Hasil Pencarian  ::  Simpan CSV :: Kembali

Abstrak :
Pada penelitian ini telah dilakukan sintesis nanokomposit nanoselulosa–SO3H/CaO–La2O3 yang diaplikasikan sebagai katalis bifungsional untuk reaksi transesterifikasi waste cooking oil (WCO) menjadi biodiesel. Sintesis katalis menunjukkan keberhasilan yang didukung dengan karakterisasi FTIR, XRD, BET, SEM, TEM dan TGA. Presentase produk  optimum sebesar 84,13% diperoleh menggunakan katalis nanokomposit nanoselulosa–SO3H/CaO–La2O3 dengan rasio molar CaO terhadap La2O3 5:1, rasio massa nanoselulosa–SO3H terhadap CaO–La2O3 2:1 dengan jumlah katalis yang digunakan 3%, waktu reaksi 120 menit, dan rasio molar iopolym : minyak sebesar 9:1. Kandungan asam lemak biodiesel hasil sintesis dianalisa menggunakan GC-MS, yang dan produk utamanya adalah senyawa iopo oleat dan iopo palmitat. Sifat fisik biodiesel hasil sintesis sesuai dengan standar SNI dan ASTM, dengan massa jenis (40 oC) 0,8706 g/mL, Asam lemak bebas (FFA) 0,381%, dan bilangan asam 0,757 mg KOH/g. Studi kinetika menunjukkan bahwa reaksi transesterifikasi WCO menjadi biodiesel menggunakan katalis nanoselulosa–SO3H/CaO–La2O<3 mengikuti pseudoorde-pertama, dengan konstanta laju reaksi 0.017 menit–1< ......H/CaO–La2O3 nanocomposites were synthesized as bifunctional catalysts for the transesterification reaction of waste cooking oil (WCO) to biodiesel. The catalyst synthesis showed success which was supported by the characterization of FTIR, XRD, BET, SEM, TEM and TGA. The optimum biodiesel yield of 84.13% was obtained using a nanocellulose–SO3H/CaO–La2O3 nanocomposite catalyst with a molar ratio of CaO to La2O3, 5:1, a mass ratio of nanocellulose–SO3H to CaO–La2O3 (2:1) with a catalyst amount of 3% , a reaction time of 120 minutes, and a molar ratio of methanol: oil, 9:1. The fatty acid content of the synthesized biodiesel was analyzed using GC-MS, which showed that the main product are methyl oleate and methyl palmitate compounds. The physical properties of the synthesized biodiesel were in accordance with the SNI and ASTM standards, with a density (40oC) 0.8706 g/mL, free fatty acids (FFA) 0.381%, and acid number of 0.757 mg KOH/g. The kinetics study showed that the transesterification reaction of WCO into biodiesel using a nanocellulose– SO3H/CaO–La2O3 catalyst followed a pseudo-first order, with a reaction rate constant of 0.017 min1.

