Failure Mode and Effects Analysis

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Failure mode and effects (critical) analysis (FMEA, FMECA) method was developed in USA in late 50s. It's aim was to prevent product failures already at the stage of product design. Early prevention of failures was especially important in space, aviation and military industries. As analyses have shown, over 3/4 of all failures during production and using of product can be prevented during product design process.

The method was popularized in USA and later in Europe and other countries. It was used first in high technology industries, but it appeared to be successful also in other industries and even in services. However, for services SERVQUAL may give better results. Since 90s it is used also in process improvement and as a simple tool of risk management. Despite over half of century since development of the method, it still finds new applications. The method can be easily digitalized and used in semiautomatic mode in MRP/ERP systems.

Range of FMEA applications

  1. Product optimization
    • at the design stage - best moment for analysis, best effects achieved due to easiness of implementing changes into the product,
    • before implementation into production - limited effects due to limited possibility of changes in product design, but still better to use it than not,
    • later stage - very limited effects, because almost all parameters are fixed. Use it before upgrading your product.
  2. Process optimization
    • implementation of new process - very good moment, however it happens very rarely in enterprise,
    • improvement of existing process - very good moment, process improvement is not as limited as product improvement. Moreover, employees know the process and its limits, which can lead to very good effects.
  3. Risk management
    • as simple method of risk identification and dealing with risk. It can be enough for most small and medium enterprises.

Process optimization can be achieved also using modified FMEA: PFMEA.

Steps of using FMEA

  1. Stage 1. Preparation
    • Definition of objectives
    • Setting a team
    • Setting scope of analysis
    • Functional decomposition
    • Data collection
  2. Stage 2. Analysis

The most important steps will be described below:

Setting scope of analysis

The scope of analysis is essential for the results. If the analysis will be limited to only several elements, it can add no value. But if the scope is too wide, the time of analysis and cost of it will be very high. Probably there is no need to analyse parts that are well known from earlier products, unless they can be incompatible with new solutions. Also level of decomposition should be considered. Very deep decomposition not always is proper perspective, as it hides problems coming from relations between elements.

Each analysis is performed in defined environment. The team should decide what are the environment variables, e.g. availability of nominal power, number of failures at a time (usually only 1 allowed), availability of necessary inputs, possibility to utilise outputs.

Functional decomposition

The object under investigation should be decomposed into elements. If it is a product, it should be decomposed into parts or even raw materials. In case of process, it should be decomposed into tasks. FMEA is very low level analysis. For each element data should be collected, including:

  • number of failures,
  • types of failures,
  • known problems (e.g. analysis of literature),
  • limits of use (e.g. temperature, humidity).

Qualitative analysis

Qualitative analysis concerns possible failures, their causes and effects:

  • failure - what wrong can happen to the element under investigation,
  • cause - what has to happen to make the failure occur; there can be several causes and each should be analysed separately,
  • effect - what will happen if failure occur (not cause! - common mistake); there may be several short-term as well as long-term effects. Each should be analysed separately.

Set of failure + cause + effect is a failure mode. All data should be entered into table (see examples below).

Quantitative analysis

Quantitative analysis refers to three variables:

  • (P) Probability of occurrence (related to cause of failure),
  • (D) Detection difficulty (related to the failure itself),
  • (S) Severity (related to effect).

Product of those three variables gives overall rating of the analysed failure mode.

Each variable is rated in scale from 1 to 10, where 10 is maximum. The enterprise using FMEA should define own evaluation tables that help in assigning ranks. Example table of probability is shown below:

Table 1. Example of probability table for mass production

Description P value Frequency
Almost impossible 1 less than 1 per million
Very rare 2 less than 1 per 20 000
Rare 3 less than 1 per 4 000
Average 4

5

6

less than 1 per 1 000

less than 1 per 400

less than 1 per 80

Often 7-8 less than 1 per 40

less than 1 per 20

Very often 9

10

less than 1 per 8

less than 1 per 2

Source: [1]

Corrective and preventive actions in FMEA

Since the R combines three areas in corrective action there are three different ways of repair:

  • Reducing the probability,
  • Improve detection,
  • Reduce nuisance of failures.

The choice depends on the type and complexity of the failure and the product. Success relies in this case only on the experience and knowledge of the team members using this method. For ease of analysis.

