1 / 59

Solid Waste Management

Solid Waste Management. Neil Hutzler Fall 2008. Sources of Solid Wastes in the United States. Mining wastes (3 billion tons per year) Agricultural wastes (500 million tons/yr) Industrial wastes (400 million tons/yr) Municipal solid waste (210 million tons/yr) About 4.5 lb/person/day

shanta
Télécharger la présentation

Solid Waste Management

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. Solid Waste Management Neil Hutzler Fall 2008

  2. Sources of Solid Wastesin the United States • Mining wastes (3 billion tons per year) • Agricultural wastes (500 million tons/yr) • Industrial wastes (400 million tons/yr) • Municipal solid waste (210 million tons/yr) • About 4.5 lb/person/day • Sewage sludge (40 million tons/yr)

  3. Source: USEPA

  4. Source of Solid Wastes • Mining waste consist mainly of rock and soil overburden from mining operations – an earth moving project • Agricultural wastes are typically organic residuals – biodegradable and recyclable • Industrial wastes are widely varied – have the potential of being hazardous • Municipal solid wastes (MSW) vary greatly in quantity and composition • We will focus on the management of MSW

  5. Composition of Solid Wastes • Garbage (food rejects, organic wastes) • Rubbish (nonputresible wastes) • Combustables (paper,plastic, wood, etc.) • Noncombustables (metal, glass, dirt, etc.) • Yard wastes • Other materials (almost anything can be found in MSW) • Water (about 15 to 20% of MSW is water)

  6. Composition of MSW Source: USEPA

  7. Other Solid Waste • Discarded appliances, furniture, cars, etc. • Street sweepings and liter • Construction and demolition debris • Dead animals • Hazardous wastes from homes and industry • Sludge from water and wastewater treatment plants. • Conclusion: the solid waste management engineer must be prepared to deal with a wide variety of materials

  8. Municipal Solid Waste Management System • On-site Storage • Collection • Transport and transfer • Processing • Disposal

  9. Storage • Responsibility of the generator of solid waste • Cans • Bags (sale can support cost of collection) • Bins or dumpsters • Compactors • Waste separation of recyclables

  10. MSW Collection • Type of collection service • Self • Curbside pickup (most common) • Set out, set back • Backyard (most expensive) • Frequency of collection • Daily (large generators) • Once per week (most common in northern states) • Twice per week (most common in southern states) • On demand (discards, special wastes) • Less frequent for recyclables • Crew size (1 to 3 for curbside pick up, more for others)

  11. Types of Collection Vehicles • Packer trucks (to increase density of MSW and mass of collection, compacted density ~900 lb/yd3) • Rear loading • Side loading • Front loading • Manual loading • Mechanical loading • Chassis specified by volume (e.g., 20 yd3) • Roll-off trucks (container left at site) • Truck for collection of recyclables

  12. Source: USEPA

  13. Source: USEPA

  14. Recycling

  15. MSW Collection • Collection Route Design • Macro routing • Districting • Micro routing

  16. Source: City of Sacramento, CA

  17. Truck Routing • Daily route method • A daily route is collected, workers work until entire route is collected • Large route method • A weekly route is established, up to workers to determine route • Single load method • Collect until truck is full • Definite working day method • Work 8 hour and then quit

  18. Routing Heuristics -- examples • Do not fragment routes, keep in same area • Collection time plus haul time should be about equal for each route • Start collecting as close to the municipal garage as possible to cut down travel time • Do not collect heavily traveled streets during rush hours • Start routes at higher elevations • Make right turns as much as possible

  19. Solid Waste- Truck Routing

  20. Example - Routing Start

  21. Example - Routing Start

  22. Example - Routing Start

  23. Example - Routing Start

  24. Transfer • In cases where the processing and disposal sites are near the collection area, the collection vehicle also hauls the full load to the site. Need to balance size to minimize number of hauls versus maneuverability needed for collection • As distances increase the solid waste engineer should consider transferring the waste to a larger vehicle (e.g., semi trailer, rail car, barge)

  25. Transfer

  26. Transfer

  27. Transfer

  28. Solid Waste Processing • Objectives of Processing include • Volume reduction (baling, shredding, incineration (also reduces mass) • Size reduction (shredding, grinding) • Component separation (hand sorting, screening, magnetic separation, air classification) • Resource recovery (composting, energy recovery, materials recovery)

  29. Baling

  30. Baling

  31. Baling

  32. Solid Waste Disposal • No matter what processing is done, there will be some residue that needs to be disposed of safely • Options for disposal • Modern, engineered landfill • Modern, engineered landfill • Modern, engineered landfill

  33. Solid Waste - Sanitary Landfill Is defined as a land disposal site employing an engineered method of disposing of solid wastes on land in a manner that minimizes environmental hazards by spreading the solid wastes to the smallest practical volume, and applying and compacting cover material at the end of each day.

  34. Solid Waste - Sanitary Landfill Site Considerations: Public Opinion Proximity of major roadways Speed Limits Load limits on roadways Bridge capacities Underpass limitations Traffic patterns and congestion Haul distance (time) Detours Hydrology

  35. Solid Waste - Sanitary Landfill Site Considerations: Availability of cover material Climate (e.g. floods, mud slides, snow) Zoning requirements Buffer areas around the site (e.g. high trees on site perimeter) Historic buildings, endangered species, wetlands, and similar environmental factors.

  36. Solid Waste - Sanitary Landfill Federal Regulations for Landfills: Subtitle D of the Resource Conservation and Recovery Act (RCRA), EPA promulgated new federal regulations for landfills. Among these regulations are restrictions on distances from airports, flood plains, and fault areas, as well as limitations on construction in wetlands and others such as: 30 meters from stream, 160 m from drinking water wells, 65 m from houses, schools and parks, 3,000 m from air port runways, requires synthetic liner.

  37. Solid Waste - Sanitary Landfill

  38. Solid Waste - Sanitary Landfill

  39. Solid Waste - Sanitary Landfill Methods of Operation: Area Method: solid waste is deposited on the surface, compacted, then covered with a layer of compacted soil at the end of a working day. This method is seldom restricted by topography: flat or rolling terrain, canyons, and other types of depressions are all acceptable.

  40. Sanitary Landfill - Area Method

  41. Sanitary Landfill - Area Method

  42. Solid Waste - Sanitary Landfill Methods of Operation: Trench Method: a trench is excavated and the solid waste is placed in it and compacted; and the soil that was taken from the trench is then laid on the waste and compacted. This method is used on level or gently sloping land where the water table is low. The advantage of this method is that the the soil taken from the trench can readily be used as cover.

  43. Sanitary Landfill - Trench Method

  44. Balefill

  45. Balefill

  46. Solid Waste Processing

  47. Incineration

More Related