Tag Archives: Power Production

Renewable Geothermal Power Expands in Nevada

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Geothermal energy is a growing industry, with more plants going into Nevada’s mostly untapped resource.

Source: www.ktvn.com

Geothermal energy is a growing type of clean energy, and nowhere is that more true than in Nevada. Ormat Technologies has built a geothermal plant every year since 2005.  […]

“This is what the future is going to bring,” Gawell said. “You will see more and more of this in years ahead and it is already a boom for Reno.”

The Steamboat Complex is a binary plant that takes hot water from deep underground, to produce power.

“We convert the heat that’s in the fluid to electrical energy,” Bob Sullivan, Senior Vice President of Ormat Technologies said. “Then we put all the fluids back into the ground where it gets reheated. So, it’s a sustainable cycle.”  […]

Along with electricity, these facilities create economic development, putting hundreds of people to work, drilling wells and building the plants.   About 500 people have permanent jobs with Ormat, in the United States.  Another 500 people work for the company around the world.

“It’s a job engine,” Sullivan said. “It takes a lot of maintenance. It takes a lot of people. It takes a lot of workers, a lot of subcontractors to keep one of these facilities running.”

While the cost of fossil fuels goes up and down, geothermal stays steady. The fuel cost is upfront, in the form of drilling wells. Gawell says what is lost in capital and labor costs is saved in fuel costs. […]”<

See on Scoop.itGreen Energy Technologies & Development

Energy Efficiency and Renewables Drives Smart Grid Technologies Market – Research & Developments

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The market for smart grid technologies is evolving rapidly as the need for a more responsive, automated power grid rises worldwide.  …

Source: www.navigantresearch.com

>”The fundamental technology for injecting intelligence into the grid has been in existence for years – more than a decade in some cases. However, the past 18 to 24 months have seen accelerating technological advancements and shifting priorities among utility industry stakeholders.

Transmission system upgrades are driven by the need to interconnect offshore or remote wind and solar farms, as well as ongoing electrification across Asia Pacific and developing regions. Falling costs for devices and communications networking, combined with the increasing emphasis on reliability and energy efficiency, will lead to robust growth in the substation and distribution automation (SA and DA) markets. Meanwhile, government mandates, especially in Europe, will drive strong smart meter penetration gains over the next decade. At the same time, utilities are facing more competition than ever and squeezed margins. These issues, along with the proliferation of smart devices in the grid, will drive impressive growth in demand for more powerful utility IT solutions and analytics. Navigant Research forecasts that global smart grid technology revenue will grow from $44.1 billion in 2014 to $70.2 billion in 2023.

This Navigant Research report analyzes the global market for smart grid technologies, with a focus on transmission upgrades, SA, DA, information and operations technology (IT/OT) software and services, and advanced metering infrastructure (AMI). The study provides a detailed analysis of the market drivers, challenges, and trends, as well as regional and country factors, for each smart grid technology segment. Global market forecasts for revenue, broken out by technology, application, component, and region, extend through 2023. The report also provides profiles of key grid infrastructure vendors and includes information on 150-plus other types of companies, major global utilities, and smart grid-related industry associations.

Key Questions Addressed:

Which smart grid technology segments are the largest and how quickly are they expected to grow?

What are the key market drivers and challenges for each smart grid technology segment?

What are the most important new trends affecting the pace of investment in smart grid technologies?

What regional factors are affecting the pace of investment in smart grid technology?

Who are the key vendors in each category of smart grid technology?   […] “<

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Development of small scale renewable landfill bio-gas electric generator in UK

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ACP funds for development of small scale landfill gas engine in UK Energy Business Review ACP’s biogas partner AlphaGen Renewables, which oversee the installation and operation of a 50kW microgeneration landfill gas engine, will develop the project.

Source: biofuelsandbiomass.energy-business-review.com

>”The project is expected to generate power from the landfill gas resource at the site under a 20 year agreement with Norfolk County Council.

