Quantification of greenhouse gas emissions from a biological waste treatment facility
Highlights: • Whole-site fugitive emissions were measured at a biowaste treatment facility. • Methane and nitrous oxide were quantified using a tracer gas dispersion technique. •The daily average whole-site methane emission was 25.6 kg CH{sub 4} h{sup −1}. • Whole-site fugitive emissions were up to eight times higher than on-site emissions. • The emissions had a significant influence on the overall environmental impact - Abstract: Whole-site emissions of methane and nitrous oxide, from a combined dry anaerobic digestion and composting facility treating biowaste, were quantified using a tracer dispersion technique that combines a controlled tracer gas release from the treatment facility with time-resolved concentration measurements downwind of the facility. Emission measurements were conducted over a period of three days, and in total, 80 plume traverses were obtained. On-site screening showed that important processes resulting in methane emissions were aerobic composting reactors, anaerobic digester reactors, composting windrows and the site’s biofilter. Average whole-site methane emissions measured during the three days were 27.5 ± 7.4, 28.5 ± 6.1 and 30.1 ± 11.4 kg CH{sub 4} h{sup −1}, respectively. Turning the windrows resulted in an increase in methane emission from about 26.3–35.9 kg CH{sub 4} h{sup −1}. Lower emissions (21.5 kg CH{sub 4} h{sup −1}) were measured after work hours ended, in comparison to emissions measured during the facility’s opening hours (30.2 kg CH{sub 4} h{sup −1}). Nitrous oxide emission was too small for a downwind quantification. Direct on-site measurements, however, suggested that the main part of the emitted nitrous oxide came from the biofilter (about 1.4 kg N{sub 2}O h{sup −1}). Whole-site emissions were compared to emissions previously measured at different point sources on-site. Whole-site fugitive emissions were three to eight times higher than the sum of emissions measured at on-site sources. The magnitude of the emissions had a significant influence on the overall environmental impact of the treatment facility, assessed by consequential life cycle assessment. Including the higher whole-site fugitive emissions led to an increase in global warming potential, from a saving of 97 kg CO{sub 2}-eq. tonne{sup −1} of treated waste (wet weight) to a loading of 71 kg CO{sub 2}-eq. tonne{sup −1}, ultimately flipping the environmental profile of the treatment facility.
- OSTI ID:
- 22742127
- Journal Information:
- Waste Management, Vol. 67; Other Information: Copyright (c) 2017 Elsevier Science B.V., Amsterdam, The Netherlands, All rights reserved.; Country of input: International Atomic Energy Agency (IAEA); ISSN 0956-053X
- Country of Publication:
- United States
- Language:
- English
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