Direct insolation explained

Direct insolation is the insolation measured at a given location on Earth with a surface element perpendicular to the Sun's rays, excluding diffuse insolation (the solar radiation that is scattered or reflected by atmospheric components in the sky). Direct insolation is equal to the solar irradiance above the atmosphere minus the atmospheric losses due to absorption and scattering. While the solar irradiance above the atmosphere varies with the Earth - Sun distance and solar cycles, the losses depend on the time of day (length of light's path through the atmosphere depending on the solar elevation angle), cloud cover, humidity, and other impurities.

Simplified formula

A simple formula gives the approximate level of direct insolation when there are no clouds:[1]

2 x
I
D=1.353kW/m
AM0.678
0.7

where AM is the airmass given by

AM=1{\cos\theta}

with θ being the zenith angle (90° minus the altitude) of the sun.

For the sun at the zenith, this gives 947 W/m2. However, another source states that direct sunlight under these conditions, with 1367 W/m2 above the atmosphere, is about 1050 W/m2, and total insolation about 1120 W/m2.[2]

Average direct insolation

For practical purposes, a time-average of the direct insolation over the course of the year is commonly used. This averaging takes into account the absence of sunlight during the night, increased scatter in the morning and evening hours, average effects of cloud cover and smog, as well as seasonal variations of the mid-day solar elevation.

Units of measurement

Direct insolation is measured in (W/m2) or kilowatt-hours per square meter per day (kW·h/(m2·day)).

1 kW·h/(m2·day) = 1,000 W · 1 hour / (1 m2 · 24 hours) = 41.67 W/m2In the case of photovoltaics, average direct insolation is commonly measured in terms of peak direct insolation as kWh/(kWp·y)(kilowatt hours per year per kilowatt peak rating)

Applications

Since radiation directly from the sun can be focussed with mirrors and lens, it can be applied to concentrated solar thermal (CST) systems.[3] [4] [5] Due to clouds and aerosols, the direct insolation can fluctuate throughout the day, so forecasting the available resource is important in these applications [6] [7]

External links

Notes and References

  1. Web site: Calculation of Solar Insolation. PVEducation.org. https://web.archive.org/web/20160129052640/http://www.pveducation.org/pvcdrom/properties-of-sunlight/calculation-of-solar-insolation. January 29, 2016. live.
  2. Web site: Introduction to Solar Radiation. Newport Corporation. live. https://web.archive.org/web/20131029234117/http://www.newport.com/Introduction-to-Solar-Radiation/411919/1033/content.aspx. October 29, 2013.
  3. Boerema. Nicholas. Morrison. Graham. Taylor. Robert. Rosengarten. Gary. 2013-11-01. High temperature solar thermal central-receiver billboard design. Solar Energy. 97. 356–368. 10.1016/j.solener.2013.09.008. 2013SoEn...97..356B.
  4. Boerema. Nicholas. Taylor. Robert A.. Morrison. Graham. Rosengarten. Gary. 2015-09-01. Solid–liquid phase change modelling of metallic sodium for application in solar thermal power plants. Solar Energy. 119. 151–158. 10.1016/j.solener.2015.06.024. 2015SoEn..119..151B.
  5. Boerema. Nicholas. Morrison. Graham. Taylor. Robert. Rosengarten. Gary. 2012-09-01. Liquid sodium versus Hitec as a heat transfer fluid in solar thermal central receiver systems. Solar Energy. 86. 9. 2293–2305. 10.1016/j.solener.2012.05.001. 2012SoEn...86.2293B.
  6. Law. Edward W.. Kay. Merlinde. Taylor. Robert A.. 2016-02-01. Calculating the financial value of a concentrated solar thermal plant operated using direct normal irradiance forecasts. Solar Energy. 125. 267–281. 10.1016/j.solener.2015.12.031. 2016SoEn..125..267L.
  7. Law. Edward W.. Prasad. Abhnil A.. Kay. Merlinde. Taylor. Robert A.. 2014-10-01. Direct normal irradiance forecasting and its application to concentrated solar thermal output forecasting – A review. Solar Energy. 108. 287–307. 10.1016/j.solener.2014.07.008. 2014SoEn..108..287L.