Abstract. ANG technology generally uses materials or carbon materials known as active carbon. Adsorbed Natural Gas (ANG) is one technique of natural gas storage in porous solid media. The solids that are used in the form of carbon materials with certain specifications so that it can absorb and store methane gas at room temperature and pressure state relative (low 93.5 to 4.0 MPa). ANG technology is the best storage technology for methane gas because the gas can be stored at room temperature and atmospheric pressure. Therefore, to improve the adsorption capability of the methane gas, in addition to the choice of raw materials also need to learn the activation method. In order to improve the quality of activated carbon to the sub-bituminous coal C type with chemical activation by mixing semikokas and the activation ingredients with ratio of 1: 3, that is 10 gr semikokas 30 gr activativation ingredients and testing of  iodine numbers which gained the highest yield at a temperature of 800^oC for 60 minutes at 1197.6 mg/gr. Coal can be used not only as fuel but can also absorb gases at ANG so as to provide added value to minerals, especially coal. Coal activated carbon with iodine 656 mg/gr has a surface area of 491 m²/ g. With This, if the activated carbon has 1197 mg/gr, the surface area of activated carbon can be assumed to 1242,4 m²/gr. The ability to absorb and store the methane gas is 99,9 mg/gr.

 

Abstrak. Teknologi ANG umumnya menggunakan material atau bahan karbon yang dikenal dengan karbon aktif. Adsorbed natural gas (ANG) merupakan salah satu teknik penyimpanan gas alam dalam media padatan berpori. Padatan yang digunakan berupa bahan karbon dengan spesifikasi tertentu sehingga dapat menyerap serta menyimpan gas metana pada keadaan suhu kamar dan tekanan yang relatif (rendah 93,5-4,0 Mpa). Teknologi ANG merupakan teknologi penyimpanan yang terbaik untuk gas metana karena gas dapat disimpan pada suhu kamar dan tekanan atmosfir. Oleh karena itu, untuk meningkatkan kemampuan adsorpsi terhadap gas metana, selain pemilihan jenis bahan baku juga perlu mempelajari metoda aktivasinya. Untuk dapat meningkatkan kualitas karbon aktif pada batubara sub-bituminus tipe C dilakukan metoda aktivasi kimia pencampuran semikokas dan bahan pengaktif yaitu dengan rasio 1 : 3, yaitu 10 gr semikokas 30 gr bahan pengaktif dan dilakukan pengujian bilangan Iodin yang dimana diperoleh hasil tertinggi pada suhu 800^oC selama 60 menit sebesar 1197,6 mg/gr. Batubara tidak hanya dapat dimanfaatkan sebagai bahan bakar tetapi dapat juga menyerap gas pada ANG sehingga dapat memberikan nilai tambah terhadap bahan tambang khususnya batubara. Karbon aktif batubara dengan bilangan iodin 656 mg/gr memiliki luas permukaan 491 m²/gr. Dengan demikian, jika karbon aktif memiliki bilangan iodin 1197 mg/gr. Karbon aktif dengan luas permukaan bsebesar 1242,4 m²/gr dengan kemampuan untuk menyerap dan menyimpan gas metana yaitu 99,9 mg/gr.

Abdullah, R., dan Wahidin. 2015. Pembuatan Karbon Aktif Dari Batubara Untuk Adsorbed Natural Gas. Teknik Kimia POLBAN. Bandung

Alson, J.A., Adler, J.M., dan Baines, T.M. 1989. Alternative Transportation Fuel. New York.

Anonim. 1981. ASTM D 388 – 77: Standard Specification For Classification Of Coals by Rank. United State : ASTM International

Anonim, 2014. Buku Panduan PT Bukit Asam Persero Tbk Tanjung Enim. Tanjung Enim. PT Bukit Asam Persero Tbk

Anonim, (BSN) Badan Standar Nasional. 1995. “SNI 06-3730.1995. Arang Aktif Teknisâ€. Jakarta : BSN (SNI 06-3730.1995)

Apriyahanda, Onny. 2015. Mengenal Compressed Natural Gas dan Manfaatnya. Energi Today. Jakarta

Arami, Arash, 2012. Production of microporous palm shell based activated carbon for methane adsorption: Modeling and optimization using response surface methodology, chemical engineering research and design.

Kumar, Abhishankar, 2011. Adsorpsoin Of Methane On Activated Carbon By Volumetric Method. Department Of Chemical Engineering National Institude Of Technology. Rourkela

Matar, S & Hatch L. F. 1994. Proses petrokimia edisi ke-2. Houston, Texas : Gulf Publishing Company.

Menon, V.C., Komarneni, S. 1998. Porous adsorbents fof vehicular natural gas storage : a review, dalam Journal of Porous Materials.

Milan. Smisek, 1970, “Manufacture of active carbonâ€, Applications of active carbon Chapters 2 and 5 in Active Carbon Milan Smisek and Slovoj Cerny, Editors Elsevier Amsterdam-London-New York pp 42 & 256-257.

Monika, Ika., dan Hernawati, T., 2010. Pengukuran Valume dan Ukuran Pori-Pori Karbon Aktif dari Batubara Airlaya. Prosiding Seminar Teknik Kimia Universitas Parahyangan. Bandung

Muchjidin, 2006. Pengendalian Mutu Dalam Industri Batu Bara. Bandung : Penerbit ITB.

R.M. Suzuki, dkk, 2007. Preparation and Characterization of Activated Carbon from Rice Bran. Departemen of Chemistry, Universidade Estadual de Maringo, Brazil.

Satish, M, Manocha. 2003. Porous Carbons. Sadana Vol. 28, part 1 & 2.

Speight, J. G. 2007. Natural gas : a basic handbook. Houston, Texas : Gulf Publishing Company.

Viswanathan, B et al. 2009. Methods of Activation and Specific Applications of Carbon Materials. Chennai : National Centre for Catalysis Research Department of Chemistry Indian Institute of Technology Madras.

World Coal Institute. 2005. Sumber daya batubara : tinjauan lengkap mengenai batubara.

Zakaria, Z, dkk. 2006. The development of adsorbent based natural gas storage for vehicle application. Department of Chemical Engineering Faculty of Chemical and Natural Resources Engineering Universitas Teknologi Malaysia.