The present disclosure generally relates to Fatty Acid Methyl Esters (FAME), and in particular to processing of FAME for use as a constituent of biodiesel.
Biodiesel is viewed as the alternative fuel to the petroleum diesel due to the renewable and environmental friendly properties. Biodiesel is a mixture of fatty acid methyl esters (FAME) produced from vegetable oils/animal fats by transesterification with methanol as well as other constituents. The compositions of FAME are constrained by the feedstock of vegetable oils/animal fats. There are six main types of FAME in biodiesel: methyl palmitate (C16:0), methyl palmitoleate (C16:1), methyl stearate (C18:0), methyl oleate (C18:1), methyl linoleate (C18:2) and methyl linolenate (C18:3); however, there may be other components known to a person having ordinary skill in the art.
The compositions of the FAME significantly affect the cold flow properties. Cold flow properties are the performances of biodiesel at low temperature. Cold flow properties of FAME can be characterized by cloud point, pour point, cold filter plugging point, and low temperature filterability test. Moreover, in North America, cloud point is used as the most appropriate standard to characterize the cold flow properties of FAME. Cloud point is referred as the temperature when biodiesel starts to form crystals (when phase separation begins to appear (i.e., when the mixture becomes “cloudy”) and the thickening fluid can clog filters or other orifices). According to the definition of cloud point, cloud point show FAME change from pure liquid mixture to liquid/solid mixtures. Therefore, cloud point is a phenomenon of solid-liquid equilibrium. The cloud point of FAME depends on the composition because the main FAME components have different melting points (as shown in Table 1). The mixture of FAME with high level of high melting point components will result in a high cloud point.
The quantitative relationship between the composition of FAME and cloud point is known. For example, Liu et al. have established the quantitative relationship between the composition of FAME and the cloud point through multiple linear statistical regression. This quantitative model shows fatty acid methyl esters with high melting points have more significant effect than those with low melting points. However, the prediction model is challenged due to a low value of R2 (proportion of variability in a data set based on how well future outcomes are predicted by a model). Imahara et al. use the thermodynamic phase heterogeneous equilibrium principal to predict the cloud point of fatty acid methyl esters according to the fraction of high melting point component. This prediction model is also challenged because the interaction between the components is not considered. Boros et al. used the thermodynamic model to predict the cloud point of fatty acid methyl esters with the UNIQUAC (UNIversal QUAsiChemical is an activity coefficient model used in description of phase equilibria) to predict the non-ideal behavior and as a result the predictability of the model significantly improved. However, their model is also challenged since it needs to be provided various parameters when a new component is added into a mixture.
While UNIFAC (UNIversal Functional Activity Coefficient) models (see Zhong, Sato, Masuoka, and Chen) have been used for predicting liquid-vapor transitions, the UNIFAC model or the modified UNIFAC model (see Gmehling, Li, and Schiller; Lohmann & Gmehling; Lohmann, Röpke, and Gmehling; Weidlich and Gmehling; and Wittig, Lohmann, and Gmehling) has not been used for predicting liquid-solid transition.
A basic challenge, therefore, remains. Specifically, when various components of fatty acid methyl esters from different sources are added, predicting the cloud point of the new mixture remains a challenge. This challenge is especially problematic since fatty acid methyl esters can originate from many sources. In fact the number of sources from which FAME can originate from may be more diverse than sources of fossil fuel. Furthermore, there can be various additives that can be included in the overall composition. Each of these presents a significant challenge for predicting the cloud point of the mixture.
Therefore, in light of the foregoing challenges with cloud point prediction, a method and a system for accurately predicting cloud point in a mixture of fatty acid methyl esters is needed where the method utilizes molecular interactions between the esters and the relationship therebetween to further provide accuracy to the prediction.
The present disclosure provides a method for predicting onset of liquid phase to solid phase transition of a mixture including a plurality of fatty acid methyl esters components. The method includes identifying chemical and molecular structure of each component of the mixture. The method further includes calculating activity coefficients for each component in a liquid phase and a solid phase. The method also includes calculating chemical potential for each component in the liquid phase and in the solid phase at a predetermined temperature and a predetermined pressure. The method further includes calculating the cloud point of the mixture.
