Effect of sludge thickness on characteristics of ultrasonic assisted hot air drying sludge

doi:10.11949/0438-1157.20200605

Abstract

Abstract:

Due to the stratification of sludge particles in the ultrasonic field, the acoustic interaction forces the particles to agglomerate on a plane perpendicular to the direction of ultrasonic propagation. Therefore, the thickness of sludge can significantly influence the characteristics of ultrasound-assisted hot air convective drying municipal sewage sludge. In this paper, the stratified aggregation phenomenon of sludge with different thicknesses was observed in the ultrasonic field using the experimental method. It was found that the stratification of the internal structure of sludge became more obvious with the increase of its thickness. The effects of ultrasound on the drying time and the drying rate of sludge with various thicknesses were studied. Meanwhile, the effective moisture diffusivity (D_eff) was analyzed. The experimental results demonstrated that the larger the sludge thickness, the longer the time length of the first falling rate stage and the promotion of the drying rate was worse when the ultrasonic power was less than 135 W. The situation was opposite at the constant rate stage. Among the sludge with the thicknesses of 5, 10, and 15 mm, the total drying time and energy consumption of the sludge with a thickness of 10 mm decreased the most substantially under the condition of ultrasonic power less than 90 W. The smaller the thickness of sludge is, the less obvious the effect of ultrasound on the effective moisture diffusivity, and vice versa.

Key words: sludge, ultrasound, drying, microstructure, aggregation

摘要：

由于在超声波声场中污泥微粒会发生分层现象，声互作用力使得微粒于超声传播方向相垂直的平面上发生凝聚，因此污泥厚度大小对超声波辅助热风干燥污泥特性有着重要的影响。通过实验的方法，对不同厚度污泥在超声波声场中的分层凝聚现象进行观察，发现污泥内部结构的分层现象随其厚度的增加而明显。研究了超声波对不同厚度污泥干燥过程中各时期干燥时长、干燥速率的影响效果，以及分析了湿分有效扩散系数（D_eff）随污泥厚度变化的情况。从实验结果中可以发现，在超声波功率小于135 W范围内，污泥厚度越大，干燥过程中第一降速期时间越长，干燥速率提升效果越差，而对恒速干燥期内干燥速率提升效果更明显；在5、10以及15 mm厚度的污泥中，10 mm厚度的污泥在超声波功率小于90 W的条件下总干燥时长降低幅度最大，干燥速率在各阶段提速也较快；污泥厚度越小，超声波功率对污泥湿分有效扩散系数影响越小，反之影响越大。

关键词: 污泥, 超声波, 干燥, 显微结构, 聚集

CLC Number:

TK 121

Xinzhu MOU, Zhenqian CHEN. Effect of sludge thickness on characteristics of ultrasonic assisted hot air drying sludge[J]. CIESC Journal, 2020, 71(S2): 241-252.

牟新竹, 陈振乾. 污泥厚度对超声波辅助热风干燥污泥特性的影响[J]. 化工学报, 2020, 71(S2): 241-252.

Figures/Tables 14

Fig.1 Schematic diagram of ultrasound-assisted hot air drying sludge setup

Fig.2 Schematic diagram of sludge freeze-drying treatment and microscopic observation device

Fig.3 Comparison of effects before and after image processing

Fig.4 3D scene of sludge constructed using ArcGIS

Fig.5 3D scenes of sludge

Table 1 Porosity of sludge with different thicknesses pretreated by ultrasound (90 W)

污泥厚度/mm	孔隙率/%	提升比/%
5	52.3	0.97
10	53.6	3.47
15	54.2	4.63

Fig.6 Evolutions of moisture ratio and drying rate profiles at different ultrasonic power

Fig.7 Comparison of duration of each stage of drying under different ultrasonic power

Fig.8 Percentage of time length reduction of sludge with 3 kinds of thicknesses

Fig.9 Drying rate of each stage under different ultrasonic power

Fig.10 Percentage of increasing drying rate of sludge with 3 kinds of thicknesses

