Selection of Prediction Methods for Thermophysical Properties for Process Modeling and Product Design of Biodiesel Manufacturing

Su, Yung-Chieh; Liu, Y. A.; Tovar, Carlos Axel Díaz; Gani, Rafiqul

doi:10.1021/ie102441u

Cited by 94 publications

(61 citation statements)

References 87 publications

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“…Interestingly, 24 many species belonging to Rhodococcus, such as Rhodococcus ruber, 25 Rhodococcus erythropolis and Rhodococcus fascians are capable of 26 synthesizing triacylglycerol (TAG) as a storage compound for their 27 carbon and energy [7,8]. These act as true storage compounds that 28 are mobilized in the absence of an extracellular carbon source [9], 29 and can, therefore, act as an alternative non-food oil feedstock for 30 the biodiesel industry. These microbial oils differ in composition 31 and properties depending on the organism and substrate used 32 [10,11].…”

mentioning

confidence: 99%

“…However, the cetane number and 405 viscosity of the biodiesel produced by ex-situ transesterification 406 were better compared to those of the in-situ transesterified 407 product. In general, a high viscosity of biodiesel is responsible for 408 reduced flow property, high thickness and engine damage, 409 whereas engine knocking, smoke, odour and ignition delay are 410 indicated by its cetane number [29,30]. Biodiesel obtained from ex- …”

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confidence: 99%

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Simultaneous lipid production and dairy wastewater treatment using Rhodococcus opacus in a batch bioreactor for potential biodiesel application

Kumar

Gupta

Pakshirajan

2015

Journal of Environmental Chemical Engineering

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confidence: 99%

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confidence: 99%

Simultaneous lipid production and dairy wastewater treatment using Rhodococcus opacus in a batch bioreactor for potential biodiesel application

Kumar

Gupta

Pakshirajan

2015

Journal of Environmental Chemical Engineering

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“…Based on SNI 7182-2012, the hydrogenated biodiesel that met the requirements was HCIME treated with a reaction time of 1 h and reaction temperature of 120°C (the cetane number value was 51.17). The increase in cetane number was due to the increased content of mono-unsaturated and saturated FAME (C18: 1 and C18: 0) as Bamgboye and Hansen [12] have reported that the cetane number of saturated and mono-unsaturated FAME is higher than that of polyunsaturated FAME.…”

Section: Property Calculation Methods Referencementioning

confidence: 97%

“…The equations to calculate CP, PP, and CFPP were based on content of unsaturated FAME (wt%). Both CP and PP equations were obtained from Sarin, et al [11], while, the CFPP equation was obtained from Su, et al [12]. Table 5 Empirical Equations to Predict FAME Properties.…”

Section: Fame Composition Effect On Oxidation Stability and Other Promentioning

confidence: 99%

“…Table 5 Empirical Equations to Predict FAME Properties. Cloud Point (CP) CP = A x U FAME + B A = -0.576; B = 48.255; U FAME = content of unsaturated FAME [11] Pour Point (PP) PP = A x U FAME + B A = -0.626; B = 45.594 [11] Cold Filter Plugging Point (CFPP) CFPP = -0.561 x US + 43.967 US = unsaturated FAME content for biodiesel [12] Viscosity (VC) ln (η mix ) = ∑ Xi f(η) Xi = Mass fraction of each FAME compositions; η = Viscosity value of each FAME composition. The viscosity (VC) equation was obtained from Clements [13] and based on the viscosity value of all FAME.…”

Section: Fame Composition Effect On Oxidation Stability and Other Promentioning

confidence: 99%

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Partial Hydrogenation of Calophyllum Inophyllum Methyl Esters to Increase the Oxidation Stability

Joelianingsih

Putra

Hidayat

et al. 2015

J. Eng. Technol. Sci.

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Abstract. Calophyllum inophyllum methyl esters have a low oxidation stability value (5-6 h) caused by high amounts of polyunsaturated fatty acid methyl esters (FAME), especially methyl linoleate. Partial hydrogenation was done to reduce the number of polyunsaturated FAME to transform them into mono-unsaturated. This was performed at 6 bar and 900 rpm with Pd/Al 2 O 3 solid catalyst in a reactor with a capacity of 1 liter. The research purpose was to learn the effects of reaction temperature (80; 100; 120°C) and time (1; 1.5; 2 h) on the FAME composition. The optimum condition of the experiment was obtained at 120°C for 1 h, with 15.47 h as the oxidation stability value, 17.8°C as the cloud point value, and 51.17 as the cetane number. Under this condition, the methyl linoleate content decreased by 59.89% w/w (from 21.869% to 8,770% w/w) and methyl linoleate hydrogenated into methyl elaidate. Meanwhile, the methyl linolenate content decreased by 85,37% w/w (from 0.205% to 0.030% w/w) and methyl linolenate hydrogenated into methyl linolelaidate. These results show that the research met the following standards: a minimum oxidation stability value of 10 h in accordance with the World Wide Fuel Charter (WWFC) 2009, a maximum cloud point value of 18°C and a minimum cetane number 51 in accordance with SNI 7182-2012. The physical properties values of the Calophyllum inophyllum methyl esters were predicted using the empirical equations.

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Rapid Models for Predicting the Low‐Temperature Behavior of Diesel

et al. 2019

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The cold filtration plugging point (CFPP) is the method most commonly applied to characterize the low‐temperature behavior of diesel and its components. However, this method is time‐consuming and does not have good repeatability, especially for samples with very low CFPP values like kerosene, light cycle oil, etc. Three new models for CFPP prediction were developed and compared: a combined density and distillation curve, differential scanning calorimetry, and near‐infrared. A set of 133 samples of diesel components were used to create the models, containing streams from different sources and levels of treatment. A further 28 diesel samples were used to validate and compare the models. All three models not only were faster than the standard method but also were found to be in good agreement with CFPP values. Each model has its own particular advantages suiting it to a particular type of diesel sample and stage of the diesel production process.

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Selection of Prediction Methods for Thermophysical Properties for Process Modeling and Product Design of Biodiesel Manufacturing

Cited by 94 publications

References 87 publications

Simultaneous lipid production and dairy wastewater treatment using Rhodococcus opacus in a batch bioreactor for potential biodiesel application

Simultaneous lipid production and dairy wastewater treatment using Rhodococcus opacus in a batch bioreactor for potential biodiesel application

Partial Hydrogenation of Calophyllum Inophyllum Methyl Esters to Increase the Oxidation Stability

Rapid Models for Predicting the Low‐Temperature Behavior of Diesel

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