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Learn how to turn organic waste into beneficial compost for soil health and environmental sustainability. Explore composting essentials, nutrient balance, moisture content, particle size, pH balance, and more. Discover the process, key factors, and technologies for effective waste management.
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Managing Organic Wastes By Composting and Vermicomposting DENR Environmental Education Workshop November 16, 1999 Presenter: Craig Coker, Division of Pollution Prevention & Environmental Assistance
Principles of Composting • What Is Compost? • The product resulting from the controlled biological decomposition of organic materials • Sanitized through the generation of heat • Stabilized to the point where it is beneficial to plant growth • Provides humus, nutrients, and trace elements to soils • Organic Materials • Landfilled wastes (food, wood, textiles, sludges, etc.) • Agricultural wastes (plant or animal) • Industrial manufacturing byproducts • Yard trimmings • Seafood processing wastes • In short, anything that can be biodegraded
Why Compost? • > 75% of solid waste in NC is organic • 12% of landfilled solid waste in NC in 1998 was food wastes/discards • Agricultural wastes potential for nutrient pollution • Yard wastes – banned from landfills in 1993 • Compost benefits to soil – 25 lbs N, 13 lbs P (as P2O5), and 7 lbs K (as K2O) per ton of compost • Environmental sustainability
The Composting Process • Biological decomposition in aerobic environment • Decomposition & mineralization by microbes • Bacteria, actinomycetes, fungi, protozoans, nematodes • Food source – Nitrogen (biodegradable organic matter) • Energy source – Carbon (bulking agent) • Outputs • Heat • Water Vapor • Carbon Dioxide • Nutrients and minerals (compost) • Process occurs naturally, but can be accelerated by controlling essential elements
Composting Essential Elements • Nutrients • Carbon/Nitrogen (C/N) – 20:1 to 35:1 • Carbon/Phosphorus (C/P) – 100:1 to 150:1 • Moisture Content – 50% to 60% (wet basis) • Particle Size – ¼” to ¾” optimum • Porosity – 35% to 50% • pH – 6.5 to 8.0 • Oxygen concentration - >5% • Temperature – 130o F. to 150o F. • Time – one to four months
Nutrient Balance in Composting • C/N ratio – target is 30:1 • > 30:1 – not enough food for microbial population • < 30:1 – nitrogen lost as ammonia (odors) • Sources of N & P - Organic wastes, manures, sludges, etc. • Sources of C – wood wastes, woodchips, sawdust • Example C/N Ratios: • Food waste 14 – 16 : 1 • Refuse/trash 34 –80 : 1 • Sewage sludge 5 –16 : 1 • Corrugated cardboard 563 : 1 • Telephone books 772 : 1 • Mixing components needed to optimize C/N ratio
Moisture Content • Source of nutrients for microbial protein synthesis and growth • Optimum water content – 50% to 60% (wet weight basis) • < 50% - composting slows due to microbial dessication • >60% - compaction, development of anaerobic conditions, putrefaction/fermentation (odors) • Water may be needed during mixing, composting • Yard wastes – 40 to 60 gallons per cubic yard • Typical moisture contents • Food wastes 70% • Manures and sludges 72% - 84% • Sawdust 19% - 65% • Corrugated cardboard 8% • Newsprint 3% - 8%
Particle Size & Distribution • Critical for balancing: • Surface area for growth of microbes (biofilm) • Adequate porosity for aeration (35% - 50%) • Larger particles (> 1”) • Lower surface area to mass ratio • Particle interior doesn’t compost – lack of oxygen • Smaller particles (< 1/8”) • Tend to pack and compact • Inhibit air flow through pile • Optimum size very material specific
pH • Optimum range 6.5 – 8.0 • Bacterial activity dominates • Below pH = 6.5 • Fungi dominate over bacteria • Composting can be inhibited • Avoid by keeping O2 > 5% • Above pH – 8.0 • Ammonia gas can be generated • Microbial populations decline
Porosity and Aeration • Optimum porosity 35% - 50% • > 50% - energy lost is greater than heat produced lower temperatures in compost pile • < 35% - anaerobic conditions (odors) • Aeration – controls temperatures, removes moisture and CO2 and provides oxygen • Airflow needs directly proportional to biological activity • O2 concentration < 5% - anaerobic conditions
Time and Temperature • Temperature is key process control factor – monitor closely • Optimum temperatures: 130o F. – 150o F. • Temperatures above 131o F. (55o C.) will kill pathogens, fecal coliform & parasites • NC Regulations (BYC, small yard waste and on-farm exempt) • Temperatures > 131o F. for 15 days in windrows • Temperatures > 131o F. for 3 days in ASP or invessel • Optimum temps achieved by regulating airflow (turning) and/or pile size
Backyard Composting • Potential diversion – 400 – 800 lbs/year/household • Suitable materials • Yard trimmings (leaves, grass, shrubs) • Food wastes (produce, coffee grounds, eggshells) • Newspaper • Unsuitable materials • Pet wastes • Animal remains (meat, fish, bones, grease, whole eggs, dairy products) • Charcoal ashes • Invasive weeds and plants (kudzu, ivy, Bermudagrass)
Backyard Composting – Easy To Do! • Locate in flat area, shielded from sun & wind • Add materials in layers (browns/greens) • Turn pile after 1st week, then 2-3 times over next two months
Backyard Composting, cont. • Can add fresh wastes when turning, but better to start new pile • Compost will be ready to use in • 4 – 6 months for piles started in Spring • 6 – 8 months for piles started in Fall • Troubleshooting – see Handout
Vermicomposting Home Wastes • Vermicompost = worm castings + bedding • Nutrient Value - 6600 ppm organic nitrogen, 1300 ppm phosphorus & 1,000 ppm potassium • What to feed worms – • Vegetable scraps, breads and grains • Fruit rinds and peels • Tea bags, coffee grounds, coffee filters, etc. • What not to feed worms – • Meat, fish, cheese or butter • Greasy, oily foods • Animal wastes
