South Dakota Wind Power and Electricity Prices- Part 2

Continuing with Net Metering in Why Are Electricity Prices Increasing? An Industry-Wide Perspective, which was mentioned at the end of the 8 June, Thursday post:

Net metering is a policy that many states already have implemented to encourage the use of small renewable energy systems. Approximately 40 states have adopted some form of net metering law for small wind and/or photovoltaic technologies; the customer receives a credit for excess power sold to the utility.

Under most state rules, all retail customers are eligible for net metering; however, some states restrict eligibility to particular customer classes {such as farm subsidies}. Customer participation in net metering programs has grown significantly.

In 2004, a total of 15,286 customers were in net metering programs—a 132-percent increase from 2003. Residential customers accounted for 89 percent of all customers participating in such programs.

{With the fourth-best wind power in the nation at 1,030 kWh per year, nearly every South Dakotan who installs a small or community wind turbine would be eligible for net metering. Diversifying income in this manner occurs any time the wind is blowing faster than 14 mph (probably five days out of seven in SD, yes?)}

The use of net metering with current metering technology is problematic, however, because standard meters cannot account for the difference

• between high-cost peak and low-cost off-peak electricity or
• in wholesale and retail electricity costs.

For example, a conventional meter only can record that over a given month an onsite generator sold a net of 100 kWh to the local utility, but will have no record of when the 100 kWh was sold. Sales at 4 p.m. on a hot summer weekday will have a much higher value than sales at 3 a.m. on a Saturday morning.

In order for electric utilities to remain financially viable in the current era of increased operating costs and continued need to invest in infrastructure development and expansion, rates must increase.

Indeed,electricity prices in many regions already have increased and further increases will be necessary in many cases. For example, between January 2005 and January 2006, U.S. electricity prices increased by an average of 11.6 percent, which predominantly reflected increased fuel and purchased power expenses.

These increases affected all customer classes

• residential prices rose by 12.5 percent
• commercial prices rose by 10.5 percent and
• industrial prices rose by 12.6 percent.

Table 9-1 provides a comparison of retail electricity prices over time, as well as similar measures for other key consumer price indices. The 2000 to 2005 picture, however, shows electricity prices growing at a slightly greater rate than that of all items in the CPI. However, even in this period, other energy prices are growing much more rapidly than electricity prices.

Retail prices have become more complex and varied in the past decade. This is a result of

• regional and state differences in rate regulation
• wholesale market organization
• generation mix and
• the individual characteristics of utilities themselves, such as their reliance on owned generation or purchased power to serve load.

It is clear that the fundamental cost driver of increased fuel prices ultimately will increase electricity prices across the country andcharacter of the price increases will have a substantial impact on the ability of utilities to pursue needed investment priorities.

By 2003, average household electricity consumption increased 21 percent, from 1.07 kilowatt (kW) per hour to 1.30 kW per hour. In 2030, average household consumption is expected to increase by more than 11 percent, to 1.45 kW per hour. Greater demand for electric power, however, does not translate directly into higher household expenditures.

Pie charts on p101 - 102, show inter-relationships of these figures.

"Impacts of Price Increases on Electricity Demand Growth Forecasts," is Appendix B.

Figure B-1 shows key inputs and outputs for Energy Information Administration's (EIA) most recent long-term forecast. EIA projects significant declines in the real price of electricity, with a
flattening in later years. This steady-to-declining trend in real electricity prices in 2006 and beyond closely tracks historical trends, and accordingly, demand follows a steady upward trajectory.

In the context of EIA’s modeling framework, the fall in prices is likely due to several factors.

• first and most important, both the rise and fall in electricity prices correspond closely with projected fuel costs.

• second, generating capacity additions underlying EIA's forecast are not dramatic in the near term, as EIA projects about 50 GW of additions over the period through 2014, well below NERC’s forecast of 86 GW.

Thus, the rate base for generation is not growing at a significant pace in the near term under EIA's projections.

While {the authors} have no reason to doubt the internal consistency {even with the contradicting comment a few paragraphs previous to this one?} of EIA's projections and the underlying data, this will impact the projection of demand growth. In EIA's projection assumptions fuel prices (notably natural gas) drop rapidly in price from a 2005 high, bringing
electricity prices down with them.

{What justification does EIA have for expecting fuel prices to decrease?! Peace in the Middle East? "Big Oil" rebates because of its massive profitability? Ease of developing Russian oil fields? What?}

In particular, real prices are assumed to increase 10 percent between 2005 and 2006, and then no change in real price is forecasted through 2014.

