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Produksi Bahan Bakar Minyak dari Pirolisis Pelet Hydropulper Reject Industri Kertas Syamsudin Syamsudin; Ibrahim Syaharuddin; Andri Taufick Rizaluddin; Reza Bastari Imran Wattimena
JURNAL SELULOSA Vol 10, No 02 (2020): JURNAL SELULOSA
Publisher : Center for Pulp and Paper

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.25269/jsel.v10i02.306

Konsumsi kertas bekas di industri kertas Indonesia mencapai 6.598.464 ton/tahun dan menghasilkan hydropulper reject sebesar 5-10% dari kertas bekas yang digunakan. Penelitian pirolisis hydropulper reject dari industri kertas untuk produksi bio-oil telah dilakukan. Tipikal limbah hydropulper reject terdiri dari 20% serat dan 80% plastik (High Density Polyethylene, HDPE >90%). Bahan padat tersebut berpotensi dikonversi menjadi bahan bakar minyak melalui proses pirolisis. Penelitian ini bertujuan mengevaluasi pirolisis pelet hydropulper reject untuk produksi bio-oil sebagai bahan bakar minyak. Setelah dipisahkan dari logam, hydropulper reject dikeringkan, dicacah, dan dibentuk menjadi pelet berdiameter 10 mm dan panjang 20-30 mm. Nilai kalor pelet hydropulper reject mencapai 29,30 MJ/kg (dried based, db) dengan kadar zat terbang 84,84% (db). Pelet hydropulper reject dipirolisis dengan reaktor kombinasi pembakaran-pirolisis. Produk yang dihasilkan berupa bio-oil mampu bakar sebanyak ±40% bahan baku dengan nilai kalor 77,79 MJ/kg. Perkiraan listrik yang dapat dihasilkan dari pemanfaatan syngas sebesar 1,08 kWh/kg hydropulper reject.Kata kunci: hydropulper reject, pirolisis, bio-oil, syngas, listrikProduction of Oil Fuel From Pyrolysis of Hydropulper Reject Pellet from Paper IndustryAbstract Waste paper consumption in Indonesian paper industries reached 6,598,464 tons/year and produced hydropulper reject about 5-10% of waste paper. Pyrolysis of hydropulper reject from the paper industry for bio-oil production has been investigated. Hydropulper reject consists of 20% fiber and 80% plastic (High Density Polyethylene, HDPE>90%). This solid material has potential to be converted into oil fuel through pyrolysis. This study aims to investigate the pyrolysis of hydropulper reject pellets for bio-oil as fuel oil production. After being separated from the metals, hydropulper reject was dried, shredded, and shaped into pellets with 10 mm diameter and 20-30 mm length. The pellets had calorific value of 29.30 MJ/kg (dried based, db) with volatile matter 84.84% (db). The pellets were pyrolized with a combustion-pyrolysis combination reactor. The product was combustible bio-oil as much as ±40% of feedstock and had calorific value of 77.79 MJ/kg. Estimated electricity generated from syngas utilization about 1.08 kWh/kg. Keywords: hydropulper reject, pyrolysis, bio-oil, syngas, electricity

Studi Kasus Proyek Co-Benefit Peningkatan Efisiensi Boiler Batubara di Industri Kertas Syamsudin Syamsudin; Katsushige Takami; Shoji Kita; Yusup Setiawan; Reza Bastari Imran Wattimena; Andri Taufick Rizaluddin
JURNAL SELULOSA Vol 10, No 01 (2020): JURNAL SELULOSA
Publisher : Center for Pulp and Paper

