Algae energy partnerships for waste water treatment plants. Our focus is lowering operational costs and carbon emissions while producing marketable biofuels.
Algae Bioenergy Solutions (ABS) plans to build a $2 million, 300,000 square foot facility in South Carolina to produce 40 million gallons per year of algae for biodiesel. ABS will use low-cost nutrients from wastewater facilities and CO2 from digesters to grow algae in photobioreactors. Electricity not used for production will be sold. ABS has an agreement with a nearby biodiesel plant to purchase the algal oil for $2-3 per gallon. Locating near existing infrastructure and using waste resources can help reduce capital costs and make algae production profitable.
Organic Feedstock & Products: A Developer's PerspectiveMassRecycle .
Organics Workshop- Mixed Organics Streams as Feedstock and Products:
Molly Bales from Harvest Power shows how the company converts organic materials into soil products and renewable energy.
Biodiesel is an alternative fuel made from vegetable oils and animal fats that can be used in diesel engines. It has advantages like being cheaper and more environmentally friendly than petroleum diesel, but producing it on a large scale could use up land needed for food crops and pure biodiesel does not flow well in cold weather. The document lists some Alberta companies and experts that work with biodiesel and advocates lobbying the government to support biodiesel due to its environmental and health benefits.
Impact on Air Quality and Climate Change: Where the Dairy Industry Stands- Jo...DAIReXNET
This material was presented as part of DAIReXNET's April 4, 2011 webinar entitled "Impact on Air Quality and Climate Change-Where the Dairy Industry Stands."
The document describes plans to build an anaerobic digestion plant to convert dairy cow manure into biogas. The plant will process 1,100 tons of manure per day from the surrounding dairy industry to produce 15,520 cubic meters per hour of biogas. This biogas will fuel generators to produce 46 megawatts of electricity. The plant will be located on 30 hectares of land and use wastewater for processing. It will create jobs and provide renewable energy while reducing pollution from dairy waste.
Algae Bioenergy Solutions (ABS) plans to build a $2 million, 300,000 square foot facility in South Carolina to produce 40 million gallons per year of algae for biodiesel. ABS will use low-cost nutrients from wastewater facilities and CO2 from digesters to grow algae in photobioreactors. Electricity not used for production will be sold. ABS has an agreement with a nearby biodiesel plant to purchase the algal oil for $2-3 per gallon. Locating near existing infrastructure and using waste resources can help reduce capital costs and make algae production profitable.
Organic Feedstock & Products: A Developer's PerspectiveMassRecycle .
Organics Workshop- Mixed Organics Streams as Feedstock and Products:
Molly Bales from Harvest Power shows how the company converts organic materials into soil products and renewable energy.
Biodiesel is an alternative fuel made from vegetable oils and animal fats that can be used in diesel engines. It has advantages like being cheaper and more environmentally friendly than petroleum diesel, but producing it on a large scale could use up land needed for food crops and pure biodiesel does not flow well in cold weather. The document lists some Alberta companies and experts that work with biodiesel and advocates lobbying the government to support biodiesel due to its environmental and health benefits.
Impact on Air Quality and Climate Change: Where the Dairy Industry Stands- Jo...DAIReXNET
This material was presented as part of DAIReXNET's April 4, 2011 webinar entitled "Impact on Air Quality and Climate Change-Where the Dairy Industry Stands."
The document describes plans to build an anaerobic digestion plant to convert dairy cow manure into biogas. The plant will process 1,100 tons of manure per day from the surrounding dairy industry to produce 15,520 cubic meters per hour of biogas. This biogas will fuel generators to produce 46 megawatts of electricity. The plant will be located on 30 hectares of land and use wastewater for processing. It will create jobs and provide renewable energy while reducing pollution from dairy waste.
Photo-bioreactor - Norezatul Shahirah bt Ahmad ZamanhuriKhaleeda Karim
This document discusses photobioreactors, which are bioreactors that use light to cultivate phototrophic microorganisms. Photobioreactors allow for carefully controlled conditions that enable higher growth rates than what is possible in natural environments. They can potentially use nutrient-rich wastewater and carbon dioxide from flue gases to derive phototrophic biomass. The document describes open and closed photobioreactor systems. Open systems like ponds have limited productivity due to depth and light availability, while closed systems can achieve higher cell densities but require more advanced engineering. The document outlines the wastewater treatment process using a photobioreactor and notes their advantages in preventing contamination and better controlling conditions.
