Parabolic Trough Employing Silicon Solar Cells as a Wavelength-Selective Mirror

Zachary Holman (Inventor)

Research output: Patent

Abstract

Photovoltaic (PV) solar cells directly convert energy from sunlight into electricity, whereas concentrated solar power (CSP) systems use focused mirrors to reflect sunlight onto a heat absorbing mechanism that powers an electricity-generating turbine. According to the National Renewable Energy Laboratory, even the best PV cells are less than 45% efficient, and the worlds most modern CSP power plant is still under 30% efficient. PV systems are inefficient because sub-bandgap and super-bandgap wavelengths (below and above the absorption range) are not absorbed and the excess energy is lost as heat. CSP systems are inefficient because, though they use the whole solar spectrum, there are many steps in the energy conversion process that each cause an appreciable efficiency loss. Currently, the only PV/CSP hybrid systems couple hot PV cells with a thermal cycle, so the PV cell doubles as both an electricity generator and a heat source. The drawback to these systems is that the efficiency of a PV cell decreases rapidly with increasing temperature. Researchers at ASU have developed a parabolic trough that splits the solar spectrum, absorbing the wavelengths most efficiently converted to electricity in the PV cells while reflecting all others to a central point to generate heat. A customizable optical coating is applied to the trough that reflects specific wavelengths depending on the type of PV cell used and what is required for the additional absorbing element. The coating allows the PV cells to operate below one-sun illumination levels and thus stay at temperatures well below 100C. Potentially, any type of flexible PV cell can be used silicon cells, multijunction cells, CdTe etc. with any additional absorbing element, such as piping filled with thermally enhanced nanoparticle fluid. Combining PV and CSP technologies in this way facilitates power plant efficiency with an estimated 50% relative gain in overall solar-to-energy conversion. Potential Applications Concentrated Solar Power Plants Photovoltaic Power Plant Solar Modules Benefits and Advantages Effective Higher energy conversion efficiency than stand-alone PV or CSP systems and leading hybrid PV/CSP systems. Practical Maximizes energy absorption of PV cells while also converting the remaining part of the electromagnetic spectrum into dispatchable energy. Versatile Customizable to any combination of PV cell and CSP technology. Retrofit Can be applied to existing CSP systems with little modification. Download Original PDF For more information about the inventor(s) and their research, please see Dr. Zachary Holman's directory webpage Dr. Roger Angel's directory webpage
Original languageEnglish (US)
StatePublished - Oct 8 2013

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Photovoltaic cells
Silicon solar cells
Solar energy
Mirrors
Wavelength
Electricity
Energy conversion
Solar power plants
Power plants
Energy gap
Optical coatings
Energy absorption
Hybrid systems
Sun
Conversion efficiency
Solar cells
Turbines
Lighting
Hot Temperature
Nanoparticles

Cite this

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title = "Parabolic Trough Employing Silicon Solar Cells as a Wavelength-Selective Mirror",
abstract = "Photovoltaic (PV) solar cells directly convert energy from sunlight into electricity, whereas concentrated solar power (CSP) systems use focused mirrors to reflect sunlight onto a heat absorbing mechanism that powers an electricity-generating turbine. According to the National Renewable Energy Laboratory, even the best PV cells are less than 45{\%} efficient, and the worlds most modern CSP power plant is still under 30{\%} efficient. PV systems are inefficient because sub-bandgap and super-bandgap wavelengths (below and above the absorption range) are not absorbed and the excess energy is lost as heat. CSP systems are inefficient because, though they use the whole solar spectrum, there are many steps in the energy conversion process that each cause an appreciable efficiency loss. Currently, the only PV/CSP hybrid systems couple hot PV cells with a thermal cycle, so the PV cell doubles as both an electricity generator and a heat source. The drawback to these systems is that the efficiency of a PV cell decreases rapidly with increasing temperature. Researchers at ASU have developed a parabolic trough that splits the solar spectrum, absorbing the wavelengths most efficiently converted to electricity in the PV cells while reflecting all others to a central point to generate heat. A customizable optical coating is applied to the trough that reflects specific wavelengths depending on the type of PV cell used and what is required for the additional absorbing element. The coating allows the PV cells to operate below one-sun illumination levels and thus stay at temperatures well below 100C. Potentially, any type of flexible PV cell can be used silicon cells, multijunction cells, CdTe etc. with any additional absorbing element, such as piping filled with thermally enhanced nanoparticle fluid. Combining PV and CSP technologies in this way facilitates power plant efficiency with an estimated 50{\%} relative gain in overall solar-to-energy conversion. Potential Applications Concentrated Solar Power Plants Photovoltaic Power Plant Solar Modules Benefits and Advantages Effective Higher energy conversion efficiency than stand-alone PV or CSP systems and leading hybrid PV/CSP systems. Practical Maximizes energy absorption of PV cells while also converting the remaining part of the electromagnetic spectrum into dispatchable energy. Versatile Customizable to any combination of PV cell and CSP technology. Retrofit Can be applied to existing CSP systems with little modification. Download Original PDF For more information about the inventor(s) and their research, please see Dr. Zachary Holman's directory webpage Dr. Roger Angel's directory webpage",
author = "Zachary Holman",
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type = "Patent",

