Simultaneous treatment of pyrolysis and activation for garden waste and adsorption performance of derived charcoal on SO<sub>2</sub>

LIU Xiaoji; LI Xulei; WANG Bin; CHANG Fengmin; WEI Wei; ZHANG Gan; WANG Kaijun

doi:10.13205/j.hjgc.202505017

Volume 43 Issue 5

May 2025

Turn off MathJax

Article Contents

Article Navigation > ENVIRONMENTAL ENGINEERING > 2025 > 43(5): 153-159

LIU Xiaoji, LI Xulei, WANG Bin, CHANG Fengmin, WEI Wei, ZHANG Gan, WANG Kaijun. Simultaneous treatment of pyrolysis and activation for garden waste and adsorption performance of derived charcoal on SO2[J]. ENVIRONMENTAL ENGINEERING , 2025, 43(5): 153-159. doi: 10.13205/j.hjgc.202505017

Citation:

LIU Xiaoji, LI Xulei, WANG Bin, CHANG Fengmin, WEI Wei, ZHANG Gan, WANG Kaijun. Simultaneous treatment of pyrolysis and activation for garden waste and adsorption performance of derived charcoal on SO₂[J]. ENVIRONMENTAL ENGINEERING , 2025, 43(5): 153-159. doi: 10.13205/j.hjgc.202505017

Citation:

LIU Xiaoji, LI Xulei, WANG Bin, CHANG Fengmin, WEI Wei, ZHANG Gan, WANG Kaijun. Simultaneous treatment of pyrolysis and activation for garden waste and adsorption performance of derived charcoal on SO₂[J]. ENVIRONMENTAL ENGINEERING , 2025, 43(5): 153-159. doi: 10.13205/j.hjgc.202505017

PDF( 894 KB)

Simultaneous treatment of pyrolysis and activation for garden waste and adsorption performance of derived charcoal on SO₂

doi: 10.13205/j.hjgc.202505017

1. CECEP (Feixi) WTE Co., Ltd., Hefei 231241, China;
2. State Key Joint Laboratory of Environment Simulation and Pollution Control, School of Environment, Tsinghua University, Beijing 100084, China

Received Date: 2024-06-03
Accepted Date: 2024-08-15
Rev Recd Date: 2024-07-12

Available Online: 2025-09-11

Abstract

Abstract

With the rapid development of urbanization in China， the huge production of garden waste in cities and towns has resulted in serious environmental pollution problems. In addition， recent treatment of garden waste is mainly focusing on incineration， which has an immediate and significant reduction effect， but is also a waste of biomass resources and unsustainable. Pyrolysis and activation are good options for resource utilization of garden waste. However， there is a lack of technical solutions to integrate pyrolysis with activation equipment to shorten the process flow and reduce the investment cost. In order to realize the scientific disposal of garden waste and improve its utilization， a pyrolysis-activation integrated furnace was developed to transform garden waste into heat and biomass-activated carbon， which verified the feasibility of the simultaneous treatment of pyrolysis and activation for garden waste. At the same time， the adsorption capacity of biomass-activated carbon on SO₂ in simulated flue gas was studied. The results showed that the simultaneous treatment of pyrolysis and activation could realize the efficient disposal and resource utilization of garden waste， and realize the high-quality cogeneration of heat-carbon （activated carbon）； the biomass activated carbon after activation had an iodine value of 550 mg/g， a specific surface area of 245.94 m²/g， and a pore volume of 0.145 m³/g； the biomass activated carbon prepared from garden waste had an adsorbing capacity on SO₂ of 14.4 mg/g， and that is 65% of the adsorption capacity of the commercial activated carbon. This study can provide a reference for the efficient disposal and resource utilization of garden waste， and the engineering promotion of simultaneous treatment of pyrolysis and activation.
- garden waste,
- simultaneous treatment of pyrolysis and activation,
- biomass activated carbon,
- sulfur dioxide adsorption

FullText(HTML)

References(25)

