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"Gasification is a thermo chemical process for converting solid fuel such as coal, wood and other biomass into fuel gas that consists of the components CO, H2, CH4, CO2 and N2. Gasification technology is increasingly in demand due to oil fuel price is more expensive. And of course gasification technology must also be able to maintain continuity of Producer gas if want to compete in the world of industry. The research objective was to study the characteristics of gasification with coconut shell fuel. Type of gasification reactors that used is a downdraft fixed bed gasifier. This study aimed to obtain the temperature profile in the gasifier during operation, flow rate, flame visualization of combustion of producer gas and calculation aspects thermodynamic. The purpose of the above studies carried out to operating the gasifier for 12 hours with the primary air flow rate and suction blower that optimum. Gasification process use coconut shell with Equivalence ratio 0.423. The best efficiency of the current study scored 78.8 %; LHV from producer gas acquired 1070.49 kcal/m3."

"Sampah padat kota (MSW) saat ini masih menjadi permasalahan dalam pengelolaannya. Sesuai dengan program pemerintah yang tertuang pada peraturan presiden nomor 35 tahun 2018 bahwa percepatan pembangunan pengolahan sampah menjadi energi listrik berbasis teknologi ramah lingkungan perlu dikembangkan. Salah satu teknologi untuk mengubah sampah menjadi energi terbarukan adalah menggunakan proses termokimia atau gasifikasi. Tujuan penelitian ini adalah menganalisis simulasi sampah padat kota (MSW) menggunakan fixed bed downdraft gasifier yaitu dengan cara menghitung neraca massa sampah padat kota (MSW) untuk dikonversi menjadi syngas sehingga diperoleh komposisi syngas, nilai kalor Low Heating Value (LHV), Cold Gasification Efficiency (CGE) dan daya gas engine. Analisis simulasi gasifikasi sampah padat kota (MSW) dengan fixed bed downdraft gasifier dilakukan dengan cara memberikan variasi air fuel ratio (AFR) sebesar 0,1 sampai 1,0 dan suhu pada 500-1000oC. Hasil analisis simulasi gasifikasi sampah padat kota (MSW) dengan fixed bed downdraft gasifier menghasilkan syngas dengan komposisi CO, CO2, H2, dan CH4 sebesar 24,78%, 18,65%, 15,6%, dan 4,06% serta nilai LHV dan CGE sebesar 6327,95 kJ/kg dan 39,73% pada AFR 0,3 suhu gasifikasi 600 oC dapat membangkitkan daya sebesar 400 kWe.

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Municipal solid waste (MSW) is still a problem in its management. In accordance with the government program contained in presidential regulation number 35 of 2018 that the acceleration of waste processing development into electric energy based on environmentally friendly technology needs to be developed. One of the technologies to convert waste into renewable energy is to use thermochemical processes or gasification. This study aims to simulation analysis of municipal solid waste (MSW) using fixed bed downdraft gasifier by calculating the mass balance of municipal solid waste (MSW) to be converted into syngas so that syngas composition, low heating value (LHV), Cold Gasification Efficiency (CGE) and power generator are obtained. Simulation analysis of municipal solid waste gasification (MSW) is done by providing a variation of air fuel ratio (AFR) of 0.1 to 1.0 and gasifier temperature at 500-1000oC. The result of simulatin analysis of municipal solid waste (MSW) with fixed bed downdraft gasifier produces syngas with composition are CO, CO2, H2, and CH4 of 24.78%, 18.65%, 15.6%, and 4.06%. Value of LHV and CGE of 6327.95 kJ/kg and 39.73% on AFR of 0.3 gasification temperature of 600 oC can power generator of 400 kWe."

