The advance of swine wastewater treatment technology

Abstract

Keywords:
• swine wastewater,
• wastewater treatment technology,
• utilization of resources,
• nitrogen removal

References

1. [1]

   马彦涛,薛金凤.养猪废水处理技术进展[J].环境与可持续发展,2009,34(5):29.
   

2. [2]

   中华人民共和国国家统计局.第一次全国污染源普查公报[J].新华月报,2010(6):65.
   

3. [3]

   潘庆.养猪场的废水污染及防治对策[J].环境污染治理技术与设备,2002(9):66.
   

4. [4]

   万风,王海燕,周岳溪,等.养猪废水处理技术研究进展[J].农业灾害研究,2012,2(1):25.
   

5. [5]

   欧阳婷,王涛,樊华.养猪废水深度治理技术研究进展[J].安徽农业科学,2016,44(35):81.
   

6. [6]

   张德林.养猪养殖户沼气池的建设[J].现代农村科技,2012(15):78.
   

7. [7]

   韦成乔.生态养猪沼气池的建设和管理研究[J].畜禽业,2018,29(11):59
   

8. [8]

   李轶,刘雨秋,张镇,等.玉米秸秆与猪粪混合厌氧发酵产沼气工艺优化[J].农业工程学报,2014,30(5):185.
   

9. [9]

   孙全平,邱凌,李自林,等.酒糟与猪粪混合厌氧发酵产沼气的研究[J].西北农业学报,2013,22(3):199.
   

10. [10]

    邓媛方,邱凌,孙全平,等.蘑菇废弃菌棒及其与猪粪混合发酵对沼气产量及质量的影响[J].农业环境科学学报,2012,31(3):613.
    

11. [11]

    LIU Y,MA S C,HUANG L,et al.Two-step heating mode with the same energy consumption as conventional heating for enhancing methane production during anaerobic digestion of swine wastewater[J].Journal of Environmental Management,2018,209:301.

12. [12]

    赵青玲,杨世关,张百良.UASB处理养猪废水条件下进水浓度对污泥颗粒化的影响[J].可再生能源,2005(5):38.
    

13. [13]

    郑仁宏.UASB处理畜禽养殖废水的启动研究[D].雅安:四川农业大学,2007.
    

14. [14]

    万莉,邹义龙,弓晓峰,等.电增强零价铁强化厌氧氨氧化处理高氮养猪废水[J].环境科学研究,2015,28(8):1302.
    

15. [15]

    ZENG Z,ZHANG M,KANG D,et al.Enhanced anaerobic treatment of swine wastewater with exogenous granular sludge:Performance and mechanism[J].Science of the Total Environment,2019,697:1.

16. [16]

    ZHOU Z,PING Z,CHENG S,et al.A challenge in anaerobic digestion of swine wastewater:Recalcitrance and enhanced-degradation of dietary fibres[J].Biodegradation,2019,30(5/6):389.

17. [17]

    CHEN J L,XU Y B,LI Y X,et al.Effective removal of nitrate by denitrification re-enforced with a two-stage anoxic/oxic (A/O) process from a digested piggery wastewater with a low C/N ratio[J].Journal of Environmental Management,2019,240:19.

18. [18]

    夏经纬.倒置A²/O²与人工湿地处理猪场废水的试验研究[D].广州:华南农业大学,2016.
    

19. [19]

    郑志彬.预处理/沼气池/两级AO工艺处理养殖废水[J].资源节约与环保,2018(4):88.
    

20. [20]

    陈凤祥.UASB/两级AO工艺处理养猪废水的应用研究[J].广州化工,2014,43(4):89.
    

21. [21]

    陈威,施武斌,龚松,等.EGSB-A/O-MBR工艺处理规模化猪场废水[J].给水排水,2014,40(3):45.
    

22. [22]

    曾哲伟.A²/O-混凝工艺处理养猪场废水[J].广州化工,2016,44(11):185.
    

23. [23]

    WU X,ZHU J,CHENG J H,et al.Optimization of three operating parameters for a two-step fed sequencing batch reactor (SBR) system to remove nutrients from swine wastewater[J].Applied Biochemistry and Biotechnology,2015,175(6):2857.