Role of protozoa and algae in waste water treatment plantpunjab university
Protozoa and algae play important roles in wastewater treatment. Protozoa help maintain biomass and remove bacteria through predation. They improve flocculation and effluent quality. Algae can remove nutrients like nitrogen and phosphorus but often do not settle well. Wastewater is well-suited for algae growth as a biofuel feedstock. Adding carbon dioxide to wastewater treatment ponds can balance nutrients for improved algae growth and wastewater treatment while producing a biofuel.
The document discusses microalgae as a source of biofuels. It notes that microalgae have the potential to produce more biomass and oil per unit area than other feedstocks. The document outlines the cultivation, harvesting, and processing steps to produce biofuels from microalgae, including biodiesel production via transesterification. While microalgae have promising theoretical yields, achieving these at commercial scale has proven challenging due to the energy and costs required for cultivation, harvesting, and processing of algal biomass.
This document summarizes water treatment and sewage treatment processes. It describes how surface water is treated through steps like sedimentation, flocculation, filtration, chlorination and fluoridation to remove contaminants. Sewage treatment involves primary, secondary and sometimes tertiary levels to remove solids, break down organic waste biologically, and remove nutrients like nitrates and phosphates. The document also discusses how excess nutrients can cause eutrophication of waterways and pollution from heavy metals and legislation limits their levels.
Waste Water Treatment Process PresentationAshish Kakadia
Ozone is a powerful disinfectant that is more effective than chlorine and can be used for waste water treatment. It is generated on-site and is highly reactive, able to oxidize organic compounds and precipitate heavy metals. Ozone can be used to treat a variety of waste streams, including municipal, industrial, and mining waste water. It is effective at removing color, cyanide, pathogens, BOD, and emerging contaminants like pharmaceuticals.
This document discusses wastewater treatment. It defines wastewater as used water that contains food scraps, oils, soaps, and human and industrial wastes. Wastewater is treated at a wastewater treatment plant (WWTP) through primary, secondary, and tertiary treatment stages to remove pollutants. Primary treatment removes large solid objects, secondary treatment uses biological processes like activated sludge to remove dissolved and suspended organic matter, and tertiary treatment uses disinfection like chlorination to kill pathogens. The goal of wastewater treatment is to recycle water for reuse and protect public health and aquatic environments.
This document discusses water pollution, including its causes, sources, types, effects, and methods of prevention. It defines water pollution as the contamination of water bodies by human and natural activities. The two main sources are point source pollution from single identifiable sources like factories, and non-point source pollution from multiple diffuse sources like agricultural runoff. Various types of water pollution are described, and effects include harm to aquatic life, disruption of food chains, diseases in humans, and destruction of ecosystems. Prevention methods center around proper waste disposal, reduced chemical usage, and wastewater treatment.
ABS is an algae development company that determines the economic feasibility of algae processing through joint ventures. It focuses on applied technology and operational efficiency to lower capital and operating expenses. ABS plans to develop a 10 million gallon per year algae processing plant in Georgia using nutrients from waste water facilities and a power plant's CO2 emissions. The algae oil would be used as feedstock for an existing biodiesel plant, while the residual algae products could be sold as fertilizer or animal feed.
The document discusses algae biofuel as a promising alternative fuel source. It provides information on the advantages of algae biofuel such as its high yield per acre and ability to use wastewater. The document also discusses challenges such as the need for large-scale sustainable algae production and efficient oil extraction methods. It outlines the key steps in the potential algae biofuel production process and value chain.
Algae Renewable Energy Carbon Credit First Timer70CentsaGallon
The interest in algae farming also includes implementing Carbon Capture, Biofuel Production, Power Generation, and other industrial flue gasses for use in Photo bioreactors for algae cultivation.
