Building wind turbines on high mountain peaks presents unique challenges: limited space, significant elevation drops, and predominantly rocky
geology. Here are tailored lightning protection and grounding strategies:
Utilize Natural Grounding Elements: Leverage the reinforced concrete
within the turbine tower and transformer foundation as inherent
grounding conductors.
Deploy Radial Artificial Grounding Grids: Install artificial grounding
electrodes radiating outwards from the foundation. The burial depth of
horizontal electrodes and the spacing of vertical electrodes must
strictly adhere to engineering standards.
Select High-Efficiency Grounding Materials: Choose materials with a larger
surface-area-to-volume ratio. Backfill should utilize low-resistivity soil or specialized resistance-reducing agents, paying particular attention to the critical interface
between the electrode and soil to minimize contact resistance.
Adopt a Practical View on Ground Resistance Measurements: With a
well-designed grounding grid and proper installation, over-reliance on specific ground resistance readings can be counterproductive. Measurements for irregular grids in complex terrains are inherently
subject to significant variance.
To address the poor current dispersion in high-resistivity rocky areas, consider the following measures:
Extend Grounding Conductors: Run grounding conductors beyond designated "Zone B" (as per schematic Figure 1) to areas with lower soil
resistivity, installing auxiliary grounding grids or current dissipation pits.
Improve Surface Soil Conductivity: Apply a layer of low-resistivity soil over Zone B, ensuring it integrates effectively with
the native, more conductive topsoil of the mountain.
Optimize External Electrode Placement: When routing external grounding
electrodes along mountain slopes, prioritize burial within the more
conductive surface soil layer. There is no need for excessive burial
depth.
Implement Equipotential Bonding: In "Zone A," establish equipotential
bonding measures to safeguard personnel from dangerous step and touch
potentials.
The installation of deep borehole grounding electrodes can be approached in two ways, depending on the rock formation:
For Fractured Rock Layers:
After drilling, enlarge the borehole bottom into a hemispherical shape.
Fill the hole with a water-soluble electrolyte solution (avoiding highly corrosive types), allowing it to seep into the surrounding fissures.
Insert the grounding electrode and backfill the borehole with soil mixed with a resistance-reducing agent.
For Solid, Dense Rock Formations:
Avoid drilling in these areas if possible. If unavoidable, maintain a
safe distance from structures.
After drilling, employ controlled low-charge blasting at the bottom of the hole to create a network of
fractures.
Proceed with the method outlined for fractured rock layers.
Designing effective lightning protection and grounding systems for wind turbines in high-altitude rocky environments requires a site-specific approach. It demands careful field investigation and a
practical application of grounding principles tailored to the unique
topography and geology. The focus should remain on robust grid design
and superior installation quality, rather than fixating solely on ground resistance measurements, which are often unreliable in such complex
settings. A well-executed grounding strategy is paramount for ensuring the long-term safety and operational reliability of these renewable energy assets.