AlphaGen Renewables chairman Richard Tipping said: “We are delighted to be partnering with ACP on this project, which is set to deliver strong returns. Renewables such as biogas are playing a growing role in the UK’s energy production.”

Albion Ventures Renewables head David Gudgin said: “Biogas is an increasingly popular area of renewable energy and we are looking forward to working with AlphaGen both on this project and others in the future.”<

See on Scoop.itGreen Energy Technologies & Development

Liquid Air Proposed as Clean Fuel Replacement for Diesel Vehicles

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Liquid air could potentially be a source of clean vehicle power for commercial trucks in the UK by 2020, according to a report by the Liquid Air Energy Network.   Source: www.environmentalleader.com >”The report projects that a liquid-air powered British fleet of 36,000 vehicles by 2025 could save more than 1 billion liters of diesel fuel, 1.4 million metric tons of carbon dioxide equivalent (well-to-wheel), and a net of £113 million ($193 million) in investment costs. […] Although liquid air is not currently in mass production, liquid nitrogen, which has similar properties, could easily be used as a temporary substitute for early liquid air vehicles while waiting for production of liquid air to ramp up to projected demand levels. Although several engine concepts in this area are being developed, report authors decided to focus on the two closest to commercial deployment: the zero-emissions “power and cooling” engine for truck and trailer refrigeration, and the diesel-liquid air “heat hybrid” engine for buses, delivery trucks and other commercial vehicles. The Dearman Engine Company is developing both applications, and its refrigeration engine begins on-vehicle testing this year and is scheduled for commercial production in 2016. According to the report, liquid air is now being recognized as a potentially powerful new energy source, and the concept has received approximately £20 million ($34 million) in government grants, including £9 million ($15.4 million) to develop liquid air energy storage for storing grid electricity, £6 million ($10 million) for a new Centre for Cryogenic Energy Storage at Birmingham University and £5 million ($8.5 million) to develop liquid air vehicle engines.”<   See on Scoop.itGreen Energy Technologies & Development

Province Calls for Renewable Energy Storage Systems Demonstration Projects

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Most of the new systems will be able to turn on a dime, storing and releasing energy almost instantaneously to help balance out the supply and demand over the course of a day

Source: www.theglobeandmail.com

>”Ontario has embarked on a quest to find the holy grail of renewable energy – an effective means to store the power generated by intermittent wind and solar installations.

The province’s Independent Electricity System Operator (IESO) recently chose five companies who will build a dozen demonstration projects designed to capture and release energy. That would allow the electricity grid to react to fluctuations in power production, which are becoming more significant with the addition of renewables whose output varies depending on how the wind blows and sun shines.

[…]

The technologies that will be tested include advanced batteries, systems that store power in the form of hydrogen, and even flywheels that hold energy as kinetic energy in a spinning rotor.

Bruce Campbell, president of the IESO, called storage facilities a “game changer” for a grid that was designed to produce electricity at exactly the same time it is consumed. “Energy storage projects will provide more flexibility and offer more options to manage the system efficiently,” he said.

The test projects will be distributed at various locations around the province, and will be connected to different parts of the grid to see how effectively they can help balance supply, demand and other transmission issues.

Among the suppliers are Hydrogenics Corp., which will test a hydrogen storage system, and Hecate Energy and Canadian Solar Solutions Inc., which will use various battery technologies. Convergent Energy and Power LLC will test a flywheel that converts electricity to kinetic energy stored in a rotor. Dimplex North America Ltd. will install thermal systems in apartments in Hamilton, Ont., that store electricity as heat in special bricks, releasing it later when the building needs to be warmed.

Rob Harvey, director of energy storage at Hydrogenics, said his company’s test system will incorporate an advanced electrolysis system that uses electricity to split water into hydrogen and oxygen. That hydrogen can then be used in a fuel cell to generate electricity when needed. Coupling the fuel cell and the electrolyser means power can be effectively stored for any length of time and dispatched as needed.

