Last updated on September 19, 2021 2:18 pm
Learn How Solar Panels Works
Are you curious about how solar panels work? They are made from melted silicon rocks. A little bit of a positive chemical element, such as boron, is added to the silicon to make sure the resulting silicon block, or ingot, has a positive potential.
Once the silicon has cooled for days and hardened, the ingot is then sliced into thin wafers, and the wafer is coated on one side with a negatively charged element, such as phosphorus. The combination of the positive boron-infused silicon on one side and negative phosphorus on the other side creates a positive/negative, or P/N, junction.
This is where the magic happens, the photovoltaic effect. Wires are then painted onto the wafer, providing a method to harness the flow of electricity. At this point, the wafer is a solar cell. When the sun hits the negative side of the solar cells, some of the negatively charged electrons are knocked loose from their atoms.
They travel across the P/N junction to the positive side, where there are holes available for them to settle into. This creates a direct current, or DC, flow. This current is measured in amps. Simultaneously, a voltage potential is created between the two sides of the solar cells.
How solar panels work? Each solar cell is capable of generating about ½ volt. Well, ½ volt doesn’t do all that much for you electrically, so several of them are wired together in series, plus to minus, to create a usable voltage.
There is much to know about how solar panels work. A typical 12-volt solar panel, as we have here has 36 of these cells in series, generating about 18V Vmp. A 20-volt solar panel like this, which is commonly used in grid-tie home solar systems will usually have 60 cells wired together for 30 volts Vmp.
Here I’ve got two 24 volt panels, the altE 24V 100W, and 200W. They both have the same number of cells, 72, but this one is only 100 watts, and this one is 200 watts. You can see that each cell in the 200-watt solar panel is twice as big as the cells in the 100-watt solar panel, so it is putting out twice the current, or amps.
Since volts times amps equal watts, twice the amps mean twice the watts. Multiple solar panels can then be wired together in series to further increase the voltage, which is then called a series string of panels.
Multiple strings of panels can then be wired together in parallel, to increase the current. Multiple solar panels all wired together make up a solar array. If you found this video helpful, please like and share it.
These waves can range in length, from short, ultraviolet waves, through the rainbow of the visible spectrum, to long infrared waves. When the sun is shining, these waves move towards the earth and hit the surface of solar cells.
Let’s take a closer look at how solar panels work. The active part of a solar cell is a wafer made of a semiconductive material, typically silicon. A semiconductor is a type of material that normally doesn’t conduct electricity well, but it can be made more conducive under certain conditions. Advertise free with hippie deals
The semiconductor part of the solar cell has three layers. The thin top layer contains silicon and a very tiny amount of an element, such as phosphorus, that has more electrons than silicon. This gives the top layer excess electrons that are free to move and make the material more conductive.
The top layer is also called negative-type, or n-type, as it favors the collection and transport of electrons. The thin bottom layer contains both silicon and an element, such as boron, that has fewer electrons than silicon.
This gives the bottom layer fewer electrons that are free to move, therefore making the material less conductive for electrons. A missing electron can be described as an effective positive charge. Therefore, the bottom layer is called positive-type, or p-type, as it preferentially favors the collection and transport of these positive charges, also dubbed ‘holes.
’ The thicker middle layer has only slightly fewer electrons, making it marginally p-type. Thin metal lines, typically made of silver, are printed on the top n-type layer, and the bottom p-type layer is in contact with an aluminum plate.
When light waves hit the top surface of the silicon solar cell, only light with wavelengths from a specific window of the solar spectrum (350-1140 nm) is absorbed into the middle layer of the solar cell.
This range of wavelengths includes the visible spectrum: ultraviolet wavelengths are so short they stop at the surface, and infrared wavelengths are so long they cannot be absorbed and pass right through the cell or are reflected back.
The lightwave knocks an electron off a silicon atom, setting the electron loose and leaving an area of positive charge (a ‘hole’) where the electron used to be. The loose electron then moves towards the top and reaches the top n-type layer, which readily accepts electrons.
Similarly, the loose hole moves towards the bottom and reaches the bottom p-type layer, which readily accepts holes. This continues as long as sunlight shines on the solar cell. Now that the electrons and the holes have been separated, connecting a wire between the top and the bottom metal electrodes provides a pathway for the electrons to move towards the holes.
The flow of electrons is an electrical current! One solar cell produces several Watts of power. This may be sufficient for running a calculator or a phone charger, but it is not sufficient for running a toaster, for example, which uses one thousand Watts.
So, several solar cells, typically 32, are wired together to make a solar panel. Several solar panels are needed to generate enough electricity to power a household. Like leaves, solar cells are a viable way to convert the sun’s rays directly into electricity that we can use.
Future challenges include improving the efficiency by which a solar cell converts sunlight to electricity and making solar energy cheaper. Of course, solar cells produce electricity only during the day, so, storing the electricity efficiently for use during nighttime is another important challenge.
Advancements in solar technologies present the potential to power our lives if we just leave it to the sun!