PV system installation and maintenance
Engineers should know the basics of photovoltaic system selection, specification, and testing to provide clients with the safest product.
By Jack Smith, Contributing Editor
Late on a Sunday afternoon, the Kern County Fire Department responded to a call it received about a commercial structure fire at a store on Rosedale Highway in Bakersfield, Calif. Crews found that a row of solar panels on the roof had caught fire. Some of the panels were still live when the crew arrived, so the fire crew had to take extra precautions until electrical power could be disconnected.
Fortunately, the crews quickly extinguished the fire, which didn’t penetrate the roof’s metal decking. Officials cleared the store, which reopened about four hours after the call. The lesson to be learned from this example is not that solar energy is unsafe or dangerous; it is to raise safety awareness when working with photovoltaic (PV) arrays and systems. While firefighters and first responders need to know how to safely disconnect electricity to ensure emergency personnel’s safety and to allow egress, facility maintenance technicians need to know how to keep the electricity flowing safely and reliably.
Typical PV system configurations
A typical commercial PV cell with a surface area of 25 sq in. produces about 2 W of power under peak sunlight conditions. If sunlight intensity is 40% of peak, the cell produces about 0.8 W. To become useful as an electrical energy source, PV cells must be connected in series and/or parallel circuit configurations to produce higher voltages and current. Wiring modules in series to produce “strings” increases voltage; wiring the strings together in parallel increases current. An array of 30 135 W rated modules can produce 4 kW.
Manufacturers combine PV cell circuits in sealed environmentally protective laminate to construct PV modules—the fundamental building blocks of PV generating systems. PV panels include several PV modules assembled and pre-wired to be field-installable. A PV array is a complete power-generating unit, which can include any number of PV modules and panels.
PV systems can provide supplemental power source for homes, businesses, municipalities, military installations, or anyone willing to make the commitment and investment. PV can be the primary power source for remote systems; for example, in pipeline-type process industries as well as in temporary field-work situations. While most of the information in this article applies to both residential and commercial PV installations, the primary focus is on commercial. Usually, residential systems differ only in size. Operating principles and configurations are very similar. Commercial systems tend to be more complex, but this isn’t always the case.
PV arrays can be placed on the roof of a facility—as with the store in Bakersfield— or on land adjacent to the facility. Typically, solar arrays require around 3 to 5 acres/MW. Roof and building-mounted arrays maximize the total sunlight-collection footprint available for a site. However, the potential for roof penetrations and roof loading as well as their consequences should be considered.
The conceptual basis for nearly every useful solar energy installation starts with the PV panels collecting sunlight. The PV array supplies dc voltage to an inverter, which converts the dc into 60 Hz ac. The ac from the inverter supplies energy to the facility or home (see Figure 1).
Obviously, some important elements are missing to make this example system useful and safe. Depending on the facility requirements, a system can also include any number of dc switching and protection devices, such as dc combiner boxes, circuit breakers, disconnect switches, and contactors. (A combiner box is a junction box used as the parallel connection point for two or more circuits.) Inverters are available in many configurations and power ranges. Some large installations employ several inverters. A “real-world” system also includes ac switching and protection devices such as ac panelboards and switchboards, disconnect switches, circuit breakers, low- and medium-voltage switchgear, and low- and medium-voltage transformers. Some installations may also have batteries, automatic transfer switching units, monitoring and metering equipment, and devices that allow electricity to be back-fed to the grid.
Functional and operational requirements, component configurations, and how the equipment connects to other power sources and electrical loads determine PV power system classifications. The two main classifications are grid-connected (or utility-interactive) systems and stand-alone systems. Grid-connected systems operate while interconnected with the utility grid. Besides the PV array itself, the main component in a grid-connected system is the inverter. The PV system, specifically the inverter, interfaces bi-directionally with the electric utility network, typically at an on-site distribution panel or service entrance.
Stand-alone PV systems operate independent of the utility grid. Facilities that use a stand-alone PV system typically use batteries for energy storage. Batteries store energy from the PV array during the day and provide energy to the electrical loads during the night or on cloudy days. Batteries also help stabilize system voltage and supply surge current to electrical loads if necessary. Typically, battery-charging controllers protect batteries from overcharging and overdischarging.
How PV systems are different
The obvious difference between PV electrical systems and utility-supplied electricity is that PV arrays generate dc. The electricity generated does not become ac until it is processed by the inverter. Some of a PV installation is necessarily dc, which requires different types of components from ac installations. Components in PV systems that are not found in ac systems include combiner boxes and dc-disconnect switches.
