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Biomethane ADVERTISING
INFORMATION Biomethane
- Best Renewable Fuel?
1.
Biomethane is One of the Most Common and
Harmful of All We
Help Cities, Counties and the Agricultural Community Reduce Their Greenhouse
Gas Emissions & Carbon
Dioxide Emissions By Recovering Valuable Biomethane
from Thursday, 29 June 2006 We
are designing and engineering the world's best Anaerobic
Digesters. Biomethane, which we also refer to as "Renewable Natural Gas" is used as a renewable fuel for our cogeneration and trigeneration power plants. Alternatively, we may sell the Biomethane to a customer and transport it to them from our Anaerobic Digesters via natural gas pipelines. We believe Anaerobic Digesters and Biomethane represent an exciting opportunity for multiple reasons: 1. Anaerobic Digesters take an existing liability and waste (Biomethane) and convert it into an asset and profit generator. 2. Anaerobic Digesters mitigate and reverse by preventing Biomethane to escape into the atmosphere, which is one of the major causes of global warming and climate change. Of all Greenhouse Gas Emissions, Biomethane is 21 times more harmful to the atmosphere than are Carbon Dioxide Emissions. 3. Anaerobic Digesters are vital for renewable energy production and helping our country's drive for energy independence. 4. EVERY wastewater treatment plant as well as ALL Concentrated Animal Feeding Operations (CAFO's) - IN EVERY COUNTRY - will soon be installing Anaerobic Digesters to prevent Biomethane from entering the atmosphere and help reverse climate change as well as for use as a renewable fuel. 5. The country of Sweden is the global leader in Biomethane production. Sweden has identified the Biomethane opportunities and is converting biowaste derived from agricultural material and residues into usable Biomethane. The Biomethane is used to generate clean, renewable electricity, residential heating, and also as a transportation fuel. Biomass sources make up 45% of Sweden’s Biomethane. Sweden's Biomethane industry has been growing at an annual rate of around 20% over the last five years. Biomethane powers more than 8,000 transit buses, garbage trucks, and 10 different models of passenger cars in Sweden. Sweden now has more than 25 Biomethane production facilities and 65 filling stations. The country believes that since Biomethane is developed from natural, organic sources that would have been released into the atmosphere, that Biomethane is considered one of the most climate-friendly fuels. Biomethane is 98% methane and easily meets the Swedish and California pipeline standards. According
to Jeff Seisler, Director of the European Natural Gas Vehicle Association,
"Biomethane has an outstanding potential as a multifaceted solution to multifaceted social problems: urban and agricultural waste management, water purification, and clean
air. Urban and agricultural waste can be processed into usable methane, as can the sewage during the water purification
process. Cleaning and compressing the gas for use in vehicles then provides cleaner air than petroleum-consuming vehicles." According
to Peter Boisen Chairman, of ENGVA, "various well respected European research institutes now estimate more than three times better fuel output per hectare of land used than if going for ethanol or
biodiesel. Sweden currently has a 51% biomethane share, [and] Switzerland 37%." France, Norway, Germany and Austria use smaller amounts for vehicles. "Iceland, completely without natural gas, uses 100% biomethane in its NGVs," Boisen says.
