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Idral Amri
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Graduate Program of Chemical Engineering Faculty of Engineering Universitas Riau, Pekanbaru, Indonesia, 28293
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INDONESIA
Journal of Bioprocess Chemical and Environmental Engineering Science
Published by Universitas Riau
ISSN : 27221334     EISSN : 27211894     DOI : -
Core Subject : Science, Social, Engineering,
Chemical Engineering, Chemistry & Bioengineering Control & Systems Engineering Decision Sciences, Operations Research & Management Environmental Science Industrial & Manufacturing Engineering Materials Science & Nanotechnology
Journal of Chemical, Bioprocess and Environmental Engineering Science merupakan Open Access Journal yang menerbitkan naskah dengan topik-topik sebagai berikut: 1) Bioprocess Engineering, 2) Catalytic Reaction Engineering Science, 3) Fundamental of Chemical Engineering and Applied Industry, 4) Industrial Chemical Engineering, 5) Material and Engineering Sciences, 6) Process and Control Engineering, 7) Energy Sciences and Technology, 8) Polymer, Oleo and Petrochemical Technology, 9) Membrane Sciences and Technology, 10) Separation and Purification Technology, 11) Water/Waste Water treatment, 12) Environmental and Safety Technology, 13) Food Processing and Engineering Sciences
Arjuna Subject : Teknik Kimia (semua kategori) - Fluid Flow and Transfer Processes
Articles 36 Documents
 1   2   3   4 
Pengaruh Tegangan dan Laju Alir pada Pengolahan Limbah Cair Tahu Menjadi Air Bersih dengan Metode Elektrokoagulasi Secara Kontinyu Idral Amri; Pratiwi Destinefa; Zultiniar
Journal of Bioprocess, Chemical and Environmental Engineering Science Vol 1 No 1 (2020): Journal of Bioprocess, Chemical, and Environmental Engineering
Publisher : Department of Chemical Engineering, Faculty of Engineering, UNRI

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (187.904 KB) | DOI: 10.31258/jbchees.1.1.1-5

Abstract

The liquid waste of the tofu industry contains high organic contaminants, such as proteins and amino acids. These organic compounds causes liquid waste of tofu industry to contain high BOD, COD, and TSS so that it can pollute the environment. Therefore, tofu liquid should be removed first by electrocoagulation method. This method has the potential to purify tofu liquid waste and decrease the content of COD, BOD, TSS, and pH contained without the addition of coagulants. The purpose of this study was to determine the effect of voltage and flow rate to neutralize pH, and reduce levels of COD, BOD, and TSS in tofu liquid waste. The parameters tested included COD, BOD, TSS, and pH using a pH meter. The electrocoagulation process uses electrical power that flows in the direction of the electrode. The electrocoagulation reactor was paired with a cable connected to the power supply then connected to an electric current with voltage variations (8; 10; and 12 V) and variations in flow rates ((0.439 ; 0.243 ; 0.087 L/min). The results of this study found that optimum conditions were obtained at current of 12 V and flow rate of 0.087 L/min with increasing pH from pH from 3.5 to 67, a decreas in COD of 72.17% from 1017 mg/L to 283 mg/L , a decrease in BOD of 71.53% from 513 mg/L to 146 mg/L, a decrease in TSS of 90.90% from 1100 mg/L to 100 mg/L. The results of the research obtained are in accordance with the waste water quality standards by Permen LH No.5 2014.
Netralisasi Limbah Cair Industri Tahu Menggunakan Metoda Elektrokoagulasi dengan Elektroda Al-Al dengan Variabel Waktu Proses dan Ketebalan Plat Idral Amri; Ihda Nurjanah; Irdoni
Journal of Bioprocess, Chemical and Environmental Engineering Science Vol 1 No 1 (2020): Journal of Bioprocess, Chemical, and Environmental Engineering
Publisher : Jurusan Teknik Kimia, Fakultas Teknik, UNRI

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (36.793 KB)

