Abstract: The presence of high levels of heavy metals in anaerobic fermentation residues is a major obstacle to the resource utilization and urgent research for removal of heavy metals in the biogas slurry is needed. The handling of large-scale residue slurry and safely returning to field urgently needed constructive suggestion. The contents of heavy metal elements in the residue of anaerobic digestion processes of the wastewater and waste of the piggery were mainly investigated. The contents of heavy metals in the original fluid and the centrifugal solution were determined in this study. They included elements, such as Cu, Zn, Cr, Cd, Pb, As, Ni, Mn, and Se, which were compared with the existing standard including the irrigation water quality standards (GB5084-2005), comprehensive discharge standard of sewage (GB8978-1996) and water-solubility humic acid fertilizer quality standards (NY1106-2010). The preliminary data suggested that both the heavy metals before and after centrifugation were in excess of the standards to some degree and the exceeding standard rate declined ignificantly after centrifugation. The absolute contents of heavy metals after centrifugation declined significantly compared with that before centrifugation. Those ratios are 91.8%, 73.2%, 47.6%, 94.5%, 93.5%, 59.4%, 95.8%, 100% for Zn, As, Cd, Cr, Cu, Ni, Mn,Pb, respectively. A descriptive statistics as well as a correlational analysis showed that there existed strong correlation among Cu, Pb, and the total suspended solids (TS). Meanwhile, significant correlation was found among TS, Cd, Zn, As, Cr, Ni, and Mn at 0.01 level. The data and the analysis above provided the theoretical and experimental support for the removal of heavy mental mainly characterized by the removal of TS. According to the comparison between contents of heavy mental conversed from large amount nutrients and corresponding standard (NY1110-2006), only as was found beyond standard. It was feasible
to apply biogas residues after centrifugation as water-solubility fertilizer due to the fact that As had low accumulation efficiency in soil and plants.
Keywords: fluid biogas residue, heavy metals, distribution, correlation, fertilization
DOI: 10.3965/j.ijabe.20130604.005
Citation: Ma J Q, Zhu H G, Fan M. Distribution of heavy metals in pig farm biogas residues and the safety and feasibility assessment of biogas fertilizer. Int J Agric & Biol Eng, 2013; 6(4): 35－43.

fluid biogas residue, heavy metals, distribution, correlation, fertilization

Jin H M, Chang Z Z, Ye X M, Ma Y, Zhu J. Physical and chemical characteristics of anaerobically digested slurry from large-scale biogas project in Jiangsu province. Transactions of the Chinese Society of Agricultural Engineering, 2011; 27(1): 291-296. (in Chinese with English abstract)

Li Y Q, Yang L J, Zhang N H. Safety and content analysis of biogas residues heavy metal from pig farm. Agro-Environment and Development, 2012; (3): 106-108. (in Chinese with English abstract)

Fuentes A, Lloréns M, Sáez J, Soler A, Aguilar M I, Ortuño J F, et al. Simple and sequential extractions of heavy metals from different sewage sludges. Chemosphere, 2004; 54(8): 1039-1047.

Fuentes A, Lloréns M, Sáez J, Isabel Aguilar M, Ortuño J F, Meseguer V F. Comparative study of six different sludges by sequential speciation of heavy metals. Bioresource Technology, 2008; 99(3): 517-525.

He Q, Mhamadi T A, Ji F Y, Yu D N, Zhou G M, Li S.

Simultaneous determination of heavy metals in waste and biogas slurry of scale farm by microwave digestion/ inductively coupled plasma-mass spectrometry. Spectroscopy and Spectral Analysis, 2012; 32(12): 3399-3401. (in Chinese with English abstract)

Dąbrowska L, Rosińska A. Change of PCBs and forms of heavy metals in sewage sludge during thermophilic anaerobic digestion. Chemosphere, 2012; 88(2): 168-173.