Continuing, Boisen adds, "China, India, Korea, the Ukraine, Spain and Italy are other examples of countries now starting up projects where biomethane will be used as a vehicle fuel." Biomethane - the Perfect, Renewable Fuel? As
Biomethane
is a near perfect fuel, and since Biomethane
represents the best of all biofuels in terms of Recycling Carbon, and has
the highest Net
Energy Balance, and as Biomethane
technologies such as Anaerobic Digesters
and Biomass Gasification
development increases and becomes even more commonplace, one of the
fundamental questions is: what is the size of the potential biomass
resource supply in the U.S.? This study doesn't address the opportunities for Biomethane production from biomass feedstock or Biomass Gasification technologies. Some recent estimates indicate that Biomethane could replace up to 50% of present natural gas consumption in the U.S. and in some countries, such as Iceland, Biomethane already provides 100% of the natural gas requirements. There
are many assumptions in the Billion Ton Study report that impact these
estimates, but we believe the estimates reasonably reflect the potential
availability and impact of biomass resources. Biomass to Biofuels By "converting" biomass wastes – such as municipal solid waste, sewage sludge, crop residues, energy crops, and manure – into biofuels, this will resolve the energy, environmental and political problems in an economical and environmentally sound manner - that will produce over one million new jobs. According
to Jeff Seisler, Director of the European Natural Gas Vehicle Association,
"Biomethane has
an outstanding potential as a multifaceted solution to multifaceted social
problems: urban and agricultural waste management, water purification, and
clean air. Urban and agricultural waste can be processed into usable
methane, as can the sewage during the water purification process. Cleaning
and compressing the gas for use in vehicles then provides cleaner air than
petroleum-consuming vehicles." According
to Peter Boisen Chairman, of ENGVA, "various well respected European
research institutes now estimate more than three times better fuel output
per hectare of land used than if going for ethanol or biodiesel. Sweden
currently has a 51% Biomethane share,
and Switzerland 37%. France, Norway, Germany and Austria use smaller
amounts for vehicles. Iceland, completely without natural gas, uses 100%
biomethane in its NGVs," Boisen says. Continuing, Boisen adds,
"China, India, Korea, the Ukraine, Spain and Italy are other examples
of countries now starting up projects where Biomethane
will be used as a vehicle fuel."
BioMethane
Services and Information We provide "turnkey" Biomethane development solutions that generate clean, renewable "BioMethane" (biogas) which in turn, provide a "Renewable Energy Credit." Some of our specialties include; Biomass Gasification, Biomass Gasifiers, Synthesis Gas and Methane Gas Recovery products and services which provide fuel for generating renewable energy and power as well as fuel for our cogeneration and trigeneration plants. BioMethane is generated from Anaerobic Digesters, Anaerobic Lagoons, Biomass Gasification, Biomass Gasifiers, Biogas Recovery, BioMethane, Concentrated Animal Feeding Operations Landfill Gas to Energy, and Methane Gas Recovery. Unlike most companies, we are equipment supplier/vendor neutral. This means we help our clients select the best equipment for their specific application. This approach provides our customers with superior performance, decreased operating expenses and increased return on investment. Cooler, Cleaner, Greener Power & Energy Solutions project development services are one of our specialties. These projects are Kyoto Protocol compliant and generate clean energy and significantly fewer greenhouse gas emissions. Unlike most companies, we are equipment supplier/vendor neutral. This means we help our clients select the best equipment for their specific application. This approach provides our customers with superior performance, decreased operating expenses and increased return on investment. Renewable
Energy Technologies provides
project development services that generate clean energy and significantly
reduce greenhouse gas emissions and
carbon dioxide emissions.
Included in this are our
turnkey "ecogeneration"
products and services which includes renewable
energy technologies, waste to energy,
waste to watts and waste
heat recovery solutions. Other project development
technologies include; Anaerobic Digester,
Anaerobic Lagoon, Biogas
Recovery, BioMethane, Biomass
Gasification, and Landfill Gas To
Energy, project development services.
