Quality Control PDF PowerPoint Presentation

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This PowerPoint presentation details quality control. It covers concepts like quality control, process control, and inspection. It's intended to be an educational resource on the topic.

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Chapter 10

Quality Control

© McGraw Hill LLC. All rights reserved. No reproduction or distribution without the prior written consent of McGraw Hill LLC.
 What is Quality Control? LO 10.1

Quality control:
A process that evaluates output relative to a standard and
takes corrective action when output doesn’t meet
standards.
If results are acceptable no further action is required.
Unacceptable results call for correction action.
Inspection alone is not sufficient to achieve a reasonable
level of quality.
Most organizations rely upon some inspection and a
great deal of process control to achieve an acceptable
level of quality.

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 Approaches to Quality
LO 10.1
Assurance

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 Acceptance Sampling and
LO 10.2
Process Control
Inspection before and after production often involves
acceptance sampling procedures.
Monitoring during production process called process
control.

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 Inspection LO 10.2

Inspection:
An appraisal activity that compares goods or services to a
standard.
Inspection issues:
How much to inspect and how often.
At what points in the process inspection should occur.
Whether to inspect in a centralized or on-site location.
Whether data results from inspecting attributes or
variables.

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 How Much to Inspect LO 10.2

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 How Often to Inspect LO 10.2

Frequency of inspection depends on the rate at which:
A process may go out of control.
On number of lots being inspected.

A stable process will require only infrequent checks.
Many small lots will require more samples than a few
large lots.

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 Where to Inspect in the Process LO 10.2

Typical inspection points:
Raw materials and purchased parts.
Finished products.
Before a costly operation.
Before an irreversible process.
Before a covering process.

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 Example of Inspection at a
LO 10.2
Hotel/Motel
Inspection Point Characteristics
Accounting/billing Accuracy, timeliness
Building and grounds Appearance and safety
Main desk Appearance, waiting times, accuracy of bills
Maid service Completeness, productivity
Personnel Appearance, manners, productivity
Reservations/occupancy Over/underbooking, percent occupancy
Restaurants Kitchen, menus, meals, bills
Room service Waiting time, quality of food
Supplies Ordering, receiving, inventories

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 Off-Site v s On-Site Inspection
ersu
LO 10.2

Effects on cost and level of disruption are a major issue
in selecting centralized versus on-site inspection.
Off-Site:
Specialized tests that may best be completed in a lab.
More specialized testing equipment.
More favorable testing environment.
On-Site:
Quicker decisions are rendered.
Avoidance of introduction of extraneous factors.
Quality at the source.

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 Statistical Process Control (SPC) LO 10.2

Quality control seeks quality of conformance of a
process.
Does the output of a process conform to the intent of
design?

SPC is used to evaluate process output.
Statistical evaluation of the output of a process.
Helps us to decide if a process is “in control” or if corrective
action is needed.

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 Process Variability LO 10.2

All processes generate output that exhibits some degree
of variability.
Two basic questions concerning variability:
1. Issue of process control.
Are the variations random? If nonrandom variation is
present, the process is considered to be unstable.

2. Issue of process capability.

Given a stable process, is the inherent variability of the
process within a range that conforms to performance
criteria?

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 Variation LO 10.2

Two kinds of variability:
Chance or random variations (common cause):
Natural variations in the output of a process, created by
countless minor factors.
Assignable (special cause) variation:
A variation whose cause can be identified.
A nonrandom variation.

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 Sampling and Sampling
LO 10.2
Distribution 1

Statistical process control involves periodically taking
samples of process output and computing sample statistics:
Sample means.
The number of occurrences of certain outcome.

Sample statistics exhibit variation.
Sample statistics are used to judge the randomness of
process variation.
The variability of sample statistics described by its sampling
distribution.

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 Sampling and Sampling
LO 10.2
Distribution 2

The sampling distribution of means is normal, and it has
less variability than the process distribution, which might
not be normal.

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 Sampling and Sampling
LO 10.2
Distribution 3

Percentage of values within given ranges in a normal
distribution.

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 Control Process LO 10.3

Sampling and corrective action are only a part of the control
process.
Steps required for effective control:
Define: What is to be controlled?
Measure: How will measurement be accomplished?
Compare: There must be a standard of comparison.
Evaluate: Establish a definition of out of control.
Correct: Uncover the cause of nonrandom variability and
fix it.
Monitor results: Verify that the problem has been
eliminated.

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 Control Charts: The Voice of the
LO 10.4
Process
Control chart:
A time-ordered plot of sample statistics obtained from an
ongoing process (for example, sample means), used to
determine if the variability exhibited reflects random
variation.
Control limits:
The dividing lines between random and nonrandom
deviations from the mean of the distribution.
Upper and lower control limits define the range of
acceptable variation.

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 Control Chart and Control Limits LO 10.4

Each point on the control chart represents a sample of n
observations.
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 Control Limits LO 10.4

Control limits are based on the sampling distribution.

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 Type one and Type two Errors 1 LO 10.4

Type I error.
Concluding a process is not in control when it actually is.
The probability of rejecting the null hypothesis when
the null hypothesis is true.
Manufacturer’s risk.
Type II error.
Concluding a process is in control when it is not.
The probability of failing to reject the null hypothesis
when the null hypothesis is false.
Consumer’s risk.

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 Type one and Type two Errors 2 LO 10.4

And the conclusion is that it is:

In Control Out of Control

If a process is actually: In Control No error Type I error (producer's risk )

Out of Control Type II error (consumer's risk ) No error

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 Type one Error LO 10.4

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 Observations from Sample
LO 10.4
Distribution

Each observation is compared to the selected limits of the
sampling distribution.

