scholarly journals Effect Of The Contact Time Of Candlenut Shell Charcoal And H3PO4 Activator As On The Purification Process Of Used Cooking Oil

2019 ◽  
Vol 12 (2) ◽  
pp. 104
Author(s):  
Yustina Bapa

Research on Comparison of the Contact Time of Candlenut Charcoal with H3PO4 Activator in the Process of Purifying Used Cooking Oil has been conducted. The purpose of this study was to determine the ability of candlenut shells activated with H3PO4 against purifying used cooking oil. The variation of the number of candlenut shells used is 1 gram, 2 grams, and 3 grams and the variation of contact time is 10 minutes, 30 minutes and 60 minutes. The results showed that the activation of hazelnut shell using H3PO4 fulfills SNI 16-3730-1995, while the results of used cooking oil purification with 2 grams of activated charcoal in 60 minutes resulted in a decrease in peroxide number of 64.58% and free fatty acids of 54, 84%.

2020 ◽  
Vol 2 (2) ◽  
pp. 83-87
Author(s):  
Mutiara Putri Utami Susanto ◽  
Kenny Kencanawati ◽  
Dwi Tia Septiani ◽  
Sani Nurahayu

The study used mahkota dewa as adsorben to decrease of the peroxide number and free fatty acids on the used cooking oil with immersion variations for 2 days dan 3 days and also concentration variations of mahkota dewa 5 % w/v, 10 % w/v, and 20 % w/v. The results of the peroxide analysis test still exceed the required number of SNI namely 10 meq O2/kg and the results of the free fatty acid analysis test in the sample with immersion and stirring time for 2 days and 3 days the concentration of  mahkota dewa 20 % w/v has met the SNI, which is 1.04 % and 0.91%.


1930 ◽  
Vol 6 (02) ◽  
pp. 139-148
Author(s):  
Zona Octarya ◽  
Adhitya Fernando

This study uses activated carbon from bagasse as adsorbent by 75 mg in 200 grams of used cooking oil. Used oil is cooking oil that has been worn for 10 hours and comes from the restaurant industry. Activated carbon is made from leftover bagasse disposal is carbonized at a temperature of 600 oC for 2 hours and was activated by NaCl and 30 % test quality with iodine adsorption test. The test results of iodine adsorption test on activated carbon bagasse is 795,56 mg g and has met the SNI standard. The results showed that the peroxide used cooking oil, oil despicing results, the results of neutralization and bleaching results using bagasse activated charcoal in a row is 10,12 meq/kg, 8,62 meq/kg, 6,04 meq/kg, and 3,93 meq/kg. While the results of the determination of free fatty acids (FFA) on used cooking oil, despicing results, the results of neutralization and bleaching results using bagasse activated charcoal in a row is 2,4 %, 2,016 %, 0,88 % and 0,49 %. The results of the determination of peroxide and free fatty acids (FFA) has not met the quality standard of cooking oil (SNI), but is able to improve the quality of cooking oil.


2021 ◽  
Vol 12 (2) ◽  
Author(s):  
Rika Endara Safitri ◽  
Ria Sheftiana Rusli Hayaati

Processing of wasted cooking oil uses the photocatalyst method with metal catalysts and zeolites to reduce organic compounds. In this study, researchers used activated charcoal from durian skin and titanium dioxide embedded in a polyamide membrane as an adsorbent which was used as a medium for processing wasted cooking oil. The purpose of this study was to determine the effect of processing used cooking oil using a membrane of polyamide/titanium dioxide/durian peels activated charcoal on changes in the characteristics of wasted cooking oil. Based on the results of research on the processing of wasted cooking oil with a membrane of polyamide/titanium dioxide/activated charcoal from durian peels, there was an increase in water content by 10.21%, a decrease in free fatty acids by 33.75%, a decrease in the peroxide number by 18.33%. Used cooking oil that has passed through the membrane has a decrease in %Transmission for the functional groups of C-H alkenes, C-O esters, and C-H alkanes. In the analysis of the compound content by mass spectrophotometry, it was found that the content of the methyl ester compound with the C17 and C19 chains was close to the composition of the biodiesel constituents.


