The electrical arc and the risk of fires in photovoltaic systems

Fire in photovoltaic plants result in property losses, loss of power generation, construction damage and people and can spread to the surrounding environment, resulting in a series of secondary disasters.

DC arc is the most common failure phenomenon in photovoltaic plants. They can occur due to poor contacts, aging of components, insulation breakdown or poor grounding.

Furthermore, DC arc damage is much greater than AC arc damage, because there is no zero crossing point on the DC arc. Once it occurs, it continues to burn, is difficult to extinguish and is very easy to cause fire accidents.

According to statistics, more than half of fire accidents in photovoltaic plants are caused by DC arcs. As the specifications of photovoltaic modules become higher, the system power and current on the DC side increase.

According to Joule's law Q=I²Rt, the current doubles and the thermal effect of the short-circuit point increases four times, thus the risk of causing a fire also increases.

DC arc rating

Unlike traditional electrical products, there is no integral enclosure for PV modules and their wiring to contain arcing and sparks caused by component and wiring failures, while many PV installations are able to operate at the typical DC voltages that sustain DC arcs.

There are three main categories of arcs in photovoltaic installations:

• Series arcs can be caused by incorrect wiring or broken series wiring;
• Parallel arcs can be caused by partial short circuits between adjacent lines of different potentials;
• Ground arcs due to insulation failure.

Series arc

Series arcs are generally caused by poor contact of cable plugs between components and poor connection between string cables and combination boxes or inverters.

Due to the large number of connectors in series in the photovoltaic plant, there are about 2 thousand pairs of connectors in a 1 MW photovoltaic plant, for example. It is difficult to guarantee that all connectors are of good quality and compatible in 100% of the projects. These hazards can lead to poor contacts and the formation of DC arcs.

Currently, some inverters integrate arc protection function, but there are two major problems with this protection:

• If there is an arc fault in a string, the entire inverter will shut down, causing extensive damage;
• Without the arc fault location function, operation and maintenance personnel cannot find the location of the arc in time and accurately, which is essentially not a solution.

Parallel arc

Parallel arcs are mainly caused by short circuit of positive and negative conductors caused by line damage or short circuit between string cables. When string cables are squeezed or mechanically worn, arcing occurs between the positive and negative electrodes, or between different strings, which is a parallel arc fault.

There is another situation that can also lead to parallel arcs, which is when the series arcs in the system are not treated in time and the heat from the series arcs burns the cable insulation and generates parallel arcs. When a parallel arc occurs between the main conductors, once the arc can obtain sufficient energy, it is more difficult to extinguish, which will cause a large fire accident.

The series arc can be extinguished by disconnecting the DC bus or corresponding string from the photovoltaic system, but the parallel fault arc cannot be extinguished and may even cause a larger current to pass through the arc path, making the arc more intense.

Currently, the arc protection function integrated in the inverter cannot detect parallel arcs and ground arcs, but the destructive power of parallel arcs is 10 times that of series arcs, and the safety risk is even greater.

Earth arc

Aging and component defects or mechanical damage lead to discharge to the ground. If components are placed improperly on metal tiles, earth arcs or leaks will occur.

This type of fault is not easy to discover, especially on rainy days. Currently, the solution is to turn off the inverter and wait for the soil to dry before turning it on. This method does not effectively eliminate hazards and increases the risk of personal electrical shock.

DC high voltage

In a photovoltaic plant, photovoltaic modules are connected in series to form a high DC voltage circuit, with voltages that can exceed 1000 V. Even when the system is turned off, there is still a high DC voltage of around 1000 V in the circuit. photovoltaic modules.

Especially for rooftop photovoltaic plants, when a fire occurs in photovoltaic systems and buildings, it is difficult to safely rescue; During routine plant operation and maintenance or property maintenance, operators and inspectors are also at risk of electrical shock.

Products in the solar energy market

Several brands offer solutions that aim to minimize the risk of arcs in photovoltaic installations. Among them, the manufacturer BENY. The company has string-level and module-level rapid shutdown devices that control panel voltages to a certain safe level in microseconds. These devices allow you to prevent accidents and improve the safety of the solar energy system.

To the quick shutdown solutions (RSD – rapid shutdown) from the BENY are designed according to CE, TUV, UL standard, comply with the laws and regulations of various countries, such as Thai Electrical Code, NEC2020. As a member of the Sunspec alliance, BENY develops PLC communication RSDs (Power Line Communication) for greater compliance with multiple string inverters.