Abstrak :
Saat ini pengembangan katalis heterogen mengarah pada pembentukan katalis yang memiliki sisi aktif asam-basa (katalis bifungsional). Pada penelitian ini, nanokomposit nanoselulosa sulfonat/SrO-ZrO2 disintesis menggunakan metode solid dispersion yang didesain sebagai katalis bifungsional yang ramah lingkungan untuk reaksi pembentukan biodiesel dengan limbah minyak goreng sebagai bahan baku. Keberhasilan sintesis didukung oleh hasil karakterisasi FTIR, XRD, BET, SEM, TEM, dan TGA. Penggabungan nanoselulosa sulfonat dengan komposit SrO-ZrO2 meningkatkan luas permukaan nanokomposit menjadi 43,298 m2/g. Katalis nanoselulosa sulfonat/SrO-ZrO2 dengan rasio massa 2:1 menghasilkan yield biodiesel terbaik. Kondisi reaksi optimum untuk produksi biodiesel menggunakan katalis nanoselulosa sulfonat/SrO-ZrO2 diperoleh pada jumlah katalis 3%, rasio molar metanol:minyak sebesar 12:1, waktu reaksi selama 150 menit, dan suhu 60℃ yang menghasilkan yield biodiesel sebesar 86%. Analisis GC-MS biodiesel menunjukkan adanya kandungan hexadecanoic acid methyl ester dan cis-13-octadecenoic acid methyl ester. Kinetika reaksi biodiesel mengikuti hukum laju pseudo-first order dengan hukum laju reaksi v=k[TGA] dan konstanta laju reaksi k=0,0128cm-1. ......The development of heterogeneous catalysts is currently leading to the formation of catalysts that have an acid-base active site (bifunctional catalysts). In this research, synthesized nanocellulose sulfonate/SrO-ZrO2 nanocomposite using solid dispersion method which is designed as an environmentally friendly bifunctional catalyst for the reaction of biodiesel formation with used cooking oil as raw material. The results of the characterization of FTIR, XRD, BET, SEM, TEM, and TGA supported the success of the synthesis. The incorporation of nanocellulose sulfonate with the SrO-ZrO2 composite increased the surface area of the nanocomposite to 43,298 m2/g. Nanocellulose sulfonate/SrO-ZrO2 catalyst with a mass ratio of 2:1 resulted in the best biodiesel yield. The optimum reaction conditions for biodiesel production using nanocellulose sulfonate/SrO-ZrO2 catalyst were obtained at the amount of 3% catalyst, methanol:oil molar ratio of 12:1, reaction time of 150 minutes, and temperature of 60℃ which resulted in biodiesel yield of 86%. GC-MS analysis of biodiesel shows the presence of hexadecanoic acid methyl esters and cis-13-octadecanoic acid methyl esters. The reaction kinetics of biodiesel follows a pseudo-first-order rate law with the rate law of the reaction v=k[TGA] and the reaction rate constant k=0.0128cm-1.

Abstrak :
ABSTRAK
Green diesel merupakan bahan bakar nabati generasi kedua yang memiliki potensi untuk menjawab kebutuhan energi baik dalam negeri maupun dunia. Proses yang digunakan untuk memproduksi green diesel adalah hidrolisis sebagai pre-treatment dan hidrodeoksigenasi menggunakan katalis NiMo/Al2O3. Hidrolisis akan mengubah trigliserida pada bahan baku, yaitu minyak jelantah menjadi free fatty acid FFA yang selanjutnya dikonversi menjadi green diesel melalui hidrodeoksigenasi. Hidrolisis minyak jelantah dilakukan pada suhu 200oC dan tekanan 16 bar dengan rasio volume air dan minyak sebesar 1:1. Waktu reaksi divariasikan dari 1 hingga 3 jam. Kondisi operasi optimum hidrolisis, yaitu pada waktu 3 jam mampu menghasilkan FFA sebanyak 73,89 . Untuk proses hidrodeoksigenasi dilakukan variasi kondisi operasi, yaitu pada suhu 375oC dan tekanan 12 bar yang dapat menghasilkan green diesel dengan konversi 80,24 , selektivitas 53,37 , dan yield 19,26 , serta pada suhu 400oC dan 15 bar yang dapat menghasilkan green diesel dengan konversi 82,15 selektivitas 69,58 , dan yield 68,87 .

---

ABSTRACT
Green diesel is a second generation of biofuel that has a potential to answer the energy needs either in Indonesia or in the world. The process used to produce green diesel are hydrolysis as a pre treatment and hydrodeoxygenation by using NiMo Al2O3 catalyst. Hydrolysis will change the triglycerides in the raw material, which is waste cooking oil into free fatty acid FFA and then converted into green diesel through hydrodeoxygenation. Hydrolysis of waste cooking oil carried out at temperature of 200oC and pressure of 16 with water and oil volume ratio of 1 1. Time is varied from 1 to 3 hours. The optimum condition of hydrolysis, which is at 3 hours can produce FFA as much as 73.89 . For hydrodeoxygenation, variations in operating condition used are 375oC with pressure of 12 bar that can produce green diesel with conversion of 80.24 , selectivity of 53.37 , and yield of 19.26 , also 400oC with pressure of 15 bar that can produce green diesel with conversion of 82.15 , selectivity of 69.58 , and yield of 68.87 .

