Hot Topic Hour on November 8 at 10:00 a.m. (CST) is FGD Scrubber Components
The conditions inside an FGD system are, to put it mildly, very nasty. The gases
and liquids present are very corrosive and abrasive. It is vital to select the
correct materials and design of an FGD system in order to minimize down time and
maintenance cost. The following speakers will describe their experience in
dealing with the FGD environment and provide recommendations on how to lengthen
the life of your system and reduce maintenance costs:
Doug Reinke, Vice-president of Sales & Marketing at Augusta Fiberglass, will
discuss FRP fiberglass components for FGDs. The power industry requires very
large components for FGD scrubber systems and Augusta Fiberglass pioneered new
techniques to deliver these component made out of FRP fiberglass. He will review
fabrication and assembly of these large components and other innovative delivery
methods to equip the power industry with corrosion resistant FRP and dual
laminate equipment.
Chris Pedersen, Chief Executive Officer of Kimre, Inc, will discuss the
AEROSEP(R) Sub-Micron-Aerosol Removal technology. This technology uses
mechanisms for collection of sub-micron particulates not available from any
other technology. Kimre's unique three dimensional structure allows the use of
fibers having small diameters to easily collect aerosols of one micron. By
combining this functionally with particle growth to one micron; sub-micron
aerosols are easily and effectively collected. The technology has been used in
European power plants burning municipal waste for decades and is also well
proven for other sub-micron aerosols.
Rob Fredell, Vice-president for Business Development at Neumann Systems Group,
Inc., will describe an advanced wet flue gas desulfurization technology known as
NeuStream®-S. This system offers coal-fired power plant operators a reliable,
lower-cost alternative to either conventional wet FGD systems or dry sorbent
injection where SO2 capture rates at or above 80 percent are desired. Using an
advanced flat-jet liquid gas contactor and a proven dual-alkali capture system,
NeuStream®-S offers high-performance acid gas control in about one-tenth the
volume of conventional spray tower or lime spray dryer arrangements, with low
parasitic power and low water consumption. For many operators, NeuStream®-S
offers the lowest cost of ownership for plants operating five or more years.
To register for this (free) session on November 8 at 10:00 a.m. (CST) click on:
http://www.mcilvainecompany.com/brochures/hot_topic_hour_registration.htm.
McIlvaine Hot Topic Hour Registration
On Thursday at 10:00 a.m. Central time, McIlvaine hosts a 90 minute web meeting
on important energy and pollution control subjects. Power webinars are free for
subscribers to either Power Plant Air Quality Decisions or Utility Environmental
Upgrade Tracking System. The cost is $125.00 for non-subscribers.
Market Intelligence webinars are free to McIlvaine market report.
2012
DATE SUBJECT
November 8 FGD Scrubber Components Power
November 15 Dampers and Expansion Joints for Coal-fired and Gas Turbine Power
Plants Power
November 29 Catalyst Selection for NOx and Other Gases Power
December 6 Boiler Feed and Cooling Water Treatment Power
December 13 Co-firing Sewage Sludge, Biomass and Municipal Waste Power
2013
January 10 Update on Oxy-fuel Combustion Power
January 17 Production of Fertilizer and Sulfuric Acid at Coal-fired Power Plants
Power
January 24 Gypsum Dewatering Power
January 31 Filter media (forecasts and market drivers for media used in air,
gas, liquid, fluid applications, both mobile and stationary). Market
Intelligence
February 7 Valves for Power Plants, Boilers and Water Treatment Facilities Power
To register for the Hot Topic Hour on November 8, 2012, click on:
http://www.mcilvainecompany.com/brochures/hot_topic_hour_registration.htm.