24. [24]

    LIU J,LI J,WANG X D,et al.Rapid aerobic granulation in an SBR treating piggery wastewater by seeding sludge from a municipal WWTP[J].Journal of Environmental Sciences,2017,51(1):332.

25. [25]

    SHENG X L,LIU R,SONG X Y,et al.Comparative study on microbial community in intermittently aerated sequencing batch reactors (SBR) and a traditional SBR treating digested piggery wastewater[J].Frontiers of Environmental Science & Engineering,2017,11(3):8.

26. [26]

    SONG X Y,LIU R,CHEN L J,et al.Advantages of intermittently aerated SBR over conventional SBR on nitrogen removal for the treatment of digested piggery wastewater[J].Frontiers of Environmental Science & Engineering,2017,11(3):e13.

27. [27]

    LI J Z,MENG J,LI J L,et al.The effect and biological mechanism of COD/TN ratio on nitrogen removal in a novel upflow microaerobic sludge reactor treating manure-free piggery wastewater[J].Bioresource Technology,2016,209:360.

28. [28]

    MENG J,LI J L,LI J Z,et al.Efficiency and bacterial populations related to pollutant removal in an upflow microaerobic sludge reactor treating manure-free piggery wastewater with low COD/TN ratio[J].Bioresource Technology,2016,201:166.

29. [29]

    MENG J,LI J L,LI J Z,et al.The role of COD/N ratio on the start-up performance and micro-bial mechanism of an upflow microaerobic reactor treating piggery wastewater[J].Journal of Environmental Management,2018,217:825.

30. [30]

    施云芬,魏冬雪.MBBR两种填料对养猪废水脱氮除磷效果对比[J].化学通报,2014,77(6):562.
    

31. [31]

    MENG J,LI J L,LI J Z,et al.Enhanced nitrogen removal from piggery wastewater with high NH₄⁺ and low COD/TN ratio in a novel upflow microaerobic biofilm reactor[J].Bioresource Technology,2018,249:935.

32. [32]

    万莉.规模化养猪场废水(沼液)BCO+SBBR好氧处理新工艺研究[D].南昌:南昌大学,2016.
    

33. [33]

    宋承谋,蔡映红,吴正杰,等.规模化养猪废水处理问题及对策[J].中国猪业,2016,11(2):66.
    

34. [34]

    ZHANG X,INOUE T,KATO K,et al.Perfor-mance of hybrid subsurface constructed wetland system for piggery wastewater treatment[J].Water Science and Technology,2016,73(1):13.

35. [35]

    LI X,LI Y Y,LI Y,et al.Diversity and distribution of bacteria in a multistage surface flow constructed wetland to treat swine wastewater in sediments[J].Applied Microbiology and Biotechnology,2018,102:10755.

36. [36]

    DONG X,REDDY G.Soil bacterial communities in constructed wetlands treated with swine wastewater using PCR-DGGE technique[J].Bioresource Technology,2010,101(4):1175.

37. [37]

    HAN Z,DONG J,SHEN Z,et al.Nitrogen removal of anaerobically digested swine wastewater by pilot-scale tidal flow constructed wetland based on in-situ biological regeneration of zeolite[J].Chemosphere,2019,217:364.

38. [38]

    LI L,LIU M,WU M,et al.Effects of duckweed (Spriodela polyrrhiza) remediation on the composition of dissolved organic matter in effluent of scale pig farms[J].Journal of Environmental Sciences,2017,55(5):247.

39. [39]

    WANG W,YANG C,TANG X,et al.Carbon and energy fixation of great duckweed Spirodela polyrrhiza growing in swine wastewater[J].Environmental Science and Pollution Research,2015,22(20):15804.

40. [40]

    LUO P,LIU F,LIU X,et al.Phosphorus removal from lagoon-pretreated swine wastewater by pilot-scale surface flow constructed wetlands planted with Myriophyllum aquaticum[J].Science of the Total Environment,2017,576:490.