Abstrak :
ABSTRAK
Pada penelitian ini, nanokomposit selulosa-Fe3O4 telah berhasil disintesis dengan memodifikasi Fe3O4 ke permukaan nanoselulosa yang telah dihidrolisis oleh asam asetat anhidrat. Selulosa yang digunakan pada penelitian ini berasal dari isolasi sekam padi. Isolasi selulosa dari sekam padi menghasilkan rendemen rata-rata sebesar 47,34 . Hasil sintesis yang diperoleh dikarakterisasi dengan menggunakan instrumentasi FT-IR, XRD, SEM dan TEM. Selanjutnya nanokomposit selulosa-Fe3O4 diaplikasikan sebagai katalis untuk sintesis metil ester dari waste cooking oil. Kondisi optimum yang diperoleh untuk sintesis metil ester dari waste cooking oil yaitu pada suhu 60oC selama 120 menit dengan komposisi katalis nanokomposit selulosa-Fe3O4 sebesar 0,09 g. Hasil yield konversi metil ester yang diperoleh sebesar 78.

---

ABSTRACT
In this research, cellulose Fe3O4 nanocomposite has been successfully synthesized by modifying Fe3O4 onto nanocellulose rsquo s surface that has been hydrolyzed by anhydrous acetate. Cellulose used in this research was isolated from rice husk. Cellulose isolated from rice husk had a yield of 47.34 . The synthesis products were characterized using FT IR, XRD, SEM and TEM. Then, cellulose Fe3O4 nanocomposite was applied as a catalyst for methyl ester synthesis from waste cooking oil. The optimal condition for methyl ester synthesis from waste cooking oil was at 60 oC for 120 minutes with composition of cellulose Fe3O4 nanocomposite catalyst of 0.09 g. The conversion yield of methyl ester was 78.

Abstrak :
Tujuan dari penelitian ini adalah sintesis nanokomposit menggunakan biopolimer selulosa (CL) dan kitosan (CS) sebagai pendukung katalis bifungsional CaO–CeO2 yang dimanfaatkan sebagai katalis heterogen dalam proses transesterifikasi waste cooking oil (WCO) menjadi biodiesel. Katalis yang berhasil disintesis dikarakterisasi menggunakan FTIR, raman, XRD, SEM, TGA dan BET. Pada penelitian diamati pengaruh rasio massa CeO2 terhadap CaO dan pengaruh rasio massa CL–CS terhadap CaO–CeO2. Diperoleh katalis terbaik CL–CS/CaO–CeO2 dengan rasio CL–CS terhadap CaO-CeO2(2:1) dan rasio CeO2 terhadap CaO (1:1) dengan pertimbangan aktivitas dan stabilitas dari katalis. Hasil konversi biodiesel dengan katalis terbaik diperoleh 89,87% dengan beberapa parameter reaksi yang optimum, yaitu jumlah katalis 3 wt%, waktu reaksi 120 menit, dan rasio molar minyak dengan metanol (1:9). Hasil analisis sifat fisik dari biodiesel sesuai dengan standar SNI 7182:2015 dan EN 14214 diperoleh massa jenis 0,8607 g/ml, asam lemak bebas (FFA) 0,186%, dan bilangan asam 0,370 mg KOH/g. Hasil karakterisasi biodiesel dengan GC–MS diperoleh metil ester dengan kelimpahan terbesar berada pada waktu retensi 18,72 menit adalah 9-octadecenoic (E)-methyl ester. Studi kinetika mengikuti pseudo-first order dengan hukum laju reaksi v= k[WCO] dengan nilai konstanta laju reaksi (k)= 0,0194 menit–1. Selain itu katalis dapat digunakan hingga lima kali tanpa kehilangan yield yang signifikan. Hasil ini menunjukkan bahwa CL-CS/CaO-CeO2 adalah katalis yang menjanjikan untuk proses produksi biodiesel yang tahan lama dan ramah lingkungan. ......The purpose of this study is the synthesis of nanocomposites using cellulose (CL) and chitosan (CS) biopolymers as a support for the bifunctional CaO–CeO2 catalyst which is used as a heterogeneous catalyst in the transesterification process of biodiesel from waste cooking oil (WCO). The catalyst that was successfully synthesized was supported by characterization using FTIR, raman, SEM, XRD, TGA, and BET. In this work, the effect of the mass ratio of CaO to CeO2 obtained the best results with the mass ratio of CaO to CeO2 (1:1), and the effect of the mass ratio of CL-CS to CaO–CeO2 obtained the best biodiesel yield with a ratio (2:1). Using the best results from nanocomposite as a catalyst for WCO into biodiesel by optimizing the amount of catalyst 3 wt%, a reaction time of 120 min, and the molar ratio of oil to methanol (1:9), the biodiesel yield was 89.41%. Analysis of the physical properties of biodiesel according to the standards of SNI 7182:2015 and EN 14214 obtained density 0.8607 g/ml, free fatty acids (FFA) 0.186%, and acid number 0.370 mg KOH/g. The results of the characterization of biodiesel with GC–MS obtained that the largest methyl ester at 18.72 min was 9-octadecenoic (E)-methyl ester. The kinetics study obeys the pseudo-first-order with the rate law of the reaction v= k[WCO] with the reaction rate constant (k)= 0.0194 min–1. In addition, the catalyst developed can be used up to five times without significant yield loss. These results suggest that CL-CS/CaO–CeO2 is a promising catalyst for a green and durable biodiesel production process.

