Spinning offshore wind: science and renewables propaganda

Advocates of offshore wind are confronted with significant difficulties. The levelized cost of electricity from offshore wind is simply not competitive with nuclear power. Any objective observer, and scientists are certainly suppose to be objective observers, would conclude that the case against off shore wind is extremely powerful.

A review of a recent report from The National Renewable Energy Laboratory (NREL), "Large-Scale Offshore Wind Power in the United States: ASSESSMENT OF OPPORTUNITIES AND BARRIERS," suggests a willingness on the part of the NREL to cross a line between science and propaganda, in support of renewable energy enterprises.

The report acknowledges,

Currently, capital costs for offshore projects are nearly double those for land-based wind projects. These higher costs accrue from, for example, the offshore turbine support structures, offshore electrical infrastructure construction, the high cost of building at sea, O&M warranty risk adjustments, turbine cost premiums for marinization, and a decommissioning contingency. These costs can be partially offset by increased energy production. In comparison with land- based wind, however, offshore wind is also immature and its costs are higher because less deployment and experience has not allowed for full realization of the learning curve, by which product costs in new industries are known to decline as a function of production quantity. Further cost uncertainty and upward cost pressure may be introduced because of U.S. dollar/euro exchange rates. High cost is one of the primary deterrents for would-be developers of offshore wind. Current projects in the United States depend on policy incentives to offset some of the high costs, but there are no guarantees that the necessary incentives will be available when a project is approved and permitted.

Although the report holds out the hope for lower future offshore wind costs, it also acknowledges,

Capital costs for offshore wind plants are analyzed using data from European deployments and projected costs for potential U.S. projects. The costs have been trending up over time, as have the costs for land-based installations. Although water depth is expected to have a significant effect on capital cost, and larger wind plant sizes should lead to lower overall capital costs, these effects have been overshadowed in the data by recent jumps in the cost of energy from all sources and other energy market dynamics. The wind turbine itself contributes approximately 44% of the total capital cost. Capital cost trends are presented for year of installation, water depth, distance from shore, and project size. Year of installation is the most significant variable in the capital cost, with a sharp rise in price (56%) indicated between 2006 and 2008. Other trends such as decreasing cost with project size may show some correlation, but consistent data are not yet available to quantify this trend.

The LCOE of offshore wind plants is about double that of comparable land-based plants using 2009 market prices. This increase in the cost of energy can be attributed to higher O&M costs as well as the previously described higher capital costs. O&M costs can account for as much as 30% of the total life-cycle cost for an offshore wind plant. Three offshore wind projects in the United States have now signed PPAs (see Table 6-3). The reader is cautioned about making direct comparisons between these PPAs because the terms are complicated and several factors may not be obvious under a casual analysis.

Thus the report tells us that offshore wind is very expensive and appears to be getting even more expensive, quite rapidly. Indeed the cost of the heavily subsidized Cape Wind Project, not discussed in this report, would appear to be significantly higher that the reports highest offshore wind estimates. Any attempt to objectively compare nuclear power costs, with offshore wind costs, would conclude that in most and perhaps all instances the cost of nuclear power would be significantly lower than the cost of onshore wind generated electricity.

The recommendation to policy makers then would be that nuclear power is the lower cost option, and should be preferred to offshore wind. Needless to say the National Renewable Energy Laboratory, is not interested in science, objectivity or low energy costs. Thus rather than acknowledge the dismal realities confronted by offshore wind developers, "Large-Scale Offshore Wind" attempts to spin the facts in order to justify huge government subsidies to the offshore wind industry. Electricity from the offshore Cape Wind project, despite large Federal and State subsidies, and additional subsidies from Federal stimulus programs, will still cost,

18.7 per kilowatt hour in its first year of operation, 2013

"Large-Scale Offshore Wind," which manages to avoid a discussion of the real cost of Cape Wind electricity, no where suggests a cost comparison between the cost of offshore wind and nuclear power. So rather than focusing on questions related to the economic viability of wind, "Large-Scale Offshore Wind," focuses on potential wind supply, as if the relative cost of tapping that supply was inconsequential.

Renewable propagandists often focus on the decontextualized nuclear cost estimates, while disguising the fact that renewable energy sources cost more. But there are limits to the ability of propagandists to spine adverse facts, and in a report that acknowledges to some measure the cost problems of offshore wind attempting to suggest that nuclear costs more without a direct comparison, would be a bit to much in addition to being very overtly dishonest. So the NREL spin doctors are forced to ignore the cost issue. Instead they focus on risk. Paradoxically their risk spin ends up being almost as dishonest as a cost spin would be.

Among the risks which offshore wind generators face, non is more violent than major storms.

