Acta Polytechnica


doi:10.14311/AP.2014.54.0325
Acta Polytechnica 54(5):325–332, 2014 © Czech Technical University in Prague, 2014

available online at http://ojs.cvut.cz/ojs/index.php/ap

IMPROVING SPECIFIC POWER CONSUMPTION
FOR MECHANICAL MIXING OF THE FEEDSTOCK

IN A BIOGAS FERMENTER BY MECHANICAL
DISINTEGRATION OF LIGNOCELLULOSE BIOMASS

Lukáš Krátký∗, Tomáš Jirout

Czech Technical University in Prague, Faculty of Mechanical Engineering, Department of Process Engineering,
Technicka 4, 166 07 Prague 6, Czech Republic

∗ corresponding author: Lukas.Kratky@fs.cvut.cz

Abstract. Lignocellulose biomass particles in a biogas fermenter batch either sediment towards the
bottom of the vessel or rise towards the batch surface, where they float and form a compact thick
scum. These processes have a basically negative influence on batch homogeneity, on evenness of the
batch temperature field, on the removal of biogas bubbles from the liquid batch, and also on mass
transfer among the microorganisms. These issues result in inefficient usage of the energy potential of
the biomass, and lead to low biogas yields. Good mixing of the bioreactor batch is very important for
stabilizing the anaerobic digestion process. The aims of our study were to evaluate the impact of the
disintegration and hydration of wheat straw on the hydrodynamic behaviour and on the specific power
consumption for mechanical mixing of a wheat straw-water suspension. On the basis of the experimental
results, it was concluded that both hydration and mechanical disintegration of lignocellulose biomass
significantly improve the homogeneity and the pumpability of biomass-water batches. Wheat straw
hydration by itself reduces the specific power consumption for batch mixing by 60 % in comparison
with untreated straw. In addition, mechanical disintegration reduces the specific power consumption
by at least 50 % in comparison with untreated hydrated straw.

Keywords: fermenter, lignocellulose biomass, mixing, specific power consumption, wheat straw.

1. Introduction
Anaerobic digestion of organic wastes, residues and
energy crops offers a very interesting option for gen-
erating biogas and also for reducing the amount of
wastes that need to be disposed of. Methane-rich
biogas has a high potential to replace natural gas, or
it can be used as a feedstock for producing of chemi-
cals and other materials [1]. Biogas production has
also been evaluated as one of the most energy-efficient
and environmentally beneficial technologies for bio-
energy production [2]. Many types and concepts of
agricultural biogas plants are currently applied, but
an anerobic fermenter remains the crucial element in
any kind of anaerobic technology. The vertical stirred
tank fermenter is the most widely-used reactor config-
uration employed for wet anaerobic fermentation [3].
Batch mixing by filling in new substrate, by thermal
convention flow, and by raising gas bubbles is usu-
ally not sufficient for an agricultural biogas fermenter.
In addition, untreated or unprocessed lignocellulose
biomass feedstock is bulky, difficult to feed into the
fermenter, and floats on the batch surface, where it
almost always forms a compact thick scum [1]. Active
batch mixing therefore needs to be implemented in or-
der to bring the microorganisms into contact with the
new feedstock, to facilitate the upflow of gas bubbles,
to achieve constant temperature conditions through-
out the fermenter, to prevent particle sedimentation

on the bottom of the vessel, and to prevent particle
floating and scum formation on the surface of the
batch [1, 4, 5].

Up to 90 % of biogas plants use mechanical stirring
equipment [1]. Mechanical mixing systems for biogas
fermenters are based on the use of impellers, which
can be categorized according to their revolutions as
slow-running or fast-running. Fast-running impellers
run mostly 1–10 times per day with agitation times of
5–60 min, whereas slowly rotating paddles mainly run
continuously [2, 3]. Submerged motor propeller stir-
rers are most often applied. They can be adjusted to
the height, to the tilt, and to the side [2]. Depending
on the size and the substrate type of the fermenter,
multistage mixing systems with up to four impellers
in a vertical stirred tank fermenter are needed in order
to prevent floating scum and sediments [1, 2]. If a
fermenter is operated at a high solid concentration,
slowly rotating paddle stirrers are preferred, with a
horizontal, vertical, or diagonal axis and large scale
paddles [1, 5]. Axial stirrers are mounted on shafts
that are centrally installed on the ceiling of the di-
gester. They form a steady stream in the digester
that flows from the bottom up to the walls, result-
ing in very efficient homogeneity of solid substrates
with manure or recycled process water. The typical
size of a completely mixed fermenter is in the range
from 1000 to 4000 m3 reactor volume [1]. The spe-
cific power consumption of a central mixing system