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 Control Charts for Variables LO 10.5

Variables generate data that are measured.
Mean control charts.
Used to monitor the central tendency of a process.

x " x­bar" charts.
Range control charts.
Used to monitor the process dispersion.
R-charts.

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 Establishing Control Limits LO 10.5

k k

x i R i
x  i 1 R  i 1
k k

where where
x Average of sample means R Average of sample ranges
xi Mean of sample i Ri Range of sample i
k Number of samples

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 x-Bar Charts: Control Limits LO 10.5

Used to monitor the central tendency of a process.

Upper control limit UCLx  x  z x
Lower control limit LCLx  x  z x
where
 x  n
 x = Standard deviation of distribution of sample means
 = Estimate of the process standard deviation
n = Sample size
z = The number of standard deviation that control limits are based
x = Average of sample means
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 Sample Range: Control Limits LO 10.5

If the standard deviation of the process is unknown
use sample range as a measure of process variability.

UCLx  x  A2 R
LCLx x  A2 R
where
A2 = A factor from Table 10.3

R = Average of sample ranges

x = Average of sample means

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 Range Charts: Control Limits LO 10.5

Used to monitor process dispersion.

UCLR D4 R

LCLR D3 R

where
D3 = a control chart factor based on sample size, n
D4 = a control chart factor based on sample size, n

D3 and D4 are obtained from Table 10.3

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 Factors for Three Sigma Control
LO 10.5
Charts 1

Table 10.3: Factors for three-sigma control limits for x and
R charts.
Number of Factor Factors For R Charts Factors For R Charts
observations for Chart , Lower Control Limit , Upper Control Limit ,
inSample, A2 D3 D4
n

2 1.88 0 3.27
3 1.02 0 2.57
4 0.73 0
2.28
5 0.58 0 2.11
6 0.48 0 2.00
7 0.42 0.08 1.92

8 0.37 0.14 1.86

9 0.34 0.18 1.82

10 0.31 0.22 1.78
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 Factors for Three Sigma Control
LO 10.5
Charts 2

Number of
Factor Factors For R Charts Factors For R Charts
observations
for Chart , Lower Control Limit , Upper Control Limit ,
inSample ,
A2 D3 D4
n

11 0.29 0.26 1.74

12 0.27 0.28 1.72

13 0.25 0.31 1.69

14 0.24 0.33 1.67

15 0.22 0.35 1.65
16 0.21 0.36 1.64
17 0.20 0.38 1.62

18 0.19 0.39 1.61

19 0.19 0.40 1.60
20 0.18 0.41 1.59

Source: Adapted from Eugene Grant and Richard Leavenworth, Statistical Quality Control, 5th ed. 19 80. McGraw-Hill
Education.

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 Using Mean and Range Charts LO 10.5

To determine initial control limits:
1. Obtain 20 to 25 samples. Compute appropriate sample
statistic(s) for each sample.
2. Establish preliminary control limits.
3. Determine if any points fall outside of the control limits.
4. Plot the data on the control chart and check for patterns.
5. If no out-of-control signs are found, assume that the
process is in control. If any out-of-control signals are
found, investigate and correct causes of variations.
Then resume the process.

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 Mean and Range Charts -
LO 10.5
Example

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 Control Charts for Attributes LO 10.5

Are used when the process characteristic is counted
rather than measured.
p-chart:
Used to monitor the proportion of defective items
generated by a process.
c-chart:
Used to monitor the number of defects per unit.

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 Use of a p-Chart LO 10.5

When observations can be placed into one of two
categories.
a. Good or bad.
b. Pass or fail.
c. Operate or don’t operate.

When the data consist of multiple samples of n
observations each.

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 Managerial Considerations LO 10.5

Managers must make a number of important decisions:
At what points in the process to use control charts.
What size samples to take.
What type of control chart to use.
Variables.
Attributes.
How often samples should be taken.

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 Run Tests LO 10.6

Even if all points are within the control limits, the data
may still not reflect a random process.
Analysts often supplement control charts with a run test.
Run test:
Checks for patterns in a sequence of observations.
Run is defined as:
Sequence of observations with a certain characteristic,
followed by one or more observations with a different
characteristic.

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 Nonrandom Patterns LO 10.6

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 Process Capability 1 LO 10.7

Once the stability of a process has been established, it is
necessary to determine if the process is capable of producing
output that is within an acceptable range:
Specifications or tolerances.
Range of acceptable values established by engineering design or
customer requirements.
Control limits.
Process variability.
Natural or inherent variability in a process.

Process capability:
The inherent variability of process output (process width) relative to the
variation allowed by the design specification (specification width).

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 Process Capability 2 LO 10.7

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 Process Capability Improvement LO 10.7

Requires reducing the process variability that is
inherent in a process.
Method Examples
Simplify Eliminate steps, reduce the number of parts, use
modular design.
Standardize Use standard parts, standard procedures.
Make mistake- Design parts that can only be assembled the correct
proof way; have simple checks to verify a procedure has
been performed correctly.
Upgrade Replace worn-out equipment; take advantage of
equipment technological improvements.
Automate Substitute automated processing for manual
processing.

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 Limitations of Capability Indexes LO 10.7

There are several risks of using capability index:
The process may not be stable, capability index is
meaningless.
The process output may not be normally distributed,
inferences about the fraction of output that isn’t
acceptable will be incorrect.
The process is not centered but C p is used, result is
misleading.

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 Operations Strategy LO 10.7

Quality is a major consideration for virtually all
customers:
Achieving and maintaining quality standards is of strategic
importance to all business organizations.
Product and service design.
Increase capability in order to move from extensive use
of control charts and inspection to achieve desired
quality outcomes.

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 End of Main Content

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