On this page you will find answers to some of the most important questions about the workings of the solar farm.
The property that enables work to be performed; for example a) an object that is moving has kinetic energy and can do work as it slows down; b) thermal energy can be converted to work in a rocket engine; c) an electromagnetic field possesses energy that can be converted to electrical work. Energy can only be transformed from one form to another; the total amount of energy is conserved.
The efficiency tells us how much useful energy we are able to use from the total energy collected. The better the efficiency is the less energy we need to collect. A smaller if more efficient solar farm can provide the energy required, but a balance between efficiency and cost is needed.
When light is shone on a material the energy from the waves (photons) is given up to electrons in the material. Given enough energy the electrons can escape the binding of the atoms of the material and become free to move. If connected up correctly these electrons can then become repsonsible for an electrical current flowing. The result is the conversion of sunlight into electricity.
A photovoltaic panel, or solar panel, is made up of an array of solar cells; many solar panels together comprise a solar farm. Solar cells convert the sunlight into electricity via the photovoltaic effect.
To conduct electricity a material must allow a current to flow. Metals have electrons that are free to move about their structure. These electrons are the charged particles, which when moving in the same direction, produce a current.
Both of these materials do not have any charged particles which are free to move. Therefore, no current is able to flow so they insulate against electricity.
Direct current (DC) is when the current only flow is one direction. Alternating current (AC) is when the current changes direction periodically, with a frequency that is often 50 times per second for many mains electricity supplies. Photovoltaic cells produce a direct current used to charge batteries. Batteries always produce a direct current.
Cables carrying low voltage DC are subject to higher losses in energy relative to those carrying high voltage AC AC. By keeping cables carrying low voltage DC as short as possible, the energy losses due to resistance are minimised and the best efficiency of a circuit is achieved.
The energy losses in a circuit are related to the resistance of the cables. The larger the diameter of the cables carrying the current, the lower the resistance, and the more efficient the circuit is.
Many solar farms are designed to work at either 12V or 24V or even 48V. Working at a higher voltage requires thinner cables because less current is required to deliver the same power. Both 12V and 24V systems are relatively cheap to put together because of the wide range of devices available at these voltages from the automotive industry. The optimal choice for us was 24V.
We use voltage regulators to govern the electricity supply from our batteries to ensure that each device we are powering receives exactly the right voltage it was designed to run at. For example, many of our astronomical cameras run a 12V, many communications devices run at 5V whereas the mount that enables the telescope to slew and track is 48V. We use 24V-12V, 24V-5V and 24V-48V voltage converters to accomplish this.
A battery is a store of chemical energy which can be changed into electricity when connected in a circuit. Chemical reaction within the battery cause negatively charged electrons at one terminal to be attracted through the external circuit to the other terminal producing a current. The negatively charged electrons are then attracted to the positive end. But the two sides are separated internally; therefore, the electrons are forced to flow around an externally connected circuit producing a current.
If just a low resistance cable were to be used - with no other circuit components - we get what's known as a short circuit. A very high current will flow, discharging the battery quickly and producing lots of heat at the same time which can be very dangerous and possibly cause a fire. Fuses are often used to break the circuit safely should a high current begin to flow.
If a battery is allowed to become too discharged, then sulphate crystals will form at the negative end of the battery - a product from electrochemical reactions when discharging - grow and harden, eventually becoming impossible to reverse through charging. Additionally, some of the active material (substances used in the chemical reactions) can fall off the plates within the battery when the battery is deeply discharged, and drop to the bottom of the battery case. This decreases the amount of available chemicals for producing electricity; and eventually, when enough of these chemicals build up, they can short circuit the battery and destroy it.
Just milliamps of current from a high voltage (>50V) can cause harm to the body because our central nervous systems have their own finely balanced electrical circuitry. However, low voltage (<50V) is less dangerous but no terminal should ever be touched. In addition, cables that are too thin for the current that they have to carry can overheat and lead to fires.
A fuse is a small device that interrupts the circuit if a dangerously high current were to start flowing. The use of fuses mean that if a piece of equipment fails and the current in the circuit becomes too high, the fuse will "blow" and break the circuit, thus preventing the situation becoming worse.
A low resistance connection to the earth, ensuring the safe dissipation of any unwanted and dangerous charge build up.
Colour coding allows electricians to keep track of whether a cable is positive or negative - it is very important to only connect cables the correct way around otherwise a dangerous short circuit and electrical fire could follow.
Water conducts electricty, just as a metal does, raising the risk of a short circuit, and electrocution. All of our cables that are outside weatherproof buildings are contained inside rugged, waterproof, insulating protection that will survive rain and wildlife.