The Spatial and Temporal Distribution of Process Gases within the Biowaste Compost

Stegenta-Dąbrowska, Sylwia; Sobieraj, Karolina; Pilarski, Grzegorz; Kozieł, Jacek A.; Białowiec, Andrzej

doi:10.3390/data4010037

Cited by 13 publications

(43 citation statements)

References 14 publications

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“…In a wintertime experiment of composting with passive aeration [45], cooling began at the ends of the pile, which was explained by the increased surface area of the material and therefore increased heat loss. In this study, a similar pattern of temperature drop was observed only in piles A1 (36th day of the process, [43] ( Figure A4)), A2 (15th and 23rd day, [43] (Figures A8 and A9)), and A3 (15th and 52nd day, [43] (Figures A17 and A22)), where it took place on just one end. Also, in some cases, areas that had previously cooled down reached a higher temperature at later stages of composting (e.g., the end of the left side of pile A6 at day 29 [43] ( Figure A43)).…”

Section: Spatial and Temporal Distribution Of Temperature Within The supporting

confidence: 79%

“…In this study, a similar pattern of temperature drop was observed only in piles A1 (36th day of the process, [43] ( Figure A4)), A2 (15th and 23rd day, [43] (Figures A8 and A9)), and A3 (15th and 52nd day, [43] (Figures A17 and A22)), where it took place on just one end. Also, in some cases, areas that had previously cooled down reached a higher temperature at later stages of composting (e.g., the end of the left side of pile A6 at day 29 [43] ( Figure A43)). It was also observed that low temperatures (prevailing in the piles in autumn and winter) were caused by an unfavorable surface-to-volume ratio, which resulted in faster heat loss (Table 3) [46].…”

Section: Spatial and Temporal Distribution Of Temperature Within The supporting

confidence: 79%

“…Four cross sections and two longitudinal cross sections (the left and right sides of the pile) were made for each of the six piles. In total 1375 cross sections were made and presented in 230 figures in a companion manuscript [43]. A small subset (16 cross sections) illustrates the chimney effect in the A1 pile and the temperature effect on CO distribution is presented in this manuscript.…”

Section: Discussionmentioning

confidence: 99%

“…In addition, only 31.1% of locations in a cross section reached thermophilic conditions (defined as T > 60 • C, necessary to kill pathogens). The entire dataset of the temporal and spatial variation of temperature is presented elsewhere [43].…”

Section: Spatial and Temporal Distribution Of Temperature Within The mentioning

confidence: 99%

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Analysis of the Spatial and Temporal Distribution of Process Gases within Municipal Biowaste Compost

Stegenta-Dąbrowska

Sobieraj

Pilarski³

et al. 2019

Sustainability

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Composting processes reduce the weight and volume of biowaste and produce products that can be used in agriculture (e.g., as fertilizer). Despite the benefits of composting, there are also problems such as odors and the emission of pollutants into the atmosphere. This research aimed to investigate the phenomenon of process gas (CO, CO2, NO, O2) evolution within a large-scale municipal composter. The effects of turning frequency and pile location (outdoor vs. indoors) on process gas and temperature spatial and temporal evolution were studied in six piles (37‒81 tons of initial weight) over a six-month period. The biowaste consisted of green waste and municipal sewage sludge. The chemical composition and temperature of process gases within four cross sections with seven sampling locations were analyzed weekly for ~7–8 weeks (a total of 1375 cross sections). The aeration degree, temperature, CO, CO2, and NO concentration and their spatial and temporal distribution were analyzed. Final weight varied from 66% reduction to 7% weight gain. Only 8.2% of locations developed the desired chimney effect (utilizing natural buoyancy to facilitate passive aeration). Only 31.1% of locations reached thermophilic conditions (necessary to inactivate pathogens). Lower O2 levels corresponded with elevated CO2 concentrations. CO production increased in the initial composting phase. Winter piles were characterized by the lowest CO content. The most varied was the NO distribution in all conditions. The O2 concentration was lowest in the central part of the pile, and aeration conditions were good regardless of the technological regime used. Turning once a week was sufficient overall. Based on the results, the most favorable recommended procedure is turning twice a week for the first two weeks, followed by weekly turning for the next two weeks. After that, turning can be stopped unless additional removal of moisture is needed. In this case, weekly turning should continue until the process is completed. The size of the pile should follow the surface-to-volume ratio: <2.5 and <2 for cooler ambient conditions.

