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6.30.2010
Energy Use in the US Statts and Figures
How many renewable energy facilities covering how much area are required to meet the electrical energy demand of the United States? The following will identify some critical issues along with a possible solution, while demonstrating that renewable energy resource installations could be available to meet the required demand, should sufficient will be exerted to actually install. One of the major dilemmas facing the widespread implementation of renewable energy resources is resolution of how to distribute the newly installed resources. The existing grid is predicated on the use of very large centralized generation sources, e.g., dams, power plants; while most renewable energy, e.g., photovoltaic, wind, is very conducive for distributed generation.
The existing very large generators are large in the sense of the amount of power they produce per unit area. Renewable sources require much more land area for a comparable power production. A major benefit of this conundrum could be the installation of a large number of small generation sources at existing sites, e.g., houses, businesses, ranches, farms with no requirements to install additional distribution capacity. The downside is how to plan for the transfer of energy from where generated to where needed when the renewable energy generators are not firm, i.e., the amount generated is neither constant nor predictable. This is exacerbated by the financial consideration that nonrenewable generators are generally most efficient and cost effective when operated at full capacity. A model for solving the problem or more accurately, debugging the solution, is to initiate the widespread use of renewable energy generation in rural areas. Although eventually the largest market will be in urban areas, virtually all problems could be resolved on a small scale by implementation in rural areas first. Rural areas have a small fraction of the total population; however, this fraction is highly independent and well skilled in solving problems. Unfortunately, this is also the segment of the population that has the least disposable income to invest in anything, much less energy with a long term payback. Thus, some sort of cash flow assistance will be required, noting tax credits are of little benefit to those whose income is not sufficient to pay much in taxes. In order to understand the magnitude of the task, one must consider how much electrical energy is going to be required to be converted from nonrenewable to renewable sources. The United States consumes ~ 4.1 trillion-kWh per year (4.1x1012 kWh/year), note this does not include fossil fuel energy consumption for transportation, heating, and other uses. Since a significant fraction is required for industrial use, which requires large concentrated sources, e.g., existing power plant dams will still be operational for 100 or more years depending on location, one could then reasonably expect the want to generate ~ 3 trillion-kWh per year with renewable sources. There are 5 primary sources of renewable energy generators in operation today; four sources can be used for large commercial (e.g., utility scale, light industry, or towns) generation and three sources that are primarily for residential use. Depending on size of the installation, two of the sources can be in either category.
For wind, assume that 0.99 trillion-kWh/year are produced by commercial size wind generators and the rest with residential. Assume that each 5 MW wind generator operates 12 hours per day for 300 days per year (allowing time for maintenance and variations in wind velocity and duration). Each wind generator then provides 18 Mega-kWh/year. Thus, approximately commercial 55,000 wind generators are needed. If each wind generator occupies ~ 1 square mile, then ~ 55,000 square miles are needed, noting that almost all the land near a wind generator can be used for ranching or farming purposes. This represents a small fraction of the land under cultivation in the western USA, where much of the wind resources are. Also, wind generators can be place off-shore. For residential wind generators, assume that each 15 kW windmill operates 6 hours per day for 250 days per year (allowing for conversion efficiency, time for maintenance, and variations in wind velocity and duration). Each wind generator then provides 22.5 kilo-kWh/year. Thus, approximately residential 450,000 wind generators are required, which is significantly lower than the total number of small businesses, farms, ranches, and rural residences in the USA. With larger residential windmills, especially for farms and ranches, not so many windmills would be required. A 25 to 50 kW windmill is much more appropriate for farm or ranch use, noting some farms that use well irrigation would need several wind generators or larger, e.g., 150-200 kW wind generators. For residential PV, assume a module conversion efficiency of 15% from the nominal solar radiance of 1000 W/m2. Assume a DC to AC conversion efficiency of 85% and operation for 6 hours per day for 300 days per year (allowing for variations for systems installed at a wide variety of locations). Thus each m2 of solar module area will