Zhang X W. Effect of biogas slurry irrigation on plants, water and soil water environment. Southwest University, 2012. (in Chinese with English abstract

Liu Y P, Zhang J F, Zou D X, Yuan H R, Li X J. Security risk analysis on the nutrients and heavy metals of biogas slurry in agricultural application. Agricultural Science & Technology, 2012; 13(5): 1067-1072.

Ni L, Sun G H, Luo G E, Shi W Y, Lu H, Ye W Z. Effect of marsh gas sewage irrigation on soil quality. Soils, 2008; 40(4): 608-611.(in Chinese with English abstract)

Li Y Z, Li G X, Diao J X, Zhu J B, Sun Y. The optimization of straw xanthates' synthesis condition and the application in elimination of heavy metal ions from biogas slurry. Journal of Agro-Environment Science, 2012; 31(9): 1848-1853. (in Chinese with English abstract)

Xu Y Z, Ma C, Cheng Y X, Wang Q Q, Zhong Z Y. Removal of heavy metals from sludge by bio-leaching. Journal of Southwest Jiaotong University, 2012; 47(1): 169-174. (in Chinese with English abstract)

Gao Z X, Wu Y H, Zhao J H, Mou Q S, Zhou G M, Luo Y W, et al. Determination of heavy metal elements in biogas slurry with inductively coupled plasma mass spectrometry (ICP-MS). Journal of Southwest University (Natural Science Edition), 2013; 35(1): 104-108. (in Chinese with English abstract)

Ministry of agriculture, environmental protection institute. Irrigation water quality standards. (in Chinese with English abstract)

Beijing environmental protection science research institute. Wastewater discharge standards. (in Chinese with English abstract)

Beijing national quality supervision and inspection center of fertilizer containing humic acid soluble fertilizers. The industry standard -Agriculture. (in Chinese with English abstract)

Beijing national fertilizer quality supervision and inspection center, Beijing new fertilizer quality supervision and inspection station, Chengdu, Ministry of agriculture fertilizer quality supervision and inspection center soluble fertilizers mercury, arsenic, cadmium, lead, chromium limit its determination. Industry standards-Agriculture. (in Chinese with English abstract)

Fu T L. The market and current situation of Chinese feed additives analysis. Fine Chemicals, 1997; (1): 3-6. (in Chinese with English abstract)

Li J, Zheng S X. Preliminary study on the heavy metal content in biogas manure. Renewable Energy Resources, 2009; 27(1): 62-64. (in Chinese with English abstract)

Tulayakul P, Boonsoongnern A, Kasemsuwan S, Wiriyarampa S, Pankumnoed J, Tippayaluck S, et al. Comparative study of heavy metal and pathogenic bacterial contamination in sludge and manure in biogas and non-biogas swine farms. Journal of Environmental Sciences, 2011; 23(6): 991-997.

Liu Y L, Ren Z A, Yan M J. Feed additive status and development trend. Journal of Animal Science and Veterinary Medicine, 2008; 27(5): 36-37. (in Chinese with English abstract)

Zhao W N. The detecting results analysis of the heavy metals (lead, cadmium) in pig feed. Jiangxi Agricultural University, 2011. (in Chinese with English abstract)

Xiong D W, Xie J, Wu Z L, Yang C F, Yu P. A Set of integrated fertilizer and water irrigation equipment on disposal of biogas slurry pollution-free and utilization. South China Agriculture, 2011, 5(3): 5-9. (in Chinese with English abstract)

Chen L H, Ni W Z, Li X L, Sun J B. Investigation of heavy metal concentrations in commercial fertilizers commonly- used. Journal of Zhejiang Sci-Tech University, 2009; 26(2): 223-227. (in Chinese with English abstract)

Abubaker J, Cederlund H, Arthurson V, Pell M. Bacterial community structure and microbial activity in different soils amended with biogas residues and cattle slurry. Applied Soil Ecology, 2013; 72(0): 171-180.

Abubaker J, Risberg K, Pell M. Biogas residues as fertilisers