983 resultados para Illinois Energy Resources Commission
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Every year, a typical family in the United States spends around half of its home energy budget on heating and cooling. In Iowa, that percentage can be higher, due to temperature extremes reached during the winter and summer months. Unfortunately, many of those dollars often are wasted, because conditioned air escapes through leaky ceilings, walls and foundations—or flows through inadequately insulated attics, exterior walls and basements. In addition, many heating systems and air conditioners aren’t properly maintained or are more than 10 years old and very inefficient, compared to models being sold today. As a result, it makes sense to analyze your home as a collection of systems that must work together in order to achieve peak energy savings. For example, you won’t get anywhere near the savings you’re expecting from a new furnace if your airhandling ducts are uninsulated and leak at every joint. The most energy-efficient central air-conditioning setup won’t perform to your expectations if your attic insulation is inadequate and can’t reduce solar heat gain to help keep your home cool. And planting the wrong types of trees or shrubs close to your home adversely can affect potential energy savings all year long.
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Although there are many ways to cut you water heating bills, the all fall into two broad categories: reducing the amount of hot water you use and making your water heating system more efficient. Fortunately, there are several strategies that can help you consume less energy and save money - and still meet you hot water needs without sacrificing comfort or practicality. The booklet was designed to answer common questions about hot water systems and to provide you with the information necessary to make informed decision about a wide variety of topics, ranging from repairing hot water faucet leaks an insulation water supply pipes to installing low-flow shower heads and tuning you your existing water heather. You'll also find details on what to consider when it's time to go comparison shopping for a new water heater-including an evaluation of the alternatives to the common gas or electric storage tank unit that's found in the majority of homes in Iowa and across the country.
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If you haven’t been in the market for new appliances during the past several years, you’re going to be surprised at how innovative and energy-efficient appliances have become. You’ll find energy-smart appliance choices in almost all price ranges. Before heading to the local appliance retailer or “big-box” store, measure the space the new appliance will occupy to make sure it will fit—and that there’s enough room to fully open the door (or lid), as well as adequate clearances for ventilation, plumbing connections and other hookups. Then go to the appliance manufacturers’ Web sites to look at product information, and make a list of questions and “must-have” and “nice-to-have-but-not-essential” features.
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Maps of Iowa's Biodiesel and Ethanol Processing Plants.
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Farms to Fuel project will demonstrate technology to produce alternative renewable energy by combining cattle manure with organic industrial waste products in an anaerobic digester. The digester produces methane gas which fires an engine set to generate base load electricity. This would create environmental benefits by turning crop, livestock, and industrial waste into renewable energy in a sustainable and profitable way. Other benefits of the project include the production of a fertilizer that is more readily applicable to crops than in its raw form.
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Amana Farms is using an anaerobic digestion, which is a two-stage digester that converts manure and other organic wastes into three valuable by-products: 1) Biogas – to fuel an engine/generator set to create electricity; 2) Biosolids - used as a livestock bedding material or as a soil amendment; 3) Liquid stream - will be applied as a low-odor fertilizer to growing crops. (see Business Plan appendix H) The methane biogas will be collected from the two stages of the anaerobic digestion vessel and used for fuel in the combined heat and power engine/generator sets. The engine/generator sets are natural gasfueled reciprocating engines modified to burn biogas. The electricity produced by the engine/generator sets will be used to offset on-farm power consumption and the excess power will be sold directly to Amana Society Service Company as a source of green power. The waste heat, in the form of hot water, will be collected from both the engine jacket liquid cooling system and from the engine exhaust (air) system. Approximately 30 to 60% of this waste heat will be used to heat the digester. The remaining waste heat will be used to heat other farm buildings and may provide heat for future use for drying corn or biosolids. The digester effluent will be pumped from the effluent pit at the end of the anaerobic digestion vessel to a manure solids separator. The mechanical manure separator will separate the effluent digested waste stream into solid and liquid fractions. The solids will be dewatered to approximately a 35% solid material. Some of the separated solids will be used by the farm for a livestock bedding replacement. The remaining separated solids may be sold to other farms for livestock bedding purposes or sold to after-markets, such as nurseries and composters for soil amendment material. The liquid from the manure separator, now with the majority of the large solids removed, will be pumped into the farm’s storage lagoon. A significant advantage of the effluent from the anaerobic digestion treatment process is that the viscosity of the effluent is such that the liquid effluent can now be pumped through an irrigation nozzle for field spreading.
