Real time control of clamping in an intelligent fixturing system.
Zuperl, Uros ; Cus, Franci ; Balic, Joze 等
Abstract: This paper presents a model-based on-line control of a
proposed intelligent fixturing system (IFS). An intelligent fixturing
system adaptively adjusts the clamping forces to optimal values during
the machining process. It consists of fixturing system, analytical
fixture-workpiece stability, model force monitoring module, clamping
force optimization algorithm and clamping control system. The emphasis
of this research is in the development of adaptive clamping ,forces
control. Numerous simulations and experiments are conducted to confirm
the efficiency and stability of proposed IFS. An IFS is suitable for
clamping of thin-wall products likely to undergo deformation due to
clamping and cutting forces during machining.
Key words: intelligent fixture, clamping force control, milling
1. INTRODUCTION
A fixturing system is used to locate and hold a workpiece in
machining, assembly, inspection and other manufacturing operations. The
specification of machining fixtures and the application of the clamping
forces have largely been experienced-based, requiring the skill of the
machinist or manufacturing engineer. Clamping forces are critical to the
final part accuracy. At some positions along the tool path, small forces
may be adequate, but large forces may be required at others. The minimum
clamping forces to secure the workpiece are different as the cutter
moves along its intended tool path. An excessive clamping force causes
deformation of a workpiece, which leads to dimensional and shape
inaccuracy. Insufficient clamping force can permit the part to slip from
the locator during the machining process. Especially in cases of
machining of thin-walled components, deformation can be minimised by
optimizing the location and magnitude of clamping forces. Therefore, in
intelligent fixturing system, both the location and magnitude of
clamping forces have to be controlled in real time (Hunter et al.,
2006). The major disadvantages of such IFS are very high cost and
limited accessibility to the workpiece. More realistic and
cost-effective approach is to use off-line optimisation of the clamps
location and on-line adjustment of clamping force. Monitoring of
clamping forces and elements of fixture enables the continuous
diagnostic of clamping system. There has been few reported work on
techniques to determine optimal clamping forces to be applied during
machining process (Deng & Melkote, 2006; Raghu & Melkote, 2004).
This paper proposes and presents the development of an intelligent
fixturing system that can intelligently control the clamping system
during machining. It optimally adjusts the clamping forces as the
position and the magnitude of the cutting forces vary during machining.
Since adaptive clamping forces appropriate to the dynamic machining
environment are provided, the proposed IFS is characterized by on-line
monitoring, dynamic clamping forces and real time fixing process
control. The ultimate goal is to fully integrate this Intelligent
Fixturing System with CNC machines so as to achieve an optimal fixturing
and machining process.
[FIGURE 1 OMITTED]
2. ARCHITECTURE OF THE IFS
Adjustment of the clamping force during machining requires the
control system to be responsive to the change in workpiece dimensions.
This is achieved by using a closed loop control using the parameter
identification of adaptive control theory. The application of adaptive
control theory in this research led to an intelligent fixturing system.
The architecture of the system is shown in Figure 1. The structure
consists of the fixturing system, fixture stability model, clamping
optimization algorithm, clamping control system, force monitoring module
and communications with CNC machine tool. At the beginning of the
machining process, the workpiece is clamped with an optimal clamping
force. Once the machining process begins, the force monitoring module
monitors the clamping forces. Once the forces exceed predetermined thresholds, a feedrate reduction request (Cus & Zuperl, 2007) or
stop request is sent to the machine tool from the communication module.
A reduced clamping force is therefore set and controlled
accordingly. The objective of the force optimization algorithm is to
minimize all the controllable and reaction forces. This is expressed as
the minimization of the sum of the squares of the clamping and reaction
forces. Based on the force analysis and rigidity and stability
constraints, the algorithm determines the optimal clamping force for
every cutter position. The optimal clamping forces are defined as the
minimum clamping forces necessary to keep the workpiece in static
equilibrium throughout the entire machining process. The predicted
optimal clamping forces are then applied in real-time using a hydraulic
clamping system. Soft PLC controls a hydraulic system to apply the
required clamping forces as the cutter moves to different locations on
the workpiece. The clamping forces are proportional to pressure in
hydraulic cylinder.
