Details 
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Overview
Solar Market Challenges
Residential and commercial energy conservation research has been an on-going process for the last several decades. The research scope extends from applying conventional and new conservation concepts to the development of active solar thermal energy systems. In general, the financial incentives to the user or to the manufacturer of such systems have not been sufficient to result in their wide-spread use. This problem was compounded by the negative visual effect of active solar systems. Accordingly, most of the research work has been financed by various government agencies. Furthermore, the relatively low cost of conventional energy during the last three decades has contributed to the lack of significant support for this research area. Harnessing Solar Energy The common procedure to harness the solar thermal energy falling on roofs is to use an active solar collection system. Standard active solar systems consist of three major subsystems: 1) a flat plat solar collectors subsystem, 2) a control unit subsystem and 3) a storage subsystem. An active solar collector system is capable of capturing approximately one third (depending on the temperature rise and the ambient temperature and the particular design of the collector) of the solar thermal energy received by its solar collector area. The most direct applications of such system are to provide direct space heating in case of air solar collectors. For liquid solar collectors, the thermal energy for space heating would be supplied through a heat exchanger. In both cases water heating is achieved through heat exchangers. Considerable amount of experimentation were conducted on storage systems using variety of material, liquid, solids, and phase change materials. According to the Government publications, the cost of an active solar collector system ranges from $30 to $80 per square foot of the solar collector area. Other hybrid systems such as solar assisted heat pump systems in the parallel and series configuration were evaluated and tested during the late sixties and early seventy. No commercial scale product is yet available. Efforts to directly convert solar thermal energy to more usable forms have been only moderately successful but no commercial outcome. Hindered Marketability Three decades later, the commercial market did not bear any of the above Research and Development effort. The major problems that hindered the marketability of active solar systems are several 
High initial capital cost
The negative visual impact of the solar collector system on the roof
Long term return on investment due to cheaper conventional options
Lack of standardization
In many cases the roof trusses needed to be reinforced to carry the relatively heavy solar panels especially in existing homes
Potential freezing in liquid type collectors in Northern regions
The current powerful simulation capability and microprocessor control capability was not fully utilized
The current popularity of PCs as powerful tools for providing load management was not existent
Degradation, leakage, corrosion and rust
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Quick Facts
The existing number of U.S. households exceeds 68 million
The annual solar energy falling on U.S. roofs is equivalent to 22 million barrels of oil per day. Utilizing only 15% of this energy is equivalent to 3.4 million barrels per day. This is equivalent to almost $50 billion annually
Approximately 1.75 million new homes are constructed annually. Accordingly, the additional annual savings could exceed $1.2 billion
This energy, substituting electrical power produced at almost 50% efficiency, can significantly reduce power plants pollution
The amount of solar thermal energy falling on building roofs in the Southern States, is more than five times the heat consumed for space heating, domestic water heating, drying, and pool heating
In northern states, the amount of energy falling on the roof can provide a significant portion of the heat load required
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The SOLAROOF System
SOALROOF can solve many of the problems that the solar market faces today.
SOALROOF will cost effectively recapture solar thermal energy falling on roofs without requiring anything to be installed on top of the roof. SOALROOF is a very low-cost solution which can be applied to both existing structures and new buildings. SOALROOF is quite flexible. It will contribute to the heating and cooling requirements in both warm and cool climates. |
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Features and Benefits
Features
Harness solar energy quickly at a very low price
Leverage existing roof structure with nothing to install on the outside
Reduce utility bills for homeowners and businesses
Benefits
The SOLAROOF technology is quite simple and can be easily incorporated within housing industry standards at very low cost.
Faster rate of return due to the low initial capital investment. The Solaroof system will cost a fraction of a conventional solar collector system.
The economic merits of the proposed system are valid in almost all U.S. climatic regions for new and existing homes and commercial buildings.
Interaction of the SOLAROOF control system with other energy systems will provide significant additional energy savings through integrated load management control.
A by-product of the SOLAROOF process is the reduction of the attic temperature which will reduce the building cooling load requirements.
On an average size home, if all 15% of the solar thermal energy, falling on the most Sothern roof section(s), can be utilized in the thermal form, the annual utility saving of $2,000 (based on 13 cents per kwh) can be realized to home owner (tax credit equivalent).
The SOLAROOF system is equally applicable to commercial, industrial and farm buildings.
This is one form of renewable energy that does not require a network for power distribution. The energy source is on the top of the building that will use it.
Garden City Development is an energy efficient ready community. Currently solar passive designs were implemented.
Kentucky Solar Test Facility - Lexington, KY
Feasibility Study for Manufacturing Flat Plate Solar Collectors - Burr Ridge, IL
Solar Desalination Process - Chicago, IL
Renewable Energy Resources & Utilization - Cairo, Egypt
Planned Marriot Resort: Design Water Desalination Plant & Waste Water Management System - Hurghada, Egypt
Develop Energy & Water Conservation Codes for Red Sea Resorts - Hurghada, Egypt
Design Installation, Operation, and Monitoring Solar Desalination Plant - Military Tech. College, Egypt
Solar Industrial Process Heat & Energy Analysis for Milk, Fruit Dehydration, Textile Dyeing, & Poultry Processing Plants - US-AID
Consultancy Services Relating to Renewable Energy Systems - United Nations Development Programs (UNDP)
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Patents
The principal investigator for the SOLAROOF Project, Dr. ElDifrawi, has developed, designed, built, and tested cost effective integrated solar heating system for air and supported tension structure; designed, built and tested a medium temperature solar collector system for commercial heating and cooling applications (US Patent 4,196,720 April 1980).
Dr. ElDifrawi has also developed a new concept for sea water desalination. The concept was modeled and simulated to a prototype (US Patent 4,363,703, December 1982). In the implementation and commercialization phase Dr. ElDifrawi managed the design, construction, operation, and training Milestones of the "Solar Sea Water Desalination Plant coupled with a Hydroponic Plantation System." The plant was developed at the Institute of Gas Technology in Chicago and was built on the Mediterranean Coast of Egypt. Dr. ElDifrawi during his directing of A&L Coal's energy program developed a system for utilizing wasted heat to generate cooling cycles. This resulted in US patent #4,266,404. |