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System Suitability

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System Suitability Lecture: Reliability & FMECA Lecturer: Dr. Dave Olwell Dr. Cliff Whitcomb, CSEP cawhitco_at_nps.edu About the Lecturer Dr. David Olwell Chair ... – PowerPoint PPT presentation

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Title: System Suitability


1
System Suitability
Lecture Reliability FMECA Lecturer Dr. Dave
Olwell Dr. Cliff Whitcomb, CSEP cawhitco_at_nps.edu
2
About the Lecturer
  • Dr. David Olwell
  • Chair, Department of Systems Engineering, NPS
  • Research interests are primarily reliability
    engineering and analysis
  • Phone (831) 656 3583 (W)
  • Email dholwell_at_nps.edu

3
Objectives
  • Be able to construct a FMECA using Risk Priority
    Numbers
  • Interpret a Fault Tree
  • Be able to perform a simple reliability
    prediction for a series system with independent
    exponential failure times
  • Understand the principles of sequential testing

4
Reading
  • BF (4ed) 12.4-12.6

5
FMECA
  • Discussion in text (section 12.4.1) is good
  • Figure 12.21 can easily be implemented in
    spreadsheet, although for large systems
    commercial software is useful
  • Bottom line RPN is used to score failure modes
    on a set of subjective scales, and the score
    orders them. We start by mitigating the ones
    with the highest number, and work down to some
    stopping point.

6
FMECA/FMEA
  • Failure Modes and Effects Analysis (FMEA) and
    Failure Modes, Effects and Criticality Analysis
    (FMECA) are methodologies designed to identify
    potential failure modes for a product or process
    before the problems occur, to assess the risk
    associated with those failure modes and to
    identify and carry out measures to address the
    most serious concerns.

7
Standards
  • MIL-STD-1629A
  • SAE Internationals J1739 and ARP5580 documents
    (for automotive and non-automotive applications,
    respectively)
  • Automotive Industry Action Groups (AIAG) FMEA-3

8
Figure
9
Common Themes
  • Item/Process Identify the item or process that
    will be the subject of the analysis, including
    some investigation into the design and
    reliability characteristics. For FMEA analysis of
    a product or system, the analysis could be
    performed at the system, subsystem, component or
    other level of the system configuration.
  • Functions Identify the functions that the item
    or process is expected to perform.
  • Failures Identify the known and potential
    failures that could prevent or degrade the
    ability of the item/process to perform its
    designated functions.
  • Failure Effects Identify the known and potential
    effects that would result from the occurrence of
    each failure. It may be desirable to consider the
    effects at the item level (Local Effects), at the
    next higher level assembly (Next Higher Level
    Effects) and/or at the system level (End
    Effects).
  • Failure Causes Identify the known and potential
    causes for each failure.

10
Common Themes
  • Current Controls Examine the control mechanisms
    that will be in place to eliminate or mitigate
    the likelihood that the potential failures will
    occur (e.g. end of line inspections, design
    reviews, etc.).
  • Recommended Actions Identify the corrective
    actions that need to be taken in order to
    eliminate or mitigate the risk and then follow up
    on the completion of those recommended actions.
  • Prioritize Issues Prioritize issues for
    corrective action according to a consistent
    standard that has been established by the
    organization. Risk Priority Number (RPN) ratings
    and Criticality Analysis are common methods of
    prioritization and they are described later.
  • Other Details Depending on the particular
    situation and on the analysis guidelines adopted
    by the organization, other details may be
    considered during the analysis, such as the
    operational mode when the failure occurs or the
    systems intended mission.
  • Report Generate a report of the analysis in the
    standard format that has been established by the
    organization. This is generally a tabular format
    similar to the one shown in Figure 1. In
    addition, the report may include block diagrams
    and/or process flow diagrams to illustrate the
    item or process that is the subject of the
    analysis. If applicable, the criticality analysis
    may be included in a separate table and various
    plots/graphs can be included to display
    statistics on the modes and rankings.

