JournalArticle SearchList By TopicSubmit ArticleRegister
ResourcesWhite PapersGlossaryStock TrackerPresentations
7 Oct 2011 | United States
Sandia awards for solar glitter, rescue robot & university partnership
Sandia National Laboratories will begin researching how to use glitter-sized photovoltaic cells in utility-scale solar power systems, which eventually could cut the costs of solar panels in half and nearly double their efficiency.
Sandia's work with industry, other labs and universities to improve the design, materials and manufacturing processes of the Microsystems-Enabled Photovoltaic (MEPV) cells won the national security laboratory a Federal Laboratory Consortium (FLC) Mid-Continent Regional Excellence in Technology Transfer Award.
Sandia also received FLC awards for the development of the Gemini-Scout Mine Rescue Robot and a technology transfer partnership with the University of New Mexico (UNM). The awards were presented recently in Monterey, Calif.
"These projects recognize Sandia National Laboratories' outstanding technology transfer efforts and highlight a variety of ways in which Sandia continues to make an impact, whether it is teaming with our local university on technology commercialization, providing a tool for first responders or developing a revolutionary way to collect solar power," said Jackie Kerby Moore, Sandia's manager of Technology & Economic Development.
Greg Nielson, team leader on the MEPV project, said Sandia is working with: Universal Instruments Corp. and Endicott Interconnect Technologies Inc., both in New York; New Jersey-based International Micro Industries Inc.; Albuquerque-based EMCORE Corp.; the National Renewable Energy Laboratory in Golden, Colo.; and the University of South Florida. This fall, some new partners, including California-based Deposition Sciences Inc. and the University of Delaware also will help with the project.
Together, the partners are applying commercially available manufacturing techniques to the solar cells and studying how to better produce them, including some techniques that can make them as small as two microns thick, which is about 3 percent of the diameter of a human hair. They also are researching more efficient materials and designs, Nielson said.
In October, Sandia will begin applying the glittery solar cells to large-scale solar power systems and building a prototype 1-foot-by-1-foot MEPV demonstration module, he said.
"As the cells have matured and gotten to the point where we're getting good, consistent performance, we're ready to jump into making systems," he said. "We've got these cells; now what are we going to do with them?"
Sandia researcher Greg Nielson, team leader on the Microsystems-Enabled Photovoltaic cell project, holds up a sample of the cells that won a regional Excellence in Technology Transfer Award from the Federal Laboratory Consortium (FLC). (Photo by Randy Montoya)
The new MEPV solar power systems based on single-junction cells are estimated to be up to 20 percent efficient, meaning they capture a fifth of the sun's energy, and could cost $1.80 per watt-peak, a way of rating a photovoltaic system that measures how many watts a panel produces when sunlight is at its peak, Nielson said. The preliminary cost estimate includes an 18 percent profit margin and the costs of manufacturing, labor, permits and racking and wiring for installation.
Today, the low-end cost of installing a traditional utility-scale solar system is about $4 per watt-peak, Nielson said.
While preliminary cost estimates for the single-junction MEPV system are competitive with what consumers pay for electricity from the grid now, Nielson hopes the cost can be cut and the efficiency increased even further with innovations that take advantage of technologies developed in the last 10-15 years.
Those being studied include: moving from single - to multi-junction cells to increase system efficiency up to a goal of 40 percent by utilizing different wavelengths of light; concentrating sunlight to decrease the amount of solar-cell area needed to produce the same amount of energy; better managing the cells' thermal output; placing the cells in a series to increase the module's voltage; placing the inverter directly into the module to reduce installation costs; and decreasing how precise the sun-tracking hardware needs to be to capture the sun's energy, thus decreasing the cost of the modules' tracking hardware, Nielson said.
Nielson said a prototype MEPV solar power system could be built in about two years, but modules for utilities or individual buildings will likely take at least seven years to reach commercial markets, due to rigorous reliability and safety testing requirements. However, consumers could have access to flexible MEPV power devices built into tents, clothing or electrical gadgets, in a few years, he said.
The companies that have taken on the challenging manufacturing and research projects, have "been a big help in advancing certain aspects of the technology, while the more advanced technology of the photovoltaic cells Sandia has done," Nielson said.
Sandia's other two FLC awards include:
- The four-foot-long, two-foot-tall Gemini-Scout Mine Rescue Robot, designed to help mine search and rescue teams save survivors in hazardous environments, such as during mining disasters, won a Notable Technology Development Award. Sandia has licensed the Gemini-Scout to Black-I Robotics, a small business in Tyngsboro, Mass. The remote-control robot contains color video cameras, a thermal imaging camera, microphones and sensors that act as eyes and ears for rescue crews and provide air-quality information. Two-way audio enables survivors to communicate with rescuers. Gemini-Scout's dual tracked-chassis design and tread enable it to negotiate obstacles, such as large rocks, railroad tracks or water and mud up to 18 inches deep. The robot also can carry up to 250 pounds of equipment for rescuers. The Gemini-Scout could be fitted to handle rescues in earthquakes, fires and mining accidents.
- STC.UNM, a nonprofit corporation owned by UNM that works closely with Sandia to promote technology transfer, won a Regional Partnership Award. STC and Sandia have 109 jointly owned invention disclosures and they have entered into 48 commercialization agreements. The partnership has promoted interaction between and crossover of scientists and researchers at both institutions, increasing collaborative research. Graduate students do research at both institutions and current and retired Sandia employees serve as faculty at UNM.