Examples

FMEA for a PC

Element Defect Effect Cause P S D R Corrective action
system unit the system will not load computer does not work improper system program 3 10 9 270 exchange program
monitor Wrong colors green and red unavailable inadequate graphics card 2 3 2 12 check cards and exchange
hard drive disc unreadable data loss bad hard drive 4 8 10 320 installation of the drive
keyboard locks possible transmission of data improper connection 4 2 5 40 Test the keyboard, check. Connection
printer Errors Print printing can not be read damage to the controller 6 3 3 54 exchange control
Disk Drive read errors you can not store data dirty disc or drive mechanism 3 5 2 30 cleaning or replacement of the drive mechanism
expansion card expansion card operation error missed opportunities Cards card not connected 7 1 8 56 Testing connections, the right mix after the test

Source: A.P. Mühlemann, J. S. Oakland, K.G. Lockyer, 1995, p. 138

The example given is very simplified and in practice would have to be greatly expanded. With several dozens or even hundreds of potential defects is useful to apply Pareto chart to carve out those that should be addressed at the earliest.

FMEA for the bathtub faucet with spray

Element Defect Effect Cause P S D R Corrective action
body leak leakage bad casting, micropores 5 10 4 200 battery change
bad threads assembly difficulties wrong setting machine 3 1 1 3 exchange of body
head spiking flooding the bathroom a little thread 2 10 8 160 head replacement
leak leakage bad seal 3 8 6 144 replacement of seals
spout mounted askew unsightly appearance incorrect assembly 7 3 1 21 reassembly
spray switch difficult switching overexertion too hard seal 8 5 3 120 change seals
incomplete switching Water poured from the spout and shower at the same time incorrect assembly 6 4 4 96 reassembly
snake interleaving unsightly appearance ?break? hose 3 6 3 54 Hose replacement
leak leakage trimming curves hose 3 7 8 168 Hose replacement

Source: own study

The analysis found that the most serious of these flaws are micropores in the bodies battery leakage hoses, knocking heads and their leaks and difficult to turn on the shower. In further work should focus on minimizing the likelihood of these problems.

Advantages of Failure Mode and Effects Analysis

Failure Mode and Effects Analysis (FMEA) is an important tool for product design and development, which can help to identify and prevent potential product failures. It has the following advantages:

  • FMEA allows to identify the most important failure modes and their effects early in the design process. This helps to prevent catastrophic product failures, reduce development costs and accelerate design process.
  • FMEA provides comprehensive information about product reliability and safety. It also helps to identify the root causes of failure and develop appropriate corrective actions.
  • FMEA is an effective tool for risk management. It helps to identify potential failure modes, assess their severity and develop preventative measures.
  • FMEA is also useful for quality assurance. It helps to identify and eliminate potential quality issues and ensures that the product meets high quality standards.
  • FMEA can be used to create and maintain effective product documentation, which can be used for troubleshooting and maintenance.
  • Finally, FMEA is a relatively simple and cost-effective analysis technique, which does not require any specialized knowledge or equipment.

Limitations of Failure Mode and Effects Analysis

The limitations of Failure Mode and Effects Analysis (FMEA) include:

  • It is time consuming, as it requires an in-depth analysis of a product’s design and the potential failure modes associated with it.
  • It does not account for external factors such as the environment in which the product will be used or the customer’s expectations for the product.
  • It is not always up-to-date with current technology and materials, as it relies on existing data.
  • It does not provide a comprehensive plan for how to address potential failures and how to mitigate the risk of them occurring.
  • It may not be accurate, as it relies on the expertise of the people involved in the FMEA process.
  • It can be difficult to determine the severity and likelihood of failure.

Other approaches related to Failure Mode and Effects Analysis

In addition to FMEA, there are several other approaches related to Failure Mode and Effects Analysis. These include:

  • Fault Tree Analysis (FTA) - This is a logical diagram that is used to identify the relationships between component failures and the overall system failure. It helps to identify the root cause of a system failure and thus identify areas of improvement.
  • Event Tree Analysis (ETA) - This is a graphical tool used to analyze the consequences of an event. It is used to identify potential risks and their associated probabilities.
  • Reliability Block Diagram (RBD) - This is a graphical tool used to analyze the reliability of a system. It is used to identify the failure points in a system and the associated probabilities of failure.
  • Failure Modes, Effects and Criticality Analysis (FMECA) - This is an extension of FMEA which takes into account both the severity of a failure and its probability of occurrence.

In summary, FMEA is just one of the approaches used in Failure Mode and Effects Analysis. Other approaches include Fault Tree Analysis, Event Tree Analysis, Reliability Block Diagram and FMECA. These methods help to identify potential risks and their associated probabilities, enabling more effective product design and production.


Failure Mode and Effects Analysisrecommended articles
FMEA analysisMaintenance strategyPFMEAQuality loss functionVisual inspectionSystem safetyQuality controlQuality Function DeploymentFault tree

References

Author: Slawomir Wawak