In many sites, the 50-year storms will be category 4 and 5 hurricanes that can have gusts greater than 80 m/s. Even though it is possible to develop structurally adequate designs using the existing standards, the process may require a more integrated design approach in cooperation with the turbine manufacturers or a Class S turbine (hurricane resilient) that exceeds the Class 1 requirements. It is possible to implement turbine design modifications for existing turbine designs that would resist or reduce the extreme loads resulting from these conditions. Such modifications could involve changes to blades and towers. Some of these changes may require compromises that might diminish the energy capture potential for a wind turbine installed at those sites to ensure survivability. For example, although the extreme winds are higher, hurricane sites have typically lower annual average wind speeds that would normally warrant a larger rotor. At hurricane sites, larger rotors may be prohibitive due to requirements for resisting extreme hurricane gusts. This may dictate a new design strategy. . . .

Understanding of extreme loads on wind turbines generated by hurricanes is important for reducing the uncertainty about survivability of the primary structure. The methodology for determining the probability of a hurricane at a particular site and the magnitude of its winds is not fully established. . . . .

In shallow water, hurricane-generated breaking waves may also create an extreme load case that has not yet been properly evaluated, especially in the Atlantic . . .

Hurricanes present unique external conditions that could require turbine design modifications. The turbine’s protection system may need specific upgrades to withstand hurricane conditions. This could include not only extreme winds that could impose high instantaneous loads, but also sustained wind speeds, high wind/wave frequency, rapid direction changes, impulsive gust loading, breaking and slamming wave loads, and multidirectional wind/wave spectra.

A second serious problem would involve a collusion between a ship or an aircraft and a Wind generator tower. "Large-Scale Offshore Wind" acknowledges this possibility but then discounts it.

Measures will need to be taken to prevent collisions (e.g., navigation exclusion zones, distance requirements for routes, mapping on navigation charts, and warning lights) or to respond rapidly to them (e.g., emergency response and rescue). . . .

Overall, collision risks are generally well understood and are unlikely to present a significant obstacle to offshore wind energy, provided these interactions and risks are considered carefully in the siting process and reasonable precautionary measures are taken to avoid the perceptions or realities of national security risks

In a discussion of socioeconomic risks, "Large-Scale Offshore Wind" observed a supposed benefit,

• Improved electric price stability

In fact rate payers can expect a significant electrical price increase as a partial payment for the Cape Wind Project.

"Large-Scale Offshore Wind" concludes its discussion of risks

A new paradigm is needed for thinking about the range of environmental and social risks of offshore wind developments, and it will need to be embodied in forward-looking state and federal energy policies. A diverse portfolio approach to energy development will include both land-based and offshore wind energy as important components in the energy mix. This new analytical paradigm is framed in the context of comparative sector risks with other energy technologies and is not limited to sector-by-sector risk analyses.

An integrated and comparative risk framework can serve as a comprehensive assessment of the costs and benefits of deploying an offshore wind farm as opposed to proceeding with some other energy choice. Rather than the sector-by-sector approach, an integrated risk framework begins to give federal, state, and local decision makers and their stakeholders a common ground for analyzing and managing risks and devising public policies and effective siting strategies . . .

So far so good, but then we learn,

Comparisons with other energy sources (such as fossil fuels and nuclear) indicate that the overall risks of offshore wind are relatively benign and not catastrophic (such as breached coal ash ponds, nuclear waste impacts).

We are also told

the life cycle of nuclear power production, albeit not generating carbon emissions during operation, involves long-term, large-scale, known impacts associated with extraction, transportation, heating and cooling, and disposal of nuclear wastes, notwithstanding the potential for catastrophic risks from accidents and terrorism. Offshore wind has a different and likely a more benign set of impacts. The reduced impacts of offshore wind should be weighed against these more significant potential life-cycle effects.

Spin away, Spin, spin, spin! We are also told,

Comparisons with other energy sources (such as fossil fuels and nuclear) indicate that the overall risks of offshore wind are relatively benign and not catastrophic (such as breached coal ash ponds, nuclear waste impacts).

It should be first noted that there has never been a casualty producing reactor accident in an American civilian NPP. There have been casualty producing accidents directly related to the operation of wind generation facilities. If history is the key to the future, the prospect of a catastrophic casualty producing accident is higher at offshore wind facilities than at Nuclear Power Plants. The worst case accident for a wind facility is pretty horrific. A collision between an oil tanker and a wind tower could produce a large oil spill with a very large environmental damage. The risk of a catastrophic accident involving a large oil spill and an offshore wind facility is probably far higher that the risk of a major accident involving nuclear waste. If large numbers of wend generators are deployed at sea, how long would it take before oil tankers would start running into them.

