Selection of process parameters in grinding ceramics.
Dobrescu, Tiberiu ; Enciu, George ; Nicolescu, Adrian 等
1. INTRODUCTION
In a grinding process, each protruding abrasive grain on a grinding
wheel generates an intense local stress field upon contacting the
workpiece surface. This stress field causes irreversible material
deformation in the form of dislocations, cracks and voids. The
material-removal mechanisms are usually classified into two categories:
brittle fracture and plastic deformations. Brittle fracture, analogous
to indentation of a brittle material by a hard indenter, involves two
principal crack systems: lateral cracks which are responsible for
material removal, and median cracks, for strength degradation. In
brittle fracture, material-removal is accomplished through void and
crack nucleation and propagation, chipping or crushing. Plastic
deformation is similar to the chip formation process in metal grinding,
which involves scratching, plowing, and chip formation. The material is
removed in the form of severely sheared machining chip. The strength,
hardness, and fracture toughness of the work material are the governing
factors that control the extent of brittle fracture and plastic
deformation. Grinding process is an inherently damaging process since
the abrasive grains are forced into the surface. It is therefore not
surprising that the grinding operation causes decreased mechanical
strength of the machined components, an effect frequently reported in
the literature (Zhang & Howes, 1994).
Owing to variations of the grinding wheel topography and
microgeometry of abrasive grains, in grinding the impacts of cutting
edges are statistically distributed. Thus, grinding processes are
characterized by probabilistic mechanisms of influencing parameters and
resulting effects. In addition the grinding system, consisting of
grinding wheel, workpiece and machine tool, causes a dynamic process
behavior with fast changes of the cutting conditions in the contact
zone. Moreover an instationary process behavior arises during grinding
of ceramic materials, as the wheel topography is steadily subjected to
changes caused by specific wear mechanisms. Without self-sharpening
effects occurring, the wheel constantly loses its grinding performance.
These three basic modes of interaction make it difficult to analyze the
grinding process and to determine the optimum process conditions as it
is frequently discussed in the literature (Inasaki, 1987). Therefore a
kinematic model of the cutting edge engagement is derived for the
evaluation of uncut chip thickness in connection with single grain
scratch tests in order to determine parameter limits to prevent surface
damage.
2. PRINCIPLE OF DUCTILE MATERIAL REMOVAL
The term "ductile regime" has been used to describe the
material-removal mechanisms in the grinding of ceramics. A hypothesis
has been advanced according to which all materials, regardless of their
hardness and brittleness, will undergo a transition from a brittle to a
ductile regime below a critical depth of cut. The hypothesis is based on
the energy consumption in different material-removal processes. The
energy required for brittle fracture is proportional to the square of a
characteristic dimension, which can be depth of cut, the energy required
for plastic deformation is proportional to the cube of the
characteristic dimension: the energy ratio of plastic flow to fracture
is therefore proportional to the characteristic dimension. As the scale
of machining decreases, plastic flow becomes an energetically more
favorable material-removal mechanism; the material-removal mechanism at
a reduced scale thus is based on the ductile regime (Zhang & Howes,
1994).
In the grinding of ceramics, material-removal may however, be based
on such mechanisms as crushing, chipping of fracture, pulverization, and
ductile deformation. In dealing with precision grinding processes, where
the depth of cut is normally in the submicrometer range, crushing and
chipping or fracture mechanisms can be excluded from this list. Material
pulverization occurs when ceramic grains sized in micrometers are
pulverized during grinding into finer grains in submicrometer range or
even smaller. In a material-removal process, the response of the
material is to generate the highest possible resistance to the external
machining system in order to maintain its natural structure. The highest
possible resistance corresponds to the highest possible energy
consumption by the material, which determines the most favorable
material-removal mechanisms in a machining process. Based on this energy
argument, pulverization is considered to be the most favorable
material-removal mechanism in grinding of ceramics at minute depth of
cut. Material removal can be due mainly to the material pulverization
rather than ductile deformation.
Single grain scratch tests represent a theoretically and
experimentally idealized model with one grain on the outer diameter of
the grinding wheel (Toenshoff, 1992). They allow a theoretical
computation of the kinematic conditions and a phenomenological view of
surface formation without stochastic superposition of different effects
during the engagement of numerous cutting edges. Contrary to ductile
metallic materials the brittle ceramic materials show cracks in the
surface and in depth, to the sides and in tangential direction when a
limiting uncut chip thickness is exceeded, depending on the workpiece
material. A surface featured by such brittle mechanisms influences the
tribological properties of slide face as well as the components tensile
strength under static and dynamic stress conditions (Dobrescu &
Anghel, 2008).
