AP02_3.vp


1 Introduction
A planar description of fluid flow caused by a rotational

axial impeller in a stirred vessel equipped with radial baffles is
usually interpreted by means of a one-loop circulation model.
In the case of a pumping-down axial impeller, the flow is
directed towards the bottom of the tank. On the bottom, the
fluid diverges, changing its direction, and then travels upward
along the vessel wall. At the top of the tank, the fluid is
directed radially inward and then redirected down to the
impeller, closing the circulation loop. However, the real liquid
flow inside a tank constitutes a pseudo-stationary high-
-dimensional dynamical system. Laser Doppler Velocimetry
(LDV) and Particle Image Velocimetry (PIV) measurements
of the velocity field in stirred vessels revealed the occurrence
of a secondary circulation loop near the bottom of the vessel,
Kresta and Wood [1] and Myers et al [2]. It was observed

further that in the upper third of the vessel the fluid
circulation was low and the main circulation loop was instable.
Pseudo-periodic flow in the shape of a macro-vortex was
detected in this region (see Fig. 1). This phenomenon was also
noticeable visually, and it was dependent on stirrer diameter
and impeller off-bottom clearance. The measure of these
macro-vortices was comparable with the scale of the vessel
and this phenomenon was called macro-instability (MI) of the
velocity field. Knowledge of the mechanism of the origin and
scale of MI is of great practical importance. Macro-vortices
improve the mixing in the upper part of the vessel, but they
also act negatively on the vessel walls, baffles, impeller shaft,
and other solid parts. In addition, the uneven vibration
influences the fixation of the apparatus. In extreme cases, it
could damage the equipment, Kratěna et al [3].

In the turbulent region of mixing, the presence of macro-
-vortices in the stirred vessel appears as a swollen surface of
the liquid, obviously different from the wavy surface result-
ing from turbulence eddies. Brůha et al [4] looked at the
frequency of MI occurrence according the movement of the
liquid surface using 3, 4, and 6 bladed PBT. Their investigat-
ions covered two impeller diameters (D � T/3 and T/4) and
three different off-bottom clearances (T � 0.3 m, C/T � 0.33,
0.4 and 0.5). Based on visual observation, they defined the
occurrence of a macro-vortex as a situation during which the
liquid surface swells up for more than 5 mm (under their
operational conditions) close to the baffle. They found out
experimentally that the occurrence of the macro-vortex is
dependent on the number of wall baffles, on the number of
stirrer blades and on the stirrer frequency. An electronic
probe measured the frequency of macro-vortex occurrence
and a linear dependence was found with stirrer frequency. It is
not sufficient to look at the liquid surface from the outside to
understand the origination of macro-vortices, and vortices
that do not reach the surface are not registered.

The authors of the above mentioned study used a mecha-
nical measuring device, developed later, called a “tornado-
meter”, which enabled the frequency of MI inside the vessel to
be measured (Brůha et al [5, 6]). They confirmed their

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Acta Polytechnica Vol. 42  No. 3/2002

Macro-instabilities of a Suspension in an
Axially Agitated Mixing Tank

M. Jahoda, V. Machoň, L. Vlach, I. Fořt

This paper deals with an experimental assessment of the occurrence of flow macro-instabilities in a mechanically stirred suspension and
visual observation of the origination and extinction of macro-vortices. The mean frequency of the occurrence of macro-instabilities in
operational conditions was also observed. The experiments were carried out in a cylindrical vessel with an inner diameter of 0.19 m, and an
axial stirrer with six pitched 45° blades (PBT) was used. The diameter of the stirrer was equal to half of the vessel diameter. The mean
frequencies of the occurrence of macro-instabilities were determined at the stirrer frequency for just suspended conditions in dependence on
solids concentration and impeller clearance (height of the stirrer above the bottom of the vessel).
Two regions of origin of macro-instabilities and one region of extinction were determined visually. It was found that the mean frequency of
occurrence of macro-instabilities increases with increasing stirrer frequency at constant concentration of solids. At constant stirrer speed, the
frequency of occurrence of macro-instabilities decreases with increasing concentration of solids. At higher concentration of solids, a sharp
change toward lower mean frequencies of macro-instabilities was observed.

Keywords: suspension, mixing, macro-instabilities.