325

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Lukáš Krátký, Tomáš Jirout Acta Polytechnica

(A) Untreated straw. (B) Milled straw.

Figure 1. The wheat straw particle sizes used in the experiments.

equipped with fast running impellers is usually in the
range of 40–70 W m−3, and the specific power con-
sumption of slowly-rotating paddle stirrers is about
10 W m−3 [5].

Good mixing of a biogas reactor batch is very im-
portant in order to stabilize the anaerobic digestion
process. On the basis of the information above, it
was supposed that biomass hydration and biomass
size reduction would prevent lignocellulose particles
sedimentating or floating on the batch surface, would
improve batch pumpability, would reduce the impeller
rotational speed for sufficient batch homogeneity, and
would therefore also reduce the specific consumption
for mixing. The aims of our study were therefore
to evaluate the impact of lignocellulose biomass pre-
treatment by mechanical disintegration and the in-
fluence of lignocellulose biomass hydration on the
hydrodynamic behaviour and also the specific power
consumption for mechanical mixing of a lignocellulose
biomass-water suspension.

2. Materials and methods
2.1. Raw material
Wheat straw was used in the experiments. Untreated
straw 40–200 mm in length was cut in the field by
a combine harvester, and collected and stored indoors
in containers at ambient temperature for 4 years before
the tests. The total solid content was determined to be
93 % wt., and the volatile solid content was 88 % wt.
The total solid content was investigated by drying
5 reference samples in a KBC-25W oven overnight at
a temperature of 105 °C. The volatile solid content
was investigated by burning dried reference samples
in an LE 09/11 furnace at the temperature of 550 °C
up to constant mass of the samples. The mass of
the material was measured using an SDC31 analytic
balance.
To be able to evaluate the impact of wheat straw

pre-treatment by mechanical disintegration, and the
impact of wheat straw hydration, on the hydrody-
namic behaviour of a mechanically mixed straw-water

batch, the length of the untreated straw had to be
reduced with the respect to the experimental layout of
mixing system. The reduced untreated straw length
was intended to provide a pulpy substance in an aque-
ous suspension, but at the same time to prevent the
suction area of the impeller becoming blocked. Two
reference straw samples of different length were used
in the experiments, see Fig. 1. The first reference sam-
ple comprised untreated straw particles approximately
30 mm in length, see Fig. 1A. This length was achieved
by cutting the untreated straw by hand, using scis-
sors. The second reference sample was pre-treated
straw, which was reduced in size by mechanical disin-
tegration. The untreated straw was first hydrated in
hot water at a temperature of 40 °C for 20 minutes.
Moisture content of 40 % wt. achieved for the wheat
straw. Then the wet wheat straw was mechanically
disintegrated using a Retting mill [6] to straw particle
sizes less than 10 mm, see Fig. 1B. The Retting mill
is a new type of shredder, which is efficiently and
continuously able to reduce wet fibrous biomass in
size [7]. The two reference samples were dried, and
were used to prepare the tested suspensions.

2.2. Mixing system
All experiments were carried out in a glass cylindrical
vessel with a flat bottom. The diameter of the vessel
was equal to D = 300 mm, and the liquid level was
H = D, see Fig. 2A. Four radial baffles b = 0.1D in
width were used in the experimental layout. A pitched
six-blade turbine d = 100 mm in diameter and with
blade width h = 0.2d was used in the experiments, see
Fig. 2B. The height of the impeller above the bottom
of the vessel varied during the experiments in the
heights of H2 = 1d and H2 = 2d. The impeller was
operated to pump the suspension both down towards
the bottom of the vessel and up towards the surface.