produce 230 kWh/year. In order to generate, 0.5 trillion-kWh/year, there needs to be ~2,175,000,000 m2 of PV modules. This is about 840 square miles of solar PV modules, smaller than most Western state counties. Assuming that the majority, say 1,500,000,000 m2, are directly used on single family dwellings, with the availability of 75 m2 per dwelling (still allowing room for solar hot water heating collectors on the south facing roof), then ~20,000,000 homes are necessary. The remaining PV generation (~ 0.16 trillion-kWh/year) would come from commercial PV facilities. Assuming a capacity of 200 kW operating 8 hours per day (use of at least ground mount single-axis trackers) for 320 days per year (allowing for variations for systems installed at a wide variety of locations) each location would generate 512,000 kWh/year. There would need to be at least 312,500 such installations, with each installation having about 1,570 m2 of PV modules and assuming an area efficiency of 10% (for trackers and mounting) so occupying ~ 4 acres. For solar thermal generation, assume each 100 MW of power capacity requires 1000 acres, including all support structures. Since solar thermal requires significant water usage for cooling (up to 1000 acre-feet/year per 100 MW), not all locations are suitable. Assuming a 500 MW plant produces 8 hours per day for 300 days per year, each location produces 1.2 billion-kWh/year. For the 1 trillion-kWh/year, then ~850 plants, occupying 4.25 million acres or 6,640 square miles (the size of larger Western state counties) All of these estimations are just that, estimations; however, the numbers clearly show that renewable energy resources can provide the majority of the electrical energy needs of the USA. As renewable energy resources are installed, no new fossil fuel power plants need be built. Eventually, all fossil fuel plants can be allowed to retire, starting with the least efficient first. The transition cannot be smooth, since both nonrenewable and renewable energy sources are only available in discrete units; however, by starting with implementation in rural areas the methods and techniques can be fully developed, which will ease large scale implementation in urban areas. Reference |
6.29.2010
New System, Algae Cleans Water & Fertilizes
act as slow-release fertilizer
seedlings could thrive on an organic fertilizer
management of the cycle of nitrogen and phosphorus
capture costs of around $5 to $6 per pound of nitrogen and $25 per pound of phosphorus
The system is practicable now
Testing: could clean up runoff that has already made it into the water system
Tags
- Science, Jeremy Hsu, agriculture, algae, environment, farming, fertilizer, water, water purification
In New System, Algae Cleans Water, Then Transforms into Organic Fertilizer
- The algae systems can capture most of the phosphorus and nitrogen in runoff
- By Jeremy Hsu Posted 05.07.2010 at 3:57 pm 7 Comments
Nature's Green Cleaner Air-dried algae (shown above) from an algal turf scrubber captured most of the nitrogen and phosphorus in the manure. USDA/Edwin Remsburg
Algal blooms that feed on nutrient-rich manure and fertilizer runoff can deplete oxygen in the water when they die, creating inhospitable dead zones -- but the same green scum might also serve as a preventive solution upstream. A microbiologist with the U.S. Agricultural Research Service used algae to recover almost 100 percent of nitrogen and phosphorus nutrients from manure, and suggested that the dried-out algae can then act as slow-release fertilizer for farms.
The solution offers better management of the cycle of nitrogen and phosphorus nutrients which plants depend on. Experiments have shown that algae can capture 60 to 90 percent of nitrogen and 70 to 100 percent of phosphorus from a mixture of manure and fresh water, as proved by the U.S. Department of Agriculture (USDA) on four dairy farms.
The system is practicable now. Farmers would have to set up algal turf scrubber (ATS) raceways covered with nylon netting to serve as a platform for algae to grow upon. The capture costs of around $5 to $6 per pound of nitrogen and $25 per pound of phosphorus is about the same as other manure-management practices.
But Walter Mulbry, the USDA microbiologist, also showed that corn and cucumber seedlings could thrive on an organic fertilizer made from the dried-out algae. That might allow farmers to recoup even more of the costs from the ATS system, or perhaps turn a profit if the price is right.
Mulbry has already begun another study to see whether fertilizer made from chicken and poultry litter can also benefit from the algae cleanup system. And he has also begun studying whether the ATS systems can remove nitrogen and phosphorus from estuaries that flow into the Chesapeake Bay, so that they could clean up runoff that has already made it into the water system.
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Algae's versatility has already won over scientists who see it as the biofuel of the future, and the tiny plant organisms have also been proving their worth in scrubbing carbon dioxide and nitrous gas from industrial smokestacks. A company called Algenol has even looked to using algae-derived plastic as a replacement for petroleum-derived plastic.
