Guide to the Wind Turbine Shadow Calculator
The calculator on the following page allows you to simulate shadows from a wind turbine on a plane, horizontal landscape any minute, hour, day, month, or year anywhere on the globe.
Warning: Huge Plots Will Take Their Time - and lots of RAM
If you wish to compute shadows for a whole year, it may take your computer from 20 minutes to a couple of hours or more, depending on the speed of your browser and your machine, and how fine a map resolution and time resolution you choose. A fine map resolution (down to 3 pixels square) or a large plot area increases processing time and the required amount of RAM on your computer significantly.
Colouring the Plot
The grey colours in your plot are selected automatically by the programme, so that the most shadow affected areas are shown in pure black, while the least affected areas are shown in white, regardless of whether you run the programme for 1 minute or a year. The unaffected areas remain green.
If you have a screen with millions of colours, you will find that the grey shadows vary very smoothly across the screen. If you like to be able to see the different "bands" of shadow minute values, like we have done in our images on this web site, set your monitor to thousands of colours, or even 256 colours.
You Can Save Your Shadow Maps
If you have generated a shadow map which you want to look at later, or compare with another map, you may save the page (e.g. onto your desktop), just like any other web page in HTML format, if you use Internet Explorer 4. Just choose Save from your file menu, (and take care where you save it, and what you name it).
Read the Number of Minutes of Shadows in Each Cell
if you have an Internet Explorer 4 browser, and you leave this option on when you generate the map, you can do an exact readout (in the status line of your browser) of the number of minutes there may be shadows in each cell by moving the cursor around on the shadow map.
You May Recolour Your Result
The plot uses a number of standard colours which look logical on a colour screen. The colours, however, may not be optimal if you wish to print the result on a black and white printer. We have therefore included a facility which allows you to change the colour scheme without redoing the long calculations: You may use a particular colour in a "shadow zone" around the turbine. If you use a large high resolution map, it may take a few minutes for your programme to do the recolouring (IE 4 is slower than Netscape 4 for this).
Paint Your Shadow Zone
You may modify your plot to show you any zone with a certain minimum number of minutes of shadows in a certain colour. Be warned, however, that with a large high resolution map, it will take several minutes to complete that process.
Other Calculator Usage
Incidentally, this calculator is very practical for photographers who wish to know where the sun is before they go out to take a picture of their favourite motive in ideal lighting conditions. (We tested it when photographing wind turbines, of course). You may also use it if you wish to know how to place a terrace in your garden (regardless of whether you want shadow or sun).
You may either specify your turbine location using the pop up menu which gives the longitude and latitude of a number of cities around the globe, or you may enter the longitude and latitude in degrees and minutes directly, together with your time zone.
The time zone is automatically included, if you use the pop up menu with city names. You may enter your time zone relative to GMT from the pop up menus, or you may enter the standard time zone meridian, i.e. the longitude relative to Greenwich which your local time system uses as a reference, which is generally a multiple of 15 degrees, corresponding to a one hour time difference. (India and a few other places have a time zone which is a multiple of 7.5 degrees, i.e. half an hour).
You may enter date and time to see the sunrise and sunset times, plus the current direction of the light coming from the sun.
Enter the hub height and the rotor diameter. A typical hub height for a 600-750 kW wind turbine is 45 to 60 m, a typical rotor diameter is 43 to 48 m. (You may find typical hub heights and rotor diameters using theWind Turbine Power Calculator turbine pop up menu).
If you wish to study shadows in areas which are lower than the base of the wind turbine, you can cheat, and increase the hub height of the turbine. Conversely, you can lower the hub height, if you wish to study areas which are higher than the base of the turbine.If you enter, say 0.5 for the rotor diameter, you may use the programme to study the behaviour of a shadow from the top of a mast, or the corner of a building. (Or you can use it to build your own sundial).
You can specify the time range for which you like your shadow images computed. You can select a minute, an hour, a day, a month, or a year.
You may set the plot area to fit your screen size (and/or paper output). If you have enough RAM (and time) you may even specify a map larger than your screen. The default size prints well on A4 paper in landscape format.The resolution parameter determines the area covered by each 3-25 pixel square. We recommend that you let each square represent less than half the rotor diameter to get a decent plot. Or, even more cleverly, you may set it to match your map resolution, and print your output on an acetate (overhead) foil as an overlay to a map of a prospective wind turbine location. (One printed pixel is 1/72 of an inch (1 inch = 2.54 cm)).The step length in minutes determines how many rotor images the programme projects onto your ground surface. The default step length of 4 minutes corresponds to the sun
azimuth changing on average 1 degree between each simulation. You may save processing time if you choose a longer step length. For a 1 month or 1 year simulation results are generally not affected much by using 8 minute steps - and it is 8 times faster than 1 minute steps. If the shadow image is not smooth, (or if it is asymmetrical in the East-West direction even if you are not running with a fixed rotor direction or a wind rose), your step length may be too large. If you double the step length, the programme assumes that the rotor shadow stays in the same place for twice as long, i.e. for each rotor image projected onto the ground, it adds the step length to a shadow counter for that particular area.
