ap-3-12.dvi


Acta Polytechnica Vol. 52 No. 3/2012

Modularity of Pressing Tools for Screw Press Producing Solid Biofuels

Miloš Matúš1, Peter Križan1

1
Slovak University of Technology in Bratislava, Faculty of Mechanical Engineering, USETM,
Nam. slobody 17, 812 31 Bratislava, Slovak Republic

Correspondence to: milos.matus@stuba.sk

Abstract

This paper focuses on the development of the newly-patented structure of a screw briquetting machine for compacting

biomass into a solid biofuel. The design of the machine is based on the results of a comprehensive study of the complicated

process of biomass compaction. The patented structure meets two main goals: the elimination of axial forces, leading

to increased lifetime of the bearings, and the new modular design of a pressing chamber and tools with their geometry

based on the application of a mathematical model.

Keywords: biomass, screw press, compaction process.

1 Introduction

Briquetting biomass by means of screw pressing is
a progressive technology in the production of solid
biofuels. Screw presses offer great advantages in pro-
ducing pressings of high quality, and they represent
the most current and promising technology in the
compaction of biomass to produce briquettes. Re-
search to develop this technology further is a logical
step. Increasing the tool life will reduce operating
costs, and will lead to lower prices for the final prod-
uct, making it a more viable application for biomass
use. Compacting biomass as a live material is very
difficult process. It is necessary to control impor-
tant construction parameters for different kinds of
biomass. The newly-patented structure of a screw
briquetting machine was designed in our department
for this purpose.

2 New design of a screw press

Research results for parameters influencing the pro-
cess of biomass compaction were applied in devel-
oping the design of a new screw press. The design
that has been developed enables the technological
and structural parameters of the compaction process
to be controlled in order to achieve high quality out-
put with various input factors. The requirements for
the development of the structure were as follows:
• Eliminate the axial load of the bearings, and
thus increase their life,

• optimize the tools in terms of shape and material
properties to increase the efficiency of the com-
paction process and to increase their lifetime,

• achieve high modularity of the machine,

• enable all important parameters of the com-
paction process to be managed and controlled,

• ensure that the pressing screw and the pressing
nozzle can be exchanged rapidly,

• produce pressings of various shapes and sizes.
The comprehensive design of the new screw press

is shown in Figure 1. It is a double chamber two-sided
design, allowing quality production of pressings from
various organic materials, due to the control options
for each significant parameter of the compaction pro-
cess, e.g. compacting pressure, pressing temperature,
pressing speed, cooling intensity of the pressings,
rapid exchange of worn tools, and required changes
of tool geometry. The structure is also equipped with
sensors that provide feedback in the compaction pro-
cess. This screw machine is a universal machine for
producing solid high-grade biofuels from a variety of
raw materials.

The machine consists of one common main drive,
a special spindle bearing that captures the work ax-
ial load and defines the exact position of the pressing
screw in the pressing chamber, two identical press-
ing chambers with tools, two filling systems, and two
cooling channels.

Single screw extruders are characterized by the
very short lifetime of the thrust bearings, or by their
large dimensions. The main objective of the two-
sided design of the press is to eliminate the axial
workload resulting from pressing the material, and
thus progressively increasing the lifetime of the bear-
ings. The bearings are loaded only with the difference
of the axial pressing forces caused by asymmetric fill-
ing of the material into the pressing chamber. The
whole workload is transmitted in the axis of the ma-
chine through the outer flange system (tensile stress)

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Acta Polytechnica Vol. 52 No. 3/2012

Figure 1: Newly-patented design of a screw press

Figure 2: Pressing chamber with tools (1 – feeding screw, 2 – pressing screw, 3 – pressing chamber, 4 – nozzles)

and the continuous solid spindle with pressing screws
on the ends (compressive stress). This system elim-
inates the need for a massive frame to transfer the
load, or for anchoring the machine. The construction
of the machine is designed for secure transmission of
an axial load to 520 kN (pressing machine is able to
draw 265 MPa for briquette diameter 50 mm).

The modularity of the double chamber machine
enables a single chamber machine to be created very
easily and quickly by removing a part of the press —
the whole side from the drive of the press — without
any other modifications. The single chamber design
is used especially for optimization experiments and
measurements, because it allows the full operating
load to be measured.

