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"Penelitian ini dilakukan untuk mengetahui pemanfaatan potensi sampah organik di Pasar Induk Kramat Jati sebagai bahan baku biogas, menentukan teknologi konversi, menghitung kapasitas energi listrik dari PLT Biogas yang dapat dibangkitkan dan menganalisa kelayakan ekonomi penerapan teknologi konversi gas engine dan gas turbin engine sebagai teknologi konversi pembangkit listrik tenaga biogas. Berdasarkan hasil perhitungan dan analisis, potensi harian sampah organik di Pasar Induk Kramat Jati yang dapat dimanfaatkan sebagai bahan baku biogas sebesar 111,7 ton/hari, produksi metan yang dihasilkan sebesar 9.299,3 m3/hari, hasil analisa penerapan teknologi konversi pembangkit menggunakan gas engine menghasilkan produksi listrik sebesar 11.728.986,5 kWh/tahun, net present value sebesar Rp. 1.493.811.495, IRR 11,81 % dan payback period 8,24 tahun, sedangkan dengan gas turbin engine menghasilkan produksi listrik sebesar 9.648.000 kWh/tahun, net present value sebesar Rp. 2.357.612.207, IRR 12,13 % dan payback period 8,04 tahun.

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This research was conducted to determine the potential utilization of organic waste in the Pasar Induk Kramat Jati biogas as a raw material, determine the conversion technology, to calculate the capacity of electricity from DG Biogas can be generated and analyzed the economic feasibility of conversion technology application of gas turbine engines and gas engines as power conversion technology biogas power plant. Based on the calculation and analysis, the potential of organic waste daily in the Market Master Jati Kramat that can be utilized as raw material for biogas amounted to 111.7 tons / day, the production of methane generated at 9299.3 m3/day, application analysis of power conversion technologies using gas engines generate electricity production amounted to 11.728.986,5 kWh/year, net present value of Rp. 1.493.811.495, IRR 11,81 % and the payback period is 8,24 years, while the gas turbine engine produce electricity amounted to 9.648.000 kWh/year, net present value of Rp. 2.357.612.207, IRR 12,13 % and the payback period is 8,04 years."

"Air limbah industri tapioka diketahui masih memiliki kandungan bahan organik yang masih cukup tinggi, sehingga sangat berpotensi menimbulkan pencemaran lingkungan apabila tidak ditangani secara baik. Padahal air limbah tersebut sangat potensial diolah menjadi bahan baku biogas untuk dikonversi menjadi energi listrik, melalui proses fermentasi anaerobik. Penelitian ini dilakukan untuk menganalisis pemanfaatan potensi limbah cair tapioka untuk pembangkit listrik tenaga biogas, dengan menentukan teknologi konversi yang digunakan, menghitung kapasitas energi listrik yang dapat dibangkitkan, serta menganalisa kelayakan ekonomi penerapan teknologi konversi gas engine sebagai teknologi konversi pembangkit listrik tenaga biogas. Berdasarkan hasil perhitungan dan analisis, potensi limbah cair tapioka dapat dimanfaatkan sebagai bahan baku biogas, dengan produksi metan yang dihasilkan sebesar 95.475 m3 per tahun, dengan penerapan teknologi konversi pembangkit menggunakan gas engine dapat memproduksi energi listrik sebesar 358.604,1 kWh/tahun, dengan net present value sebesar Rp. 833.220.569,-, IRR 19,2% dan payback period 8,7 tahun.

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Tapioca industrial waste water is known to still contain organic material that is still quite high, so it is potentially cause environmental pollution if not handled properly. Whereas the very potential of wastewater processed into raw material for biogas is converted into electric power, through a process of anaerobic fermentation.

This research was conducted to analyze the utilization potential of tapioca liquid waste to biogas power plant, by specifying the conversion technology used, calculating the capacity of electrical energy that can be raised, as well as analyze the economic feasibility of the application of gas engine conversion technology as conversion technology is biogas power plant.

Based on the calculation and analysis, potential tapioca liquid waste can be used as raw material for biogas, methane generated by the production of 95 475 m3 per year, with the application of the conversion technology uses a gas engine generator to produce electrical energy by 358,604.1 kWh / year, with a net the present value of Rp. 833 220 569, -, IRR of 19.2% and a payback period of 8.7 years."

