Currently I believe that one of the most popular green energy method that exists are the solar cells (photovoltaic cells) . With this being said , I believe is its quite appropriate that last weeks lab experiment we worked with a solar cell cell. For this experiment we used a flashlight as our light source, a solar cell that was connected to the Lego Mindstorm which will also work as a voltmeter and measure the output voltage that results from the light received by the solar cell.We wanted to test two things:
-
The relationship between the distance from the light source to the solar cell ans the resulting output voltage.
-
The relationship of the light absorbance of colors.
For both experiments we obtained a table of results and its graphical representation(this will the analysis of the results easier)
For the first experiment we started measuring the voltage when there is no light; this value was our reference value ( Vo=0.0353 volts). Our results should be higher than the reference value since for our actual experiment we will be applying direct light to the solar cell. We started our measurements at an initial position of x= 0 inches or 0 centimeters(cm). We pointed out flashlight directly at the solar cell and measured the output voltage; then we incremented the distance o between the source(flashlight) and the receiver ( solar cell) and repeated the procedure. We incremented the distance every time by 3 inches, but our results were recorded in centimeters since this is the proper unit for the metric system. These are our results for our first experiment.
|
Distance between source and receiver |
Output Voltage |
|
no light |
0.035347 Volts |
|
0 cm |
0.585754 Volts |
|
7.62 cm |
0.302211 Volts |
|
15.24 cm |
0.51134 Volts |
|
22.86 cm |
0.513906 Volts |
|
30.48 cm |
0.425379 Volts |
Table1 : Output voltage from the solar cell with respect to the distance between source and receiver
Graph 1: Graphical representation of the results shown in Table
As you can see there is one particular value that doesn’t quite follow the trend line; the value at x=7.62 cm is too low than the expected value. The reason for this numbers s that the light was not directly pointing to the solar cell but it was only pointing to one section of the panel. After realizing our mistake, we were more careful for the next runs and always pointed the light to the center of the solar cell.
For our second experiment we did something a little bit more different. We placed difference color sheets between the solar cell and the flashlight. As you may already know the reason is that can see colors is because when light hits an object; all the colors are absorbed by the object except one that gets reflected which is the color that we see; you can see a representation of this below:
Image1 : Color reflection
Since colors get absorbed, that leads us to think that placing a color sheet in between our light source and the receiver will result in a change of the amount of light that gets to the solar cell and therefore the output voltage generated by the solar cell. We tested different colors: green, red, yellow and blue. We are expecting to have the least amount of output voltage after using the darkest color( blue) and the highest amount of the voltage from the lightest color red . Here are our results:
|
Color Filter |
Output Voltage |
|
Green |
0.576773 |
|
Blue |
0.566509 |
|
Red |
0.580622 |
|
Yellow |
0.572924 |
Table 2: Output voltage for each color filter
Graph 2: Graphical representation of the light absorbance
From Graph 2 you can see that our values were are expected the amount of voltage that we generated while the blue filter was applied was significantly less than the amount of voltage that was generated when the red filter was used.
From this experiment I learned the importance of the angle that the solar cells are placed on the panel; since the output voltage that will be obtained from these won’t be as high as it could potentially be. I also learned that we won’t be able to produce as much voltages if we filtered the light with dark color materials.