References

[1]	National Bureau of Statistics. 2023 China statistical yearbook[M]. Beijing:China Statistical Publishing House，2023. 国家统计局. 2023年中国统计年鉴[M]. 北京:中国统计出版社，2023 年.
[2]	LIU Y，QI Z Y，ZHAO J Y，et al. Urban garden waste and its resource utilization in China[J]. Recyclable Resources and Circular Economy，2020，13（8）:38-44. 刘瑜，戚智勇，赵佳颖，等. 我国城市园林废弃物及其资源化利用现状[J]. 再生资源与循环经济，2020，13（08）:38-44.
[3]	ZHANG K L. Study on catalytic hydrogenation of biomass-based 5-hydroxymethylfurfural to prepare furans[D]. Guangzhou:South China University of Technology，2021. 张凯莉. 生物质基5-羟甲基糠醛催化氢化制备呋喃类化合物的研究[D]. 广州:华南理工大学，2021.
[4]	JIANG D H，SUN K T，QI W，et al. Current situation and suggestions of biomass power generation industry in China[J]. Renewable Energy，2014，32（4）:542-546. 蒋大华，孙康泰，亓伟，等. 我国生物质发电产业现状及建议[J]. 可再生能源，2014，32（4）:542-546.
[5]	PENG Z Y. Effects of straw returning and nitrogen fertilizer management on yield of direct seeding rice under wheat/oil-rice rotation and its physiological basis[D]. Ya'an:Sichuan Agricultural University，2022. 彭志芸. 麦/油—稻轮作下秸秆还田与氮肥管理对直播稻产量的影响及其生理基础[D]. 雅安:四川农业大学，2022.
[6]	SU Y J. Study on the effect of Sumucus verrucosporum enzyme system on lignin and the mechanism of enzymatic hydrolysis synergistic effect on corn straw[D]. Changchun:Jilin Agricultural University，2019. 苏瑛杰. 疣孢漆斑菌酶系对玉米秸秆木质素影响及酶解增效作用机理研究[D]. 长春:吉林农业大学，2019.
[7]	WU J Y，LI X W，DING Y，et al. Study on carbon emission characteristics of biochar reuse in preparation of biochar from food waste biogas residue to promote anaerobic digestion of biogas production[J]. Journal of Environmental Science，2024，44（3）:227-236. 武俊尧，李向炜，丁燕，等. 餐厨垃圾沼渣制备生物炭回用促进厌氧消化产沼气工艺的碳排放特征研究[J]. 环境科学学报，2024，44（3）:227-236.
[8]	JU Y Y，DING Y J，SHAO Q Q，et al. Properties and application potential of biochar from urban garden waste[J]. Forestry Science，2020，56（8）:107-120. 鞠艳艳，丁元君，邵前前，等. 城市园林废弃物生物质炭性质及其应用潜力[J]. 林业科学，2020，56（8）:107-120.
[9]	HU G Y，SONG Y. Effects of biochar from garden waste at different pyrolysis temperatures on tomato yield，quality and bacterial wilt in continuous cropping facilities[J]. Jiangsu Agricultural Sciences，2021，49（23）:156-161. 胡广宇，宋旸. 不同热解温度园林废弃物生物质炭对设施连作番茄产量、品质及青枯病的影响[J]. 江苏农业科学，2021，49（23）:156-161.
[10]	REN X Y，QI X C，CAO C，et al. Analysis on the production and application development of biomass activated carbon materials under the strategy of"double carbon"[J]. Forest Products Industry，2022，59（04）:48-51，63. 任学勇，祁项超，曹畅，等.“双碳”战略下生物质活性炭材料生产与应用发展探析[J]. 林产工业，2022，59（04）:48-51+63.
[11]	TSARPALI M，KUHN J N，PHILIPPIDIS G P. Activated carbon production from algal biochar:Chemical activation and feasibility analysis[J]. Fuel Communications，2024，19.
[12]	LIU B，CHEN T，WANG B，et al. Enhanced removal of Cd²⁺ from water by AHP-pretreated biochar:Adsorption performance and mechanism[J]. Journal of Hazardous Materials，2022，Sep 15（438）:129467.
