AP04_3web.vp


1 Introduction
This paper describes the conceptual design process of

OCTASLIDE redundant parallel kinematics for a machine
tool. Redundantly actuated parallel kinematics is a recently
developed new concept for machine tools. It enables all me-
chanical properties of machine tools to be improved several
times simultaneously. This is particularly demonstrated on
the design of the OCTASLIDE. This is a concept of five-axis
machine tool center. The paper describes the critical initial
design phases and the accessible mechanical properties. The
design process follows the newly developed design methodol-
ogy for parallel kinematics machines.

2 Concept of redundant actuation for
parallel kinematics
Parallel kinematics means kinematic refers to where a

body carrying a tool (called a platform) is supported by
several independent links (legs) from the frame. Parallel kine-
matics has the advantage that in principle all drives can be on
the frame (decreased moving masses) and that its structure
is a truss (increased stiffness). However, it also has severe
disadvantages, mainly the occurrence of singular positions
in the workspace and a generally smaller workspace due to
link collisions.

These problems of parallel kinematics can be removed by
the principle of redundant actuation [1]. If the platform of
parallel kinematics is supported on a redundant number of
legs (links), i.e. on more than the needed number of DOFs –

in plane, on more than 3 legs, and in space, on more than
6 legs, then the following simplified consideration can be
applied. If a certain combination of 6 legs from the redundant
number of legs in the given position of the kinematics leads to
a singular position, then the other combination of another 6
legs in the same position will be in a non-singular position
(Fig. 1). Certainly switching between different selected combi-
nations of legs is just an ideal consideration. The kinematics
must use all redundant legs simultaneously and the control
must be correspondingly smooth. The actuators of parallel
structures can be realized by different principles (Fig. 2), not
only by telescopic links.

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Acta Polytechnica Vol. 44  No. 3/2004

Design and Properties of Octaslide
Redundant Parallel Kinematics
V. Bauma, M. Valášek, Z. Šika

This paper describes the conceptual design process of OCTASLIDE redundant parallel kinematics for a machine tool. Redundantly
actuated parallel kinematics is a recently developed new concept for machine tools. It enables all mechanical properties of machine tools to be
improved several times simultaneously. This is particularly demonstrated on the design of the OCTASLIDE. This is a concept of a five-axis
machine tool centre. The paper describes the critical initial design phases and the accessible mechanical properties. The design process has
follow the newly developed design methodology for parallel kinematics machines.

Keywords: parallel kinematics, redundant actuation, five axes, machine tool, dexterity, stiffness.

Fig. 1: The concept of redundant actuation of parallel kinematics

Fig. 2: The different constructions of link actuators (telescopic, sliding, rotational)



Using telescopic links, the octapod has been proposed as a
redundant variant of the traditional hexapod. This paper
deals with the conceptual design of redundant parallel kine-
matics with sliding links.

3 Design methodology for parallel
kinematics
The design of parallel kinematics is a difficult problem.

The fundamental problem is that almost all design para-
meters are mutually dependent. This leads to significantly
increased computational complexity. A special design meth-
odology has therefore been developed for parallel kinematics
[2]. This methodology has succeeded in decreasing the com-
putational complexity of the design by decomposing the
design process into several hierarchical levels and by using of
computational tools capable of computing the mechanical
properties globally (for the whole workspace, rather than
for one position in it).

4 Octaslide concept
The octaslide is a redundant version of the hexaslide. It is

a parallel kinematics the links of which have sliding actuators.
The principal concept of such a structure is shown in Fig. 3.
The platform is suspended on 8 links with actuators, unlike
the hexaslide or pentaslide, which are suspended on only 6 or
5 links.

5 Workspace and dexterity
optimization
The goal is to design the octaslide as a machine tool for a

cylindrical workspace with a diameter of 1200 mm (length
is almost unlimited). The platform is again a cylinder with
diameter 400 mm and a length of 700 mm for axial suspen-
sion of the spindle. The goal is to maximize the orientation
angles for five-axis machining.

The investigation and optimization were provided on
three testing trajectories (Fig. 4). The first is a planar circular
trajectory with chords of radius 540 mm in plane x-z, the
second is a conical trajectory from the origin with variant
deflection angle �, and the third is a conical trajectory on a cir-
cular path in plane x-z of radius 540 mm with variant
deflection.

First, the hexaslide was optimized. Two structures were in-
vestigated. The first kinematic structure is symmetric (Fig. 5).
The second structure is asymmetric, with links of different
lengths (Fig. 6).

The influence of structure asymmetry on the important
kinematic property of dexterity (characterizing the distance
from the singular position) is very strong. A comparison of the
dexterity behaviour of the two hexaslide structures on three
testing trajectories is shown in Fig. 9 (left).