Fig. 1: Flow patterns in a vessel stirred by an axial impeller. Main
circulation loop I, secondary circulation loop II, macro-
-vortex III.



previous finding that the mean MI frequency is linearly
related to the rotational speed of the impeller. The impeller
off-bottom clearance influenced the slope of this dependency.
They also observed that the MI frequency is accompanied by
changes in the angle of the impeller discharge flow and
the appearance of an unstable secondary circulation loop.
Further, the dimensionless MI frequency was defined as the
mean frequency of MI occurrence divided by the frequency
of the stirrer speed, and the dependency of this quantity
on modified Reynolds number, Re, was found in three hydro-
dynamic regimes. In the laminar region of fluid flow in the
vessel (Re < 200), the primary circulation loop was steady and
the MI was not registered. In the transient region of the flow
(200 < Re < 5000), the dimensionless frequency of MI was
found to increase logarithmically with increasing values of Re.
Under fully turbulent conditions (Re > 9000), the values of
MI frequency of occurrence were near to constant in the
range from 0.043 to 0.048. The intensity of the turbulence
increased with increasing Re number, and it was not possible
to distinguish between MI and turbulent eddies during highly
turbulent flow (Re > 67000) . Generally, the measuring
method with a tornadometer is regarded by many authors as
unreliable, because of the presence of the arm inside the
vessel, which could influence the fluid flow.

Montes et al [7] use LDV measurements and spectral
analysis to observe MI frequency occurrence in a stirred tank
equipped with a six-bladed 45° PBT impeller (T � 0.3 m,
D � T/3, C/T � 0.35). The axial and radial components of the
velocity were measured at eight locations situated evenly in
a rectangular net in the stirred region. The measurements
lasted 25 minutes and the time record of the velocity was
analysed by the Fast Fourier Transform (FFT). The dominant
frequency was determined from the frequency spectrum.
The dominant frequencies were proved in all measurement
locations, but the obtained values of the power spectrum
density were not identical. It was concluded that MI are
macroscopic phenomena with a dimension comparable with
the dimension of the apparatus. The results confirmed the
previous finding that the mean frequency of MI increases
linearly with the stirred frequency.

Hasal and Fořt [8] applied a non-linear dynamic system
analysis method to data measured by Montes et al [7]. They
demonstrated the possibility to detect and separate the
low dimensional component of the velocity field from the
stochastic turbulent component. In the velocity field, the
macro-instabilities presented a marked component of kinetic
energy. The presence of MI in the velocity record was more
distinct in laminar and transient flow regimes. The macro-
-instabilities were poorly manifested in the discharge flow
of the impeller, where their relative magnitude takes on
a minimal value. The authors deduced possible production of
MI from the interaction of the impeller discharge stream
and the ascending circulation streams.

Roussinova and Kresta [9] analysed the LDV time series
of axial velocities upstream of the baffle using the Lomb algo-
rithm as an alternative method to FFT for the case of un-
evenly spaced data. They found a dominant MI frequency of
0.62 Hz in a system stirred by a pitched blade 45° tur-
bine (4 blades) with diameter D � T/2 (T � 0.24 m) and
Re � 48 � 104. The impeller off-bottom clearance (C/T � 0.33,
0.5, and 0.67) did not change the value of the dominant

frequency. The dimensionless MI frequency was constant at
0.18 for Re > 104. No dominant frequency appeared for
small PBT (D � T/4) at any impeller off-bottom clearance.

The previous investigations show that the incidence of
macro-instability is very sensitive to vessel geometry and the
procedure of MI frequency determination. Our goal was to
examine experimentally the occurrence of macro-instabilities
in a mechanically stirred system in which the solid particles
were present and fully suspended.

2 Experimental

The experiments were carried out in a stirred cylindrical
baffled vessel with a flat bottom and inner diameter
T � 0.19 m. A sketch of the experimental tank is shown in
Fig. 2. The mixed charge was a suspension in water of solid
particles at room temperature, and the vessel was filled to
the height H � T. An outer square glass tank was filled with
water in order to minimize the effects of vessel curvature on
visual observation. The axial impeller was a pitched blade
turbine (PBT) of diameter D � T/2 with six blades inclined
at 45° (pumping down), and its off-bottom clearances were
C/T � 0.2, 0.3, and 0.4. The width of the blade, h, was one fifth
of the impeller diameter D. The impeller speed, N, was varied
in the range from 75 rpm to 200 rpm. The PVC solid particles
were spherical in shape, diameter 0.94 mm, and density
1260 kg m �3. The solids concentration was changed from
2.5 % to 22.5 % by weight (from 2 % to 18.7 % by volume).
The experiments were done in conditions where the solid
particles were fully suspended or in a condition near to full
suspension. The visual method, Zwietering [10], was used for
assessment of the minimal impeller speed at which the solid
particles were just suspended, Njs.

