ULTRAFILTRATION CONCENTRATING OF CURD WHEY AFTER ELECTROFLOTATION TREATMENT
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Abstract (English):
This work offers a view on the outcomes of a study focusing on ultrafiltration of curd whey treated on the basis of the membrane electroflotation method in order to ensure more complete extraction of whey proteins when processing recoverable dairy crude. The feature that makes the method different is the presence of membranes between the anode and the cathode while the machines for membrane electroflotation are designed so that current does not run through the whey. To determine the element composition of whey prior to and after electroflotation the method of electron probe X-ray microanalysis was used. It has been shown that the filtration rate of whey treated through electroflotation nearly doubles up if compared to the initial rate. There has also been detected the dependence related to the impact that the concentration of solids and the pressure have on the filtration rate; besides, the kinetics of the ultrafiltration process has been investigated. The method of electron probe X-ray microanalysis was employed to study the element composition of whey both before and after the electroflotation treatment. The increase in the whey ultrafiltration rate after electroflotation can be explained by a growing Hydrogen index and a reduced concentration of Calcium after electroflotation. Besides, a quantitative physical model of whey ultrafiltration was developed, which takes into view specific features of polarization layer formation. The model implies conditional division of whey flow at the membrane surface into two streams - a normal one and a tangential one. Part of the protein molecules transported by the normal flow settles on the membrane surface while the other part of them remains near the surface up until it is pushed into the whey bulk by protein molecules of the tangential flow. That all mentioned above fixes certain elements of newness in the field of membrane technologies. The study was performed at the Voronezh State University of Engineering Technologies and the North Caucasus Federal University (Russian Federation).

Keywords:
Whey, ultrafiltration, electroflotation, membrane technology
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INTRODUCTION Membrane technologies are the basis for low-waste and even non-waste (in case proper arrangements are made) dairy productions [1]. However, their wide implementation is limited, in particular due to low production capacity of membrane machines. This also holds true for ultrafiltration separation of protein from milk whey [2]. Intensification of this process takes, first of all, minimization of protein deposit on the membrane surface. For instance, preliminary treatment of heated whey with ultrasound will reduce the membrane congestion and the amount of the protein deposit [3]. However, after numerous regular cleanings membranes increase their hydrodynamic resistance, which must be due to the fact that the pores get stuffed with protein from the inside surfaces [4]. If the impact of protein deposit could be minimized in any way, then concentration polarization will be the factor limiting the permeate flow through the membrane [5]. Thus, if for filtering sheep cheese whey membranes are used that are made of composite fluoropolymer, this allows a larger flow of permeate compared to polysulfone membranes, and protein deposits are minimum, while the dependency between the filtration rate Copyright © 2017, Evdokimov et al. This is an open access article distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/ ), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material for any purpose, even commercially, provided the original work is properly cited and states its license. This article is published with open access at http://frm-kemtipp.ru. ISSN 2310-9599. Foods and Raw Materials, 2017, vol. 5, no. 1 and the pressure is typical of concentration polarization [6]. Whey acidity has a significant impact on the degree of protein deposit. The major role in reducing membrane permeation in case of changing рН belongs, obviously, to β-lactoglobulin. This is suggested with the following experimentally obtained data. In the рН range of 3.9-4.65, the filtration capacity goes down along with the growing рН [7]. At the same time, there is data [8] showing that under a decreasing hydrogen index down to рН 4.65, a high concentration and a low ionic strength of the solution, the solubility of β-lactoglobulin goes down sharply. The results obtained through scanning electron microscope investigation [9] suggest that filtration of β-lacto- globulin solutions