2017 ◽  
Vol 901 ◽  
pp. 135-141 ◽  
Author(s):  
Yehezkiel Steven Kurniawan ◽  
Muslih Anwar ◽  
Tutik Dwi Wahyuningsih

A new ketal cyclic from ethyl 9,10-dihydroxyoctadecanoate with acetone had been synthesized by reflux and sonochemical method. The synthesis was performed via several steps of reaction, i.e.: transesterification, hydrolysis, oxidation with 1% KMnO4 in basic condition, esterification, and ketalization. The structures of the products were confirmed by FTIR, GC-MS, 1H- and 13C-NMR spectrometers. Direct transesterification of used cooking oil produced a mixture of ethyl ester in 82.94% yield meanwhile hydrolysis of this mixture gave free fatty acids mixture in 88.46% yield. Hydroxylation reaction of free fatty acids mixture yielded a white powder of 9,10-dihydroxyoctadecanoic acid in 46.52% yield. Esterification of 9,10-dihydroxyoctadecanoic acid and ethanol catalyzed by sulfuric acid with reflux condition for 4 hours and sonochemical method, respectively yielded 90% and 93.8% of ethyl 9,10-dihydroxystearate. In the other side, the utilization of KSF montmorillonite as catalyst conducted with reflux gave 52% in yield of ester. Furthermore, the use of acetone in 45 minutes sonochemical method with montmorillonite KSF catalyst gave cyclic ketal (ethyl 8-(2,2-dimethyl-5-octyl-1,3-dioxolan-4-yl)octanoate) as a yellow viscous liquid in 53.30% yield. From physicochemical properties –density, kinematic viscosity, viscosity index, total acid number, total base number and iodine value- gave the conclusion that this novel compound is potential biolubricant candidates to be developed.


1970 ◽  
pp. 87-94
Author(s):  
Samsuar Samsuar

Cooking oil is one of the foods that are needed by the community in daily life. The use of cooking oil continuously at high temperatures, produces cooking oil that is no longer feasible to use. Therefore, it’s necessary to purify used cooking oil so that it can be reused for non-foood purposes such as making soap or biodiesel fuel. This purification process is utilie the activated carbon of reeds (Imperata cylindrica L. Raeusch) as an adsorbent to reduce the levels of free fatty acids and colors in used cooking oil. Free fatty acid content test using acid base titration method and color change using Uv-Vis spectrofotometry method. This study aims to determine the optimum concentration of reeds activated carbon as an adsorbent in reducing the levels of free fatty acids and colors in used cooking oil, which consists of the concentration of reeds activated carbon which is a consentration of 2,5; 5; 7,5; 10; dan 12,5%. The results of variance analysis showed the optimum concentration of reeds activated carbon to reduce the levels of free fatty acids and colors absorbance in used cooking oil at a concentration of 7,5%. The percentage of decreasing levels of free fatty acids gorengan and pecel lele are 78.57% and 78.85%. Decrease in absorbance of gorengan color from 1,792% to 0,384% and the pecel lele color absorbance from 2,521 to 0,515. Keywords : Activated Carbon,Color, Free Fatty Acid, Reeds, and Used Cooking Oil.


2019 ◽  
Vol 12 (1) ◽  
pp. 19
Author(s):  
Loth Botahala ◽  
Yanti Malailak ◽  
Herlin Silvia Maure ◽  
Hagar Karlani

The effectiveness of the absorption of activated rice husk and hazelnut shells on the purification of used cooking oil has been carried out. The aim is to determine the absorption capacity of the active charcoal of rice husk and hazelnut shells to purify used cooking oil. After being physically activated, activated charcoal from rice husk and pecan shells is applied to the purification of used cooking oil. The results show that the quality of hazelnut shell charcoal is better than rice husk after it is applied to purifying used cooking oil.