11
Figure
12
RPN (Risk Priority Number)
  • Severity (S)
  • 1-10 scale
  • A rating of the severity or seriousness of each
    potential failure effect.
  • Occurrence/frequency (O)
  • 1-10 scale
  • A rating of the likelihood of occurrence for each
    potential failure cause.
  • Detection (D)
  • A rating of the likelihood of detecting the
    failure cause.
  • 1-10 scale, hard to detect being higher
  • RPN SOD

13
Comment
  • Scales are arbitrary
  • Implies they can only be used for ranking failure
    modes internal to the system, and may not be not
    useful for comparing across systems
  • Must be well defined enough so that different
    people assign the same number

14
Example Battery
  • Severity 8 - Extreme Effect. Product inoperable
    but safe. Customer very dissatisfied.
  • Occurrence 5 - Low. Occasional number of
    failures likely expect about 2.7 failures per
    1000 due to this cause.
  • Detection 1 - Almost Certain. The operator will
    almost certainly be able to detect the failure

15
Criticality Analysis A different approach
  • Criticality (Q)(FMFR)(PL)
  • Item Unreliability (Q) The probability of
    failure for the item at the time of interest for
    the analysis.
  • Failure Mode Ratio of Unreliability (FMFR) The
    ratio of the item unreliability that can be
    attributed to the particular failure mode. For
    example, if an item has four failure modes, then
    one mode may account for 40 of the failures, a
    second mode may account for 30 and the two
    remaining modes may account for 15 each.
  • Probability of Loss (PL) The probability that
    the failure mode will cause a system failure (or
    will cause a significant loss). This is an
    indication of the severity of the failure effect
    and may be set according to the following scale
  • Actual Loss 100
  • Probable Loss 50
  • Possible Loss 10
  • No Loss 10

16
Battery
  • Criticality is (0.08)(0.25)(1.0) (.02)
  • Use for relative rankings, not necessarily an
    absolute scale

17
Recommendations
  • An important use of the FMECA is to document
    mitigation strategies
  • The estimated reduction in the RPN is shown if
    the suggested mitigation is adopted
  • Useful to compare before and after risk
  • In the early FMECA, recommendations suggested
    reduced risk for the first failure mode from 294
    to 28

18
Comment
  • This FMECA approach is commonly used for
    reliability, but can be applied to other domains
    where risk identification and mitigation are of
    interest

19
Fault Trees
  • Fault trees emphasize what must occur for system
    failures while reliability block diagrams
    emphasize what must occur for a systems to work
  • They are logically equivalent
  • Partial FTs can be useful when trying to isolate
    fault structure
  • Discussion in book is pretty good, if short

20
BF Textbook Example
  • Here is an example of the RBDs from Figure 12.10
    reworked as fault trees

21
Simple reliability prediction
  • Requires either data or assumptions
  • If reliability of components is known, use their
    data
  • Be careful to verify that the conditions of use
    are the same as those that generated the
    historical data
  • If making assumptions, be realistic and
    conservative

22
Example
  • Here is an example of reliability prediction for
    Figure 12.10(a) using the data from Table 12.2
    and a mission time of 100 hours

23
Sequential testing
  • Sequential testing allows early termination of a
    reliability test
  • If the system exceeds requirements or fails
    requirements by a large margin, the test
    terminates early
  • For close calls, it takes more testing to
    accumulate enough data to decide
  • Idea covered again in system assessment course

24
Example
  • The example in the text (Section 12.5.1 and
    Figure 12.26) is good
  • Focus on understanding the interpretation of Fig
    12.26
  • That example assumes exponential failure times.
  • Know the four key elements for constructing the
    figure producer risk, consumer risk, threshold
    MTBF, objective MTBF
  • The horizontal axis is total time on test, or
    TTT, and is the sum of all the running time of
    the units that have failed or are still being
    tested

25
Operational Testing
  • Study section 12.5.4

26
Conclusion
  • Reliability is a very important element of
    suitability
  • Several NPS courses are available for further
    study
  • OA4302 Reliability and Weapon System
    Effectiveness Measurement
  • SE3321 Reliability Management and Data Systems
  • SE3322 Reliability Centered Maintenance
  • SE4321 Reliability Growth and Accelerated Testing
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