Table 2 Analysis of variance for sample in ultrasound-assisted convective drying

时期	来源	平方和（SS）	自由度（D_f）	MS均方	F检验
恒速期	污泥厚度	2.002×10^-8	2	1.001×10^-8	2741.760
	超声波功率	4.395×10^-10	2	2.198×10^-10	60.194
	误差	1.460×10^-11	4	3.651×10^-12
	总和	2.048×10^-8	8	4.762×10^-9
第一降速期	污泥厚度	9.524×10^-9	2	2.771×10^-10	135.052
	超声波功率	5.543×10^-10	2	3.526×10^-11	7.860
	误差	1.140×10^-10	4
	总和	1.022×10^-8	8
第二降速期	污泥厚度	1.514×10^-9	2	7.569×10^-10	25.512
	超声波功率	3.868×10^-11	2	1.934×10^-11	0.652
	误差	1.187×10^-10	4	2.967×10^-11
	总和	1.071×10^-9	8

Fig.11 Linear fitting between lnMR vst (thickness of sludge: 15 mm, ultrasonic power: 45 W)

Fig.12 Effective moisture diffusivity (Deff) of sludge under different ultrasonic power

References 36

1	王兴栋, 张斌, 余广炜, 等. 不同粒径污泥热解制备生物炭及其特性分析[J]. 化工学报, 2016, 67(11): 4808-4816.
	Wang X D, Zhang B, Yu G W, et al. Preparation of biochar with different particle sized sewage sludge and its characteristics [J]. CIESC Journal, 2016, 67(11): 4808-4816.
2	Li R J, Wen W B, Lin J Y. Enhanced dewaterability of textile dyeing sludge using micro-electrolysis pretreatment [J]. Journal of Environmental Management, 2015, 161: 181-187.
3	Gayathri T, Kavitha S, Kumar S A, et al. Effect of citric acid induced deflocculation on the ultrasonic pretreatment efficiency of dairy waste activated sludge [J]. Ultrasonics Sonochemistry, 2015, 22: 333-340.
4	宋艳培, 庄修政, 詹昊, 等. 污泥与褐煤共水热碳化的协同特性研究[J]. 化工学报, 2020, 71(5): 2320-2330.
	Song Y P, Zhuang X Z, Zhan H, et al. Investigation on thermochemical conversion characteristics and regularity of co-hydrothermal carbonization solid fuel from sewage sludge and lignite [J]. CIESC Journal, 2020, 71(5): 2320-2330.
5	李海燕, 刘欢, 汪家兴, 等. 基于化学改性的脱水污泥低温热风干化特性[J]. 化工学报, 2018, 69(7): 3257-3262.
	Li H Y, Liu H, Wang J X, et al. Characteristics of dehydrated sludge based on chemical modification: low temperature hot-air drying [J]. CIESC Journal, 2018, 69(7): 3257-3262.
6	李亚林, 刘蕾, 张毅, 等. 电渗透/Fe-过硫酸盐氧化协同强化污泥深度脱水[J]. 化工学报, 2016, 67(9): 4013-4019.
	Li Y L, Liu L, Zhang Y, et al. Coordination of electro-osmotic and Fe-persulfate oxidation process on sewage sludge deep-dewatering [J]. CIESC Journal, 2016, 67(9): 4013-4019.
7	Zhan T L, Zhan X, Lin W, et al. Field and laboratory investigation on geotechnical properties of sewage sludge disposed in a pit at Changan landfill, Chengdu, China [J]. Engineering Geology, 2014, 170: 24-32.
8	Cieślik B M, Namiesnik J, Konieczka P. Review of sewage sludge management: standards, regulations and analytical methods [J]. Journal of Cleaner Production, 2015, 90: 1-15.
9	Tuncal T, Uslu O. A review of dehydration of various industrial sludges [J]. Drying Technology, 2014, 32(14): 1642-1654.
10	Siucińska K, Konopacka D. Application of ultrasound to modify and improve dried fruit and vegetable tissue: a review [J]. Drying Technology, 2014, 32(11): 1360-1368.
11	Bantle M, Hanssler J. Ultrasonic convective drying kinetics of clipfish during the initial drying period [J]. Drying Technology, 2013, 31(11): 1307-1316.
12	Sabarez H T, Gallego-Juarez J A, Riera E. Ultrasonic-assisted convective drying of apple slices [J]. Drying Technology, 2012, 30(9): 989-997.
13	García-Pérez J V, Cárcel J A, Benedito J, et al. Power ultrasound mass transfer enhancement in food drying [J]. Food and Bioproducts Processing, 2007, 85(3): 247-254.
14	Packyam G S, Kavitha S, Kumar S A, et al. Effect of sonically induced deflocculation on the efficiency of ozone mediated partial sludge disintegration for improved production of biogas [J]. Ultrasonics Sonochemistry, 2015, 26: 241-248.
15	Bantle M, Eikevik T M. A study of the energy efficiency of convective drying systems assisted by ultrasound in the production of clipfish [J]. Journal of Cleaner Production, 2014, 65: 217-223.
16	Lima A G B D, Neto S R F, Silva W P. Heat and Mass Transfer in Porous Media [M]. Berlin Heidelberg: Springer, 2012: 161-185.