2.3. Suspensions
Three types of suspensions were used in the exper-
iments. The suspensions were prepared from water

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vol. 54 no. 5/2014 Improving Specific Power Consumption For Mechanical Mixing

(A) Position of the impeller in the vessel. (B) A pitched six-blade turbine.

Figure 2. Experimental layout.

(A) SUS1 – untreated, dry. (B) SUS2 – untreated, hydrated. (C) SUS3 – milled, hydrated.

Figure 3. Behaviour of stationary wheat straw in a non-mixed aqueous suspension.

and untreated straw (SUS1), from untreated hydrated
straw (SUS2) and from milled hydrated straw (SUS3),
all with 1 % wt. of total solids of straw. The mass of
the material was measured using a Kern FKB labora-
tory balance.

The behaviour of suspension SUS1 in the vessel in
the non-mixed steady state was that all straw particles
floated on the surface of the batch due to the density of
the straw, which was lower than the density of the liq-
uid. These straw particles therefore created a compact
floating scum on the surface of the batch, see Fig. 3A.
Suspension SUS2 comprised untreated straw particles,
also 30 mm in length. However, the untreated straw
was first hydrated in water at a process temperature
of 60 °C for residence time of 1 hour before it was used.
Suspension SUS3 comprised milled straw particles less
than 10 mm in length. These particles were also first

hydrated in water under a processing temperature
of 60 °C for residence time of 1 hour before it was
used. As is shown in Figs. 3B and 3C, straw hydra-
tion caused partial sedimentation of the material in
the vessel in the non-mixed steady state. However,
a certain proportion of the straw, which was lighter
than the liquid, again rose to the surface of the batch,
where it formed a floating scum.

3. Fluid flow properties
of a milled and hydrated
wheat straw-water suspension

3.1. Rheological properties
The rheological properties for SUS3 (a milled and hy-
drated wheat straw suspension) were determined on
the basis of a measurement of the power consumption

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Lukáš Krátký, Tomáš Jirout Acta Polytechnica

(A) The geometry of the system. (B) The equipment.

Figure 4. Experimental setup for the investigation of rheological properties.

Figure 5. Dependence of shear stress on shear flow of suspension SUS3.

for a stirred impeller with a defined power charac-
teristic. The experiments were carried out in a glass
cylindrical vessel with a flat bottom 150 mm in inner
diameter D, and the liquid level was H = D. A stan-
dardised anchor agitator with D/d = 1.11, h/d = 0.12,
HV/D = 0.8 and H2/d = 0.055 was used in the ex-
periments, see Fig. 4. Sufficient homogeneity of the
batch mixing was achieved during the experiments in
the creeping flow regime.
An RC20 Rheometer was used for the torque mea-

surement. The rheometer makes direct measurements
of torque MK for adjusted impeller speed n. On the
basis of this data, power consumption P was calcu-
lated as follows:

P = 2πnMK. (1)

It was also necessary to evaluate dimensionless power

number PO for an investigation of the rheological
properties of a mixed batch:

PO =
P

ρn3d5
. (2)

Based on knowledge of the power characteristic for
the anchor impeller, which is expressed by the correla-
tion equation published e.g., in [8], the corresponding
Reynolds number Re values were determined by com-
paring the calculated Po values with the characteristic.
Then, using the Reynolds number values, the effective
viscosity µef was calculated as follows:

Re =
ρnd2

µef
therefore µef =

ρnd2

Re
. (3)

It is generally known that the effective viscosity value
is in accordance with the apparent viscosity value η

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vol. 54 no. 5/2014 Improving Specific Power Consumption For Mechanical Mixing

Figure 6. Dependence of power consumption on impeller speed.

at effective shear rate γ, which can be calculated on
the basis of Metzner and Otto [8]:

γ = kn. (4)