Here are the Headlines for the October 26, 2012 – Utility E-Alert
UTILITY E-ALERT
#1098 – October 26, 2012
Table of Contents
COAL – US
Lawsuit wants SCR at Reid Gardner
SCS Energy scraps Plans for PurGen Coal-fired Power Plant in NJ
COAL – WORLD
Congo’s Gecamines Plans 500 MW Coal-Fired Power Plant
IL&FS plans 4,000 MW Mota Layja Power Plant in Gujarat, India
GAS/OIL / US
Sargas Texas to build 250 MW Power Plant at Calhoun Port in Texas
LIPA pursues possible Yaphank or Shoreham Power Plant by 2018
Northland Power acquires Rights to develop Two Gas-fired Peaking Plants in
Illinois
Holland BPW recommends New Site for proposed Natural Gas-fired Power Plant
GAS/OIL – WORLD
General Electric planning 1,000 MW Power Plant in Kenya
Uzbekistan to build 250 MW Combined Cycle Gas Turbine at Tahiasht CPPP
Gulf JP has financing for 1,600 MW Rojana Industrial Park Combined Cycle Plant
in Thailand
BIOMASS
Metso to deliver 100 MW Biofuel-fired Boiler to Jönköping Energi in Sweden
Centrica pulling out of Biomass-fired Power Projects in UK
Drax raises £190 Million for conversion of Three Units to Biomass-firing
NUCLEAR
E.ON pulls out of Finnish Nuclear Power Plant Project
Dominion to close 556 MW Kewaunee
BUSINESS
Uzbekistan plans to attract Korean Kepco to construct New Thermal Power Plant
at Uchkuduk
Santee Cooper to retire Coal, Oil-fired Power Plants at Jefferies and Grainger
Fuel Tech awarded ULTRA™ Orders in China Totaling $2.6 Million
$7.5 Billion Air and Water Monitoring Market in East Asia
HOT TOPIC HOUR
(Free) “Hot Topic Hour” on November 1st is on “Cooling Towers and Cooling
Tower Water Treatment as well
as Co-generation to Eliminate Cooling”
Upcoming Hot Topic Hours
For more information on the Utility Environmental Upgrade Tracking System, click
on: http://www.mcilvainecompany.com/brochures/energy.html#42ei.
Strategically Located Energy Complexes are the Greenest Option Affordable
Energy complexes that burn a combination of coal and biomass, provide waste heat
to other manufacturing within the complex, and capture CO2 to use for enhanced
oil recovery are the greenest option. Furthermore, they are affordable and
practical. This is the conclusion reached in the McIlvaine report, Fossil &
Nuclear Power Generation: World Analysis & Forecast. (www.mcilvainecompany.com)
This conclusion is based on the following facts:
• Coal has to be a bridge fuel for at least the next 40 years
• Cogeneration doubles the efficiency of coal-firing
• Coal combustion is the most economical way to provide CO2 for enhanced oil
recovery
• New coal-fired power plants with only a 25 year life can replace old
coal-fired power plants economically
• Methane has one hundred times the global warming effect of CO2 in the first 25
years
Renewables at best are carbon neutral. A holistic concept combining
co-generation, enhanced oil recovery, biomass co-combustion and
ultrasupercritical boilers can result in a net reduction in greenhouse gases,
the avoidance of other pollutants escaping to the atmosphere and a net gain in
water.
The world will be spending $300 billion per year to construct new coal-fired
power plants. The question is where will they be built? Presently, the U.S.
consumption of coal is down, but exports are way up. China has been and will
install as much coal-fired capacity as exists in the U.S. every six years.
India, Vietnam, Indonesia and other Asian countries are also building many power
plants.
Logic and economics may or may not prevail. Global warming is just what the
title indicates. It is-- global. If the U.S. solves its CO2 emission problems by
shipping coal to China, it only transfers the emission source. As long as the
U.S. keeps buying goods which require energy to manufacture, China will keep
building new coal-fired power plants.
At the rate coal is being consumed, it will not be a major source of greenhouse
gas emissions seventy-five years from now. Likewise, the supply of other fossil
fuels will diminish rapidly over the next seven decades. So we need to look at
the allocation of these resources with both a focus on the short-term and
long-term impact on the world economy and the environment.