17	Toğru I T, Pehlivan D. Modelling of thin layer drying kinetics of some fruits under open-air sun drying process [J]. Journal of Food Engineering, 2004, 65(3): 413-425.
18	Shi Q L, Zheng Y Q, Zhao Y. Mathematical modeling on thin-layer heat pump drying of yacon (Smallanthus sonchifolius) slices [J]. Energy Conversion and Management, 2013, 71: 208-216.
19	Koua K B, Fassinou W F, Gbaha P, et al. Mathematical modelling of the thin layer solar drying of banana, mango and cassava [J]. Energy, 2009, 34(10): 1594-1602.
20	Shen F, Peng L, Zhang Y Z, et al. Thin-layer drying kinetics and quality changes of sweet sorghum stalk for ethanol production as affected by drying temperature [J]. Industrial Crops and Products, 2011, 34(3): 1588-1594.
21	Doymaz I. Thin-layer drying behaviour of mint leaves [J]. Journal of Food Engineering, 2006, 74(3): 370-375.
22	Sun L X, Liu S X, Wang J X, et al. The effects of grain texture and phenotypic traits on the thin-layer drying rate in maize (Zea mays L.) inbred lines [J]. Journal of Integrative Agriculture, 2016, 15(2): 317-325.
23	Fu B A, Chen M Q. Thin-layer drying kinetics of lignite during hot air forced convection [J]. Chemical Engineering Research and Design, 2015, 102: 416-428.
24	Pillai G M. Thin layer drying kinetics, characteristics and modeling of plaster of Paris [J]. Chemical Engineering Research and Design, 2013, 91(6): 1018-1027.
25	Huang Y W, Chen M Q, Jia L. Assessment on thermal behavior of municipal sewage sludge thin-layer during hot air forced convective drying [J]. Applied Thermal Engineering, 2016, 96: 209-216.
26	Sun G Y, Chen M Q, Huang Y W. Evaluation on the air-borne ultrasound-assisted hot air convection thin-layer drying performance of municipal sewage sludge [J]. Ultrasonics Sonochemistry, 2017, 34: 588-599.
27	赵芳, 陈振乾, 施明恒. 超声波作用下污泥水分扩散过程的数值模拟[J]. 工程热物理学报, 2011, 32(4): 659-662.
	Zhao F, Chen Z Q, Shi M H. Numerical simulation on moisture diffusion process of sludge under the effect of ultrasound [J]. Journal of Engineering Thermophysics, 2011, 32(4): 659-662.
28	Trujillo F J, Juliano P, Gustavo B C, et al. Separation of suspensions and emulsions via ultrasonic standing waves - a review [J]. Ultrasonics Sonochemistry, 2014, 21(6): 2151-2164.
29	王宝军, 施斌, 蔡奕, 等. 基于GIS的黏性土SEM图像三维可视化与孔隙度计算[J]. 岩土力学, 2008, (1): 251-255.
	Wang B J, Shi B, Cai Y, et al. 3D visualization and porosity computation of clay soil SEM image by GIS [J]. Rock and Soil Mechanics, 2008, (1): 251-255.
30	Zhang X Y, Chen M Q, Huang Y W, et al. Isothermal hot air drying behavior of municipal sewage sludge briquettes coupled with lignite additive [J]. Fuel, 2016, 171: 108-115.
31	Chung L L, Tasirin S M, Wan R W D. A new variable diffusion drying model for the second falling rate period of paddy dried in a rapid bin dryer [J]. Drying Technology, 2003, 21(9): 1699-1718.
32	Belhamri A. Characterization of the first falling rate period during drying of a porous material [J]. Drying Technology, 2003, 21(7): 1235-1252.
33	Mowla D, Tran H N, Allen D G. A review of the properties of biosludge and its relevance to enhanced dewatering processes [J]. Biomass and Bioenergy, 2013, 58: 365-378.
34	Choudhury D, Sahu J K, Sharma G D. Moisture sorption isotherms, heat of sorption and properties of sorbed water of raw bamboo (Dendrocalamus longispathus) shoots [J]. Industrial Crops and Products, 2011, 33(1): 211-216.
35	Lasagabaster A, Abad M J, Barral L, et al. FTIR study on the nature of water sorbed in polypropylene (PP)/ethylene alcohol vinyl (EVOH) films [J]. European Polymer Journal, 2006, 42(11): 3121-3132.
36	Yao Y. Enhancement of mass transfer by ultrasound: application to adsorbent regeneration and food drying/dehydration [J]. Ultrasonics Sonochemistry, 2016, 31: 512-531.

