calibration by comparison to a reference transducer — Amendment 1 | 60.60 | |
Methods for the calibration of vibration and shock transducers — Part 21: Vibration calibration by comparison to a reference transducer — Amendment 2 | 30.99 | |
Methods for the calibration of vibration and shock transducers — Part 21: Vibration calibration by comparison to a reference transducer — Technical Corrigendum 1 | 60.60 | |
Methods for the calibration of vibration and shock transducers — Part 22: Shock calibration by comparison to a reference transducer | 90.93 | |
Methods for the calibration of vibration and shock transducers — Part 22: Shock calibration by comparison to a reference transducer — Amendment 1 | 60.60 | |
Methods for the calibration of vibration and shock transducers — Part 31: Testing of transverse vibration sensitivity | 90.93 | |
Methods for the calibration of vibration and shock transducers — Part 31: Testing of transverse vibration sensitivity — Amendment 1 | 10.99 | |
Methods for the calibration of vibration and shock transducers — Part 32: Resonance testing — Testing the frequency and the phase response of accelerometers by means of shock excitation | 60.60 | |
Methods for the calibration of vibration and shock transducers — Part 33: Testing of magnetic field sensitivity | 60.60 | |
Methods for the calibration of vibration and shock transducers — Part 41: Calibration of laser vibrometers | 90.93 | |
Methods for the calibration of vibration and shock transducers — Part 42: Calibration of seismometers with high accuracy using acceleration of gravity | 90.20 | |
Methods for the calibration of vibration and shock transducers — Part 43: Calibration of accelerometers by model-based parameter identification | 60.60 | |
Methods for the calibration of vibration and shock transducers — Part 44: Calibration of field vibration calibrators | 60.60 | |
Methods for the calibration of vibration and shock transducers — Part 45: In-situ calibration of transducers with built in calibration coil | 60.60 | |
Methods for the calibration of vibration and shock transducers — Part 34: Testing of sensitivity at fixed temperatures | 50.20 | |
Mechanical vibration and shock — Performance parameters for condition monitoring of structures | 90.93 | |
Mechanical vibration and shock — Measurement of vibration power flow from machines into connected support structures — Part 1: Direct method | 90.93 | |
Mechanical vibration and shock — Measurement of vibration power flow from machines into connected support structures — Part 2: Indirect method | 90.93 | |
Mechanical vibration and shock — Signal processing — Part 1: General introduction | 90.93 | |
Mechanical vibration and shock — Signal processing — Part 1: General introduction — Technical Corrigendum 1 | 60.60 | |
Mechanical vibration and shock — Signal processing — Part 2: Time domain windows for Fourier Transform analysis | 90.93 | |
Mechanical vibration and shock — Signal processing — Part 2: Time domain windows for Fourier Transform analysis — Technical Corrigendum 1 | 60.60 | |
Mechanical vibration and shock — Signal processing — Part 3: Methods of time-frequency analysis | 90.93 | |
Mechanical vibration and shock — Signal processing — Part 4: Shock-response spectrum analysis | 90.93 | |
Mechanical vibration and shock — Characterization of the dynamic mechanical properties of visco-elastic materials — Part 1: Principles and guidelines | 90.93 | |
Mechanical vibration and shock — Characterization of the dynamic mechanical properties of visco-elastic materials — Part 2: Resonance method | 90.93 | |
Mechanical vibration and shock — Characterization of the dynamic mechanical properties of visco-elastic materials — Part 2: Resonance method — Amendment 1 | 60.60 | |
Mechanical vibration and shock — Characterization of the dynamic mechanical properties of visco-elastic materials — Part 3: Cantilever shear beam method | 90.93 | |
Mechanical vibration and shock — Characterization of the dynamic mechanical properties of visco-elastic materials — Part 3: Cantilever shear beam method — Amendment 1 | 60.60 | |
Mechanical vibration and shock — Characterization of the dynamic mechanical properties of visco-elastic materials — Part 4: Dynamic stiffness method | 90.93 | |
Mechanical vibration and shock — Characterization of the dynamic mechanical properties of visco-elastic materials — Part 5: Poisson ratio based on comparison between measurements and finite element analysis | 90.93 | |
Mechanical vibration and shock — Characterization of the dynamic mechanical properties of visco-elastic materials — Part 6: Time-temperature superposition | 60.60 | |
