implementation of strategies to optimize the co-composting
TRANSCRIPT
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Implementation of strategies to optimize the co-
composting of green waste and food waste in developing
countries. A case study: Colombia A. Hernández-Gómez, D. Gordillo, F. Gómez, A. Calderón,
C. Medina, V. Sánchez-Torres, E. R. Oviedo-Ocaña
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Outline
Introduction
Materials and Methods
Results and Discussion
Conclusions
References 2
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Introduction
Materials and Methods
Results and Discussion
Conclusions
References 3
Outline
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4(Troschinetz & Mihelcic, 2009)
Introduction
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5(BID, 2015)
Food Waste (FW)
Green Waste (GW)
Characterization of solid waste in some cities of Colombia
Introduction
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Composting
GW are mainly composed by:
Lignin
Hemicellulose
Cellulose
Management alternative:
Limitations regarding the processing time and quality of the product
Introduction
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Strategies:
Food waste co-composting Two-stage composting
(TSC) Phosphate Rock (PR)
addition
Introduction
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(Zhang et al. 2013)
Introduction
Strategies:
Food waste co-composting Two-stage composting
(TSC) Phosphate Rock (PR)
addition
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Introduction
Materials and Methods
Results and Discussion
Conclusions
References 9
Outline
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Estimation of the production and physical composition of GW
Each of the discharges made by the collector truck during the study period were monitored.
The total capacity of the truck was 7.4 m³ (3.7 x 2 x 1 m)
Materials and Methods
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NMX-AA-19-1985 for sample quartering
NMX-AA-15-1985 for bulk density
Estimation of the production and physical composition of GW
Materials and Methods
Co-composting of GW, PF and UF using TSC and traditional (T)
TA
TB
(TSC + 15% PR)
(T +15% PR)
TC (T)
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Introduction
Materials and Methods
Results and Discussion
Conclusions
References 12
Outline
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Total production
Bulk density = 153.25 kg/m³
0 1 2 3 4 5 6 7 8 9 10 11 12 1350
80
110
140
170
200
230
192,9192,45
156,02
137,68
199,35
144,29
167,58
130,3121,76
80
127,24
189,47
PESO VOLUMÉTRICORainy period
Test
Bul
k de
nsity
[kg
/m³]
Production = 732.5 kg/day
73.25 kg/day-ha Green areas
Results and Discussion
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Physical composition
74% can be used in GW composting processes
Results and Discussion
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0 10 20 30 40 50 60 70 80 90 1000,0
10,0
20,0
30,0
40,0
50,0
60,0
70,0TATBTCTamb.V.
Time (days)
Tem
per
atu
re (
°C)
Results and Discussion
Composting process
0 10 20 30 40 50 60 70 80 90 1000
2
4
6
8
10
TATBTC
Time (days)
pH
0 10 20 30 40 50 60 70 80 90 1000
150
300
450
600
750
TATBTC
Time (days)
BD
(K
g/m
³)
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Treatment Ash (%)CEC
(cmol/kg)TOC (%) EC (mS/cm) WRC (%) PT (%)
TA 74,87(4,04)a 22,00(1,48)b 16,63(6,60)a 0,20(0,15)a 153,73(11,38)b 6,56(1,14)a
TB 74,83(2,95)a 20,43(4,35)b 12,21(3,98)a 0,13(0,02)a 145,60(12,60)b 7,33(0,04)a
TC 51,60(13,55)b 32,77(3,66)a 20,87(7,87)a 0,21(0,01)a 237,47(66,40)a 0,56(0,24)b
NTC 5167 < 60 >30 >15 - >100 >1
NCh 2880 - - - < 3 - -
Moisture (%) TON (%) pH GI (%) C/N -
TA 30,37(1,81)ab 0,88(0,15)b 7,72(0,10)a 176a 20,00(11,00) -
TB 27,97(2,14)b 0,73(0,03)b 7,80(0,04)a 163ab 16,57(4,74) -
TC 33,87(3,56)a 1,37(0,15)a 7,51(0,07)b 102b 14,93(3,88 -
NTC 5167 <35 >1 >4 - <9 - - -
NCh 2880 30 - 45 > 0,5 5 - 8.5 > 80 < 25 -
Results and DiscussionComposting process
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Introduction
Materials and Methods
Results and Discussion
Conclusions
References 17
Outline
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The bulk density of GW varies considerably due to the typical climatic conditions of the context.