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A handful of South Dakota wind-

• 6 PM Jun 08, WSW at 21 mph

• 3 PM Jun 08, W at 16 mph

• 9 AM Jun 08, W at 7 mph

• 4 AM Jun 08, WNW at 15 mph

• 9 PM Jun 07, NNW at 25 mph.

Do contact me if you want to buy any of this blog's content or would like to have other specific wind power-related content uncovered.

'Til next time. Best Wind.

South Dakota Wind Power and Electricity Prices- Part 1

Why Are Electricity Prices Increasing? An Industry-Wide Perspective. JUNE 2006; a report from the Edison Electric Institute (EEI) and the "numbers crunching" by the Department of Energy Energy Information Agency (EIA) are the foundation for exporting South Dakota's wind power.

When South Dakotans harvest the nation's fourth-best wind power (1,030 billion kWh each year) using small, community, and large wind turbines, we can increase generating capacity additions. This satisfies, in the context of EIA’s modeling framework, one aspect of changes in electricity prices we can influence. EIA identified a fall in prices likely due to

First and most important, both the rise and fall in electricity prices correspond closely with projected fuel costs.

Second, generating capacity additions underlying EIA's forecast are not dramatic in the near term, as EIA projects about 50 GW of additions over the period through 2014, well below NERC’s forecast of 86 GW. Thus, therate base for generation is not growing at a significant pace in the near term under EIA's projections.

Price volatility is expected in commodity markets and electricity markets are particularly volatile because, unlike most other commodities, electricitycannot be stored and its short-run demand is highly price inelastic.

This makes electricity prices particularly sensitive to sudden changes in market conditions, such as the loss of a large generating plant or largetransmission line, or large shocks in input costs.

The primary advantages of renewables are low, stable operating costs and the environmental benefits of little or no air and water emissions. However, renewable technologies generally are more costly to build (on an installed $/kW basis), although construction times for wind and solar are typically shorter than for fossil-based generation capacity.

While some biomass and geothermal operate as baseload capacity {constant minimum available power}, wind and solar have lower capacity factors {rated power output} and their power output is intermittent because they are based on variable resources. Renewable resources also vary quite substantially in their geographic distribution.

Wind capacity has been growing at about 20 percent per year recently, which has largely been a result of renewable requirements established at the state level and the periodic renewal of the production tax credit allowed for renewables, there also has been increased demand from customers of “green” electricity at a premium rate offered by utilities.

The need for additional utility generation and transmission will be mitigated to some extent by increased development of small, onsite customer generation. Such generation is typically known as distributed generation (DG). Examples of DG include microturbines, biomass-based generators, small wind turbines, solar thermal electric devices, and backup generators at office buildings, industries, and hospitals.

In contrast to large, central-station power plants, distributed power systems typically range from less than a kilowatt to tens of megawatts in size. Energy Information Administration (EIA) projects that 5.5 GW of DG, or slightly less than two percent of all new generating capacity, will be installed over the next 25 years. {On-site small, community, and large wind turbines}

In addition to reducing the need for generation investment, optimally sited DG can reduce the need for transmission and distribution investment while resolving some system constraints and reducing line losses.

Section 1251 of EPAct 2005 encourages the development of small, onsite generation by requiring states to consider if utilities should make net metering services available upon request to any customer.

EPAct 2005 Amends the Public Utility Regulatory Policies Act of 1978 (PURPA) to require each electric utility to make available upon request net metering and time-based (smart) metering service, including credits for consumers with large loads who enter into pre-established peak load reduction agreements that reduce a utility's planned capacity obligations.

(Sec. 1253) Declares that no electric utility shall be required to enter into a new contract or obligation to purchase electric energy from a qualifying cogeneration facility or a qualifying small power production facility (qualifying facility) if FERC finds that the qualifying facility has nondiscriminatory access to certain specified relationships.

(Sec. 1254) Requires each electric utility to make available, upon customer request, interconnection service to any electric consumer it serves (under which an onsite generating facility on the consumer's premises is connected to local distribution facilities).

Concludes with Part 2 on Friday.

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A handful of South Dakota wind-

7 PM Jun 07, NNW at 28 mph, light rain

2 PM Jun 07, SW at 28 mph, thunder in the vicinity

9 AM Jun 07, WSW at 9 mph

3 AM Jun 07, SW at 30 mph

8 PM Jun 06, S at 25 mph.

Do contact me if you want to buy any of this blog's content or would like to have other specific wind power-related content uncovered.

'Til next time. Best Wind.