Human response to vibration — Guidance and terminology for instrumentation and equipment for the assessment of daily vibration exposure at the workplace according to the requirements of health and safety | 60.60 | |
Calibration of conditioning amplifiers for dynamic application | 20.00 | |
Mechanical vibration — Criteria and safeguards for the in-situ balancing of medium and large rotors | 95.99 | |
Mechanical vibration and shock — Parameters to be specified for the acquisition of vibration data | 90.93 |
No matching records found
1. Overview of Standards
![Iso Iso](/uploads/1/2/6/0/126036530/756073906.jpg)
Weighting Filters
A-, B-, and C-Weighting Filters
- ANSI S1.4-2014
- ANSI S1.42-2001
- IEC 61672-1:2013
- JIS C 1509-1:2005
Weighting Filters
- ITU-R 468-4
- JIS C 6102:1998
- Dolby
Telecommunications Weighting Filters
- ITU-T 0.41 (CCITT)
- Bell System Technical Reference 41009 (C-message)
Human Vibration Weighting Filters
- ISO 8041:2005 (E): Human Response to Vibration – Measuring Instrumentation
- JIS B 7760:2004: Whole-Body Vibration
- JIS B 7761:2004: Hand-Transmitted Vibration
Octave Analysis
- ANSI S1.11-2014: Electroacoustics - Octave-band and fractional-octave-band filters, class 1
- IEC 61260:2014: Electroacoustics - Octave-band and fractional-octave-band filters, class 1
- JIS C 1514:2002: Electroacoustics - Octave-band and fractional-octave-band filters, class 1
Sound Level
Iso Vibration Severity Standards
- ISO/IEC 61672-1:2002
- ANSI S1.4-1983
2. Weighting Filters
A-, B-, and C-Weighting Filters
ANSI Standards
When combined with any DSA device, the weighting filter used by the SVT A, B, C Weighting Filter (Fixed Rates) VI or designed by the SVT Weighting Filter VI complies with the following standards:
The SVT Weighting Filter VI accommodates any sample rate greater than 4 kHz and designs the filter coefficients to target the attenuation curves defined by the ANSI standards. Given the selected sampling frequency, compliance with a particular filter type, either Type 1 or Type 0, is ensured up to a specific frequency. This frequency is the maximum frequency within tolerances. Use the SVT Max Frequency Within Tolerances [ANSI] VI to determine the maximum frequency within tolerances. The SVT A, B, C Weighting Filter (Fixed Rates) VI supports the following sample rates:
4 kHz, 8 kHz, 10 kHz, 11.025 kHz, 12.8 kHz, 20 kHz, 22.05 kHz, 25.6 kHz, 40 kHz, 44.1 kHz, 48 kHz, 50 kHz, 51.2 kHz, 80 kHz, 96 kHz, 100 kHz, 102.4 kHz, 192 kHz, 200 kHz, 204.8 kHz, 500 kHz, 1 MHz
For all supported sample rates the VI achieves Type 0 compliance to the Nyquist frequency.
ISO/IEC Standard
Use the SVT A, B, or C Weighting Filter (Fixed Rates) VI or the SVT Weighting Filter VI to apply an A-, B-, or C-weighting filter to time-domain signals. When combined with any DSA device, the weighting filter used by the SVT A, B, or C Weighting Filter (Fixed Rates) VI or designed by the SVT Weighting Filter VI complies with:
- IEC 61672-1:2002
The SVT Weighting Filter VI accommodates any sample rate greater than 4 kHz and designs the filter coefficients to target the attenuation curves defined by the IEC standards. Given the selected sampling frequency, compliance with a particular filter type, either Class 2 or Class 1, is ensured up to a specific frequency. This frequency is the maximum frequency within tolerances. Use the SVT Max Frequency Within Tolerances [IEC] VI to determine the maximum frequency within tolerances. The SVT A, B, C Weighting Filter (Fixed Rates) VI supports the following sample rates:
4 kHz, 8 kHz, 10 kHz, 11.025 kHz, 12.8 kHz, 20 kHz, 22.05 kHz, 25.6 kHz, 40 kHz, 44.1 kHz, 48 kHz, 50 kHz, 51.2 kHz, 80 kHz, 96 kHz, 100 kHz, 102.4 kHz, 192 kHz, 200 kHz, 204.8 kHz, 500 kHz, 1 MHz
For all supported sample rates the VI achieves Class 1 compliance to the Nyquist frequency.
Radiocommunications Weighting Filters
![Iso vibration standards pdf Iso vibration standards pdf](/uploads/1/2/6/0/126036530/905448111.jpg)
ITU-R 468-4 and Dolby
When combined with any DSA device, the weighting filter used by the SVT Radiocommunications Weighting Filter (Fixed Rates) VI complies with the ITU-R 468-4 standard. The SVT Radiocommunications Weighting Filter (Fixed Rates) VI accommodates the following sample rates:
20 kHz, 22.05 kHz, 25.6 kHz, 40 kHz, 44.1 kHz, 48 kHz, 50 kHz, 51.2 kHz, 80 kHz, 96 kHz, 100 kHz, 102.4 kHz, 192 kHz, 200 kHz, 204.8 kHz, 500 kHz, 1 MHz
For all supported sample rates, the VI achieves compliance to the Nyquist frequency.
