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Effect of curved anchor impellers on power consumption and hydrodynamic parameters of yield stress fluids (Bingham–Papanastasiou model) in stirred tanks

  • Ibrahim Alraddadi , Dezhi Yang , Nek Muhammad Katbar , Kada Benhanifia , Lakhdar Rahmani , Brahim Mebarki , Houari Ameur , Wasim Jamshed EMAIL logo , Mohamed R. Eid , Syed M. Hussain and Sayed M. El Din
Published/Copyright: December 28, 2023
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REVIEWS ON ADVANCED MATERIALS SCIENCE
From the journal REVIEWS ON ADVANCED MATERIALS SCIENCE Volume 62 Issue 1

Abstract

This study introduces a three-dimensional numerical analysis of the mixing yield stress fluid inside stirred vessels. The Bingham–Papanastasiou model predicts the yield stress behavior of the working fluid. The implications of a new anchor impeller design are investigated; it involves certain modifications to a typical anchor impeller’s blade. Different curved shapes replace the straight blade of a classical anchor. The flow pattern and energy consumed inside the stirred system for various geometrical configurations, Reynolds numbers (0.1, 1, 10, and 100), and Bingham numbers (1, 10, 100, and 500) have been investigated. According to the findings, introducing this new geometrical configuration gives a significant acceleration of flow pattern and extension of the well-mixed zone, as well as decreased power consumption ( Np ). Three configurations were introduced to the mixing system: Case 1 is a standard anchor impeller, and Cases 2 and 3 are curved anchor impellers with two shapes different. Case 3 (helical design of blade) has been found to be the less power consumption case by five times, i.e., for Case 1 and Case 2, Np = 5 , whereas for Case 3, Np = 1 . Based on the results, it is evident that the configuration (Case 3) demonstrates a superior geometric design in enhancing mixing characteristics compared to the other configurations.

Keywords: mixing; yield stress fluid; curved anchor impeller; stirred tank; power consumption

Nomenclature

A

surface around the impeller ( m 2 )

Bn

Bingham number

D

container diameter ( m )

Da

anchor impeller diameter ( m )

Ds

shaft diameter ( m )

F x

x-Force path ( N )

F y

y-Force path ( N )

H

container height ( m )

m

stress growth parameter ( s )

N

impeller rotational speed, ( 1 / s )

Np

Power number

R

vessel radius ( m )

Re

Reynolds quantity

S

rate of deformational tensor

V t *

nondimensional velocity ( V t * = Vt / π ND )

w

blade thickness ( m )

Greek symbols

γ ̇

shear rate ( 1 / s )

μ 0

dynamic viscosity ( Pa·s )

Ca

curvature angle (° degree)

Γ

torque (Nm)

ρ

fluid density ( kg· m 3 )

τ

shear stress ( Pa )

Ω

impeller rotational rapidity ( 1 / s )

1 Introduction

Mechanical agitation is one of the fundamental unit operations widely used in the industrial fields of chemical, pharmaceutical, metallurgy, petroleum, gas dispersion, etc. The operation of mechanical agitation essentially contributes to increasing the homogeneity degree of the mixture and accelerates the heat and mass transfer in the mixing system for obtaining a high final quality product with the required physicochemical characteristics.

Viscoplastic fluids are the most important kind of non-Newtonian fluid because they are characterized by high viscosity and complex rheological behavior. The mixing of these fluids produces many problems, such as the creation of a well-mixed region and a stagnant zone near the anchor blade [1]. Viscoplastic or yield stress fluids are substances that exhibit unique characteristics. Below a certain yield stress threshold, these substances behave like highly viscous liquids. However, once the yield stress is surpassed, they transform into shear-thinning liquids. Another term used to describe these materials is shear-thinning liquids.

When subjected to yield stress, these substances undergo a significant reduction in viscosity. This phenomenon is often observed, indicating a change in their flow behavior. The mechanical response of solids that involves time-dependent and irreversible (inelastic) stresses is referred to as viscoplasticity. In the industrial sector, heavy oils, slurries of mining tailings, freshly mixed concrete, and wood pulp are notable examples of viscoplastic materials. Likewise, in ecological contexts, cooled lava and mud also exhibit viscoplastic properties. Measuring rheological properties involves the characterization and quantification of how materials respond to applied forces or deformations. The most widely used method to measure rheological properties is rotational viscometry. This method measures the viscosity of fluids by rotating a spindle or bob in the sample and measuring the torque required for rotation. The resulting shear stress and shear rate are used to determine the viscosity.