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Climate refers to the long-term course or condition of weather, usually over a time scale of decades and longer. It has been documented that our global climate is changing (IPCC 2007, Copenhagen Diagnosis 2009), and Iowa is no exception. In Iowa, statistically significant changes in our precipitation, streamflow, nighttime minimum temperatures, winter average temperatures, and dewpoint humidity readings have occurred during the past few decades. Iowans are already living with warmer winters, longer growing seasons, warmer nights, higher dew-point temperatures, increased humidity, greater annual streamflows, and more frequent severe precipitation events (Fig. 1-1) than were prevalent during the past 50 years. Some of the impacts of these changes could be construed as positive, and some are negative, particularly the tendency for greater precipitation events and flooding. In the near-term, we may expect these trends to continue as long as climate change is prolonged and exacerbated by increasing greenhouse gas emissions globally from the use of fossil fuels and fertilizers, the clearing of land, and agricultural and industrial emissions. This report documents the impacts of changing climate on Iowa during the past 50 years. It seeks to answer the question, “What are the impacts of climate change in Iowa that have been observed already?” And, “What are the effects on public health, our flora and fauna, agriculture, and the general economy of Iowa?”
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Today, perhaps without their realization, Iowans are factoring climate change into their lives and activities. Current farming practices and flood mitigation efforts, for example, are reflecting warmer winters, longer growing seasons, warmer nights, higher dew-point temperatures, increased humidity, greater annual stream flows, and more frequent severe precipitation events (Fig. 1) than were prevalent during the past 50 years. Some of the effects of these changes (such as longer growing season) may be positive, while others (particularly the tendency for greater precipitation events that lead to flooding) are negative. Climate change embodies all of these results and many more in a complex manner. The Iowa legislature has been proactive in seeking advice about climate change and its impacts on our state. In 2007, Governor Culver and the Iowa General Assembly enacted Senate File 485 and House File 2571 to create the Iowa Climate Change Advisory Council (ICCAC). ICCAC members reported an emissions inventory and a forecast for Iowa’s greenhouse gases (GHGs), policy options for reducing Iowa’s GHG, and two scenarios charting GHG reductions of 50% and 90% by 2050 from a baseline of 2005. Following issuance of the final report in December 2008, the General Assembly enacted a new bill in 2009 (Sec. 27, Section 473.7, Code 2009 amended) that set in motion a review of climate change impacts and policies in Iowa. This report is the result of that 2009 bill. It continues the dialogue between Iowa’s stakeholders, scientific community, and the state legislature that was begun with these earlier reports.
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The 2008 Biobased Industry Outlook Conference was held September 7-10 on the Iowa State University campus. Over 750 people attended the plenary sessions on the morning of September 8th; 580 people registered for the full conference. Sponsorships: $92,500 in sponsorships in addition to the IPF was secured for the conference (considered “match” to the IPF grant). Including the $11,250 IPF sponsorship ($12,500 minus overhead charges of $1,250), the total amount contributed for conference sponsorships was $103,750. A list of sponsors and the amount of sponsorship is listed in Appendix A. Sponsorship funds received from the Iowa Power Fund were used for supplies and materials. Please see Appendix B which documents the transfer of IPF grant funds internally at ISU and their use.
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This station was required to have air temperature, relative humidity, wind speed and direction, and pavement temperature sensors of similar quality to the traditional RWIS sensors, have an integrated solar powered battery system, and be trailer-mounted for ease of transport. The station was tested by the Iowa DOT for basic reliability and sensor performance for a month and a half in Ames, Iowa before being moved to near Osceola, Iowa in early February 2010 for further field testing and evaluation. DOT field maintenance staff was able to successfully set up the station with minimal instruction and found the station to be relatively intuitive in its installation. Air temperature, wind speed, and wind direction observations from the station were compared to a nearby RWIS station and had good agreement. Pavement temperature readings were compared to sites within 40 miles of the station, and the readings correlated. The station has had good reliability.
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The technology used in this proposal is Bioprocess Algae’s Vertical Mounted Photo bioreactor. Inputs to this system are CO2 from a rich source, here an ethanol plant, nutrients, wastewater from the ethanol plant, sunlight and waste heat if available. The outputs from this system are algae oil, which is similar to other vegetable oils, dilapidated algae meal, and dry whole algae. Application use of the oil will be biodiesel feedstock, an alternative feedstock for ethanol or as a feedstock for other energy production processes.