This document discusses the potential of algae as a source of biofuel and other products. It begins by describing how algae were crucial for oxygenating the early Earth's atmosphere. Today, algae are being investigated for their potential to provide abundant fuel, food, and help sequester carbon. The document outlines the financial investments that have been made in algae technology companies and projects timelines for commercialization of algae fuels ranging from 2-3 years to over 10 years depending on the company. It also discusses using algae for nutraceuticals and describes some algae cultivation and photobioreactor technologies.
Flue gas mitigation technology that will aid in alleviating our emissions from point sources (i.e. power plants) by supplementing growth of ALGAE to produces our transportation sector fuels.
Global Energy Technology Group plans to acquire farms in California to develop renewable energy projects using jatropha biodiesel. The company will purchase land and develop jatropha plantations to produce oil for biodiesel production. Jatropha is a drought-resistant crop suitable for marginal lands that produces oil for biodiesel without competing with food crops. The company expects to benefit from government incentives for biodiesel production and carbon credits from the jatropha plantations.
Bio aviation refers to the use of sustainable biofuels instead of fossil fuels in the aviation industry. Second generation biofuels are produced from non-food crop sources like jatropha and camelina and can reduce lifecycle emissions by up to 84%. Several airlines have conducted test and commercial flights using biofuel blends of up to 50% with no required aircraft modifications. The aviation industry is working to develop and certify sustainable biofuels that meet performance and environmental standards for widespread commercial use.
The document discusses the concept of a bio-economy and services provided by a bio-economy consultancy. The consultancy offers four services to help clients realize their bio-economy goals: research, experimentation, process design/modeling, and project commissioning. Examples are given of leading bio-economy companies in areas like biofuels, biochemicals, and sustainable waste recovery.
Green Earth Technologies produces biodegradable motor oils, cleaning products, and other goods made from renewable resources like plant and animal oils. Their G-Brand products are patented and designed to be environmentally friendly alternatives to conventional petroleum-based goods. Green Earth aims to reduce foreign oil dependence and pollution through its sustainable and domestically-produced lines.
This document discusses various models for producing biodiesel from waste cooking oil on the West Coast of the United States. It outlines commercial, public, and legal models including a program in Santa Cruz that collects used fryer oil from restaurants to produce biodiesel, a program in San Francisco that collects brown and yellow grease to produce biodiesel, and a legal mandate in Portland requiring biodiesel blends and limiting feedstocks. The document also provides resources on biodiesel production, environmental regulations, and funding opportunities to support more sustainable biodiesel programs.
Pond Technologies was founded in Toronto, Canada on May 2007. Their mission is to use microalgae, the original superfood and the planet’s first carbon storage technology, to solve some of the largest problems facing the world today.
Algae-based biofuels company that provides equipment and services for algae production and processing. They aim to become the premier algae solutions provider in Florida through projects like utilizing farmland for algae-to-biodiesel production. Algae oil has potential as a sustainable feedstock due to its high yields per acre and ability to grow anywhere. The company explores using algae for wastewater treatment and CO2 sequestration in addition to biofuel production.
Recent talks on biofuels have outlined their un-sustainability in the production phase; commodities such as corn, rapeseed, palm oil and soya are being grown and harvested in a way that could have negative economic, social and environmental effects, and have a global impact on land use, food security, water resources, deforestation and global markets.
Photo-bioreactor - Norezatul Shahirah bt Ahmad ZamanhuriKhaleeda Karim
This document discusses photobioreactors, which are bioreactors that use light to cultivate phototrophic microorganisms. Photobioreactors allow for carefully controlled conditions that enable higher growth rates than what is possible in natural environments. They can potentially use nutrient-rich wastewater and carbon dioxide from flue gases to derive phototrophic biomass. The document describes open and closed photobioreactor systems. Open systems like ponds have limited productivity due to depth and light availability, while closed systems can achieve higher cell densities but require more advanced engineering. The document outlines the wastewater treatment process using a photobioreactor and notes their advantages in preventing contamination and better controlling conditions.
Role of protozoa and algae in waste water treatment plantpunjab university
Protozoa and algae play important roles in wastewater treatment. Protozoa help maintain biomass and remove bacteria through predation. They improve flocculation and effluent quality. Algae can remove nutrients like nitrogen and phosphorus but often do not settle well. Wastewater is well-suited for algae growth as a biofuel feedstock. Adding carbon dioxide to wastewater treatment ponds can balance nutrients for improved algae growth and wastewater treatment while producing a biofuel.