leaves the membranes with some deposit appearing as thick layers. Transmission electron microscopy of membrane cross section [10] shows that similar deposits with incorporations of α- lactalbumin globules are also to be found in case of milk whey filtration. The рН range where the whey filtration rate is minimum (рН 4.6-5.5) is close to the range where isoelectric points of various β-lacto- globulins can be found (рI 4.9-5.4) [11, 12]. Since the рН of curd whey lies within this range, its ultrafiltration is more complicated than that of cheese whey. Neutralization of cheese whey with correcting chemical agents in most cases results in its reduced organoleptic features and increased allergenic capacity [13]. This is why there is a lot of interest taken in reducing curd whey acidity with electrophysical methods, e.g. electrodialysis [14] or membrane electroflotation. Membrane electroflotation is different from conventional electroflotation used for protein- containing solutions by the presence of a membrane between the cathode and the anode, while the machines themselves are arranged so that the electric current does not go through whey. Treatment this way improves the product’s organoleptic features, while the hydrogen index goes up as well [15]. Electroflotation results in 20-30% of protein eliminated from whey. One of the areas for using floated whey could be ultrafiltration treatment aiming at more thorough extraction of proteins. This is what the present work is focused on. OBJECTS AND METHODS OF STUDY In the ultrafiltration device used for the experiment, retentive mechanism/block moves round. There were track-etched polyethylene tetraphtalate membranes used, with a pore diameter of 60 nm. The filtration rate of distilled water in the ultrafiltration cell was 12 ml/min (pressure - 0.2 MPa) (filtration rate her means the volume of filtrate that has passed through the membrane as per a single unit of time). The required level of рН, while the samples of whey were prepared, was reached through adding NаОН or НС1. For electron probe X-ray microanalysis the whey was first dried, after which scanning electron microscopy was used to select several areas (0.2 mm) within the obtained powders for further microanalysis. EXPERIMENT OUTCOMES For 10 minutes following electroflotation, the whey рН goes up from 5.0 to 6.05. The filtration rate of whey that has been treated this way nearly doubles if compared to untreated whey (Fig. 1). Further electroflotation whey treatment would not increase the filtration rate any more. The results obtained through the experiment indicate that there is a certain value in ultrafiltration of floated whey as well as in further research in the area. Filtration rate, ml/min Fig. 2 shows the dependence of curd whey filtration rate on the dry substance concentration, measured under рН = 4.8 and рН = 6.6. The charts demonstrate that the filtration rates at рН close to the values in Fig. 1 reveals a difference of 1.7 times. Whey species Filtration rate, ml/min Fig. 1. Filtration rate for initial (pH = 4.5) and floated (pH = 6.05 and pH = 7.4) wheys (t = 30C, p = 0.2 МPa). Concentration, % Fig. 2. Relationship between curd whey filtration rate and concentration of dry substances: (1) pH = 4.8; (2) pH = 6.6. Therefore, the filtration rate growth for the floated whey, if compared to the initial whey, is mostly due to a significant change in the whey hydrogen index through electroflotation. The smaller angles in the charts at 3-6% concentrations of dry substances mean that the 10-15% reduction in the protein concentration in the floated whey, if compared to the initial whey, has virtually no impact on the filtration rate. Therefore, it is most likely that there are two factors ISSN 2310-9599. Foods and Raw Materials, 2017 vol. 5, no. 1 h that have an impact on the growth in the floated w ey Therefore, there is proof to the hypothesis stated in filtration rate. This, first of all, is due to the changing [11] and stating that globular formations of α-lactd values of рН, while there is some extra impact ad ed albumin, casei , and immunoglobulins may deposit on by the reducing concentration in Calcium ions. the membrane shaping some sort of bridges above e Calcium ions present in whey are known to sp ed down its filtration rate [16]. Electron probe analysis pores, which later on host layers. proteins that can develop done on the whey prior to, and following The data obtained make it possible to assume that electroflotation showed a decrease in the Ca ion jellification process in a thick layer of β-lactoglobulin concentration in the floated whey (Table 1). Table 1. Whey element composition follows a mechanism that is different