For the purposes of promoting an understanding of the principles of the present disclosure, reference will now be made to the embodiments illustrated in the drawings, and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of this disclosure is thereby intended.
A novel method and system have been developed for predicting cloud point in a mixture including fatty acid methyl esters (FAME). The system 100 is depicted in
Prediction of Cloud Point
To describe the cloud point modeling methodology, a theoretical description of molecular interaction is provided herein.
Phase Equilibrium in the Heterogeneous Closed System
For a closed system with n phases and m components, at equilibrium, there exist the following relations:
(1) The temperature in each phase is the same:
T1=T2= . . . =Tn=T Eq. 1
(2) The pressure in each phase is the same:
P1=P2= . . . =Pn=P Eq. 2
(3) The chemical potential (i.e., partial molar free energy, is a form of potential energy that can be absorbed or released during a chemical reaction) of component i in each phase (i.e., liquid and solid) is the same:
μi1=μi2= . . . =μin=μi Eq. 3
The chemical potential of each component i is represented by:
μi(T,P)=μio(T,P)+RT ln(αi) Eq. 4
Where
μio: Standard chemical potential at temperature T and pressure P
R: gas constant with the value of 8.3145 J·mol−1·K−1
T: is the temperature
αi: Activity of component i
The chemical potential of A in phase 1 and phase 2 are shown in 5 and 6, respectively.
μA1(T,P)=μA1,o(T,P)+RT ln(αA1) Eq. 5
Where
μA1(T,P): Chemical potential of A in phase 1 at temperature T and pressure P
μA1,o(T,P): Standard chemical potential of A in phase 1 at temperature T and pressure P
αA1: Activity of A in phase 1
μA2(T,P)=μA2,o(T,P)+RT ln(αA2) Eq. 6
Where
μA2(T,P): Chemical potential of A in phase 2 at temperature T and pressure P
μA2,o(T,P): Standard chemical potential of A in phase 2 at temperature T and pressure P
μA2: Activity of A in phase 2
When A in phase 1 and phase 2 are in an equilibrium state, the chemical potential of A in each phase is the same. Therefore, Eq. 5 and Eq. 6 can be combined into Eq. 3, as provided below in Eq. 7.
μA1,o(T,P)RT ln(αA1)=μA2,o(T,P)RT ln(αA2) Eq. 7
The relationship between the activity of A in phase 1 and phase 2 is shown in Eqs. 8 and 9.
RT ln(αA1/αA2)=ΔμAo(T,P) Eq. 8
ΔμAo(T,P)=μA2,o(T,P)−μA1,o(T,P) Eq. 9
Where
ΔμAo(T,P): Standard chemical potential change of A from phase 1 to 2
Therefore, according to condition of heterogeneous phase equilibrium and the definition of chemical potential, Eqs. 8 and 9 can be written in the form of Eq. 9A.
The chemical potential cannot be readily calculated; however, it can be calculated according the following relationship (as shown in Eq. 10).
ΔμAo(T,P)=ΔHm−TΔSm Eq. 10
Where
ΔHm: Enthalpy change of A from phase 1 to 2
ΔSm: Entropy change of A from phase 1 to 2
The enthalpy and entropy changes are state variables in thermodynamics and can be calculated by designing a calculable route. An example of such a route is provided in
RT ln(αA1/αA2)=ΔHm−TΔSm Eq. 11
To calculate the enthalpy change and entropy change for component i from liquid to solid, a new route is designed and consists of three steps. The liquid component i at temperature T and pressure P is chilled to the melting point of component i (Tm,i) and the enthalpy change and entropy change are ΔHm,i1(T,P) and ΔSm,i1(T,P). The liquid component i changes from liquid to solid at the melting point of component i, and the enthalpy change and entropy change are ΔHm,i2(T,P) and ΔSm,i2(T,P). Solid component i is heated from the melting point of component i to temperature T and the enthalpy change and entropy change are ΔHm,i1(T,P) and ΔSm,i1(T,P). The enthalpy change and entropy change in each step are shown in Eq. 11A to 11F.