As we have seen large Category IV and Category V hurricanes pose serious threats to wind generators. A hurricane of that magnitude would not simply take out one generator, it might take out whole offshore wind farms, which represent billions of dollars worth of investment.

the overall risks of offshore wind are relatively benign and not catastrophic

Where dies that come from? Certainly not the discussion of offshore wind risks in "Large-Scale Offshore Wind." Once again we see the National Renewable Energy Laboratory playing propagandist for the renewable energy industry at the expense of objectivity, at the expense of science.

Finally, he risks of post carbon renewable energy include risks related to cost. The Cape Wind Project demonstrates that even with huge federal and state subsidies, electricity produced by offshore wind generators will not be cost competitive with conventional nuclear power, and still less cost competitive with Generation IV molten salt nuclear technology. When is the National Renewables Energy Laboratory going to face this unpleasant reality? When is the NREL going to stop spinning the truth about renewable energy?

We need a carbon-mitigation cost index

We need a carbon-mitigation cost index. The index should measure the cost of eliminating the emissions of a ton of CO2, or of eliminating a ton of CO2 from the atmosphere. Without a carbon emission cost index, there is no measure of the potential effectiveness of policy options designed to prevent carbon emissions, or to decrease atmospheric carbon content.

The existence of a carbon mitigation index can serve as an effective counter to propaganda campaigns in favor of in opposition to various energy forms.

Recently a collition of anti-nuclear organizations including WECF ( Women in Europe for a Common Future), The International Forum on Globalization, WISE (World Information Service on Energy), Friends of the Earth International, and Nuclear Information & Resource Service published a statement that asserted:

Nuclear power steals “time and money” that would be better invested in energy efficiency and renewable technologies

This claim is not supported by any detailed analysis of the relative costs and benefits of carbon mitigation with nuclear and renewables. In fact the capital costs associated with renewables are higher per unit of electrical output, and since renewable tend to replace low carbon emission emitting combined cycle gas turbines, while nuclear displaces high carbon emission coal fired power units, nuclear appears to be 3.5 times more cost effective than onshore as a carbon mitigation tool, and even more cost effective than off shore wind and all forms of solar.

The effectiveness of nuclear power as a carbon mitigation tool can be illustrated with a map and two list. First the map showing the states where nuclear power plants are located:
Here is the EIA's list of Nuclear power plants by state:

U.S. Nuclear Power Plants by State	Plants
Alabama	Browns Ferry
	Farley (Joseph M. Farley)
Arizona	Palo Verde
Arkansas	Arkansas Nuclear One
California	Diablo Canyon
	San Onofre
Connecticut	Millstone
Florida	Crystal River 3
	St Lucie
	Turkey Point
Georgia	Hatch (Edwin I. Hatch)
	Vogtle
Illinois	Braidwood
	Byron
	Clinton
	Dresden
	LaSalle County
	Quad Cities
Iowa	Duane Arnold
Kansas	Wolf Creek
Louisiana	River Bend
	Waterford
Maryland	CalvertCliff
Massachusetts	Pilgrim
Michigan	Donald C. Cook
	Enrico Fermi (Fermi)
	Palisades
Minnesota	Monticello
	Prairie Island
Mississippi	Grand Gulf
Missouri	Callaway
Nebraska	Cooper
	Fort Calhoun
New Hampshire	Seabrook
New Jersey	Hope Creek
	Oyster Creek
	Salem Creek
New York	Fitzpatrick (James A. Fitzpatrick)
	Indian Point
	Nile Mile Point
	R.E. Ginna (Ginna, or Robert E. Ginna)
North Carolina	Brunswick
	McGuire
	Shearon-Harris(Harris)
Ohio	Davis-Besse
	Perry
Pennsylvania	Beaver Valley
	Limerick
	Peach Bottom
	Susquehanna
	Three Mile Island
South Carolina	Catawba
	H.B. Robinson
	Oconee
	Virgil C. Summer (Summer)
Tennessee	Sequoyah
	Watts Bar
Texas	Comanche Peak
	South Texas
Vermont	Vermont Yankee
Virginia	North Anna
	Surry
Washington	Columbia Generating Station
Wisconsin	Kewaunee
	Point Beach

The effectiveness of nuclear power in carbon mitigation can be demonstrated by comparing the map and the above state list with the states listed in Table A-2 found in "The Near-Term Impacts of Carbon Mitigation Policies on Manufacturing Industries", a 2002 study of carbon emission issues for industry:

Carbon emission per million kwh electricity generated by States (metric tons per million kwh)

We consider electricity carbon emissions from three fossil fuels -- coal, petroleum and gas. The physical quantities of coal, petroleum and gas used by states to generate electricity are obtained from Electric Power Monthly (EIA, 1993). The individual fuel quantities are converted to energy using conversion factors from Manufacturing Energy Consumption Survey 1991. This energy consumption is multiplied by carbon emission coefficients (from Emissions of Greenhouse Gases in the United States, EIA 1996) to obtain carbon emissions by state by aggregating carbonemissions from coal, petroleum and gas. Carbon emissions per unit of electricity generated (metric tons per million kWh) are calculated by dividing state carbon emissions with state net electricity generation. In Table A-2, we present the electricity carbon emissions for the US and individual states. The average carbon emission from electricity generation is about 180.9 metric tons per million kWh. The range is from 0 (Idaho) to 462 (N. Dakota). A state with a high coefficient means it uses a high share of fossil fuel to generate electricity. A smaller coefficient indicates a higher use of hydro or nuclear power.

