1. Introduction
The scale-up of the gas-liquid mixing process is a challenging task. Some of these challenges are associated with the fluid’s non-Newtonian behavior resulting in oxygen depletion zones upon scale-up. Coaxial mixers comprising of a central impeller and an anchor have shown promising performance in mixing non-Newtonian fluids [
1]. The mass transfer coefficient, gas hold-up, power consumption, and flow hydrodynamics obtained by an aerated coaxial mixer filled with non-Newtonian fluid have been studied by a small number of researchers [
2,
3,
4,
5,
6,
7].
The mass transfer coefficient (
kLa) is a process-limiting parameter in many mixing operations used in biochemical industries [
8]. Because of that, much effort has been made to maintain the mass transfer constant upon the scaling up of a mixing tank [
9,
10,
11,
12]. It has been shown that the
kLa is largely dependent upon the specific power consumption and the aeration rate. Thus, controlling the specific power consumption and proper aeration rate are crucial to maintain the mass transfer rate of the large-scale mixer the same as its small-scale counterpart [
13,
14].
According to the literature review, there has never been a scale-up investigation of the coaxial mixer. Therefore, the main objective of this study was to determine the coaxial mixer’s scalability by maintaining the mass transfer coefficient constant. In this study, a scaling up analysis was carried out using two coaxial mixer scales containing a non-Newtonian fluid. The gas hold-up profile, energy dissipation rate profile, mixing hydrodynamics, and power consumption were investigated to propose a successful scale-up approach by exploring the effect of the impellers’ speed, aeration rate and central impeller pumping direction.
2. Experimental Setup and Methods
Experimental Method
A cylindrical tank with a diameter of 40 cm was used in this study as a small-scale mixing tank. A large-scale mixing vessel was built based on the geometrical similarities and with a scale-up factor of 1.5. Two impellers, namely as a central impeller and an anchor, were mounted on the upper and lower shafts, respectively. Each shaft was able to rotate independently. The pitched blade impeller was used as a central impeller. The geometrical parameters of both the small-scale and large-scale coaxial mixer are listed in
Table 1. The air was introduced inside the mixing tank through a ring sparger. The operational conditions used in this study can be found in
Table 2. Carboxymethyl cellulose (CMC) solution with a concentration of 0.5 wt% was used as a working fluid. The rheological data of the working fluid was obtained by a rheometer. It was found that the rheological behavior of the CMC solutions at room temperature (22 ± 1 °C) obeys the power-law model as follows:
where,
and
are the shear stress and shear rate, respectively.
The gas hold-up was measured using the electrical resistance tomography (ERT) method. In this method the conductivity profile constructed for each plane of the ERT system was used to determine the gas hold-up by applying the simplified Maxwell equation. The ERT systems employed for both large-scale and small-scale mixers consisted of four planes.
The mass transfer coefficient was obtained by the dynamic pressure gassing-out method. In this study, three dissolved oxygen meters were employed at different heights of the mixing vessel to record the oxygen concentration inside the CMC solution.
The power consumption of each impeller was acquired from the relevant torque meter. The residual torque due to friction was subtracted from the measured torque to obtain the net power consumption.
3. Numerical Method
The numerical model to solve the gas-liquid multiphase flow was generated by ANSYS FLUENT (2020 R1) software. In this model the Eulerian–Eulerian approach was adopted to solve the mass and momentum transport equations. The dispersed
turbulence model was implemented. The modified Brucato [
15] drag model was utilized and the Sato [
16] model was used to consider the bubble-induced turbulence effect.
The moving zones inside the mixing tank were modeled using the sliding mesh technique. The top surface of the mixing vessel was set to the degassing boundary condition and the mass flow rate boundary condition was defined at the top surface of the sparger.
The time step used in this numerical model was 0.001 s. The mathematical model was solved for almost 24 revolutions of the central impeller. The grid independency test was performed. The 1,653,952 cells and 4,673,962 cells were found to be optimum grid sizes for the small-scale and large-scale models, respectively. Both mixer scales were validated using the gas hold-up profile, power consumption, and mass transfer coefficient.