ΔHm,i1(T,P)=∫TT
ΔSm,i1(T,P)=∫TT
ΔHm,i2(T,P)=−ΔfusHm,i Eq. 11C
ΔSm,i2(T,P)=−ΔfusHm,i/Tm,i Eq. 11D
ΔHm,i3(T,P)=∫T
ΔSm,i3(T,P)=∫T
Where
Cp,m,iL: Molar heat capacity of liquid component i at constant pressure
Cp,m,iS: Molar heat capacity of solid component i at constant pressure
ΔfusHm,i: Molar fusion enthalpy of component i
According to thermodynamic state variables, there are the following two relations as shown in Eqs. 11G and 11H.
ΔHm,io(T,P)=ΔHm,i1(T,P)+ΔHm,i2(T,P)+ΔHm,i3(T,P) Eq. 11G
ΔSm,io(T,P)=ΔSm,i1(T,P)+ΔSm,i2(T,P)+ΔSm,i3(T,P) Eq. 11H
According to Eqs. 11A through 11H, the enthalpy change and entropy change of component i from liquid to solid are shown in Eq. 11I and 11J.
ΔHm,io(T,P)=−∫TT
ΔSm,io(T,P)=−∫TT
Where
ΔCp,m,i: Molar heat capacity difference of component i at constant pressure in liquid and solid
ΔCp,m,i=Cp,m,iL−Cp,m,iS Eq. 11K
According to the above equations, one thermodynamic model to predict the cloud point as the function of the composition is show in Eq. 11L.
RT ln(αiL/αiS)=−ΔfusHm,i(1−T/Tm,i)−∫TT
The heat capacity difference of component i in liquid and solid can be considered negligible and the thermodynamic model can then be expressed according to Eq. 11M.
RT ln(ΔiL/ΔiS)=−ΔfusHm,i(1−T/Tm,i) Eq. 11M
The solid only contains one component in an ideal solution. Therefore, the thermodynamic model can be expressed according to Eq. 11N.
RT ln ΔiL=−ΔfusHm,i(1−T/Tm,i) Eq. 11N
According to the definition of activity (further defined herein), the thermodynamic model changes to Eq. 11O.
R ln(γiLχiL)=ΔfusHm,i(1/Tm,i−1/T) Eq. 11O
The activity coefficient of the component in the mixture of FAME can be calculated according to the Modified Universal Functional Activity Coefficient (UNIFAC) model, further described below. For a given composition of FAME, there is a calculated temperature according to Eq. 11O for each component. The cloud point of the mixture of FAME is the highest calculated temperature.
In a special case, the mixture of FAME is close to an ideal solution. The activity coefficient is 1 and the thermodynamic model becomes to Eq. 11P.
R ln(χiL)=ΔfusHm,i(1/Tm,i−1/T) Eq. 11P
For a given composition of FAME, a temperature is calculated according to Eq. 11P for each component. The highest calculated temperature is the cloud point of the mixture of FAME.
Modified Universal Functional Activity Coefficient (UNIFAC) Model
As seen in Eq. 11, activities are introduced to the model. The activity of A is defined as in Eq. 12.
αA=γAχA Eq. 12
Where
γA: Activity coefficient of A
χA: Mole fraction of A
When the components are independent and do not interact, the system is ideal. Therefore, the activity coefficient is 1 and the activity is equal to the molar fraction. Thus, for the ideal system, the thermodynamic model for the heterogeneous phase equilibrium is shown in Eq. 13.
RT ln(χA1/χA2)=ΔHm−TΔSm Eq. 13
According to the relationship between chemical potential and enthalpy/entropy, the thermodynamic model is written as
Where
ΔfusHm,i and ΔCp,m,i are the molar fusion enthalpy of component i and the difference in the heat capacity at constant pressure between solid phase and liquid phase, respectively, and
Tm,i is the melting point of component i.