Many researchers investigated the performance of different agitator designs inside the stirred tank system and analyzed their impact on the hydrodynamics parameters such as flow pattern, energy consumed, and heat transfer. The anchor impeller is one of the most important agitators for mixing highly viscous fluids. Several studies focused on the geometry modification of anchor impellers and their effect on mixing efficiency. Hami et al. [2] and Rahmani et al. [3] managed a thermo-hydrodynamic study of combining Newtonian fluids inside a cylindrical container. They investigated the mixing parameters with an inclined anchor impeller blade. The results revealed that an anchor with no inclination consumes significantly more energy. The effect of anchor impeller speed on eliminating the stagnant region for yield stress fluids in the stirred container has been studied widely [4,5,6]. Mebarki et al. [7] numerically investigated the mechanical agitation of viscoplastic fluids in stirred vessels with circular anchor impellers. They discussed the impact of the impeller design on the rheological parameters of the stirred tank (flow pattern behavior and power consumption). Ameur [8] has made a novel modification to the standard anchor impeller to improve fluid flow movement inside the stirred tank by adding arm blades to the standard impeller design. An improvement in the flow pattern has been noted, as has the elimination of the dead zone. According to the findings, the anchor with four blades is sufficient to obtain the best performance. Kazemzadeh et al. [9] and Ameur and Ghenaim [10] introduced a new agitator design in the mixing system: a curved blade turbine mounted on the classical anchor impeller. They investigated the effect of the combined anchor–turbine agitator on the flowing pattern, shearing zone, and power consumption. Kamla et al. [11] performed a numerical study of stirred tanks with modifications to the anchor impeller geometry for different Reynolds numbers (0.1–60). They found that the anchor with a circular shape is characterized by the lowest energy consumed. The arrangement with an octagonal form (A-8b), on the other hand, is distinguished by the widest well-sheared zone inside the container. Kada et al. [12] elaborated on the effect of the new modifications on the anchor impeller by including an arm blade to the standard anchor impeller shape and varying its inclination with different angles (20°, 45°, and 60°). The results obtained revealed that the most efficient impeller is the configuration of an anchor impeller with four arm blades inclined by 60°. This case enhanced the shearing zone in the container and reduced the energy consumed. A comparative study between the standard anchor impeller and the helical agitator was conducted by Yusof et al. [13]. From the result, they found that the anchor produces 0.28 Nm and the helical 0.24 Nm of torque during the mixing operation. Driss et al. [14] numerically investigated the mixing of viscous fluid by introducing a new design of anchor impeller in which pitched blades were mounted on the classical anchor impeller. They confirmed their numerical results with the previous experimental work [15,16,17,18]. These studies involve a two-dimensional numerical study of the thermal behavior of a yield stress fluid inside a stirred tank by an anchor impeller agitator. They discussed the thermal characteristics of the mixing system, including the temperature contour and isotherm line distribution. The results showed that the decrease in Bingham numbers (plasticity of fluid) improved heat transfer inside the stirred container. Some modifications were made to the anchor impeller shape, and they analyzed the influence of design on the structure of the flow pattern (velocities – shearing zone) and power consumption inside the stirred container [19,20,21,22,23,24,25]. Rahmani et al. [21] performed a comparative study between gate impellers, two-blade agitators, and anchor impeller agitators. They found that the anchor impeller is more efficient in accelerating fluid flow and minimizes power consumption during the mixing operation. Prajabpati and Ein-Muzaffar [26] performed a numerical study of the mixing of Xanthan gum solution inside a stirred tank. They obtained that the optimum value of clearance to diameter ratio is c / d = 0.012 , and the thickness impeller to diameter ratio is w / d = 0.079 . They discovered that the anchor impeller with four blades exhibited higher efficiency in the mixing operation compared to the anchor impeller with two blades.

