Flexible multibody dynamics and intelligent control of a hydraulically driven hybrid redundant robot machine
Al-saedi, Mazin (2014-06-03)
Väitöskirja
Al-saedi, Mazin
03.06.2014
Lappeenranta University of Technology
Acta Universitatis Lappeenrantaensis
Julkaisun pysyvä osoite on
https://urn.fi/URN:ISBN:978-952-265-595-0
https://urn.fi/URN:ISBN:978-952-265-595-0
Tiivistelmä
The assembly and maintenance of the International Thermonuclear Experimental
Reactor (ITER) vacuum vessel (VV) is highly challenging since the tasks performed by
the robot involve welding, material handling, and machine cutting from inside the VV.
The VV is made of stainless steel, which has poor machinability and tends to work
harden very rapidly, and all the machining operations need to be carried out from inside
of the ITER VV. A general industrial robot cannot be used due to its poor stiffness in
the heavy duty machining process, and this will cause many problems, such as poor
surface quality, tool damage, low accuracy. Therefore, one of the most suitable options
should be a light weight mobile robot which is able to move around inside of the VV
and perform different machining tasks by replacing different cutting tools.
Reducing the mass of the robot manipulators offers many advantages: reduced material
costs, reduced power consumption, the possibility of using smaller actuators, and a
higher payload-to-robot weight ratio. Offsetting these advantages, the lighter weight
robot is more flexible, which makes it more difficult to control. To achieve good
machining surface quality, the tracking of the end effector must be accurate, and an
accurate model for a more flexible robot must be constructed.
This thesis studies the dynamics and control of a 10 degree-of-freedom (DOF)
redundant hybrid robot (4-DOF serial mechanism and 6-DOF 6-UPS hexapod parallel
mechanisms) hydraulically driven with flexible rods under the influence of machining
forces. Firstly, the flexibility of the bodies is described using the floating frame of
reference method (FFRF). A finite element model (FEM) provided the Craig-Bampton
(CB) modes needed for the FFRF. A dynamic model of the system of six closed loop
mechanisms was assembled using the constrained Lagrange equations and the Lagrange
multiplier method. Subsequently, the reaction forces between the parallel and serial
parts were used to study the dynamics of the serial robot. A PID control based on
position predictions was implemented independently to control the hydraulic cylinders
of the robot.
Secondly, in machining, to achieve greater end effector trajectory tracking accuracy for
surface quality, a robust control of the actuators for the flexible link has to be deduced.
This thesis investigates the intelligent control of a hydraulically driven parallel robot
part based on the dynamic model and two schemes of intelligent control for a hydraulically driven parallel mechanism based on the dynamic model: (1) a fuzzy-PID
self-tuning controller composed of the conventional PID control and with fuzzy logic,
and (2) adaptive neuro-fuzzy inference system-PID (ANFIS-PID) self-tuning of the
gains of the PID controller, which are implemented independently to control each
hydraulic cylinder of the parallel mechanism based on rod length predictions. The serial
component of the hybrid robot can be analyzed using the equilibrium of reaction forces
at the universal joint connections of the hexa-element. To achieve precise positional
control of the end effector for maximum precision machining, the hydraulic cylinder
should be controlled to hold the hexa-element.
Thirdly, a finite element approach of multibody systems using the Special Euclidean
group SE(3) framework is presented for a parallel mechanism with flexible piston rods
under the influence of machining forces. The flexibility of the bodies is described using
the nonlinear interpolation method with an exponential map. The equations of motion
take the form of a differential algebraic equation on a Lie group, which is solved using a
Lie group time integration scheme. The method relies on the local description of
motions, so that it provides a singularity-free formulation, and no parameterization of
the nodal variables needs to be introduced. The flexible slider constraint is formulated
using a Lie group and used for modeling a flexible rod sliding inside a cylinder. The
dynamic model of the system of six closed loop mechanisms was assembled using
Hamilton’s principle and the Lagrange multiplier method. A linearized hydraulic
control system based on rod length predictions was implemented independently to
control the hydraulic cylinders. Consequently, the results of the simulations demonstrating the behavior of the robot machine are presented for each case study.