You may choose rotor direction as random (default), which means the rotor may be facing in any direction (random azimuth), you may choose worst case, where the rotor always faces the sun.
You may choose a fixed rotor azimuth angle from -90 to 90 degrees. The angle is measured relative to South, and the solar angle is positive before noon, regardless of hemisphere. 0 means that the wind is coming form the South or North. Southeast/Northwest is 45 degrees in the Northern hemisphere, and -45 degrees in the Southern hemisphere. East/West is 90 or -90 degrees. To help you select the correct angle, you may use the pop up menu.
Finally, you may choose to enter a wind rose with a frequency distribution for your wind directions. Since a normal propeller type wind turbine is symmetrical about its rotor plane, you should add the percentages for North and South, and so forth in each of your directions. The programme accepts 8, 12 and 16 compass directions, which means that you specify 4, 6, or 8 percentages. The program checks that the sum is exactly 100, before it is willing to do the simulation. Please note that wind roses are specified with the North as 0 degrees, and that the degrees are given in a clockwise direction (retrograde direction).
You should specify the fraction of daytime hours the turbine will be running. 0.75 is a typical fraction. The basic result in terms of minutes of shadows is multiplied by this fraction.
You should specify the fraction of daytime hours with bright sunshine. The basic result in terms of minutes of shadows is multiplied by this fraction.
If you have accurate statistics on the number of bright sunshine hours per month, you may instead use that data in your calculations, by filling out the sunshine table at the bottom of the page. In that case the programme uses the table data for each month instead of the average. We have included sunshine data for 3 Danish locations (you select them from the pop up menu). If you have reliable monthly data available for your location, please e-mail us (giving the source) so that we may include it in the city pop up menu. Remember to check the box that says you want to use the table for your calculations. (A clever trick: If you wish to see the pattern of shadows during e.g. June, July, and August only, you may set the sunshine percentages for the three months only, and leave the rest of the months at zero, and then run a simulation for a year, using the sunshine table).
You may set a maximum distance from the wind turbine for the shadow plot, since it is usually not relevant to look at distances above 7 to 10 rotor diameters or 1,000 m at the most.
Finally, you may choose to have your output displayed with mouse-sensitive shadow readout (for I.E. 4 browsers), which means that you may read the number of minutes of shadow in each cell on the map in your browser's status line by placing the mouse cursor on a particular cell. Using this mechanism increases RAM demand.
In this programme the sunrise time is defined as the moment a straight line to the centre of the sun passes the horizon in the upwards direction on the date you have entered in your data. In your local newspaper, you may find that the sunrise is defined as being some minutes earlier, when the upper edge of the sun reaches the horizon. In addition, the refraction (bending of the light) in the atmosphere means that you can actually see the sun before it reaches the horizon. The sunrise is in local time, or daylight saving time, if the Daylight saving time box is checked.
The solar noon is when the sun reaches it highest point in the sky, i.e. the solar altitude is at its maximum. Noon is in local time, or daylight saving time, if the Daylight saving time box is checked.
In this programme sunset time is defined as the moment a straight line to the centre of the sun passes the horizon in the downwards direction on the date you have entered in your data. In your local newspaper, you may find that the sunset is defined as being some minutes later, when the upper edge of the sun reaches the horizon. In addition, the refraction (bending of the light) in the atmosphere means that you can actually see the sun after it goes below the horizon. The sunset is in local time, or daylight saving time, if the Daylight saving time box is checked.
The declination is the angle between the earth's equatorial plane, and the earth-sun line.As the earth rotates, it spins around its axis which points to the North Star. This axis is inclined 23.45° relative to the plane in which it orbits the sun. The angle between the equatorial plane and the earth-sun line thus varies between +/-23.45° during the year, being approximately zero on the 21/3 and 23/9 (Equinox), and reaching its extreme values on 21/6 and 21/12 (Solstice). (Its precise value varies a bit from year to year since a year is 365.25 days long).
This is the number of minutes and seconds it takes for the solar disc to move the 0.531° between the bottom and the top of the sun at sunrise or sunset. At the equator the sunrise and sunset last little more than two minutes. As you move towards the polar regions, the duration increases significantly, particularly in winter, as you may verify by altering the latitude.
The solar azimuth is the angle in the horizontal plane between the South and the sun at the moment in time you have entered in your data. The angle is positive before noon, negative after noon (regardless of hemisphere).
The solar altitude is the angle between the horizontal plane and the sun.
Direction form the Sun (Sun Vector)
If you are standing in the centre of the turbine with your back towards the South, and you move x units of length to the right (East), y ahead (North), and z up (or rather -z down), then a straight line from your new position to the centre of the turbine will be pointing directly to the sun. The values for x, y, and z are given in the three boxes.
© Copyright 1997-2003 Danish Wind Industry Association
Updated 10 May 2003