The document discusses microalgae as a source of biofuels. It notes that microalgae have the potential to produce more biomass and oil per unit area than other feedstocks. The document outlines the cultivation, harvesting, and processing steps to produce biofuels from microalgae, including biodiesel production via transesterification. While microalgae have promising theoretical yields, achieving these at commercial scale has proven challenging due to the energy and costs required for cultivation, harvesting, and processing of algal biomass.
This document summarizes water treatment and sewage treatment processes. It describes how surface water is treated through steps like sedimentation, flocculation, filtration, chlorination and fluoridation to remove contaminants. Sewage treatment involves primary, secondary and sometimes tertiary levels to remove solids, break down organic waste biologically, and remove nutrients like nitrates and phosphates. The document also discusses how excess nutrients can cause eutrophication of waterways and pollution from heavy metals and legislation limits their levels.
Waste Water Treatment Process PresentationAshish Kakadia
Ozone is a powerful disinfectant that is more effective than chlorine and can be used for waste water treatment. It is generated on-site and is highly reactive, able to oxidize organic compounds and precipitate heavy metals. Ozone can be used to treat a variety of waste streams, including municipal, industrial, and mining waste water. It is effective at removing color, cyanide, pathogens, BOD, and emerging contaminants like pharmaceuticals.
This document discusses wastewater treatment. It defines wastewater as used water that contains food scraps, oils, soaps, and human and industrial wastes. Wastewater is treated at a wastewater treatment plant (WWTP) through primary, secondary, and tertiary treatment stages to remove pollutants. Primary treatment removes large solid objects, secondary treatment uses biological processes like activated sludge to remove dissolved and suspended organic matter, and tertiary treatment uses disinfection like chlorination to kill pathogens. The goal of wastewater treatment is to recycle water for reuse and protect public health and aquatic environments.
This document discusses water pollution, including its causes, sources, types, effects, and methods of prevention. It defines water pollution as the contamination of water bodies by human and natural activities. The two main sources are point source pollution from single identifiable sources like factories, and non-point source pollution from multiple diffuse sources like agricultural runoff. Various types of water pollution are described, and effects include harm to aquatic life, disruption of food chains, diseases in humans, and destruction of ecosystems. Prevention methods center around proper waste disposal, reduced chemical usage, and wastewater treatment.
ABS is an algae development company that determines the economic feasibility of algae processing through joint ventures. It focuses on applied technology and operational efficiency to lower capital and operating expenses. ABS plans to develop a 10 million gallon per year algae processing plant in Georgia using nutrients from waste water facilities and a power plant's CO2 emissions. The algae oil would be used as feedstock for an existing biodiesel plant, while the residual algae products could be sold as fertilizer or animal feed.
The document discusses algae biofuel as a promising alternative fuel source. It provides information on the advantages of algae biofuel such as its high yield per acre and ability to use wastewater. The document also discusses challenges such as the need for large-scale sustainable algae production and efficient oil extraction methods. It outlines the key steps in the potential algae biofuel production process and value chain.
Algae Renewable Energy Carbon Credit First Timer70CentsaGallon
The interest in algae farming also includes implementing Carbon Capture, Biofuel Production, Power Generation, and other industrial flue gasses for use in Photo bioreactors for algae cultivation.
This document discusses the potential of algae as a source of biofuel and other products. It begins by describing how algae were crucial for oxygenating the early Earth's atmosphere. Today, algae are being investigated for their potential to provide abundant fuel, food, and help sequester carbon. The document outlines the financial investments that have been made in algae technology companies and projects timelines for commercialization of algae fuels ranging from 2-3 years to over 10 years depending on the company. It also discusses using algae for nutraceuticals and describes some algae cultivation and photobioreactor technologies.
Flue gas mitigation technology that will aid in alleviating our emissions from point sources (i.e. power plants) by supplementing growth of ALGAE to produces our transportation sector fuels.