Abstrak :
The use of waste cooking oil (WCO) as feedstock and in microwave heating technology helps to reduce the cost of biodiesel. In this study, a continuous flow transesterification of waste cooking oil (WCO) by microwave irradiation for biodiesel production using calcium oxide (CaO) as aheterogeneous catalyst, calcined from cockle shells, is used. The catalyst was packed inside a plastic perforated container mounted on a stirrer shaft and inserted inside the reactor. The thermocouple inside the reactor was connected to a temperature controller and microwave power input to maintain the temperature. Response surface methodology (RSM) was employed to study the relationships between power input, stirrer speed and liquid hourly space velocity (LHSV) on the WCO methyl ester (WCOME) conversion at a fixed molar ratio of methanol to oil of 9 and a reaction temperature set at 65oC. The experiments were developed using the Box-Behnken design (BBD) for optimum conditions. The transesterification of the WCO was produced at 72.5% maximum WCOME conversion at an optimum power input of 445 W, stirrer speed of 380 rpm and LHSV of 71.5 h-1 . The energy consumption in a steady state condition was 0.594 kWh for the production of 1 litre WCOME, for this heterogeneous catalyst is much faster than conventional heating.

Abstrak :
Thermal decomposition of fish bones to obtain calcium oxide (CaO) was conducted at various temperatures of 400, 500, 800, 900, 1000, and 1100 °C. The calcium oxide was then characterized using X-ray diffractometer, FTIR spectrophotometer, and SEM analysis. The calcium oxide obtained from the decomposition at 1000 °C was then used as a catalyst in the production of biodiesel from waste cooking oil. Diffraction pattern of the calcium oxide produced from decomposition at 1000 °C showed a pattern similar to that of the calcium oxide produced by the Joint Committee on Powder Diffraction Standard (JCDPS). The diffractions of 2q values at 1000 °C were 32.2, 37.3, 53.8, 64.1, and 67.3 deg. The FTIR spectrum of calcium oxide decomposed at 1000 °C has a specific vibration at wave-length 362 cm-1, which is similar to the specific vibration of Ca-O. SEM analysis of the calcium oxide indicated that the calcium oxide's morphology shows a smaller size and a more homogeneous structure, compared to those of fish bones. The use of calcium oxide as a catalyst in the production of biodiesel from waste cooking oil resulted in iod number of 15.23 g/100 g KOH, density of 0.88 g/cm3, viscosity of 6.00 cSt, and fatty acid value of 0.56 mg/KOH. These characteristic values meet the National Standard of Indonesia (SNI) for biodiesel.