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Section: Spatial and Temporal Distribution Of Temperature Within The supporting

confidence: 79%

Section: Spatial and Temporal Distribution Of Temperature Within The supporting

confidence: 79%

Section: Discussionmentioning

confidence: 99%

Section: Spatial and Temporal Distribution Of Temperature Within The mentioning

confidence: 99%

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Analysis of the Spatial and Temporal Distribution of Process Gases within Municipal Biowaste Compost

Stegenta-Dąbrowska

Sobieraj

Pilarski³

et al. 2019

Sustainability

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“…The software will optimize the carbonized refuse-derived fuel (CRDF) production process before its valorization in the torrefaction process. In addition, the appropriate selection of the MSW mixture will help determine the cost-effectiveness of MSW mechanical pre-treatment and torrefaction of individual, site-specific wastes, waste streams, and their mixtures, such as municipal sludge [9] or compost [10].…”

Section: User Notesmentioning

confidence: 99%

Waste to Carbon Energy Demand Model and Data Based on the TGA and DSC Analysis of Individual MSW Components

Stępień

Serowik

Kozieł

et al. 2019

Data

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The pioneering developed simplified mathematical model can be used to determine the energy consumption of the torrefaction process. Specifically, the energy balance model was developed for torrefaction of municipal solid waste (MSW; a combustible fraction of common municipal waste). Municipalities are adopting waste separation and need tools for energy recovery options. This type of model is needed for initial decision-making, evaluation of cost estimates, life cycle analysis (LCA), and for optimizing the torrefaction of MSW. The MSW inputs are inherently variable and are site-, location-, and country-dependent. Thus, in this model, MSW inputs consist of eight types of common municipal waste components: chicken meat, diapers, gauze, eggs packaging, paper receipts, cotton, genuine leather, and polypropylene. The model uses simple experimental input consisting of thermogravimetric (TGA) and differential scanning calorimetry (DSC) analyses for each type of individual MSW material. The model was created in a Microsoft Office Excel spreadsheet and is available for download and use for site-specific waste mixes and properties. The model allows estimating the energy demand of the process depending on the percentage composition of the MSW and the final torrefaction temperature. The model enables initial optimization of the torrefaction process regarding its energy demand by changing the proportion of MSW mix and the final temperature.

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The role of Serendipita indica and Lactobacilli mixtures on mitigating mycotoxins and heavy metals’ risks of contaminated sewage sludge and its composts

Youssef

Al-Huqail

Ali

et al. 2020

Sci Rep

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Accumulation of the Municipal Sewage Sludge (MSS) is considered as one of the most harmful renewable ecological and human health problems. MSS is a renewable resource that could be used as a soil organic amendment. This study aims to reduce the Heavy Metals (HMs) from the sludge content and sludge compost. Furthermore, this study is considered the first to assess the mycotoxins content in sludge and sludge compost via a new biological treatment using the fungus Serendipita indica or a mixture of lactic acid bacteria, thus providing safer nutrients for the soil amendment for a longer time and preserving human health. The HMs and mycotoxins were determined. The results exhibited that the biotic remediation of bio-solid waste and sewage sludge compost succeeded; a new bio-treated compost with a very low content of heavy metals and almost mycotoxins-free contents was availed. Also, the results indicated that the Lactobacilli mixture realized the best results in reducing heavy metals contents and mycotoxins. Afterward, S. indica. biotic remediation of bio-solid waste and sewage sludge compost minimized the health risk hazards affecting the human food chain, allowing for the different uses of sludge to be safer for the environment.

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The Spatial and Temporal Distribution of Process Gases within the Biowaste Compost

Cited by 13 publications

References 14 publications

Analysis of the Spatial and Temporal Distribution of Process Gases within Municipal Biowaste Compost

Analysis of the Spatial and Temporal Distribution of Process Gases within Municipal Biowaste Compost

Waste to Carbon Energy Demand Model and Data Based on the TGA and DSC Analysis of Individual MSW Components

The role of Serendipita indica and Lactobacilli mixtures on mitigating mycotoxins and heavy metals’ risks of contaminated sewage sludge and its composts

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