41. [41]

    LI X,ZHANG M,LIU F,et al.The significance of Myriophyllum elatinoides for swine wastewater treatment:Abundance and community structure of ammonia-oxidizing microorganisms in sediments[J].PLOS ONE,2015,10(10):e0139778.

42. [42]

    LI X,ZHANG M,LIU F,et al.Abundance and distribution of microorganisms involved in denitrification in sediments of a Myriophyllum elatinoides purification system for treating swine wastewater[J].Environmental Science and Pollution Research International,2015,22(22):17906.

43. [43]

    CHEN L,LIU F,JIA F,et al.Anaerobic ammonium oxidation in sediments of surface flow constructed wetlands treating swine wastewater[J].Applied Microbiology and Biotechnology,2017,101(3):1301.

44. [44]

    HUANG X,ZHENG J,LIU C,et al.Performance and bacterial community dynamics of vertical flow constructed wetlands during the treatment of antibiotics-enriched swine wastewater[J].Chemical Engineering Journal,2017,316:727.

45. [45]

    敖子强,付嘉琦,桂双林,等.处理养猪废水的人工湿地植物筛选综述[J].家畜生态学报,2016,37(7):87.
    

46. [46]

    许惠英,朱新富,王志荣.人工湿地技术在养猪废水处理中的应用[J].浙江树人大学学报(自然科学版),2010,10(4):15.
    

47. [47]

    童凯,李俊斌.养猪废水处理工程实例介绍[J].北方环境,2011,23(7):179.
    

48. [48]

    万莉,章洪涛,弓晓峰,等.鄱阳湖流域养猪废水治理概况与进展[J].南水北调与水利科技,2015,13(4):798.
    

49. [49]

    邓玉君,叶志隆,叶欣,等.流化床造粒法回收猪场废水中氮磷:鸟粪石颗粒的形貌与组成[J].环境工程学报,2016,10(6):2933.
    

50. [50]

    HUANG H,LIU J,WANG S,et al.Nutrients removal from swine wastewater by struvite precipitation recycling technology with the use of Mg₃(PO₄)₂ as active component[J].Ecological Engineering,2016,92:111.

51. [51]

    KIM D,MIN K,LEE K,et al.Effects of pH,molar ratios and pre-treatment on phosphorus recovery through struvite crystallization from effluent of anaerobically digested swine wastewater[J].Environmental Engineering Research,2017,22(1):12.

52. [52]

    WU Z,ZOU S,ZHANG B,et al.Forward osmosis promoted in-situ formation of struvite with simultaneous water recovery from digested swine wastewater[J].Chemical Engineering Journal,2018,342:274.

53. [53]

    LUO Z,WANG D,YANG J,et al.Nitrogen removal from digested piggery wastewater using fermented superphosphate within the pretreatment stage and an MAP fertilizer pot test[J].Journal of Cleaner Production,2019,212:372.

54. [54]

    赵倩倩,顾玲.PVDF膜接触器脱除回收垃圾渗滤废液中的氨氮[J].天津化工,2014,28(1):53.
    

55. [55]

    张宗阳,郝兴阁,赵建敏,等.双套型中空纤维膜接触器用于脱除水溶液中氨氮[J].高校化学工程学报,2016,30(5):1213.
    

56. [56]

    刘芮,陆军,李保,等.错流式中空纤维膜接触器脱除水中氨氮的实验研究[J].工业水处理,2015,35(3):52.
    

57. [57]

    SHI L,HU Y,XIE S,et al.Recovery of nutrients and volatile fatty acids from pig manure hydrolysate using two-stage bipolar membrane electrodialysis[J].Chemical Engineering Journal,2018,334:134.

58. [58]

    LIM S,KIM T,KIM J,et al.Enhanced treatment of swine wastewater by electron beam irradiation and ion-exchange biological reactor[J].Separation and Purification Technology,2016,157:72.

59. [59]

    HUANG H,ZHANG D,GUO G,et al.Dolomite application for the removal of nutrients from synthetic swine wastewater by a novel combined electrochemical process[J].Chemical Engineering Journal,2018,335:665.

60. [60]

    WANG H M,MIAO Z,LI Y F,et al.Energy self-sustained treatment of swine wastewater in a microbial electrochemical technology-centered hybrid system[J].Environmental Science:Water Research & Technology,2020,6(3):747.

