Solar Power Batteries, Charge Controllers And Solar Inverters

SCI219-Discussion on the Solar System

Solar Power Batteries

A solar power battery is a simple battery which would be charged with energy gained from solar panels. Solar power batteries are those devices, which are capable of producing and store the DC electricity. Solar electric systems commonly make use of batteries that are used as substitutes of solar panels during night or cloudy days. In such cases, the electricity which is needed could be easily drawn from batteries instead of getting it from the solar array. The solar array cannot act as a generator because of insufficient sunlight (Budischak et al., 2013).

Solar panel systems have emerged as the fastest growing energy sources in several countries. The battery is not a vital part of a photovoltaic system. Whenever a solar electric system is connected with the utility grid, it does not comprise of a battery system. A backup of power is always needed for certain electric devices (Singh, 2013). Most of the solar electric systems, which are disconnected from the utility grid possess batteries and charge controllers. These are the kind of devices who manage the charging and discharging capacity of the battery. In a solar system, the batteries are typically connected and combined in a battery in order to get the required capacity and voltage.

A battery comprises of cells that could be either dry or wet. The wet cell batteries are mostly common than the dry cells which is because of the efficiency of the cost, reliability and higher efficiency of performance. Irrespective of the kind of battery used in a solar system, the cost of a solar battery is a considerable part of the cost of the entire solar system. A solar power battery which would have a lesser capacity would not be able to the daily needs of energy. Hence the entire solar system would become useless. On the other hand, if a battery possesses higher capacity, the cost of the solar system would increase but it would also severely degrade the performance of the solar system (Zweibel, 2013). 

The working of solar power batteries is based on the conversion of AC energy that would be produced by the solar panels and storing the energy in the form of DC power. In some cases, the solar batteries possess their own inverter that would offer integrated conversion of energy. Depending on the capacity of the solar power battery, the battery could charge the larger amount of the solar system (Hoppmann, 2014).

Charge Controllers of the Solar System

A solar charge controller or solar charge regulator is a voltage or current regulator, which are kept in order to control the batteries from being overcharged. The charge controller helps in regulating the voltage and keeps a check on the incoming current from the solar panels that are entering the solar power battery. The solar charge controller manages the ongoing power into the battery from the solar array. The charge controller keeps a check that the solar power batteries do not get overcharged during the time of the day. It also ensures that the power should not run backwards to the solar panels during the time of the night, which would completely drain the batteries. Some of the solar charge controllers are provided with supplementary proficiencies such as load and lightning control but the primary job of the charge controllers is to manage the charge (Bhoye & Sharma, 2014).

There are two different technologies of a solar charge controller. These are Pulse Width Modulation (PWM) and Maximum Power Point Tracking (MPPT). These two types of charge controllers are very much different from each other. The MPPT solar charge controller is much more expensive than the PWM solar charge controller (Thygesen & Karlsson, 2014).

The Pulse Width Modulation (PWM) is the traditional kind of solar charge controller, which are currently the standard of the industry. These kind of charge controllers establishes a connection from the solar panel to the battery. When there is a regular connection from the solar panel to the battery bank, the voltage of the output of the array is brought down to the voltage of the battery. The PWM solar charge controller is good solution at lower cost for the use in smaller systems. The PWM solutions can perform at a temperature which would range from moderate to high (Kazimierczuk, 2015).

The Maximum Power Point Tracking (MPPT) is a recent form of solar charge controller, which is majorly used in the recent times. The solar charge controller would measure the Vmp voltage of the solar panel and then converts the PV voltage to the voltage of the battery (Harish & Prasad, 2013). The MPPT charge controller is the main suitable choice for their use in higher systems of power. The MPPT charge controller would also be able to function when the temperature of the solar cell would range from low to very high temperature conditions (Subudhi & Pradhan, 2013). 

Basic Features of the Solar Charge Controller

Basic Features of the Solar Charge Controller

There are many features of the solar charge controller. These are mentioned as follows:

• The solar charge controller helps in protecting the battery from excess charging
• The charge controller also reduces the maintenance of the system and thus increases the lifetime of the battery.
• The solar charge controller also provides an auto charging indication.
• The reliability of the solar charge controller is high.
• The solar charge controller requires about 10 amp to 40 amp of current for the charging.
• The charge controller also monitors the reverse flow of current (Osman, Rahim & Selvaraj, 2013).

Function of the Solar Charge Controller

The basic function of the solar charge controller is to keep a control of the voltage of the device and thus opens the circuit and halts the charge when the voltage of the battery rises to a certain level. Many of the solar charge controllers utilize a mechanical form of relay in order to open or close the circuit. They can also halt or begin the heading of electric power to the electric storage devices.

In general, solar power systems make use of 12V batteries. The solar panels is capable of transmitting much voltage, which is indulged for charging the battery. The charging voltage of the solar charge controller are normally kept at a higher level and the complete charging time of the battery is reduced. This technique allows the solar systems to work constantly in an optimum way. When higher voltage is passed through the wires from the solar panels to the solar charge controllers, the dissipation of power in the wires is reduced (Traube et al., 2013).

The reverse flow of power could be also controlled with the help of the solar charge controllers. The solar charge controllers are also responsible for distinguishing when no power would be originating from the solar panels. This would also open the circuits, which separate the solar panels from the solar power batteries thus halting the reverse flow of electric current.

Applications of Solar Charge Controllers

In the recent times, the entire process of the generation of electricity from sunlight has gained much popularity than other sources. The photovoltaic panels are completely free of pollution and also they do not require high level of maintenance.