To investigate MI frequency occurrence, the upper part
of the mixing vessel close to the baffle leading edge
was observed (see Fig. 2). The presence of red colored solid
particles made it possible to observe the appearance of
macro-vortices. A typical spiral shape characterized a fully
developed macro-vortex. A video camera was used to reduce
the spatial view for visual observation. The time between
two successive appearances of macro-vortices was stored in
the computer memory in accordance with a signal from an

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Acta Polytechnica Vol. 42  No. 3/2002

T

C

D

H

Observational

area

Fig. 2: Experimental vessel



operator. For each experimental condition, the recording
time was about 30 min. The reciprocal values of the time
series give the incidence of MI. The mean values of
MI frequency occurrence, fM, and its dimensionless form,
fMI � fM/ N, were then calculated.

3 Results and discussion
During the experiments, two circulation flow patterns

were observed. There was a stable and symmetrical circulation
pattern around impeller speed 65 rpm (C/T � 0.2, 0.3, and
0.4), which resembled the flow described by Kresta and Wood
[1]. The single primary circulation loop reaches a height of
only 2/3 H. This is in agreement with the results presented
by Bittorf and Kresta [11]. If the impeller speed increas-
ed, the stable flow pattern turned into unstable conditions.
The primary circulation loop is unstable and macro flow in-
stabilities begin to appear. An upper part of the mixed vessel
was stirred mainly by means of the macro-vortices. These
vortex structures are able to reach the free surface if they have
sufficient energy. A local swell due to a macro-vortex was
apparent for impeller speed around 200 rpm. This cor-
responds to the description made by Brůha et al [4].

Two regions of origin of macro-instabilities and one
region of extinction were determined visually. The first area of
origin was along the leading edge of the baffle. A stream
moving up beside a baffle usually headed to the impeller area,
but sometimes the flow was accelerated and reached the free
surface or came near to the surface. Macro-vortices developed
from this jet stream (see Fig. 3). Similar macro-vortex creation
was observed by Montes et al [7]. The second area of origin
was located between adjacent baffles at a horizontal distance
0.25 T from vessel wall to shaft (see Fig. 3). The macro-
-vortices were formed on an interface between the ascending
stream of suspension along the vessel wall and the descending
stream that arrived from the baffle trailing edge. The stream
interface was nearly constant in the vertical direction from the
vessel bottom (from 0.45 T to 0.5 T) for impeller speed above
Njs and for all investigated off-bottom impeller clearances.
The horizontal position of the interface was slightly pitched
due to stream that arrived from the baffle trailing edge. The
area of macro-vortex extinction was always in the upper
quadrant of the stirred vessel near the baffle leading edge
and the free surface, and it was not dependent on the macro-
-vortex origin. The frequency of macro-vortex occurrence was
in the range from 0.5 to 2 s�1.

The dependence of the mean value of the dimensionless
frequency of macro-instability occurrence on impeller speed
for constant solid concentration 10 % by weight is shown in
Fig. 4. The figure exposes some influence of the amount
of solid particles in suspension on macro-vortex detection.
The minimal impeller speed for full suspension of solid
particles, determined by Zwietering’s method, was found to
be 135 rpm. This method is very dependent on the opinion of
an observer. It seems that the real value of Njs ranged from
135 to 150 rpm. For higher impeller speed, the solid particles
were fully suspended and the dimensionless frequency values
of MI are practically steady. This behaviour conforms with
a one-phase system in which the dimensionless MI frequency
scarcely changes in the region of developed turbulence.