Many research investigations have concentrated on yield stress fluids; however, a few studies have focused on the Bingham–Papanastasiou model. This study focuses on examining the impact of a novel anchor impeller design on the mixing characteristics and hydrodynamic behavior (including flow pattern, power consumption, and pumping capacity). The objective is to investigate these effects through numerical simulations. The innovative design involves replacing the conventional straight blades with wavy blades, aimed at enhancing the flow pattern within the mixing system. The simulations incorporate the Bingham–Papanastasiou model to accurately capture the behavior of the flow.

2 Geometric description

Figure 1 illustrates the geometry parameters of the mixing structure. It involves a cylindrical container with a flat surface bottom. The stirring is ensured by introducing a new design of anchor impeller (curved anchor blade) with different geometrical configurations. In this study, six different design instances were evaluated, as displayed in Figure 2. The details of the geometrical factors are shown in Table 1.

Figure 1 Mixing system geometry.
Figure 1

Mixing system geometry.

Figure 2 Anchor impeller with different modification shapes.
Figure 2

Anchor impeller with different modification shapes.

Table 1

Measurements on the stirred tank geometry

D H Da w Ds c Ca
0.3 0.3 0.2 0.02 0.032 0.03 25°

3 Mathematical model

The three-dimensional laminar flow of viscoplastic fluids (Bingham–Papanastasiou model) in a cylindrical container has been accomplished by using a computational fluid dynamics software package (COMSOL Multiphysics 5.4) and introducing different shapes of anchor impellers. The dimensionless equations are resolved by using the finite element methodology using Galarkin’s method. The computational domain is discretized with an unstructured grid (tetrahedral mesh), as shown in Figure 3. The residual convergence was set at 10−6 for this simulation.

Figure 3 Mesh of the geometry study.
Figure 3

Mesh of the geometry study.

In this study, 3-D steady-state incompressible fluid flow has been assumed, and the dimensional governing formulas can be composed as shown in Sections 3.1 and 3.2.

3.1 Continuity equation

(1) U X + V Y + W Z = 0 .

3.2 Momentum equation

(2) ρ U t + U U X + V U Y + W U Z = P X + X 2 μ U X + Y μ U Y + V X + Z μ U Z + W X ,

(3) ρ V t + U V X + V V Y + W V Z = P Y + X μ U Y + V X + Y 2 μ V Y + Z μ V Z + W Y ,

(4) ρ W t + U W X + V W Y + W W Z = P Z + X μ U Z + W X + Y μ V Z + W Y + Z 2 μ W Z .

According to the Bingham–Papanastasiou concept [27], the relationship that follows may be used to characterize the yield stress fluid:

(5) μ = μ 0 + τ γ ̇ exp ( 1 m γ ̇ ) ,

where μ 0 stands for fixed viscosity and signifies the yield stress, τ denotes the shearing stress of the liquid, m signifies the stress expansion exponentially, commonly referred to as a normalization variable, and γ ̇ is the shearing rate.

3.3 Nondimensional variables

(6) X * = 2 X D , Y * = 2 Y D , Z * = 2 Z D , U * = U π ND , V * = V π ND , W * = W π ND , P * = P ρ ( π ND ) 2 , t * = 2 π Nt , and γ ̇ * = γ ND .

By using the above dimensionless parameters, Eqs (1)–(4) can be composed in a nondimensional structure, as shown in Sections 3.4 and 3.5.

3.4 Continuity equation

(7) U * X * + V * Y * + W * Z * = 0 .

3.5 Momentum equation

(8) U * t * + U * U * X * + V * U * Y * + W * U * Z * = P X * + 2 π d D 2 1 Re X * 2 1 + Bn γ * ̇ ( 1 exp ( M γ ̇ * ) ) U * X * + Y * 1 + Bn γ * ̇ ( 1 exp ( M γ ̇ * ) ) U * Y * + V * X * + Z * 1 + Bn γ * ̇ ( 1 exp ( M γ ̇ * ) ) U * Z * + W * X * ,

(9) V * t * + U * V * X * + V * V * Y * + W * V * Z * = P Y * + 2 π d D 2 1 Re Y * 2 1 + Bn γ * ̇ ( 1 exp ( M γ ̇ * ) ) V * Y * + X * 1 + Bn γ * ̇ ( 1 exp ( M γ ̇ * ) ) U * Y * + V * X * + Z * 1 + Bn γ * ̇ ( 1 exp ( M γ ̇ * ) ) V * Z * + W * Y * ,

(10) W * t * + U * W * X * + V * W * Y * + W * W * Z * = P Z * + 2 π d D 2 1 Re Z * 2 1 + Bn γ * ̇ ( 1 exp ( M γ ̇ * ) ) W * Z * + X * 1 + Bn γ * ̇ ( 1 exp ( M γ ̇ * ) ) U * Z * + W * X * + Y * 1 + Bn γ * ̇ ( 1 exp ( M γ ̇ * ) ) V * Z * + W * Y * .

