The rapidly developing renewable power generation industry can be compared to an hourglass: Inexhaustible supplies of free resources — sun and wind — are converted into a corresponding outflow of electrical energy at a notable return on investment. But the process includes the neck of the hourglass through which the resources must pass. This is the solar array or wind tower. These assets must be kept diligently functioning at maximum efficiency and safety for the process to yield its anticipated return. This article shares best practices for maintaining the electrical systems of solar and wind assets.
WIND SYSTEMS
Wind towers are particularly at risk because of their great height: 280 ft and getting taller. It is estimated that a tower extending more than 50 ft above surrounding structures becomes a prime lightning target. Lightning interruptions can cause downtime, and the damage isn’t limited to the structure. It can extend down to sensitive control systems, further limiting profitability (Photo 1).
Protecting a system from lightning should be considered as early as site selection and system design. Useful sources of standardization are available in IEC 61024, Protection of Structures against Lightning, and IEC 61400, Wind Energy Generation Systems, Part 24:Lightning Protection.
SOLAR SYSTEMS
Solar panels are at similar lightning risk as wind towers, as they are installed on roofs or in vast open fields where they may be the highest structure in the area.
NFPA 70, National Electric Code (NEC) specifies:
Exposed non-current-carrying metal parts of module frames, equipment, and conductor enclosures shall be grounded.
Every module component, including inverters, combiner boxes, and disconnects must be connected to an equipment grounding conductor (EGC). These converge commonly at the ground busbar inside the main distribution panel. From there, the grounding electrode conductor (GEC) completes the connection to the ground electrode. When removing panels, care must be taken not to disrupt the bonding. For roof mounts, this is often rebar in the foundation that should be supplemented by a ground rod to prevent damage to the concrete during fault clearance. Full requirements are described in NFPA 780, Standard for Lightning Protection Systems; NEC Article 250 Grounding and Bonding; NEC Article 690 Solar Photovoltaic Systems; and UL 96A, Standard for Installation Requirements for Lightning Protection Systems.
Grounding System
The tower and array should be designed, constructed, installed, and maintained according to the highest industry standards. Grounding is an indispensable part of this process. It is easy to become focused on the dynamics, such as the turning of blades or the humming of transformer operation, and overlook the indispensable contribution made by the grounding system. Buried out of sight and not visibly operating, these critical components can be largely ignored until an incident such as a wind tower crashing to the ground.
Don’t wait for such an event to happen. Ensure the system is designed and installed following industry standards and local conditions first — and then is periodically checked and regularly maintained.
It is commonly believed that burying a rod and connecting the electrical system means it is grounded, but that is not necessarily the case. The grounding system must be treated with the same attention and care as any other electrical component.
Grounding Conductor
The other main element of this protection system is the grounding conductor. No matter how good the grounding electrode (rod, grid, or other structure) is, it will be rendered useless without a continuous, low-impedance path to conduct lightning and fault current safely into the soil, avoiding equipment and personnel. This is the job of the grounding conductor. In general applications, it connects the dead frame of equipment to the ground bus at the entrance panel.
The structure is unique in wind generation systems: It spans from the tips of the blades to connect with the ground grid at the base of the tower. The frequency of lightning strikes increases with height, and studies have suggested that rotating blade tips are particularly attractive.
For adequate protection, the grounding conductor must be regularly tested (Photo 2). Turbine manufacturers typically specify 15 mΩ to 30 mΩ for a safe path to ground. A low-resistance ohmmeter is the designated tester for this purpose. Traditionally, these testers use a 10 A test current to reliably assure a sufficiently low-impedance path. These can be bulky, given the physical demands of this testing environment.
Recent improvements in meter technology have made the job easier by introducing handheld 1-A testers with sufficient accuracy and resolution. The most sensitive part of the ground path is through the blade because the stress of motion can cause the grounding conductor to crack. If the two fragments remain in contact, a simple continuity test will still pass. A more robust test current and measurement resolution will unerringly reveal such a break.
But there’s still a unique problem: the distance of the blade tips from the ground. As with handheld testers, technological advances have been realized. Test leads with lengths of 100 m have become available. However, long leads create an additional problem: resistance. A compensation factor allows for power loss in some instruments when using leads of a normal length. Compensation for extra-long leads is accomplished via this formula:
P = I2R
Where:
P = output power of the instrument
I = output current of the instrument.
R = (resistance of load) + (resistance of test leads)
Standard compensation in the average meter can fall short of delivering enough power against the daunting lead resistance that would exist in 100-m leads. Adequate compensation is achieved by reducing test current. Some instruments have a selector switch to reduce current; others do so automatically. Either way, a 1-A test current has proven sufficient to yield accurate and reliable test results. The ohmmeter is thereby enabled to test with milli-ohm resolution without lead resistance entering the measurement.
