Statistical Process Control

Statistical Process Control Douglas M. Stewart, Ph.D. The Anderson Schools of Management The University of New Mexico

Quality Control (QC) • Control – the activity of ensuring conformance to requirements and taking corrective action when necessary to correct problems • Importance • Daily management of processes • Prerequisite to longer-term improvements

Designing the QC System • Quality Policy and Quality Manual • Contract management, design control and purchasing • Process control, inspection and testing • Corrective action and continual improvement • Controlling inspection, measuring and test equipment (metrology, measurement system analysis and calibration) • Records, documentation and audits

Example of QC: HACCP System • Hazard analysis • Critical control points • Preventive measures with critical limits for each control point • Procedures to monitor the critical control points • Corrective actions when critical limits are not met • Verification procedures • Effective record keeping and documentation

Inspection/Testing Points • Receiving inspection • In-process inspection • Final inspection

Receiving Inspection • Spot check procedures • 100 percent inspection • Acceptance sampling

Lot received for inspection Sample selected and analyzed Results compared with acceptance criteria Accept the lot Reject the lot Send to production or to customer Decide on disposition Acceptance Sampling

Arguments for: Provides an assessment of risk Inexpensive and suited for destructive testing Requires less time than other approaches Requires less handling Reduces inspector fatigue Arguments against: Does not make sense for stable processes Only detects poor quality; does not help to prevent it Is non-value-added Does not help suppliers improve Pros and Cons of Acceptance Sampling

In-Process Inspection • What to inspect? • Key quality characteristics that are related to cost or quality (customer requirements) • Where to inspect? • Key processes, especially high-cost and value-added • How much to inspect? • All, nothing, or a sample

Economic Model C1 = cost of inspection and removal of nonconforming item C2 = cost of repair p = true fraction nonconforming Breakeven Analysis: p*C2 = C1 If p > C1 / C2 , use 100% inspection If p < C1 / C2 , do nothing

Human Factors in Inspection complexity defect rate repeated inspections inspection rate Inspection should never be a means of assuring quality. The purpose of inspection should be to gather information to understand and improve the processes that produce products and services.

Gauges and Measuring Instruments • Variable gauges • Fixed gauges • Coordinate measuring machine • Vision systems

Examples of Gauges

Metrology - Science of Measurement Accuracy - closeness of agreement between an observed value and a standard Precision - closeness of agreement between randomly selected individual measurements

Repeatability and Reproducibility • Repeatability (equipment variation) – variation in multiple measurements by an individual using the same instrument. • Reproducibility (operator variation) - variation in the same measuring instrument used by different individuals

Repeatability and Reproducibility Studies • Quantify and evaluate the capability of a measurement system • Select m operators and n parts • Calibrate the measuring instrument • Randomly measure each part by each operator for r trials • Compute key statistics to quantify repeatability and reproducibility

Reliability and Reproducibility Studies(2)

Reliability and Reproducibility Studies(3)

R&R Constants

R&R Evaluation • Under 10% error - OK • 10-30% error - may be OK • over 30% error - unacceptable

R&R Example • R&R Study is to be conducted on a gauge being used to measure the thickness of a gasket having specification of 0.50 to 1.00 mm. We have three operators, each taking measurement on 10 parts in 2 separate trials.

Calibration • Calibration - comparing a measurement device or system to one having a known relationship to national standards • Traceability to national standards maintained by NIST, National Institute of Standards and Technology

Statistical Process Control (SPC) • A methodology for monitoring a process to identify special causes of variation and signal the need to take corrective action when appropriate • SPC relies on control charts

Common Causes Special Causes

Histograms do not take into account changes over time. Control charts can tell us when a process changes

Control Chart Applications • Establish state of statistical control • Monitor a process and signal when it goes out of control • Determine process capability

Commonly Used Control Charts • Variables data • x-bar and R-charts • x-bar and s-charts • Charts for individuals (x-charts) • Attribute data • For “defectives” (p-chart, np-chart) • For “defects” (c-chart, u-chart)

Developing Control Charts • Prepare • Choose measurement • Determine how to collect data, sample size, and frequency of sampling • Set up an initial control chart • Collect Data • Record data • Calculate appropriate statistics • Plot statistics on chart

Next Steps • Determine trial control limits • Center line (process average) • Compute UCL, LCL • Analyze and interpret results • Determine if in control • Eliminate out-of-control points • Recompute control limits as necessary

Typical Out-of-Control Patterns • Point outside control limits • Sudden shift in process average • Cycles • Trends • Hugging the center line • Hugging the control limits • Instability

Shift in Process Average

Identifying Potential Shifts

Cycles

Trend

Final Steps • Use as a problem-solving tool • Continue to collect and plot data • Take corrective action when necessary • Compute process capability

Process Capability • Capability Indices

Process Capability (2)

Control In Control Out of Control Capability Capable Not Capable IDEAL Capability Versus Control

Process Capability Calculations

Excel Template

Special Variables Control Charts • x-bar and s charts • x-chart for individuals

Statistical Process Control