If the tests are successful, Mr. Harvey said, this could be a significant new line of business for Hydrogenics, which now makes hydrogen-producing systems for industrial customers, as well as fuel cells, which are essentially engines that use hydrogen as fuel.”<

 

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Grid Scale Energy Storage Solutions For Future Virtualization

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Examines grid scale energy storage solutions ranging from pumped hydro, compressed air, thermal storage, advanced batteries, fuel cells and purely electric storage systems.

Source: greeneconomypost.com

Renewable energy sources often have a common problem of matching supply with demand, hence the need for energy storage to bridge the gap.  One major component of future VPP (Virtual Power Plants) is energy storage, in the form of battery storage, fuel cells, pumped hydro, flywheels, compressed air or other forms of existing and new technologies.

One promising form of energy storage combines gravity with water where energy is stored in raising heavy weights.  Electrical energy is converted to potential energy during periods of over-supply and then converted back to electricity when demand is greater than supply.

>”A Cutting Edge Variation of Pumped Hydro

Gravity Power, LLC, a privately-held company, based in Southern California (in Goleta, CA just north of Santa Barbara) is developing a novel grid-scale energy storage system for global commercialization called the Gravity Power Module (GPM). Like pumped hydro the working energy carrier is water that is pumped between a high pressure and a low pressure reservoir running a reversible generator/pump assembly to either produce power by drawing down the high pressure reservoir or store it up by pumping water from the low pressure store back into the high pressure store. In this sense it operates on the very same principles – and thus can also benefit from existing capital equipment, such as the reversible hydro generator/pump assemblies for example – as traditional pumped hydro.

Gravity Powers technology circumvents traditional pumped hydro difficulties related to siting, negative environmental impact, huge land demands, permitting, long-lead times and the very large investment required, by burying it all underground…. literally.

The GPM system uses a very large and very dense high mass piston that is suspended in a deep, water-filled shaft. The piston is equipped with sliding seals to prevent leakage around the piston/shaft interface and its immense mass pressurizes the supporting water column beneath it. A high pressure pipe from the bottom of this shaft enables water to be run or pumped through a generator/pump assembly of the same types now used in pumped hydro systems. The low pressure low energy potential water is returned above the piston adding somewhat to its weight and further pressuring the remaining high energy potential water column.

The massive piston moves up and down the shaft, storing and releasing power in a closed sealed cycle. It is compact with a small land footprint and the units can be clustered together into larger groups. It also is environmentally benign, no toxic chemicals or explosive dangers.

I like the scalable nature of this store that makes it suited to incremental growth of capacity. I also like how this energy storage system could be placed very near the big urban areas of greatest need for this kind of electric capacity. The fact that this energy storage system can take advantage of a lot of already existing infrastructure and technical knowhow from the existing pumped hydro sector is a definite advantage.

I would like to see more details on the costs of the boring of the immense vertical shafts; the long term performance metrics of the shaft seals (that would be an expensive repair job I would think. All in all I think this or something like it is a strong contender in the energy storage sector.”<

Read more: http://greeneconomypost.com/fifteen-grid-scale-energy-storage-solutions-watch-15924.htm#ixzz35bedEesM

VPP – New Models for the Distributed Grid Network

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National Instruments, LocalGrid, and Toronto Hydro pilot the software-defined, peer-to-peer distributed grid architecture.

Source: www.greentechmedia.com

>” […] Because each CompactRIO endpoint is inherently flexible, LocalGrid can provide “protocol conversion which we can update dynamically over the air, analytics that we can update to the system, and run multiple applications on the same device,” he said. This is similar in intent to the kind of field-distributed computing capability that Silver Spring Network’s new SilverLink Sensor Network platform and Cisco’s new IOx platform are opening up to partners, but it’s pretty far ahead of the capabilities of the vast majority of today’s grid edge devices.

