Recent trends in measurements of sphericity.
Adamczak, Stanislaw ; Janecki, Darius ; Stepien, Krzysztof Stanislaw 等
Abstract: Parameters relating to sphericity are not included in the
standards of the Geometrical Product Specifications (GPS). The methods
used for assessing sphericity involve measuring roundness profiles of a
sphere in several cross-sections. However, such methods do not guarantee
accurate qualitative and quantitative results, especially if the
analyzed surface contains local irregularities. This paper presents the
latest findings on the measurement of sphericity deviations and the
fundamentals of the concept of combined measurement of sphericity.
Key words: sphericity, measurement, deviation, evaluation
1. INTRODUCTION
In industrial practice, assessing the sphericity of an object
requires measuring its roundness profiles in several selected
cross-sections. Since the quantitative and qualitative information
obtained in this way is generally not sufficiently accurate,
specifically, if some local irregularities are present, manufacturers of
spherical components used, for instance, by the rolling beating or
automotive industries, expect improvements in this field. It is vital
that assessment be reliable and that the whole object measured be
graphically represented.
The method developed by the authors, which is a method of combined
measurement, meets these expectations. It involves first measuring
roundness profiles of a spherical object placed on a measuring table in
several equally spaced cross-sections, then rotating it by a right angle
about the vertical axis, and measuring it in another several equally
spaced cross-sections. Such measurement can be performed using radial
measuring instruments equipped with a special unit for controlling the
object rotation about at least two perpendicular axes. The concept
requires developing a mathematical model of measurement strategy.
2. METHODS OF SPHERICITY MEASUREMENT
According to the existing industrial standards, the strategy for
sphericity assessment consists in measuring roundness profiles in two or
three mutually perpendicular planes (see Fig. 1). The results obtained
for the individual cross-sections are represented graphically in polar
coordinates, which makes it possible to determine sphericity deviations.
This approach to sphericity measurement is very simplified because a
significant part of the spherical surface is not measured.
[FIGURE 1 OMITTED]
Most industrial standards state that the best reference in
sphericity evaluation is the minimum circle circumscribed on a measured
profile. Sphericity measurements are generally conducted using radial
devices, i.e. ones determining changes in the radius. In radial
measurement, the workpiece is placed on a table, which can be rotary or
non-rotary, according to the design of the device. If the measuring
table is non-rotary, the measuring sensor rotates. Figure 2 shows a
schematic diagram of a typical radial device (Kanada, 1997).
[FIGURE 2 OMITTED]
Recent advances in metrology have caused that researchers are
working on the development of other methods for sphericity measurement.
A large number of institutions are investigating the use of coordinate
measurement systems to assess sphericity deviations. As the accuracy of
coordinate measuring machines is increasing, this technique may soon be
applied not only to assess sphericity but also other form deviations.
Nowadays, however, it is still the radial devices that provide the
highest measurement accuracy. One of the most original methods proposed
recently for measuring sphericity was that developed by Gleason &
Schwenke (1998) (see Fig. 3).
[FIGURE 3 OMITTED]
This measurement strategy is called the three-point method. When
the measurement is performed for a rotating workpiece, the measuring
signal m(o) is affected not only by the form deviation s(o) but also by
the mutual alignment of the support points and the location of the
sensor. The best way to determine the relationship between the value of
the measuring signal and the real deviation is to apply a Fourier
transform (Adamczak et al., 2011). An advantage of the concept presented
in Ref. [2] is that the measuring signal is not affected by the spindle
errors. The most important drawback is that some harmonic components of
the profile cannot be detected by the measuring system. Another
interesting concept of measurement of spherical workpieces is the use of
optical systems (Halkaci et al., 2007). Their accuracy, however, is
still relatively low, when form deviations are measured. This suggests
that optical methods are not suitable for accurate sphericity
measurements.
3. EVALUATION OF SPHERICITY DEVIATIONS
A large number of academic and industrial research centres are
engaged in developing and improving methods for the measurement of
spherical surfaces as well as methods for the evaluation of sphericity
deviations. Traditionally, the methods used for assessing deviations
from an ideal sphere are similar to those used for analyzing
out-of-roundness.
The research activities conducted in this area include calculation
of reference sphericity parameters based on the measurement data. In
order to solve this problem, different approaches can be applied.
Numerical methods, for instance, seem to be suitable when the
measurement is performed using a coordinate measuring machine (Samuel
& Shunmugam, 2003). Another method of calculation of reference
spheres is to apply computational geometry techniques, which frequently
make use of the so-called Voronoi diagrams (see Samuel & Shunmugam,
2002, and Huang, 1999). Sphericity can also be evaluated using the
method described by Fan & Lee (1999). They suggest that sphericity
should be assessed with respect to the minimum zone reference sphere by
applying the principle of minimum total potential energy. A completely
different approach to the assessment of sphericity deviations was
proposed by Kanada (1997), who suggests analyzing the statistical
parameters.
4. A NOVEL APPROACH TO SPHERICITY MEASUREMENT
The concept of accurate measurement of sphericity deviations
developed at the Kielce University of Technology is based on various
solutions presented in the literature as well as the authors'
experience concerning accurate measurement of roundness and
cylindricity. The research project involving the development of the
method was divided into two parts: theoretical (including computer
simulations) and experimental. The theoretical investigations included:
defining the spherical surface, selecting a relevant measurement
strategy, generating and superimposing profiles, filtering the profiles,
calculating the reference sphere and the sphericity parameters (Adamczak
et al., 2009).
The authors assumed the following strategy of measurement. First, a
selected sphere is measured on a measuring table to determine its
roundness profiles in several equally-spaced cross-sections. Next, the
object is rotated at a right angle about the vertical axis so that more
cross-sections can be measured (see Fig. 4). The limitation of the
approach proposed by authors is that the fixing unit may not rotate the
workpiece accurately, which can influence measurement data.
[FIGURE 4 OMITTED]
5. SUMMARY
Since the existing measurement strategies applied to assess
sphericity deviations are not sufficiently accurate, the authors
developed a combined method, which involves measuring the changes in
radius with radial devices. The measuring instrument is a computer-aided
radial device for measuring radius changes in roundness profiles. It is
equipped with a special-purpose fixing unit for accurate positioning of
the measured element. The next stage of the research will be the
experimental verification of the concept. It will be carried out at the
Kielce University of Technology at the Laboratory of Computer-Aided
Measurements of Geometrical Quantities.
6. REFERENCES
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