5S Process in Reliability Improvement

The 5-S process is a method for ensuring workplace cleanliness, order and organization and should be at the heart of any reliability improvement initiative. It consists of five fundamental steps:

1. Sort— Get rid of accumulated junk that has no value to the job at hand. In Maintenance, this includes removing everything that does not add value to the work being done — components from broken machinery, unrepaired spare assemblies and tools, obsolete charts and graphs and "abandoned-in-place" equipment and piping systems. If it is not needed for the job at hand, it needs to be eliminated.
2. Straighten— Organize what remains after the first step. Consider the flow of work through the area and position equipment and storage facilities to eliminate lost motion and wasted travel. A craftsperson should not have to search for a tool or move something out of the way to begin work.
3. Scrub/Shine— Workplace cleanliness is the next step. Precision work requires a clean work environment. Shop spaces used to rebuild equipment should approach "clean room" standards. Remove all dust, dirt and contamination. Seal concrete floors so that spills are easily cleaned. Repair lighting fixtures and paint the work area with light colors — a brightly lit work environment is much more likely to remain clean. Deteriorating equipment conditions are more easily spotted when not covered by contamination.
4. Standardize— When the workplace is clean and organized, it must be kept that way. A system should be put into place that ensures the condition of the work area does not degrade. Visual controls can be used at the equipment level — registration marks on fasteners, color coding correct operating ranges on gauges and matched marking assemblies are examples.
5. Sustain— A process for conducting audits on a regular basis should be considered. When management shows a concern for workplace condition, it is much more likely to remain in good shape. Every employee must understand the need for safety, order and cleanliness. The facility should be kept in "tour condition" at all times.

The cleanliness must be performed so you won’t have to work in an unsafe, disorganized area which puts you at risk or even in danger. Since 5-S is for you, you also have an obligation and the responsibility to help prepare the tools and make sure they are in the proper place so that you can begin your job on time and efficient. Clean-up and organize your work area every day so that each new day is easier and safer than the day before. Share your input with your leaders so that the tools you need will be available to you, increasing your efficiency. Volunteer to help with the 5-S tours and resolve issues that are noted.

Reliability Centered Maintenance Advantage and Disadvantages

Reliability centered maintenance (RCM) is the maintenance approach used when following a process that assesses equipment condition and determines the maintenance requirements of any physical asset in its operating context.

Basically, the RCM methodology addresses key issues not dealt with by other maintenance programs. This approach recognizes that all equipment in a facility is not of equal importance—to either the process or to facility needs and safety. Focusing on reliability of equipment means recognizing that equipment design and operations differ, and that each piece of equipment will have a different probability of undergoing failure from degradation than will another. A reliability-focused approach will mean structuring a maintenance program based upon the understanding of equipment needs and priorities, as well as limited financial and personnel resources, to plan activities such that equipment maintenance is prioritized while operations are optimized.

Simply put, RCM is a systematic approach of evaluating a facility's equipment and resources to best match the two needs. This results in a high degree of facility reliability and cost-effectiveness, and is highly reliant on predictive maintenance. However, it also recognizes that maintenance activities on equipment that is inexpensive and less important to overall facility reliability may be best left to a reactive maintenance approach, focusing both labor and financial resources on higher priority and more costly equipment. The following maintenance program breakdowns of continually top-performing facilities echo the RCM approach, which utilizes all available maintenance tactics. As is shown, all maintenance approaches are used, but the predominant strategy used is predictive.

• <10%>
• 25% to 35% Preventive
• 45% to 55% Predictive

Because RCM is so heavily weighted on utilization of predictive maintenance strategies, its program advantages and disadvantages mirror those of predictive maintenance. In addition to these advantages, RCM will allow a facility to more closely match its resources to operational needs and at the same time improve both reliability and also reduce associated maintenance costs.

Advantages

• Can be the most efficient maintenance program
• Lowers costs by eliminating unnecessary equipment maintenance or system overhauls
• Minimizes the frequency of overhauls
• Reduces probability of sudden equipment failures
• Focuses maintenance activities on critical system components
• Increases component reliability
• Incorporates root cause analysis

Disadvantages

• Can have significant startup costs associated with staff training and equipment needs
• Savings potential is not readily seen by management

Is Preventive Maintenance Necessary?

