Utilization of Tar Waste from the Gasification Process of Landfill Waste as a Disinfectant

Pramadaningtyas, Putri Segi; Rachmawati, Siti; Setyono, Prabang; Himawan, Widhi

doi:10.12911/22998993/169960

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Tytuł artykułu

Utilization of Tar Waste from the Gasification Process of Landfill Waste as a Disinfectant

Autorzy

Pramadaningtyas Putri Segi , Rachmawati Siti , Setyono Prabang , Himawan Widhi

Treść / Zawartość

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28_pramadaningtyas_utilization_jee_10_2023.pdf

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Identyfikatory

DOI

10.12911/22998993/169960

Warianty tytułu

Języki publikacji

Abstrakty

Gasification is a combustion process that can converts waste into electricity. Tar waste is liquid waste from the gasification process that has not been managed and utilized. Tar waste contains toxic compounds that can pollute the environment if they enter it. Tar waste has the potential to be used as a raw material for disinfectants because it contains phenol and polycyclic aromatic hydrocarbon (PAH) compounds This study aims to determine the potential of tar waste as a disinfectant based on antibacterial activity tests and phenol coefficient tests with Salmonella typhimurium bacteria. Tar waste was tested for its antibacterial activity to determine the effective concentration between with concentrations of 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90% and 100% that has the potential to be an active ingredient in disinfectants. The effectiveness of the disinfectant was measured by the coefficient value of tar waste compared to 5% phenol against the Salmonella typhimurium test bacteria. If the coefficient value is equal to or greater than 1, it is said that tar waste is effectively used as a disinfectant. The results showed that the effective concentration of tar waste as a raw material for disinfectant through the antibacterial activity test was 100% with an inhibition zone diameter of 0.275556 mm in the weak category. The phenol coefficient value of 100% tar waste is 0.05. The conclusion of this study is that tar waste with a concentration of 100% is not yet effective as a raw material for disinfectant according to SNI 1842:2019.

Słowa kluczowe

tar disinfectant antibacterial phenol coefficient

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2023

Tom

Vol. 24, nr 10

Strony

315--323

Opis fizyczny

Bibliogr. 40 poz., rys., tab.

Twórcy

autor

Pramadaningtyas Putri Segi

Faculty of Mathematics and Science Department of Environmetal Science, Sebelas Maret University, Surakarta City, Indonesia

autor

Rachmawati Siti

siti.rachmawati@staff.uns.ac.id

Faculty of Mathematics and Science Department of Environmetal Science, Sebelas Maret University, Surakarta City, Indonesia

https://orcid.org/0000-0001-6566-0374

autor

Setyono Prabang

Faculty of Mathematics and Science Department of Environmetal Science, Sebelas Maret University, Surakarta City, Indonesia

autor

Himawan Widhi

Faculty of Mathematics and Science Department of Environmetal Science, Sebelas Maret University, Surakarta City, Indonesia