For more information: call us at: 832-758-0027 We are Renewable Energy Technologies specialists and develop clean power and energy projects that will generate a "Renewable Energy Credit," Carbon Dioxide Credits and Emission Reduction Credits. Some of our products and services solutions and technologies include; Absorption Chillers, Adsorption Chillers, Automated Demand Response, Biodiesel Refineries, Biofuel Refineries, Biomass Gasification, BioMethane, Canola Biodiesel, Coconut Biodiesel, Cogeneration, Concentrating Solar Power, Demand Response Programs, Demand Side Management, Energy Conservation Measures, Energy Master Planning, Engine Driven Chillers, Geothermal Heatpumps, Groundsource Heatpumps, Solar CHP, Solar Cogeneration, Rapeseed Biodiesel, Solar Electric Heat Pumps, Solar Electric Power Systems, Solar Heating and Cooling, Solar Trigeneration, Soy Biodiesel, Trigeneration, and Watersource Heatpumps. More
About BioMethane, BioMethanation and
Methanogenesis: BioMethane is the new, and renewable "natural gas!" Biomethane will some day replace the "methane" that is sold by the local gas companies. Biomethane has an unlimited supply, whereas the methane sold by gas companies has a limited supply. Biomethane is renewable, whereas the methane sold by your gas utility company is not renewable. Biomethane recovery, use and production generates "Greentags" or a "Renewable Energy Credit" for the owners and is GOOD for our environment. The production and use of the natural gas sold by the gas company does NOT generate these incentives and new revenue streams and is NOT good for our environment. Biomethane is "naturally" produced from organic materials as they decay. Sources of BioMethane include; landfills, POTW's/Wastewaster Treatment Systems, and every tree or agricultural product that is no longer living. Biomethane is also generated from animal operations where manure can be collected and the BioMethane is generated from anaerobic digesters where the manure decomposes. BioMethane, after installation of the biomethane equipment is essentially free, as opposed to buying natural gas, presently costing around $10.00/mmbtu. Methanogenesis is the production of CH4 and CO2 by biological processes that are carried out by methanogens. More About
Biomass
Gasification and BioMethanation Technology Biomass Gasification is the process in which BioMethane is produced in the BioMass Gasification process. The BioMethane is then used like any other fuel, such as natural gas, which is not a renewable fuel. What are Biomass Gasifiers? Biomass gasifiers are reactors that heat biomass in a low-oxygen environment to produce a fuel gas that contains from one fifth to one half (depending on the process conditions) the heat content of natural gas. The gas produced from a gasifier can drive highly efficient devices such as turbines and fuel cells to generate electricity. More
About Biomass Gasification and BioMethanation Technology As
previously stated, Biomethanation is the process of conversion of organic
matter in the waste (liquid or solid) to Biomethane (sometimes referred to
as "Biogas) and manure by microbial action in the absence of air,
known as "anaerobic digestion." Interest
in Biomethanation as an economic, environmental and energy-saving waste
treatment continues to gain greater interest world-wide and has led to the
development of a range of anaerobic reactor designs. These high-rate,
high-efficiency anaerobic digesters are also referred to as "retained
biomass reactors" since they are based on the concept of retaining
viable biomass by sludge immobilization.
It has the potential to become the growth engine for rural development in
the country. Biomass fuels such as firewood and agriculture-generated residues and wastes are generally organic. They contain carbon, hydrogen, and oxygen along with some moisture. Under controlled conditions, characterized by low oxygen supply and high temperatures, most biomass materials can be converted into a gaseous fuel known as producer gas, which consists of carbon monoxide, hydrogen, carbon dioxide, methane and nitrogen. This thermo-chemical conversion of solid biomass into gaseous fuel is called biomass gasification. The producer gas so produced has low a calorific value (1000-1200 Kcal/Nm3), but can be burnt with a high efficiency and a good degree of control without emitting smoke. Each kilogram of air-dry biomass (10% moisture content) yields about 2.5 Nm3 of producer gas. In energy terms, the conversion efficiency of the gasification process is in the range of 60%-70%. Multiple Advantages of Biomass Gasification Conversion of solid biomass into combustible gas has all the advantages associated with using gaseous and liquid fuels such as clean combustion, compact burning equipment, high thermal efficiency and a good degree of control. In locations, where biomass is already available at reasonable low prices (e.g. rice mills) or in industries using fuel wood, gasifier systems offer definite economic advantages. Biomass gasification technology is also environment-friendly, because of the firewood savings and reduction in CO2 emissions. Biomass gasification technology has the potential to replace diesel and other petroleum products in several applications, foreign exchange. Applications for Biomass Gasification Thermal applications: cooking, water boiling, steam generation, drying etc. Motive power applications: Using producer gas as a fuel in