"Sekam padi dan serbuk gergaji adalah biomassa yang melimpah di Indonesia sebagai negara agraris sehingga dapat dimanfaatkan dengan baik sebagai bahan bakar energi terbarukan pada proses gasifikasi. Tipe reaktor gasifikasi Fixed Bed Downdraft menjadi pilihan karena jenis reaktor yang sederhana, memungkinkan berbagai bahan bakar, dan menghasilkan syngas relatif bersih dengan kandungan tar dan partikel yang kecil sehingga memiliki efisiensi tinggi. Tujuan dari tesis ini adalah mengetahui nilai optimum kalor dan efisiensi termal pada variasi nilai rasio ekivalensi, suhu gasifikasi dan campuran sekam dan sebuk gergaji melalui proses simulasi berbasis semi kesetimbangan. Hasil simulasi data gas sintesis yang disajikan berupa CH4, H2, CO dan CO2 yang divalidasi dengan literatur eksperimen dan simulasi. Variabel terikat dalam tesis ini adalah laju alir massa feedstock senilai 1,7 kg/jam dengan variasi rasio ekivalensi 0,18, 0,23, 0,27, dan 0,31, variasi suhu gasifikasi 400oC hingga 1000oC dan variasi campuran umpan senilai 100% sekam, 75:25, 50:50, 25:75 dan 100% serbuk gergaji. Adapun olah data yang diperlukan yaitu menghitung rasio ekivalensi, berat molekul gas dan biomassa, densitas syngas, massa syngas per massa biomassa dan nilai Lower Heating Value (LHV). Pada akhirnya, hasil riset ini menunjukkan bahwa rasio ekivalensi optimum ditemukan senilai 0,27 dengan kalor syngas paling maksimum sebesar 3,05 MJ/kg untuk sekam dengan effsiensi 29,26% dan 4,99 MJ/kg untuk serbuk gergaji dengan effsiensi 34,51%. Sedangkan suhu optimum ditemukan senilai 700oC pada sekam dengan kalor syngas 3,38 MJ/kg effsiensi 32,36% dan 750oC pada serbuk gergaji sebesar 5,84 MJ/kg effisiensi 40,42%. Ditambah lagi seiring tambahan campuran 25% serbuk gergaji pada sekam dapat meningkatkan rata-rata kalor syngas dan termal effisiensi masing-masingnya sebesar 3% dan 1,93%.

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Rice husks and sawdust are abundant biomass in Indonesia as an agricultural country so that they can be utilized properly as renewable energy fuels in the gasification process. The Fixed Bed Downdraft gasification reactor type was chosen because the reactor type is simple, allows for a variety of feedstocks, and produces relatively clean producer gas with small tar and particle content so that it has high efficiency. The purpose of this research is to determine the optimum value of energy and thermal efficiency for variations of the equivalence ratio, gasification temperature and mixture of rice husks and sawdust through simulation process based a semi-equilibrium method. The results of the simulation of the syngas data presented the content of CH4, H2, CO and CO2 were validated by the experimental and simulation literature. The dependent variable in this research is the feedstock mass flow rate of 1.7 kg/hour with variations of the equivalence ratio of 0.18, 0.23, 0.27, and 0.31, the variation of the gasification temperature from 400oC to 1000oC and the variation of the feedstock mixture as 100% rice husk, 75:25, 50:50, 25:75 and 100% sawdust. Then data processing required is to calculate the equivalence ratio, gas and biomass molecular weight, syngas density, syngas mass per biomass mass and Lower Heaing Value (LHV) value. Finally, the results of this research showed that the optimum equivalence ratio was found to be 0.27 with the maximum syngas energy as 3.05 MJ/kg for husk with an efficiency of 29.26% and 4.99 MJ/kg for sawdust with an efficiency of 34, 51%. Meanwhile, the optimum temperature was found to be 700oC in husk with syngas energy of 3.38 MJ/kg efficiency of 32.36% and 750oC on sawdust of 5.84 MJ/kg efficiency of 40.42%. In addition, adding 25% sawdust to the rice husks can increase the average syngas energy and thermal efficiency by 13% and 1.93%, respectively."