Abstract

The tofu factory located in Pangkalan Kerinci, Pelalawan District, produces 1 m3 of liquid waste every day and are immediately disposed of without going throught the processing before release to environment. The analysis shows that the liquid waste is not in accordance with Permen LH No. 5 2014. This will deerease the oxygen level in the water. The purpose of this study was to determine reduce levels of TSS, BOD and pH with plate thicknes and prosesing time. Neutralization of liquid waste of tofu industry. The electrocoagulation method was used to reduce BOD, TSS and neutralize pH by varying the time, plate thickness. The conclusions obtained are: (1) Time variation (20, 40 and 60 minutes), and effective time is 60 minutes, current strength of 0.6 A decreases 72% BOD concentration, TSS 69.9% and pH becomes 6.01. (2) Variation in plate thickness (0.5; 1.0 and 1.5 mm), and effective plate thickness of 1 mm at 60 minutes can reduce BOD concentration 73.14%, TSS 68.78%, pH becomes 6.83. The results of the research obtained are in accordance with Permen LH No.5 of 2014.
Produksi Bioetanol Generasi Kedua dari Pelepah Kelapa Sawit dengan Variasi Pre-Treatment H2SO4 dan Waktu Fermentasi ojsadmin; Adrianto Ahmad; Idral Amri; Rahmah Nabilah
Journal of Bioprocess, Chemical and Environmental Engineering Science Vol 1 No 1 (2020): Journal of Bioprocess, Chemical, and Environmental Engineering
Publisher : Jurusan Teknik Kimia, Fakultas Teknik, UNRI

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (613.236 KB)

Abstract

Indonesia merupakan negara produsen dan eksportir kelapa sawit terbesar di dunia. Seiring semakin luasnya lahan perkebunan sawit, maka semakin banyak industri pengolahan sawit yang mengakibatkan jumlah limbah yang dihasilkan juga besar. Indonesia menghasilkan limbah kelapa sawit sebesar 66.750 juta pelepah atau sekitar 300 juta ton/tahun. Dengan melimpahnya pelepah kelapa sawit dapat dimanfaatkan sebagai sumber energi alternatif terbaru yaitu bioetanol. Tujuan penelitian ini yaitu mensintesis bioetanol dari pelepah sawit, menentukan pengaruh konsentrasi H2SO4 pada proses hidrolisis dan menentukan waktu optimum produksi bioetanol dari bahan baku pelepah kelapa dengan metode separate hydrolysis and fermentation (SHF). Tahapan penelitian ini yaitu pretreatment basa menggunakan larutan KOH yang diperoleh dari ekstrak abu Tandan Kosong Sawit, selanjutnya proses pretreatment oksidatif menggunakan larutan H2O2 3%. Kemudian proses hidrolisis dengan variasi H2SO4 yaitu 1,5 M, 2 M, dan 2,5 M selama 3 jam pada suhu 100oC dan dilanjutkan dengan proses fermentasi untuk menghasilkan bioetanol dengan waktu fermentasi yaitu 24 jam, 48 jam, 72 jam, 96 jam, dan 120 jam . Hasil penelitian menunjukkan bahwa pada proses hidrolisis dihasilkan konsentrasi gula maksimum sebesar 161,98 gr/L. Konsentrasi terbaik H2SO4 pada penelitan ini yaitu 2 M dan waktu fermentasi terbaik 96 jam dengan kadar bioetanol yang diperoleh sebesar 7% atau 55,25 g/L.
Pengaruh Pretreatment pada Fermentasi Bioetanol Generasi Kedua dari Serat Buah Kelapa Sawit ojsadmin; Adrianto Ahmad; Idral Amri; Wida Sri Wani
Journal of Bioprocess, Chemical and Environmental Engineering Science Vol 1 No 1 (2020): Journal of Bioprocess, Chemical, and Environmental Engineering
Publisher : Jurusan Teknik Kimia, Fakultas Teknik, UNRI

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (239.849 KB)