Telecommunications Weighting Filters
When combined with any DSA device, the weighting filter used by the SVT Telecommunications Weighting Filter (Fixed Rates) VI complies with the following standard and reference:
- ITU-T 0.41 (CCITT)
- Bell System Technical Reference 41009 (C-message)
The SVT Telecommunications Weighting Filter (Fixed Rates) VI supports the following sample rates:
4 kHz, 8 kHz, 10 kHz, 11.025 kHz, 12.8 kHz, 20 kHz, 22.05 kHz, 25.6 kHz, 40 kHz, 44.1 kHz, 48 kHz, 50 kHz, 51.2 kHz, 80 kHz, 96 kHz, 100 kHz, 102.4 kHz, 192 kHz, 200 kHz, 204.8 kHz, 500 kHz, 1 MHz
For all supported sample rates, the VI achieves compliance to the Nyquist frequency.
Human Vibration Weighting Filters
Iso Vibration Standards 10816
When combined with any DSA device, the human vibration weighting filters that the Sound and Vibration Measurement Suite provides comply with ISO 8041:2005 (E): Human Response to Vibration – Measuring Instrumentation.
The Sound and Vibration Measurement Suite provides the following weighting filters that you can apply to human vibration signals:
- Wb—Weighting for vertical whole-body vibration, z–axis, seated, standing or recumbent person, based on ISO 2631–4.
- Wc—Weighting for horizontal whole-body vibration, x–axis, seat back, seated person, based on ISO 2631-1.
- Wd—Weighting for horizontal whole-body vibration, x– or y–axis, seated, standing or recumbent person, based on ISO 2631-1.
- We—Weighting for rotational whole-body vibration, all directions, seated person, based on ISO 2631-1.
- Wf—Weighting for vertical whole-body vibration, z–axis motion sickness, seated or standing person, based on ISO 2631-1.
- Wh—Weighting for hand-arm vibration, all directions, based on ISO 5349-1.
- Wj—Weighting for vertical head vibration, x–axis recumbent person, based on ISO 2631-1.
- Wk—Weighting for vertical whole-body vibration, z–axis seated, standing or recumbent person, based on ISO 2631-1.
- Wm—Weighting for whole-body vibration in buildings, all directions, based on ISO 2631-2.
3. Octave Analysis
Iso Vibration Standards Chart
Overview
The Octave Analysis VIs can accommodate any sampling frequency and any number of fractional-octave bands. These VIs offer compliance with the following standards:
- ANSI S1.11-2014: Electroacoustics - Octave-band and fractional-octave-band filters, class 1
- IEC 61260:2014: Electroacoustics - Octave-band and fractional-octave-band filters, class 1
Midband Frequencies
According to the IEC 61260:2014 and the ANSI S1.11-2014 standards, the exact mid-band frequencies, fm, of any filter in a set of filters shall be determined from the following expression:
fm = frGx/b, when b is odd
fm = frG(2x+ 1)/2b, when b is even
Where fr is the reference frequency, G = 100.3 is the octave frequency ratio, 1/b is the bandwidth designator, and equals 1 for octave, 1/3 for 1/3 octave, 1/6 for 1/6 octave, 1/12 for 1/12 octave, and 1/24 for 1/24 octave, x is any integer, positive or negative, or zero.
Nominal Frequencies
The exact midband frequencies are used to design the filters for fractional-octave analysis. However, all the octave analysis tools in the Sound and Vibration Measurement Suite return the nominal midband frequencies, also called the preferred frequencies. In the case of octave and 1/3 octave analyses, the nominal frequencies are calculated in accordance with the ANSI and IEC standards. In the case of 1/6, 1/12, and 1/24 octave analyses, the nominal frequencies are calculated in accordance with the Annex E (informative) of the IEC 61260:2014 and the ANSI S1.11-2014 standards.
Compliance with ANSI and IEC Standards
When combined with any National Instruments DSA device, the appropriate microphone, and proper signal conditioning, the filters produced by the octave analysis tools in the Sound and Vibration Measurement Suite comply with the following standards:
- ANSI S1.11-2014: Electroacoustics - Octave-band and fractional-octave-band filters, class 1
- IEC 61260:2014: Electroacoustics - Octave-band and fractional-octave-band filters, class 1
- JIS C 1514:2002: Electroacoustics - Octave-band and fractional-octave-band filters, class 1
For octave filters, choose a sampling frequency at least three times the exact center frequency of the highest frequency band. For fractional-octave filters, choose a sampling frequency at least 2.5 times the exact center frequency of the highest frequency band.
4. Sound Level
Iso Vibration Standards
When combined with any National Instruments DSA device, the appropriate microphone, and proper signal conditioning, the Sound Level VIs are compliant with the ISO/IEC 61672-1:2002 standard.
National Instruments dynamic signal acquisition boards combined with the NI LabVIEW Sound and Vibration Software, have been tested and found compliant with several ANSI and IEC standards including the requirements for a class 1 instrument specified in IEC 61672-1: 2002. The filters used meet the requirements for a class 1 instrument specified in IEC 61260: 1995.
For a complete system, a suitable microphone compatible with ANSI S1.4 or IEC 651 requirements for a Type 1 precision microphone needs to be specified.