NPL- National Physical Laboratory
ARAI- Automotive Research Association of India
Bureau of Indian Standards (BIS)
ISO - International Organization for Standardization
NABL- National Accreditation Board for Testing and Calibration Laboratories
NIST- National Institute of Standards and Technology
EURAMET- European Association of National Metrology Institutes
FORCE:
1. IS : 4169-1988 - Method for calibration of force -proving instruments used for the verification of uniaxial testing machines
2. ASTM E 74 – 06: Standard practice of Calibration of Force-Measuring Instruments for Verifying the Force Indication of Testing Machines1.
3. ISO 376:2011(E) - Metallic materials-calibration of force -proving instruments used for the verification of uniaxial testing machines.
Torque Transducer:
1. BS 7882:2008 : Method for calibration and classification of torque measuring devices.
2. EURAMET cg 14: Static Torque measuring devices.
The conventional mass value of a body is equal to the mass mc of a standard that balances this body under conventionally chosen conditions. The unit of the quantity "conventional mass" is the kilogram
The conventionally chosen conditions are:
tref = 20 C 0 = 1.2 kg m-3 c = 8 000 kg m-3
The conventional mass has the same unit as mass, because its values are defined through the multiplication of a mass by a dimensionless quantity.
When a measuring instrument is sent for calibration, after the process is completed it is returned to the user along with a Calibration Certificate. But what exactly is a calibration certificate? What is the purpose of the certificate? How do I verify a calibration certificate? What a Calibration Certificate should contain?
In order to understand what exactly a Calibration Certificate is, we must first familiarize ourselves with the meaning of the term ‘calibration’.
A calibration is a process that compares a known (the standard) against an unknown (the customer's device). During the calibration process, the offset between these two devices is quantified and the customer's device is adjusted back into tolerance (if possible). A true calibration usually contains both "as found" and "as left" data.
measurement uncertainty - parameter, associated with the result of a measurement, that characterizes the dispersion of the values that could reasonably be attributed to the measurand. (International Vocabulary of Basic and General Terms in Metrology)
Advantages of electronic force proving instruments instead of force proving ring device:
Metrology is the science of measurement and its application. It represents the basis for trust on the results obtained. The national metrology system of a country represents the infrastructure that enables the performance and application of measurement for purposes that mirror the economic and social core of the nation.
Purpose of Metrology – legal metrology, industrial metrology and scientific metrology.
These are fields that have been internationally accepted to cover all the technical and practical aspects of measurements.
In order that investigator in different parts of the country and different parts of the world may compare the results of their experiments on a consistent basis. It is necessary to establish certain standard units of length, mass, time, temperature, pressure, etc.
A Dimension defines a physical variable that is used to describe some aspect of a physical system. The fundamental value associated with any dimension is given by a Unit.
A Unit defines a measure of a dimension.
Fundamental Dimension: Length, Mass, Time, Temperature, Electrical Current, Luminous Intensity.
Derived Dimension: Acceleration, Area, Density, Velocity and Force.
The precision to which we can measure something is limited by experimental factors, leading to uncertainty. The uncertainty depends on various factors including environmental, process, man or machine. The better control of these various factors, better the uncertainty.
The deviation of a measurement from the "correct" value is termed the error, so error is a measurement of how inaccurate our results are.
There are two general types of errors.
. Systematic Errors - A error that is constant from one measurement to another, for example, an incorrectly marked ruler would always make the same mistake measuring something as either bigger or smaller than it actually is every time. These errors can be quite difficult to eliminate!
