Surface metrology

Surface metrology is the measurement of small-scale features on surfaces, and is a branch of metrology. Surface primary form, surface waviness and surface roughness are the parameters most commonly associated with the field. It is important to many disciplines and is mostly known for the machining of precision parts and assemblies which contain mating surfaces or which must operate with high internal pressures.

Surface finish may be measured in two ways: contact and non-contact methods. Contact methods involve dragging a measurement stylus across the surface; these instruments are called profilometers. Non-contact methods include: interferometry, confocal microscopy, focus variation, structured light, electrical capacitance, electron microscopy, and photogrammetry.

Overview

The most common method is to use a diamond stylus profilometer. The stylus is run perpendicular to the lay of the surface.[1] The probe usually traces along a straight line on a flat surface or in a circular arc around a cylindrical surface. The length of the path that it traces is called the measurement length. The wavelength of the lowest frequency filter that will be used to analyze the data is usually defined as the sampling length. Most standards recommend that the measurement length should be at least seven times longer than the sampling length, and according to the Nyquist–Shannon sampling theorem it should be at least two times longer than the wavelength of interesting features. The assessment length or evaluation length is the length of data that will be used for analysis. Commonly one sampling length is discarded from each end of the measurement length. 3D measurements can be made with a profilometer by scanning over a 2D area on the surface.

The disadvantage of a profilometer is that it is not accurate when the size of the features of the surface are close to the same size as the stylus. Another disadvantage is that profilometers have difficulty detecting flaws of the same general size as the roughness of the surface.[1] There are also limitations for non-contact instruments. For example, instruments that rely on optical interference cannot resolve features that are less than some fraction of the operating wavelength. This limitation can make it difficult to accurately measure roughness even on common objects, since the interesting features may be well below the wavelength of light. The wavelength of red light is about 650 nm,[2] while the average roughness, (Ra) of a ground shaft might be 2000 nm.

The first step of analysis is to filter the raw data to remove very high frequency data (called "micro-roughness") since it can often be attributed to vibrations or debris on the surface. Filtering out the micro-roughness at a given cut-off threshold also allows to bring closer the roughness assessment made using profilometers having different stylus ball radius e.g. 2µm and 5µm radii. Next, the data is separated into roughness, waviness and form. This can be accomplished using reference lines, envelope methods, digital filters, fractals or other techniques. Finally, the data is summarized using one or more roughness parameters, or a graph. In the past, surface finish was usually analyzed by hand. The roughness trace would be plotted on graph paper, and an experienced machinist decided what data to ignore and where to place the mean line. Today, the measured data is stored on a computer, and analyzed using methods from signal analysis and statistics.[3]

Equipment

See also: Profilometer
For a full list of standardized instruments, see ISO 25178#Instruments.

Contact (tactile measurement)

Stylus-based contact instruments have the following advantages:

Technologies:

Non-Contact (optical microscopes)

Optical measurement instruments have some advantages over the tactile ones as follows:

Vertical scanning:

Horizonal scanning:

Choice of the right measurement instrument

Because of every instrument has advantages and disadvantages the operator must choose the right instrument depending on the measurement application. In the following some advantages and disadvantages to the main technologies are listed:

Resolution

The scale of the desired measurement will help decide which type of microscope will be used.

For 3D measurements, the probe is commanded to scan over a 2D area on the surface. The spacing between data points may not be the same in both directions.

In some cases, the physics of the measuring instrument may have a large effect on the data. This is especially true when measuring very smooth surfaces. For contact measurements, most obvious problem is that the stylus may scratch the measured surface. Another problem is that the stylus may be too blunt to reach the bottom of deep valleys and it may round the tips of sharp peaks. In this case the probe is a physical filter that limits the accuracy of the instrument.

Roughness parameters

The real surface geometry is so complicated that a finite number of parameters cannot provide a full description. If the number of parameters used is increased, a more accurate description can be obtained. This is one of the reasons for introducing new parameters for surface evaluation. Surface roughness parameters are normally categorised into three groups according to its functionality. These groups are defined as amplitude parameters, spacing parameters, and hybrid parameters.[6]

Profile roughness parameters

Parameters used to describe surfaces are largely statistical indicators obtained from many samples of the surface height. Some examples include:

Table of useful surface metrics
Parameter Name Description Type Formula
Ra, Raa, Ryni arithmetic average of absolute values Mean of the absolute values of the profile heights measured from a mean line averaged over the profile Amplitude R_a = \frac{1}{n} \sum_{i=1}^{n} \left | y_i \right |
Rq, RRMS root mean squared Amplitude R_q = \sqrt{ \frac{1}{n} \sum_{i=1}^{n} y_i^2 }
Rv maximum valley depth Maximum depth of the profile below the mean line with the sampling length Amplitude R_v = \min_{i} y_i
Rp maximum peak height Maximum height of the profile above the mean line within the sampling length Amplitude R_p = \max_{i} y_i
Rt Maximum Height of the Profile Maximum peak to valley height of the profile in the assessment length Amplitude R_t = R_p - R_v
Rsk Skewness Symmetry of the profile about the mean line Amplitude R_{sk} = \frac{1}{n R_q^3} \sum_{i=1}^{n} y_i^3
Rku Kurtosis Measure of the sharpness of the surface profile Hybrid R_{ku} = \frac{1}{n R_q^4} \sum_{i=1}^{n} y_i^4
RSm Mean Peak Spacing Mean Spacing between peaks at the mean line Spatial RS_{m} = \frac{1}{n} \sum_{i=1}^{n} S_i

This is a small subset of available parameters described in standards like ASME B46.1[7] and ISO 4287.[8] Most of these parameters originated from the capabilities of profilometers and other mechanical probe systems. In addition, new measures of surface dimensions have been developed which are more directly related to the measurements made possible by high-definition optical gauging technologies.

Most of these parameters can be estimated using the SurfCharJ plugin for the ImageJ.

Areal surface parameters

The surface roughness can also be calculated over an area. This gives Sa instead of Ra values. The ISO 25178 series describes all these roughness values in detail. The advantage over the profile parameters are:

Surfaces have fractal properties, multi-scale measurements can also be made such as Length-scale Fractal Analysis or Area-scale Fractal Analysis.[9]

Filtering

To obtain the surface characteristic almost all measurements are subject to filtering. It is one of the most important topics when it comes to specifying and controlling surface attributes such as roughness, waviness, and form error. These components of the surface deviations must be distinctly separable in measurement to achieve a clear understanding between the surface supplier and the surface recipient as to the expected characteristics of the surface in question. Typically, either digital or analog filters are used to separate form error, waviness, and roughness resulting from a measurement. Main multi-scale filtering methods are Gaussian filtering, Wavelet transform and more recentlty Discrete Modal Decomposition. There are three characteristics of these filters that should be known in order to understand the parameter values that an instrument may calculate. These are the spatial wavelength at which a filter separates roughness from waviness or waviness from form error, the sharpness of a filter or how cleanly the filter separates two components of the surface deviations and the distortion of a filter or how much the filter alters a spatial wavelength component in the separation process.[7]

See also

External links

References

  1. 1 2 Degarmo, E. Paul; Black, J T.; Kohser, Ronald A. (2003). Materials and Processes in Manufacturing (9th ed.). Wiley. pp. 223–224. ISBN 0-471-65653-4.
  2. "What Wavelength Goes With a Color?". Retrieved 2008-05-14.
  3. Whitehouse, DJ. (1994). Handbook of Surface Metrology, Bristol: Institute of Physics Publishing. ISBN 0-7503-0039-6
  4. Gao, F; Leach, R K; Petzing, J; Coupland, J M (2008). "Surface Measurement errors using commercial scanning white light interferometers". Measurement Science and Technology 19: 015303. Bibcode:2008MeScT..19a5303G. doi:10.1088/0957-0233/19/1/015303.
  5. Rhee, H. G.; Vorburger, T. V.; Lee, J. W.; Fu, J (2005). "Discrepancies between roughness measurements obtained with phase-shifting and white-light interferometry". Applied optics 44 (28): 5919–27. doi:10.1364/AO.44.005919. PMID 16231799.
  6. Gadelmawla E.S.; Koura M.M.; Maksoud T.M.A.; Elewa I.M.; Soliman H.H. (2002). "Roughness parameters". Journal of Materials Processing Technology 123: 133. doi:10.1016/S0924-0136(02)00060-2.
  7. 1 2 ASME B46.1. Asme.org. Retrieved on 2016-03-26.
  8. ISO 4287 Archived January 19, 2004, at the Wayback Machine.
  9. Surface Metrology Laboratory – Washburn Shops 243 – Scale-sensitive Fractal Analysis. Me.wpi.edu. Retrieved on 2016-03-26.
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