I would like to thank you for the wonderful opportunity. I would also like to thank everyone who attended and gave their encouraging and insightful inputs. It was a rewarding experience to present and get positive feedback. 

Peter and I, would love to keep working and participating in this process since we are here on campus for another two years. It would be really nice if you would involve us. Excited about that!

Also, I am attaching the PowerPoint presentation for reference and further use. 

Thanks once again, and I hope everyone stays safe and healthy. 

Warm regards,

Prajakta Gharpure

Grind2Energy: Turning Campus Food Waste into Fuel

The 49,000 students educated at the University of Illinois can generate a lot of food waste. Most of it winds up in a landfill. But for students with a dining hall plan, food waste is ultimately turned into energy, helping the campus reduce its carbon footprint.

With the "Grind2Energy" system, food scraps are ground down and ultimately run through an anaerobic digester at the Urbana-Champaign Sanitary District, producing methane that is used for fuel to power the plant. The system was installed at Florida Avenue Residence Halls last fall, and others are in the works.

"Hopefully this small piece will be part of a bigger system down the road," said Thurman Etchison, Assistant Director of Housing Dining Services for Equipment and Facilities.

SOLAR FARM LANDSCAPE BUFFER
F&S representatives shared detailed designs for the pollinator supportive landscape buffer along the future Solar Farm 2.0 site to the Village of Savoy. Village leaders were pleased with the design plans and thanked us for being responsive to their neighborly request. When completed, this site will serve as a demonstration for pollinator-friendly solar arrays, following the requirements of the Pollinator Friendly Solar Site Act (Illinois Pub. Act 100-1022). Solar Farm 2.0 will produce approximately 20,000 megawatt-hours (MWh) annually, and will generate the equivalent electricity use of more than 2,000 average American homes.

In order to reach the iCAP objective of 25,000 MWh/year of solar energy by FY25, additional panels will need to be installed.  Large scale, ground mounted panels appear to be the least expensive route towards achieving the FY25 objective.

Good morning Morgan,

I have gathered the numbers that correspond to an acre of solar cover. 

The estimate is that an acre of solar canopy could generate 760,536 kWh annually (this estimate takes into account the weather patterns of our location and possible shading/system inefficiencies).  

I remember you saying that right now the University pays $0.05 per kWh.  Our solar farms are charged $0.045 per kWh that they generate.  This means that $0.005 is saved for every kWh generated.  That can be used to estimate that an acre of solar canopy would save roughly $3,800 per year.  

I thought that I would also include the National Renewable Energy Laboratory’s estimate for what a solar retailer would charge per kWh of electricity in our area: $0.036.  This would mean that $0.014 could be saved per kWh on a solar canopy system, or roughly $10,650 per acre.  

Let me know what else I can find,

Ryan Day