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Like many states, Iowa faces significant challenges on the energy front. Energy prices have surged in recent years to record levels before declining precipitously following the financial crisis that broke in September 2008. Despite this pullback, the fundamentals that contributed to higher energy prices are expected to return once economies rebound. Oil prices have gone up on increased demand, driven in large part by developing countries such as China and India, whose economies have been rapidly expanding. Natural gas prices have also fluctuated dramatically, trading in a range from $4.50 to $13.00/MMBtu over the past year, but are unlikely to remain at low levels over the long term. As shown in our analysis later on in this report, the difference in levelized cost of electricity from a gas‐fired combined cycle plant can vary significantly depending on the fuel cost. Dependence on others for energy supply involves significant risks and uncertainties. Thus, if Iowa wishes to reduce its dependence on others – or even achieve energy independence – Iowa needs to pursue actions on a numbers of fronts. Following the status quo is not an option. A carbon tax would change the energy landscape in Iowa. Since Iowa is currently 75% dependent on coal, a carbon tax could mean that generators, and in turn ratepayers, could be on the hook for higher electricity prices, though it remains to be seen exactly what the tax scheme will be. In addition to existing plants, a carbon tax would also have a significant impact on the cost of new generation plant. We have modeled carbon taxes ranging from $0‐50/ton in our analysis in the Appendix. However, if a more aggressive carbon policy came into play resulting in market values of for example, $100/ton or even $200/ton, then that could raise the cost of coal‐ and gas‐fired generation significantly, making alternatives such as wind more economical.
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A newly completed study commissioned by the Iowa Office of Energy Independence shows increased jobs, tax revenue and economic activity as a result of Iowa Power Fund projects. The analysis is divided into two parts. Part I assesses the specific impacts of projects that have been funded directly. Part II offers an analysis of the long term impacts when projects are successfully replicated.
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This report presents a summary of the economic impact of the 31 projects supported by the Iowa Power Fund from 2008 through September 2010. The focus of the report is on the economic and fiscal impacts resulting from the projects supported by the Iowa Power Fund. As a part of the study, project related construction impacts were estimated for projects including a construction phase. In addition, Impact Data Source developed projections to estimate the potential long‐term impacts of the project for the State of Iowa and the nation. Using data reported by project managers on economic impact data sheets, information gathered from the project’s application and conversations conducted with the project manager, an individual impact analysis was produced for each of the 31 projects. Renewable Energy Research and Iowa All of the research and commercialization projects funded by the Iowa Power Fund contribute to reducing the state’s reliance on fossil fuels and increasing the use of renewable energy. These projects focus on many different types of renewable energy and various aspects of energy efficiency and conservation. Overall, the research supported by the Iowa Power Fund seeks to capitalize on Iowa’s resources and economic base to help the state become a leader in renewable energy. Iowa is the nation’s leader in corn production and, not surprisingly also the nation’s leader in ethanol production. A number of funded projects seek to increase or improve ethanol production through utilizing more parts of the corn plant or improving the drying processes related to production. Several biodiesel projects seek new ways to produce biodiesel and utilize more of the co‐products in livestock feed. One project is demonstrating electricity generation from farm and other industrial waste at a large scale. While these advancements in biofuels and renewable energy may be replicated outside of the state, the funded projects will disproportionately benefit Iowa in the long run, given how these projects are so tied to Iowa’s strong agriculture industry. The manufacturing industry is the leading employment sector in Iowa and the state’s focus on renewable energy may help strengthen this industry. Many of the projects supported by the Iowa Power Fund are researching ways to improve wind turbine manufacturing or reduce the cost of solar energy. Manufacturing related to renewable energy will likely grow in Iowa and help support a transitioning economy.
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ISU’s proposed research will (1) develop methods for designing clean and efficient burners for low‐Btu producer gas and medium‐Btu syngas, (2) develop catalysts and flow reactors to produce ethanol from medium‐Btu synthesis gas, and (3) upgrade the BECON gasifier system to enable medium‐Btu syngas production and greatly enhanced capabilities for detailed gas analysis needed by both (1) and (2). This project addresses core development needs to enable grain ethanol industry reduce its natural gas demand and ultimately transition to cellulosic ethanol production.