[13]	LENG F R. Study on material-energy balance of waste wood for activated carbon[J]. Shanxi Chemical Industry，2024，44（2）:12-15. 冷富荣. 废弃木材制备活性炭的物质能量平衡研究[J]. 山西化工，2024，44（2）:12-15.
[14]	祁帅杰，黄亚继，徐鹏程，等. 废弃木质建筑模板与典型生物质热解产物分布及特性对比[J/OL]. 化工进展:1-11[ 2024-05-10]. QI S J，HUANG Y J，XU P C，et al. Comparison of distribution and characteristics of waste wooden building formwork and typical biomass pyrolysis products[J/OL]. Chemical Industry and Engineering Progress:1-11.[ 2024-05-10].
[15]	ZHANG Z R，LIU Q H，WANG W G，et al. Effect of preparation temperature on physicochemical characteristics of bamboo charcoal-based biochar[J]. Environmental Engineering，2021，39（11）:96-102，126. 张卓然，刘清华，王伟刚，等. 制备温度对竹炭基生物炭理化特征的影响[J]. 环境工程，2021，39（11）:96-102，126.
[16]	LIU W，XU Z C，LI H X，et al. Solidification effect of sludge biochar on heavy metals in polluted dredged sediment of river in mining area[J]. Environmental Engineering，2024，42（2）:32-39. 刘维，徐志嫱，李红星，等. 污泥生物炭对矿区河道受污染疏浚底泥中重金属的固化效果[J]. 环境工程，2024，42（2）:32-39.
[17]	XING W L，ZHANG M M，ZHU H N，et al. Pyrolysis Experiment of Municipal Solid Waste and Yard Waste[J]. Environmental Engineering，2019，37（3）:152-157，197. 邢文龙，张蒙蒙，朱赫男，等. 城市生活垃圾与园林废物的热解实验[J]. 环境工程，2019，37（3）:152-157，197.
[18]	CUI Z L，XIE J F，WU F Z，et al. Experimental study on microwave pyrolysis characteristics of water hyacinth[J]. Contemporary Chemical Industry Research，2024（6）:33-35. 崔朝霖，谢俊峰，吴方哲，等. 水葫芦微波热解特性的实验研究[J]. 当代化工研究，2024（6）:33-35.
[19]	WANG P. Study on the effect of roasting pretreatment on the activation characteristics of water vapor of rice husk pyrolysis coke[D]. Nanjing:Southeast University，2019. 汪鹏. 烘焙预处理对稻壳热解焦水蒸气活化特性的影响研究[D]. 南京:东南大学，2019.
[20]	DENG F. Preparation of peat-based activated carbon and its pore structure evolution and regulation[D]. Beijing:China University of Mining and Technology（Beijing），2021. 邓锋. 泥炭基活性炭的制备及孔结构演化与调控研究[D]. 北京:中国矿业大学（北京），2021.
[21]	VALDERRAMA C，GAMISANS X，HERAS X D L，et al. Sorption kinetics of polycyclic aromatic hydrocarbons removal using granular activated carbon:intraparticle diffusion coefficients[J]. Journal of Hazardous Materials，2008，157（2/3）:386-396.
[22]	ZHANG Z B. Study on the activity and lifetime of coke catalyst to remove tar[D]. Harbin:Harbin Institute of Technology，2019. 张智博. 焦炭催化剂脱除焦油的活性和寿命研究[D]. 哈尔滨:哈尔滨工业大学，2019.
[23]	WANG G R，XU G F，DU S Q，et al. Study on the preparation of columnar activated carbon by water vapor activation of bamboo charcoal and its adsorption properties[J]. Acta Bamboo，2021，40（3）:29-35. 王国睿，徐光福，杜松青，等. 刺竹炭水蒸气活化制备柱状活性炭及其吸附性能研究[J]. 竹子学报，2021，40（3）:29-35.
[24]	ZHANG J X，DENG S，YAO F D，et al. Experimental study on adsorption of SO₂ and Hg in flue gas by PTFE composites[J]. Environmental Engineering，2014，32（11）:88-92. 张建星，邓双，姚福德，等. PTFE复合材料吸附烟气中SO₂和Hg的实验研究[J]. 环境工程，2014，32（11）:88-92.
[25]	YANG L Z，XIE W，YAN L，et al. Boosting SO₂/CO₂ separation with self-enhanced SO₂ adsorption in a microporous metal-organic framework[J]. Separation and Purification Technology，2024，346.