Abstract

Indonesia is a country with a growing human population, causing the need of energy also increases. Bioethanol has been widely used in transportation as a fuel that is increasingly reduced. Palm fruit fiber has a high enough potential to be developed into an alternative energy source, namely bioethanol because of its high lignocellulosic content. The purpose of this study was to determine the composition of sulfuric acid in the hydrolysis process, determine the initial sugar composition of the bioethanol produced, and determine the optimal processing time for the formation of bioethanol in the Hydrolysis and Separate Fermentation (SHF) method. The stages in this study were the hydrolysis of palm fruit fiber using H2SO4 with variations of 1M, 2M, and 3M for 3 hours at 100 oC. The fermentation process is carried out with variations in time for 24 hours, 48 hours, 72 hours, 96 hours and 120 hours. The results showed that in the hydrolysis process the optimum H2SO4 concentration of 3M produced a sugar concentration of 87.83 gr/L. The fermentation process obtained an optimal fermentation time of 96 hours with a bioethanol concentration of 31.57 g / L. The greater the initial concentration and the longer time fermentation, the more bioethanol is obtained at optimal times.
Modification of Sago Starch-Based Bioplastic Using Citric Acid with Variation Plasticizers Glycerol and Sorbitol: Properties and Biodegradability Studies ojsadmin; Trisuciati Syahwardini; Cindy Oktaviani; Vivi Novriyani; Said Zul Amraini; Bahruddin
Journal of Bioprocess, Chemical and Environmental Engineering Science Vol 1 No 1 (2020): Journal of Bioprocess, Chemical, and Environmental Engineering
Publisher : Jurusan Teknik Kimia, Fakultas Teknik, UNRI

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (442.755 KB)

Abstract

Bioplastic or biodegradable plastic is one of alternative replacement to conventional plastic that has the potential to harmful to the environment. One of the raw material that has the potential to be made into bioplastic is sago starch because it has ability to degraded. The general purpose of this research is to determine the characteristics of sago-based bioplastic by modified the citric acid, microcrystalline cellulose filler, plasticizer sorbitol and glycerol. The synthesis method is casting of starch, water, filler Micro Cristalline Cellulose (MCC) with varying plasticizer sorbitol and glycerol with composition of filler is (15-25 % w/w), composition of plasticizer (25– 35 % w/w), and composition citric acid (3-9 % w/w). The results showed that the treatment with the addition of MCC fillers, plasticizers, and citric acid are contributed to the mechanical properties produced. In the best process conditions (20% w/w MCC filler, plasticizer sorbitol 30% w/w with citric acid 0.95% w/w) give result Tensile strength 15.84 MPa, Elongation 9.32%, Young's Modulus 171.2 MPa, Biodegradation 51.65%, and wavelength absorption 1722.51 cm-1
Optimalisasi Penggunaan Kitosan Limbah Kulit Udang Vannamei sebagai Koagulan dalam Perbaikan Kualitas Air Danau Shabriyani Hatma; Setyawati Yani; A. Suryanto
Journal of Bioprocess, Chemical and Environmental Engineering Science Vol 1 No 2 (2020): Journal of Bioprocess, Chemical, and Environmental Engineering
Publisher : Jurusan Teknik Kimia, Fakultas Teknik, UNRI

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (332.384 KB) | DOI: 10.31258/jbchees.1.2.17-24

Abstract

The lake in UNHAS is thought to have experienced pollution which causes the water quality to be poor so that it cannot be utilized at all. For that we need a way to improve water quality. In this study, a natural coagulant was used, namely chitosan from Vannamei shrimp shell waste from KIMA which from the past until now has not been optimally managed, so that it is an aspect that also needs attention. The method used was a jar test, through rapid mixing and slow mixing processes with variants of increasing the concentration of chitosan 0.5, 1, 1.5, 2, 2.5 (%) at stirring speed of 100, 300, 500, and 70 rpm. The results of the study, namely the effect of shrimp shell chitosan on lake water quality for TDS testing showed that, the more addition of chitosan which was parallel with the stirring speed, the solid content decreased so that the shrimp shell chitosan as a coagulant was indeed quite good to be used as an alternative to improve lake water quality in reducing solids content. Optimal at a stirring speed of 500 rpm with the addition of the concentration of chitosan as much as 10 ml / 2.5% to the volume of the lake water sample.
Produksi Bioetanol Generasi Kedua dari Pelepah Kelapa Sawit dengan Variasi Pretreatment H2SO4 dan Waktu Fermentasi Idral Amri; Adrianto Ahmad; Rahmah Nabilah
Journal of Bioprocess, Chemical and Environmental Engineering Science Vol 1 No 2 (2020): Journal of Bioprocess, Chemical, and Environmental Engineering
Publisher : Jurusan Teknik Kimia, Fakultas Teknik, UNRI

