| HND - Manufacturing |
|Quality & Business improvement |
|Ass 3- FMEA |
| |
|Jacob Helliwell |
|30/06/15 |

| |

Contents
Contents 2
Introduction 3
Task 1 3
Task 2 5
Task 3 7
Task 4 8
Conclusion 8
References 8
Appendices 9

Introduction

In this assignment I have taken on the role of a business improvement engineer who is responsible for leading a team to develop continuous improvement principles and techniques within the workplace. This will be done through the use of FMEA which will show my understanding of the crucial steps needed in the FMEA process; to improve quality, reduce cost, improved productivity of employees and increased customer satisfaction.

Task 1

Failure Mode and Effects Analysis (FMEA) is a method designed to identify potential failure modes for a product or process, to assess the risk associated with those failure modes, to rank the issues in terms of importance and to identify and carry out corrective actions to address the most serious concerns.

Although the purpose, terminology and other details can vary according to type (e.g. Process FMEA, Design FMEA, etc.), the basic methodology is similar for all.

In general, FMEA / FMECA requires the identification of the following basic information:

•Item

•Function

•Failure

•Effects of Failure

•Causes of Failure

•Current Controls

•Recommended Actions

•Plus other relevant details

The FMEA procedure is a tool that has been adapted in many different ways for many different purposes. It can contribute to improved designs for products and processes, resulting in higher reliability, better quality, increased safety, enhanced customer satisfaction and reduced costs. The tool can also be used to establish and optimize maintenance plans for repairable systems and/or contribute to control plans and other quality assurance procedures. It provides a knowledge base of failure mode and corrective action information that can be used as a resource in future troubleshooting efforts and as a training tool for new engineers.

WHRU T-Duct Damper FMEA

Scope

A multi louvre damper & its control panel is part of the final elements on a waste heat recovery unit. In general the multi louvre damper set comprise of a sensor, logic solver, components to trip the gas turbines on an offshore oil rig and limit switches. This report will focus on the safety of the multi louvre damper and the main parts of multi louvre damper control panel which consists of:

- Pressure sensing valve

- Solenoid Valve

- Pilot Valves

- Double acting pneumatic cylinder

- Failsafe air receiver

- Limit Switches

[pic]

Above is a block diagram for the components supplied; for a complete shutdown of the gas turbines only the limit switches will be required .

On the right is an example Multi Louvre Damper set which the FMEA is based on.

. See Appendix 1 for FMEA sheet.

Task 2

The Multi Louvre Dampers are independently operated pieces of equipment. Installation and connection to the site control system should be made according to site requirements. Refer to GA drawings, P&ID drawings, wiring diagrams and instrument drawings for details and connection information

Damper operation during a timed event

Operation of the Damper pair is by a single linear double acting pneumatic actuator.

The Inlet damper & Bypass damper are mechanically linked to operate together so as one opens the other will close.

With the air connected to the control panel and the solenoid energised the damper can be operated with an appropriate 4-20mA control signal to operate the positioner.

An appropriate level of signal will provide a proportional movement and position of the damper blades.

The T-Duct Damper set consists of two independent dampers. The control signal requirement is 4-20 mA signal. The default (failsafe) position for the Inlet damper is closed and the default position for the Bypass damper is open. Application of the control signal to the PMV inputs via the junction boxes will cause the damper blades to move to a proportional position accordingly.

By virtue of the fact the bypass damper is linked to the inlet the position the following are indicative relative positions for the blades:-

• Bypass damper to its fully open position = Inlet damper fully closed • Bypass damper to its 75% open position = Inlet damper 25% open • Bypass damper to its 50% open position = Inlet damper 50% open • Bypass damper to its 25% open position = Inlet damper 75% open • Bypass damper to its fully closed position = Inlet damper fully open

The control panel is fitted with a solenoid valve and a pressure sensing valve. The solenoid must be supplied with 24V for operation and the air supply pressure must exceed 4.5 Barg for pneumatic operation to occur. Failure of either of these criteria will prevent the damper set from operating and keep them in their respective failsafe’s.

The damper set is provided with an Air Receiver reservoir to provide pressure for failsafe operations if the main air supply fails. If the air receiver over pressurises the safety relief valve will vent the tank.