Seeing Wind Power

At the Texas Tech Book Pages is a book review of Windmill Tales, edited by Coy F. Harris, with photographs by Wyman Meinzer, and an Introduction by Steve Halladay.

"On the prairies of North America, wind and water were pervasive, but whereas wind was tangible, water in quantity was hidden beneath the surface. The vast grasslands fed great herds of animals, which in turn sustained native Americans, but it was not until water could be brought to the surface that the plains could be cultivated and developed into a great agricultural bread-basket for the growing nation. The self-governing windmill forever changed the culture of this vast region."

"The only sound that day was from the windmill, a creaking sound that a windmill makes turning in the summer breeze. It is a memory I deeply cherish and why I love windmills so much."

--A visitor to the American Wind Power Center.

"In Windmill Tales, in ninety-nine beautiful full-color images, photographer Wyman Meinzer shows American windmills as they appear today. Many of them are still working, and others have fallen or are preserved at the American Wind Power Center, but all illustrate the way of life that was made possible by the windmill."

"Brief reminiscences and stories told by visitors to the American Wind Power Center give the reader a sense of the central importance of windmills in the lives of early pioneers in the West. Some of the stories reflect the sense of humor ranch and farm families developed to help them through hard times, whereas others hint at disappointment and tragedy. Together with the photographs they give us a fascinating insight into our history."

"The agricultural development of the plains is the story of the ingenuity, hardship, success, and sometimes failure of settlers as they applied a new technology in an environment with which they were barely familiar. The stories of these settlers and of their children and grandchildren often focus on the windmill, for this source of life-sustaining water often became the center of ranch and farm life.

A second windmill museum, the Mid-Americal Windmill Museum is here.
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Using the Beaufort Wind Scale- described later- you can roughly estimate the number of watts your wind turbine could harvest by seeing what effects wind has on trees, flags, and "trash-moving."

"The Beaufort scale is an empirical measure for describing wind intensity based mainly on observed sea conditions. Its full name is the Beaufort wind force scale. Beaufort origianlly used knots and open seas descriptions; the scale has been adapted for use on land as well."

4 on the scale is 13 - 18 mph. Dust and loose paper raised. Small branches begin to move and wind farming begins to make economic sense. National Renewable Energy Laboratory (NREL) energy density classes 3/4/5 are in this Beaufort number.

Wind power density is measured in watts per square meter. It indicates how much energy is available at the site for conversion by a wind turbine. A not-too-technical description of energy density classes is here.

5 on the scale is 19 - 24 mph. Smaller trees sway. NREL energy density classes 5/6/7.

6 on the scale is 25 - 31 mph. Large branches in motion. Whistling heard in overhead wires. Umbrella use becomes difficult. NREL energy density classes 6/7.

7 on the scale is 32 - 38 mph. Whole trees in motion. Effort needed to walk against the wind. Exceeds NREL energy density class maximum 7.

8 on the scale is 39 - 46 mph. Twigs broken from trees. Cars veer on road. Exceeds NREL energy density class maximum 7.

9 on the scale is 47 - 54 mph. Light structure damage. "Shingle-stripping" wind. Exceeds NREL energy density class maximum 7.

10 on the scale is 55 - 63 mph. Trees uprooted. Considerable structural damage. Most turbines "cut-out at these speeds to prevent damaging the generator and geartrain. Exceeds NREL energy density class maximum 7.

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A handful of South Dakota wind-

7 PM Jun 06, S at 24 mph

11 AM Jun 06, SSE at 29 mph

6 AM Jun 06, S at 21 mph light rain

5 AM Jun 06, SSE at 12 mph

8 PM Jun 05, S at 5 mph.

Do contact me if you want to buy any of this blog's content or would like to have other specific wind power-related content uncovered.

'Til next time. Best Wind.

Rural Electric Co-ops and Wind Power

The Realities of Consumer-Owned Wind Power For Rural Electric Co-operatives, a 16-page Power Point PDF, was presented originally as Power Point slides by

Steve Lindenberg, U.S. Department of Energy; and Jim Green, National Renewable Energy Laboratory; WINDPOWER 2006; Pittsburgh, on June 4-8, 2006.