3 Design of the pressing
chamber

The pressing chamber must be strong enough to with-
stand the internal pressure while pressing. It consists
of the body of the pressing chamber, the feed screw,

the pressing screw and the individual nozzles (Fi-
gure 2). High material requirements and geometric
requirements are placed on the tools inside the press-
ing chamber. The material requirements include high
abrasion resistance, toughness and thermal stability.
The geometrical requirements are complicated, and
vary according to the type of raw material. The ba-
sic geometrical requirements are to ensure an increase
in material pressure during compaction. In addition,
the geometry of the tool must generate axial move-
ment of the material to ensure continuity of the com-
pacting process.

The pressing chamber is coated by heating de-
vices to control the pressing temperature, which is
the most important parameter in the biomass com-
paction process. The chosen design of the heating
system provides direct measurement and control of
the pressing temperature, up to 350 ◦C.

During optimization of the compacting process, it
is possible to change the shape and size of the press-
ing by simply and quickly changing the tool (screws
and pressing nozzles), changing the inner diameter
of the pressing chamber, the length of the pressing
chamber, the combination of tool materials, the taper

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Acta Polytechnica Vol. 52 No. 3/2012

of the pressing chamber, etc. The structural param-
eters of pressing tools are optimized experimentally,
e.g. the whole compaction process for different types
of raw materials.

4 Design of the pressing screw

The geometry of the pressing screw (Figure 3) en-
sures a high degree of material compaction in the
pressing chamber and compression of the material
through the nozzle, thus achieving a compact bri-
quette of high density, strength and surface quality.
The movement of the material, the compression, the
rate of wear and the stress distribution depend pri-
marily on the chosen geometry of the screw. It is
therefore extremely important to pay close attention
to the design of the screw geometry.

Figure 3: Monolithic pressing screw (1 – working
thread part of the screw, 2 – tip)

We obtained a mathematical model (1) describ-
ing the dependence of the compacting pressure on the
geometry of the screw by deriving the theory for the
speed and power relations in the screw.

p = p0 · eA·
l
D (1)

This mathematical model is very important in de-
signing the geometry of the pressing screw (p – work-
ing pressure, p0 – initial pressure, A – constant of pro-
portionality, l – active length of the screw, D – outer
diameter of the screw). This relationship shows that
the pressure in the screw profile is exponentially de-
pendent on the length of the screw. The constant of
proportionality (A) depends on the geometry of the
screw profile and the friction between the material
and the nozzle (fp), as well as the friction between
the material and the screw (fz). The condition of a
sharp pressure increase requires that the friction co-
efficient (fp) be as large as possible, while the coeffi-
cient (fz) is as small as possible. The coefficient (fz)
can greatly affect the surface quality of the screw.
The goal is to achieve minimum surface roughness.
Coefficient (fp) can be increased by increasing the
nozzle roughness or by machining grooves into the
surface of the nozzles in the direction of the screw
axis. Grooving not only increases the friction, but
also prevents rotation of the material invoking so-
called axial block flow.

The application of this theory will be demon-
strated on three geometric variants of pressing screws

(Figure 4, 5, 6). For simplicity in comparing the dif-
ferent variants, the input parameters are the same
for each screw:

Figure 4: Screw section of variant A

Figure 5: Screw section of variant B

Figure 6: Screw section of variant C

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Acta Polytechnica Vol. 52 No. 3/2012

Figure 7: Relationship between pressure and the number of screw threads at a constant initial pressure (po =
1.05 MPa)

• Outer diameter of screw (D = 70 mm)
• Inner diameter of screw (d = 40 mm)
• Cross-sectional area of thread (S = 325 mm2)
• Width of screw guide surface (e = 5 mm)
• Number of threads (z = 3)
Figure 7 shows that the geometry of variant A

has the smallest increase in working pressure. On
the other hand, the geometry of variant C causes the
working pressure to increase most (with respect to
the number of threads). For each variant, the thread
area is constant. Only the pitch of the screw changes
in accordance with the screw profile. For the con-
dition of a sharp increase in working pressure, the
thread geometry of variant C is most suitable. How-
ever, it cannot be definitively held that the thread
profile is optimal in all respects. Certainly it is nec-
essary to verify the assumption made above also for
other considerations — strength, technological fac-
tors, and cost.

The pressing screw is the most stressed compo-
nent in the machine, with the highest level of wear.
It is subject to high pressure, abrasion and heat. The
critical part of the screw is the tip (Figure 3) and the
first 1.5 revolutions of the thread, which shows on the
instrument workload distribution.