The Papanastasiou-model equation in its dimensionless form is represented by the following expression:

(11) μ * = 1 + Bn γ * ̇ ( 1 exp ( M γ ̇ * ) ) ,

where Bn represents the Bingham number, Bn = τ D μ 0 N , and M is the dimensionless regularization parameter, M = μ 0 / D (the dimensionless regularization parameter M controls the regularization or smoothing of the stress field in the model). When a fluid gets close to a yield stress state, the regularization value M is often brought in to avoid an anomaly or destabilization from taking place. This may happen whenever the fluid is under stress. When the term for regularization is included in the model, it is able to provide an illustration of the stress field that is more accurate while still maintaining stability in the numerical simulations. γ ̇ * is the dimensionless shear rate parameter. The main parameter for determining the performance and efficacy of the stirred usage is the power consumption, which is defined as follows:

(12) Np = P ρ N 3 d 5 .

P represents the energy consumption attained by the integral around the impeller plane. It is defined as follows:

(13) P = A Ω Γ d A ,

where Ω represents the impeller rotational speed, Ω = 2 π N , and Γ represents the torque, which is applied on a point r = ( x , y , z ) and is defined as follows:

(14) Γ = r · F ,

where F is the force that is applied to all points on the surface.

(15) Γ = ( x F y y F x ) .

Finally, the power consumption is calculated using the following equation:

(16) P = A 2 π N ( x F y y F x ) d A .

Reynolds number is one of the parameters that describe the hydrodynamic flow in the mixing system. It is expressed as a ratio across the viscous powers and the inertial force:

(17) Re = ρ N d 2 μ .

The yield stress flow or fluid plasticity parameter of the yield stress fluid is defined by Bingham number in dimensionless form as follows:

(18) Bn = τ D μ 0 N .

4 Validation

It is vital to compare the results of our numerical research with the results that were previously published in the literature in order to verify the correctness of our numerical study’s findings. For the purpose of validation in this inquiry, the study of Marouche et al. [28] has been used for comparison. The Bingham modeling liquids utilized rheological and geometric features (a standard anchor impeller and a fluid with the characterization of μ = 0.1 Pa · s and τ = 0.1 Pa with an inertia quantity Re = 13.8 ). As can be seen in Figure 4, outcomes demonstrate a high degree of congruence among our computational outcomes and the earlier outcomes of the research conducted by Marouche et al. [28].

Figure 4 Tangential velocity in the tank.
Figure 4

Tangential velocity in the tank.

5 Grid independence

In order to ensure the integrity and reliability of the results obtained from the code, it is crucial to verify their independence from variations in the grid structure or the number of elements. To validate this, extensive testing was conducted using multiple meshes, as shown in Table 2. In the 3D study, mesh element number 2,095,841 (fin mesh) was chosen so that there would be no change in the calculated values and the error in those values should be less than 10−6. The mesh test is carried out using the parameters Re = 100 , μ = 0.01 Pa · s , and τ = 1 Pa .

Table 2

A test of the independence of the mesh

Mesh type Mesh number Np CPU time
Normal 275,258 367.458 4 h 58 min
Fine 1,144,853 367.501 9 h 09 min
Finer 2,095,841 367.502 13 h 2 min
Extra mesh 3,540,058 367.502 25 h 21 min

6 Results and discussion

6.1 Inertia influence

The flowing configuration is the most important parameter that indicates the hydrodynamic structure inside the stirred container system. In this study, the flow pattern structure has been investigated under the influence of various inertia values ( Re = 0.1 , 1 , 10 , and 100 ).