Bibliografia

1. Agustina, W., Sumpono, S., Elvia, R. 2017. Aktivitas Asap Cair Cangkang Buah Hevea Braziliensis Sebagai Anti Bakteri Staphylacoccus aureus. Alotrop, 1(1).
2. Ahmad, F. 2012. Kandungan Senyawa Polisiklik Aromatik Hidrokarbon (PAH) di Teluk Jakarta (Polycyclic Aromatic Compounds Hydrocarbons (PAH) Content in Jakarta Bay). ILMU KELAUTAN: Indonesian Journal of Marine Sciences, 17(4), 199–208.
3. Ajizah, A. 2004. Sensivitas Salmonella typhimurium Terhadap Ekstrak Daun Psidium guajava L. Bioscientiae, 1(1), 31–38.
4. Alawi, M.A., & Azeez, A.L. 2016. Study of polycyclic aromatic hydrocarbons (PAHs) in soil samples from Al-Ahdab oil field in Waset Region, Iraq. Toxin Reviews, 35(3–4), 69–76.
5. Arbain, A., Mardana, N.K., & Sudana, I.B. 2009. Pengaruh Air Lindi Tempat Pembuangan Akhir Sampah Suwung terhadap Kualitas Air Tanah Dangkal di Sekitarnya di Kelurahan Pedungan Kota Denpasar. Ecotrophic, 3(2), 387818.
6. Budiarti, L. Y., Wydiamala, E., & Ulfa, N. 2021. Phenol Coefficient Test Combination Infusion of Cananga odorata–Averrhoa bilimbi L. Against Staphylococcus aureus and Salmonella typhi in Vitro. Bioinformatics and Biomedical Research Journal, 4(1), 19–26.
7. Chan, W.P., S.A.M.B. Yusoff, A. Veksha, A. Giannis, T.T. Lim, & G. Lisak. 2020. Analytical Assasment of Tar Generated during Gasification of Municipal Solid Waste: Distribution og GC-MS detectetable Tar Compounds, Undetectable Tar Residues and Inorganic Impurities. Fuel. 268, 1–10.
8. Dewanto, D.K., Hermawan, R., Muliadin, M., Riyadi, P.H., Aisiah, S., & Tanod, W.A. 2021. Profil GC-MS dari ekstrak daun Rhizophora apiculata dari pesisir Teluk Tomini, Sulawesi Tengah dengan aktivitas antibakteri dan antioksidan. Jurnal Kelautan: Indonesian Journal of Marine Science and Technology, 14(1), 30–42.
9. Edward, E. 2017. Pengamatan kadar senyawa polisiklik aromatik hidrokarbon (pah):(benzo [a] pyren, benzo [a] antrasen, Benzo [b] fluoranten, di-benzo [a, h] antrasen, Dan benzo [g, h, i] perylen) dalam air laut di Teluk Jakarta. Jurnal Kelautan: Indonesian Journal of Marine Science and Technology, 10(2), 113–128.
10. Fahruddin. 2010. Bioteknologi Lingkungan. Bandung:Alfabeta.
11. Faruq, U.I. 2016. Studi potensi limbah kota sebagai pembangkit listrik tenaga sampah (PLTSa) Kota Singkawang. Jurnal Teknik Elektro Universitas Tanjungpura, 2(1).
12. Hasan, N.Y.. 2020. Senyawa Toksik Pencemar Udara: Polycyclic Aromatik Hydrocarbon (PAHs). Jurnal Rekayasa Lingkungan. 8(2), 67–77.
13. Hafeza, D., Novalina, D., & Wicaksana, A.Y. 2021. Experimental Study Antibakteri Produk Disinfektan Metode Dilusi (Doctoral dissertation, Universitas’ Aisyiyah Yogyakarta).
14. Haji, A.G., Mas’ud, Z.A., Lay, B.W., Sutjahjo, S.H., & Pari, G. 2006. Karakterisasi Asap Cair Hasil Pirolisis Sampah Organik Padat (Characterization of Liquid Smoke Pyrolyzed from Solid Organic Waste). Jurnal Teknologi Industri Pertanian, 16(3).
15. Harman, D.A. 2013. Efektivitas anti bakteri ekstrak daun sirih (piper betle l.) terhadap bakteri enterococcus faecalis (penelitian in vitro). Skripsi. Makassar:Universitas Hasanudin.
16. Hidayati, Z., & Syafitri, L.N. 2021. Pengadaan Poster Edukasi Covid-19 Dan Pelatihan Pembuatan Disinfektan Di Pondok Pesantren Al-Fattah Siman Lamongan. TA’AWUN, 1(01), 63–81.
17. Irianto, K. 2007. Mikrobiologi Umum. Bandung:CV Yrama Widya.
18. Khaira, A. 2016. Penentuan koefisien fenol pembersih lantai Dengan kandungan benzalkonium klorida 1, 5% Terhadap bakteri Pseudomonas aeruginosa (Bachelor›s thesis, Fakultas Kedokteran Universitas Islam Negeri Syarif Hidayatullah Jakarta).
19. Manarisip, T., Yamlean, P.V., & Lolo, W.A. 2019. Formulasi Dan Uji Efektivitas Antibakteri Sediaan Gel Ekstrak Etanol Daun Kersen (Muntingia calabura L.) Sebagai Antiseptik Tangan. Pharmacon, 8(3), 580–590.
20. Mayachiew, P., dan Devahastin, S. 2008. Antimicrobial andantioxidant activities of Indian gooseberry and galangalextract. LWT-Food Science and Technology, 41, 1153–1159.
21. Musafira, F., Qadrini, L., Fatimah, M.F., & Ardiputra, S. 2020. Edukasi Pembuatan dan Penyemprotan Desinfektan pada Masyarakat di Desa Suruang Kecamatan Campalagian Kabupaten Polewali Mandar. Community Development Journal: Jurnal Pengabdian Masyarakat, 1(3), 416–421.