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (0.025 KB) | DOI: 10.31258/jbchees.1.2.1-16

Abstract

Indonesia merupakan negara produsen dan eksportir kelapa sawit terbesar di dunia. Seiring semakin luasnya lahan perkebunan sawit, maka semakin banyak industri pengolahan sawit yang mengakibatkan jumlah limbah yang dihasilkan juga besar. Indonesia menghasilkan limbah kelapa sawit sebesar 66.750 juta pelepah atau sekitar 300 juta ton/tahun. Dengan melimpahnya pelepah kelapa sawit dapat dimanfaatkan sebagai sumber energi alternatif terbaru yaitu bioetanol. Tujuan penelitian ini yaitu mensintesis bioetanol dari pelepah sawit, menentukan pengaruh konsentrasi H2SO4 pada proses hidrolisis dan menentukan waktu optimum produksi bioetanol dari bahan baku pelepah kelapa dengan metode separate hydrolysis and fermentation (SHF). Tahapan penelitian ini yaitu pretreatment basa menggunakan larutan KOH yang diperoleh dari ekstrak abu Tandan Kosong Sawit, selanjutnya proses pretreatment oksidatif menggunakan larutan H2O2 3%. Kemudian proses hidrolisis dengan variasi H2SO4 yaitu 1,5 M, 2 M, dan 2,5 M selama 3 jam pada suhu 100oC dan dilanjutkan dengan proses fermentasi untuk menghasilkan bioetanol dengan waktu fermentasi yaitu 24 jam, 48 jam, 72 jam, 96 jam, dan 120 jam . Hasil penelitian menunjukkan bahwa pada proses hidrolisis dihasilkan konsentrasi gula maksimum sebesar 161,98 gr/L. Konsentrasi terbaik H2SO4 pada penelitan ini yaitu 2 M dan waktu fermentasi terbaik 96 jam dengan kadar bioetanol yang diperoleh sebesar 7% atau 55,25 g/L. Kata kunci : bioetanol, fermentasi, hidrolisis, pelepah kelapa sawit, saccharomyces cerevisiae
Pembuatan Briket Kalori Tinggi Menggunakan Limbah Pulp dan Tempurung Kelapa Sebagai Cofiring dengan Campuran Limbah Sludge CPO Sebagai Bahan Perekat Michael Tanuwijaya; Idral Amri; Zultiniar
Journal of Bioprocess, Chemical and Environmental Engineering Science Vol 1 No 2 (2020): Journal of Bioprocess, Chemical, and Environmental Engineering
Publisher : Jurusan Teknik Kimia, Fakultas Teknik, UNRI

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (165.669 KB) | DOI: 10.31258/jbchees.1.2.25-38