Figure 5 gives the velocity distribution on the horizontal sector at the middle-high of the container with different Reynolds values ( Re = 0.1 , 1 , 10 , and 100 ). It is visible from these velocity contours that the upsurge of inertia amount leads to an increment in the velocity near the blade impeller region and that the cavern size is being expanded with the increase of Re , indicating a good mixing along this region. We can also note the same influence on the vertical sector of the vessel shown in Figure 6, which depicts the velocity distribution along the vertical section inside the vessel. It was observed that an increase in the inertia value resulted in a larger circulation zone, particularly with a high Reynolds value ( Re = 100 ). This indicates that as the inertia increases, the fluid movement within the stirred tank intensifies.

Figure 5 Velocity distribution on the horizontal sector mid-high of the container.
Figure 5

Velocity distribution on the horizontal sector mid-high of the container.

Figure 6 Velocity outline on the vertical sector of the container; impeller plane; and median plane.
Figure 6

Velocity outline on the vertical sector of the container; impeller plane; and median plane.

Figure 7 presents the velocity in two directions of the impeller (median plane and impeller plane) with a comparison between the velocities in the two directions of the impeller. The maximum value of velocity in the impeller and median plane is 0.045 and 0.9, respectively. We also note that the flow is mainly tangential in the stirred tank. The same results were noted by Ameur [8] and Kada et al. [12] who found the dominance of tangential flows in the stirred system with an anchor impeller.

Figure 7 Tangential velocity V t * V{t}^{* } on the impeller plane and median plane of the stirred vessel.
Figure 7

Tangential velocity V t * on the impeller plane and median plane of the stirred vessel.

The flow patterns in a stirred vessel are shown through the distribution of the streamline presented in Figure 8 at the low Reynolds value ( Re = 0.1 1 ), which limits the progress of the liquid flowing inside the vessel. The flow is limited near the anchor blade tip. A dead zone is formed between the blade tip and vessel wall in the horizontal section of the streamline distribution for Reynolds value ( Re = 0.1 1 ). These zones disappear with the increase of inertia ( Re = 10 100 ). It is also clear that with a high inertia value, the flow moves from the blade tip region, and it is gradually developed with the increased Reynolds number. In addition, from the last case when Re = 100 , it can be noted that the streamlines change the direction from the tangential to the axial path in the vessel, which means the existence of axial flow with this high value of inertia.

Figure 8 Streamline distribution in the whole vessel for diverse Reynolds quantities.
Figure 8

Streamline distribution in the whole vessel for diverse Reynolds quantities.

Figure 9 illustrates the variation of power consumption versus the Reynolds number. At low Reynolds number values, the stirred system consumes a significant amount of energy. Conversely, as the Reynolds value increases during the mixing operation, the energy consumption decreases significantly. This confirms the previous results of Mebarki et al. [7], Ameur [8], and Kada et al. [12]. The inertia has a big influence on changing the structure of the flowing design inside the stirred tank.

Figure 9 Power consumption as a function of Reynolds number.
Figure 9

Power consumption as a function of Reynolds number.

6.2 Effect of design

To enhance the mixing circulation in the tank, we introduce a new design of classical anchor impellers in the stirred system. Many geometrical configurations were tested to analyze the hydrodynamics structure of the mixing system by introducing new geometrical configurations of anchor impellers.

Figures 10 and 11 present the velocity contour inside the stirred tank for diverse anchor geometries along the vertical and horizontal sections, respectively. It is noteworthy that the inclusion of curved blades in the design intensifies fluid pumping and, consequently, enhances circulation throughout the entire volume of the tank when compared to standard anchor blades. The geometric configuration of the wavy blades allows for a larger volume to be swept, resulting in a wider region of well-stirred fluid.

Figure 10 Velocity distribution in the vertical section of the vessel for different impeller designs ( Re = 100 \mathrm{Re}=100 , Bn = 10 {\rm{Bn}}=10 ).
Figure 10

Velocity distribution in the vertical section of the vessel for different impeller designs ( Re = 100 , Bn = 10 ).

Figure 11 Velocity distribution in the horizontal section of the vessel for different impeller designs ( Re = 100 \mathrm{Re}=100 , Bn = 10 {\rm{Bn}}=10 ).
Figure 11

Velocity distribution in the horizontal section of the vessel for different impeller designs ( Re = 100 , Bn = 10 ).

