Page 137 - makedonca
P. 137
microorganisms, and economic benefits. Environ Technol (United Kingdom). 1–13.
https://doi.org/10.1080/09593330.2023.2184728
[80] Maalouf A, Mavropoulos A (2023) Re-assessing global municipal solid waste
generation. Waste Manag Res. 41:936–947.
https://doi.org/10.1177/0734242X221074116
[81] Teshome YM, Habtu NG, Molla MB, Ulsido MD (2023) Municipal solid wastes
quantification and model forecasting. Glob J Environ Sci Manag. 9:227–240.
https://doi.org/10.22034/GJESM.2023.02.04
[82] National, Agricultural, Statistics, Service (2021) Farm Production Expenditures 2020
Summary
[83] (2023) Vermicomposting Online Course.
https://ccclib.bibliocommons.com/events/6480c1360744fbe2fca423ba
[84] DESKU EIACP TEAM Vermicomposting Earthworm Prac
[85] Aquino AU, Baylon DG, Dela Cruz FPB, et al (2019) Development of a Solar-Powered
Closed-Loop Vermicomposting System with Automatic Monitoring and Correction via
IoT and Raspberry Pi Module. In: 2019 IEEE 11th International Conference on
Humanoid, Nanotechnology, Information Technology, Communication and Control,
Environment, and Management, HNICEM 2019. IEEE, pp 1–5
[86] Embalzado E, Samaniego L, Cortez Z, et al (2019) Automated Vermicomposting
System (of Proper Waste Ratio + MCU Vermicomposting Bed). In: 2019 IEEE 11th
International Conference on Humanoid, Nanotechnology, Information Technology,
Communication and Control, Environment, and Management, HNICEM 2019. IEEE,
pp 1–5
[87] Bagali V, Jiddi V, Jahagirdar W (2021) Vermicomposting of Biodegrable Waste: An
Iot based Approach. In: 2021 5th International Conference on Electrical, Electronics,
Communication, Computer Technologies and Optimization Techniques, ICEECCOT
2021 - Proceedings. IEEE, pp 443–447
[88] Mohamed A, Akl AA, Badr MM, et al (2023) Classifying the vermicompost
production stages using thermal camera data. IEEE Access.
https://doi.org/10.1109/ACCESS.2023.3339884
[89] Shalini VB, Maheswari AU, Marimuthu C, Jeshima J (2022) Vermi-Composting using
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