Solar combiner boxes aggregate the dc power from the PV array, and provide overcurrent protection according to National Electrical Code (NEC) requirements. Individual inputs connect to fuse holders. The load sides of the fuse holders connect together to form a common bus, which connects to the output lugs. Combiner boxes are either source combiners or array combiners. Source combiners are located closer to the PV panels. Array combiners—or re-combiners—aggregate outputs from several source combiners into a single circuit and are found in large installations. Array combiners have higher input fuse holders and higher output current.
Typically, PV systems generate voltage in the 400 to 600 Vdc range, a much higher voltage than found in most building systems. Combining this higher voltage with the lack of a current sine wave with zero-crossings creates several system design, component, and wiring challenges—particularly when switching these dc circuits on and off. Compared to ac systems with a zero-crossing current sine wave, interrupting higher voltage dc circuits requires an increased air gap to safely and quickly interrupt and break the arc. Wiring multiple poles of a single switch in series creates the increased air gap for safe arc interruption.
Since dc circuits consist of two wires—a positive and a negative—one of them must serve as ground in most PV systems, like the neutral in an ac system. The solar panel manufacturer specifies which of these two wires is grounded. Negative grounding is the more common configuration. This bond is usually made at the inverter. According to the NEC, only the current-carrying ungrounded conductor shall be switched.
Potential PV problems
Most PV systems that are installed by qualified and reputable professionals are installed safely and reliably. However, having a PV electric power system installed by untrained persons can lead to trouble. Some of the common problems associated with the design, installation, and operation of PV systems include:
- Extensive shading of the PV array
- Insecure structural attachment to rooftops and other structures
- Inadequate weather sealing for roof and other penetrations
- Unsafe wiring
- Unsafe battery installation or improper battery maintenance or use
- Insufficient conductor ampacity and/or insulation type
- Using unlisted equipment
- Improperly applying listed or unlisted equipment
- Improper placement of overcurrent protection and disconnect devices
- Improper system grounding
- Inadequate labeling on major system components and disconnect devices
- Inadequate documentation on system design and operating and maintenance requirements
- Inadequate environmental protection for certain system components.
Testing and troubleshooting
Any PV system design package must include supporting documentation, which should—at a minimum—include system specifications, electrical schematics, mechanical drawings, parts lists, materials lists, and source lists. Documentation should also include installation and checkout procedures, user and operator training, maintenance requirements, troubleshooting guides, and a list of the specific tools and equipment required to perform these tasks.
Maintenance requirements for PV installations depend on the type of system design and equipment used. Some installations require very little attention, perhaps just annual inspections. Others—especially those with batteries—may require maintenance intervals of four to six months, or even component (usually battery) replacements over the system’s lifetime. Typical maintenance items that PV installations may require include:
- Inspecting wiring connections and terminations for looseness and corrosion
- Inspecting wiring harnesses to ensure they are neatly bundled and protected
- Inspecting the PV array for cleanliness, absence of damage, and structural integrity
- Inspecting roof penetrations and weather sealing
- Maintaining batteries, which may include cleaning, adding electrolyte, charge equalization, and replacement if needed.
Regardless of whether you are installing or maintaining a PV system, use the appropriate tools for the task. Typically, you can perform most tasks that involve the PV modules and their associated dc
circuits with a high-quality digital multimeter (DMM) with an amp clamp or a clamp meter with voltage-measurement capabilities.
Being aware of potential problems, and testing and troubleshooting with tools suitable for the task at hand, will help you get—and keep—a PV system running safely and reliably.
Smith is a technical writer and editor based in North Aurora, Ill. He is also a Pure Power contributing editor.
PV installation standards and certification
In most cases, the applicable standard for photovoltaic (PV) systems is the National Electrical Code (NEC). Article 690 of the NEC deals specifically with PV system installations, covering wiring methods, overcurrent protection and disconnect provisions, grounding, and other issues. Generally, PV system installations must be inspected according to NEC requirements, and inspectors generally check that listed equipment is used. Underwriter’s Laboratories (UL) is one of a few organizations that provide safety listings for PV equipment. The Institute of Electrical and Electronics Engineers (IEEE) has published a number of standards, recommended practices, and guidelines for PV systems and equipment, including IEEE 929, which outlines the basic operational and safety requirements for grid-connected PV systems.
The North American Board of Certified Energy Practitioners (NABCEP) offers certifications and certificate programs geared toward renewable energy professionals throughout North America, including a certification program for solar electric installers. As of May 2009, 710 individuals have passed the NABCEP PV installer certification exam. The complete listing of NABCEP-certified solar PV installers can be viewed on the organization’s website.
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