IC engines for applications such as water pumping Electricity generation: Using producer gas in dual-fuel mode in diesel engines/as the only fuel in spark ignition engines/in gas turbines. Publicly Owned Treatment Works ("POTW's") or Wastewater Treatment Plants More and more, cities, counties and municipalities are faced with greater environmental compliance issues relating to their municipally-owned landfills, Publicly Owned Treatment Works ("POTW's") or Wastewater Treatment Plants. A city's landfill and/or POTW provides an excellent opportunity for cities to reduce their emissions as well as provide an additional revenue stream. These facilities may have valuable gases that our company recovers and pipes to one of our clean, environmentally-friendly cogeneration or trigeneration energy systems. We solve a city's environmental liabilities (air emissions) and provide a new cash flow simultaneously. We offer turn-key solutions for cities that includes the preliminary feasibility analysis, engineering and design, project management, permitting and commissioning. We provide very attractive financing packages for cities that does not add to a city's liability, yet provides a valuable new revenue stream. And, we are also able to offer a turn-key solution for qualified municipalities that includes our company owning, operating and maintaining the onsite power and energy plant. At
the heart of the system is a (Bio) Methane Gas Recovery system similar
those used in Flare Gas Recovery or Vapor Recovery Units. Methane
Gas Recovery, Flare Gas Recovery, Vapor Recovery, Waste to Energy and
Vapor Recovery Units all recover valuable "waste" or vented
fuels that can be used to provide fuel for an onsite power generation
plant. Our waste-to-energy and waste to fuel systems significantly
or entirely, reduces your facility's emissions (such as Methane
Gas Recovery and vapor recovery units can be located in hundreds of
applications and locations. At a landfill, Wastewaster Treatment
System (or Publicly Owned Treatment Works - "POTW") gases from
the facility can be captured from the anaerobic digesters, and manifolded/piped
to one of our onsite power generation plants, and make, essentially,
"free" electricity for your facility's use. These
associated "biogases" that are generated from municipally
owned landfills or wastewater treatment plants have low btu content or
heating values, ranging around 550-650 btu's.
This makes them Additionally, if heat (steam and/or hot water) is required, we will incorporate our cogeneration or trigeneration system into the project and provide some, or all, of your hot water/steam requirements. Similarly, at crude oil refineries, gas processing plants, exploration and production sites, and gasoline storage/tank farm site, we convert your facility's "waste fuel" and environmental liabilities into profitable, environmentally-friendly solutions. Our
Methane Gas Recovery systems are designed and engineered for these
specific applications. It is important to note that there are many
internal combustion engines or combustion turbines that are NOT suited for
these applications. Our systems are engineered precisely for your
facility's application, and our engineers know the engines and turbines
that will work as well as those that don't. More importantly, we are
vendor and supplier neutral! Our only concerns are for the optimum
system solution Our turn-key systems includes design, engineering, permitting, project management, commissioning, as well as financing for our qualified customers. Additionally, we may be interested in owning and operating the flare gas recovery or vapor recovery units. For these applications, there is no investment required from the customer. For more information, please provide us with the following information about the flare gas or vapor:
An
Anaerobic Digester is a device for optimizing the anaerobic digestion of
biomass and/or animal manure, and possibly to recover biogas also referred
to as BioMethane for energy production.
Digester types include batch, complete mix, continuous flow (horizontal or
plug-flow, multiple-tank, and vertical tank), and covered lagoon. Anaerobic
digestion is a biological process that produces a gas principally composed
of methane (CH4) and carbon dioxide (CO2) otherwise known as biogas. These
gases are produced from organic wastes such as livestock manure, food
processing waste, etc. The
The
U.S. EPA AgSTAR is an outreach program designed to reduce methane
emissions from livestock waste management operations by promoting the use
of biogas recovery systems. A biogas recovery system is an anaerobic
digester with biogas capture and combustion to produce electricity, heat
or hot water. Biogas recovery systems are effective at confined livestock
facilities that handle manure as liquids and slurries, typically swine and
dairy farms. Anaerobic digester technologies provide enhanced
environmental and financial performance when compared to traditional waste
management systems such as manure storages and lagoons. Anaerobic
digesters are particularly effective in reducing methane emissions but
also provide other air and water pollution control opportunities. AgSTAR
provides an array of information and tools designed to assist producers in
the evaluation and implementation these systems, including:
Methane
Emissions from Animal Waste Management Methane
emissions occur whenever animal waste is managed in anaerobic conditions.