22. Nurfadhilah, I., Marliana, L., Lutfiah, L., & Zahra, S.F. 2022. Optimasi Pembangkit Listrik Tenaga Sampah Berbasis Teknologi Co-Gasifikasi Thermal dengan Refuse Derived-Fuel sebagai Solusi Permasalahan Sampah dan Lingkungan. COMSERVA Indonesian Jurnal of Community Services and Development, 1(10), 850–858.
23. Paudel, B., Bhattarai, H.D., Kim, I.C., Lee, H., Sofronov, R., Ivanova, L., Poryadina, L., & Yim, J.H. 2014. Estimation of antioxidant, antimicrobial activity and brine shrimp toxicity of plants collected from Oymyakon region of the republic of Sakha (Yakutia), Russia. Biological Research, 47(1), 1–6.
24. Prando, D., S.S. Ail, D. Chiaramonti, M. Baratieri, & S. Dasappa. 2016. Characterisation of the Producer Gas From an Open Top Gasifier: Assessment of Different TAR Analysis Approaches. Fuel, 181, 566–572.
25. Rachmawani, D., Yulianda, F., Kusmana, C., Boer, M., & Parwati, E. 2016. Dampak Hidrokarbon Aromatik Terhadap Ekosistem Mangrove Di Kawasan Binalatung Kota Tarakan Kalimantan Utara (Impact of Aromatic Hydrocarbon on Mangrove Ecosystem in Binalatung Area Tarakan City North Kalimantan). Jurnal manusia dan Lingkungan, 23(3), 295–303.
26. Rahma, E. 2015.Penetuan Koefisien Fenol Pembersih Lantai yang Mengandung Pine Oil 2, 5% terhadap Pseudomonas aeruginosa. (Bachelor’s thesis, Fakultas Kedokteran Universitas Islam Negeri Syarif Hidayatullah Jakarta).
27. Rachmawani, D., Yulianda, F., Kusmana, C., Boer, M., & Parwati, E. 2016. Dampak Hidrokarbon Aromatik Terhadap Ekosistem Mangrove Di Kawasan Binalatung Kota Tarakan Kalimantan Utara (Impact of Aromatic Hydrocarbon on Mangrove Ecosystem in Binalatung Area Tarakan City North Kalimantan). Jurnal manusia dan Lingkungan, 23(3), 295–303.
28. Rialita, T., Rahayu, W. P., Nuraida, L., & Nurtama, B. 2015. Aktivitas antimikroba minyak esensial jahe merah (Zingiber officinale var. Rubrum) dan lengkuas merah (Alpinia purpurata K. Schum) terhadap bakteri patogen dan perusak pangan. Agritech, 35(1), 43–52.
29. Siagian, K.J. 2016. Eliminasi Kandungan Tar pada Gasifikasi Tandan Kosong Kelapa Sawit. Skripsi. Padang:Universitas Andalas.
30. Siregar, I. P. 2020. Studi Pemanfaatan Water Aromatic/Hidrosol Sereh Wangi dalam Pembuatan Kosmetik Face Toner. Prosiding Pendidikan Teknik Boga Busana, 15(1).
31. SNI 6 1842: 2019. Cairan Disinfektan Pembersih Lantai. Badan Standar Nasional:Jakarta.
32. Suhara, N.A., Mauludiyah, E.N., Suhara, N.A., & Maulana, I.T. 2020. Isolasi Fraksi Senyawa Aktif Antibakteri Staphylococcus epidermidis Dari Chlorella vulgaris B Sebagai Bahan Aktif antiseptik. Jurnal Ilmiah Farmasi Farmasyifa, 3(1), 18–25.
33. Suryani, N., Nurjanah, D., & Indriatmoko, D.D. 2019. Aktivitas antibakteri ekstrak batang kecombrang (Etlingera elatior (Jack) RM Sm.) terhadap bakteri plak gigi streptococcus mutans. Jurnal Kartika Kimia, 2(1), 23–29
34. Tambun, R., Limbong, H.P., Pinem, C., & Manurung, E. 2016. Pengaruh ukuran partikel, waktu dan suhu pada ekstraksi fenol dari lengkuas merah. Jurnal Teknik Kimia USU, 5(4), 53–56.
35. Vidian, F. 2008. Gasifikasi Tempurung Kelapa Menggunakan Updraft Gasifier Pada Beberapa Variasi Laju Alir Udara Pembakaran. Jurnal Teknik Mesin, 10(2), 88–93.
36. WHO. 2002. Prevention of hospital-acquired infections. Diambil dari http://apps.who.int/iris/bitstream/handle/10665/67350/WHO_CDS_CSR_EPH_2002.12.pdfua=1;jsessionid=078B922346A27A014DE1B99078DBFA1A?sequence=1.
37. Yana, S., & Badaruddin, B. 2017. Pengelolaan Limbah Plastik Sebagai Upaya Pengurangan Pencemaran Lingkungan Melalui Transformasi Yang Memiliki Nilai Tambah Ekonomi. Jurnal Serambi Engineering, 2(4).
38. Yogafanny, E. 2015. Pengaruh aktifitas warga di sempadan sungai terhadap kualitas air Sungai Winongo. Jurnal Sains & Teknologi Lingkungan, 7(1), 29–40.
39. Yuliati, F., & Susanto, H. 2018. Kajian pemanfaatan arang sekam padi aktif sebagai pengolah air limbah gasifikasi. Jurnal Teknik Kimia Indonesia, 10(1), 9–17.
40. Zeng, X., Y. Ueki, R. Yoshiie, I. Naruse, F. Wang, Z. Han, & G.Xu. 2020. Recent Progress in TAR Removal by Char and the Aplications : A Comprehensive Analysis. Carbon Resources Conversion, 3, 1–18.

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Bibliografia

Identyfikator YADDA

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