61. [61]

    DING W J,CHENG S A,YU L L,et al.Effective swine wastewater treatment by combining microbial fuel cells with flocculation[J].Chemosphere,2017,182:567.

62. [62]

    CERRILLO M,OLIVERAS J,VINAS M,et al.Comparative assessment of raw and digested pig slurry treatment in bioelectrochemical systems[J].Bioelectrochemistry,2016,110:69.

63. [63]

    CERRILLO M,VINAS M,BONMATI A.Overcoming organic and nitrogen overload in thermophilic anaerobic digestion of pig slurry by coupling a microbial electrolysis cell[J].Bioresource Technology,2016,216:362.

64. [64]

    SCHERSON Y,WELLS G,WOO S,et al.Nitrogen removal with energy recovery through N₂O decomposition[J].Energy Environ Sci,2013,6(1):241.

65. [65]

    SCHERSON Y,WOO S,CRIDDLE C.Production of nitrous oxide from anaerobic digester centrate and its use as a co-oxidant of biogas to enhance energy recovery[J].Environmental Science & Technology,2014,48(10):5612.

66. [66]

    WESSBACH M,THIEL P,DREWES J,et al.Nitrogen removal and intentional nitrous oxide production from reject water in a coupled nitritation/nitrous denitritation system under real feed-stream conditions[J].Bioresource Technology,2018,255:58.

67. [67]

    MEISSBACH M,GOSSLER F,DREWES J,et al.Separation of nitrous oxide from aqueous solutions applying a micro porous hollow fiber membrane contactor for energy recovery[J].Separation and Purification Technology,2018,195:271.

68. [68]

    WEISSBACH M,DREWES J,KOCH K.Application of the oxidation reduction potential (ORP) for process control and monitoring nitrite in a coupled aerobic-anoxic nitrous decomposition operation (CANDO)[J].Chemical Engineering Journal,2018,343:484.

69. [69]

    MAYUNG J,WANG Z,YUAN T,et al.Production of nitrous oxide from nitrite in stable type ii methanotrophic enrichments[J].Environmental Science & Technology,2015,49(18):10969.

70. [70]

    GAO H,LIU M,GRIFFIN J,et al.Complete nutrient removal coupled to nitrous oxide production as a bioenergy source by denitrifying polyphosphate-accumulating organisms[J].American Chemical Society,2017(8):4531.

71. [71]

    WANG Y,GAO W,YEN H,et al.Cultivation of Chlorella vulgaris JSC-6 with swine wastewater for simultaneous nutrient/COD removal and carbohydrate production[J].Bioresource Technology,2015,198:619.

72. [72]

    VIMALKUMAR G,SURESH S,DHARMARJAN R,et al.Use of mixed wastewaters from piggery and winery for nutrient removal and lipid production by Chlorella sp.MM3[J].Bioresource Technology,2018,256:254.

73. [73]

    WEN Y,HE Y,JI X,et al.Isolation of an indigenous Chlorella vulgaris from swine wastewater and characterization of its nutrient removal ability in undiluted sewage[J].Bioresource Technology,2017,243:247.

74. [74]

    LEE Y,HAN G.Complete reduction of highly concentrated contaminants in piggery waste by a novel process scheme with an algal-bacterial symbiotic photobioreactor[J].Journal of Environmental Management,2016,177:202.

75. [75]

    YU J,HU H,WU X,et al.Coupling of biochar-mediated absorption and algal-bacterial system to enhance nutrients recovery from swine wastewater[J].Science of the Total Environment,2020,701:1.

76. [76]

    GUO G,CAO W,SUN S,et al.Nutrient removal and biogas upgrading by integrating fungal-microalgal cultivation with anaerobically digested swine wastewater treatment[J].Journal of Applied Phycology,2017,29(6):2857.

77. [77]

    KIM H,CHOI W,CHAE A,et al.Evaluating integrated strategies for robust treatment of high saline piggery wastewater[J].Water Research,2016,89:222.