Therefore, the thermodynamic model can be provided as
The heat capacity at constant pressure change from solid phase to liquid phase is small enough to be neglected. Thus, the thermodynamic model can be provided as
Generally, the solid phase has small amount of fatty acid methyl esters at the cloud point. Therefore, the solid phase can be viewed as one component and an ideal solution. Consequently, the thermodynamic model is written as
This equation is used to calculate the T for different components and the maximum value of T is viewed as the cloud point.
When the mixture of fatty acid methyl esters is viewed as an ideal solution, the activity coefficient is 1 and the model is written as
However, modeling using ideal framework results in unacceptable inaccuracies. Therefore, it is necessary to know the activity coefficient in non-ideal systems for the utilization of the thermodynamic model of heterogeneous phase equilibrium. The modified UNIFAC model is the most accurate for calculating the activity coefficients. The modified UNIFAC model is derived from UNIFAC model.
To further describe the modified UNIFAC model, first the UNIFAC model is described. In the UNIFAC model, the activity coefficient has two parts: the effect of the group shape and the effect of the group interactions (as shown in Eq. 14).
ln γi=ln γiGS+ln γiGI Eq. 14
Where
γi: Activity coefficient of component i
γiGS: Effect of group interaction on the activity coefficient of component i
γiGI: Effect of group interaction on the activity coefficient of component i
The effect of the group shape on the activity coefficient is expressed in Eq. 15.
ln γiGS=1−Vi+ln Vi−5qi(1−Vi/Fi+ln(Vi/Fi)) Eq. 15
Where
Vi=ri/Σjχjrj Eq. 16
ri=Σiνkiδi Eq. 17
Fi=qi/Σjχjqj Eq. 18
qi=ΣiνkiQi Eq. 19
Where
χj: Mole Fraction of component j
δk: Volume parameter of group k
Qk: Surface area parameter of group k
νki: Number of group k in component i
The effect of the group interaction on the activity coefficient is shown in Eq. 20.
ln γiGI=Σkνki(ln ηk−ln ηki) Eq. 20
ln ηk is the group k contribution on the activity coefficient through the group interaction (as shown in Eq. 21) and ln ηki is the group k contribution on the activity coefficient through the group interaction in the pure component i (as shown in Eq. 22).
ln ηk=5Qk(1−ln(Σmθmτmk)−Σi(θiτki)/Σjθjτji) Eq. 21
ln ηki=5Qk(1−ln(Σmθmτmk)−Σi(θiτki)/Σjθjτji)(for χi=1) Eq. 22
Where
θm=QmXm/ΣnQnXn Eq. 23
Xm=Σjνmjχj/ΣnΣjνmjχj Eq. 24
τm=exp(−Aji/T) Eq. 25
Where
Aji: Group interaction parameter
To decrease the deviation in predicting activity coefficient, the UNIFAC model was modified. According to the modified UNIFAC model, the activity coefficient includes two parts: the effect of the group shape on the activity coefficient and the effect of the group interaction on the activity coefficient. In the modified UNIFAC model, both the effects of group shape and group interaction on the activity coefficient of the modified UNIFAC model are different from those of the UNIFAC model.
According to the modified UNIFAC model, the effect of the group shape on the activity coefficient is expressed in Eq. 26.
ln γiGS=1−Vi1+ln Vi1−5qi(1−Vi/Fi+ln(Vi/Fi)) Eq. 26
And
Vi1=ri3/4/Σjχjrj3/4 Eq. 27
Vi=ri/Σjχjrj Eq. 28
ri=Σiνkiδi Eq. 29
Fi=qi/Σjχjqj Eq. 30
qi=ΣiνkiQi Eq. 31
Where
χj: Molar Fraction of component j
δk: Volume parameter of group k
Qk: Surface area parameter of group k
νki: Number of group k in component i
The effect of the group interaction on the activity coefficient is shown in Eq. 32.
ln γiGI=Σkνki(ln ηk−ln ηki) Eq. 32
where, ln ηk is the group k contribution on the activity coefficient through the group interaction (as shown in Eq. 33),
ln ηki is the group k contribution on the activity coefficient through the group interaction in the pure component i (as shown in Eq. 34).
where
Aji: Group interaction parameter
Bji: Group interaction parameter
Cji: Group interaction parameter
To apply the thermodynamic model disclosed herein to predict the cloud point according to the composition of fatty acid methyl esters, the properties of pure fatty acid methyl esters such as melting points and fusion enthalpy should be known. To use the modified UNIFAC model in activity coefficients prediction, the group shape parameters and group interaction parameter should be known. These parameters are discussed below.