Liquid manure management systems, such as ponds, anaerobic lagoons, and
holding tanks create oxygen free environments that promote methane
production. Manure deposited on fields and pastures, or otherwise handled
in a dry form, produces insignificant amounts of methane. Currently,
livestock waste contributes about 8 percent of human-related methane
emissions in the Emission
Reduction Technology: Anaerobic Digestion For
more detailed information on commercially available anaerobic digestion
technologies and their costs, download Managing
Manure with Biogas Recovery Systems: Improved Performance at Competitive
Costs (PDF, 4 pp., 4.4
MB Accomplishments
The AgSTAR Program has been very successful in encouraging the development
and adoption of anaerobic digestion technology. Since the establishment of
the program in 1994, the number of operational digester systems has
doubled. This has produced significant environmental and energy benefits,
including methane emission reductions of approximately 124,000 metric tons
of carbon equivalent and annual energy generation of about 30 million kWh.
The graph below shows the historical use of biogas recovery technology for
animal waste management.
The
development of anaerobic digesters for livestock manure treatment and
energy production has accelerated at a very fast pace over the past few
years. Factors influencing this market demand include: increased technical
reliability of anaerobic digesters through the deployment of successful
operating systems over the past five years; growing concern of farm owners
about environmental quality; an increasing number of state and federal
programs designed to cost share in the development of these systems; and
the emergence of new state energy policies (such as net metering
legislation) designed to expand growth in reliable renewable energy and
green power markets. In
the past 2 years alone, the number of operational digester systems has
increased by 30%. For more detailed information on anaerobic digester use
in the The
process of anaerobic digestion consists of three steps. This
section describes the anaerobic digestion (AD) process, outlines
guidelines for assessing the feasibility of AD and biogas usage at a swine
facility and provides summary information on AD system performance and
reliability. Anaerobic
Digestion Technology Description AD
promotes the bacterial decomposition of the volatile solids (VS) in animal
wastes to biogas, thereby reducing lagoon loading rates and odor. The
primary component of an AD system is the anaerobic digester, a waste
vessel containing bacteria that digest the organic matter in waste streams
under controlled conditions to produce biogas. As an effluent, AD yields
nearly all of the liquid that is fed to the digester. This remaining fluid
consists of mostly water and is allowed to evaporate from a secondary
lagoon, land-applied for irrigation and fertilizer value or recycled to
flush manure from the swine building to the digester. The
benefits of AD include:
AD
takes place in three steps: hydrolysis, acid formation, and methane
generation. During the first step, hydrolysis, bacterial enzymes break
down proteins, fats and sugars in the waste to simple sugars. During acid
formation, bacteria convert the sugars to acetic acid, carbon dioxide and
hydrogen. Then the bacteria convert the acetic acid to methane and carbon
dioxide, and combine carbon dioxide and hydrogen to form methane and
water. Digester
technologies that can be used to collect biogas from swine facilities
include:
Although
a sequencing batch reactor has been used for AD at one swine facility in
the Appendix
B provides contact information that can help producers find AD system
designers/installers, odor control technologies, generators, heating and
cooling equipment, and other information to help manage air and water
quality at hog facilities. Covered
lagoon digesters are the simplest AD system. These systems typically
consist of an anaerobic combined storage and treatment lagoon, an
anaerobic lagoon cover, an evaporative pond for the digester effluent, and
a gas treatment and/or energy conversion system. Figure 1 shows a typical
schematic for a floating covered anaerobic lagoon.
