Pyrheliometer

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ISO 9060:2018 Class A, fast response & spectrally flat, pyrheliometer MS-57 Pyrheliometer.jpg
ISO 9060:2018 Class A, fast response & spectrally flat, pyrheliometer
1913 Balloon Borne Pyrheliometer 1913 Balloon Borne Pyrheliometer.jpg
1913 Balloon Borne Pyrheliometer
Typical pyrheliometer, for measurement of direct solar radiation DR01 pyrheliometer 1.jpg
Typical pyrheliometer, for measurement of direct solar radiation
Pyrheliometer: (3) body, (4) protection cap, (5) window with heater, (2) sight, (1) humidity indicator, (7) cable DR01 pyrheliometer linedrawing.pdf
Pyrheliometer: (3) body, (4) protection cap, (5) window with heater, (2) sight, (1) humidity indicator, (7) cable

A pyrheliometer is an instrument that can measure direct beam solar irradiance. [1] Sunlight enters the instrument through a window and is directed onto a thermopile which converts heat to an electrical signal that can be recorded. The signal voltage is converted via a formula to measure watts per square metre.

Contents

Standards

Pyrheliometer measurement specifications are subject to International Organization for Standardization (ISO) and World Meteorological Organization (WMO) standards. Comparisons between pyrheliometers for intercalibration are carried out regularly to measure the amount of solar energy received. The aim of the International Pyrheliometer Comparisons, [2] which take place every 5 years at the World Radiation Centre [3] in Davos, is to ensure the world-wide transfer of the World Radiometric Reference. During this event, all participants bring their instruments, solar-tracking and data acquisition systems to Davos to conduct simultaneous solar radiation measurements with the World Standard Group. [4]

Applications

Typical pyrheliometer measurement applications include scientific meteorological and climate observations, material testing research, and assessment of the efficiency of solar collectors and photovoltaic devices.

Usage

Pyrheliometers are typically mounted on a solar tracker. As the pyrheliometer only 'sees' the solar disk, it needs to be placed on a device that follows the path of the sun.

See also

Related Research Articles

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References

  1. "Pyrheliometer". kippzonen.com. Archived from the original on April 12, 2009.
  2. "welcome to pmodwrc". April 16, 2010. Archived from the original on 2010-04-16.
  3. "welcome to pmodwrc". July 2, 2007. Archived from the original on 2007-07-02.
  4. "Startseite". PMOD/WRC.