Even the U.S. Department of Energy and various branches of the U.S. military have begun seriously exploring algae-derived solutions. If that doesn't entirely ensure a clean future, it at least suggests a future with a scummy color palette ranging from pale to bright green.
[USDA]
- Brought to you by: Scotts Contracting GREEN BUILDER_St Louis "Renewable Energy" Missouri http://www.stlouisrenewableenergy.com, contact scotty@stlouisrenewableenergy.com for additional information
Great News in Wind Turbine Development.
I happily bring the following article to my readers.
Scotts Contracting offers Wind Power Systems and the Required Installation and Electric Hook-Up.
contact scottscontracting@gmail.com to schedule your free Green Site Evaluation.
Massive Wind Turbine Survives Pummeling By Equally Massive Testing Machine
- By Rebecca Boyle Posted 05.27.2010 at 9:30 am 4 Comments
Massive Turbine Test Samsung's 90-ton, 2.5-megawatt wind turbine drive train meets the National Wind Technology Center's 2.5-megawatt dynamometer. Rob Wallen, National Renewable Energy Laboratory
Wind turbines of the future will be hulking behemoths, each capable of producing multiple megawatts of power. But before they're installed in wind farms, manufacturers need to be sure they are built to last. To this end, a monstrous 2.5-MW turbine--one of the world's largest--just survived an equally big test.
The 2.5-megawatt dynamometer at the National Renewable Energy Laboratory blasted the turbine's drive train, built by Samsung, with 12.6 million inch-pounds of torque, the energy lab says.
In other words, the turbine drive train went through years of wear and tear in about two months. It was the largest full-scale dynamometer test of a wind turbine ever done in the United States, NREL says.
The dynamometer — a cool name for a machine that measures force and torque — has a 3,550-horsepower electric motor coupled to a three-stage epicyclic gearbox, according to NREL. It can produce speeds up to 30 revolutions per minute, meaning it can simulate anything from a slight breeze to a full-force gale.
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Tags
- Technology, Rebecca Boyle, environment, renewable energy, vertical wind turbine, wind power, wind turbines
- Computer models simulate the tower, rotor and turbine blades, and other models calculate what the main shaft torque should be, depending on weather conditions. The shaft therefore responds to various wind conditions just like it would in the field, NREL says.
- Special Turbine Delivery: NREL technicians unload a 90-ton Samsung wind turbine drive train after it made the trip on semi-trailers from Houston to NREL's National Wind Technology Center. Rob Wallen, National Renewable Energy Laboratory
Samsung has a 2.5-MW turbine in operation in Texas, but it's never been tested above 600 kilowatts. Samsung wanted to take its drive shaft out for a spin, so the company shipped the 185,000-pound device from Houston to Golden, Colo., using a gigantic 185-foot-long, 19-axle rig.
All this bigness is peanuts compared to future wind turbines, however — NREL is already building a 5-MW dynamometer, which would be capable of testing the next generation of huge wind turbines.
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Solar Energy-Our Government, Govt Fees Hinder Solar Development
Solar Energy-Our Government, Govt Fees Hinder Solar Development
this article is somewhat of a follow up article post: http://stlouisrenewableenergy.blogspot.com/2010/06/energy-in-our-future-where-will-it-come.html. Where I posted: "c) Politics within the USA will Keep the Renewable Energy Resources from becoming Main Stream and affordable to the masses."I urge everyone to Contact your Legislative Department and let them know you approve Solar Energy Production. Feel Free to utilize the following Link.sign the letter now.
America faces unprecedented economic, national security and environmental challenges. The solution – transition to clean, renewable energy. Join our movement of more than 5 million calling for clean energy and climate policies that will create millions of jobs, make us energy independent and solve the climate crisis.
sign the letter now.Tags
Government Fees Could Be Hindering the Rollout of American Solar Power
- A bureaucracy built for oil and gas leasing punishes the most efficient technology
- By Clay Dillow Posted 06.17.2010 at 2:17 pm 43 Comments
Solar One's Mojave Desert Solar Plant U.S. Department of Energy
Given the way the government is beating up on a certain foreign oil company this morning, it's easy to think perhaps this is the impetus America needs to align government, industry, and popular sentiment toward developing home-grown renewable energy sources. But a look at the charges the Bureau of Land Management levies against solar power projects on public lands tells a different tale. In fact, it seems the more efficient your power plant, the more the BLM wants you to pony up.
