基于正交分析的垃圾焚烧炉多源固废掺烧经济性分析

发电技术

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基于正交分析的垃圾焚烧炉多源固废掺烧经济性分析

张洪波¹，杨自强¹，李子龙¹，莫黄幸¹，廖艳芬^2*

1.光大环保(中国)有限公司，广东省深圳市 518000；2.华南理工大学电力学院，广东省广州市 510640

基金资助:
广东省重点领域研发计划项目(2020B1111380001)；广东省住房和城乡建设厅2024年科技创新计划项目(2024-R37-201656)

Economic Analysis of Multi-Source Solid Waste Co-Incineration in Waste Incinerators Based on Orthogonal Analysis

ZHANG Hongbo¹, YANG Ziqiang¹, LI Zilong¹, MO Huangxing¹, LIAO Yanfen^2*

1.China Everbright Environment Group Limited, Shenzhen 518000, Guangdong Province, China; 2.School of Electric Power, South China University of Technology, Guangzhou 510640, Guangdong Province, China

Supported by:
Key Program of Guangdong Province (2020B1111380001); Department of Housing and Urban-Rural Development of Guangdong Province (2024-R37-201656)

摘要/Abstract

摘要： 【目的】污泥、沼渣等固废在垃圾焚烧炉中掺烧已成为其主要处理方式之一，为更加高效经济地掺烧，通过热力计算，开展了垃圾焚烧炉中市政污泥、厨余沼渣的多源固废掺烧经济性分析。【方法】分别通过单因素分析及L₁₆(4³)正交分析，探究干基污泥掺烧比、干基沼渣掺烧比、污泥/沼渣入炉含水率对经济收益净现值的影响，并针对污泥、沼渣处理费收入不同的情况，给出是否引入多源固废掺烧的投资建议。【结果】干基污泥比为7%、干基沼渣比为3%、污泥/沼渣入炉含水率为40%时，是经济性最佳掺烧工况。在已掺烧其中一种固废的基础上，引入另一种固废进行多源掺烧的条件为：当扣除运费后沼渣处理费收入高于33元/t时，可引入沼渣协同掺烧；当扣除运费后污泥补贴高于15元/t时，可引入污泥协同掺烧。【结论】当单源固废掺烧时，在燃烧工况恶化程度允许范围内，可尽量增加掺烧比例；当多源固废掺烧时，应考虑两者的相互影响，探究最佳掺烧比例。

关键词: 经济性分析, 正交分析, 掺烧, 热力计算, 垃圾焚烧炉, 污泥, 厨余沼渣, 净现值

Abstract: [Objectives]　Co-incineration of solid wastes such as sludge and digestate in waste incinerators has become one of the main disposal methods. To achieve more efficient and economical co-incineration, an economic analysis of multi-source solid waste co-incineration involving municipal sludge and food waste digestate in waste incinerators is conducted using thermal calculations.[Methods]　The univariate analysis and L₁₆(4³) orthogonal analysis are employed to examine the impacts of the dry-basis sludge co-incineration ratio, dry-basis digestate co-incineration ratio, and the moisture content of sludge/digestate fed into the furnace on the net present value of economic benefits. Investment suggestions on whether to introduce multi-source solid waste co-incineration are provided, taking into account variations in income from sludge and digestate treatment fees.[Results]　The economically optimal co-incineration conditions are a dry-basis sludge ratio of 7%, a dry-basis digestate ratio of 3%, and a moisture content of sludge/digestate fed into the furnace of 40%. On the basis of co-incinerating one type of solid waste, the conditions of introducing another to achieve multi-source co-incineration are determined as follows. When the income from digestate treatment fee is higher than 33 yuan/t after deducting the transportation cost, co-incineration of digestate could be adopted. When the subsidy for sludge is higher than 15 yuan/t after deducting the transportation cost, co-incineration of sludge could be introduced.[Conclusions]　When single-source solid waste is co-incinerated, the co-incineration ratio can be increased as much as possible within the allowable range of combustion condition deterioration. When multi-source solid waste is co-incinerated, the interaction between the two should be considered to explore the optimal co-incineration ratio.

Key words: economic analysis, orthogonal analysis, co-incineration, thermal calculations, waste incinerator, sludge, food waste digestate, net present value

张洪波, 杨自强, 李子龙, 莫黄幸, 廖艳芬. 基于正交分析的垃圾焚烧炉多源固废掺烧经济性分析[J]. 发电技术.

ZHANG Hongbo, YANG Ziqiang, LI Zilong, MO Huangxing, LIAO Yanfen. Economic Analysis of Multi-Source Solid Waste Co-Incineration in Waste Incinerators Based on Orthogonal Analysis[J]. Power Generation Technology.

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