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5. |
Statistical Process Control Statistical Process Control (SPC) is a widely
used sampling technique which checks the quality of an item which is engaged
in a process. SPC can also be used to inform management of improved process
changes (Krajewski et al., 2010). SPC identifies the nature of variations in
a process, which are classified as being caused by ‘chance’ causes or
‘assignable’ causes. |
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5.1. |
Chance Causes of Variation Processes will have some inherent variability due to factors such as ambient temperature, wear of moving parts or slight variations in the composition of the material that is being processed. The technique of SPC involves calculating the limits of these chance-cause variations for a stable system, so any problems with the process can be identified quickly. The limits of the chance-cause variations are called control limits and are shown on a control chart, which also shows sample data of the measured characteristic over time. There are control limits above and below the target value for the measurement, termed the upper control limit (UCL) and lower control limit (LCL) respectively. The behaviour of the process is observed by studying the control chart and if the sample data plotted on the chart shows a random pattern within the upper and lower control limits then the process is ‘in-control’. However if a sample falls outside the control limits or the plot shows a non-random pattern then the process is ‘out-of-control’. |
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5.2. |
Assignable Causes of Variation An assignable cause of variation is a variation
in the process which is not due to random variation but can be attributed to
some change in the process, which needs to be investigated and rectified.
However in some instances the process could actually be working properly and
the results could have been caused by sampling error. There are two types of
error which can occur when sampling from a population. A type I error is
indicated from the sample output when none . A type II error is when an error
is occurring but has not beenaactually
occurs. The probability of a type I error is termed. Type I errors may lead
to rectification workbindicated
by the sample output. The probability of a type II error is termed which is unnecessary and even the
unnecessary recall of ‘faulty’ products. Type II errors will lead to
defective products as an out-of-control process goes unnoticed. Customer
compensation and loss of sales may result if defective products reach the
marketplace. The sampling methodology should ensure that the probability of
type I and type II errors should be kept as low as reasonably possible |
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5.3. |
Types of Control Charts Two types of control charts are for variable data
and for discrete data.. Control charts for variable data display samples of a
measurement that will fall in or out of a range around a specified target
value. Examples of variable data could be a customer transaction time in a
bank or the width of an assembly component. Two control charts are used in
measuring variable data. An X,–– chart shows the distance of sample values
from the target value (central tendency). An R chart shows the variability of
sample values (dispersion). Attribute control charts measure discrete values
such as if a component is defective or not. Thus there are no values, as in a
variable control chart, from which a mean and range can be calculated. The
data will simply provide a count of how many items conform to a specification
and how many do not. Two control charts will be described for attribute data.
The p-chart which shows the proportion of defectives in a sample and the
c-chart which shows the number of defectives in a sample |
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ISO
9001 |
applies
when the supplier is responsible for the development, design, production,
installation, and servicing of the product. |
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ISO
9002 |
applies
when the supplier is responsible for production and installation |
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ISO
9003 |
applies
to final inspection and testing of products. |
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ISO
9004 |
provides
guidelines for managers of organisations to help them to develop their
quality systems. It gives suggestions to help organisations meet the
requirements of the previous four standards. |
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The
standard is general enough to apply to almost any good or service, but it is
the specific organisation or facility that is registered or certified to the
standard. To achieve certification a facility must document its procedures
for every element in the standard. These procedures are then audited by a
third party periodically. The system thus ensures that the organisation is
following a documented, and thus consistent, procedure which makes errors
easier to find and correct. However the system does not improve quality in
itself and has been criticised for incurring cost in maintaining
documentation while not providing guidance in quality improvement techniques
such as statistical process control. |
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