"ABSTRAKRasio elektrifikasi di Provinsi Jambi merupakan yang terendah di Sumatera dengan rasio eletrifikasi sebesar 39,59 . Dibutuhkan adanya tambahan energi listrik di daerah Jambi, terutama di daerah yang belum terjangkau energi listrik salah satunya adalah dengan memanfaatkan biogas yang berasal dari limbah cair pengolahan kelapa sawit atau sering disebut Palm Oil Mill Effluent POME , menjadi energi listrik. Sebagaimana diketahui kelapa sawit merupakan komoditas perkebunan yang terbesar di jambi, limbah cair dari pengolahan kelapa sawit masih belum dimanfaatkan hanya ditampung pada kolam terbuka yang dapat menyebabkan terbentuknya emisi gas rumah kaca. Pada penelitian ini akan digunakan data-data dari salah satu perkebunan kelapa sawit di Jambi, dengan produksi POME sekitar 144.859 ton/tahun. Dengan COD sebesar 64.005 mg/l. Berdasarkan kajian teknologi yang dilakukan dipilih tipe bioreaktor anaerob jenis Continues Stirred Tank Reactor CSTR dengan volume bioreaktor sebesar 2808 m3 dan HRT selama 6,79 hari . Digunakan simulasi untuk memprakirakan proses dan hasil yang terjadi pada sistem Pembangkit Listrik Biogas dari POME PLTBg POME .Berdasarkan hasil simulasi bahan baku POME sebesar 167766 kg/jam dapat menghasilkan 2777 kg/jam. Hasil simulasi Gas Engine menghasilkan energi listrik sebesar 1050 kW. Produksi biogas sebesar 2.988.889 m3/ tahun, serta energi listrik yang dihasilkan sekitar 5380 MWh per tahunnya.Nilai investasi sekitar 3.663.119 USD dapat menarik para investor jika harga jual tarif listrik diwilayah sumatera lebih dari 1.500 IDR/kWh, dengan IRR sebesar 11,2 dan NPV sebesar USD 43.010. dan payback period sekitar 8 tahun.

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ABSTRACT

Electrification ratio Jambi Province is the lowest in Sumatra with eletrification ratio around to 39.59 . Needed the addition of electrical energy in Jambi, especially in areas which not reached by electricity. One of choice is using biogas derived from liquid waste from palm oil mill or called Palm Oil Mill Effluent POME into electrical energy.As it is known palm oil is the largest plantation commodity in Jambi, liquid waste from palm oil mill is still not used only accommodated in open ponds which can lead to the formation of greenhouse gas emissions.In this research will be using data from one of the oil palm plantations in Jambi, with POME production about 144 859 tonnes year. With COD 64 005 mg l. Based on studies conducted chosen technology type anaerobic bioreactor types Continues Stirred Tank Reactor CSTR with volume of bioreaktor 2808 m3 and HRT for 6,79 days Using a simulation to predict the processes and outcomes that occur on the system of POME Biogas Power Plant PLTBg POME .Based on simulation results feed POME 16766 kg hour will be produce methane 2777 kg hour, it can be generate electicity 1050 kW.Biogas production amounted to 2,988,889 m3 year, and the electrical energy produced approximately 5380 MWh per year.Investment value approximately 3,663,119 , will be attractive for investors if the sale price of electricity tariffs in the region of Sumatra more than 1,500 IDR kWh, with an IRR of 11 2 and a NPV of USD 43 010. and payback period of about 8 years."

"Fruit waste is a part of municipal solid waste which is typically disposed of directly to a landfill site. In order to utilize this valuable renewable resource, anaerobic biological processes can be employed to convert fruit waste to biogas. This usable gas is then used to generate electricity. This paper describes a comprehensive study to set up technology for converting fruit waste to electricity via biogas production. First, the fruit waste characteristics (type and composition) were systematically evaluated, and then laboratory experiments for biogas conversion to explore gas production from the waste were carried out. The biogas plant was then designed, based on the information obtained. Finally, a comparison of biogas plant with landfill was performed using life cycle assessment (LCA) to determine environmental impacts, and economic evaluation to assess daily processing costs. The results from waste characterization in one of the biggest fruit markets in Indonesia showed that the three main component fruit types were orange (64%), mango (25%), and apple (5%). Rotten fruit contributes up to 80% of the total waste in the fruit market. Based on the experimental work, the potential gas production in the biogas plant was calculated to be approximately 1075 Nm3/day, comprising 54% methane, based on 10 tons per day of fruit waste. The comparison demonstrates that it is a better option to utilize fruit waste in a biogas plant, in terms of LCA and daily operational costs, than to dispose of it in landfill."