What Is Solar Power - an Enlightening Guide

2022-11-10 | By Kitronik Maker

License: See Original Project

Courtesy of Kitronik

Guide by Kitronik Maker

The sun provides a huge potential source of energy for our planet. Average solar ‎energy falling on the planet is around 1300 W/m2. This is roughly the equivalent ‎energy to that used by an electric kettle. Whilst the light the sun provides is really ‎useful for seeing and helping plants to grow, it is not that useful for powering our ‎modern society.‎

Solar Panels can help here – a solar panel converts light into electricity, which can ‎then be used to power many things. This guide assumes a basic knowledge of ‎electricity.‎

You can download a PDF of this guide here.‎‎ ‎

Solar History:‎

Solar Cells have been around for over 130 years! Solar cells generate electricity by ‎absorbing the energy from light and using this to push electrons along the wires. ‎This is called the photovoltaic effect, which was first demonstrated in 1839 by ‎Edmond Becquerel.‎

Charles Frits built the first practical solar cell in 1884, using a thin covering of gold ‎leaf over selenium. It was not very efficient, converting around 1% of the light ‎energy to electricity, but it was a revelation at the time, with Frits stating that it ‎produced a current “that is continuous, constant, and of considerable force".‎

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Figure 1 The first Solar Panel Installation – 1884‎

The development of the solar cell did not really take off until the beginning of the ‎semiconductor industry. Transistors, and modern solar cells, both rely on the P-N ‎Junction that can be created in a semiconductor.‎‎ ‎

What is a Semiconductor?‎

Just as metals conduct electricity, and are called conductors, and insulators, such ‎as plastics, do not, there are a few elements which conduct electricity only partially, ‎or only under certain circumstances.‎

These elements are called semiconductors. Silicon, Germanium, and Selenium are ‎semiconductors. The properties of a semiconductor, such as how it conducts, can ‎be altered by adding small amounts of other elements. This is called ‘Doping’ and ‎changes the semiconductor to P-Type (where there are more spaces electrons can ‎flow into) or N-Type (where there are more electrons than normal).‎

A lot of modern semiconductor devices, such as diodes, transistors, and solar ‎panels, rely on a property of semiconductors which occurs when a P-type and an ‎N-type semiconductor are joined. The PN Junction which is formed can be thought ‎of as like a cliff – electrons can travel from the high side over the cliff to the low ‎side but cannot get from the low side back up. This property is why a diode will ‎only conduct in 1 direction.‎‎ ‎

Modern Solar Cells:‎

The modern solar cell was patented in 1946 by Russell Ohl (US Patent 2,402,662) ‎following work on semiconductor impurities and his discovery of the PN junction (in ‎‎1939). Solar cells can be made from most semiconductors, but the most common ‎currently used is silicon. This is because it has a good price/performance trade off. ‎Gallium Arsenide is used for higher performance solar cells but is also higher cost.‎

The circuit diagram of a solar cell:‎

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Figure 2 Solar Cell circuit symbol

Combines elements of the circuit symbol for a battery, and the circuit symbol for a ‎light sensitive device. When light hits the junction, the absorption of its energy ‎liberates electrons, and these can flow to produce a current in a circuit. Diodes and ‎transistors (both contain P-N junctions) are sensitive to light, hence most ‎electronic components are packaged into light proof ‘chips’ as we want to keep the ‎light out to prevent spurious operation.‎

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Figure 3 Raspberry PI – showing light sensitive component

The Raspberry Pi nicely illustrates this: The model 2 used a WL-CSP packaged ‎chip (U16 in Figure 3), which has an exposed silicon die. This chip is designed for ‎minimum size, and is usually used inside mobile phones, which have a light tight ‎outer case. This chip was found to be sensitive to certain light sources, causing ‎the Pi to crash. (See References)‎‎

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Figure 4 Single solar cells

A single silicon solar cell typically generates a maximum of about 0.6V, and only a ‎small amount of current, which is not sufficient to power many devices. So solar ‎cells are connected together (Figure 4) to create move useful voltages (such as 5V ‎for a USB power pack).‎

The calculator in Figure 5 has 4 solar cells in its solar panel, which generate ‎approximately 1.5V to power it.‎

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Figure 5 A solar powered calculator

Multiple solar cells are called a solar panel and can come in many configurations of ‎series and parallel connections to produce the required output voltage and current ‎capacities. Often people refer to Panel and Cell interchangeably.‎‎ ‎

Using Solar Panels:‎

Modern solar cells have efficiencies ranging from around 10% to nearly 50%. A ‎typical silicon cell has an average efficiency of about 20%. Solar cells only ‎generate electricity when light is shining on them. It is common to store the energy ‎generated so that it can be used when there is no light. When they are in the dark ‎then no energy is generated, and due to leakage within the solar cell they can ‎actually consume energy from an attached storage device (such as a battery or ‎capacitor).‎

The Kitronik Solar Torch (2175) stores its energy in a pair of capacitors. Its circuit ‎diagram is shown in Figure 6. The capacitors (C1 and C2) are charged by the solar ‎cell, and then that energy can be used to light the LED. To prevent the solar cell ‎‎‘wasting’ the stored energy, there is a Schottky blocking diode in the circuit (D1). ‎Schottky diodes have a low voltage drop, which means that less of the solar ‎energy is wasted, and they are common in renewable power electronics.‎

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Figure 6 Solar Powered Torch schematic Conclusions

Solar power has been around for a very long time, but it has only been of practical ‎use since the invention of the semiconductor. Modern solar panels consist of a ‎number of solar cells connected together to provide the required power output. ‎Development in solar panels means that the efficiency is now up from around 1% to ‎nearly 50% in the best cases, and the cost of generated electricity from solar cells ‎is falling. Whilst solar cells only generate when exposed to light, it is possible to ‎store that energy and use it later, for instance in a torch.‎‎ ‎‎

You can download a PDF of this guide here.‎‎

‎Images used in this document sourced from:‎

Main Image: andreas160578 from Pixabay
Figure 1: Charles frits first_solar_array-charles_fritts.jpg (800×608) (si-‎cdn.com) Viewed 11 Dec 2020
Figure 2: Solar Cell circuit symbol by Kitronik
Figure 3: Photo of Raspberry PI by Kitronik, Illustrates Raspberry PI Blog -‎‎ https://www.raspberrypi.org/blog/xenon-death-flash-a-free-physics-lesson
Figure 4: Photo of single solar cells. Wikipedia Solar cell - Solar cell - ‎Wikipedia Viewed 16th Dec 2020‎
Figure 5: Photo of solar powered calculator by Kitronik
Figure 6: Solar Powered Torch schematic by Kitronik‎

‎By

David Sanderson,

‎MEng (hons) DIS, CEng MIMarEST

Technical Director at Kitronik‎ ‎‎

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