Examples of the utilization of the solar charge controller are:

• The street lights make use of photovoltaic cells in order to convert the energy of the sunlight into electric charge. The entire solar system makes use of solar charge controller in order to store the charge in the solar power batteries, which has several uses in various areas.
• Hybrid solar systems also makes use of multiple sources of energy in order to provide full time supply of backup to various other sources.
• Various systems in home uses PV module for their application in household items (Badawy et al., 2014).

Inverters plays a major role in the use of electric systems in case of a power loss scenario. The basic function of an inverter is to invert the output of the direct current (DC) into alternating current (AC). The AC is the standard which is used by every commercial appliances. Hence the inverter is viewed as the main gateway between the photovoltaic system and the taker of energy. They also help in the monitoring of the data, advanced controls of utility and system design engineering. The manufacturers of inverter are capable of providing post-installation services, which are essential to maintain the production of energy and a high performance level for the project. It also includes preventive measures, operational and management services and a quick time of repair (Schwarzer, Buschhorn & Vogel, 2014).

Function of the Solar Charge Controller

A solar inverter or a converter is capable of converting the variable direct current (DC) output of a photovoltaic solar panel into a utility based frequency AC, which could be used and fed into a commercial grid of electricity. The solar power inverters possess special designed functions that are capable of adapting their usage with photovoltaic arrays (Carrasco et al., 2013). This includes MPPT and protection of anti-islanding. The solar power inverter is an important device in any system of solar power. The converted AC power is being used mainly for the running of different home based appliances such as refrigerator, microwave, television and many others. In general, the power required for the solar power system is being mainly used for the loads of AC power (Xavier et al., 2017).

Different Types of Solar Inverters     

There are a number of solar inverters, which are used in the market in the recent times. These are mentioned as follows:

off-Grid Inverters

These kind of inverter systems are mainly used in the remote power systems in which the solar inverter is being fed by DC power from a panel of battery. The battery panel can be charged with the help of solar panels. These kind of inverters have combined the battery chargers that could be used to increase the battery obtained from an AC source of power. 

Grid Tie Inverters

Solar Inverters that are associated with the power grid can be also called as a grid tie inverter. These kind of inverters feed the electric power by their corresponding phase and frequency. The frequency of the power might range from 50Hz in countries like India and 60Hz in North America to the power of output. These also possess the effectiveness that is supplied by the AC power. The grid tie inverters are specifically designed in order to shut down itself whenever the system senses that a loss of supply has been encountered from the power utility.

Battery Backup Inverters

These kind of inverters are specially designed and manufactured in order to pull the energy from a battery source. The battery charge is conserved with the help of the use of an on-board charger and an extra source of energy, which is transferred to the electric grid. These inverters provide the AC power with particular loads during outages of electric power.   

Micro Inverters

These kind of inverters are becoming a modern form in the solar industry. These type of inverters are small and compact in size, portable and hence supports a lot of performance. These may also include the functions and features of any common inverters.

Applications of Solar Charge Controllers

The Working of Solar Inverters

The solar energy that is abstracted from the sun is converted into electrical energy with the help of the photovoltaic cells. The gained energy is being stored in solar power batteries during the time of the day for the purpose of several operations whenever there would be a need (Cao et al., 2013).

Advantages of Solar Inverters  

1. The solar inverters have been a constant support in reducing the effect of the greenhouse gases and the effect of global warming.
2. The use of solar based devices would be extremely helpful in saving money and energy as in the recent times many people have started the use of solar based devices.
3.  As solar inverters help in the conversion of DC power to AC power, hence it would be useful for the people who use a fractional amount of electricity.
4. The solar inverter is cost effective in nature. 

Disadvantages of Solar Inverters

1. The price of a solar inverter is high.
2. Solar inverters would be able to function properly only when there is a substantial amount of electricity.
3. The solar panels, which are used to attract the rays of the sun need a lot of space (Ellabban, Abu-Rub & Blaabjerg, 2014).

Mounting Brackets for the Solar System

The popularity of solar power has risen another renewable technology. The solar power batteries is able to store extra solar power for later use. Many companies are in the process of developing solar batteries, which could be installed with the help of solar panels in order to create “solar-plus storage” systems, which could be used in homes. A solar energy system comprises of solar panels, an equipment to mount the solar panels on the roofs, an inverter and a monitoring system of the performance, which can track the production of electricity. The solar panels are able to capture the light energy from the sun and convert the energy into electricity (Hosenuzzaman et al., 2015). The electricity is then passed within the inverter and then it could be converted into a form, which could be used in home. A majority of the solar energy systems that are connected to the grid of electricity are used for residential purposes. When the solar panels produce more electricity, the excess of the power is fed again to the electric power grid. When a large amount of electricity is needed for residential purposes, then the power could be drawn from the electric grid.

PV Array

Photovoltaic is a term, which is used for the conversion of light energy into electricity. This conversion could be done with the help of semiconducting materials which can exhibit the effect of photovoltaic. A photovoltaic system makes use of the solar panels that comprises of a number of solar cells. The solar cells generate electric power. The installation of photovoltaic systems could be mounted on the ground, roofs or walls. The mount of these systems could be fixed or they could make use of a solar tracker in order to follow the path of the sun across the sky (Eftekharnejad et al., 2013). There are some specific advantages of photovoltaics. Once they are installed, the operation of these cells would not generate any amount of pollution or greenhouse emissions of gas. Photovoltaic systems also have several disadvantages. The output of the power of the cell is mainly dependent on the direct sunlight. Due to this, 10-25% of energy of the sunlight is usually lost if a system of tracking is not used as the cell would not be directly facing the sun at all point of time. There are many other factors that affect the diminishing of the effect of the sunlight such as dust, clouds and many other factors. Another major issue which affects the diminishing power factor is the concentration of the production in the number of hours corresponding to the core insolation.    

Solar Inverters

References  

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