The same investigation was done for the octaslide. Two
structures were designed and optimized – symmetric and

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Acta Polytechnica Vol. 44  No. 3/2004

Fig. 3: Kinematic concept of the octaslide

�

x

z

y

�

x

z

y

Fig. 4: Three testing trajectories



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Acta Polytechnica Vol. 44  No. 3/2004

-1 -0.5 0 0.5 1
-1

-0.5

0

0.5

1

1

6

2

x

5

3

4

z

y

-1 0 1

-1.5

-1

-0.5

0

0.5

6

1

x

4

3y

5

2

-1.5-1-0.500.5
-1

-0.5

0

0.5

1

5

1
2

4

z

3

6

-1

0

1

-2

0

2
-1

0

1

x

6

2

5

3

y

z

1

4

Fig. 6: Hexaslide with an asymmetric structure (different lengths of links)

-1 -0 .5 0 0.5 1
-1

-0 .5

0

0.5

1

1

6
5

2

x

4

3

z

-1 0 1

-1 .5

-1

-0 .5

0

0.5

6

1

2

x

4

3

y

5

-1 .5-1-0 .500.5
-1

-0 .5

0

0.5

1

5

1

y

2

4

z

3

6

-1

0

1

-2

0

2
-1

0

1

x

6

5

3

y

z
4

2

1

Fig. 5: Hexaslide with a symmetric structure



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Acta Polytechnica Vol. 44  No. 3/2004

-1 -0.5 0 0.5 1
-1

-0.5

0

0.5

1

1

8

2

7

x

6

34

5

z

-1 0 1

-1.5

-1

-0.5

0

0.5

8

1

2

7

x

6
4

5

y

3

z

-1.5-1-0.500.5
-1

-0.5

0

0.5

1

1

5

3

y

8

4 2

76

-1

0

1

-2

0

2
-1

0

1
1

x

8

2
4

y

z

5

6
7

3

Fig. 8: Octaslide with an asymmetric structure (different lengths of links)

-1 -0.5 0 0.5 1
-1

-0.5

0

0.5

1

8

1

7

2

x

6

3

4

5

z

-1 0 1

-1.5

-1

-0.5

0

0.5

8

1

7

2

x

6
4

5

y

3

-1.5-1-0.500.5
-1

-0.5

0

0.5

1

7

3

y

2

z

4

8

6

1

5

-1

0

1

-2

0

2
-1

0

1

1

x

2

y

z

6
7

5

4

8

3

Fig. 7: Octaslide with a symmetric structure



asymmetric (Figs. 7 and 8). The influence of these structures
on dexterity on the testing trajectories is again very strong. A
comparison of the dexterity behaviour of the two octaslide
structures on three testing trajectories is shown in Fig. 9
(right).

A comparison of the dexterity on testing trajectories of the
optimized hexaslide and octaslide is shown in Fig. 10 a, b, c.
The behaviour of the octaslide is significantly better as the
dexterity minimum is increased and its variation is decreased.

The principle of asymmetry was further investigated and
the structure of the octaslide was optimized (Fig. 11) by vary-
ing the link lengths and their positioning on the frame. The
dexterity was further significantly improved above the previ-
ous levels (Fig. 10c) comparing the optimized hexaslide and
the two octaslides. The octaslide from Fig. 11 has better dex-
terity in almost the whole workspace.

Simultaneously with the dexterity, the declination angles
characterizing the orientation capabilities were also investi-

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Acta Polytechnica Vol. 44  No. 3/2004

Fig. 9: Dexterity on three testing trajectories for the hexaslide (left) and the octaslide (right)



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Acta Polytechnica Vol. 44  No. 3/2004

a) b)

c) d)

Fig. 10: Dexterity comparison on three testing trajectories of optimized hexaslide and octaslide

Fig. 11: Further optimized octaslide with increased asymmetry of links



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

Acta Polytechnica Vol. 44  No. 3/2004

Fig. 12: Octaslide with a conical platform

Fig. 13: Stiffness in the workspace for the hexaslide (left) and the octaslide (right) in directions x, y, z



gated and optimized. The declination of the hexaslide for tra-
jectory 2 is 14o, and for trajectory 3 it is 13o. The declination
of the octaslide for trajectory 2 is 16o, and for trajectory 3 it is
12o. This means that the two structures are comparable in
terms of their orientation capabilities. Then the structure of
the octaslide was further optimized. The platform was conical
instead of cylindrical (Fig. 12). This modification enables the
declination angle to be extended to 33o.

6 Octaslide stiffness
The stiffness in the whole workspace was compared for the

two optimized variants of the hexaslide and the octaslide.
They are shown in Fig. 13. The comparison of maximum,
minimum and average values demonstrates the significant su-
periority of the octaslide. The increase in the maximum val-
ues is 65–74 %, and the increase in the average values is
43–54 %.

7 Conclusions
The concept of redundant actuation enables the design of

new parallel kinematics with significantly improved mechani-
cal properties. This has again been confirmed by the design of
the octaslide.

8 Acknowledgment
The authors appreciate the support of MSMT project

J04/98:212200008.

References
[1] Valášek M. et al: “New Concept of Redundant Parallel

Robot”. In: Proc. of Mechatronics and Robotics 97, VUT
Brno, Brno 1997, p. 269–274.

[2] Valášek M., Šika Z., Bauma V., Vampola T.: Design
Methodology for Redundant Parallel Robots, in Proc. of
AED 2001, 2nd Int. Conf. on Advanced Engineering De-
sign, Glasgow, 2001, p. 243–248.

Ing. Václav Bauma, CSc.
phone: +420 224 357 373
e-mail: vaclav.bauma@fs.cvut.cz

Prof. Ing. Michael Valášek, DrSc.
phone: +420 224 357 361
fax: +420 224 916 709
e-mail: michael.valasek@fs.cvut.cz

Ing. Zbyněk Šika, Ph.D.
phone: +420 224 357 452
e-mail: zbynek.sika@fs.cvut.cz

Department of Mechanics

Czech Technical University in Prague
Faculty of Mechanical Engineering
Karlovo nám. 13
121 35 Praha 2, Czech Republic

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Acta Polytechnica Vol. 44  No. 3/2004