In conclusion, this thesis studies the dynamic analysis of a special hybrid (serialparallel)
robot for the above-mentioned special task involving the ITER and investigates
different control algorithms that can significantly improve machining performance.
These analyses and results provide valuable insight into the design and control of the
parallel robot with flexible rods.
Reactor (ITER) vacuum vessel (VV) is highly challenging since the tasks performed by
the robot involve welding, material handling, and machine cutting from inside the VV.
The VV is made of stainless steel, which has poor machinability and tends to work
harden very rapidly, and all the machining operations need to be carried out from inside
of the ITER VV. A general industrial robot cannot be used due to its poor stiffness in
the heavy duty machining process, and this will cause many problems, such as poor
surface quality, tool damage, low accuracy. Therefore, one of the most suitable options
should be a light weight mobile robot which is able to move around inside of the VV
and perform different machining tasks by replacing different cutting tools.
Reducing the mass of the robot manipulators offers many advantages: reduced material
costs, reduced power consumption, the possibility of using smaller actuators, and a
higher payload-to-robot weight ratio. Offsetting these advantages, the lighter weight
robot is more flexible, which makes it more difficult to control. To achieve good
machining surface quality, the tracking of the end effector must be accurate, and an
accurate model for a more flexible robot must be constructed.
This thesis studies the dynamics and control of a 10 degree-of-freedom (DOF)
redundant hybrid robot (4-DOF serial mechanism and 6-DOF 6-UPS hexapod parallel
mechanisms) hydraulically driven with flexible rods under the influence of machining
forces. Firstly, the flexibility of the bodies is described using the floating frame of
reference method (FFRF). A finite element model (FEM) provided the Craig-Bampton
(CB) modes needed for the FFRF. A dynamic model of the system of six closed loop
mechanisms was assembled using the constrained Lagrange equations and the Lagrange
multiplier method. Subsequently, the reaction forces between the parallel and serial
parts were used to study the dynamics of the serial robot. A PID control based on
position predictions was implemented independently to control the hydraulic cylinders
of the robot.
Secondly, in machining, to achieve greater end effector trajectory tracking accuracy for
surface quality, a robust control of the actuators for the flexible link has to be deduced.
This thesis investigates the intelligent control of a hydraulically driven parallel robot
part based on the dynamic model and two schemes of intelligent control for a hydraulically driven parallel mechanism based on the dynamic model: (1) a fuzzy-PID
self-tuning controller composed of the conventional PID control and with fuzzy logic,
and (2) adaptive neuro-fuzzy inference system-PID (ANFIS-PID) self-tuning of the
gains of the PID controller, which are implemented independently to control each
hydraulic cylinder of the parallel mechanism based on rod length predictions. The serial
component of the hybrid robot can be analyzed using the equilibrium of reaction forces
at the universal joint connections of the hexa-element. To achieve precise positional
control of the end effector for maximum precision machining, the hydraulic cylinder
should be controlled to hold the hexa-element.
Thirdly, a finite element approach of multibody systems using the Special Euclidean
group SE(3) framework is presented for a parallel mechanism with flexible piston rods
under the influence of machining forces. The flexibility of the bodies is described using
the nonlinear interpolation method with an exponential map. The equations of motion
take the form of a differential algebraic equation on a Lie group, which is solved using a
Lie group time integration scheme. The method relies on the local description of
motions, so that it provides a singularity-free formulation, and no parameterization of
the nodal variables needs to be introduced. The flexible slider constraint is formulated
using a Lie group and used for modeling a flexible rod sliding inside a cylinder. The
dynamic model of the system of six closed loop mechanisms was assembled using
Hamilton’s principle and the Lagrange multiplier method. A linearized hydraulic
control system based on rod length predictions was implemented independently to
control the hydraulic cylinders. Consequently, the results of the simulations demonstrating the behavior of the robot machine are presented for each case study.
In conclusion, this thesis studies the dynamic analysis of a special hybrid (serialparallel)
robot for the above-mentioned special task involving the ITER and investigates
different control algorithms that can significantly improve machining performance.
These analyses and results provide valuable insight into the design and control of the
parallel robot with flexible rods.
Kokoelmat
- Väitöskirjat [1099]