How Accurate Is Your Machining Center?
Figure 1
PreviousNextThere are several positioning standards that provide methods by which an accuracy or repeatability specification can be determined. The same machine tool will give different accuracy and repeatability numbers depending on the standard used. This makes comparison shopping between various machine tools difficult.
This article compares six of the most common linear Carbide Turning Inserts positioning standards used by the machine tool industry, in the United States, Europe and Asia to qualify machining centers. The standards that will be compared are:
NMTBA (United States), ISO 230-2 (Europe), BSI BS 4656 Part 16 (British), VDI/DGQ 3441 (German), JIS B 6336-1986 (Japanese), and ASME B5.54-92 (USA).
But before getting into a comparison of these standards, it's necessary to define some critical terminology. Defining these terms permits discussion from a common frame of reference.
Most of us have, at one time or another, shot a gun or bow, or thrown a dart. In each case we were trying to hit a target, preferably the bull's-eye. If we fire six times at the target bull's-eye and hit it every time, we have very good aim—we are accurate. The bull's-eye would probably look like Figure 1.
This same analogy applies to machine tools. Both the machine builder and user want the machine slide to hit that target bull's-eye every time it's moved. But the machine sometimes has different ideas. An accuracy spec quantifies how well we hit the target. Each linear positioning standard defines a method for determining accuracy and other specifications on a consistent basis.Machine tool builders talk about three kinds of accuracy: unidirectional forward, unidirectional reverse and bidirectional. Let's say you were in a contest where you had to walk toward a target while shooting and then shoot at the same target while walking away from it. The accuracy while walking toward the target would be unidirectional forward accuracy and that walking away from the target is unidirectional reverse. Each of these are scored individually. You can also score the overall accuracy forward and reverse. This is called bidirectional accuracy because it takes both directions into account.
Machine tool builders can describe accuracy with terms like error-band, accuracy, positional deviation, position uncertainty and mean-to-mean accuracy. Each of these terms is calculated differently.
If we look again at Figure 1, the distance between each hit illustrates repeatability. We know they are all in the bull's-eye but chances are the person firing the gun wavered slightly or was just a fraction of an inch off when sighting, causing the bullets to hit not one on top of the other, which would be perfect repeatability, but rather in a pattern shown in Figure 1. This pattern is repeatability. Machine tool slides also vary about the target point. Here's another example of accuracy and repeatability.
Figure 2 shows a very tight pattern. Therefore, the repeatability is very good. Even so, the person must have pulled left every time he/she fired, or maybe the rifle sight was off to the left slightly. The result is poor accuracy. Remember the bull's-eye is still the target.
We can enter the same contest of shooting at a target while walking toward it and away from it. Walking toward the target we get a pattern of holes perhaps like Figure 3. This represents forward repeatability.
Walking away from the target we may get a pattern like Figure 4. This illustrates reverse repeatability.
Repeatability is tested as the total range, so if the bottom bullet hole and the top bullet hole are 0.5 inch apart, then this figure represents the repeatability. There is also a bidirectional repeatability which takes into account both Figures 3 and 4, and as a value would be the distance from the bottom bullet hole on Figure 4 to the top hole on Figure 3.
Transferring this comparison to a machine tool, we have six targets for each machine slide. We position to these targets from both directions seven times and from this information we derive repeatability.
Repeatability may be described by terms such as forward repeatability, reverse repeatability, bidirectional repeatability, and positional scatter. Each of these terms is calculated differently.
Lost MotionLost motion means motion is initiated but you don't see any results until all the lost motion is accounted for—like taking up slack on a block and tackle. If you look closely at Figures 3 and 4 you will notice our marksman has lost motion. In Figure 3, all the bullets are left of center, and in Figure 4 they are right of center. The difference between them is lost motion. Other lost motion terms are reversal error, and mean reversal error.
Now assume we have six targets, and position to each target seven times. We position from an arbitrary starting point—let's call it zero. If we position to six targets, turn around and position to the same six targets on our way back to zero, save all the errors at each target point, then repeat this seven times, we have 84 pieces of data. Figure 5 will give you the general idea of the normal collection process for these data.
From this data accuracy, repeatability, and lost motion specifications are calculated.
SigmaBut before we calculate any of these values, we must talk about sigma. It's represented by the Greek letter s or S. Sigma is also known as Standard Deviation. Standard deviation is normally shown using a bell shaped curve as shown in Figure 6 (at right).
On each side of center (x) is 3s, which is three times one sigma.
As you can see, on the bell curve, ± 1 sigma covers about 68 percent of the area under the curve. ±2 sigma covers 95 percent and ±3 sigma covers 99.7 percent. If we position to our six targets seven times each, calculate the standard deviation, and multiply it by six, then 997 times out of 1,000, we would hit our six targets within that value.
The same raw data was used for all six comparisons. This data is in the inch system of measurement and all values are in microinches (millionths of an inch). So, for example a measurement of 982 as indicated on the chart would be 0.000982 or 982 millionths of an inch.
What's It Mean?All the standards except JIS output total bandwidth for the values, even though many builders advertise ± values regardless of which standard is used. This may render the appearance of a lower number.
NMTBA is the only standard that statistically calculates using bidirectional data. The other statistical standards generate their bidirectional data from the individual forward and reverse information only. This is not necessarily better or worse than NMTBA, but it definitely does result in smaller figures, which can unfairly impact a prospective customer's spreadsheet. The fact is that NMTBA is the most stringent.
ASME B5.54-92 is really the "new kid on the block," but has quickly become the new national standard of the United States, replacing the statistical NMTBA in many arenas. However, each standard has its place depending on your taste for either statistical data or actual raw data.