4. Results and Discussion
Previously, it was found that the mass transfer efficiency obtained for the coaxial mixer comprised of a pitched blade impeller in the upward pumping direction and an anchor (PBU-anchor) in the co-rotating mode was higher than that for the other coaxial mixer configurations [
2]. Thus, in this study the PBU-anchor mixer in the co-rotating mode was investigated.
Analysis of the cavity size and local gas hold-up is one of the methods used to determine the flow regime inside the mixing vessel [
17]. Therefore, in this study the local gas hold-up profile was investigated both experimentally and numerically. The local gas hold-up profile obtained from the ERT plane located near the central impeller showed a good agreement with the results obtained from the CFD model. As can be seen in
Figure 1, it was found that at the higher power consumptions, the cavity size in the vicinity of the central impeller was almost negligible and the mixing flow regime was under complete dispersion condition.
The results obtained from ERT depicted in
Figure 1a show that the flow hydrodynamics was almost uniform throughout the mixing vessel. Furthermore, according to the results illustrated in
Figure 1b, it was found that the gas hold-up distributions in both radial and axial direction were uniform and the cavity size generated by the coaxial mixer at the vicinity of the central impeller was insignificant.
The flow regime attained by the coaxial mixer was further investigated by analyzing the relative power demand (RPD). In order to measure RPD, the aerated power consumption was divided by the unaerated power consumption. It was found that RPD has an inverse relation with the cavity size. In another words, by increasing the cavity size the RPD value obtained by the PBU-anchor mixer decreased. This was due to the fact that under large cavity size conditions, only a small amount of drag force was produced against the central impeller rotation and as a result the amount of the power consumption obtained by the central impeller was decreased.
It was revealed that for the large-scale PBU-anchor mixer in the co-rotating mode under the same specific power consumption and central impeller tip speed, the RPD results followed the same pattern as its small-scale counterpart upon scale-up. This finding was important since it showed that the large-scale flow-regime could be predicted based on the flow-regime observed by its small-scale counterpart.
kLa and the aeration rate (volumetric flow rate of air per volume of working fluid) were kept constant at both small and large scales to investigate the performance of the PBU-anchor mixer upon scale-up. The specific power consumption of the large-scale mixing tank was found to be lower than that of the small-scale mixing tank when this method was used as a scale-up approach to maintain the mass transfer coefficient constant. As can be seen in
Figure 2, it was observed that reasonable gas hold-up and energy dissipation rate distributions were achieved for the large-scale mixer. As shown in
Figure 2c, the fluid velocity vector profile demonstrated that the flow regime acquired by the large-scale PBU-anchor mixer in the co-rotating mode was under complete dispersion condition upon scale-up.
5. Conclusions
The scale-up study was performed for an aerated coaxial mixer comprising a pitched blade impeller in an upward pumping direction as a central impeller and an anchor as a close-clearance impeller. The effectiveness of the scale-up study was assessed by investigating the power consumption, energy dissipation rate, gas hold-up, mass transfer, and fluid hydrodynamics.
It was observed that at the same central impeller tip speed and anchor impeller rotational speed, the flow regime attained by the large-scale mixer was almost the same as its small-scale counterpart. Furthermore, for the first time, a scale-up study of the PBU-anchor mixer in the co-rotating mode was conducted successfully. The established scale-up was based on maintaining the mass transfer coefficient constant between the two scales.
Author Contributions
A.R.: Conceptualization, Methodology, Software, Validation, Formal analysis, Investigation, Writing—original draft. F.E.-M.: Conceptualization, Resources, Methodology, Writing—review & editing, Supervision, Project administration, Funding acquisition. A.L.: Conceptualization, Resources, Methodology, Writing—review & editing, Supervision, Project administration, Funding acquisition. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by Natural Sciences and Engineering Research Council of Canada grant number RGPIN-2019-04644.
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
Not applicable.
Acknowledgments
The financial support of the Natural Sciences and Engineering Research Council of Canada (NSERC) is gratefully acknowledged.
Conflicts of Interest
The authors declare no conflict of interest.
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