Holographic Lens / Mirror Aperture (Hl/ma) Design for Hybrid Thermal Solar Systems

Technology #ua13-037

Questions about this technology? Ask a Technology Manager

Download Printable PDF

Categories
Researchers
Raymond Kostuk
Professor, Electrical & Computer Engineering
Shelby Vorndran
Student, Optical Sciences
Deming Zhang
Graduate Assistant, Research, Electrical & Computer Engineering
Juan Russo
Graduate Assistant, Research, Electrical & Computer Engineering
Michael Gordon
Graduate Assistant, Research, Electrical & Computer Engineering
Managed By
Amy Phillips
Sr. Licensing Manager (520) 621-9579

Holographic Lens / Mirror Aperture (HL/MA) Design for Hybrid Thermal Solar Systems

Technology:  Researchers at the University of Arizona have designed a hybrid solar collection and distribution system to optimize the use of the solar collector footprint as well as the solar spectrum.  The system splits the spectrum into two components to distribute the peak wavelengths for algae growth, PV, and thermal uses. Algae responds best to photosynthesis wavelengths 400-700 nm) whereas photovoltaic cells and thermal collectors respond well to different and broader spectral ranges.  In the UA design, one wavelength band is focused by a holographic lens through a mirror aperture ionto a ground target, landing uniformly within the shadow of the mirror.  The rest of the spectrum passes through the lens, reflects off of the mirror, and lands on the thermal or photovoltaic receiver. The design accommodates 4 different geometries, including thermal mirror arrays and photovoltaic arrays, so is versatile in its applicability.

 

Background:

 

With the increased interest in biofuels, such as algae, and in efficient use of solar radiation collectors, a need exists to optimize the energy efficiencies of the ground footprint.  Several designs currently exist to spread the solar spectrum for optimization of PV conversion to electricity, but they don’t address thermal conversion or biofuel needs. Biofuels such as algae exhibit better growth if they are protected from portions of solar radiation outside of the photosynthesis band of 400nm to 700nm.  Thermal needs can tap a different broad portion of the solar specrum than PV.  Solar collectors, for PV or thermal, and algae farms take up large footprints of real estate.  The most efficient method of solar-based energy production would utilize one footprint for all three forms of solar-based energy production.  The design by the UA researchers not only provides a means of using one footprint for collecting light for all forms, but optimizes the algae production as well as the thermal or photovoltaic conversion efficiencies.

 

Advantages:

* Optimizes footprint of algae farm and solar collector field

* Improves algae growth by protecting algae from harmful solar radiation wavelengths

* Versatile configurations

Applications:

* Solar energy production, algae farms

* Thermal energy production

* Radiation splitting and optimization

Lead Inventor:  Shelby Vorndran, College of Optical Sciences

Contact:  Amy Phillips; amyp@tla.arizona.edu; aphillips@optics.arizona.edu

Refer to case number UA13-037