In summary, any of the standards described may be used to evaluate a machine tool's linear positioning. However, we must be aware that one standard can allow the machine to appear to be more accurate than it will be when evaluated using another standard.
About the authors: Steven Klabunde is vice president of corporate technology and Ronald Schmidt is quality assurance test engineer for Giddings & Lewis, Fond du Lac, Wisconsin.
Comparison OverviewAs can be seen from the numerical comparison table (at the bottom of this page), values represented by the various standards can vary dramatically given the same raw data.
NMTBA. Because this standard has been the reigning monarch of American machining centers for several decades, we will use it as the standard for comparison of all others.
ISO 230-2 calculates forward, reverse, and bidirectional repeatability. Notice that bidirectional has a different value than NMTBA. This is because ISO uses the largest of six sigma forward and reverse or the sum of three sigma forward plus three sigma reverse plus the absolute value of lost motion, whereas NMTBA statistically calculates the bidirectional repeatability.
ISO also uses the average error for lost motion instead of the point with the largest lost motion like NMTBA. This results in about 40 percent of the values of NMTBA. Accuracy in ISO is calculated by finding the largest signed number in the + 3 forward and reverse data, then subtracting the smallest signed number from the forward/reverse - 3 data. NMTBA calculates accuracy forward, reverse, and bidirectionally; all statistically. ISO uses only forward and reverse data.
VDI forward and reverse accuracy is the same as NMTBA. Forward, reverse repeatability are the same as NMTBA. Positioning uncertainty (P) is related to bidirectional accuracy but is calculated using averages and averages of averages.
This procedure reduces the actual numbers to about 40 percent of the NMTBA value in this example (compare 1966 and 851). Positional deviation (Pa) is mean-to-mean accuracy. It is the average of the forward runs less the average of the reverse runs; then the average of these is taken.
Again, it results in a very small number with no correlation to any NMTBA value. Positional scatter (Ps) is related to bidirectional repeatability. VDI averages sigma from forward and reverse, gets the absolute value, then multiplies the value by six and keeps the largest value. NMTBA statistically calculates the bidirectional sigma value, multiplies it by three, and uses this 3 value as bidirectional repeatability. On the chart, lost motion or reversal error is (U). This value compares to NMTBA lost motion and has the same value.
BSI is identical to ISO except for an additional term in BSI called mean bidirectional position deviation (D). This term does not have a similar term in NMTBA. The D value is the largest average of the forward and reverse averages less the smallest of the average forward + reverse averages.
JIS B 6336-1986 treats accuracy and repeatability differently than most other standards. Accuracy is measured by positioning to equal increments covering almost the entire travel of the slide, once in each direction. The accuracy is then the largest error range of either the plus or minus direction.
For repeatability, the standard requires positioning to a point at one end of travel seven times. This procedure is then repeated at the center of travel and again at the opposite end of travel. The largest error at any of the three points is saved. The process is repeated in the opposite direction. The largest error in either direction is divided by two to give a ± value.
Lost motion is calculated by positioning to a reference point, continuing in the same direction by a known increment, then reversing by the same increment. This procedure is repeated at both ends and the center of travel. At each location, data are collected seven times, averaged, and the largest of the three averages is called lost motion.
ASME B5.54 accuracy is determined by the range of the average deviations. From the forward we use the largest and smallest values regardless if in forward or reverse. The standard specifies three round trips. Since the data used for this discussion is seven round trips, the numbers will be of a wider range than normal.
An additional linear performance attribute is also obtained from the averages. This figure is maximum reversal error (Rmax) and is defined as the maximum difference of the forward and the reverse , the same as many of the statistical standards do.
The B5.54 standard calls for bidirectional repeatability to be tested in a fashion similar to that of JIS 6336 but bidirectionally. However, most manufacturers and most laser software calculate the repeatability directly from the accuracy runs. This provides more data which is spread over all target points compared to the ten bidirectional hits at two locations that the current standard calls for.
Thus a request is under consideration to change this part of the standard.
Numerical Comparisons NMTBA ISO VDI BSI JIS B5.54
-------------------------------------------------------------------------------- AccuracyForward Accuracy 982 NA 982 NA NA NAReverse Accuracy 1030 NA 1030 NA NA NABidirectional Accuracy 1966 NA NA NA NA NAAccuracy NA A 1109 NA A 1109 NA A 937Positional Deviation NA NA Pa 449 NA NA NAPositional Uncertainty NA NA P 851 NA NA NAMean Position Deviation NA NA NA D 799 NA NAForward Absolute Accuracy NA NA NA NA 600 NAReverse Absolute Accuracy NA NA NA NA 480 NABidirectional Absolute Accuracy NA NA NA NA NA NA NMTBA ISO VDI BSI JIS B5.54
-------------------------------------------------------------------------------- RepeatabilityForward Repeatability 182 R182 182 RU+182 NA NAReverse Repeatability 280 R280 280 RU-280 NA NABidirectional Repeatability 1966 R 820 NA RB 820 NA NAPositional Scatter NA NA Ps 222 NA NA NAForward Absolute Repeatability NA NA NA NA 420 NACermet Inserts Reverse Absolute Repeatability NA NA NA NA NA NABidirectional Absolute Repeatability NA NA NA NA NA NA NMTBA ISO VDI BSI JIS B5.54
-------------------------------------------------------------------------------- Lost MotionLost Motion 629 NA NA NA 180 NAMean Reversal Error NA B 203 NA B 203 NA NAReversal Error NA NA U 629 NA NA R max 629
=Forward Repeatability =Reverse Repeatability
The drilling inserts suppliers Blog: http://onlooker.livedoor.biz/by abrahamboy | 2023-06-06 12:44