Global Energy Technology Group plans to acquire farms in California to develop renewable energy projects using jatropha biodiesel. The company will purchase land and develop jatropha plantations to produce oil for biodiesel production. Jatropha is a drought-resistant crop suitable for marginal lands that produces oil for biodiesel without competing with food crops. The company expects to benefit from government incentives for biodiesel production and carbon credits from the jatropha plantations.
Bio aviation refers to the use of sustainable biofuels instead of fossil fuels in the aviation industry. Second generation biofuels are produced from non-food crop sources like jatropha and camelina and can reduce lifecycle emissions by up to 84%. Several airlines have conducted test and commercial flights using biofuel blends of up to 50% with no required aircraft modifications. The aviation industry is working to develop and certify sustainable biofuels that meet performance and environmental standards for widespread commercial use.
The document discusses the concept of a bio-economy and services provided by a bio-economy consultancy. The consultancy offers four services to help clients realize their bio-economy goals: research, experimentation, process design/modeling, and project commissioning. Examples are given of leading bio-economy companies in areas like biofuels, biochemicals, and sustainable waste recovery.
Green Earth Technologies produces biodegradable motor oils, cleaning products, and other goods made from renewable resources like plant and animal oils. Their G-Brand products are patented and designed to be environmentally friendly alternatives to conventional petroleum-based goods. Green Earth aims to reduce foreign oil dependence and pollution through its sustainable and domestically-produced lines.
This document discusses various models for producing biodiesel from waste cooking oil on the West Coast of the United States. It outlines commercial, public, and legal models including a program in Santa Cruz that collects used fryer oil from restaurants to produce biodiesel, a program in San Francisco that collects brown and yellow grease to produce biodiesel, and a legal mandate in Portland requiring biodiesel blends and limiting feedstocks. The document also provides resources on biodiesel production, environmental regulations, and funding opportunities to support more sustainable biodiesel programs.
Pond Technologies was founded in Toronto, Canada on May 2007. Their mission is to use microalgae, the original superfood and the planet’s first carbon storage technology, to solve some of the largest problems facing the world today.
Algae-based biofuels company that provides equipment and services for algae production and processing. They aim to become the premier algae solutions provider in Florida through projects like utilizing farmland for algae-to-biodiesel production. Algae oil has potential as a sustainable feedstock due to its high yields per acre and ability to grow anywhere. The company explores using algae for wastewater treatment and CO2 sequestration in addition to biofuel production.
Recent talks on biofuels have outlined their un-sustainability in the production phase; commodities such as corn, rapeseed, palm oil and soya are being grown and harvested in a way that could have negative economic, social and environmental effects, and have a global impact on land use, food security, water resources, deforestation and global markets.
The document discusses biodiesel, including what it is, how it is made through transesterification, its properties and benefits compared to petroleum diesel. It also discusses biodiesel blends, production of biodiesel from algae, and potential applications and adoption of biodiesel in Pakistan.
This document discusses the potential for using algae as a biofuel source in Virginia. It notes that algae grows very quickly, requires less land than other biofuel crops, and has significant environmental benefits like cleaning water and absorbing carbon dioxide. While algae biofuels currently cost more than petroleum-based fuels, studies estimate that algae could potentially produce over 5,000 gallons of biodiesel per acre each year while only requiring 2-5% of agricultural land to fuel US transportation compared to over 600% for soybeans. The document outlines several algae research and pilot projects underway in Virginia to evaluate native algal species for oil production and optimize algae growth using wastewater in order to potentially produce biodie
This document defines fuel and discusses conventional and alternative fuels. It notes that fossil fuels will deplete within a few centuries unless alternatives are developed. Biodiesel is introduced as a renewable alternative produced through transesterification of vegetable oils. Algae are also discussed as a promising source for biodiesel, with several cultivation methods described, though commercialization challenges remain. The document concludes renewable fuels can help address energy and environmental issues if developed sustainably.
The document discusses aquatic biofuels as a new option for bioenergy production in the Mediterranean region. It describes how microalgae can be grown to produce biofuels, either through open pond systems or more expensive photo bioreactor systems. Microalgae have significant advantages over other biofuel feedstocks like soy or rapeseed, producing over 30 times more oil per hectare. The document also discusses using fish waste from aquaculture as a feedstock for biodiesel production and notes technologies for this in Vietnam and Honduras that could be transferred to the Mediterranean region. It acknowledges challenges in cost but sees potential benefits for income generation and carbon abatement through algal biofuel production.