Figure
1 . Covered anaerobic lagoon digester Covered
lagoon digesters typically have a hydraulic retention time (HRT) of 40 to
60 days. The HRT is the amount of time a given volume of waste remains in
the treatment lagoon. A collection pipe leading from the digester carries
the biogas to either a gas treatment system such as a combustion flare, or
to an engine/generator or boiler that uses the biogas to produce
electricity and heat. Following treatment, the digester effluent is often
transferred to an evaporative pond or to a storage lagoon prior to land
application. Climate
affects the feasibility of using covered lagoon digesters to generate
electricity. Engine/generator systems typically do not produce sufficient
waste heat to maintain temperatures high enough in covered lagoon
digesters in the winter to sustain consistently high biogas production
rates. Using propane or natural gas to provide additional heat for the
lagoon contents is typically not an economically viable option. Without
that additional heat, most covered lagoon digesters produce less biogas in
colder temperatures, and little or no gas below 39 FACE=
"Symbol">° F. As a result, covered lagoon digesters are most
appropriate for use in warm climates if the biogas is to be used for
energy or heating purposes. Complete
mix digester systems consist of a mix tank, a complete mix digester and a
secondary storage or evaporative pond. The mix tank is either an
aboveground tank or concrete in-ground tank that is fed regularly from
underfloor waste storage below the animal feedlot. Waste is stirred in the
mix tank to prevent solids from settling in the waste prior to being fed
to the digester. The complete mix digester is essentially a
constant-volume aboveground tank or in-ground covered lagoon that is fed
daily from the mix tank. Complete mix digesters with in-ground lagoons
often employ covers similar to those used in covered lagoon digesters. In
the digester, a mix pump circulates waste material slowly around the
heater to maintain a uniform temperature. Hot water from an
engine/generator cogeneration water jacket or boiler is used to heat the
digester. A cylindrical aboveground tank, such as that shown in Figure 2,
optimizes biogas production, but is more capital intensive than in-ground
tanks. The only operating AD system in Source:
EPA. (February 1997). AgStar Technical Series: Complete Mix Digesters –
A Methane Recovery Option for All Climates. EPA 430-F-97-004. Figure
2 . Complete mix digester schematic Complete
mix digesters have an HRT of 15 to 20 days, which means that complete mix
digesters can reduce the overall lagoon volume required for waste storage
and treatment. This makes complete mix digesters comparable to covered
lagoon digesters in cost, despite the increased complexity of stirring,
mixing and plumbing components. In addition, biogas production rates, and
therefore heat and electricity production, are greater and more consistent
than for covered lagoons. This can help reduce system payback periods
compared to covered lagoon systems. Like covered lagoon systems, digester
effluent from complete mix digesters is frequently stored in evaporative
ponds or storage lagoons. System
Requirements This
section provides guidelines for conducting a preliminary assessment of the
feasibility of using AD at a swine facility. Although AD system
requirements will vary depending on the application and system design,
there are some rule-of-thumb measures that should be noted when assessing
the feasibility of AD at a given location. For AD to potentially be
technically feasible and cost-effective, a swine facility should:
If
the above characteristics are present, the facility is a possible
candidate for AD. Many pre-existing waste storage and treatment lagoons
are too large to practically or cost-effectively employ covers over their
entire area. Partial covers may be an option to recover methane from these
older systems, as an alternative to installing a completely new storage
and treatment lagoon system. If
energy recovery is to be employed, methane production and gas quality
should be considered and compared to energy requirements at the facility.
Daily biogas production at installed farm-based anaerobic digesters in the
Facilities
that are located south of the line of climate limitation in Figure 3 are
usually warm enough for cost-effective energy recovery from covered lagoon
digesters. In most cases, facilities north of the climate line in Figure 3
are too cold for cost-effective energy recovery from covered lagoon
digesters. Complete mix digesters can be used in cold or warm climates. If
odor control is the only objective, either covered lagoon or complete mix
digesters may be used, but odor control will be less effective in the
winter for covered lagoon digesters south of the line of climate
limitation in Figure 3. In general, complete mix digesters are the most
appropriate choice for use in
Figure
3 . Line of climate limitation for biogas energy recovery Table
2 shows which digesters are appropriate for the waste collection
strategies at covered swine facilities. Complete mix digesters can operate
with a waste total solids (TS) percentage between 3 and 10 percent, while
covered lagoon digesters can use waste with a TS percentage less than 2
percent. Table
2 . Matching a digester to existing waste collection practices
Source
– Adapted from: EPA. (July 1997). AgStar Handbook: A Manual for
Developing Biogas Systems at Commercial Appendix
C describes each of the various waste collection technologies listed in
Table 2. Biomethane Utilization Options This
section discusses some of the biogas utilization options that are
available for use with AD. Electricity generation with waste heat recovery
(cogeneration) and direct combustion and use in equipment that normally
uses propane or natural gas are the two primary options for biogas
utilization. Electricity generated using biogas can be generated for
on-farm use or for sale to the electric power grid if an economically
attractive power purchase agreement can be negotiated through the local
utility or rural electric cooperative. Direct combustion allows the gas to
be used in existing equipment that normally uses propane or natural gas
such as boilers or forced air furnaces with minor equipment modifications.