78. [78]

    WANG M,YANG Y,CHEN Z,et al.Removal of nutrients from undiluted anaerobically treated piggery wastewater by improved microalgae[J].Bioresource Technology,2016,222:130.

79. [79]

    袁林江,彭党聪,王志盈.短程硝化-反硝化生物脱氮[J].中国给水排水,2000(2):29.
    

80. [80]

    于德爽,彭永臻,张相忠,等.中温短程硝化反硝化的影响因素研究[J].中国给水排水,2003(1):40.
    

81. [81]

    尚会来,彭永臻,张静蓉,等.温度对短程硝化反硝化的影响[J].环境科学学报,2009,29(3):516.
    

82. [82]

    曾薇,彭永臻,王淑莹,等.两段SBR法去除有机物及短程硝化反硝化[J].环境科学,2002(2):50.
    

83. [83]

    高大文,彭永臻,杨庆,等.应用实时控制实现和稳定短程硝化反硝化[J].中国给水排水,2003(12):1.
    

84. [84]

    董文艺,赵志军,李继.甲烷作为反硝化气体碳源的研究进展[J].安全与环境工程,2011,18(4):64.
    

85. [85]

    王东豪,廖方成,邓正栋,等.氧气浓度对好氧甲烷氧化耦合反硝化过程的影响[J].净水技术,2019,38(7):101.
    

86. [86]

    范秋香,吴箐,常佳丽,等.反硝化型甲烷厌氧氧化的研究进展[J].生态学杂志,2015,34(6):1747.
    

87. [87]

    XIE G,LIU T,CAI C,et al.Achieving high-level nitrogen removal in mainstream by coupling anammox with denitrifying anaerobic methane oxidation in a membrane biofilm reactor[J].Water Research,2018,131:196.

88. [88]

    FAN S,XIE G,LU Y,et al.Granular sludge coupling nitrate/nitrite dependent anaerobic methane oxidation with anammox:From proof-of-concept to high rate nitrogen removal[J].Environmental Science & Technology,2020,54(1):297.

89. [89]

    HU Z,RU D,WANG Y,et al.Optimization of a nitrite-dependent anaerobic methane oxidation (n-damo) process by enhancing methane availability[J].Bioresource Technology,2019,275:101.

90. [90]

    CAI C,HU S,CHEN X,et al.Effect of methane partial pressure on the performance of a membrane biofilm reactor coupling methane-depen-dent denitrification and anammox[J].Science of the Total Environment,2018,639:278.

91. [91]

    BEATRIZ M,CRUZ G,DIMITAR K,et al.Anammox for ammonia removal from pig manure effluents:Effect of organic matter content on process performance[J].Bioresource Techno-logy,2009,100(7):2171.

92. [92]

    ZHANG Z,ZHANG Q,XU J,et al.Long-term effects of heavy metals and antibiotics on granule-based anammox process:Granule property and performance evolution[J].Applied Microbiology and Biotechnology,2016,100(5):2417.

93. [93]

    NI S,YANG N.Evaluation of granular anaerobic ammonium oxidation process for the disposal of pre-treated swine manure[J].PeerJ,2014,2(1):e336.

94. [94]

    何占飞.厌氧氨氧化处理养殖废水启动实验研究[D].西安:西南交通大学,2008.
    

95. [95]

    张正哲.重金属离子对厌氧氨氧化颗粒污泥的影响及其修复策略研究[D].杭州:杭州师范大学,2016.
    

96. [96]

    李晶.氟喹诺酮抗生素对厌氧氨氧化菌活性抑制研究[D].大连:大连理工大学,2015.
    

97. [97]

    赵楠婕,解庆林,游少鸿,等.厌氧氨氧化工艺处理猪场废水沼液的试验研究[J].四川环境,2012,31(5):4.
    

98. [98]

    荀方飞,何占飞,葛亚军,等.厌氧氨氧化处理猪场养殖废水最佳运行工艺研究[J].广东农业科学,2010,37(7):174.
    

99. [99]

    WANG S,WANG L,DENG L W,et al.Performance of autotrophic nitrogen removal from digested piggery wastewater[J].Bioresource Technology,2017,241:465.

Proportional views