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Top 3 Safety Hazards to Avoid for PV Solar Installations

Fluke has announced the top three electrical hazards to avoid when installing and maintaining PV solar installations to keep technicians safe. Renewable energy is one of the fastest growing markets in the world – in the UK, solar installations have doubled within the last year and are expected to double again by 2030.

Such rapid expansion is accelerating the search for ways to reduce risks associated with commissioning and installing photovoltaic (PV) systems. The resulting demand for highly accurate hand-held devices capable of carrying out safe and reliable measurements in these applications has now been met with the introduction of the world’s first CAT III 1500 V true-RMS solar clamp meter – the Fluke 393 FC.

In PV applications current is “wild” and not limited by electronics, therefore choosing the correct solar testing equipment is vital if workers – and the PV system itself – are to be protected against a range of potential electrical hazards.

The Fluke 393 FC helps to protect against the three main electrical hazards – shock or electrocution from energised conductors, arc faults that spark fires and arc flash that leads to explosions. Control measures and best practices that can mitigate these risks are different when working with PV to working with any other kind of energy generating resource. That’s why it’s important that multimeters, test leads and fuses are rated for the application being worked on.

Shock or electrocution from energised conductors can happen when current takes an unintended path through a human body, with lethal results from as little as 50 milliamps (mA) hitting the heart. Electrical shocks are typically caused by faulty insulation of cables and wiring, damaged insulation of safety covers or improper grounding. The main places such conditions exist in a PV system are the combiner box, the equipment grounding conductor, the PV source and output circuit conductors.

Electrical arc faults that spark fires are high power discharges of electricity between two or more conductors, with the discharge causing heat that can lead to the deterioration or even the burning of wiring insulation. PV systems are particularly vulnerable to arc faults caused by disruption in conductor continuity or by unexpected current between two conductors, often the result of a ground fault.

Arc flash is a phenomenon of large-scale PV arrays that have medium-to-high voltage levels. Only since large-scale solar energy systems have been created has arc flash become a DC issue, which is why arc flash hazard risk analysis must now be carried out on DC systems over 120V. The issue is particularly prevalent when fault-checking in energised combiner boxes, where PV source circuits are used in parallel to increase current, or when carrying out checks on medium-to-high voltage switchgear and transformers. An arc flash happens when there’s a significant level of energy available to an arc fault in DC and AC conductors.

The flash emits hot gases and radiant energy that can be around 19,500°C (or four times the temperature of the surface of the sun). The most at-risk set-ups are residential inverters with input voltage up to 500V and large-scale inverters with up to 1500V. It’s essential to use a meter that’s rated for the relevant measurement category or CAT rating as well as the application’s voltage level. This is so the unit can cope with average voltage levels and high voltage spikes and transients that are capable of producing shocks or causing an arc flash.

Most major manufacturers of inverters and solar modules are shifting from 1000V systems to 1500V for greater efficiency. For solar installations, overvoltage category CAT III 1500V systems are being more widely used and CAT III and CAT IV equipment is essential for PV systems at high altitudes. Only the Fluke 393 FC True-RMS Solar Clamp Meter matches the insulation demands of such CAT III environments.

The meter is designed specifically for use by PV installation technicians and maintenance specialists who work in high voltage DC environments. The clamp can measure up to 1500V DC, 100 V AC, DC power and current up to 999.9A DC or AC through the thin jaw which is ideal for the kind of cramped spaces found in combiner boxes or inverters. Other key features of the clamp, which has a three-year warranty and is IP54 rated (making it well suited to work outdoors), include an audio polarity indicator that helps to prevent accidental miswires by ensuring PV panels are installed correctly.

Polarity functions and audible and visual polarity checks are crucial when commissioning a new site, whether at the combiner box level or inverter level. With a DC polarity check, it’s easy to spot if polarity of strings has been reversed accidentally, avoiding the risk of fires at the combiner box as well as damage to the equipment and danger to personnel.

All test results are logged and reported via the Fluke Connect software that comes with the Fluke 393 FC true-RMS Solar Clamp Meter. Using just a phone, engineers can make and save measurements quickly, with the phone recording for 10 minutes and reporting readings to colleagues. Capable of measuring and recording up to two weeks, this safe, reliable and rugged meter also comes with an 18in iFlex flexible current probe for extended AC current measurements up to 2500amps. Test leads are also rated to CAT III 1500V DC.

Hans-Dieter Schuessele, Application and Technology Expert EMEA, Fluke said: “Safety is essential when commissioning and installing PV systems. The future of power needs tools that are able to keep you safe in harsh environments – risk is not an option and you literally have to trust your meter with your life. That’s why the world’s first CAT III 1500 V true-RMS clamp meter has been designed to deliver enhanced protection for users in challenging CAT III environments. It’s very important that there’s a solid meter with multiple functions capable of operating at that rating – the solar industry desperately needs a solution like the Fluke 393 FC.”

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