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.25269/jsel.v10i01.296

Pertumbuhan industri yang pesat menyebabkan masalah emisi gas rumah kaca. Kegiatan co-benefit peningkatan efisiensi boiler batubara telah dilakukan di industri kertas dalam proyek “Co-benefit Indonesia Tahun 2018” dari Kementerian Lingkungan Hidup Jepang dengan tujuan melakukan identifikasi langkah-langkah yang terkait dengan konservasi energi dan penurunan polutan emisi boiler industri berbahan bakar batubara dan cara melakukannya. Identifikasi meliputi analisis efisiensi termal boiler, pengukuran kadar air batubara, pengukuran kualitas air umpan boiler, air blowdown, dan kondensat, pemeriksaan insulasi panas, pengaturan rasio udara pembakaran, dan pengendalian operasi multi boiler. Berbagai kehilangan panas dianalisis dan beberapa rekomendasi diberikan untuk implementasi di pabrik sehingga efisiensi boiler dapat ditingkatkan. Beberapa masalah yang perlu diperbaiki untuk konservasi energi meliputi penggunaan batubara dengan kadar air tinggi, rasio udara pembakaran tinggi, konduktivitas air umpan tinggi menyebabkan rasio blowdown tinggi, tidak dilakukan insulasi pada mesin produksi yang relatif tua, dan pengoperasian beberapa boiler dengan efisiensi rendah. Potensi perbaikan melalui penyesuaian kadar air batubara, perbaikan rasio udara pembakaran, optimalisasi rasio blowdown, pemulihan air kondensat, pemasangan insulasi, dan kontrol multi boiler secara teori menghasilkan reduksi konsumsi batubara 16.445 ton/tahun atau 48,63%, dan reduksi CO2 sebesar 19.589 tCO2/tahun dengan estimasi penghematan biaya Rp 12 milyar/tahun. Kata kunci: co-benefit, industri kertas, boiler, batubara, emisi.Case Study of Co-Benefit Project Improvement of Coal Boiler Efficiency in The Paper IndustryABSTRACT Industrial rapid growth has caused greenhouse gas emissions problems. Co-benefit activities to improve the efficiency of coal boilers have been carried out in paper industry in the project of “Co-benefit Indonesia FY 2018” from the Japan Ministry of Environment aimed at identifying required steps to save energy and reduction of pollutant emission from the coal-fired industrial boilers and how to achieve it. Identification include analysis of boiler thermal efficiency, coal moisture content measurement, boiler feed water, blowdown water and condensate quality measurement, heat insulation examination, combustion air ratio management, and control of multiple boiler operations. Various heat losses have been analyzed and some recommendations have been proposed to be implemented by factory management to improve boiler efficiency. There are several issues that need to be addressed for energy conservation, namely: high water content coal utilization, high combustion air ratio, high conductivity feed water which causes high blowdown ratios, no insulation on relatively old production machines, and operational of several low efficiency boilers. The results of the co-benefit identification indicated that the potential for corrective action by adjusting the coal water content, improving the combustion air ratio, optimizing the blowdown ratio, recovering condensate water, installing insulation, and controlling multiple boilers theoretically can result coal consumption reduction of 16,445 tons/year or 48.63%, and CO2 reduction of 19,589 tCO2/year with an estimated cost savings of Rp 12 billion/year.

PELET REJECT INDUSTRI KERTAS SEBAGAI BAHAN BAKAR BOILER Yusup Setiawan; Sri Purwati; Aep Surachman; Reza Bastari Imran Wattimena; Henggar Hardiani
JURNAL SELULOSA Vol 4, No 02 (2014): JURNAL SELULOSA
Publisher : Center for Pulp and Paper