Figure 12 illustrates the streamline outline inside the stirred tank for diverse designs of impellers. In the first case, the streamlines exhibit remarkable similarity along the vessel, indicating the dominance of tangential flows due to the implementation of the classical anchor impeller. This observation shows a stagnation of fluid flow within the vessel under these conditions. However, in the second and third cases, a significant alteration in the fluid flow structure is observed. There is a noticeable transition of streamlined direction from horizontal to axial orientations, indicating the creation of an axial flow within the stirred tank. This axial flow pattern enhances the circulation of fluid within the mixing system. An increase in the velocity and improvement in the mixing operation by expanding the well-moving zone inside the stirred tank can be seen. Especially with Case 3, we found that it has an important effect on improving the flow pattern, in addition to reducing the power consumption during the mixing process.

Figure 12 3D streamline outlines in the whole vessel.
Figure 12

3D streamline outlines in the whole vessel.

Figure 13 shows the power consumption as a function of the Reynolds number at diverse geometrical configurations. It is readily apparent that Case 3 possesses a noteworthy advantage over the other cases due to its remarkably low energy consumption. The disparity in energy usage becomes strikingly evident, as Case 3 consumes a mere fraction of the energy consumed by the alternative cases. In fact, the energy consumption of Case 3 is five times lower when compared to the energy consumption of the other cases. This significant discrepancy in energy efficiency highlights the substantial benefits offered by Case 3, making it a highly favorable choice in terms of minimizing energy requirements and optimizing overall operational costs.

Figure 13 Power consumption as a function of a Reynolds quantity for different geometrical configurations.
Figure 13

Power consumption as a function of a Reynolds quantity for different geometrical configurations.

6.3 Effect of blade number

In this section, the effect of blade numbers on the hydrodynamic structure (flow pattern, well-moving zone, and power consumption) is represented. In this part of the study, the number of blades increased for the geometrical configurations (Cases 1–3) to obtain new three geometrical configurations (Cases 4–6). Each configuration has four blades.

Based on the findings depicted in Figure 14, it is evident that increasing the number of blades has a notable effect on enlarging the well-moving zone. Among the compared cases, Case 6 emerges as the optimal configuration for enhancing the flow pattern. Notably, Case 6 exhibits the widest sheared zone, extending from the impeller plane to the vessel wall.

Figure 14 Velocity distribution on the vessel (3D and 2D views) for different geometrical configurations with four blades.
Figure 14

Velocity distribution on the vessel (3D and 2D views) for different geometrical configurations with four blades.

Figure 15 clearly demonstrates the energy consumption across different geometrical configurations, where it becomes evident that the power values remain consistent across the entire range of Reynolds Numbers ( Re = 0.1 100 ). Notably, an increased number of blades has a significant impact on accelerating the velocity field within the vessel and expanding the well-moving zone. However, it is noteworthy that despite these variations in flow characteristics, all of the geometrical arrangements exhibit the same energy consumption. The Case 6 configuration stands out as the most efficient choice, as it not only exhibits the same energy consumption as the other configurations but also boasts the largest well-moving zone in comparison. This combination of factors makes Case 6 the optimal configuration, offering both energy efficiency and an expanded region of effective fluid movement.

Figure 15 Power consumption as a function of a Reynolds quantity for different geometrical configurations ( Bn = 10 {\rm{Bn}}=10 ).
Figure 15

Power consumption as a function of a Reynolds quantity for different geometrical configurations ( Bn = 10 ).

6.4 Effect of plasticity

The impression of plastic parameter Bn on the dynamical characteristics of the mixing system is presented in this section. This investigation is performed for various geometry configurations under the effect of various plasticity values Bn = 1 , 10 , 100 , and 500 .

From the results shown in Table 3, it was found that for low Bingham numbers ( Bn = 1 10 ), the geometry configuration of Case 1 has low energy consumed about 367.5 compared to the rest geometry configurations in Cases 2 and 3. For high plasticity value ( Bn = 100 500 ), the geometry configuration of Case 2 was less energy-consuming compared with other cases. It can be noted that the anchor agitator of Case 1 is efficient for low plasticity range values, while Case 2 is more efficient for the high plasticity range values.

