1 / 45

Technical Note 8

Technical Note 8. Process Capability and Statistical Quality Control. Process Variation Process Capability Process Control Procedures Variable data Attribute data Acceptance Sampling Operating Characteristic Curve. OBJECTIVES. Basic Forms of Variation.

walt
Download Presentation

Technical Note 8

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Technical Note 8 Process Capability and Statistical Quality Control

  2. Process Variation • Process Capability • Process Control Procedures • Variable data • Attribute data • Acceptance Sampling • Operating Characteristic Curve OBJECTIVES

  3. Basic Forms of Variation Assignable variationis caused by factors that can be clearly identified and possibly managed Example: A poorly trained employee that creates variation in finished product output. Common variationis inherent in the production process Example: A molding process that always leaves “burrs” or flaws on a molded item.

  4. High High Incremental Cost of Variability Incremental Cost of Variability Zero Zero Lower Spec Target Spec Upper Spec Lower Spec Target Spec Upper Spec Traditional View Taguchi’s View Taguchi’s View of Variation Traditional view is that quality within the LS and US is good and that the cost of quality outside this range is constant, where Taguchi views costs as increasing as variability increases, so seek to achieve zero defects and that will truly minimize quality costs. Exhibits TN8.1 & TN8.2

  5. Process Capability • Process limits • Specification limits • How do the limits relate to one another?

  6. Process Capability Index, Cpk Capability Index shows how well parts being produced fit into design limit specifications. As a production process produces items small shifts in equipment or systems can cause differences in production performance from differing samples. Shifts in Process Mean

  7. Process Capability – A Standard Measure of How Good a Process Is. A simple ratio: Specification Width _________________________________________________________ Actual “Process Width” Generally, the bigger the better.

  8. Process Capability This is a “one-sided” Capability Index Concentration on the side which is closest to the specification - closest to being “bad”

  9. The Cereal Box Example • We are the maker of this cereal. Consumer Reports has just published an article that shows that we frequently have less than 15 ounces of cereal in a box. • Let’s assume that the government says that we must be within ± 5 percent of the weight advertised on the box. • Upper Tolerance Limit = 16 + .05(16) = 16.8 ounces • Lower Tolerance Limit = 16 – .05(16) = 15.2 ounces • We go out and buy 1,000 boxes of cereal and find that they weight an average of 15.875 ounces with a standard deviation of .529 ounces.

  10. Cereal Box Process Capability • Specification or Tolerance Limits • Upper Spec = 16.8 oz • Lower Spec = 15.2 oz • Observed Weight • Mean = 15.875 oz • Std Dev = .529 oz

  11. What does a Cpk of .4253 mean? • An index that shows how well the units being produced fit within the specification limits. • This is a process that will produce a relatively high number of defects. • Many companies look for a Cpk of 1.3 or better… 6-Sigma company wants 2.0!

  12. Types of Statistical Sampling • Attribute (Go or no-go information) • Defectives refers to the acceptability of product across a range of characteristics. • Defects refers to the number of defects per unit which may be higher than the number of defectives. • p-chart application • Variable (Continuous) • Usually measured by the mean and the standard deviation. • X-bar and R chart applications

  13. Statistical Process Control (SPC) Charts UCL Normal Behavior LCL 1 2 3 4 5 6 Samples over time UCL Possible problem, investigate LCL 1 2 3 4 5 6 Samples over time UCL Possible problem, investigate LCL 1 2 3 4 5 6 Samples over time

  14. Control Limits are based on the Normal Curve x m z -3 -2 -1 0 1 2 3 Standard deviation units or “z” units.

  15. x Control Limits We establish the Upper Control Limits (UCL) and the Lower Control Limits (LCL) with plus or minus 3 standard deviations from some x-bar or mean value. Based on this we can expect 99.7% of our sample observations to fall within these limits. 99.7% LCL UCL

  16. Example of Constructing a p-Chart: Required Data Number of defects found in each sample Sample No. No. of Samples

  17. Statistical Process Control Formulas:Attribute Measurements (p-Chart) Given: Compute control limits:

  18. Example of Constructing a p-chart: Step 1 1. Calculate the sample proportions, p (these are what can be plotted on the p-chart) for each sample

  19. Example of Constructing a p-chart: Steps 2&3 2. Calculate the average of the sample proportions 3. Calculate the standard deviation of the sample proportion

  20. Example of Constructing a p-chart: Step 4 4. Calculate the control limits UCL = 0.0924 LCL = -0.0204 (or 0)

  21. UCL LCL Example of Constructing a p-Chart: Step 5 5. Plot the individual sample proportions, the average of the proportions, and the control limits

  22. Example of x-bar and R Charts: Required Data

  23. Example of x-bar and R charts: Step 1. Calculate sample means, sample ranges, mean of means, and mean of ranges.

  24. Example of x-bar and R charts: Step 2. Determine Control Limit Formulas and Necessary Tabled Values From Exhibit TN8.7

  25. UCL LCL Example of x-bar and R charts: Steps 3&4. Calculate x-bar Chart and Plot Values

  26. Example of x-bar and R charts: Steps 5&6. Calculate R-chart and Plot Values UCL LCL

  27. Basic Forms of Statistical Sampling for Quality Control • Acceptance Sampling is sampling to accept or reject the immediate lot of product at hand • Statistical Process Control is sampling to determine if the process is within acceptable limits

