1 / 25

Chapter 8. Process Capability & Statistical Quality Control

Chapter 8. Process Capability & Statistical Quality Control . Outline: Basic Statistics Process Variation Process Capability Process Control Procedures Variable data X-bar chart and R-chart Attribute data p-chart Acceptance Sampling Operating Characteristic Curve. Focus.

verrill
Télécharger la présentation

Chapter 8. Process Capability & Statistical Quality Control

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. Chapter 8. Process Capability & Statistical Quality Control Outline: • Basic Statistics • Process Variation • Process Capability • Process Control Procedures • Variable data • X-bar chart and R-chart • Attribute data • p-chart • Acceptance Sampling • Operating Characteristic Curve

  2. Focus • This technical note on statistical quality control (SQC) covers the quantitative aspects of quality management • SQC is a number of different techniques designed to evaluate quality from a conformance view • How are we doing in meeting specifications? • SQC can be applied to both manufacturing and service processes • SQC techniques usually involve periodic sampling of the process and analysis of data • Sample size • Number of samples • SQC techniques are looking for variance • Most processes produce variance in output • we need to monitor the variance (and the mean also) and correct processes when they get out of range

  3. μ -3s +3s 99.7% Basic Statistics Normal Distributionshave a mean (μ) and a standard deviation (σ) For a sample of N observations: Mean where: xi = Observed value N = Total number of observed values Standard Deviation

  4. -3s -2s +2s +3s 99.7% a/2 a/2 LCL UCL a = Prob. ofType I error Statistics and Probability • SQC relies on central limit theorem and normal dist. • We establish the Upper Control Limits (UCL) and the Lower Control Limits (LCL) with plus or minus 3 standard deviations. Based on this we can expect 99.7% of our sample observations to fall within these limits. • Acceptance sampling relies on Binomial and Hyper geometric probability concepts

  5. Basic Stats • Using SQC, • samples of a process output are taken, and • sample statistics are calculated • The purpose of sampling is to find when the process has changed in some nonrandomway • The reason for the change can then be quickly determined and corrected • This allows us to detect changes in the actual distribution process

  6. Variation • Random (common) variation is inherent in the production process. • Assignable variation is caused by factors that can be clearly identified and possibly managed • Using a saw to cut 2.1 meter long boards as a sample process • Discuss random vs. assignable variation • Generally, when variation is reduced, quality improves. • It is impossible to have zero variability. T or F ?

  7. 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

  8. Process Capability • Tolerance (specification, design) Limits • Bearing diameter 1.250 +- 0.005 inches • LTL = 1.245 inches UTL = 1.255 inches • Process Limits • The actual distribution from the process • Run the process to make 100 bearings, compute the mean and std. dev. (and plot/graph the complete results) • Suppose, mean = 1.250, std. dev = 0.002 • How do they relate to one another?

  9. Specification Width Actual Process Width Specification Width Actual Process Width Tolerance Limits vs. Process Capability

  10. Process Capability Example • Design Specs: Bearing diameter 1.250 +- 0.005 inches • LTL = 1.245 inches UTL = 1.255 inches • The actual distribution from the process  mean = 1.250, s = 0.002 • +- 3s limits  1.250 +- 3(0.002)  [1.244, 1.256] • Anew process,  std. dev. = 0.00083

  11. Process Capability Index, Cpk • Capability Index shows how well parts being produced fit into design limit specifications • Compute the Cpk for the bearing example. • Old process, mean = 1.250, s = 0.002 • What is the probability of producing defective bearings? • New process, mean = 1.250, s= 0.00083, re-compute the Cpk • When the computed (sample) mean = design (target) mean, what does that imply?

  12. The Cereal Box Example • Recall the cereal example. 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 + 0.05(16) = 16.8 ounces • Lower Tolerance Limit = 16 – 0.05(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 0.529 ounces.

  13. 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 = 0.529 oz • What does a Cpkof 0.4253 mean? • Many companies look for a Cpk of 1.3 or better… 6-Sigma company wants 2.0!

  14. Types of Statistical Sampling • Sampling to accept or reject the immediate lot of product at hand (Acceptance Sampling). • Attribute (Binary; Yes/No; Go/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 • Sampling to determine if the process is within acceptable limits (Statistical Process Control) • Variable (Continuous) • Usually measured by the mean and the standard deviation. • X-bar and R chart applications

  15. Evidence for Investigation…

  16. x UCL LCL Control Limits • If we establish control limits at +/- 3 standard deviations, then we would expect 99.7% of our observations to fall within these limits

  17. Attribute Measurements (p-Chart) • Item is “good” or “bad” • Collect data, compute average fraction bad (defective) and std. dev. using: • The, UCL, LCL using: • Excel time!

  18. Variable Measurements (x-Bar and R Charts) • A variable of the item is measured (e.g., weight, length, salt content in a bag of chips) • Note that the item (sample) is not declared good or bad • Since the actual the standard deviation of the process is not known (and it may indeed fluctuate also) we use the sample data to compute the UCL & LCL • For 3-sigma limits, factors A2 , D3 , and D4 and are given in Exhibit TN8.7, p. 359 • Excel time!

  19. Acceptance Sampling vs. SPC • Sampling to accept or reject the immediate lot of productat hand (Acceptance Sampling). • Determine quality level • Ensure quality is within predetermined (agreed) level • Sampling to determine if the process is within acceptable limits - Statistical Process Control (SPC) 3

  20. Advantages Economy Less handling damage Fewer inspectors Upgrading of the inspection job Applicability to destructive testing Entire lot rejection (motivation for improvement) Disadvantages Risks of accepting “bad” lots and rejecting “good” lots Added planning and documentation Sample provides less information than 100-percent inspection Acceptance Sampling

  21. A Single Sampling Plan • A Single Sampling Plan simply requires two parameters to be determined: • n the sample size (how many units to sample from a lot) • c the maximum number of defective items that can be found in the sample before the lot is rejected.

  22. RISK • RISKSfor the producer and consumer in sampling plans: • Acceptable Quality Level (AQL) • Max. acceptable percentage of defectives defined by producer. • a(Producer’s risk) • The probability of rejecting a good lot. • Lot Tolerance Percent Defective (LTPD) • Percentage of defectives that defines consumer’s rejection point. •  (Consumer’s risk) • The probability of accepting a bad lot.

  23. 1 0.9 a = .05 (producer’s risk) 0.8 0.7 n = 99 c = 4 0.6 Probability of acceptance 0.5 0.4 B =.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 9

  24. Example: Acceptance Sampling 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. 10

  25. 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 Developing A Single Sampling Plan • Determine: • AQL? a? • LTPD? ? • Divide LTPD by AQL  0.03/0.01 = 3 • 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 (3). • Thus,c= 6 • From the row with c=6, get  nAQL = 3.286 and divide it by AQL • 3.286/0.01 = 328.6, round up to 329, n = 329 Sampling Plan: Take a random sample of 329 units from a lot. Reject the lot if more than 6 units are defective.

More Related