2018 ◽  
Vol 7 (1) ◽  
pp. 41
Author(s):  
Muhammad Silmi Hi Abubakar ◽  
Siti Nuryanti ◽  
Suherman Suherman

Study on the purification and quality test of used cooking oil with turmeric has been done. This study aims to determine the quality of cooking oil after purified turmeric. The quality parameters of oil studied were the moisture content, free fatty acids (FFA), and peroxide. The methods used for determination of these parameters were gravimetry for moisture content, acid-base titration for free fatty acids, and iodometric for peroxide. The test results for water from 0.6% to 0.4% free fatty acid from 1.2% to 0.2%, and peroxide levels before and after purification were successively from and 6 meq/g to 4 meq/g, respectively. Only free fatty acids of all three parameters met the requirement of SNI.


10.17158/224 ◽  
2012 ◽  
Vol 18 (1) ◽  
Author(s):  
Annabelle A. Callano

Intake of unsafe food causes many acute and life-long diseases, ranging from diarrheal diseases to various forms of cancer. Thus, it is imperative that safety issues on food adulteration and heavy metals contamination be evaluated for the benefits of the consuming public. Consequently, oxidation stability and heavy metal analyses on used cooking oil and four selected street-vended foods from three different sampling sites were done. Analyses of test parameters were performed using standard methods and procedures. Overall results of the analyses with three trials each showed that peroxide value, free fatty acids, cadmium (Cd) and lead (Pb) did not conform to the allowable levels set for the food products. The peroxide value was three to eight times higher than the limit of 10meq/kg since it ranges from 33.33 - 86.67meq/kg whereas Cd and Pb showed concentration of 0.60 – 1.57 ppm and 30.00-35.00 ppm, respectively. On the other hand, percent free fatty acids (%FFA) ranges from 0.72 to 0.93% on used cooking oil while selected street-vended foods FFA status were recorded at the range of 1.49 to 2.92%. The results clearly indicate oxidative rancidity due to repetitive use of cooking oil and heavy metal contamination on the test samples which were found to be significantly higher than the maximum limits. This could mean that prolonged exposure to these street vended foods is detrimental to human health. The high level of POV, Cd and Pb of these products can significantly pose food poisoning, foodborne disease, neurotoxicity and even cancer.


2018 ◽  
pp. 189-193
Author(s):  
P Purwati ◽  
Tri Harningsih

ABSTRAK Minyak digunakan secara berulangkali mengakibatkan penurunan kualitas minyak. Salah satunya adalah peningkatan asam lemak bebasnya. Limbah ampas tebu yang diubah ke dalam bentuk arang digunakan menurunkan asam lemak bebas pada minyak goreng bekas. Penambahan arang ampas tebu dengan variasi massa dapat menurunkan asam lemak bebas. Asam lemak bebas minyak bekas sebelum ditambah dengan arang ampas tebu adalah 0,62 %. Angka tersebut mengalami penurunan setelah penambahan variasi massa ampas tebu dimulai dengan 2,5 gram; 5,0 gram; 7,5 gram; 10,0 gram dan 12,5 gram. Hasil asam lemak bebas berturut-turut 0,61%; 0,55%; 0,48%; 0,45%; 0,43%. Kondisi optimum dari massa arang ampas tebu sebesar 12,5 gram. Prosentase penurunan asam lemak bebas sebesar 30,41 % dengan kadar asam lemak bebas dari sebelum dilakukan adsorbsi sebanyak 0,61% menjadi 0,43%.   Kata kunci: arang ampas tebu, asam lemak bebas, minyak goreng bekas       ABSTRACT Oils used repeatedly will result in a decrease in the quality of oil. One of which is the increase in free fatty acids. The waste bagasse which is converted into charcoal form used to lower free fatty acid in used oil casting. The addition of charcoal of bagasse with variation of mass can decrease free fatty acid. The fatty acid free of used oil before it is added with sugarcane bagasse is 0,62%. The number decreases after the addition of variation of bagasse mass begins with 2,5 grams; 5,0 grams; 7,5 grams; 10,0 grams and 12; 5 grams. Free fatty acids result are 0,61%; 0,55%; 0,48%; 0,45%; 0; 43% respectively. The optimum condition from the mass of charcoal of bagasse is 12,5 grams. Percentage of free fatty acid decrease of 30,41% with free fatty acid content from before adsorbs 0,61% to 0,43%.   Keywords: charcoal of bagasse, free fatty acids, used cooking oil


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