Vermicomposting – How To Do It • Bin – wooden, plastic or metal with tight-fitting lid • 2’ x 3’ x 1’ – good for 2-3 person household • Need drainage holes in bottom and air vents on top and sides
Vermicomposting – How to do it • Add moist drained bedding to worm bin • 1” – 2” strips of newspaper/cardboard/leaves/peat moss/sawdust • Fill bin with bedding • Start with 2 lbs of redworms/lb daily scraps • Eisenia foetida or Lumbricus rubellus • Bury food scraps under 4 – 6” bedding • Rotate burial around bin to prevent overloading • Harvest vermicompost in 3 – 6 months
Institutional Composting • University dining halls • Industrial/government cafeterias • Current programs in North Carolina • UNC – Asheville (Earth Tub) • UNC – Charlotte (Earth Tub – next year) • NIEHS (Worm Wigwam) • DENR/Archdale Cafeteria • Sampson Correctional Institution (Worm Wigwam) • Brown Creek Correctional (Rotary Drum Composter) • Several small schoolroom vermicomposting systems
Institutional Composting Worm Wigwam (small) Worm Wigwam (large)
Institutional Composting Rotary Drum Earth Tub
Institutional Composting • Key is efficient source separation of organics • Separate collection containers from regular trash • Training needed to minimize contaminants (non-compostables like plastics, foils, metals)
Commercial Composting • Larger-scale commercial and municipal facilities • Feedstocks: manures, agricultural wastes (I.e. cotton gin trash), industrial and municipal wastewater treatment sludges, food wastes • Technologies used: • Windrows • Aerated Compost Bins • Aerated Static Pile • In-Vessel Systems • Produced compost sold for $18 - $20/yd3
Overview • Technology in Composting • Materials Handling • Biological Process Optimization • Odor Control • Capital Cost • Increases with technology • Operational Costs • Decrease with technology • Footprint (Area Required) • Decreases with technology (usually)
Windrow Composting • Materials mixed and formed into windrows • Windrows 7’ –8’ wide, 5’ – 6’ tall, varying lengths • Compost turned and mixed periodically • Aeration by natural/passive air movement • Composting time : 3 – 6 months
Windrow Composting, cont. • Equipment Needed • Grinder/Shredder • Tractor/FEL • Windrow Turner • tractor-pulled • self-propelled • Screener • One Acre Can Handle 4,000 - 7,000 CY Compost Mix
Aerated Compost Bins • Aeration through porous floor plates • Composting time : 2 - 3 weeks • Curing time : 2 months • Durable materials of construction • Equipment needed : front end loader • Vector/vermin control needed with food wastes • Capacities : 3 - 4 days food waste + bulking agent per bin
Aerated Static Pile Composting • Mixed materials built on bed with aeration pipes embedded • Aeration by mechanical blowers • Composting for 21 days, followed by curing for 30 days • Often used in biosolids (sludge) composting
Aerated Static Pile • Better suited to larger volumes (landscape debris, sludges) • Shorter processing time than with windrows • May not be suited to wastes that need mixing during composting, like food wastes • Difficult to adjust moisture content during composting if needed • Odor control difficult with positive aeration • Less land area than windrows, still labor intensive
In-Vessel Composting • More mechanically complex • More expensive • Smaller footprint (area) • Relatively high operations & maintenance costs
Commercial Composting in NC • Brooks Contractors, Goldston, NC • Windrow composting – eggshells, food waste, yard wastes, cardboard • McGill Environmental, Rose Hill, NC • Aerated static pile – biosolids, industrial food processing residues, furniture wastes • Progressive Soil Farms, Welcome, NC • Windrow composting – textile wastes, yard wastes • City of Hickory, NC • In-vessel composting – biosolids, sawdust • Mountain Organic Materials, Asheville, NC • Aerated compost bins – manures and sawmill wastes • Others: Lenoir, Morganton, Shelby
Compost Benefits • Physical Benefits • Improved soil structure, reduced density, increased permeability (less erosion potential) • Resists compaction, increased water holding capacity • Chemical Benefits • Modifies and stabilizes pH • Increases cation exchange capacity (enables soils to retain nutrients longer, reduces nutrient leaching) • Biological Benefits • Provides soil biota – healthier soils • Suppresses plant diseases
More Compost Benefits • Binds heavy metals and other contaminants, reducing leachability and bioabsorption • Degrades petroleum contaminants in soils • Enhances wetlands restoration by simulating the characteristics of wetland soils • Coarser composts used as mulch provide erosion control • Can provide filtration and contaminant removal of stormwater pollutants • Biofiltration of VOC’s in exhaust gases
Compost Utilization Examples • Planting Bed Establishment • Apply 3 – 6 yd3 per 1000 sq. feet • Rototill to depth of 6 – 8” • Mulch and water after plants installed • Turfgrass Establishment • Apply 2” – 3” layer of compost to soil • Rototill 6 – 8” deep • Rake smooth, lay sod or spread seed • Apply starter fertilizer and/or water as needed • Compost Used For Bedding Mulch • 2” – 3” layer installed before mulching with pine bark or hardwood bark mulch
Summary • Composting is an effective way to manage organic wastes • Composting promotes environmental sustainability by converting a waste to a value-added product that improves our environment • Composting can be done at home, at school or at work, and by commercial and municipal entities • Composting is a mix of the art of the gardener, the science of horticulture, and the discipline of waste engineering…COMPOST HAPPENS!