from, for instance, jellification in rather concentrated protein solutions. Actually, the induction period of jellification in the latest case is from several hours to several days, while it only takes dozens of seconds for gel to develop on a membrane. Type of whey Element, share,% Na P Cl K Ca Floated whey 1.25 0.43 1.55 0.57 0.52 Non-floated whey 1.06 0.8 1.03 0.45 1.02 This means that polarization layer development could be viewed not from the stance of gel formation yet similarly to particle deposition on solid bodies from gas phase, or i case of sedimentation deposition, from The difference in the filtration rate for wheys with a liquid under the conditions of a tangential flow. various рН v h alue remains in case of c anging share of Let us make a conditional division breaking the the dry substances in the solution, which should also be flow of protein molecules approaching the membrane true for floated and non-floated w eys. With dry surface in two - a flow that is normal towards the substances concentration w tending to ards zero, the membrane surface and a tangential one. o graphs, as c uld be expected, tend to intersect. Figures Each molecule of the normal flow, when 3 and 4 demonstrate the d ependence of filtrate volume approaching the surface, will stay there for a certain on time, and filtration rate on pressure, respectively. period of time τ0, until a connection develops between this molecule and other protein molecules. If, within N RESULTS A D DISCUSSION, this time, the molecule experiences an impact with a PROCESS MODEL Fig. 3 shows that 20-30 seconds after filtration is tangential flow molecule then it will be knocked out; however, if this impact takes place after the time of τ0 started, the curve indicating the dependence between filtrate volume and time reaches the straight line portion, which means stable filtration rate. then it will get fixed on the surface and will not be knocked out. This metastable condition of a molecule may take place during filtration, unlike other processes of interaction etween solutions and solid bodies, due Filtrate volume, ml to the fact that a large protein molecule will pressed against the surface with the water flow passing through the membrane. Let us accept that each molecule of the tangential flow experiences a co-impact with a molecule from the normal flow, so the number of these molecules Nτ approaching a certain point at the surface within the time of t shall e equal to the number of the co-impacts Nc within the same period of time: N c  N  . (1) Filtration elapsed time, min Then, all t e molecules of the perpendicular flow would approach the same point on the surface in a Fig. 3. Theoretical (1) and experimental (2) dependencies of filtrate volume of filtration time. The grades of the curves were used to determine the rate of steady filtration. At pН = 4.0 the steady rate was certain average piece of time t1 that depends on the solution concentration and the velocity of the molecules ve: 1 vst = 0.7 ml/min; at pН = 10 vst = 1.2 ml/min. Since the t1  . v 3 C (2) process stabilization time is much lo er than that of e 0 measuring (5 min) in the previous experiments then the average filtration rate determined through these Since we a e focusing on a thin layer of the liquid experiments can be considered close to the stable rate. Using the data of the electron microscopy [10] we can at the membrane surface, the concentration of С0 in that might be taken as stable. suggest that the sublayer with the α-lactalbumin The period of time t2, within which the tangential globules coating it, as well as the β-lactoglobulin layer above that, are developed within 20-30 sec. flow molecule following way: reach point А, shall be expressed the 2 t  1 . (3) In case the polarization layer is mostly developed faster than steady protein distribution takes place in the 0 v 3 C Within time t the point А will be reached by the Ncross number of cross flow molecules: boundary layer, then the cross velocity of protein molecules ve shall be approximately equal to the velocity of the filtrate flow passing through the membrane vf. Using (2), (3), (4), (5), (9) in (6), in view of Ni = N Ncross  t , (4) t1 we shall get: N ⎛ (t)  t⎜ v (t)3 C 0  ⎞  ⎟ . (10) as well as by those of the tangent ail flow Nt: rem ⎜ f ⎝ t 0 2 ⎟ 2 ⎠ t  N  t . (5) 2 Now let us calculate the number of the molecules remaining on the surface as a result of impacts: The developing polarization layer shapes, on the membrane surface, another membrane, through which whey is filtered. In view of the hydraulic resistance and the membrane porosity, the Kozeny-Carman equation [17] could be modified as follows: N rem  Ncross  Ni  P , (6) f v   mk0  P , (11) where Р is the probability of an approaching molecule to be knocked out. Assume that within the time t2, there were 10 molecules of the normal consequently approaching the boundary between impacts. The time for staying at the boundary for the first molecule is 10t1, 2nd - 9t1, the last one - t1. Let us take τ0 = 3t1. In this case the tenth, the ninth, and the eighth molecules may be knocked out at impact, while the others may not. The knock out probability Р is: a1  l where is the coefficient k0 depends on the filtrate viscosity, the microstructure and porosity of the polarization layer, m is the membrane porosity, a1 is the parameter taking into account its hydraulic resistance. Joining the polarization layer thickness l with the number of protein molecules that constitute it, we will have the following formula: P  3 10  3t1 10t1   0 10t1 . (7) m N l   rem , (12) Since 10 is the number of the molecules that approached the boundary within a time interval between the impacts, then: 10  t2 , (8) t1  P  0 . (9) t2  pr S  S por  Where S is the area of the polarization layer, Spor is the total area of the pores that can be determined from the porosity of the polarization layer, m is the mass of a protein molecule, Nrem is the number of protein molecules, and pr is its density. Solving the equation system (10-12) regarding υf in view of (3) we shall get: v f  ⎡ (c  k  v2  t)  k1 p c  k  v2  t 2  4tk  v2  c  k p⎤ . (13) ⎢    1 ⎥  c ⎢ ⎣ Here 2 a   ⎥ ⎦ S  S  0 k  С 3 0  2 , k1  m  k0 , с  1 pr m por . The formula below could be used to calculate the volume of the filtrate developing within the time t : t V  k1  p  dy ⎡ f      2      2  2    2    ⎤ . (14) 0 ⎢ c ⎢ ⎣ k v y c k v y 2 4 y k v c k1 p ⎥  c ⎥ ⎦ Filtration rate, ml/min The dependence of the filtration rate on the pressure, as calculated following the formula (13), as well as the kinetic curve determined through integration of this formula, lay within satisfactory agreement with the experimental ones (Fig. 3, 4). More accurate data could be obtained taking into account the specific hydrodynamic features of whey flowing through a canal of a certain shape. Pressure, MPa Fig. 4. Theoretical (1) and experimental (2) dependencies of filtration rate on pressure. Let us accept that, following [18], the major role in β-lactoglobulin molecular interaction belongs to hydrophobic and electrostatic interactions, which may result in aggregation of proteins based o the mechanism described, for instance, in [19]. During that, the electrostatic interactions among protein globules are of local nature [20]. Then the condition for a molecule’s getting fixed in the polarization layer will imply three events coming simultaneously - a position of a proper molecule that would ensure its touching the polarization layer with the hydrophobic area; the presence of a hydrophobic area on such a molecule at the spot of contact with the polarization layer, and not very strong an electrostatic repulsion between the areas of globules approaching one another. In case the рН of the solution is high enough, then the last condition often fails to be met, the time τ0 gets longer and, respectively, following (13), (14) the filtration rate is growing, which is observed in case of floated whey filtration. Electroflotation treatment for curd whey, which leads to a growth in the protein molecule negative charge, is likely to prove especially useful when using negatively charged membranes [21] that improve significantly ultrafiltration productivity. Due to a lower level of Са in concentrates of curd whey after it has been subjected to electroflotation treatment, they can be recommended to elderly people, since milk and dairy products may have a negative effect on the health in the elderly age, that is due to specific features about calcium absorption, which facilitates atherosclerosis [22]. CONCLUSION The study has shown that there is a reason to conduct ultrafiltration concentration of curd whey after it has been subjected to electroflotation treatment. Improved organoleptic properties of floated whey allow using ultrafiltration not only to produce whey protein concentrates with a high concentration factor, yet also to make base for yogurt, dairy drinks, and jellies with a higher content of whey proteins. At the same time it is possible not to exceed the concentration factor of 2-2.5, which reduces the load on the ultrafiltration equipment and decreases its elements, membranes first of all, contamination with protein. ACKNOWLEDGEMENTS The work was supported by the Ministry of Education and Science of the Russian Federation (Contract Minobrnauki of Russia № 2017-218-09-162).
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