Abstract

Indonesia is one of the largest paper producing and exporting countries in the world. Along with the increase in paper production causes an increase in solid waste originating from the reject pulp. The reject pulp has the potential to produce energy because it still contains high cellulose content of around 85.16% which is able to support the provision of usable and environmentally friendly fuel. The purpose of this study was to use of reject pulp as fuel in the form of briquettes by mixing coconut shell charcoal as cofiring and CPO sludge as an adhesive. The beginning of in this research is pretreatment of raw material samples and quality testing such as coconut shells which go through the authoring process using the torefaction process with temperature variations of 275 ° C and 300 ° C which are then mashed and reject the pulp through a washing and drying process in an oven which is then processed. form into briquettes with a variety of composition of reject pulp and coconut shell charcoal cofiring from 80%: 0%, 20%: 60%, 30%: 50%, 50%: 30%, 60%: 20%, and 0%: 80% , for adhesive 20% while 90%: 0%, 30%: 60%, 40%: 50%, 50%: 40%, 60%: 30%, 70%: 20% and 90%: 0% for adhesive 10 % of the total briquette weight which is ± 2 grams. The briquettes that have been form must qualified to the quality standards of SNI for wood charcoal (No.1 / 6235/2000) where after being tested only a few compositions have qualified the standards, for the reject pulp composition and coconut shell charcoal cofiring from 0:90, 30:60 40:50 with an adhesive composition of 10% and a composition of 0:80, 20:60, 30:50 with an adhesive composition of 20%, with the highest calorific value of 5274 cal/g, moisture content of 5.37%, and ash content of 2.65%.
Optimasi Pembuatan Film Biodegradabel dari Komposit Pati Sagu – MCC yang Dimodifikasi dengan Asam Sitrat Trisuciati Syahwardini; Bahruddin; Ida Zahrina
Journal of Bioprocess, Chemical and Environmental Engineering Science Vol 1 No 2 (2020): Journal of Bioprocess, Chemical, and Environmental Engineering
Publisher : Jurusan Teknik Kimia, Fakultas Teknik, UNRI

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (200.425 KB) | DOI: 10.31258/jbchees.1.2.39-51

Abstract

Optimization is a way to find variable values that are considered optimal, effective, and efficient to achieve the desired results. The approach that is more often used for optimization problems with multi-variables is the desirability function. The components carried out by the optimization are microcrystalline cellulose (MCC) (x1), citric acid (x2), sorbitol (x3) with the response are Tensile Strength (Y1), Elongation (Y2), Modulus young (Y3), Biodegradability (Y4), and Water Uptake (Y5). Optimization is done by using Design Expert 10.0.1 Software. Through Desirability Function analysis, the optimum treatment composition was obtained at the MCC filler variation of 18% w / w starch, citric acid 3% w / w starch, and sorbitol 33% w / w starch with the optimum response value predicted for tensile strength (Y1) = 11.38 MPa; Elongation (Y2) = 13.54%; Young's modulus (Y3) = 118.05 MPa; Biodegradability (Y4) = 46.89%; and Water Uptake (Y5) = 52.13%. The combined desirability value is 0.551
Prediksi Kesetimbangan Cair-Cair Sistem Pati-PVA-Air dengan metode UNIFAC Lusiana Sri Wahyuni; Bahruddin; Ida Zahrina
Journal of Bioprocess, Chemical and Environmental Engineering Science Vol 1 No 2 (2020): Journal of Bioprocess, Chemical, and Environmental Engineering
Publisher : Jurusan Teknik Kimia, Fakultas Teknik, UNRI

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (154.155 KB) | DOI: 10.31258/jbchees.1.2.52-62

Abstract

The manufacture of bioplastics by mixing PVA with starch, for example from sago, cassava, sweet potatoes, and potatoes and so on have been widely practiced. However, in some cases, blending of the polymers may not produce the desired properties due to the lack of miscibility between the mixed polymers. So that in making bioplastics a mixture of starch and PVA requires data support of the miscibility of raw materials for making bioplastics into water solvents. Miscibility can be predicted using UNIQUAC Functional - group Activity Coefficient (UNIFAC) method. The activity coefficient resulting from the UNIFAC calculation of the ternary system of starch, PVA and water shows that the activity coefficient of starch tends to increase with increasing starch composition, while the activity coefficient of PVA is not very stable. The water activity coefficient shows the opposite tendency. Temperature does not seem to have a significant effect on the composition of starch and PVA, from the calculation obtained the starch composition of 0.01045 - 0.15325 and PVA 0.38407 - 0.23860. Likewise, water shows that the heating temperature does not really affect the composition of the water. The calculation of the balance of the mixture is carried out to get the right composition for the mixture of starch, PVA and water to form a perfectly mixed mixture. The results of calculating the composition in equilibrium are shown in the ternary diagram. The diagram shows a single-phase graph, where if a mixture containing 2 components dissolves completely, it will form a single-phase region.

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