The k value generally depends both on the type of
impeller and on the geometrical configuration of the
mixing system. A k value equal to 15.8 is given for
this configuration [8]. Based on these calculations, the
dependence of shear stress on shear rate was plotted
according to this equation:

τ = Kγm, (5)

see Fig. 5.
A power-law model was used to describe the rheo-

logical properties of the wheat straw-water mixing sys-
tem. Using the least square method, the consistency
coefficient and the power-law index were calculated
for the power-law rheological model, as follows:

τ = 4.0735γ0.76. (6)

The rate of reliability R was equal to 0.97. The re-
sults clearly show that suspension SUS3 evinces non-
Newtonian behaviour that is characterized by a consis-
tency coefficient K of 4.07 Pa sm and a dimensionless
power-law index m of 0.76.

3.2. An investigation of the fluid flow
regime

The fluid flow regime is generally dependent both on
the rheological properties of the batch and on the set
up of the process parameters and the geometry of the
mixing system. As has been shown, the milled and hy-
drated straw in a suspension evinced non-Newtonian
behaviour. However, this property strongly affects the
effective viscosity value, and thereby the power con-
sumption during mixing. It is generally known that

the fluid flow in a batch depends on the Reynolds num-
ber, which is defined according to (3). Three types
of fluid flow during mixing are known, i.e., creeping
flow, transitional flow and turbulent flow. To be able
to evaluate the existence of turbulent or creeping flow
during batch mixing, the following considerations were
taken into account. The power consumption gener-
ally depends on the power number, the density of
the suspension, the impeller speed and the impeller
diameter:

P = POρn3d5. (7)
According to the theory of mixing [8], the power num-
ber is inversely proportional to the Reynolds number
during the creeping flow regime:

PO =
A

Re
. (8)

Using the definition of the Reynolds number in (3),
where the effective viscosity is replaced by the power-
law model

µef = Kγm−1 (9)
and the shear rate is replaced by (4), the dependence
of the power consumption on the impeller revolutions
and on the impeller diameter is derived:

P = Bn1+md3, (10)

where constant B is defined as

B = AKkm−1. (11)

Based on the derived formula (9) and assuming the
same geometry of the mixing system, it was con-
cluded that the power consumption generally de-
pends on the (1 + m)th power of the impeller rev-
olutions during creeping fluid flow, i.e., on the revo-
lutions powered to 1.76 for the tested batch. How-
ever, the power number is constant in the turbulent

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Lukáš Krátký, Tomáš Jirout Acta Polytechnica

Figure 7. A comparison of the specific power consumption levels for the tested configurations and suspensions. PTB
– the impeller pumps towards the bottom of the vessel; PTS – the impeller pumps towards the surface of the batch

fluid flow regime [8], so the power consumption is
dependent on the impeller revolutions to the power
of three.
The fluid flow regime in the batch was experimen-

tally verified on the basis of these formulations. Tak-
ing into account the complete geometry of the tested
mixing system described in section 2.2, the fluid flow
regime was investigated for a baffled glass cylindrical
vessel 150 mm in diameter equipped with a six pitched-
blade turbine. A high-precision RC20 Rheometer was
used for the torque measurements. Several powers
were calculated by (1) by measuring the torque MK
for the adjusted impeller speed n. The impeller speeds
were chosen for the state when sustainable batch ho-
mogeneity was reached.

The dependence of power consumption on impeller
revolutions is depicted in Fig. 6. Using the LSM
method, the power-law dependence of power consump-
tion on impeller speed was fitted to the data. The
regression equation of the power-law curve showed
that the power consumption depends on the impeller
revolutions powered to 2.98 with a rate of reliability
equal to 1. Finally, the exponent with a value of 2.98
fully corresponds with turbulent flow regime theory,
where a theoretical value of 3 is defined. We will now
use the theory for scaling up according to the specific
power, defined as follows:

nd2/3 = const. (12)

On the basis of this formula, it is clear that a higher
Reynolds number was reached in the vessel 300 mm in
diameter than in the vessel 150 mm in diameter. All
the experiments in the 300 mm vessel were therefore
shown to have been carried out in a turbulent fluid
flow regime.