The degree of load and tool wear is also depen-
dent on the raw material. Further research and op-
timization is therefore under preparation for several
sets of tools to be made from a variety of special
steels, coating tools and tools with hard-grinding
threads. Pressing screws are designed as monolithic
(Figure 3), as well as folded (Figure 8, Figure 9),
which can have a rotating tip to reduce friction. A
folded screw can have each part made of a different
material, which reduces costs. The modularity of the
tool enables optimization of the compaction efficiency

of different types of raw materials at the lowest tool
cost. A worn pressing screw can be replaced or the
raw material can be changed very rapidly thanks to
the use of a supermagnet. It is only necessary to
insert the screw.

Figure 8: Folded pressing screw with a rotating tip

Figure 9: Folded pressing screw with a fixed tip

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Figure 10: Pelleting nozzle

Figure 11: Pressings made by a single machine

5 Pressing nozzle

The individual nozzles within the pressing chamber
must copy the shape of the thread of the screws and
prevent rotation of the material, while simultane-
ously allowing it to move axially. The nozzle geom-

etry is determined in such a way that it copies the
thread, from the pressing chamber to its tip, while
gradually transforming the material into the desired
product shape, i.e. a briquette. The nozzles are
highly stressed by the compressive pressure, the heat
and, most importantly, by abrasion. The surface of
the material must therefore be very hard and resis-
tant to abrasion, while internally the material must
be relatively ductile.

Several pressing nozzle geometries were developed
within the research project, with different lengths,
diameters and tapers. These nozzles are, as well as
screws, made of different materials for purpose of us-
ing them for different types of raw materials They
can be exchanged very quickly and easily, thanks to
the cassette system. The pressing nozzles determine
the size and shape of the resulting pressings by their
shape and design. The pressing nozzle in the cham-
ber can be exchanged to produce several pressings at
the same time (Figure 10, 11). In this way, the same
machine can produce briquettes or pellets by simply
changing the pressing chamber. By making a simple
change, it is possible to produce pressings of various
shapes: cylindrical, elliptical, polygons, etc.

6 Modularity of tools in the

pressing chamber

Modularity of the pressing chamber (Table 1) of the
screw press enables the compaction process for differ-
ent types of raw materials to be optimized easily and
quickly by exchanging the tools. The optimization
criteria are: quality of production, process efficiency,
energy costs, tool costs, and tool lifetime. A ma-
jor advantage is that pressings of various shapes and
sizes can be made using a single machine.

Table 1: Scheme of the pressing chamber modularity of the screw press

Modularity Material Geometry Construction Technologies

Pressing screw Steel Coating
Hard-grinding

Length of screw
Diameter of screw
Taper of screw
Profile of thread

Monolithic Folded
a) fixed tip
b) rotating tip

Pressing nozzles Steel Coating
Hard-grinding

Length of nozzle
Diameter of nozzle
Taper of nozzle
Different section of
pressings (circle,
ring, ellipse,
polygon, etc.)
Shape of pressings
Number of
pressings

Monolithic
Folded
Briquetting nozzle
(one pressing)
Pelleting nozzle
(more than one
pressing)

Briquetting
Pelleting

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7 Conclusion

Research on biomass compaction indicated a need for
a compacting machine with a modular design, where
all significant parameters of the compaction process
can be controlled. The aim of this paper has been
to present a newly-patented screw press design that
satisfies all requirements for modularity and control
of the parameters. It enables this process to be opti-
mized for different types of raw materials, and high
quality production to be achieved. The results of
an experimental study of the compacting process led
to the engineering design of a production machine,
tailor-made to the customer’s requirements, that is
able to minimize the costs for investment, energy and
operation. The design of the screw press is unique
in its modularity and high reliability. Six patents
and utility models protecting the intellectual prop-
erty rights of the authors have been taken out for
this screw press.

Acknowledgement

This paper is an outcome of the project “Devel-
opment of progressive biomass compacting technol-
ogy and production of prototype and high-productive
tools” (ITMS project code: 26240220017), on basis
of support funding from the European Regional De-
velopment Fund’s Research and Development Oper-
ational Programme.

References

[1] Matúš, M., Križan, P.: Influence of structural
parameters in compacting process on quality of
biomass pressing. In Aplimat – Journal of Ap-
plied Mathematics. 2010, Vol. 3, No. 3, p. 87–96.
ISSN 1337-6365.

[2] Matúš, M., Križan, P., Ondruška, J., Šooš, L’.:
Analysis of tool geometry for screw extrusion ma-
chines. In Aplimat – Journal of Applied Mathe-
matics. 2011, Vol. 4, No. 4. ISSN 1337-6365.

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