The damper set position signal is reported via a feedback potentiometer on shaft of the bypass damper. Both damper sets in the T-Duct are fitted with limit switch boxes for the open and closed positions. The limit switches, as for all other electrical termination requirements, can be accessed via the appropriate junction box fitted to the side of the equipment.

In the event of loss of air, power or pressure the damper will failsafe using the reserve air provided from the air receiver.

With a 100% open signal to the actuator, the Inlet damper will open fully & the Bypass damper will therefore fully closed.

If the air supply, solenoid voltage or the control signal is lost, or the supply air pressure is low the damper will return to the designated failsafe position, this being:- Inlet failsafe closed & Bypass failsafe open.

Notes:

The multi louvre damper set is designed to ensure that both the Inlet & Bypass sides of the damper cannot be both closed at the same time; the linkage mechanism between the two units prevents this.

Task 3

See appendix 2 for fishbone diagram.

One main cause for faulty dampers is instrument problems; the cause for this are various such as incorrect setup of instruments, poor maintenance and incorrectly spec’d items which are not suitable for the job. The effects of instrument problems can cause the damper assembly to failsafe at random times which can cause major problems on site as the damper is directly linked to turbines therefore meaning if the damper fail safes the turbines will also fail safe (shut down). Turbines shutting down on site can mean massive loss of money for end users.

Another major cause is poor design engineering; the cause for this is usually down to lack of experience/ training, drawings not being checked and incorrect/ out of date 3rd party models being used. The effects of poor design can be numerous such as binding shafts which causes the damper blades to stick during operation therefore causing the damper to struggle to operate normally, other effects of bad design which can’t be easily amended is the damper clashing with structural steel on site; this error is generally down to client giving the design engineers outdated models and can cause major problems when the damper is about to be installed on site and they have a planned date for turning on turbines.

Poor manufacturing can also be a cause for dampers not working properly on site, this again is usually down to a lack of training and experience but it can also be down to poor working conditions and poor quality control. Effects of poor manufacturing can range from poor operation in service (dampers not sealing properly, shaft binding, lose keyways on levers) to massive warranty claims as service engineers are called to site to try and amend the mistakes made in manufacturing.

Incorrect commissioning can also be a major cause for damper troubles, this is usually down to lack of information on the operation and maintenance manual, installing the damper without the operation and maintenance manual and improper handling of dampers and control. Effects of poor installation can range from poor operation in service (dampers not sealing properly, shaft binding, lose keyways on levers) to massive warranty claims as service engineers are called to site to try and amend the mistakes made.

Task 4

In industry there are plenty of methods used to prevent mistakes; these are usually in the form of \n error proofing activity which identifies suitable solutions. One commonly used method is poka-yoke which prevents an error from occurring; it is the first step in truly error-proofing a system. Error-proofing is a manufacturing technique of preventing errors by designing the manufacturing process, equipment, and tools so that an operation literally cannot be performed incorrectly.

The goal of mistake-proofing is to eliminate mistakes. In order to eliminate mistakes, we need to modify processes so that it is impossible to make them in the first place. With mistake-proofing solutions, many repetitive tasks that depend upon the memory of the worker are built into the process itself. Mistake-proofing frees the time and minds of the workforce to pursue more creative and value-adding activities. Mistake-proofing also involves a change in the mind-set of the organization. Organizations must establish a mistake-proofing mind-set that promotes the belief that it is unacceptable to allow for even a small number of product or service defects.

See appendix 3 for a Poka-Yoke for some assembly jobs found on a Damper.

Conclusion

In this assignment I have carried out an FMEA report. From this I have successfully identified what might fail on a product from work, what the result of this failure would be, how likely it is to occur, how severe it would be and the likelihood of this being spotted before it reaches the customer. This has also involved carrying out a root cause analysis as part of a mistake/ error proofing activity.

References

http://www.isixsigma.com/dictionary/poka-yoke/ http://www.thetoyotasystem.com/lean_inventions/poka_yoke-you-can%E2%80%99t-go-wrong.php Appendices

Appendix 1- FMEA Report

Appendix 2- Fish Bone Diagram

Appendix 3- Poka- Yoke