Written by William C. Worsham (Senior Consultant and Trainer, Reliability Center, Inc.) Feature article for "Focus on Reliability" Column at MaintenanceResources.com

Reliability Centered Maintenance has changed the way we think about Preventive Maintenance (PM). It has caused some to question whether it is even necessary to do preventive maintenance. The truth is most manufacturing facilities would benefit from a good preventive maintenance program. It would be especially beneficial for those plants that rely on breakdown or run-to-failure maintenance. But, a preventive maintenance program is potentially risky, so it must be administered and performed properly to be successful. This paper will examine both the benefits and risks of preventive maintenance and offer some ideas on how to make it successful. We will start with a definition of preventive maintenance.

What is Preventive Maintenance?

Preventive maintenance is planned maintenance of plant and equipment that is designed to improve equipment life and avoid any unplanned maintenance activity. PM includes painting, lubrication, cleaning, adjusting, and minor component replacement to extend the life of equipment and facilities. Its purpose is to minimize breakdowns and excessive depreciation. Neither equipment nor facilities should be allowed to go to the breaking point. In its simplest form, preventive maintenance can be compared to the service schedule for an automobile.

A bona fide preventive maintenance program should include:

• Non-destructive testing
• Periodic inspection
• Preplanned maintenance activities
• Maintenance to correct deficiencies found through testing or inspections.

The amount of preventive maintenance needed at a facility varies greatly. It can range from a walk through inspection of facilities and equipment noting deficiencies for later correction up to computers that actually shut down equipment after a certain number of hours or a certain number of units produced, etc.

Many reasons exist for establishing a PM program. Listed below are a few of these. Whenever any of these reasons are present, a PM program is likely needed.

Reasons for Preventive Maintenance

• Increased Automation
• Business loss due to production delays
• Reduction of insurance inventories
• Production of a higher quality product
• Just-in-time manufacturing
• Reduction in equipment redundancies
• Cell dependencies
• Minimize energy consumption (5% less)
• Need for a more organized, planned environment

Why Have a PM Program

• The most important reason for a PM program is reduced costs as seen in these many ways:
• Reduced production downtime, resulting in fewer machine breakdowns.
• Better conservation of assets and increased life expectancy of assets, thereby eliminating premature replacement of machinery and equipment.
• Reduced overtime costs and more economical use of maintenance workers due to working on a scheduled basis instead of a crash basis to repair breakdowns.
• Timely, routine repairs circumvent fewer large-scale repairs.
• Reduced cost of repairs by reducing secondary failures. When parts fail in service, they usually damage other parts.
• Reduced product rejects, rework, and scrap due to better overall equipment condition.
• Identification of equipment with excessive maintenance costs, indicating the need for corrective maintenance, operator training, or replacement of obsolete equipment.
• Improved safety and quality conditions.

If it cannot be shown that a preventive maintenance program will reduce costs, there is probably no good reason other than safety to have a PM program.

The Law of PM Programs:
There are many advantages for having a good preventive maintenance program. The advantages apply to every kind and size of plant. The law of PM programs is that the higher the value of plant assets and equipment per square foot of plant, the greater will be the return on a PM program. For instance, downtime in an automobile plant assembly line at one time cost $10,000 per minute. Relating this to lost production time an automobile manufacturer reported that the establishment of a PM program in their 16 assembly plants reduced downtime from 300 hours per year to 25 hours per year. With results such as this no well-managed plant can afford not to develop a PM program.

Preventive Maintenance Program Risks
As mentioned in the beginning of this report, preventive maintenance does involve risk. The risk here refers to the potential for creating defects of various types while performing the PM task. In other words, human errors committed during the PM task and infant mortality of newly installed components eventually lead to additional failures of the equipment on which the PM was performed. Frequently, these failures occur very soon after the PM is performed. Typically, the following errors or damage occur during PM’s and other types of maintenance outages.

• Damage to an adjacent equipment during a PM task.
• Damage to the equipment receiving the PM task to include such things as:
• Damage during the performance of an inspection, repair, adjustment, or installation of a replacement part.
• Installing material that is defective, incorrectly installing a replacement part, or incorrectly reassembling material.
• Reintroducing infant mortality by installing new parts or materials.
• Damage due to an error in reinstalling equipment into its original location.