Algiesel aims to produce biodiesel from algae by growing algae in wastewater, extracting the lipids from the algae biomass, and converting the lipids into biodiesel. The initial plan involves laboratory and testing phases to optimize techniques for growing high-lipid algae, concentrating the algal biomass, and extracting the lipids. While some algal strains showed potential, scaling up cultures faced challenges from unstable environmental parameters like temperature and salinity. Further research is needed to identify algal strains that can grow robustly while providing high lipid yields to make algal biodiesel economically feasible compared to other biodiesel sources like jatropha.
The document discusses Algaetech, a Malaysian company researching and developing microalgae production. It aims to establish a fully integrated algae cultivation operation in Malaysia and Southeast Asia. Algaetech operates an algae laboratory and production ponds. It is working to commercialize algae-based biofuels and high-value products like astaxanthin in Malaysia and establish the region's algae industry through research, technology development, and promoting regional collaboration.
Methanex is the world's largest producer and supplier of methanol. We create value through our leadership in the global production, marketing and delivery of methanol to customers. View our latest Investor Presentation for more details.
UnityNet World Environment Day Abraham Project 2024 Press ReleaseLHelferty
June 12, 2024 UnityNet International (#UNI) World Environment Day Abraham Project 2024 Press Release from Markham / Mississauga, Ontario in the, Greater Tkaronto Bioregion, Canada in the North American Great Lakes Watersheds of North America (Turtle Island).
World economy charts case study presented by a Big 4
World economy charts case study presented by a Big 4
World economy charts case
World economy charts case study presented by a Big 4
World economy charts case study presented by a Big 4World economy charts case study presented by a Big 4
World economy charts case study presented by a Big 4
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Cleades Robinson, a respected leader in Philadelphia's police force, is known for his diplomatic and tactful approach, fostering a strong community rapport.
ZKsync airdrop of 3.6 billion ZK tokens is scheduled by ZKsync for next week.pdfSOFTTECHHUB
The world of blockchain and decentralized technologies is about to witness a groundbreaking event. ZKsync, the pioneering Ethereum Layer 2 network, has announced the highly anticipated airdrop of its native token, ZK. This move marks a significant milestone in the protocol's journey, empowering the community to take the reins and shape the future of this revolutionary ecosystem.
2. ALGAE BIOENERGY SOLUTIONS, LLC “CAN YOU MAKE A PROFIT FROM SLIME” CHUCK PARDUE & THOMAS ANHORN ~PRESENTERS~ COPYIRGHT(ABS) 5/13/2010
3. ALGAE OIL When transportation fuels are compared side-by-side, algae oil-delivered fuels offer significant economic, ecological and safety advantages over petroleum products.Algae Bioenergy Solutions, LLC (ABS) will use state of the art photo bio-reactors/led air systems in an indoor natural climate controlled environmentto produce a high volume of oil each day.
4. (ABS) IS AN ALGAE DEVELOPMENT COMPANY ABS DETERMINES SITE AND ECONOMIC FEASIBILITY OF ALGAE PROCESSING THROUGH JOINT VENTURES WITH: ~ WASTE WATER TREATMENT PLANTS MUNICIPAL SITES ~ INDUSTRIAL SITES ~AGRICULTURAL OPERATIONS
5. ECONOMIC CONSIDERATIONS OF ALGAE DEVELOPMENT MOST ALGAE COMPANIES ARE FOCUSED ON TECHNOLOGY SPECIES SELECTION AND DEVELOPMENT PONDS VS PHOTO-BIOREACTORS HARVESTING EXTRACTION
6. FOCUS INSTEAD ON CAPITAL EXPENSE AND OPERATIONAL EXPENSES CAPITAL EXPENSE COSTS LAND, PERMITTING, ENGINEERING EQUIPMENT, INSTALLATION $120,000 TO $2,000,000 PER ACRE LABOR, UTILITIES, FEEDSTOCKS, SEED ALGAE, MAINTENANCE, ADMINISTRATIVE (MARKETING, INSURANCE, ETC.)