Remote Earth
The termination of the protection system is the electrode buried in the earth. This must not be taken for granted. The mere fact of its existence is not enough, although it is often thought of in that manner. It must be tested, like any other electrical component. Surge arresters alone are inadequate without a good ground. The goal is low resistance to remote earth — the maximum resistance a fault current or lightning stroke will encounter before being safely dissipated. There is no universal standard, but electrode resistance should be held to 1 Ω to 5 Ω.
Testing and maintenance
Testing is particularly difficult with renewables because a single electrode is not grounding a single network, as in a building. Rather, potentially enormous numbers of wind towers and solar panels are daisy-chained together, and the chain is often growing. The biggest problem is that ground testing requires long leads strung to test probes far out in the soil, with the distances based on multiples of the maximum dimension of the grid or array. This can quickly become prohibitive. There is no simple answer, but one of the worst things to do is to wait to test until the job is done. By that time, the composite electrode could be virtually too big to test.
Plan ahead and test the sections as they are installed. This applies to solar and wind systems, as the issue is the same (Photo 3). Every time a new section is paralleled, resistance will drop significantly, so collectively, by the time the job is done, an adequate ground will be provided. Periodic maintenance must also be performed, and this can be a bigger challenge.
The most widely respected ground electrode test, fall of potential, is likely to require too much space. Be familiar with methods that have been specifically designed to deal with this problem. The most prevalent is the slope method. Another is intersecting curves. Instructions for these methods are commonly available in the literature, such as “Getting Down to Earth: A Practical Guide to Earth Resistance Testing.” Lightning protection and power grounding have different criteria, so make sure all requisite conditions are met. Power grounds may be shallow-buried, and this may not afford sufficient protection from lightning.
The grounding system must be tested upon installation for initial conformance to specs and standards, and then periodically thereafter. The familiar “out of sight, out of mind” can be deadly here. Clearance of lightning strikes and electrical faults will often work as intended, leaving the tower structure and function unharmed. However, the grounding electrode can be seriously compromised during the process of clearance — and it is dangerously out of sight. Regular testing, as well as after known strikes, is necessary. Changes in soil composition, especially moisture and subsurface corrosion, can have the same effect over a longer time scale.
Copper theft is a problem throughout the electrical industry, and it can be particularly acute on wind farms because of their size and remote location. In addition, grounding is often buried at much shallower depths than cabling, making theft that much easier. The clamp-on ground tester can be a useful tool here as a quick means of determining whether continuity exists or has been corrupted by theft.
Thorough record-keeping is particularly in order, as comparing results can be especially informative in recognizing problems and issues. It’s also a good idea to note exactly where test probes are placed so that subsequent testing can be done for comparison to stored records. The data is useful to note changes for maintenance personnel, even if the size of the grid precludes objective accuracy to remote earth. If testing is precisely repeated, changes in results can be indicative of issues that must be addressed.
CONCLUSION
Effective grounding is indispensable to the safe and efficient operation of wind towers and solar arrays. The two are identical in requiring a continuous, low-impedance path to ground and a low-impedance connection to the surrounding earth. The test equipment is the same, and procedures are only slightly — but critically — adjusted to the site.
ANSI/NETA MTS, Standard for Maintenance Testing Specifications for Electrical Equipment and Systems, Sections 7.13– 7.14 provides recommended visual and mechanical inspections and electrical tests for grounding systems and ground-fault protection systems.
REFERENCES
IEC 61024, Protection of Structures against Lightning
IEC 61400, Wind Energy Generation Systems, Part 24: Lightning Protection.
NFPA 70, National Electric Code (NEC), Article 250 Grounding and Bonding.
NFPA 70, National Electric Code (NEC), Article 690 Solar Photovoltaic Systems.
NFPA 780, Standard for Lightning Protection Systems.
UL 96A, Standard for Installation Requirements for Lightning Protection Systems.
Megger. “Getting Down to Earth: A Practical Guide to Earth Resistance Testing,” 2018. Accessed at https://www.megger.com/en-ca/support/technical-library/technical-guides/getting-down-to-earth-a-practical-guide-to-earth.
ANSI/NETA MTS–2023, Standard for Maintenance Testing Specifications for Electrical Equipment and Systems. Accessed at https://www.netaworld.org/standards/ansi-neta-mts.
Jeffrey R. Jowett is a Senior Applications Engineer for Megger in Valley Forge, Pennsylvania, serving the manufacturing lines of Biddle, Megger, and Multi-Amp for electrical test and measurement instrumentation. He holds a BS in biology and chemistry from Ursinus College. Jowett was employed for 22 years with James G. Biddle Co., which became Biddle Instruments and is now Megger.