Combustion is usually a seasonal use for biogas, as most boiler and
furnace applications are only required during the winter. The EPA FarmWare
manual describes some characteristics of engine/generator and direct
combustion systems that can be used with biogas. The following subsections
draw from the FarmWare manual to provide some basic information about the
use of these systems at covered swine facilities and other farm
applications. Electricity Generation Commercial
electricity generation systems that use biogas typically consist of an
internal combustion (IC) engine, a generator, a control system and an
optional heat recovery system. IC
engines designed to burn propane or natural gas are easily converted to
burn biogas by adjusting carburation and ignition systems. Such engines
are available in nearly any capacity, but the most successful varieties
are industrial engines that are designed to work with wellhead natural
gas. A biogas-fueled engine will normally convert 18 to 25 percent of the
biogas Btu value to electricity. Two
types of generators are used on farms: induction generators and
synchronous generators. Induction generators operate in parallel with the
utility and cannot operate as a stand-alone power source. Induction
generators derive their phase, frequency and voltage from the utility.
Synchronous generators operate as an isolated system or in parallel to the
utility, and require more sophisticated intertie systems to match output
to utility phase, frequency and voltage. Control
systems are required to protect the engine and the utility. Control
packages are available that can shut the engine off due to mechanical
problems, utility power outage or utility voltage and frequency
fluctuations, or in the event that excess power is generated that the
utility will not accept. Generators that operate in parallel with the
utility system, such as induction generators, require an intertie system
with safety relays to shut off the engine and disconnect from the utility
in the event of a problem. Intertie negotiations with a utility for
induction generators are typically much easier than for a synchronous
generator, due to the level of control the utility has over the
characteristics of power entering the grid from an induction generator.
The primary advantage of a synchronous generator is its ability to act as
a stand-alone power source. However, if operated as an isolated system, a
synchronous generator must be oversized to meet the highest electrical
demand, while operating less efficiently at average or partial loads. Due
to the system size and more complicated control requirements, a
synchronous generator operating as an isolated system is typically more
expensive than an induction generator. Biogas
engines reject approximately 75 to 82 percent of the energy input as waste
heat. This waste heat can be used to heat the digester and/or provide
water or space heat to the facility. Commercial heat exchangers can
recover waste heat from the engine water cooling system and the engine
exhaust, recovering up to 7,000 Btu/hour for each kW of generator load.
Waste heat recovery increases the energy efficiency of the system to 40 to
50 percent. Ongoing
research and development is focusing on the use of microturbines and fuel
cells for converting biogas to electricity. Microturbines are high-speed,
small-scale (typically less than 100 kW) gas-driven turbine systems that
produce electricity efficiently, have low emissions and require little
maintenance. Reflective Energies in The
Department of Energy’s WRBEP funded a project in fiscal year 2000 in Direct Combustion Direct
combustion of biogas on-site in a boiler or forced air furnace can provide
seasonal heat to nurseries, farrowing rooms and other facilities at a
swine facility. A cast iron natural gas boiler can be used for most farm
boiler applications. The air-fuel mixture will require adjustment and
burner jets will need to be enlarged for use with low-Btu gas. Cast iron
boilers are available in many sizes, from 45,000 Btu/hour and up.
Untreated biogas may be used, but all metal surfaces of the boiler housing
should be painted to prevent corrosion. Flame tube boilers with heavy
gauge flame tubes may be used if the exhaust temperature is maintained
above 300 FACE= "Symbol">° F to prevent condensation. Forced
air furnaces can be used in place of direct fire room heaters, but biogas
must be treated to remove hydrogen sulfide because of potential corrosion
problems in metal ductwork. System
Performance and Benefits of AD There
are several measures of waste management system performance that are
relevant for producers considering the use of AD. These include:
AD
is the only waste management strategy available that provides the option
to recover methane for energy production. The
APCD has determined that the minimum standard for compliance with odor
control regulations for waste vessels and impoundments is an 80 percent
reduction in all odor-causing gases, including hydrogen sulfide, ammonia
and volatile organic compounds from waste vessels or impoundments. Table 3
compares the effectiveness of some of the odor control methods being
implemented at covered swine facilities in Table
3 . Odor control effectiveness of management strategies for
anaerobic lagoons
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