4. Results and discussion
The specific power consumption was determined on
the basis of the findings for the minimum impeller
rotational speed for sufficient batch homogeneity and
for the corresponding torque. The turbulent suspen-
sion flow was studied visually during batch mixing on
the bottom of the vessel, at the level of the suspen-
sion along the baffles, and also on the batch surface.
Sufficient batch homogeneity was defined as the state
in which the straw particles do not remain for a short
time period (approximately 2 s) at all the places men-
tioned above. The minimum impeller rotational speed
for sufficient batch homogeneity was recorded as soon
as sufficient batch homogeneity was reached. The im-
peller rotational speed was measured using a Siemens
1XP8001 electronic counter, and the minimum im-
peller revolutions for sufficient batch homogeneity
were visually determined with accuracy of ±5 %. The
torque was measured by a DR1 torsion shaft angle sen-
sor, manufactured by Lorentz MessTechnik. The data
was recorded using an A/D converter to the PC, and
was recalculated using the calibration function to the
torque values. Based on knowledge of the minimum
impeller rotational speed for batch homogeneity nM
and on knowledge of the corresponding torque MKM,
the power and also the specific power consumption
were calculated:

PM = 2πnMMKM, (13)

� =
PM
V
. (14)

A comparison of the specific power consumption
on the suspension type of mixing system and on the
geometrical configuration is shown in Fig. 7. Fig-
ure 8 shows the state of the suspension at the min-
imum impeller rotational speed for sufficient batch

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vol. 54 no. 5/2014 Improving Specific Power Consumption For Mechanical Mixing

(A) SUS1 – untreated. (B) SUS2 – untreated, hydrated. (C) SUS3 – milled, hydrated.

Figure 8. The homogenized batch at H2/d = 2 with the impeller pumping to the batch surface.

homogeneity for the configuration of the mixing sys-
tem H2/d = 2 and with the impeller pumping to
the batch surface. The maximum specific power
consumption value of 1531 W m−3 was reached dur-
ing mixing of suspension SUS1 (untreated straw) for
the bottom pumping impeller located at a height of
H2/d = 1. The reason is that the wheat straw parti-
cles floated only on the batch surface (Fig. 3A). A very
high impeller revolution of 730 min−1 was therefore
needed to drag them from the surface into the liq-
uid batch and to achieve sufficient batch homogene-
ity.

The maximum specific power consumption value of
321 W m−3 was reached while mixing suspension type
SUS2 (untreated, hydrated straw) for the impeller
pumping to the batch surface and its location at a
height of H2/d = 1. Sufficient batch homogeneity was
observed at an impeller rotational speed of 402 min−1.
On the basis of a visual study of the mixed batch,
it was observed that partial plugging of the impeller
suction area, caused by a high local concentration of
solid phase, was the main influence on the specific
power consumption value. However, if the impeller
pumped to the bottom of the vessel, the main limi-
tation on achieving sufficient batch homogeneity was
getting the floating straw at the batch surface into
the liquid level. No straw sedimentation was observed
at the bottom of the vessel for an impeller revolution
of 150 min−1, but the suspension flow in the vessel
did not affect the flow around the batch surface. The
size of the primary circulation loop was gradually in-
creased with increasing impeller revolutions, and more
intensive turbulent macro vortices were gradually gen-
erated. The floating straw was therefore dragged from
the surface into the liquid batch at impeller revo-
lution 307 min−1, with corresponding specific power
consumption of 199 W m−3.

Based on the comparison of the specific power con-
sumptions on the suspension type and on the geo-
metrical configuration of mixing system (Fig. 7), it
can be concluded that the low energy demanding con-
figuration of the presented mixing system has the
impeller located at a height of H2/d = 2. The main
factor, which has a strong influences on the specific
power consumption value, is the hydrodynamic action
of the impeller in the presence of solid phase. The
trbulent vortices that are formed close to the batch
surface around the impeller easily that the floating
straw particles are got into the liquid level. However,
if the impeller is located at a height of H2/d = 1,
a very high impeller revolution is needed to gener-
ate these vortices around the batch surface. Based
on a comparison of the data for the position of the
impeller at a height of H2/d = 2, it can be con-
cluded that pumping to the bottom of the vessel and
to the batch surface have practically no influence on
the specific power consumption. The measured spe-
cific power consumptions were 166 W m−3 for SUS1
(untreated straw), 66 W m−3 for SUS2 (untreated, hy-
drated straw), and 34 W m−3 for SUS3 (milled, hy-
drated straw).