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AU - Holman, Zachary

PY - 2013/10/8

Y1 - 2013/10/8

N2 - Photovoltaic (PV) solar cells directly convert energy from sunlight into electricity, whereas concentrated solar power (CSP) systems use focused mirrors to reflect sunlight onto a heat absorbing mechanism that powers an electricity-generating turbine. According to the National Renewable Energy Laboratory, even the best PV cells are less than 45% efficient, and the worlds most modern CSP power plant is still under 30% efficient. PV systems are inefficient because sub-bandgap and super-bandgap wavelengths (below and above the absorption range) are not absorbed and the excess energy is lost as heat. CSP systems are inefficient because, though they use the whole solar spectrum, there are many steps in the energy conversion process that each cause an appreciable efficiency loss. Currently, the only PV/CSP hybrid systems couple hot PV cells with a thermal cycle, so the PV cell doubles as both an electricity generator and a heat source. The drawback to these systems is that the efficiency of a PV cell decreases rapidly with increasing temperature. Researchers at ASU have developed a parabolic trough that splits the solar spectrum, absorbing the wavelengths most efficiently converted to electricity in the PV cells while reflecting all others to a central point to generate heat. A customizable optical coating is applied to the trough that reflects specific wavelengths depending on the type of PV cell used and what is required for the additional absorbing element. The coating allows the PV cells to operate below one-sun illumination levels and thus stay at temperatures well below 100C. Potentially, any type of flexible PV cell can be used silicon cells, multijunction cells, CdTe etc. with any additional absorbing element, such as piping filled with thermally enhanced nanoparticle fluid. Combining PV and CSP technologies in this way facilitates power plant efficiency with an estimated 50% relative gain in overall solar-to-energy conversion. Potential Applications Concentrated Solar Power Plants Photovoltaic Power Plant Solar Modules Benefits and Advantages Effective Higher energy conversion efficiency than stand-alone PV or CSP systems and leading hybrid PV/CSP systems. Practical Maximizes energy absorption of PV cells while also converting the remaining part of the electromagnetic spectrum into dispatchable energy. Versatile Customizable to any combination of PV cell and CSP technology. Retrofit Can be applied to existing CSP systems with little modification. Download Original PDF For more information about the inventor(s) and their research, please see Dr. Zachary Holman's directory webpage Dr. Roger Angel's directory webpage

AB - Photovoltaic (PV) solar cells directly convert energy from sunlight into electricity, whereas concentrated solar power (CSP) systems use focused mirrors to reflect sunlight onto a heat absorbing mechanism that powers an electricity-generating turbine. According to the National Renewable Energy Laboratory, even the best PV cells are less than 45% efficient, and the worlds most modern CSP power plant is still under 30% efficient. PV systems are inefficient because sub-bandgap and super-bandgap wavelengths (below and above the absorption range) are not absorbed and the excess energy is lost as heat. CSP systems are inefficient because, though they use the whole solar spectrum, there are many steps in the energy conversion process that each cause an appreciable efficiency loss. Currently, the only PV/CSP hybrid systems couple hot PV cells with a thermal cycle, so the PV cell doubles as both an electricity generator and a heat source. The drawback to these systems is that the efficiency of a PV cell decreases rapidly with increasing temperature. Researchers at ASU have developed a parabolic trough that splits the solar spectrum, absorbing the wavelengths most efficiently converted to electricity in the PV cells while reflecting all others to a central point to generate heat. A customizable optical coating is applied to the trough that reflects specific wavelengths depending on the type of PV cell used and what is required for the additional absorbing element. The coating allows the PV cells to operate below one-sun illumination levels and thus stay at temperatures well below 100C. Potentially, any type of flexible PV cell can be used silicon cells, multijunction cells, CdTe etc. with any additional absorbing element, such as piping filled with thermally enhanced nanoparticle fluid. Combining PV and CSP technologies in this way facilitates power plant efficiency with an estimated 50% relative gain in overall solar-to-energy conversion. Potential Applications Concentrated Solar Power Plants Photovoltaic Power Plant Solar Modules Benefits and Advantages Effective Higher energy conversion efficiency than stand-alone PV or CSP systems and leading hybrid PV/CSP systems. Practical Maximizes energy absorption of PV cells while also converting the remaining part of the electromagnetic spectrum into dispatchable energy. Versatile Customizable to any combination of PV cell and CSP technology. Retrofit Can be applied to existing CSP systems with little modification. Download Original PDF For more information about the inventor(s) and their research, please see Dr. Zachary Holman's directory webpage Dr. Roger Angel's directory webpage

M3 - Patent

ER -