fbpx

Tag: solar

Corrosion on solar panels

Corrosion on solar panels

Corrosion on solar panels. High-quality photovoltaic panels from reputable manufacturers last at least 25 years reliably. However, modules from less well-known manufacturers often fail quickly. This is usually caused by corrosion on the solar cells.

It is commonly believed that the formation of rust is unique to ferrous metals. In practice, this is not the case, as the integrity of the conductive pathways can be not only oxidative, but also electrochemical in nature.

Corrosion on solar panels – causes.

The main problem with any SES is the need to place the modules outdoors. For this reason, the panels and fasteners themselves are constantly exposed to negative environmental influences.

The slightest breach of seal causes moisture to enter the conductive tracks. Metal and water create a classic galvanic element, as a result:

-the moisture begins to act as an electrolyte;
-nearby metals of different types become a cathode/anode pair;
the less electrolytically stable metal begins to lose electrons and -decomposes;
-conductive busbars or fasteners become inoperative.

How to avoid corrosion on solar panels.

To avoid such a scenario, manufacturers use the following techniques:

-Avoid combining metals with significant differences in electrochemical potentials, e.g. aluminium and copper. 
-If it is not possible to use only one material (in welding or threaded joints), the closest pairs in terms of this parameter are selected. This minimises the risk of galvanic reaction.
-Design solutions are created which allow for the use of insulating gaskets at the most risky locations.
-In order to prevent moisture from penetrating the metal, surfaces are painted with water resistant paints. 
-The last method is chrome plating or galvanising steel and anodising aluminium.
Corrosion on solar panels

Advantages of different solar panel corrosion protection coatings.

1. Painting is the simplest and most effective method of protection. It is inexpensive and can be done by the owner of the solar plant himself. It is sufficient to periodically renew the paint layer on the exposed surfaces and the metal structures, which are protected against moisture, will survive the photovoltaic panels for a long time. There are no restrictions on application depending on the material. The recommended coating thickness is at least 1.5-2.0 mm.

2. Anodic oxidation. Used as an anti-corrosion agent for the most electrochemically unstable element, aluminium. To prevent the metal itself from becoming an electron-emitting anode, a surface oxide layer takes on this role. The technology is reliable and sufficiently long-lasting.

3. Galvanising. The frequent use of zinc to prevent corrosion in solar panels can be explained by the fact that it is the lowest in the electrochemical series. Contact with moisture is detrimental to this metal, but it does not affect the layer underneath it. The method is considered ideal because of its versatility, reliability and ease of renewed protection through inexpensive cold galvanizing. The zinc coating thickness is approx. 0.75-0.85 mm in moderate climates, and 1.0-1.2 mm in regions with high humidity and/or aggressive substances.

4. Gaskets made of rubber and polymers. Non-metallic gaskets are used successfully to prevent corrosion in solar panels. They are most often used at the bolt fixing points. The rubber or polymer gasket has the advantage of fulfilling two protective functions simultaneously:

-it ensures a complete watertightness;
-does not compromise the integrity of the joint due to its high elasticity.

5. Other corrosion protection technologies. The most common corrosion prevention technology today for solar panels is frameless modules. They completely eliminate the main vulnerability of the panels – the connection point between the working part of the module and the frame.

This technology is widely used:

In almost all second-generation panels based on rare-earth metals;
100% of third-generation batteries, which are flexible films printed on a 3D printer and filled with a transparent polymer.

INSTAGRAM

Battery cost effective option
How solar panels work

How solar panels work

How solar panels work. Solar panels are already being used to power a wide variety of equipment, from mobile gadgets to electric cars. First used to power space stations more than 40 years ago, solar panels are now firmly established in everyday life as a source of clean, free energy. The sun has always sent and still sends billions of kilowatts of radiant energy to the earth and this source will continue to do so for millions of years to come.

