PV Retrofit Performance Improvement – Long-Term Field Results

Ultrathin SiO Functional Coatings for Efficiency Improvement of Existing Solar Plants

Overview

Improving the performance of existing photovoltaic installations has become an increasingly important part of global solar development. While new solar parks continue to be built worldwide, a large share of installed photovoltaic capacity consists of systems that have been operating for many years.

Many of these installations remain technically sound but experience avoidable energy losses caused by reflection, surface contamination and environmental exposure.

Long-term field observations show that ultrathin SiO₂-based functional coatings applied to photovoltaic glass surfaces can measurably improve energy yield without requiring any modification of electrical or structural components.

This non-invasive retrofit technology enables performance improvements in operating solar plants and can be implemented without module replacement or system redesign.

Global Potential of PV Retrofit Technologies

Global photovoltaic capacity has reached the terawatt scale, with a significant share of installations built between 2000 and 2015.

These systems often continue to operate reliably but show measurable efficiency losses due to:

  • reflection losses at the glass surface
  • accumulation of dust and airborne particles
  • uneven wetting behaviour
  • thermal stress

Retrofit technologies that modify only the glass surface provide a practical method to improve system performance without replacing modules or changing electrical infrastructure.

This approach is particularly suitable for utility-scale solar plants.

Technology Principle

Ultrathin SiO₂ functional coatings modify the surface energy of photovoltaic glass at the nanometre scale.

The coating forms a permanently bonded functional glass surface with the following effects:

  • improved light transmission
  • reduced reflection losses
  • improved utilisation of diffuse light
  • reduced dirt adhesion
  • improved natural cleaning behaviour

Because only the glass surface is modified, electrical and mechanical properties remain unchanged.

The technology can be applied both to new installations and to existing solar plants.

Long-Term Field Results

Long-term field measurements in different climate zones demonstrate consistent performance improvements.

Typical observations include:

Optical Base Effect

Improved light transmission typically results in:

2–5% energy yield increase under clean reference conditions

High Soiling Environments

In dusty environments, combined optical and anti-soiling effects can result in:

5–20% energy yield improvement

Higher values have been observed under extreme environmental conditions.

Performance Stability

Multi-year observations show stable performance improvements over time.

Performance improvements are typically most visible:

  • in morning and evening hours
  • under diffuse light conditions
  • during variable weather conditions

These observations confirm improved utilisation of diffuse solar radiation.

Influence on Soiling and Cleaning

Surface contamination is one of the main causes of energy loss in photovoltaic installations.

Functionalised glass surfaces significantly reduce particle adhesion.

Field observations indicate:

  • extended cleaning intervals
  • stable surface transparency
  • reduced water consumption
  • lower maintenance effort

In dry regions, natural cleaning by wind and rain can remove a large proportion of loose particles.

These effects are particularly relevant for large solar parks.

Industrial Applications

The technology has been applied in operating solar plants in different regions.

In parts of Asia, surface functionalisation is increasingly integrated into regular maintenance cycles of solar parks.

Application can be performed without dismantling modules and without interruption of plant operation.

This allows efficient implementation even in large installations.

Safety and Material Compatibility

Ultrathin functional coatings do not affect electrical or mechanical safety of photovoltaic modules.

Investigations indicate:

  • stable electrical parameters
  • no mechanical stress on modules
  • full compatibility with photovoltaic glass

The technology is suitable for long-term operation.

Economic Considerations

Even moderate improvements in energy yield can have significant economic impact in large solar installations.

Additional energy production combined with reduced cleaning requirements can result in attractive payback periods.

Retrofit technologies therefore provide an economically viable method to improve existing solar plants without major investment.

This is particularly relevant for:

  • utility-scale solar parks
  • high-dust environments

water-limited regions

Conclusion

Long-term field observations demonstrate that nanoscale SiO₂ surface functionalisation provides a technically reliable method for improving the performance of existing photovoltaic installations.

The technology enables measurable yield improvements, reduced soiling losses and stable operating conditions without modification of electrical or structural components.

PV retrofit technologies based on surface functionalisation represent a scalable approach to improving the efficiency of existing solar power systems.

Frequently Asked Questions –

PV Retrofit Performance

PV retrofit performance improvement refers to methods that increase the energy output of existing solar installations without replacing modules or modifying electrical systems.

Surface functionalisation technologies can improve light transmission and reduce soiling losses, resulting in measurable increases in energy yield.

Long-term field observations indicate typical improvements of:

  • 2–5% from improved light transmission
  • 5–20% in dusty environments

Higher values may occur under extreme environmental conditions.

Results depend on climate conditions and installation characteristics.

Ultrathin functional coatings modify only the glass surface and do not affect electrical or mechanical properties of photovoltaic modules.

Field experience indicates stable operation without impact on module safety.

Yes.

PV retrofit coatings can be applied to operating solar plants without dismantling modules or modifying electrical systems.

This allows efficient implementation in utility-scale installations.

Functionalised glass surfaces reduce particle adhesion and improve wetting behaviour.

This allows wind and rain to remove a larger share of surface contamination and helps maintain higher surface transparency.

Even moderate improvements in energy yield can significantly improve the economics of large solar installations.

Reduced cleaning requirements and increased energy production can lead to attractive payback periods.

PV retrofit technologies based on nanoscale surface functionalisation have been applied in operating solar installations in different climate regions.

Long-term field observations demonstrate consistent performance improvements.

The technology and long-term field assessments presented on this page are based on work by:

Dieter Schwindt
Founder and Technical Director – nanopool GmbH

www.nanopool.eu
Certified Expert for Nanotechnology and Surface Functionalization