However, all specific power consumptions mentioned
above are slightly higher than real values. It was visu-
ally observed that both the non-milled and the milled
straw particles had a tendency to cover the impeller
blades. This effect primarily caused an increase in
fluid flow resistance that leads to an increase in power.
However, the effect of centrifugal forces effectively re-
moved the straw particles from the blades. Based on
this information, it can generally be concluded that
straw hydration reduces the specific power consump-
tion by 60 % for untreated straw, while a combination
of straw pre-treatment by mechanical disintegration
and by hydration decreases the specific power con-

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Lukáš Krátký, Tomáš Jirout Acta Polytechnica

sumption by 80 % for untreated straw. Mechanical
disintegration itself decreases the specific power con-
sumption by 50 %, at least for untreated hydrated
straw.

5. Conclusions
Based on the experimental results, it has been con-
cluded that both hydration and mechanical disintegra-
tion of lignocellulose biomass significantly decreased
the specific power consumption for achieving a homo-
geneous biomass-water suspension.

• Hydration and mechanical disintegration of ligno-
cellulose biomass significantly improve the homo-
geneity and pumpability of biomass-water batches.

• A milled and hydrated wheat straw-water suspen-
sion evinces non-Newtonian behaviour with a power-
law index equal to 0.76.

• Straw hydration by itself decreases the specific
power consumption by 60 % for untreated straw.

• Combined straw pretreatment by mechanical dis-
integration and by hydration reduces the specific
power consumption by 80 % for untreated straw.

• Mechanical disintegration by itself reduces the spe-
cific power consumption by at least 50 % for un-
treated hydrated straw.

List of symbols
A constant [–]
b baffle width [m]
B constant [Pa sm]
d impeller diameter [m]
D vessel diameter [m]
H height of a liquid level [m]
h width of a blade [m]
H2 height of the impeller above the bottom [m]
HV height of the impeller [m]
k Metzner and Otto constant [–]
K consistency coefficient [Pa sm]
m power-law index [–]
MK torque [N m]
MKM torque minimum impeller rotational speed for batch

homogeneity [N m]

n rotational speed of impeller [s−1]
nM minimum impeller rotational speed for batch homo-

geneity [s−1]
P power consumption [W]
PM power consumption at minimum impeller rotational

speed for batch homogeneity [W]
Po power number [–]
R rate of reliability [–]
Re Reynolds number [–]
V volume of suspension [m3]

µef effective viscosity [Pa s]
γ shear rate [s−1]
� specific power [W m−3]
η apparent viscosity [Pa s]
ρ density of suspension [kg m−3]
τ shear stress [Pa]

References
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2010, 85, pp. 849-860.

[2] Schulz, H., Eder, B.: Bioplyn v praxi. Ostrava: HEL
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[3] Pandey, A.: Handbook of plant-based biofuels. In CRC
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[4] Chanakya, H.N., Srikumar, K.G., Anand, V., Modak,
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[5] Jirout, T., Rieger, F., Moravec, J.: Studie míchání
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[6] Krátký, L., Jirout, T. and Nalezenec, J.: Lab-scale
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[7] Slabý, F., Nalezenec, J., Krátký, L., Maroušek J.:
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332


	Acta Polytechnica 54(5):325–332, 2014
	1 Introduction
	2 Materials and methods
	2.1 Raw material
	2.2 Mixing system
	2.3 Suspensions

	3 Fluid flow properties of a milled and hydrated wheat straw-water suspension
	3.1 Rheological properties
	3.2 An investigation of the fluid flow regime

	4 Results and discussion
	5 Conclusions
	List of symbols
	References