There are some significant inconsistencies in some of the analyses. For example,
the short-term warming impact of methane is very high compared to CO2. However,
methane converts to CO2 over a period of time. Most of the decision models use a
one hundred year comparison of the relative harm and conclude that methane is
only twenty-nine times more harmful than CO2. But if the focus is on the
short-term rather than long-term impacts, then this ratio needs to be increased.
Global Warming Impact in Tons of CO2 Equivalent in 25 Year Increments for One
Ton of Emissions
Gas Year 1-25 Year 26-50 Year 51-75 Year 76-100 Total
CO2 25 25 25 25 100
Methane 2,825 25 25 25 2,900
In the first 25 years, the warming impact of methane is one hundred thirteen
times greater than CO2. The methane losses from unconventional gas exploration,
production and transport have not been fully quantified. There is general
agreement that they are at least two percent. This still makes gas relatively
greener than conventional coal. However, there are some experts who claim that
losses are closer to four percent which would make even conventional coal
competitive. In any case, there is a big advantage for clean coal over the first
25 years.
Forward looking utility companies such as Great Rivers Energy are building
efficient complexes. The Coal Creek power plant not only generates power but all
the energy needed for a co-located ethanol plant. The Spiritwood plant which is
just being restarted also has a number of efficient ways to utilize excess heat
resulting in efficiencies that are nearly double older stand-alone power plants.
New studies show that if coal-fired power plants were built in areas where there
is a need for enhanced oil recovery there would be a use for all the CO2
generated by all the world’s coal-fired power plants. Furthermore, new
technology for condensing moisture from the power plant discharge gases would
actually create water. Therefore a power plant burning 20 percent biomass and 80
percent coal and also sequestering the CO2 for enhanced oil recovery, would
actually reduce the CO2 in the atmosphere and emit no pollutants; it would also
create, rather than use, water.
Relative Emissions of Pollutants in Tons of CO2 Equivalent
Process Separate and Old
Processes Integrated and New with Carbon Sequestration Integrated and New
Without
Carbon Sequestration
Coal-fired Boiler 100 4 30
Steam Assisted Enhanced Oil Recovery 5 1
Co-generation Facility such as Cellulosic Ethanol 10 1 1
Biomass in Normal Cycle 0 -10 0
Total Impact 115 -4 31
1 ton of SO2 = 100 tons of equivalent CO2, 1 ton of Mercury = 1 million tons of
CO2
If oxycombustion is used, all the flue gases are CO2 so there are no atmospheric
emissions. The CO2 is used to recover oil. No credit is taken for the fact that
additional energy would be required to recover oil from a new source. The Blue
Flint ethanol plant of Great Rivers Energy does not have a dedicated boiler, so
its emissions are negligible. If it were using the cellulosic rather than the
corn based ethanol process, it would also generate waste biomass which could be
combusted in the coal-fired boiler.
In general, biomass is neutral. Plants absorb CO2 as they grow and release it
again when they decay. The substitution for coal in the integrated systems
causes the biomass carbon to be sequestered.
There are many older coal-fired boilers in the U.S. and other countries which
cannot practically produce CO2 for enhanced oil recovery. However, rather than
just operate them as is for the next 25 years before retirement, it will be
highly desirable to convert them to energy complexes including district heating.
The Martin Drake power plant near downtown Colorado Springs is typical of such
plants. It is centrally located where the waste heat can be economically used.
The elimination of the cooling tower would also be an aesthetic benefit. It is
already investing in very efficient SO2 scrubber systems provided by Neumann
Systems. The conversion of older plants to energy complexes can reduce the total
harm in tons of CO2 equivalent to just 27 percent (31/115) of the present
emissions. This is the most cost-effective way to reduce emissions and should be
a high priority.