Parameters
Melting Points and Fusion Enthalpy
To predict the cloud point based on the composition of fatty acid methyl esters by the above thermodynamic model, the melting points and fusion enthalpies of the pure components should be known. The relationship between melting point and fusion enthalpy as shown in Eq. 38.
ΔfusHm=TmΔfusSm Eq. 38
The fusion enthalpy and fusion entropy can be calculated by a group contribution model according to Eq. 39.
Where ni is the number of group i in the component, and
κi is the group value of entropy contribution, respectively.
According to the group contribution model, the fatty acid methyl esters have the following groups: —CH3, —CH2—CH═ and —C(═O)O—. The group contributions for fusion enthalpy are shown in Table 2.
aThe group value will multiply 1.31 for the number of consecutive methylene groups no less than the sum of the remaining groups.
The melting points of fatty acid methyl esters are shown in Table 1. The fusion enthalpies of fatty acid methyl esters are shown in Table 3.
The fusion enthalpies of the saturated pure fatty acid methyl esters were determined. Due to the non-ideal property of the mixture of fatty acid methyl esters, the activity coefficients of the components are determined. For the methyl esters, according the modified UNIFAC model, the groups include CH2, CH3, CH═CH and (C═O)OCH3. The group shape parameters are shown in Table 4 and the group interaction parameters are shown in Table 5. Based on the composition of fatty acid methyl esters and the group parameter, above equations can be used to predict the activity coefficients.
Results
Cloud Points of a Binary System
The model was tested for several binary FAME and the measured and predicted cloud points of these binary mixtures are shown in
Cloud Points and the Compositions in Ternary System
Ternary systems were examined composed of: C14:0/C16:0/C18:0, C18:/C18:2/C18:3 and C16:0/C18:0/C18:1. The predicted and experimentally measured cloud points of these ternary mixtures are presented in
Using method discussed in the present disclosure, the predicted and experimentally measured cloud points are plotted in
TCP,P=0.975TCP,D+8.55 Eq. 40
Where TCP,P and TCP,D are the predicted cloud points and detected cloud points of the mixtures of FAME, respectively.
In operation, referring back to
The method described herein is depicted in
identifying chemical and molecular structure of each component of the mixture (step 210). The method 200 also includes calculating activity coefficients for each component in a liquid phase and a solid phase according to
(step 220). The method 200 also includes:
calculating chemical potential for each component in the liquid phase and in the solid phase at a predetermined temperature and a predetermined pressure according to
μiL=μi0,L(T,P)+RT ln(γiLχiL)
μiS=μi0,S(T,P)+RT ln(γiSχiS)
(step 230). The method 200 also includes calculating the cloud point of the mixture (step 240).
Those skilled in the art will recognize that numerous modifications can be made to the specific implementations described above. Therefore, the following claims are not to be limited to the specific embodiments illustrated and described above. The claims, as originally presented and as they may be amended, encompass variations, alternatives, modifications, improvements, equivalents, and substantial equivalents of the embodiments and teachings disclosed herein, including those that are presently unforeseen or unappreciated, and that, for example, may arise from applicants/patentees and others.
The present U.S. Non-provisional patent application is related to and claims the priority benefit of U.S. Provisional Patent Application Ser. No. 61/573,012, filed Aug. 3, 2011, the contents of which is hereby incorporated by reference in its entirety into this disclosure.
