Effect of Adsorbent Mesh Activated Charcoal Bamboo Betung on Coconut Shell Liquid Smoke Purification Process
DOI:
https://doi.org/10.24843/JBETA.2023.v11.i02.p08Keywords:
activated charcoal, adsorbent, dehydration, liquid smoke, purificationAbstract
Liquid smoke is the product of the condensation of burning organic matter by the pyrolysis process. Grade 1 liquid smoke for preservatives is processed through a purification stage with multilevel distillation which takes a long time. This study aims to obtain the quality of coconut
shell liquid smoke grade 1 based on SNI 8985:2021. The liquid smoke purification process uses the dehydration method with bamboo betung activated charcoal as an adsorbent with variations in sizes of 40 mesh, 60 mesh, 80 mesh, and 100 mesh. The parameters observed were water content, ash content, SEM (Scanning Electron Microscopy), acidity (pH), and GC-MS (Gas
Chromotography-Mass Spectroscopy). The results showed that the 40 mesh treatment resulted
in a moisture content of 4.38%, 2.70% ash content, pH 3.3, and a purification time of 87 minutes.
The 60 mesh treatment resulted in a moisture content of 5.78%, ash content of 3.39%, pH of 3.2,
and a purification time of 90 minutes. Treatment of 80 mesh resulted in 5.95% moisture content,
ash content of 4.14%, pH of 3.1, and a purification time of 93 minutes. The 100 mesh treatment
resulted in a moisture content of 6.75%, ash content of 7.50%, pH 3, and a purification time of
100 minutes. The resulting grade 1 liquid smoke contains phenol compounds of 1.94% - 5.14%,
creosol compounds of 5.84% - 15.56%, and acid compounds of 0.11% - 3.47%. The 100 mesh
adsorbent is recommended as a food preservative with the characteristics of a clear color, odorless, pH value of 3.0, phenolic compounds of 5.14%, acidic compounds of 3.27%, and
creosol 15.56%.
References
Adhitya, R., Alimuddin, & Aman, P. S. (2015).
Pemurnian Asap Cair Dari Kulit Durian Dengan
Menggunakan Arang Aktif. Journal of the
Japanese Society of Pediatric Surgeons, 10(2),
112–120.
https://doi.org/10.11164/jjsps.4.1_156_2
Ayu, P. R., Nyoman, U. G. I., & A.A.A, D. S. W.
(2018). Analisis Potensi Ketersediaan Tanaman
Bambu dan Pemasaran Kerajinan Bambu di
Desa Kayubihi Kecamatan Bangli Kabupaten
Bangli. Agribisnis Dan Agrowisata, 7(3).
https://doi.org/10.33140/tapi1
Badan Standardisasi Nasional - BSN. (1995). Standar
Nasional Indonesia untuk Arang Aktif Teknis
SNI 06-3730-1995. 20.
Badan Standardisasi Nasional (BSN). (2021). Crude
Asap Cair Lignoselulosa sebagai Bahan Baku
(SNI 8985 : 2021 ). 1–24.
Baird, Z. S., Uusi-Kyyny, P., Pokki, J. P., Pedegert,
E., & Alopaeus, V. (2019). Vapor Pressures,
Densities, and PC-SAFT Parameters for 11 Bio
compounds. In International Journal of
Thermophysics (Vol. 40, Issue 11). Springer
US. https://doi.org/10.1007/s10765-019-2570-9
Diharyo, Salampak, Zafrullah, D., & Sulmi, G.
(2020). Pengaruh lama aktifasi dengan H3PO4
dan ukuran butir arang cangkang kelapa sawit
terhadap ukuran pori dan luas permukaan butir
arang aktif. Prosiding Seminar Nasional
Lingkungan Lahan Basah, 5(1), 48–54.
Fardiansyah, H. (2017). Pemanfaatan Media Bambu
Sebagai Adsorbent Penyerap Logam Kadmium
(Cd) dengan Perbandingan Tanpa Aktivasi dan
Aktivasi dengan Asam Sitrat. Skripsi. Publikasi.
Fakultas Teknik Sipil Dan Perencanaan UII,
Yogyakarta.
Fauzan, F., & Ikhwanus, M. (2017). Pemurnian Asap
Cair Tempurung Kelapa Melalui Distilasi dan
Filtrasi Menggunakan Zeolit dan Arang Aktif.
Prosiding Semnastek, p-ISSN : 2407 – 1846, 1
2.
Herlina, P. K., Yoel, P., & Gazali-AI. (2020).
Pemanfaatan arang aktif dari bambu untuk
pengolahan limbah cair. Saintis, 1(2).