7. THERE’S GOT TO BE A MORE ECONOMICAL WAY TO MAKE ALGAE DINOSAURS DID IT ON THE CHEAP WHY NOT US?
8. OPERATIONS EXPENSE ONE TON OF ALGAE REQUIRES: ~ 1/3 TON OF NUTRIENTS, 1.8 TONS OF CO2 NUTRIENTS COST $200 - $400 A TON CO2 $20 - $30 A TON ~ SUNLIGHT OR ARTIFICIAL LIGHT, ELECTRICITY .08 - .11 CENTS A KILOWATT ~ TO MAKE A PROFIT YOU NEED FREE NUTRIENTS, CO2 AND LOW COST ELECTRICITY
9. WHERE TO FIND FREE OR LOW COST NUTRIENTS ~WASTE WATER TREATMENT PLANTS HAVE PLENTY OF NUTRIENTS (NITRATES, ETC) ~ PERHAPS 300 PPM AFTER THEY HAVE REMOVED THE “NASTY STUFF” ~ THEY WANT TO REDUCE NITRATES AND PHOSPHATES AFTER THEY CLEAN THE WATER BEFORE DISCHARGE BACK TO RIVERS & STREAMS ~ DIVERT ONE OF THEIR EFFLUENT STREAMS TO “YOUR” ALGAE PROCESSING PLANT
16. Ability to utilize Algae oil feedstock to make biodiesel
17. ABS will take nutrients from waste water treatment facilities such as this nearby treatment facility.
18. ADDITIONAL FREE NUTRIENT SOURCES ~ FARMS ~ CATTLE AND DAIRY FARMS ~ CHICKEN FARMS ~ CATFISH FARMS REFERENCE: DR. RON PUTT’S “HOW-TO MANUAL ON GROWING ALGAE ON FARMS” “ALGAE AS A BIODEISEL FEEDSTOCK”
19. PROFITS FROM SALES OF ALGAE PRODUCTS “HIGH VALUE PRODUCTS/SHORT TERM VS COMMODITY PRODUCTS LONG TERM” ~ ALGAE OILS (LIPIDS) ~ BIODIESEL FEEDSTOCK (THAT IS WHY ABS IS WORKING ON ALGAE DEVELOPMENT) ~ JET FUEL (EUROPEAN AIRLINE DEMAND 2012) ~ BOILER FUEL ~ VARIOUS EXPERIMENTAL FUELS ~ ALGAE DRY PRODUCT ~ ETHANOL ~ ANIMAL AND FISH FOOD ~ FERTILIZER ~ ALGAE FOR NUTRICEUTICALS, OMEGA-3, COSMETICS, HIGH VALUE; BUT WILL MARKET BE SATURATED?
20. TO MAKE A PROFIT IN ALGAE PRODUCTION TECHNOLOGY IS IMPORTANT ; BUT FINDING WAYS TO REDUCE CAPITAL COSTS BY JOINT VENTURES, DUAL USES OF EXISTING RESOURCES AND FINDING FREE SOURCES OF NUTRIENTS, CO2 AND LOW COST ENERGY IS EVEN MORE IMPORTANT!
21. OBJECTIVES Algae Bioenergy Solutions, LLC (ABS) is seeking Technology and Financial Partners to develop its processing facility located in Augusta Georgia and take full advantage of: A local available low cost source for nutrients, water, CO2 and labor. Immediate demand for Algae Oil at affiliated Biodiesel Plant. Local demand by Farmers for fertilizer and animal feed. Available to ABS are various tax credits and grants from IRS, DOE and USDA subject to DOE and IRS approval. The project may elect to take a 30% tax credit as a grant payable within 60 days of start of production.
23. Contact us today for technology or financial partnership opportunities. CORPORATE OFFICE 211-A Bobby Jones Expressway Martinez, GA 30709 706-823-2000 office 706-722-0149 fax Contact: Chuck Pardue President chuckpardue3@gmail.com OPERATIONS Algae Bioenergy Solutions, LLC 1660 Dixon Airline Road Augusta, GA 30906 Contact: Thomas Anhorn VP of Operations tanhorn3@pelerin.us 805-602-1088 (M)