  28. Acceptance Sampling • Purposes • Determine quality level • Ensure quality is within predetermined level • Advantages • Economy • Less handling damage • Fewer inspectors • Upgrading of the inspection job • Applicability to destructive testing • Entire lot rejection (motivation for improvement)

  29. Acceptance Sampling (Continued) • Disadvantages • Risks of accepting “bad” lots and rejecting “good” lots • Added planning and documentation • Sample provides less information than 100-percent inspection

  30. Acceptance Sampling: Single Sampling Plan A simple goal Determine (1) how many units, n, to sample from a lot, and (2) the maximum number of defective items, c, that can be found in the sample before the lot is rejected

  31. Risk • Acceptable Quality Level (AQL) • Max. acceptable percentage of defectives defined by producer • Thea (Producer’s risk) • The probability of rejecting a good lot • Lot Tolerance Percent Defective (LTPD) • Percentage of defectives that defines consumer’s rejection point • The  (Consumer’s risk) • The probability of accepting a bad lot

  32. 1 0.9 a = .05 (producer’s risk) 0.8 0.7 n = 99 c = 4 0.6 0.5 Probability of acceptance 0.4 =.10 (consumer’s risk) 0.3 0.2 0.1 0 1 2 3 4 5 6 7 8 9 10 11 12 AQL LTPD Percent defective Operating Characteristic Curve The OCC brings the concepts of producer’s risk, consumer’s risk, sample size, and maximum defects allowed together The shape or slope of the curve is dependent on a particular combination of the four parameters

  33. Example: Acceptance Sampling Problem Zypercom, a manufacturer of video interfaces, purchases printed wiring boards from an outside vender, Procard. Procard has set an acceptable quality level of 1% and accepts a 5% risk of rejecting lots at or below this level. Zypercom considers lots with 3% defectives to be unacceptable and will assume a 10% risk of accepting a defective lot. Develop a sampling plan for Zypercom and determine a rule to be followed by the receiving inspection personnel.

  34. Example: Step 1. What is given and what is not? In this problem, AQL is given to be 0.01 and LTDP is given to be 0.03. We are also given an alpha of 0.05 and a beta of 0.10. What you need to determine is your sampling plan is “c” and “n.”

  35. Exhibit TN 8.10 c LTPD/AQL n AQL c LTPD/AQL n AQL 0 44.890 0.052 5 3.549 2.613 1 10.946 0.355 6 3.206 3.286 2 6.509 0.818 7 2.957 3.981 3 4.890 1.366 8 2.768 4.695 4 4.057 1.970 9 2.618 5.426 Example: Step 2. Determine “c” First divide LTPD by AQL. Then find the value for “c” by selecting the value in the TN8.10 “n(AQL)”column that is equal to or just greater than the ratio above. So, c = 6.

  36. Example: Step 3. Determine Sample Size Now given the information below, compute the sample size in units to generate your sampling plan c = 6, from Table n (AQL) = 3.286, from Table AQL = .01, given in problem n(AQL/AQL) = 3.286/.01 = 328.6, or 329 (always round up) Sampling Plan: Take a random sample of 329 units from a lot. Reject the lot if more than 6 units are defective.

  37. Question Bowl A methodology that is used to show how well parts being produced fit into a range specified by design limits is which of the following? • Capability index • Producer’s risk • Consumer’s risk • AQL • None of the above Answer: a. Capability index

  38. Question Bowl On a quality control chart if one of the values plotted falls outside a boundary it should signal to the production manager to do which of the following? • System is out of control, should be stopped and fixed • System is out of control, but can still be operated without any concern • System is only out of control if the number of observations falling outside the boundary exceeds statistical expectations • System is OK as is • None of the above Answer: c. System is only out of control if the number of observations falling outside the boundary exceeds statistical expectations (We expect with Six Sigma that 3 out of 1,000 observations will fall outside the boundaries normally and those deviations should not lead managers to conclude the system is out of control.)

  39. Question Bowl You want to prepare a p chart and you observe 200 samples with 10 in each, and find 5 defective units. What is the resulting “fraction defective”? • 25 • 2.5 • 0.0025 • 0.00025 • Can not be computed on data above Answer: c. 0.0025 (5/(2000x10)=0.0025)

  40. Question Bowl You want to prepare an x-bar chart. If the number of observations in a “subgroup” is 10, what is the appropriate “factor” used in the computation of the UCL and LCL? • 1.88 • 0.31 • 0.22 • 1.78 • None of the above Answer: b. 0.31 (from Exhibit TN8.7)

  41. Question Bowl You want to prepare an R chart. If the number of observations in a “subgroup” is 5, what is the appropriate “factor” used in the computation of the LCL? • 0 • 0.88 • 1.88 • 2.11 • None of the above Answer: a. 0 (from Exhibit TN8.7)

  42. Question Bowl You want to prepare an R chart. If the number of observations in a “subgroup” is 3, what is the appropriate “factor” used in the computation of the UCL? • 0.87 • 1.00 • 1.88 • 2.11 • None of the above Answer: e. None of the above (from Exhibit TN8.7 the correct value is 2.57)

  43. Question Bowl The maximum number of defectives that can be found in a sample before the lot is rejected is denoted in acceptance sampling as which of the following? • Alpha • Beta • AQL • c • None of the above Answer: d. c

  44. End of Technical Note 8

More Related