Number | Name | Date | Kind |
---|---|---|---|
6426448 | Booth et al. | Jul 2002 | B1 |
20040049813 | Russell et al. | Mar 2004 | A1 |
20110023352 | Knuth et al. | Feb 2011 | A1 |
Entry |
---|
Dunn, R.O., “Crystallization behavior of Fatty Acid Methyl Esters”, Journal of American Oil Chem Society, 2008. |
Chang et al., “Integrated process modeling and product design of biodiesel manufacturing”, Industrial Engineering Chemical Research, 2010. |
Alcantara, et al. “Catalytic production of biodiesel from soy-bean oil, used frying oil and tallow,” Biomass and Bioenergy, 2000, vol. 18, No. 6; pp. 515-527. |
Bailey, et al. “Solubilities of some normal saturated and unsaturated long-chain fatty acid methyl esters in acetone, n-hexane, toluene, and 1,2-dichloroethane,” Journal of Chemical & Engineering Data, 1970, vol. 15, No. 4; pp. 583-585. |
Benjumea, et al. “Basic properties of palm oil biodiesel-diesel blends,” Fuel, 2008, vol. 87, No. 10; pp. 2069-2075. |
Bhale, et al. “Improving the low temperature properties of biodiesel fuel,” Renewable Energy, 2009, vol. 34, No. 3; pp. 794-800. |
Boey, et al. “Biodiesel production via transesterification of palm olein using waste mud crab (Scylla serrata) shell as a heterogeneous catalyst,” Bioresource Technology, 2009, vol. 100, No. 24; pp. 6362-6368. |
BP, “BP Statistical Review of World Energy Jun. 2011,” BP p.l.c., London, 2011. |
Cetinkaya, et al. “Optimization of Base-Catalyzed Transesterification Reaction of Used Cooking Oil,” Energy & Fuels, 2004, vol. 18, No. 6; pp. 1888-1895. |
Cheng Sit Foon, et al. “Crystallisation and Melting Behavior of Methyl Esters of Palm Oil,” American Journal of Applied Sciences, 2006, vol. 3, No. 5; pp. 1859-1863. |
Chiu, et al. “Impact of cold flow improvers on soybean biodiesel blend,” Biomass and Bioenergy, 2004, vol. 27, No. 5; pp. 485-491. |
Dantas, et al. “Characterization and kinetic compensation effect of corn biodiesel,” Journal of Thermal Analysis and Calorimetry, 2007, vol. 87, No. 3; pp. 847-851. |
Demirbas, “Biodiesel from waste cooking oil via base-catalytic and supercritical methanol transesterification,” Energy Conversion and Management, 2009, vol. 50, No. 4; pp. 923-927. |
Dias, et al. “Production of biodiesel from acid waste lard,” Bioresource Technology, 2009, vol. 100, No. 24; pp. 6355-6361. |
Diaz-Felix, et al. “Pretreatment of yellow grease for efficient production of fatty acid methyl esters,” Biomass and Bioenergy, 2009, vol. 33, No. 4; pp. 558-563. |
Dizge, et al. “Biodiesel production from sunflower, soybean, and waste cooking oils by transesterification using lipase immobilized onto a novel microporous polymer,” Bioresource Technology, 2009, vol. 100, No. 6; pp. 1983-1991. |
Dunn, et al. “Low-Temperature Properties of Triglyceride-Based Diesel Fuels: Transesterified Methyl Esters and Petroleum Middle Distillate/Ester Blends,” JAOCS, 1995, vol. 72, No. 8; pp. 895-904. |
Dunn, “Effects of Minor Constituents on Cold Flow Properties and Performance of Biodiesel,” Progress in Energy and Combustion Science, 2009, vol. 35, No. 6; pp. 481-489. |
Dunn, et al. “Low-Temperature Filterability Properties of Alternative Diesel Fuels from Vegetable Oils,” Fuel and Energy Abstracts, 1997, vol. 38, No. 5. |
Dunn, et al. “Improving the Low-Temperature Properties of Alternative Diesel Fuels: Vegetable Oil-Derived Methyl Esters,” JAOCS, 1996, vol. 73, No. 12; pp. 1719-1728. |
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20130204591 A1 | Aug 2013 | US |
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61573012 | Aug 2011 | US |