The government justifiably charges private businesses rent if they want to operate solar or wind arrays on public lands. But on top of that there is a compicated fee structure -- the "megawatt capacity fee" -- that drives the total rent as high as twice the market value for comparable private land. The BLM -- again, justifiably -- says its just trying to get taxpayers something back for private enterprise that benefits from the land they own. But the way the fees are structured is somewhat suspect.
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The BLM is essentially charging more efficient technologies more in megawatt capacity fees. According to NYT's Green Blog, a photovoltaic plant that deploys big PV panels has to pay $5,256 per megawatt. But more efficient solar thermal plants that use solar energy to turn a steam-driven turbine are hit with a $6,570 fee. If either technology is coupled with an energy storage system that delivers power even when the sun doesn't shine -- a key component to making solar power more than just a secondary energy resource -- the fee takes a flying leap to $7,884 per megawatt.
If you're generating 550 megawatts, like First Solar's Riverside County, Calif., PV array is expected to, that's a lot of money, and the consumer has to pay that. We're more scientists than economists over here, but that fee structure seems like it creates a vast disincentive for companies to deploy more efficient, better solar technologies. It's a consequence of trying to adapt archaic oil and gas leasing models to new energy paradigms, and frankly it seems at odds with our stated goal -- and I'm talking directly to President Obama and DOE chief Stephen Chu here -- of developing renewable energy resources right here at home.
Public lands belong to taxpayers and indeed private enterprise should pay fair market value to lease them, but saddling these projects with outrageous costs pushes up the price of solar energy, keeping carbon fuels in their current position as market darling. Weaning ourselves from foreign oil -- and eventually all oil -- seems a far better public reward than a monetary benefit paid to the public coffers.
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June 29-New Solar Cell Technologies-
thin-film, flexible copper-indium-deselenide solar cells
cheap to produce
tuff and sturdy enough to withstand the stresses of the battlefield.
That means flexibility, durability, and efficiency never before seen from commercial solar technology.
Tags
- Technology, Clay Dillow, battlefields, energy, environment, green tech, military, photovoltaics, renewable energy, solar cells, solar power
To Power Future Battles, DARPA Wants Combat-Tough Solar Cells
- By Clay Dillow Posted 06.23.2010 at 10:00 am 2 Comments
Making Better Solar- Researchers work on a sheet of flexible solar cells at the University of Delaware's Institute of Energy Conversion. University of Deleware Institute of Energy Conversion
In recent years, the U.S. military has been making small strides toward a greener energy standard – the Navy wants to create a green strike group by 2012, while the Air Force has been testing biofuels in its aircraft. But for troops on the ground relying increasingly on electronic devices, solar is the way forward. With that in mind, DARPA has assembled an industry-academic team of photovoltaic leaders to create the next generation of battle-ready solar cells that achieve 20 percent conversion while standing up to harsh combat conditions.
The $3.8 million dollar, 54-month Low-Cost Lightweight Portable Photovoltaics program (PoP) includes several private PV companies and will be led on the academic side by the University of Delaware's Institute of Energy Conversion (IEC) with the goal of demonstrating solar cells that are not only cheap to produce, but sturdy enough to withstand the stresses of the battlefield. That means flexibility, durability, and efficiency never before seen from commercial solar technology.
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To do so, the research team will push thin-film, flexible copper-indium-deselenide solar cells to their limits, tapping the technology portfolios of at least four different industry partners to meet DARPA's goals, which – per usual – are lofty even given the four-and-a-half year time frame. By comparison, commercial solar panels range from 5-20% efficiency, but flexible thin-films generally average somewhere between 7-11% efficiency, and they're nowhere close to combat-ready.
To make the leap, the team will obviously have to focus on the dual goals of upping efficiency while turning the delicate into the durable. That's going to take some serious innovating in materials and PV tech, but the good news – as is often the case with DARPA projects – is that advances in the technology should eventually trickle on down to civilian tech, giving all of us tough, portable solar powered devices to abuse.
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