P3
The Market for Small Wind Turbines is in Rural America
• Better access to good wind resources
• Zoning is less often a barrier
• Larger parcels provide adequate space for wind turbine installations
• Most of rural America receives electric service from rural electric cooperatives

P8
Net Metering for Wind Only 22 states have net metering for all rural customers [map]

P9
Wind Interconnection Dispute in Iowa
FERC ruling in February 2006 backed away from the net metering enforcement action of June 2005. Provisions of EPAct 2005 are changing the scene; outcome is uncertain for net metering

p10
Understanding the Co-ops

p13
Times Are Changing
• Member preferences turning to renewable energy
• Price of electricity is going up
• Opportunity for rural economic development–Wind is an untapped resource
• Wind power is a hedge for an uncertain future with respect to:
Price of coal; Price of natural gas; Carbon taxes; [Congressional mis-steps one and two].

P 15
Conclusions

p 16
Carpe Ventum
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Carpe Ventum? The Latin roughly means "Seize Wind." Does the Latin phrase spur us to install a wind turbine compared to an English phrase? Does the Latin make us more clever, smarter, or more likely to be a successful wind farmer? For me, all "carpe ventum" did was send me looking for a Latin-English dictionary and after looking at two Google pages of them, then futzing with "that looks right." Gad, no wonder we have less and less time to accomplish useful things; we're often required to do preparation tasks in order to understand something that has been "clarified."

It's best to have cheese with whine, so I'd better stop now.
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Clean Renewable Energy Bonds (CREBs) is a five-page PDF produced by The National Rural Electric Cooperative Association (NRECA) a national service organization dedicated to representing the national interests of cooperative electric utilities and the consumers they serve.

{Surprisingly, the PDF is encrypted to prevent abstracting the document for easier comprehension. Perhaps not fully serving consumers' interests.}

The doc is an overview of the Energy Policy Act of 2005 (P.L. 109-58) where the tax credit bond serves as a tax credit to the bondholder. The doc has these headers

• qualified projects
• qualified issuers
• how CREBs work
• availability
• application process
• terms of CREBs
• credit rate
• spending the proceeds of CREBs
• board action needed for re-imbursement
• parties involved in issuing CREBs
• partnering with private entities
• marketing CREBs
• CREBs versus the Production Tax Credit
• steps to take immediately and
• other resources.
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Even though we enjoy 1,030 billion kWh of wind power every year, there is the rare boring day-
6 PM Jun 05, ENE at 3 mph
1 PM Jun 05, Variable at 3 mph
10 AM Jun 05, NNE at 7 mph
5 AM Jun 05, Calm
9 PM Jun 04, N at 16 mph.

Do contact me if you want to buy any of this blog's content or would like to have other specific wind power-related content uncovered.

'Til next time. Best Wind.

A wind co-op model for South Dakotans

Nick Rahall. a West Virginia Congressman, is instigating mis-informed legislation that will re-chill wind development as did legislation by his fellow Congressmen concerning wind turbines and military radar clutter. Too-often urban legislators dream up regs or laws that don't "make a lick of sense." Does Mr. Rahall enjoy air-conditioning and heating? Is he concerned about affordable electricity rates for his constituents? If "yes," then ethically he is accountable for being thoroughly educated about birds and bats stricking wind turbine blades. Glass windows are equally destructive of birds; is he dreaming up a federal reg for that technology as well?
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Our Wind Co-op is a unique cooperative of small-scale wind turbines on farms, ranches and public and private facilities across the Northwest. Through this collaborative effort, 10-kW turbines were installed at numerous rural sites serviced by publicly-owned utilities. Ten small wind turbines (10 kW rated power each) have been installed across the Pacific Northwest.

The Co-op was established in 2003 to foster growth in smallscale, distributed wind power; by 2007, 145,776 kWh have been harvested by members' turbines. Our Wind Co-op Green Tags are “value-added” because they are derived from small-scale, locally owned wind turbines.

In recognition of these unique qualities, Puget Sound Energy purchased all the Green Tags produced by OWC members in Washington and Oregon through 2006, and offered them for sale to their consumers through the utility’s Green Power Plan.

A review of how Our Wind Co-op leverages tag sales to reduce the cost-share required of site hosts is presented in this eight-page PDF. These Our Wind Co-op FAQs show how well-designed the co-op's business is.

South Dakotans can mimic this organization to harvest some of the 1,030 billion kW hours of wind power we enjoy (well ... SOME of us, any way) each year. We can harness some of those kWhs and put them to work for us in a number of situations, such as for air-conditioning and heating. We have a working model that can be adapted to our climate and REA situations; it's not "rocket science" any more!

A handful of South Dakota wind-
8 PM Jun 04, N at 20 mph
4 PM Jun 04, NNW at 23 mph11 AM
Jun 04, NNE at 14 mph
5 AM Jun 04,Calm 10 PM
Jun 03, NNW at 15 mph.