Paper mill using recycle fiber as raw material produces reject containing fiber and plastic. The reject was identified by means of sorting. Reject pellet was prepared by drying, followed by shredding, and pellets molding. It was analyzed for its proximate composition (moisture, ash, volatile matter and fixed carbon). Calorific value, sulfur content, ash mineral content, and ash fusion temperatures were also tested. The results showed that reject consists of 50.75% fiber and 49.25% plastic of which is >99% High Density Polyethylene (HDPE). Reject contains a high calorific value of about 7000 cal/g which could potentially be used as fuel. Coal boiler fuel containing 5-50% reject pellet shows no indication of slagging and fouling in the boiler.Keywords: reject, pellet, coal, calorific value, fuel ABSTRAKIndustri kertas berbahan baku kertas bekas menghasilkan reject yang mengandung serat dan plastik. Reject diidentifikasi komponennya dengan cara pemilahan. Proses pembuatan pelet dari reject industri kertas terdiri dari proses pengeringan, pencacahan, dan pencetakan pelet. Pelet reject dianalisis proksimat (kadar air lembap, kadar abu, kadar zat terbang (volatile matter) dan karbon padat (fixed carbon). Nilai kalor, kadar sulfur, kadar mineral abu, dan suhu fusi abu (Ash Fusion Temperature) pelet reject juga diuji. Hasil menunjukkan bahwa komponen reject terdiri dari serat 50,75% dan plastik 49,25% dengan kandungan plastik jenis High Density Polyethylene (HDPE) lebih dari 99%. Nilai kalor pelet reject sekitar 7.000 kalori/gram. Hal ini menunjukkan potensi pelet reject sebagai bahan bakar campuran batubara. Penambahan pelet reject sebanyak 5 - 50% ke dalam batubara dapat digunakan sebagai bahan bakar boiler tanpa menyebabkan indikasi terjadinya slagging dan fouling di dalam boiler.Kata kunci: reject, pelet, batubara, nilai kalor, bahan bakar

Potensi Penerapan Self-Locking Wall pada Pemanfaatan Limbah Sludge Deinking Industri Kertas sebagai Batako Interlok Reza Bastari Imran Wattimena; Aep Surachman; Wachyudin Aziz
JURNAL SELULOSA Vol 1, No 01 (2011): JURNAL SELULOSA
Publisher : Center for Pulp and Paper

This research utilize the wastewater sludge into construction/building materials, i.e brick (brick concrete) as partition interlock system (self-locking wall). With the amount of deinking sludge ranged 3-4% of production capacity and moisture content reaches 60-80%, providing an opportunity for the beneficiaries in the availability of cheap raw materials. This experiment using composition variation of cement : sand : sludge to determine optimum composition based on the physical test for several parameters such as compressive strength and Factor of Safety (FOS). Solidwork 2009® software is used to determined the shape and dimension that suitable to be applied at knock-down house. This program is also used to analyze the strength of self-locking wall products with different forms of locking to improve the strength and meets the minimum quality level of “Mutu Bata Beton Pasangan Dinding” (SNI 03-0349-1989), that is 21 kg/cm2. It shows that interlock brick from deinked pulp and waste paper, compotition 1 : 8 with 50 & 70% sludge persentation give good result to be used as self-locking wall concept.Key words : sludge, interlock brick, knock-down house, self-locking wall ABSTRAKPenelitian ini memanfaatkan sludge industri kertas menjadi bahan bangunan batako (bata beton) sebagai partisi dengan pemasangan sistem interlock (self-locking wall). Jumlah sludge industri kertas berkisar 3–4 % kapasitas produksi dengan kadar air 60–80% memberikan peluang ketersediaan bahan baku yang murah. Percobaan menggunakan variasi komposisi semen : pasir : sludge untuk menentukan komposisi yang optimum atas dasar uji fisik beberapa parameter seperti kuat tekan dan Factor of Safety (FOS). Untuk merancang produk, dimanfaatkan perangkat lunak Solidworks® 2009, sehingga didapatkan bentuk dan dimensi yang sesuai untuk diterapkan pada rumah knock down. Dengan perangkat lunak ini dapat diperoleh bentuk pengunci yang dapat membantu meningkatkan kekuatan produk self locking wall yang memenuhi persyaratan Mutu Bata Beton Pasangan Dinding (SNI 03-0349-1989) kelas IV sebesar 21 kg/cm2. Hasil penelitian menunjukkan bahwa batako interlok menggunakan campuran bahan baku deinked pulp dan kertas bekas, komposisi 1 : 8 dengan persentase serat sebanyak 50% & 70% memenuhi persyaratan untuk digunakan sebagai pengisi dinding/partisi sistem self-locking wall.Kata kunci : limbah padat, batako interlok, knock-down, self-locking wall

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