Article Sidebar

Submitted
Oct 19, 2020
Accepted
Dec 22, 2020
Published
Dec 26, 2020
Download
PDF
Statistic
Read Counter : 1356 Download : 1002

Downloads

Download data is not yet available.

Main Article Content

Abstract

Setiap tahun produksi plastik meningkat secara eksponensial, karena kebutuhannya sangat diperlukan oleh manusia. Tapi plastik berbeda dengan limbah yang lain, disebabkan oleh proses penguraiannya. Guna mengurangi populasi limbah plastik, kegiatan pengabdian kepada masyarakat di desa Wari Ino menitik beratkan pada sosialisasi masalah limbah plastik dan teknik pengolahan. Adapun hasil kegiatan menunjukan perubahan pengetahuan akan bahaya limbah plastik dan penerapan teknologi tepat guna menggunakan sistem pirolisis mampu menghasilkan BBM (Bahan Bakar Minyak) dari plastik jenis HDPE (High Density Polyethylene). Tapi teknologi tersebut masih bersifat prototipe, dan memerlukan pengembangan sehingga dapat dipakai serta diakui oleh seluruh masyarakat secara luas.

Keywords

Plastik Wari Ino Pirolisis Teknologi

Article Details

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Author Biographies

Masitah Yusniar, Universitas Halmahera

Matematika

Meidy Kaseside, Universitas Halmahera

Matematika

Samsul Bahri Loklomin, Universitas Halmahera

Matematika

Trifena Punana Lesnussa, Universitas Halmahera

Matematika

How to Cite
Masitah Yusniar, Meidy Kaseside, Samsul Bahri Loklomin, Trifena Punana Lesnussa, Yunius M Samalukang, & Nikolaus Dalengkade, M. (2020). Prototipe Penerapan Teknologi Tepat Guna Pengolahan Limbah Plastik Berbasis Sistem Pirolisis . CARADDE: Jurnal Pengabdian Kepada Masyarakat, 3(2), 319-327. https://doi.org/10.31960/caradde.v3i2.627
Download Citation
Endnote/Zotero/Mendeley (RIS)
BibTeX

References

  1. PE. (2016). Plastics Europe, Association of Plastics Manufacturers, An Analysis of European plastics, Demand and Waste Data.
  2. Miandad, R., Barakat, M, A., Aburiazaiza, A, S., Rehan, M., & Nizami, A, S. (2016). Catalytic Pyrolysis of Plastic Waste: A review. Process Safety and Environmental Protection, 102(2016), 822-838.
  3. Vanapalli, K, R., Sharma, H, B., Ranjan, V, P., Samal, B., Bhattacharya, J., Dubey B, K., & Goel, S. (2020). Challenges and Strategies for Effective Plastic Waste Management During and Post COVID-19 Pandemic. Science of the Total Environment 750(141514), 1-10.
  4. Duis, K., & Coors, A. (2016). Microplastics in the Aquatic and Terrestrial Environment: Sources (with a specifc focus on personal care products), Fate and Effects. Duis and Coors Environ Sci Eur, 28(2), 2-25.
  5. Roch, S., friedrich, C., & Brinker, A. (2020) Uptake Routes of Microplastics in Fishes: Practical and Theoretical Approaches to Test Existing Theories. Scientific Reports, 10:3896, https://doi.org/10.1038/s41598-020-60630-1
  6. Talley, T, S., Venuti, N., & Whelan, R. (2020). Natural History Matters: Plastics in Estuarine Fish and Sediments at the Mouth of An Urban Watershed. Plos One, 15(3), 1-9.
  7. Dalengkade, M, N. (2019). Pemodelan Reaksi Suhu Udara terhadap Penyinaran Cahaya Matahari dalam Hutan Bakau. Barekeng, 13(2), 061-068.
  8. Dalengkade, M, N. (2020a). Profil 24 Jam Kuat Penerangan, Suhu Udara, Kelembaban Udara di Luar dan di dalam Hutan Mangrove. Barekeng, 14(1), 047-058.
  9. Dalengkade, M, N. (2020b). Fluktuasi Temporal Kelembaban Udara di Dalam dan Luar Ekosistem Mangrove. Barekeng, 14(2), 159-166.
  10. Geyer, R., Jambeck, J, R., & Law, K, L. (2017). Production use and Fate of All Plastics Ever Made. Science Advances, 3(7), 1-5.
  11. Royer, S, J., Ferron, S., Wilson, S, T., Karl, D, M. (2018). Production of Methane and Ethylene from Plastic in the Environment. Plos Ones, 13(8), 1-13.
  12. Dwivedi, P., Mishra, P, K., Mondal, M, K., & Srivastava, N. (2019). Non-Biodegradable Polymeric Waste Pyrolysis for Energy Recovery. Heliyon, 5(8), 1-15.
  13. Abnisa, F., Sharuddin, S, D, A., Zanil, M, F, B., Daud, W, M, A, W., & Mahlia, T, M, I., (2019). The Yield Prediction of Synthetic Fuel Production from Pyrolysis of Plastic Waste by Levenberg-Marquardt Approach in Feedforward Neural Networks Model. Polymers, 11(11), 1-16.
  14. Yousef, S., Eimontas, J., Striugas, N., & Abdelnaby, M, A. (2020). Modeling of Metalized Food Packaging Plastics Pyrolysis Kinetics Using an Independent Parallel Reactions Kinetic Model. Polymer, 12(8), 1-14.
  15. Antelava, A., Damilos, S., Hafeez, S., Manos, G., Al-Salem, S, M., Sharma, B, K., Kohli, K., & Constantinou, A. (2019). Plastic Solid Waste (PSW) in the Context of Life Cycle Assessment (LCA) and Sustainable Management. Environmental Management, 64(2),230-244.
  16. Quadri, M, W., & Dohare, Er, D. (2020). A Study to Optimise Plastic to Fuel Technology-A Review. IJERT, 9(4),190-222.
  17. Silva, N, N, D., Pinto, F, R., Alencar, D, B, D., Parente, R, S. (2019). Transformation of Plastic Waste into Fuel by Pyrolysis. International Journal for Innovation Education and Research, 7(11), 628-636.
  18. Bungay, V, C. (2017). Kinetic Study on the Pyrolysis and Gasification of Plastic Waste. Chemical Engineering Transactions, 56(32), 193-198.

Most read articles by the same author(s)