The dependence of the mean value of the dimensionless
frequency of macro-instability occurrence on solid
concentration for constant impeller speed is shown in Fig. 5.
The solid particles were in the fully suspended state. There is

5

Acta Polytechnica Vol. 42  No. 3/2002

Fig. 3: Sketch of origin of macro-instabilities.
1a) The area of origin was along the leading edge of the

baffle.
1b) Area of origin between two adjacent baffles.
1c) Fully developed macro-vortex.
2) Ascending stream along the vessel wall.
3) Descending stream arriving from the baffle trailing

edge.
4) Interface between ascending and descending streams.

Fig. 4: Dependence of mean value of dimensionless MI fre-
quency on impeller speed for C � 0.2 T, Njs � 135 rpm,
w � 10 %w/w, 1.4 � 104 < Re < 2.8 � 104



a turning point between solids concentrations 7.5 %w/w and
10 %w/w. Solid particles above a concentration of 7.5 %w/w
greatly influenced the fluid flow inside the vessel. From visual
observation, it was apparent that the flow patterns were more
stable in the case of higher solids concentrations than at lower
concentrations.

Figure 6 depicts the dependence of the mean value of the
dimensionless frequency of macro-instability occurrence on
solid concentration for minimal impeller speed when the
solid particles were just suspended. The values of

dimensionless MI frequency were very similar for the two
off-bottom clearances, C � 0.2 T and 0.3 T, above all when the
solids concentration was higher than 7.5 %w/w. In the case of
impeller off-bottom clearance 0.4 T and w > 15 %w/w, the
investigation of macro-vortex incidence could not be carried
out due to a high degree of turbulent eddies.

4 Conclusions
The existence of macro-instability occurrence in the

examined mixing system was proved by visual observation
for a wide range of solid particles concentrations and
three off-bottom impeller clearances. Two regions of origin
of macro-instabilities and one region of extinction were de-
termined. The macro-vortices evolved either in an area along
the leading edge of the baffle or at a location between the

baffles at a horizontal distance 0.25 T from vessel wall to
impeller shaft. The macro-vortices always disappeared in the
upper quadrant of the stirred vessel near the baffle lead-
ing edge and free surface. The frequency of macro-vortex
occurrence was found to be in the range from 0.5 to 2 s�1.
The visual method is very simple but demanding on the
attentiveness of the operator. The mean value of the
macro-instability frequency is linearly related to the impeller
rotational speed for equal concentrations of solids particles.
The mean value of the dimensionless frequency of macro-
-instability occurrence is steady above the minimal impeller
speed for just suspension conditions. At constant stirrer
speed, the frequency of occurrence of macro-instabilities de-
creases with increasing concentration of solids. A turning
point was observed between solids concentrations 7.5 %w/w
and 10 %w/w. At higher concentration of solids, the mean
frequencies of the macro-instabilities were identical. The
results for impeller off-bottom clearances 0.2 T and 0.3 T are
very similar.

5 List of Symbols
C impeller off-bottom clearance, m
D impeller diameter, m
fM mean value of frequency of occurrence of macro-

-instabilities, s�1

fMI mean value of dimensionless frequency of occurrence
of macro-instabilities

H height of suspension in the vessel, m
h width of impeller blade, m
N impeller speed, s�1

Njs minimal impeller speed for just suspended condition,
s�1

Re Reynolds number
T vessel diameter, m
w solid particles concentration by weight

Acknowledgement
This research was financially supported by Research

Projects of the Ministry of Education of the Czech Republic
J19/98:223400007 and J04/98:2122 0008.

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6 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 42  No. 3/2002

Fig. 5: Dependence of the mean value of dimensionless MI
frequency on solid concentration for C � 0.2 T and
N � 150 rpm

Fig. 6: Dependence of the mean value of dimensionless MI
frequency on solid concentration for Njs



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Dr. Ing. Milan Jahoda
phone: +420 2 2435 3223
e-mail: Milan.Jahoda@vscht.cz

Doc. Ing. Václav Machoň, CSc.
Ing. Lubomír Vlach

Dept. of Chemical Engineering
Prague Inst. of Chemical Technology
Faculty of Chemical Engineering
Technická 3, 166 28 Praha 6, Czech Republic

Doc. Ing. Ivan Fořt, DrSc.
phone: + 420 2 2435 2713

Dept. of Process Engineering
Czech Technical University in Prague
Faculty of Mechanical Engineering
Technická 4, 166 07 Praha 6, Czech Republic

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Acta Polytechnica Vol. 42  No. 3/2002