One of the energy sources is a solar panel that generates alternative energy from the sun. It is relatively new, but has already gained popularity in Europe due to its high efficiency and reasonable cost. Solar panel is an almost inexhaustible source of energy, capable of storing and converting light rays into energy and electricity. In Ukraine, a new source of energy is gradually gaining popularity.

How solar panels work. Operating Principle of Solar Cells.

On the principle of solar cells is a constant current photoelectric generator, which uses the effect of converting the rays of energy into electrical energy. More specifically, solar cells utilise the property of semiconductors based on silicon crystals. Quanta of light hitting a semiconductor wafer knock out an electron from the outer orbit of that chemical element’s atom, which creates enough free electrons to generate an electric current. However, one or two silicon elements are not enough for the voltage and power of such a source to be sufficient for household applications.

Therefore, they are assembled into complete panels, where they are connected in parallel or in series. The area of such panels may vary from a few square centimetres to several square metres. By increasing the number of panels, it is possible to achieve a higher power output from a energy solar panel.

How solar panels work

However, the performance of a solar panel depends not only on the area, but also on the intensity of the sunlight and the angle of incidence of the rays. Consequently, the performance of the solar panel depends on the area and geographical latitude where the house is located, on the weather and time of year, and on the time of day. In addition, in order for the solar panel system to work and supply energy to the grid, a number of additional electrical devices must be installed, in particular.

-An inverter that converts direct current to alternating current;
-A rechargeable battery whose role is to store energy and smooth out voltage variations due to changes in light conditions;
-A battery charge controller that prevents the battery from overcharging or discharging prematurely.

All this is called an autonomous power supply system based on solar panels.

How solar panels work. What is the principle of an alternative energy source?

Firstly, the photovoltaic cells are silicon wafers. Silicon, on the other hand, is similar to pure silicon in its chemical composition. It is this nuance that has made it possible to lower the cost of a solar cell and put it on the assembly line already.

It is imperative that silicon is crystallised as it is itself a semiconductor. Monocrystals are much easier to make, but they do not have many facets, due to which the electrons are able to move in a straight line.

It is important to know that the addition of phosphorus or arsenic increases the electrical conductivity. Also one of the important properties of silicon is its invisibility to infrared radiation. Thanks to this element, the converter blocks only absorb the useful parts of the solar spectrum.

Sequence of operation of a solar panel. How solar panels work.

1. the energy of the sun enters the plates.
2. The plates heat up and release electrons.
3. the electrons actively move along the conductors.
4. The conductors give a charge to the batteries.

How solar panels work

The design and operating principle of a power source can be described as simple.

It consists of just two parts: the main body; the converter units. In most cases, the casing is made of plastic. It looks like an ordinary tile, to which the converter units are attached.

The transducer block is a silicon wafer. It can be made in two ways: polycrystalline; monocrystalline. The polycrystalline method is the least expensive and the monocrystalline method is considered the most efficient. All other additional parts (e.g. controllers and inverters), microcircuits are attached only to increase the performance and function of the energy source. Without them, the solar panel will also be able to function.

There are two types of connection: in series; in parallel. The only difference is that the parallel connection increases the current and the series connection increases the voltage. If there is a need to maximise the operation of two parameters at once, parallel-serial is used.

But it is worth bearing in mind that high loads can cause some contacts to burn out. Diodes are used to prevent this. One diode is capable of protecting one quarter of the photocell. If they are not in the device, there is a good chance that the entire energy source will cease to function after the first rain or hurricane.

Like any technical device, a solar panel has its own performance and technical specifications, which differ between models, from different manufacturers, but with a rather small discrepancy. For a solar panel area of approx. 0.2 m², the module output is approx. 10 W. The voltage at maximum load is approx. 25 V. The short-circuit current is approx. 500 µA. The module weighs approx. 2 kg. Typical efficiency of a solar panel is 14 to 18%. The service life of such a plate is at least 25 years

INSTAGRAM

Legal framework for solar panels.

Shopping Cart

No products in the cart.

X