Abstrak :
The use of Waste Cooking Oil (WCO) as feedstock, and microwave heating technology are favored to reduce the cost of biodiesel. In order to identify the effect of using biodiesel from WCO Methyl Ester (WCOME) blends on diesel engine emissions and performance, WCOME blends were tested in a single-cylinder Direct Injection (DI) diesel engine at a constant speed of 2500 rpm and with five loads. For comparison, commercial diesel fuel, Petron Diesel Max (PDM), and biodiesel mixture from palm oil (POME) were also used. The performance and emission test results of the five test fuels: PDM, BP10, BP20, BW10, and BW20 were then compared with simulation results created by using GT-Power software. The experimental results indicated that using POME and WCOME blends led to increments in Brake Specific Fuel Consumption (BSFC) of up to 5.9% and reduction in Brake Thermal Efficiency (BTE) of up to 29.3% compare to PDM. These biodiesel blends also increased nitrogen oxide emissions and decreased carbon dioxide, carbon monoxide and hydrocarbon emissions for all engine loads at a constant speed of 2500 rpm. The experimental testing of the cylinder peak pressure demonstrates significant increase with the increase of engine load for the four test fuels. All the simulation graphs show similar trends.

Abstrak :
Biodiesel yang terdiri dari senyawa fatty acid methyl ester (FAME) menjadi salah satu solusi bahan bakar alternatif karena dapat terurai secara hayati sehingga lebih ramah lingkungan dan dapat digunakan secara berkelanjutan di masa mendatang. Senyawa FAME terbentuk dari reaksi transesterifikasi asam lemak yang terkandung dalam minyak nabati atau limbah yang kaya asam lemak seperti minyak goreng bekas menggunakan alkohol rantai pendek dengan bantuan katalis. Pada penelitian ini dilakukan sintesis katalis core-shell CaO@SiO2 menggunakan metode Stöber dan surfaktan CTAB dengan variasi parameter waktu, jenis katalis, dan jumlah katalis terhadap uji aktivitas katalisis dalam proses reaksi transesterifikasi minyak goreng bekas menjadi FAME. Kombinasi dari material CaO dan SiO2 dengan struktur core-shell memberikan kinerja aktivitas katalisis yang baik dalam proses reaksi transesterifikasi minyak goreng bekas menjadi FAME. Katalis yang berhasil disintesis dikarakterisasi menggunakan FTIR, XRD, dan SEM. Sedangkan, yield dan kemurnian FAME dianalisis menggunakan GC-MS. Reaksi transesterifikasi dari core-shell CaO@SiO2 menghasilkan yield FAME sebesar 60.29% dengan jumlah katalis 2 wt.% dan waktu reaksi selama 4 jam pada suhu 65 oC. ......Biodiesel consists of fatty acid methyl ester (FAME) compounds, which is one of the alternative fuel solutions due to its biodegradable nature. Thus, making it more environmentally friendly and can be used sustainably in the future. FAME compounds are formed from the transesterification reaction of fatty acids contained in vegetable oil or waste which are rich in fatty acids, such as waste cooking oil using short chain alcohol with the help of a catalyst. In this research, the synthesis of core-shell CaO@SiO2 catalyst carried out using the Stöber method and CTAB surfactant with various parameters of time, type, and the amount of catalyst to test the catalytic activity in the transesterification reaction process of waste cooking oil into FAME. The combination of CaO and SiO2 materials with a core-shell structure provide good catalytic activity performance and stability in the transesterification reaction process of used cooking oil into FAME. The synthesized catalyst is characterized using FTIR, XRD, and SEM. Meanwhile, the yield and purity of FAME are analyzed using GC-MS. The transesterification reaction from core- shell CaO@SiO2 obtained the highest yield of FAME up to 60.29% with a catalyst amount of 2 wt.% and a reaction time of 4 hours at 65 oC.