The stability model is used to monitor the fixturing stability
during the entire operation. Once instability appears, the module sends
a command to the hydraulic system to increase the corresponding clamping
force. This process is repeated until the completion of the machining
process. Positive reaction forces at the locators ensure that the
workpiece maintains contact with all the locators from the beginning of
the cut to the end. A negative reaction force at the locator indicates
that the workpiece is no longer in contact with the corresponding
locators and the fixturing system is considered unstable. This stability
criterion has been used by many other researchers (Yeh & Liou,
2000).
3. EXPERIMENTS AND RESULTS
A test rig based on commercially available modular fixturing system
has been design to demonstrate the effectiveness of the proposed
intelligent fixturing system. Machining experiments are carried out on a
thin-wall workpiece. On a Heller Bea 02 machine tool with Fagor CNC
controller it is necessary to make the slot shown in Figure 1. Tool path
if marked with arrow from point 1 to point 2. The milling cutter of 16
mm diameter with two cutting inserts (R-216-16 03 M-M) with the
following cutting conditions: cutting speed (v=25m/min), feedrate
([f.sub.z]=0.01mm/tooth), cutting depth (a=2.5 mm) is used for the
experiment. The workpiece material is the steel Ck-45. Piezoelectric sensors are built into six locators to measure reaction forces (R1-R6)
during machining. The measurements indicate that the reaction force R1
at some tool position is almost zero, which means that the workpiece in
not in equilibrium. This indicates that the fixturing system is not
stable under this set of constant clamping forces (C1=300N C2=250N). The
clamping forces must be increased until all the reaction forces become
positive.
[FIGURE 2 OMITTED]
Two hydraulic clamping cylinders are employed to clamp the
prismatic workpiece. The fluid pressure in each hydraulic cylinder is
measured by a pressure gauge. The cutting forces, tool position, the
positions of clamping/locating elements, the friction coefficient
([eta]=0.4) and the workpiece weight (Fg=47N) are taken into
consideration during on-line calculations of optimal clamping forces.
The optimal clamping forces are shown in Figure 2. Te results show that
the clamping forces can be very small by applying varied clamping forces
during machining in comparison with fixed clamping scheme. The
corresponding positive reaction forces are given in Figure 3 that shows
the workpiece will not detach from the six locators.
[FIGURE 3 OMITTED]
4. CONCLUSION
Architecture and control scheme for a proposed intelligent
fixturing system has been presented. This is cost-effective approach
which uses off-line optimisation of the clamps location and on-line
adjustment of clamping forces.
The sensing and clamping operations of the intelligent fixture are
controlled by a PC through Labview application. It is found out that
sensor feedback is the most important part of an intelligent system.
The force control performance of the developed system is very
promising since the clamping forces can be varied within an interval of
150 msec.
The average accuracy of the machined workpiece is improved for 12%
due to adaptive control of the clamping forces and the robustness of the
system to disturbances is also greater.
It is expected that future implementation of the system will
incorporate besides adaptive clamping force control also repositioning of the clamping elements.
5. REFERENCES
Cus, F. & Zuperl, U. (2007). Adaptive self-learning controller
design for feedrate maximization of machining process. Adv. Produc.
Engineer. Manag., Vol. 2, No. 1, 18-27
Deng, H. & Melkote, S. N. (2006). Determination of minimum
clamping forces for dynamically stable fixturing. International Journal
of Machine Tools and Manufacture, Vol. 46, 847-857
Hunter, R.; Rios, J.; Perez, J. M. & Vizan, A. (2006). A
functional approach for the formalization of the fixture design process.
International Journal of Machine Tools and Manufacture, Vol. 46, 683-697
Raghu, A. & Melkote, S. N. (2004). Analysis of the effects of
fixture clamping sequence on part location errors.
International Journal of Ma-chine Tools and Manufacture, Vol. 44,
373-382
Yeh, J. H. & Liou, F. W. (2000). Clamping Fault Detection in a
Fixturing System. Journal of Manufacturing Processes, Vol. 2, 194-202
