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Modern plants are often "combined cycle" generators, meaning that the exhaust of one engine is used as the heat source for another. The hot exhaust from the jet is used to boil water into steam, and the steam is used to turn a second turbine; if ...

Capturing energy from the earth's heat is pretty easy pickin's for geologically-active areas of the world like Iceland, Indonesia, and Chile. In some locations, hot fluids are so near the earth's surface that heat from naturally-occurring hot fluids can be directly circulated through buildings for heating. Iceland, in particular, takes advantage of this low-hanging energy fruit. However, in most areas of the world where geothermal energy is captured, the heat is used to generate electricity. Conventional Geothermal Energy Unlike some of the more common alternative energies - hydro, solar, and wind - geothermal is impervious to weather conditions. This independence means it provides excellent base load electricity. Currently all commercial geothermal electricity is generated by so-called conventional systems, whereby naturally- occurring hot water or steam is accessed at comparatively shallow depths in areas of very high geothermal gradient. Wells are commonly drilled to depths on the order of 2 km. The water or steam they produce is used to spin turbines that in turn generate electricity.

Evaporator comes in different types but all types of evaporators work on the same principle, using steam as an evaporating medium.

Get the detailed info on evaporator that helps you distinguish evaporator according to its application.

Ausra is a leading player in the field of concentrating solar power (CSP), which utilizes mirrors to focus sunlight on a heating element containing a fluid to produce a steam that drives a turbine to generate electricity.

Geothermal energy is in the dock in Germany, but some scientists are pleading for leniency. A government panel is investigating claims by the geological survey for the state of Rhineland-Palatinate that a geothermal plant triggered a magnitude-2.7 earthquake on 15 August in the town of Landau in the state. If the panel finds against the company that built the plant, Geo X of Landau, it could be shut down. Geothermal plants work by pumping water into hot rocks several kilometres down, forcing small cracks in the rock to expand. Steam escapes through the cracks to the surface, where it drives a turbine, producing clean energy. But critics say the process increases the risk of earthquakes. "Any process that injects pressurised water at depth into rocks will cause them to fracture and possibly trigger earthquakes," says Brian Baptie, an earthquake specialist at the British Geological Society.

NV Energy deal, legislation in Congress could help state develop solar power SolarReserve, a California energy company, is planning to build a 100-megawatt solar thermal power plant near Tonopah, and on Tuesday it announced that NV Energy had agreed to buy power from the plant. As Stephanie Tavares reported on the Las Vegas Sun's Web site, the plant is designed to use heat storage technology that will allow its steam turbines to run at night. The Crescent Dunes Solar Energy Project is being vetted by the Bureau of Land Management. The company says it could break ground by 2011 and expects construction to last two years.

Very interesting presentation at the TED Conference.  Not quite a nuclear battery, but a really good redesign of nuclear power systems. excerpt: "Instead of finding a new way to boil water, Wilson's compact, molten salt reactor found a way to heat up gas. That is, really heat it up. Wilson's fission reactor operates at 600 to 700 degrees Celsius. And because the laws of thermodynamics say that high temperatures lead to high efficiencies, this reactor is 45 to 50 percent efficient. Traditional steam turbine systems are only 30 to 35 percent efficient because their reactors run at low temperatures of about 200 to 300 degrees Celsius. And Wilson's reactor isn't just hot, it's also powerful. Despite its small size, the reactor generates between 50 and 100 megawatts of electricity, which is enough to power anywhere from 25,000 to 100,000 homes, according to Wilson. Another innovative component of Wilson's take on nuclear fission is its source of fuel. The molten salt reactor runs off of "down-blended weapons pits." In other words, all the highly enriched uranium and weapons-grade plutonium collecting dust since the Cold War could be put to use for peaceful purposes. And unlike traditional nuclear power plants, Wilson's miniature power plants would be buried below ground, making them a boon for security advocates. According to Wilson, his reactor only needs to be refueled every 30 years, compared to the 18-month fuel cycle of most power plants. This means they can be sealed up underground for a long time, decreasing the risk of proliferation. Wilson's reactor is also less prone to proliferation because it doesn't operate at high pressure like today's pressurized-water reactors or use ceramic control rods, which release hydrogen when heated and lead to explosions during nuclear power plant accidents, like the one at Fukushima in 2011. In the event of an accident in one of Wilson's reactors, the fuel from the core would drain into a "sub-critical" setting- or tank-

This paper is focussed on thermal storage technologies using phase change materials (PCMs) in the temperature range of 120-300°C for solar thermal power generation and high temperature process heat. As the state-of-the-art reference system a steam accumulator is described, which typically has a volume-specific thermal energy density of 20-30 kWh m-3.

Hydrogen is a better source of energy than you think, according to Fujitsu. The Japanese electronics giant inaugurated a 200-kilowatt hydrogen fuel cell from UTC on Friday that will provide electricity as well as heat to the buildings on its campus here. The fuel cell--which sits in the parking lot and looks like a pair of giant green dumpsters--provides two types of energy to the facility. First, a unit heats methane with steam to create hydrogen. The hydrogen is passed through a proton exchange membrane (PEM). The electricity produced by the reaction with the PEM runs lights, computers and other equipment

Talking about turning the world upside down.