The winners were selected from an FLC region that is home to more than 100 federal laboratories in 14 states: Arkansas, Colorado, Iowa, Kansas, Missouri, Montana, Nebraska, New Mexico, North Dakota, Oklahoma, South Dakota, Texas, Utah and Wyoming.
"The reason we believe we can get the prices down is we're taking a completely different approach to the photovoltaic systems and that's based on the MEPV cells. It's a direction that the industry has not taken at all," he said.
Sandia National Laboratories is a multiprogram laboratory operated by Sandia Corporation, a wholly owned subsidiary of Lockheed Martin Corporation, for the U.S. Department of Energy's National Nuclear Security Administration. With main facilities in Albuquerque, N.M., and Livermore, Calif., Sandia has major R&D responsibilities in national security, energy and environmental technologies, and economic competitiveness.
Main Image: The Gemini-Scout Mine Rescue Robot which won the regional Notable Technology Development Award from the FLC. (Photo by Randy Montoya)
Source: Sandia Corporation
For more attend: Printed Electronics USA 2011 .
For more read: Thin Film Photovoltaics and Batteries 2011-2021.
Market data; market and technology appraisal; case studies: the complete picture for printed, flexible and organic electronicsOpportunities for premium pricing, safer and lower cost products: case studies, technologies, players and forecasts
- Printed, Organic & Flexible Electronics Forecasts, Players & Opportunities 2014-2024
- Printed Electronics for Healthcare, Cosmetics and Pharmaceuticals 2014-2024
- Organic Photovoltaics (OPV) 2013-2023: Technologies, Markets, Players
- Dye Sensitized Solar Cells (DSSC/DSC) 2013-2023: Technologies, Markets, Players
- Stretchable Electronics Comes to Market
- Thin Film Photovoltaics 2012-2022: Forecasts, Technologies, Analysis
- Internet of Things (IoT): Business Opportunities 2015-2025
- Smart Packaging Comes To Market: Brand Enhancement with Electronics 2014-2024
- Wearable Technology 2014-2024: Technologies, Markets, Forecasts
- Transparent Conductive Films (TCF) 2014-2024: Forecasts, Markets, Technologies
- Energy Harvesting and Storage 2014-2024: Forecasts, Technologies, Players
- Barrier Films for Flexible Electronics 2013-2023: Needs, Players, Opportunities
- Introduction to Printed, Organic and Flexible Electronics
- OLED Lighting Opportunities 2014-2025: Forecasts, Technologies, Players
- Electric Aircraft 2014-2024: Trends, Projects, Forecasts
- Wireless Sensor Networks (WSN) 2014-2024: Forecasts, Technologies, Players
- Wireless Power Transmission for Consumer Electronics and Electric Vehicles 2014-2024
- Electrochemical Double Layer Capacitors: Supercapacitors 2014-2024
- Electric Vehicle Forecasts, Trends and Opportunities 2014-2024
- RFID Forecasts, Players and Opportunities 2014-2024
- Printed and Flexible Sensors 2014-2024: Technologies, Players, Forecasts
- Touch Screen Modules: Technologies, Markets, Forecasts 2012-2022
- Hybrid and Electric Vehicles for Military, Police & Security 2012-2022
- Printed and Chipless RFID Forecasts, Technologies & Players 2011-2021
Printed, Organic & Flexible Electronics Forecasts, Players & Opportunities 2014-2024
Printed Electronics for Healthcare, Cosmetics and Pharmaceuticals 2014-2024
Organic Photovoltaics (OPV) 2013-2023: Technologies, Markets, Players
Dye Sensitized Solar Cells (DSSC/DSC) 2013-2023: Technologies, Markets, Players
Stretchable Electronics Comes to Market
Thin Film Photovoltaics 2012-2022: Forecasts, Technologies, Analysis
Internet of Things (IoT): Business Opportunities 2015-2025
Smart Packaging Comes To Market: Brand Enhancement with Electronics 2014-2024
Wearable Technology 2014-2024: Technologies, Markets, Forecasts
Transparent Conductive Films (TCF) 2014-2024: Forecasts, Markets, Technologies
Energy Harvesting and Storage 2014-2024: Forecasts, Technologies, Players
Barrier Films for Flexible Electronics 2013-2023: Needs, Players, Opportunities
Introduction to Printed, Organic and Flexible Electronics
OLED Lighting Opportunities 2014-2025: Forecasts, Technologies, Players
Electric Aircraft 2014-2024: Trends, Projects, Forecasts
Wireless Sensor Networks (WSN) 2014-2024: Forecasts, Technologies, Players
Wireless Power Transmission for Consumer Electronics and Electric Vehicles 2014-2024
Electrochemical Double Layer Capacitors: Supercapacitors 2014-2024
Electric Vehicle Forecasts, Trends and Opportunities 2014-2024
RFID Forecasts, Players and Opportunities 2014-2024
Printed and Flexible Sensors 2014-2024: Technologies, Players, Forecasts
Touch Screen Modules: Technologies, Markets, Forecasts 2012-2022
Hybrid and Electric Vehicles for Military, Police & Security 2012-2022
Printed and Chipless RFID Forecasts, Technologies & Players 2011-2021
A semi-artificial leaf faster than 'natural' photosynthesis
Graphene may be key to leap in supercapacitor performance
Braking energy recuperation in Spanish rail system
A self-organizing thousand-robot swarm
Electric vehicles set for 2014 MPG Marathon
Nevs' electric vehicle prototype series