For more information on: Fossil & Nuclear Power Generation: World Analysis &
Forecast, click on: http://www.mcilvainecompany.com/brochures/energy.html#n043
The World Market for Electrostatic Precipitator Systems, Repair Parts and
Service Will Exceed $15 Billion in 2013
The market for ESP repair and service will be $8 billion in 2013, whereas, the
new systems market will exceed $7.5 billion. This is the conclusion in the
latest update of Electrostatic Precipitators: World Markets published by the
McIlvaine Company. (www.mcilvainecompany.com)
2013 Electrostatic Precipitator Sales Revenues ($ Millions)
Segment New Systems Repair and Upgrade Total
World 7,500 8,000 15,500
Africa 200 130 330
America 800 1,200 2,000
Asia 5,600 5,370 10,970
Europe 900 1,300 2,200
East Asia will be the largest market for new systems as well as for repair parts
and service. In NAFTA and Western Europe, the new system market will be small
compared to repair and service. The reason is that both regions have very large
installed bases of precipitators but small markets for new coal-fired
generators, steel mills and pulp/paper plants. Furthermore, new power plants in
both these regions are more likely to be equipped with fabric filters than
electrostatic precipitators.
India is buying large numbers of precipitators for coal-fired power plants. This
is creating a much larger market for new systems than for repair and service.
However, the ash in Indian coals is abrasive and there is a high ratio of ash to
total coal burned. This creates special maintenance problems.
Chinese suppliers dominate the market for new precipitators in Asia. Alstom is
the market leader in Europe and North America. Major suppliers are also based in
Japan and Korea.
The biggest challenge for precipitator suppliers is the more stringent
regulatory environment. Precipitators are sensitive to the type of particulate
being captured. So when fuels change the precipitator performance changes.
Fabric filters are not sensitive to the dust characteristics and are, therefore,
more likely to be selected when the mandated emission limits are low.
For more information on Electrostatic Precipitators: World Market, click on:
http://www.mcilvainecompany.com/brochures/air.html#n018.
Wind Industry Makes Steady Progress
The latest developments in wind energy may be found in McIlvaine’s Renewable
Energy Projects and Update.
GE Celebrates 300 Wind Turbines Installed in Brazil
GE, which this year is celebrating its 10th anniversary in the wind industry,
announced that it has installed 300 wind turbines in Brazil. Over the next two
years, GE will install more than 600 additional units in Brazil as it continues
to grow in the region, the company reported at the Brazil Windpower Conference
in Rio de Janeiro.
As the GE fleet expands, the company also is announcing its plans to open two
local service centers by 2014, representing a $1.5 million investment in Brazil.
The service centers will employ more than 100 service technicians and be located
in Rio Grande do Norte and Bahia.
Vestas Supplies its First Turbines with Intelligent Aviation Lights, Reducing
the Visual Impact of Wind Power Plants
The Obstacle Collision Avoidance System — or OCAS — is an innovative solution
that only activates the lights when an aircraft is operating in the immediate
vicinity of a wind power plant. This minimizes the visual impact on local
environment and opens up new commercial opportunities for sites with regulatory
lightning restrictions.
The main feature of OCAS is a powerful radar system. Sited at the wind power
plant, radars scan the surrounding area for nearby aircraft. If an aircraft is
detected, the radar-system tracks its heading, speed and altitude and gauges
whether or not the aviation lights on top of the wind turbines should be turned
on. Once the aircraft has safely passed the site, the lights are automatically
switched off again, thereby minimizing the visual impact on the surrounding
environment.
Vestas acquired the technology from Norwegian radar specialists OCAS AS in
October 2011. OCAS is approved by aviation authorities in the U.S., Canada,
Norway and Sweden and is already installed at more than 60 sites throughout
Europe and North America.
Gamesa G8X-2.0 MW and G9X-2.0 MW Machines Received Certificates in China
Gamesa Wind Turbines including G80, G87, G90, G97 and G87 CS –each of them with
2.0 MW of capacity- have received certificates respectively from China
Electricity Power Research Institute (CEPRI).
The testing dates back to April 2011, under the combined efforts of 20 people
from the engineering team and their counterparts in Spain, the first G87-2.0 MW
was tested in Almendarache in September of 2011 and received certificate in
November same year. This successful case set a solid foundation and created a
better communication platform between Gamesa engineers and CEPRI, and
consequently makes it possible for the other four types of Gamesa machines to
get tested and receive certificates within 9 months.