Jamilatun, S., & Salamah, S. (2015). Peningkatan
Kualitas Asap Cair Dengan Menggunakan
Arang Aktif Sntt Fgdt 2015. Simposium Nasional Teknologi Terapan (SNTT), 3, 1–6.
Jamilatun, S., Salamah, S., Aslihati, L., & Suminar,
W. (2016). Pengaruh Perendaman Ikan Nila
Dengan Asap Cair ( Liquid Smoke ) Terhadap
Daya Simpan. Seminar Nasional Sains Dan
Teknologi, November 2016, 1–8.
Lestari, E. S., Hadi, Y. S., & Pari, G. (2019).
Pemanfaatan Campuran Arang Aktif Kayu
Muntingia calabura L. dan Bakteri Escherichia
coli pada Pengolahan Limbah Kromium
Industri Elektroplating. Jurnal Penelitian Hasil
Hutan, 37(2), 105–122.
Nafi’ah, R. (2016). Kinetika Adsorpsi Pb ( II ) dengan
Adsorben Arang Aktif dari Sabut Siwalan.
Jurnal Farmasi Sains Dan Praktis, I(2), 28–37.
Nurrahmad, F. A., & Khalimatus, S. (2022).
Pengaruh Jenis Dan Rasio Penambahan
Adsorben Pada Pemurnian Asap Cair. Distilat:
Jurnal Teknologi Separasi, 8(1), 18–27.
https://doi.org/10.33795/distilat.v8i1.293
Sanjaya, A. S., & Agustine, R. P. (2015). Studi
Kinetika Adsorpsi Pb Menggunakan Arang
Aktif Dari Kulit Pisang. Konversi, 4(1), 17.
https://doi.org/10.20527/k.v4i1.261
Saputra, R. Y., Naswir, M., & Suryadri, H. (2020).
Perbandingan Karakteristik Asap Cair Pada
Berbagai Grade Dari Pirolisis Batubara. Jurnal
Engineering,
2(2),
96–108.
https://doi.org/10.22437/jurnalengineering.v2i2
.11531
Septian, F. D., & Nur, M. M. N. (2020). Kajian
Pengaruh Pemurnian Asap Cair dengan Metode
Distilasi dan Adsorpsi Menggunakan Zeolit
Alam. 1(2), 2–5.
Seri, M., & Feni, P. S. (2017). Pengaruh Suhu,
Waktu, Dan Kadar Air Bahan Baku Terhadap
Pirolisis Serbuk Pelepah Kelapa Sawit. Jurnal
Teknik
Kimia
USU,
6(2),
35–40.
https://doi.org/10.32734/jtk.v6i2.1581
Setyarini, H. D., Apriani, M., & Cahyono, L. (2021).
Karakterisasi Adsorben dari Ampas Teh Tanpa
Aktivasi dan Teraktivasi. l(2623), 156–159.
Shinta, N. Y. S., & Sinar, A. A. P. (2018). Pemurnian
Asap Cair Terhadap Kinerja Reaktor Pirolisis
Melalui Proses Filtrasi Zeolit Aktif. Prosiding
Seminar
Nasional
Teknologi
Industri,
Lingkungan Dan Infrastruktur, 1(September),
1–6.
Thuroihan Aminulloh. (2020). Pembuatan Asap Cair
Grade 1 Berbahan Limbah Tempurung Kelapa
Sebagai Bahan Pengawet. Skripsi. Publikasi.
Program Studi Budi Daya Tanaman
Hortikultura
Politeknik
Peternakan Mapena, Tuban.
Pertanian
dan
Walangare, K. B. A., Lumenta, A. S. M., Wuwung, J.
O., & Sugiarso, B. A. (2013). Rancang Bangun
Alat Konversi Air Laut Menjadi Air Minum Dengan
Proses
Destilasi
Sederhana
Menggunakan Pemanas Elektrik. Jurnal Teknik
Elektro
Dan
Komputer,
2(2).
https://ejournal.unsrat.ac.id/index.php/elekdank
om/article/view/1786
Wirawan, I. P.S., Sutrisno, S., Seminar, K. B., &
Nelwan, L. O. (2018). Characteristics of
Microactive Carbon from Bamboo Var. Petung
as Adsorbent. IOP Conference Series: Earth
and
Environmental
Science,
1315/147/1/012028
147(1).
Wirawan, I. Putu Surya, Mardjan, S. S., Seminar, K.
B., & Nelwan, L. O. (2018). Purification of
bioethanol with bamboo activated carbon as
adsorben. International Journal of Scientific
and Technology Research, 7(12), 166–169.
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