In the institution of higher education UIS, the production of GW is about 732.5 kg per day, whereof 74% (i.e. leaves, branches and grass clippings) can be recycling by composting processes.
Regarding the composting process, TA and TB did not present significant differences (p ≤ 0.05) in most of the evaluated parameters, which allows to affirm that the two-stage composting did not represent time optimization or improvements in the quality of the product.
The PR achieved increasing the phosphorous content in the product; however, it is necessary to decrease the percentage of PR added, due to the fact that possible inhibitions of the process were presented due to the high content applied. TC presented better results in terms of product quality; however, it still has deficiencies in phosphorus content.
Conclusions
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This work was carried out thanks to the support of the Universidad Industrial de Santander (Colombia), through the project 2354 of 2017
Acknowledgments
THANK YOU!
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1. Odlare, M., Arthurson, V., Pell, M., Svensson, K., Nehrenheim, E., Abubaker, J.: Land application of organic waste - Effects on the soil ecosystem. Appl. Energy 88, 2210-2218 (2011)2. Oviedo-Ocaña, E.R., Dominguez, I., Komilis, D., Sánchez, A.: Co-composting of Green Waste Mixed with Unprocessed and Processed Food Waste: Influence on the Composting Process and Product Quality. Waste and Biomass Valorization 10, 63-74 (2019)3. Malakahmad, A., Idrus, N.B., Abualqumboz, M.S., Yavari, S., Kutty, S.R.M.: In-vessel co-composting of yard waste and food waste: an approach for sustainable waste management in Cameron Highlands, Malaysia. Int. J. Recycl. Org. Waste. Agric. 6, 149-157 (2017)4. Wei, Y., Li, J., Shi, D., Liu, G., Zhao, Y., Shimaoka, T.: Environmental challenges impeding the composting of biodegradable municipal solid waste: A critical review. Resour. Conserv. Recycl. 122, 51-65 (2017)5. United States Environmental Protection Agency (USEPA), 2013. Advancing Sustainable Materials Management: 2013 Fact Sheet- Assessing Trends in Material Generation, Recycling and Disposal in the United States. (2015)6. Troschinetz, A.M., Mihelcic, J.R.: Sustainable recycling of municipal solid waste in developing countries. Waste Manag. 29, 915-923 (2009)7. Zhang, L., Sun, X.: Influence of bulking agents on physical, chemical, and microbiological properties during the two-stage composting of green waste. Waste Manag. 48, 115-126 (2016)8. Boldrin, A., Christensen, T.H.: Seasonal generation and composition of garden waste in Aarhus (Denmark). Waste Manag. 30, 551-557 (2010)9. Belyaeva, O.N., Haynes, R.J.: Chemical, microbial and physical properties of manufactured soils produced by co-composting municipal green waste with coal fly ash. Bioresour. Technol. 100, 5203-5209 (2009)10. Bustamante, M.A., Ceglie, F.G., Aly, A., Mihreteab, H.T., Ciaccia, C., Tittarelli, F.: Phosphorus availability from rock phosphate: Combined effect of green waste composting and sulfur addition. J. Environ. Manage.182, 557-563 (2016)11. López, M., Soliva, M., Martínez-Farré, F.X., Bonmatí, A., Huerta-Pujol, O.: An assessment of the characteristics of yard trimmings and recirculated yard trimmings used in biowaste composting. Bioresour. Technol. 101, 1399-1405 (2010)12. Benito, M., Masaguer, A., Moliner, A., De Antonio, R.: Chemical and physical properties of pruning waste compost and their seasonal variability. Bioresour. Technol. 97, 2071-2076 (2006)
References