Do contact me if you want to buy any of this blog's content or would like to have other specific wind power-related content uncovered.

'Til next time. Best Wind.

Wind power and wind energy definitions #2

Wind is to "Aericulture" as crops and livestock are to agriculture. And "aerinomics" is to "aericulture" as agronomics is to agriculture. Putin this perspective, wind farming is (or should be, here in South Dakota) just another agricultural practice. Installing and operating a small wind turbine is "wind gardening" while community wind is "commons wind" (but probably stretches the farming lingo into "left field." OK, I'll leave it there.)

Over here in South Dakota we have the nation's fourth-best potential wind power- 1,030 billion kW hours annually. One-third of that (343 billion kW hours) could be harvested by wind turbines to meet the power requirements of 36,645,299 homes (each home uses 9,360 kW hours per year). But the variable nature (speed, duration, direction) of wind demand a concurrent constant source of electricity to sustain "the life we've grown accustomed to."

So even here, you can't be a wild-eyed get off the grid now person without radically changing your lifestyle. However these definitions and posts will serve as your "roadmap" to reducing electricity bills or diversifying income.
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C-BED- Minnesota’s Community-Based Energy Development legislation offers some important benefits to community wind projects.

An overview is through this link.

Community wind- small wind turbines are installed by a community or individuals to generate wind power for municipal or local use. Selling excess wind power is a secondary concern for community wind operators.

Condition monitoring- the use of sensors to measure and telecommunications to inform operators of the "wear and tear" of equipment. Vibration analysis.tribology, and thermography are all examples of Condition Monitoring techniques.

Maintenance Resources, an online dictionary, is the source for this definition.

Cut-in wind speed- the wind speed at which a wind turbine starts to generate electricity. With higher wind speed the turbine approaches its rated power and maximum electricity generation.

Dispatchable- power generation that can be immediately increased to meet demand above baseline power or immediately decreased once demand falls to baseline. Fossil-fueled power and nuclear-fired power are dispatchable power. Wind power is non-dispatchable because it is
variable. A variable source of power causes some degree of instability in a power grid.

Distribution- information about the distributions of wind speeds and the frequency of the varying wind directions, can be shown by drawing a wind rose using meteorological tower measurements. Wind roses vary from one location to the next.

Electricity wheeling- an energy consumer is able to select her/his own energy supplier, or "wheel in" energy from one of two or more different suppliers. When a utility on one region sells energy to a customer in another utility's territory, the energy is said to be wheeled to the
customer.

A handful of South Dakota wind-

3 PM Jun 03, N at 24 mph
1 PM Jun 03, N at 18 mph
11 AM Jun 03, N at 16 mph
3 AM Jun 03, N at 5 mph
5 PM Jun 02, N at 20 mph light rain; mist.

Do contact me if you want to buy any of this blog's content or would like to have other specific wind power-related content uncovered.

'Til next time. Best Wind.

On-Farm Energy Production

On March 8, 2007, Montana's senior U.S. Senator Max Baucus (D-MT, Senate Agriculture Committee ) introduced legislation that would give incentives to produce renewable energy "on-farm" farmers and ranchers. The proposal status is S. 828.

On-farm Energy Production Act of 2007," is an amendment to the Environmental Quality Incentives Program (EQIP).

Sen. Tom Harkin (D-Iowa) and Chairman of the Senate Agriculture Committee, today signed onto Baucus' bill, {link}which will go before the Agriculture Committee for its consideration before going to the Senate floor.

Baucus' bill would amend the EQIP which currently gives producers incentives to do conservation work on their lands.

The bill will help farmers and ranchers install windmills, solar panels, or biodiesel oilseed presses on their operations. The federal government would pay about 50 percent of the total costs to add renewable energy sources to the farm or ranch.

Baucus said other alternative energy programs help agriculture producers, but indirectly. Under his bill, farmers and ranchers will benefit directly because they'll be able to cut their energy and fuel bills. The Farm Bureau and the Farmer's Union back this proposed legislation to boost alternative energy.

A Handful of South Dakota wind-

{wind farming doesn't make economic sense until the wind is faster than 14 mph, so this Handful yields little wind power}

Noon Jun 02, N at 6 mph
9 AM Jun 02, N 7 mph
5 AM Jun 02, Calm light rain; mist
9 PM Jun 01, E at 6 mph
7 PM (23) Jun 01, ENE at 5 mph light rain
2 PM (18) Jun 01, E at mph 14 light rain .

Do contact me if you want to buy any of this blog's content or would like to have other specific wind power-related content uncovered.

'Til next time. Best Wind.