Table 3

Power consumption versus plasticity parameter values ( Bn = 1 500 ) for different geometry configurations

Bn Np (power consumption)
Case 1 Case 2 Case 3
1 367.5 460.19 399
10 691.7 683.5 649
100 2132.6 1495.6 3,029
500 10,493 6731.9 11,181

Figures 1618 show velocity distribution along with the stirred tank for Cases 1, 2, and 3, separately. From the consequences, it can be observed from all cases that with a high value of plasticity ( Bn = 100 , 500 ), a low circulation of fluid flow has been remarked inside the vessel, whereas the decrease in the plasticity value was accompanied by a rise in the circulation along with the stirred system for all cases geometry. In addition, it can be observed that the anchor agitator in Case 3 has a significant impact on flow acceleration, indicating that it is effective in all of the cases investigated in this study.

Figure 16 Velocity distribution along with the stirred container (vertical and horizontal sectors) Case 1 with diverse plasticity amounts Bn (1–500).
Figure 16

Velocity distribution along with the stirred container (vertical and horizontal sectors) Case 1 with diverse plasticity amounts Bn (1–500).

Figure 17 Velocity distribution along with the stirred container (vertical and horizontal sectors) Case 2 with diverse plasticity quantities Bn {\rm{Bn}} (1–500).
Figure 17

Velocity distribution along with the stirred container (vertical and horizontal sectors) Case 2 with diverse plasticity quantities Bn (1–500).

Figure 18 Velocity distribution along with the stirred container (vertical and horizontal sectors) Case 3 with diverse plasticity quantities Bn {\rm{Bn}} (1–500), when Re = 1 \mathrm{Re}=1 .
Figure 18

Velocity distribution along with the stirred container (vertical and horizontal sectors) Case 3 with diverse plasticity quantities Bn (1–500), when Re = 1 .

7 Conclusion

In this work, the hydrodynamic behavior of viscoplastic liquid within the stirred container has been investigated numerically. The study was undertaken for different inertia values ( Re = 0.1 , 1 , 10 , and 100 ) and plasticity ( Bn = 1 , 10 , 100 , and 500 ). The following is an overview of our study’s findings:

  • The increase in inertia value gives a considerable improvement in the movement zone along with the mixing tank, as was seen in the distribution of streamlines.

  • At low plasticity parameter values ( Bn = 1 and 10 ), a significant circulation was observed inside the stirred system, as well as a decrease in the moving zone accompanied by a rising plasticity value ( Bn = 100 and 500 ).

  • For low plasticity parameter values ( Bn = 1 and 10 ), Case 1 is deemed the most efficient in terms of energy consumption. Conversely, for high plasticity values ( Bn = 100 and 500 ), Case 2 is considered the most efficient.

  • The influence of geometrical modification of the anchor impeller shape on the main parameter of mixing flow is obvious in terms of power consumption and flow pattern. Case 3 has been found to be the less energy-consuming case by five times, i.e., Case 1 and Case 2 with Np = 5 and Case 3 with Np = 1 , and notably, in blade shape from the straight to the curved design, there is a big impact on the acceleration of flow inside the vessel, especially with Case 3.

  • Case 3 is characterized by a big influence on flow circulation and low energy consumption, and therefore, the anchor impeller of Case 3 could be chosen as sufficient for obtaining the best performance.

Acknowledgments

The researchers would like to express their heartfelt appreciation to the Islamic University of Madinah, Saudi Arabia for the support provided to this research work.

  1. Funding information: The researchers would like to express their heartfelt appreciation to the Islamic University of Madinah, Saudi Arabia for the support provided to this research work.

  2. Author contributions: All authors have accepted responsibility for the entire content of this manuscript and approved its submission.

  3. Conflict of interest: The authors state no conflict of interest.

  4. Data availability statement: All data generated or analyzed during this study are included in this published article [and its supplementary information files].

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Received: 2023-03-27
Revised: 2023-09-07
Accepted: 2023-11-19
Published Online: 2023-12-28

© 2023 the author(s), published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

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https://doi.org/10.1515/rams-2023-0156
Keywords for this article
mixing; yield stress fluid; curved anchor impeller; stirred tank; power consumption
Creative Commons
BY 4.0

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