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Abstract

Ventilation is very important during the biodrying process because it affects the biodrying efficiency and secondary pollution. In this study, three ventilation modes—intermittent negative ventilation (IN), continuous negative ventilation (CN) and intermittent positive ventilation (IP)—were used to provide the same amount of total air during biodrying of municipal solid waste (MSW). During the entire 16-day experiment, 68.4%, 68.7% and 67.2% of water contained in the initial waste was removed under IN, CN and IP trials respectively. The ratio of water loss to volatile solid loss was used to evaluate the biodrying efficiency, with values of 5.35, 5.93 and 4.82 being observed for IN, CN and IP trials respectively. The total organic carbon concentrations of the leachate generated from the biodrying of waste were as high as 25,000 mg/l, while those of the condensate were not higher than 3500 mg/l. During the entire process, the average ammonia concentrations of leachate and condensate were 1350 mg/l and 2140 mg/l respectively. From the aspect of biodrying efficiency, continuous negative ventilation was the most preferable ventilation mode for biodrying of MSW, while special care should be taken to prevent aqueous pollution if it is used in a MSW treatment plant.

Keywords

Municipal solid waste (MSW)biodrying efficiency aqueous phase pollution ventilation modes high moisture content water removal leachate

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References

Adani

Baido

Calcaterra

Genevini

(2002) The influence of biomass temperature on biostabilization – biodrying of municipal solid waste. Bioresource Technology 83: 173–179.

Chiumenti

Diaz

Savage

Eggerth

Goldstein

(2005) Modern Composting Technologies. Emmaus, PA: The J.G. Press, Inc. Emmaus.

Choi

Richard

Ahn

(2001) Composting high moisture materials: biodrying poultry manure in a sequentially fed reactor. Compost Science & Utilization 9: 303–311.

de Bertoldi

Vallini

Pera

(1983) The biology of composting: a review. Waste Management & Research 1: 157–176.

de Bertoldi

Sequi

Lemmes

Papi

(1996) The Science of Composting. London: Blackie Academic & Professional, pp. 9–59.

Ekinci

Keener

Elwell

Michel

(2004) Effects of aeration strategies on the composting process: Part I. Experimental studies. Transactions of the American Society of Agricultural Engineers 47: 1697–1708.

Haug

(1993) The Practical Handbook of Compost Engineering. Boca Raton, FL: CRC Press, Inc., pp. 261–286.

Tang

Yang

Fang

Shao

(2012) The emission patterns of volatile organic compounds during aerobic biotreatment of municipal solid waste using continuous and intermittent aeration. Journal of the Air & Waste Management Association 62: 461–470.

Jimenez

Garcia

(1991) Composting of domestic refuse and sewage sludge. I. Evolution of temperature, pH, C/N ratio and cation-exchange capacity. Resources, Conservation and Recycling 6: 45–60.

10.

Kuchenrither

Martin

Smith

Williams

(1985) Design and operation of an aerated windrow composting facility. Water Pollution Control Federation 57: 213–219.

11.

Miller

MacGregor

Psarianos

Cirello

Finstein

(1982) Direction of ventilation in composting wastewater sludge. Water Pollution Control Federation 54: 111–113.

12.

Pierucci

Porazzi

Martinez

Adani

Carati

Rubino

Colombi

. (2005) Volatile organic compounds produced during the aerobic biological processing of municipal solid waste in a pilot plant. Chemosphere 59: 423–430.

13.

Pos

(1991) Composting – Theoretical Applications, Municipal, and Commercial Composting Workshop. University of Guelph, Canada.

14.

Quazi

Albert

Tao

(2000) Kinetic analysis of forced aeration composting – I. Reaction rates and temperature. Waste Management & Research 18: 303–312.

15.

Rada

Franzinelli

Taiss

Ragazzi

Panaitescu

Apostol

(2007) Lower heating value dynamics during municipal solid waste bio-drying. Environmental Technology 28: 463–469.

16.

Scaglia

Orzi

Artola

Font

Davoli

Sanchez

Adani

(2011) Odours and volatile organic compounds emitted from municipal solid waste at different stage of decomposition and relationship with biological stability. Bioresource Technology 102: 4638–4645.

17.

Stentiford

Mara

Taylor

Leton

(1983) Forced aeration co-composting of domestic refuse and sewage sludge. In: Proceedings of the international conference on composting of solid wastes and slurries, Leeds, UK, 28–30 September, pp. 58–72. Leeds: University of Leeds.

18.

Sugni

Calcaterra

Adani

(2005) Biostabilization-biodrying of municipal solid waste by inverting air-flow. Bioresource Technology 96: 1331–1337.

19.

Sun

Zhang

Wang

Sun

(2010) Effects of different aeration pattern on co-composting of night soil and leaf. Journal of Anhui Agriculture Science 38: 16899–16902 [in Chinese].

20.

Zhang

Jin

Shao

(2008a) Bio-drying of municipal solid waste with high water content by aeration procedures regulation and inoculation. Bioresource Technology 99: 8796–8802.

21.

Zhang

Shao

Jin

Han

(2008b) Biodrying of municipal solid waste with high water content by combined hydrolytic-aerobic technology. Journal of Environmental Sciences-China 20: 1534–1540.

22.

Zhang

Shao

(2009) Effect of inoculation time on the bio-drying performance of combined hydrolytic-aerobic process. Bioresource Technology 100: 1087–1093.

23.

Velis

Longhurst

Drew

Smith

Pollard

SJT

(2009) Biodrying for mechanical–biological treatment of wastes: A review of process science and engineering. Bioresource Technology 100: 2747–2761.

Biodrying of municipal solid waste under different ventilation modes: drying efficiency and aqueous pollution

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