3. MODELLING THE KINEMATICS OF AN INTRUDING CUTTING EDGE
Based on single grain scratch tests a kinematic model of the
intrusion of a cutting edge is developed considering limiting uncut chip
thickness hg for each workpiece material. This model intends to
determine process parameters effecting mainly plastic deformation along
surface relevant areas of the grain path, thus minimizing the number of
induced microcracks. During modeling of the kinematic grain path creep
feed grinding and reciprocating grinding conditions are separated by
their different characteristic courses of uncut chip thickness leading
to different mechanisms of surface generation as show in Figure 1
(Dobrescu, 1998).
Creep feed grinding is characterized by a comma-shaped course of
grain path (Figure 1.a) caused by the superposition of two subsequent
cycloid arches. The uncut chip thickness h versus the grinding wheel
rotation angle [phi] starts at zero in the moment of contact at point B,
growing almost linearly until the maximum uncut chip thickness
[h.sub.max] is reached at point M, and then decreasing arch-shaped
towards point A, where the grain leaves the workpiece again (Figure
1.c). In the shown system of coordinates with the workpiece speed
[v.sub.w] related to the center of the grinding wheel the trajectory of
the single grain is computed:
x([phi]) = [r.sub.s] x (([phi]/q + sin [phi]) (1)
y([phi]) = [r.sub.s] - (1 - cos [phi]) (2)
With q=[v.sub.s]/[v.sub.w]. The x coordinate of contact point B
results from:
[x.sub.B] = [pi] x [r.sub.s]/q (3)
Where [r.sub.s] are grinding wheel radius and [v.sub.s] is
circumferential speed of grinding wheel.
[FIGURE 1 OMITTED]
Caused by the superposition of the grain path cycloids a wavy
surface profile with sharp ridges arises. The uncut chip thickness
correlated to the peaks of these ridges is defined as the surface
relevant uncut chip thickness [h.sub.0], representing the maximum of
crack inducing stress along the arising workpiece surface. In order to
avoid rim and sub-surface damages, kinematic process parameters are
consequently chosen in a way, that the surface relevant uncut chip
thickness [h.sub.0], which can be adjusted by these kinematic
parameters, does not exceed the limiting uncut chip thickness hg for a
specific material. These definitions and kinematics are valid for uncut
as well as downcut conditions.
Reciprocating grinding (Figure 1.b) is defined by single grain
paths of subsequent revolution not intersecting inside the workpiece.
Theoretically a small web of the original surface remains, reducing to a
ridge under limit conditions. The maximum uncut chip thickness
[h.sub.max] at reciprocating grinding equals the selected depth of cut
ae. This maximum is reached in the middle of the contact arch (Figure
1.c) and represents the surface relevant uncut chip thickness [h.sub.0]
as well.
4. COMPARISON OF KINEMATIC MODELING AND REAL GRINDING PROCESS
The superposition of multiple kinematic cutting edges on one
circumferential line can be taken into account by correcting the speed
ratio corresponding to the number of cutting edges, i.e. 10 equidistant kinematical cutting edges on a circumferential line can be compared to a
wheel speed increased by ten times. In a real grinding process small
deviations of shape and roundness of the grinding wheel, an eccentricity
of the wheel fixture and influences caused by vibrations and deflection
are to be taken into consideration.
5. CONCLUSION
The following guidelines and general rules should be considered for
the selection of process parameters in grinding of ceramics:
* Creep feed grinding results in low uncut chip thickness and
therefore minimum surface damage. Following the presented definition of
creep feed grinding, not necessarily a great depth of cut is assumed.
Even a spark-out process can be implemented under creep feed conditions.
* An increased removal rate should be realized by increased depth
of cut more than high workpiece speeds, as long as sufficient coolant supply is guaranteed.
* Increased cutting speeds reduce the uncut chip thickness at the
single grain and improve surface quality.
* During finishing, one single depth of cut with respectively
reduced workpiece speeds should be preferred in order to obtain low
cutting forces.
6. REFERENCES
Dobrescu, T. (1998). Cercetari privind optimizarea masinilor de
superfinisat materiale fragile, PhD Theses, University
"Politehnica" of Bucharest, Romania
Dobrescu, T.; Anghel, F. (2008). Surface grinding method of silicon
wafers, Annals of DAAAM for 2008, 22 - 25th October 2008, Tarnava,
Slovakia, pp. 0395-0396
Inasaki, I. (1987). Grinding of Hard and Brittle Materials, CIRP Annals, no. 36, pp. 463-471
Toenshoff, H. K.; Peters, J.; Inasaki, I. & Paul, T. (1992).
Modeling and Simulation of grinding Processes, CIRP Annals, no. 41, pp.
677-688
Zhang, B. & Howes, T. D. (1994). Material Removal Mechanisms in
Grinding Ceramics, CIRP Annals, no. 43, pp. 305-308