For the advanced G128-4.5 MW wind turbine, Gamesa is scheduled to receive the
certificate in China in the coming two months after finishing a series of tests
of LVRT in Alaiz, Spain on August 14, 2012. It will definitely help Gamesa to
further develop the market for this type of machine in China.
For the time being, Gamesa G58-850 kW has been tested in Liaoning province by
Northeast Electricity Power Research Institute (under CEPRI) and received
certificate in March of this year. G52-850 kW is on the way of testing and will
receive the certificate soon.
Bird-Friendly Wind Power Brings Manufacturing Jobs to New Jersey
Raymond Green, a World War II veteran and retired welder and operating engineer
has hired Sigma Design Company located in Middlesex, N.J. to test, analyze,
refine, optimize and manufacture his patented invention: Catching Wind Power
(CWP) Compressed Air Enclosed Wind Turbine. Once launched, it will bring 25+ new
technology jobs to New Jersey.
The blades of traditional wind turbines can kill bats, birds, and other flying
wildlife. This was a concern to Green, so he designed a system that eliminates
external blades. The patented “Inner Compression Cone Technology” (ICCT)
squeezes the incoming air, compressing it as it is drawn through the turbine and
multiplies it creating more power. The ICCT technology also creates virtually no
noise. The blades are internal, closer together, and smaller therefore
eliminating the sound traditional blades make as they spin and swoop past the
tower.
The turbine is offered in different sizes ranging from personal portables to
massive wind farm units. This versatile product is very cost-efficient for any
location and allows the user to take green energy anywhere they go.
JLM Energy Inc. Introduces Zefr, the Arrayed Wind Turbine
JLM Energy Inc., a leading energy technology company, announced the unveiling of
Zefr, its unique wind array turbine system. Designed as an urban wind turbine,
Zefr is the first of its kind that is engineered to operate in an array.
The breakthrough development of Zefr was initiated when a multidisciplinary team
of engineers and technicians were organized at JLM Energy Inc. The goal was to
increase wind power adoption with smaller, arrayed wind turbines that are
compatible with urban and suburban environments. Zefr broadens the market
opportunities to commercial building owners and their tenants that are looking
to reduce their environmental footprint. Large wind turbines do not have the
same flexibility in urban and suburban environments and are often cost
prohibitive for small to medium size business owners.
Zefr has several advantages including ease of installation, quieter operation,
safety (humans and birds) and it is architecturally more pleasing. Depending on
the configuration of the structure, the turbines can be mounted on rooftops,
sidewalls and pole structures.
Mass Megawatts’ Improved Wind Augmentation System is near Completion
Mass Megawatts Wind Power, Inc. reported that the company's new wind
augmentation system is near completion.
The Mass Megawatts' wind augmentation system utilizes a less complicated and
inexpensive wind-focusing technique to increase the wind velocity directed at
the turbine by an average of 70 percent. This accelerated wind speed, in turn,
results in a significant, three-fold increase in the electrical power generated
by the turbine.
The company's augmentation system eliminates the need for turbine structures to
exceed a height of 80 feet to realize adequate wind velocity. This reduces
material and installation costs while expediting zoning approval in many
locations. Additionally, the augmenter technology makes it possible for turbines
to operate profitably in lower wind-speed locations.
Using horizontal or propeller type turbine blades, the cost per rated kilowatt
is projected to be less than $1000 and anticipated to approach $600 in mass
production. This compares very favorably with traditional wind power systems
that realize a cost of $1500 to $2000 per rated kilowatt.
For more information on Renewable Energy Projects and Update please visit
http://www.mcilvainecompany.com/brochures/Renewable_Energy_Projects_Brochure/renewable_energy_projects_brochure.htm
----------
You can register for our free McIlvaine Newsletters at:
http://www.mcilvainecompany.com/brochures/Free_Newsletter_Registration_Form.htm.
Bob McIlvaine
President
847-784-0012 ext 112
rmcilvaine@mcilvainecompany.com
www.mcilvaine@mcilvainecompany.com
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191 Waukegan Road Suite 208 | Northfield | IL 60093
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