Especially disturbing about these types of errors is the fact that they go unnoticed – until they cause an unplanned shutdown. There is some published data that illustrates this point. It comes from the fossil-fuel power industry.

A review of the data from fossil-fueled power plants that examined the frequency and duration of forced outages after a planned or forced maintenance outage reinforces this concept. That data showed that of 3146 maintenance outages, 1772 of them occurred in less than one week after a maintenance outage. Clearly, this is pretty strong evidence that suggests that in 56% of the cases, unplanned maintenance outages were caused by errors committed during a recent maintenance outage.

Having performed and supervised many industrial PM’s, I also support this concept. I can remember many instances where it would take days after a PM was performed to get everything back to normal. This was particularly true when many components that came in contact with the product being produced were replaced. I remember working with the quality people on many occasions to insure that every position on a multiple position machine was once again producing first quality product. Many times it required adjusting and/or replacing components that were adjusted or replaced on the PM.

How to Have a Successful PM Program
The key to a successful Preventive Maintenance (PM) program is scheduling and execution. Scheduling should be automated to the maximum extent possible. Priority should be given to preventive maintenance and a very aggressive program to monitor the schedule and ensure that the work is completed according to schedule should be in place.

Preventive Maintenance Execution:
Traditional preventive maintenance was based on the concept of the bathtub curve. That is, new parts went through three stages, an infant mortality stage, a fairly long run stage, and a wear-out stage. The PM concept was to replace these parts before they entered the wear-out phase. Unfortunately, Reliability Centered Maintenance based on research done by United Airlines and the rest of the aircraft industry showed that very few non-structural components exhibit bathtub curve characteristics. Their research showed that only about 11% of all components exhibit wear-out characteristics, but 72% of components do exhibit infant mortality characteristics. These same characteristics have been shown to apply in Department of Defense systems as well as power plant systems. It is very likely that they apply universally as well. Therefore, they should be taken into account when configuring preventive maintenance on industrial equipment.

In order to have a successful PM program, the message is clear. The PM should focus on cleaning, lubrication, and correcting deficiencies found through testing and inspections. When there is a need to adjust or replace components, it should be done by highly trained and motivated professionals. Predetermined parts replacement should be minimal and done only where statistical evidence clearly indicates wear-out characteristics. In the absence of data to support component replacement, an age exploration program or the collection of data for statistical analysis to determine when to replace components should be initiated. Borrowing from the Japanese, lubrication points should be clearly marked with bright red circles to ensure that lubrication tasks are not missed. Cleaning should be carried our to remove dust, dirt, and grime because these things mask defects that can cause unplanned maintenance outages.

Motivating Preventive Maintenance Workers:
A quality preventive maintenance program requires a highly motivated preventive maintenance crew. To provide proper motivation, the following activities are suggested:

• Establish inspection and preventive maintenance as a recognized, important part of the overall maintenance program.
• Assign competent, responsible people to the preventive maintenance program.
• Follow-up to assure quality performance and to show everyone that management does care.
• Provide training in precision maintenance practices and training in the right techniques and procedures for preventive maintenance on specific equipment.
• Set high standards.
• Publicize reduced costs with improved up-time and revenues, which are the result of effective preventive maintenance.

In addition to explaining the importance of a good preventive maintenance program and the benefits that can be derived from it, training is probably the most effective motivational tool available to the maintenance supervisor. Maintenance and training professionals have estimated that a company should spend $1200 per year for training of supervisors and $1000 per year for each craftsperson. In fact, due to advances in technology, if the company has not provided any training for craftspeople in the past 18 months, their skills have become dated.

Conclusion
It is possible to have a successful preventive maintenance program. From a cost reduction viewpoint it is essential, but it does entail risk. When the proper care is taken, the risks, however, can be minimized. In order to minimize risk, preventive maintenance has to be carefully planned and carried out by well-trained and motivated workers. The biggest benefits of a PM program occur through painting, lubrication, cleaning and adjusting, and minor component replacement to extend the life of equipment and facilities.