In fact, in terms of technology that allows interoperability without a lot of expensive and complex pre-integration work, “The existing players do not have solutions that will do this job,” Leigh said. “They’re not fast enough, they’re not open enough, or they don’t have solutions that are cost-effective enough in the distribution space.”

So far, LocalGrid has connected four sites with a combination of solar PV and wind turbine inverters and metering hardware, and is now in the midst of its second phase of developing custom algorithms for tasks such as detecting faults and forecasting solar and wind generation and loads on distribution circuits, Leigh said. These aren’t necessarily huge challenges for Toronto Hydro’s existing IT infrastructure at pilot scale, “But if we were to multiply that across the network, it’s just not feasible to get all that data to be analyzed into a back-end system,” he said.

As for how to expand LocalGrid’s software capabilities to a broader set of grid endpoints, Leigh cited Cisco’s IOx-enabled grid routers as potential future partners. Other big grid vendors like General Electric, ABB and Siemens “are at different stages starting to open up their systems,” he said. “The question that still has to be worked out is how much third-party development can take place on their new systems.”

That’s the same question that Duke has been asking the grid vendor community, via its plans to open its source code and hardware adapter reference designs to the public. The past half-decade has seen open-source grid systems emerge from simulation software and data management tools to a few real-world grid applications, albeit still in the experimental stage. Perhaps the next half-decade will see the open grid edge platform attain real-world status.”<

Virtual Power Plants (VPP): A New Tech Based Utility Model for Renewable Power Integration

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Today’s global energy market is in the midst of a paradigm shift, from a model dominated by large centralized power plants owned by big utilities to a mixed bag of so-called distributed energy generation facilities — smaller residential, commercial and industrial power generation systems &mdas

Source: www.renewableenergyworld.com

>”Virtual Power Plants

One distributed generation technology with significant growth potential is the virtual power plant (VPP). In the VPP model an energy aggregator gathers a portfolio of smaller generators and operates them as a unified and flexible resource on the energy market or sells their power as system reserve.

VPPs are designed to maximize asset owners’ profits while also balancing the grid. They can match load fluctuations through forecasting, advance metering and computerized control, and can perform real-time optimization of energy resources.

“Virtual power plants essentially represent an ‘Internet of Energy,’ tapping existing grid networks to tailor electricity supply and demand services for a customer,” said Navigant senior analyst Peter Asmus in a market report. The VPP market will grow from less than US $1 billion per year in 2013 to $3.6 billion per year by 2020, according to Navigant’s research — and one reason is that with more variable renewables on the grid flexibility and demand response are becoming more crucial.

Asmus called VPPs “an ideal optimization platform for the coming transformation of the power grid,” adding that both supply and demand flexibility will be increasingly necessary to accommodate fast ramping periods and address corresponding supply forecast errors.

German utility RWE began a VPP in 2012 that now has around 80 MW of capacity. According to Jon-Erik Mantz, commercial director of RWE Energy Services in Germany, in the near future flexibility will become a commodity. Virtual power plants generate additional value from the flexibility they can offer the grid, he said-so, for RWE, “this is why we concentrate on building VPPs.” As large utilities’ market share falls in response to growing self-consumption, he said, utilities can still “be part of a VPP and profit.”

Dr. Thomas Werner, senior key expert in product lifecycle management at Siemens, said that in order to integrate diverse smaller energy sources, “You need an energy management system with good data models which represents energy resources on the one hand and, on the other, the energy market environment.” Werner believes VPPs fulfill these conditions and are the best way to integrate a growing number of power sources into the grid and the market.

“VPPs can be handled like other conventional generation,” he said. “They can target different energy markets and regulatory environments. They can play as important a role as conventional concentrated generation.”

“No Real Competition”

“From my point of view, there is no real competition for the VPP concept,” Werner said, pointing to VPPs’ use of cheap and ubiquitous information and communication technologies, while other technology trends like building energy storage systems incur comparatively heavy costs. VPPs can also avoid expensive installation costs in, for example, a home system, he notes. Self-consumption for home or industrial use is hampered by having to produce “the right amount of power at the right time.”

