1 / 24

Small-Scale Solar-Biopower Generation For Rural Central America

Small-Scale Solar-Biopower Generation For Rural Central America. Project support from: US Department of State, Western Hemisphere Affairs Energy & Climate Partnership of the Americas (ECPA) Dana Kirk, Ph.D., P.E. Michigan State University Biosystems and Agricultural Engineering

makara
Télécharger la présentation

Small-Scale Solar-Biopower Generation For Rural Central America

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Small-Scale Solar-Biopower Generation For Rural Central America Project support from: US Department of State, Western Hemisphere Affairs Energy & Climate Partnership of the Americas (ECPA) Dana Kirk, Ph.D., P.E. Michigan State University Biosystems and Agricultural Engineering kirkdana@anr.msu.edu

  2. Project Partners

  3. Core Project Team • PI – Ajit Srivastava, MSU BAE • Co PI – Wei Liao, MSU BAE • Co PI – Dawn Reinhold, MSU BAE • Educational coordinator – Luke Reese, MSU BAE • Project manager – Dana Kirk, MSU BAE • Francisco Aguilar – UCR AE • Daniel Baudrit – UCR AE • Alberto Miranda – UCR AE • Lorena Lorio – UCR Micro • Lidieth Uribe – UCR Micro

  4. Project Objectives • Optimize local thermophilic anaerobic microbial consortia • Implement a solar-biopower generation system • Evaluate the technical and economic performance • Establish an outreach program in Central America

  5. Facts of solar energy Central America • Advantages • Theoretical: 1.76 x 105 TW striking Earth, Practical: 600 TW • It is the cleanest energy source on the Earth. • Solar energy reaching the earth is abundant. • Disadvantages • Sun does not shine consistently. • Solar energy is a diffuse source. • It is difficult to collect, covert, and store solar energy. From: http://www.global-greenhouse-warming.com/solar.html

  6. Facts of Biogas Energy from Wastes • Advantages • A biological process • Reducing greenhouse gas emission • Enhancing nutrient management • Disadvantages • Low efficiency of organic matter degradation • Difficulty of power generation for small-medium operations Completely Stirred Tank Reactor (CSTR) Anaerobic Sequence Batch Reactor (ASBR) Plug-flow digester

  7. Agricultural residues available in Costa Rica • More than 600 MW electricity per year could be potentially generated from this amount of waste streams through anaerobic digestion technology.

  8. Solar-biopower concept Integrating wastes utilization with solar and biological technologies will create a novel self-sustainable clean energy generations system for small-medium scale operations Solar Energy Bioenergy Animal Manure Fertilizers Anaerobic Digestion Post- treatment Other Organic Wastes Reduced GHG Clean Water

  9. Solar-biopower concept Benefits of system integration • Overcome the disadvantages of individual technologies • Unsteady energy flow for solar power generation • Low efficiency of mesophilic anaerobic digestion on degradation of organic matter • Higher energy requirement of thermophilic aerobic digestion • Provide sufficient and stable energy for small-medium sized rural community • Solar energy utilization • Improved efficiency of anaerobic digestion on degradation of organic matter • Biogas energy as chemical storage – steady energy flow

  10. Mass balance Predicted mass balance for the integrated solar-bio system on 1,000 kg of mixed sludge and food wastes • Generating 66 kWh electricity per day • Producing 5 gasoline gallon equivalent (GGE) renewable fuel per day • The calculation of mass balance was based on the expected results that will be achieved by this project. • A kg COD destroyed produces 350 L methane gas.

  11. Solar-biopower system Power unit Solar unit Bioreactor Post-treatment

  12. Construction site Solar Bio-Reactor Site Fabio Baudrit Experiment Station

  13. Major system components • 16 – 2 m2flat-plate solar collector with support • 22 m3 anaerobic digester • 50 m3 gas bag • 2 – 10 kW electric generators • 4 – 144 m2wetland/sand filter cells Solar Bio-Reactor Sand Filter / Wetland

  14. Solar thermal system Solar collectors, hot water tank (white), & hot water storage (green)

  15. Anaerobic digester Poly tank anaerobic digester Official ribbon (digester in background clad in tin) Field engineering

  16. Feedstock & digestate handling Digestate solid-liquid separator Feedstock grinder, auger & mix tank (pump not shown)

  17. Biogas storage Gas bag, foam interceptor, & scrubber Full gas bag, May 2, 2013 Biogas sampling

  18. Sand filter & wetlands Sandfilter 1 Vertical wetland (sand filter 2) Surface wetland 2 Surface wetland 1

  19. Solar-biopower system performance • Feedstock: • Beef manure (950+ kg/d) • Food waste • Chicken litter (20 kg/d) • Temperature: • Currently 45oC±2oC • Target 50oC±1oC • Biogas production: ≈20 m3/d • Biogas quality: 60+% CH4 • Volatile solids destruction: 39% to 44%

  20. Water reclamation Organic waste Anaerobic digester Sand filter No. 1 Sand filter No. 2 Reclaimed water Original waste stream The effluent from solar-bioreactor The water from the 1st cell of post-treatment The water from the 2nd cell of post-treatment May 2013

  21. Outcomes to date • Pilot system • Biogas production at 70% of goal • Biogas quality and solids destruction have achieved goals • Install biogas flow meter • Connect electrical generators to the experiment station power • Begin sand filter/wetland research • Bioenergy support lab at UCR – capable of carrying out BMP’s and other analysis • Utilization of local manufacturing – coffee equipment & solar panels • Study abroad “Ecological Engineering in the Tropics” completed in December of 2012

  22. Next steps • Finalize microbial consortia papers • Continue to operate pilot system until Sept. 2014 • Operate portable unit at second location – wastewater or food processor • Complete economic and policy evaluation • 2013 study abroad planned for December • Expand bioenergy capabilities to address commercial needs

  23. Other announcements • August 13, 2013 – MSU Waste to Resource Field Day • Highlights: • South Campus Anaerobic Digester (500 kW from 130 cows) • Research digester, compost facility, student organic farm, recycling center, power plant, ADREC • For more information go to :http://events.anr.msu.edu/adrec/ • October 15 to 17 – Anaerobic Digester Operator Training (East Lansing, MI) • Highlights • System commissioning • Maintaining biological health • Safety • Operational troubleshooting • For information contact kirkdana@anr.msu.edu

  24. Questions? Dana M Kirk, Ph.D., P.E. Biosystems and Agricultural Engineering Anaerobic Digestion Research and Education Center E: kirkdana@anr.msu.edu P: 517.432.6530

More Related