Median/Individual Measurements Control Charting and Analysis for Family Processes by John van der Veen and Perry Holst

Zuletzt geändert 3rd Jan 2013
Category: Qualitatskontrolle > Quality Analyst
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Quality Analyst E696 Quality Analyst case study Introduction In the late 1980s, consultants John van der Veen and Perry Holst became aware of the special problems associated with control charting for manufacturing applications they referred to as family processes. Typical examples of family processes are bottle filling and parts manufacture using multiple cavity molds. Family processes share many or all the following characteristics: The family consists of multiple similar or identical member processes originating from a common source or manufacturing stream. For example, a bottling line may have 24 fill heads. The member processes are completed more or less simultaneously. E.g. all bottles are filled in a single step. Each member process may have its own mechanical component(s) or subsystem. E.g. each bottle filler head has its own supply tube and fill head. Each member process has its own sources of variation. E.g. Bottle filler head performance may vary. The family process as a whole is subject to its own global causes of variation. E.g. Bottle fill line pressure may fluctuate. Family processes undoubtedly increase the speed and convenience of manufacturing. However, control charts depict only global sources of variation and cannot pinpoint local assignable causes for individual family members. For example, consider the results when a single fill channel is blocked in a 12-cavity mold. Control charts, as commonly applied, use a random sampling from all cavities and therefore cannot identify the specific cavity with the obstructed channel. The channel may remain blocked, yet the chart will show the overall process to be in statistical control. Conversely, charting each cavity each family memberwould be impractical and time-consuming. In further addressing the problems of family process analysis, Holst and van der Veen encountered a valuable but underutilized analytical technique, Median/Individual measurements (M/I) control charting. The power of the M/I chart, says van der Veen, is in its ability to display sources of variation separately. This allows you to identify the source of any problem and take appropriate action. Through use of M/I charting, manufacturers can avoid improper interpretation of data and subsequent problems of over-adjustment and unnecessary batch replacement of tools, machine parts or equipment. Family processes are affected by two types of factors: those that influence all family members and those that influence only one individual member. As the name implies, Median/Individual charting examines data from both perspectives. The median is the midpoint of a samples measurements and therefore tracks the global process. Individuals depict single members of the measured family. When the median is shown to be in control, it typically indicates that the overall process is in control. If the median trends out of control, the global process is likely also out of control. If all family members are in control, no individual stands out. If an individual member charts out of control, the operator should look for a local assignable cause. In a trial application using Median/Individual charting a major motor oil producer analyzed data from a 36-head bottle filling line. To determine fill, weights were recorded from the filled bottle conveyor. Subsequent process changes included adjusting a chronically malfunctioning fill head identified through M/I charting. Soon fill variation was reduced below bottle tare variation. This prompted the producer to recommend M/I charting to its bottle manufacturer, a multiple cavity mold user. The lubricant producer now plans to apply M/I charting at all of its facilities. They expect to realize a savings of some 600,000 gallons of motor oil annually from improvements in fill operations alone. Median/Individual measurements control charting offers advantages to any number of family process applications: Metal, glass or plastic package manufacture Metal, glass or plastic package filling Cast or molded metal and plastic product manufacture Machining with multiple grinders or spindles Printed circuit board manufacture for analyzing board drilling, as well as part placement and attachment In addition to these, Northwest Analytical and the authors believe there are numerous other applications yet to be described. Median/Individual Measurements Control Charts For Family Processes A family process consists of a number of statistically independent processes that are affected by common factors. Often, there are too many independent processes (family members) to chart each one separately. This causes manufacturers to examine the entire family process by combining the independent processes in a single X-bar control chart using small random samples (n=5, for example). These efforts are futile, because such charts are insensitive to the independent processes. In contrast, Median/Individual measurements control (M/I) charts reveal not only the behavior of the entire family process, but also the behavior of the independent processes. M/I charts foster process improvement by concentrating on the outlying independent processes. Insensitivity In single output processes, all process factors are globalthe product is acted upon by every factor in the process. A change in any global factor will result in a corresponding change in the final product. Therefore, when plotted on an X-bar chart, a small sample of contiguous output from a single output process will inarguably show product variation caused by global factors. However, the output of family processes is also subject to statistically independent individual factors. That is, each member of the family has its own set of localized variations. These local variations will affect an X-bar chart only when they are includedby chanceas part of the sample. If an operator samples five units from a 32-cavity mold, the probability of a cavity not being included in the sample is 83.3%. With hourly sampling, production may go for a full shift or even a full day without sampling one of the cavities. (Table 1) This insensitivity defeats one of the primary reasons for using control charts: early detection of process changes leading to nonconforming production. When a faulty cavity is part of a sample that leads to an out of control point, the usual response is to adjust global process factors. If the offending family member is not included in the next sample, the process will then appear to have been properly adjusted. In fact, the operator will have erroneously changed a process that was actually in statistical control, causing the process to now trend out of control. In a multiple head filling line, the global process may chart as centered within the control limits, yet individual heads may simultaneously short fill and over fill. If global factors trend up from center, more samples start to show some overfill. Based on this information, the operator would then adjust the process downward. Soon, the samples start showing short fills and the operator adjusts the process upwards. This never-ending cycle of adjustment produces nonconforming products most of the time. The actual solutions would be either to adjust the extreme heads towards center to accommodate global variation or to reduce the amount of variation in the offending individual family members. If control limits are calculated from sufficient historical data to include all the effects of locally induced variation, the control limits will then be artificially inflated, compounding the problems of small sample X-bar charts. As a consequence, the global factors for which the chart is intended will be poorly and inadequately controlled. One obvious alternative is to use a sample consisting of one unit from each individual of the family. Individual variations of sufficient magnitude will be shown as out of control on the range chart. This approach primarily conveys information from the global effects; we still lack sufficient information to easily identify offending individuals. Moreover, an individual can exceed its expected variation and still not show up as an out of control point on the full sample X-bar chart. Inefficiency Another alternative is to keep separate small sample X-bar charts for each individual family member. However, the logistics of collecting even as few as five samples from each member is both impractical and inefficient; for a 16-cavity mold, sample collection would involve sorting by cavity, measuring, and plotting 80 units for each sample period. Larger family processes typically may have as many as 64 or more members. Data gathering and analysis for hourly samples would be a full-time job and still produce delayed results. Additionally, charting each family member does not readily convey information about global factors affecting the process. Finding a solution The dilemma posed by family processes required an innovative solution. In their book Statistical Quality Control, Grant and Leavenworth proposed manually combining the results of median charts with individual measurements charts. Individual measurements track local variations, while median charts monitor global variation. Median charts require no calculations by the operator, eliminating still another potential source for errors. Range variations are inherently visible in the plot of each sample. In a median chart, each sample or observation consists of a unit from each member of the family. Sampling frequency is process-dependent; initially, sampling should be frequent enough to profile the process. Ongoing sampling frequency depends on the rate of variation. Stable processes need to be sampled less frequently. A median () is a measurement of central tendency similar to mean (). The median of a sample is that point which divides the values of the individual () measurements in half. 50% of the values are greater than the median and 50% are less than the median. If the sample size (n) is an odd number,

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