Table A-2. Electricity Carbon Emissions by State
State	Total ElectricityCarbon Emissions (1000 metric tons)	Net Electricity Generation (Million Kwh)	Emission coeff. (Metric Tons per Million Kwh)
Alabama	10857.6	68374.0	158.8
Alaska	492.1	2980.0	165.1
Arizona	7629.8	52722.0	144.7
Arkansas	5419.2	27541.0	196.8
California	6233.6	89701.0	69.5
Colorado	6879.0	23983.0	286.8
Connecticut	1206.7	19308.0	62.5
Delaware	1103.4	4941.0	223.3
District of Columbia	29.9	74.0	403.6
Florida	17847.4	103809.0	171.9
Georgia	10379.8	68908.0	150.6
Hawaii	1161.4	5301.0	219.1
Idaho	0.0	4993.0	0.0
Illinois	11308.0	93424.0	121.0
Indiana	19893.9	71633.0	277.7
Iowa	6741.0	22219.0	303.4
Kansas	6223.3	23606.0	263.6
Kentucky	13500.7	57209.0	236.0
Louisiana	8793.1	43072.0	204.1
Maine	239.3	6021.0	39.7
Maryland	4554.5	29109.0	156.5
Massachusetts	4174.0	25254.0	165.3
Michigan	12424.0	62171.0	199.8
Minnesota	6629.7	29038.0	228.3
Mississippi	2348.9	16187.0	145.1
Missouri	10161.1	41586.0	244.3
Montana	4484.3	18521.0	242.1
Nebraska	3482.1	16510.0	210.9
Nevada	3804.0	16153.0	235.5
New Hampshire	727.3	10853.0	67.0
New Jersey	1550.5	22562.0	68.7
New Mexico	6458.8	20369.0	317.1
New York	9873.3	84002.0	117.5
North Carolina	9306.1	63030.0	147.6
North Dakota	9744.3	21060.0	462.7
Ohio	21933.0	102417.0	214.2
Oklahoma	8806.1	35114.0	250.8
Oregon	979.6	31099.0	31.5
Pennsylvania	18139.9	127446.0	142.3
Rhode Island	26.2	101.0	259.3
South Carolina	4102.6	53597.0	76.5
South Dakota	971.5	4879.0	199.1
Tennessee	9151.4	57253.0	159.8
Texas	49010.9	185738.0	263.9
Utah	5902.6	24461.0	241.3
Vermont	10.6	3365.0	3.1
Virginia	4255.3	37051.0	114.8
Washington	2637.2	63174.0	41.7
West Virginia	11867.8	53339.0	222.5
Wisconsin	7700.7	34386.0	223.9
Wyoming	10580.0	30898.0	342.4
U.S.	381737.6	2110542.0	180.9

Amory Lovins has repeatedly stated:

I do think we need to allocate capital judiciously and take opportunity costs seriously.

This statement is of course true. Lovins also states,

I do not think you can make an empirically based business case that the existing nuclear power plant fleet has been economically worthwhile (counting all externalities at zero), nor that there is any business case for building more. This is of course an empirical question.

I have provided just sort of case in my numerous analyses of the relative costs of renewables and nuclear power. But I believe that far more work needs to be done, and this work, rather than renewables advocacy should be the proper role of a Nationals Renewable Energy Laboratory. Lovins argues that nuclear power is not a cost effective carbon mitigation tool, without assessing the true cost of carbon mitigation with renewables, and without exploring the potentials for lowering nuclear costs. There is real potential for lowering cost by altering nuclear manufacturing techniques, changing siting criteria, and in other innovative approach to nuclear cost issues. In addition there is probable cause to believe that adopting alternative nuclear technologies could lower nuclear costs in a dramatic fashion, while increasing nuclear safety, resolving the issue of nuclear waste and not encouraging nuclear proliferation.

It is clear then that the claim that nuclear power does not mttigate carbon emissions can be shown to be false, and the claim that nuclear power. The question posed by Amory Lovins thus becomes, "is it cost effective to build more nuclear plants as a cost mitigation tool?" My arguments to date tend to demonstrate that it is, but we need more research, and more research tools. We need a carbon-mitigation cost index.