VPPs can deliver needed energy at peak usage times, and can store any surplus power, giving the energy aggregator more options than would exist in a single power plant. Other advantages include improved power network efficiency and security, cost and risk savings in transmission systems, increased value from existing infrastructure assets and reduced emissions from peaking power plants. And, importantly, VPPs can also enable more efficient integration of renewable energy sources into the grid by balancing their variability.

For example, explains Werner, if one wind power source generates a bit more energy than predicted and another generates a bit less, they will compensate for each other, resulting in a more accurate forecast and making it easier to sell the capacity in the market or to use it in power systems operation.

A VPP can also combine variable renewable power sources with stable, controllable sources such as biomass plants, using the flexibility of the biomass source to smooth out any discrepancy between planned and actual production.”<

Deep Energy Retrofits–A Necessity for Old Buildings

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“Studies show that focusing on energy efficiency and usage from buildings and homes is still a more effective and less expensive choice than investing in new energy sources. After all, on a global scale, residential and commercial buildings account for 40% of total final energy consumption, from HVAC, lighting, water heating, and further building functions, so a push on diminishing wastefulness in this area will have a much greater and more immediate effect than focusing on other, less sure practices (such as building wind turbines). At the moment, revamping a building to be more energy efficient will have instant effects on savings and efficiency, which is where retrofitting comes into play. Retrofitting involves giving older buildings, which often have out-of-date heating, cooling and lighting systems, an internal and external update. The entire process isn’t cheap, but it’s far less pricey than starting from the bottom up, and causes far less havoc for businesses who can’t afford to move offices while construction is taking place.”

via From Guest Blogger Blake Meredith: Deep Energy Retrofits–A Necessity for Old Buildings.

Geothermal Energy: Superior to Natural Gas for Powering the Electrical Grid

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See on Scoop.itGreen & Sustainable News

Geothermal resources provide about 3,440 MW of power to the United States electrical grid as of early 2014.

Duane Tilden‘s insight:

>”In a recent report, the Geothermal Energy Association explored geothermal power’s unique values that make it essential to the U.S. energy mix.  These plants have the same important baseload qualities coal now provides for over two thirds of the electric power generation in the nation.  Geothermal can be a high-value substitute for baseload fossil fuel or nuclear power plants, providing firm, clean power 24 hours a day regardless of extraneous conditions.

“As state and national policies move to significantly reduce climate changing power emissions, geothermal is a baseload clean energy that can replace baseload fossil fuels at a minimum cost to the power system,” says Karl Gawell, GEA’s executive director.

Gawell explains that as the grid uses more variable energy resources, which it most certainly will, the flexibility of geothermal energy is an attribute that regulators are still learning about.  “Flexible geothermal can help firm the system, allowing for imbalance, and is able to provide supplemental reserve,” he adds.

The U.S. continues to make strides toward a cleaner energy mix largely through wind and solar contracts to meet goals of state Renewable Portfolio Standards. This creates a greater need for firming power, and although geothermal can provide this as well, it could get lost in the mix if natural gas becomes a fallback to offset intermittency.

In his 2014 State of the Union address, President Obama called natural gas “the bridge fuel that can power our economy with less of the carbon pollution that causes climate change.” Geothermal energy, too, provides the same stabilizing function as natural gas and comes with unique environmental and economic ancillary benefits. Ancillary services support the transmission of electricity from a supplier to a purchaser and include scheduling and dispatch, reactive power and voltage control, loss compensation, load following, system protection, and energy imbalance.

A geothermal plant can be engineered to optimize these services. In most geothermal plants built today, operators can increase or decrease the amount of power being generated in order to match load requirements — such as making up for gaps caused by intermittency.   Geothermal energy and natural gas play a similar role to the power grid with the capability to dispatch, or to change a facility’s power output by ramping up or down depending on system needs.”<

See on www.renewableenergyworld.com