[1]	Cheng CHENG, Zhongdi DUAN, Haoran SUN, Haitao HU, Hongxiang XUE. Lattice Boltzmann simulation of surface microstructure effect on crystallization fouling [J]. CIESC Journal, 2023, 74(S1): 74-86.
[2]	Xin WU, Jianying GONG, Long JIN, Yutao WANG, Ruining HUANG. Study on the transportation characteristics of droplets on the aluminium surface under ultrasonic excitation [J]. CIESC Journal, 2023, 74(S1): 104-112.
[3]	Chunyu LIU, Huanyu ZHOU, Yue MA, Changtao YUE. Drying characteristics and mathematical model of CaO-conditioned oil sludge [J]. CIESC Journal, 2023, 74(7): 3018-3027.
[4]	Yuanhao QU, Wenyi DENG, Xiaodan XIE, Yaxin SU. Study on electro-osmotic dewatering of sludge assisted by activated carbon/graphite [J]. CIESC Journal, 2023, 74(7): 3038-3050.
[5]	Guangyu WANG, Kai ZHANG, Kaihua ZHANG, Dongke ZHANG. Heat and mass transfer and energy consumption for microwave drying of coal slime [J]. CIESC Journal, 2023, 74(6): 2382-2390.
[6]	Zhen LONG, Jinhang WANG, Junjie REN, Yong HE, Xuebing ZHOU, Deqing LIANG. Experimental study on inhibition effect of natural gas hydrate formation by mixing ionic liquid with PVCap [J]. CIESC Journal, 2023, 74(6): 2639-2646.
[7]	Xinyue WANG, Junjie WANG, Sixian CAO, Cui WANG, Lingkun LI, Hongyu WU, Jing HAN, Hao WU. Effect of glass primary container surface modification on monoclonal antibody aggregates induced by mechanical stress [J]. CIESC Journal, 2023, 74(6): 2580-2588.
[8]	Lanhe ZHANG, Qingyi LAI, Tiezheng WANG, Xiaozhuo GUAN, Mingshuang ZHANG, Xin CHENG, Xiaohui XU, Yanping JIA. Effect of H₂O₂ on nitrogen removal and sludge properties in SBR [J]. CIESC Journal, 2023, 74(5): 2186-2196.
[9]	Wenqi HOU, Yan SUN, Xiaoyan DONG. Basification modification of transthyretin significantly enhances inhibitory effect on amyloid-β protein aggregation [J]. CIESC Journal, 2023, 74(5): 2100-2110.
[10]	Chenxin LI, Yanqiu PAN, Liu HE, Yabin NIU, Lu YU. Carbon membrane model based on carbon microcrystal structure and its gas separation simulation [J]. CIESC Journal, 2023, 74(5): 2057-2066.
[11]	Yuhao CHEN, Xiaoping CHEN, Jiliang MA, Cai LIANG. Gaseous pollutants emissions from rotary kiln combustion of municipal sewage sludge [J]. CIESC Journal, 2023, 74(5): 2170-2178.
[12]	Jinsheng REN, Kerun LIU, Zhiwei JIAO, Jiaxiang LIU, Yuan YU. Research on the mechanism of disaggregation of particle aggregates near the guide vanes of turbo air classifier [J]. CIESC Journal, 2023, 74(4): 1528-1538.
[13]	Yuming CHEN, Wei LI, Xiang YAN, Jingdai WANG, Yongrong YANG. Research progress on regulation of aggregation structure for nascent polyethylene [J]. CIESC Journal, 2023, 74(2): 487-499.
[14]	Xiang GUO, Jinshuo QIAO, Zhenhua WANG, Wang SUN, Kening SUN. Progress of structure for carbon-fueled solid oxide fuel cells [J]. CIESC Journal, 2023, 74(1): 290-302.
[15]	Xinyi LUO, Chao FENG, Jing LIU, Yu QIAO. Phosphorus recovery from products of sewage sludge via different thermal treatment processes [J]. CIESC Journal, 2022, 73(9): 4034-4044.