How Often Should You Inspect Equipment?

IDCON INC
Tags: preventive maintenance, maintenance and reliability

This is a question we hear a lot when we are on site at plants, mills and mines around the world. The short answer to this question is that you have to use your experience and common sense supported by a logical decision structure.

Let’s start with defining what we mean by inspections. Inspections include all objective and subjective inspections.

In order to set the frequency of your preventive maintenance inspections, you need to understand what Failure Developing Period (FDP) is.

Failure Developing Period (FDP) (or Pf Curve)

The FDP is the time period from when it is possible to detect a failure until breakdown occurs.  A failure is when a system or equipment is operating correctly within given parameters but has signs of problems.

For example, a centrifugal pump may be cavitating, but is still providing the required flow for the operation; this is a failure, but not a break down. The cavitations in our example will eventually develop into a breakdown. The breakdown occurs when the pump is unable to perform its intended function.

 

 

The FDP is the time difference between the failure and the break down. If the pump started to cavitate at 6 am and it broke down 6 pm 6 days later, the FDP is 156 hours.

So, what’s the Inspection Frequency?
The theoretical answer to the question is very simple. The inspection frequency should roughly be: FDP/2

For example, if the estimated failure developing period is 14 days and we need some time to plan and schedule the corrective maintenance for that failure to avoid a break down. A reasonable inspection frequency is 7 days (FDP/2).  If the inspection frequency is longer than 14 days, we may miss the failure and we will have a breakdown. 

The real problem is that we don’t know what the FDP is.  There is no standard, no documentation and most plants do not have any history on FDP.

Inspection Tools changes the FDP

FDP changes when we have access to better tools. For example, we may be able to detect a problem with a pillow block bearing by listening to it with a stethoscope. This method may give us a warning period of a few days (on average depending on situation). However, if we use a vibration analyzer, we can probably detect the same failure at least 6 weeks in advance.

The failure is the same, but the FDP has changed!  For the most part, the only reason we buy inspection tools is to extend the FDP with more accuracy.

In reality, the ability to detect a failure during the FDP also depends on the person’s ability to do the inspection, environment (lighting, temperature, indoor vs. outdoor, etc.), and operational parameters at the time of inspection, equipment design and accessibility, and much more.

Too many variables

Some variables that trip up many plants when calculating the FDPs are:

All these variables inevitably lead many plants to do the wrong thing…start a massive study to find the answers to these variables.

Why is a massive study not a good approach? I mean all you have is time, right?

This is not a good approach because in 999 times out of 1000, you will not have the data you need to do the analysis and even if you did, the best bang for the buck is usually to get your people trained and then out there doing inspections rather than performing a big analysis.

What you will end up with when you do a complicated analysis without data is a guess based on a lot of work, so let’s not do the complicated analysis and instead do a guess using our experience and cut out 99.9% of the work.

Example

Let’s look at some typical problems with an AC Motor.  This example does not include all failure modes, for example, if you look at bearing manufacturer manual, a bearing has over 50 failure modes.  So instead we need to look at most common and most likely problems. 

Example:  AC Motor, 125 HP, 80% load, 24/7 operation, dusty environment.

COMMON PROBLEM

GUESSTIMATED FDP

INSPECTION & FREQUENCY

Temp increase center of motor due to overload or damaged winding

Weeks

Temp gun weekly

Vibration in bearings

4 -12 weeks

Vibration analysis every 2 weeks

Dirt buildup on motor

1 Month

Check/clean bi- weekly

Bolts loose

1 Month

Inspect bolts bi – weekly

Frame & foundation for corrosion

1 Year

Visual detailed inspection semi-annually

Temperature increase inboard bearing (can’t get good temperature reading on outboard bearing)

2 Weeks

Inspect IB bearing with IR gun weekly (don’t exceed 170 F  77C)

Electrical Junction box and cables

1 Month

Bi-weekly

Noise from bearings, winding, overload, etc.

1 Week

Other tools above will pick up source of noise earlier, recommend weekly.

Immediate damage such as forklift run in, something falling on motor

Instant

Can’t catch problems early without a FDP.

Increase in load (A)

2-4 weeks

Weekly Current (A) reading

As mentioned previously there are many more failure modes, I have picked some common problems to illustrate my point.

Notice in the right-hand column there are many different inspection frequencies even when we do a simplified analysis. Our estimates are just guesswork and will vary depending on who is doing the inspection, the type of tool and environment, so we should not take the numbers too seriously, they are estimates.
Instead, you should look at some of the shorter inspection intervals and then add some of the longer interval inspections to those since you may as well do the longer ones when you’re there. They don’t take too long time to do and we are just guessing the intervals.

In our AC Motor example, we could group them as follows in a typical process plant environment:

 

Sample Checks on an AC Motor

Weekly

Temp IB Bearing
Temp center Motor
Vibration pen at painted spot
Check Cleanliness of Motor
Look at condition of junction box and cables
Visually look for water on motor
Check fan with stroboscope
Listen for unusual noise

Monthly

Measure Amps
Vibration analysis with Analyzer (different than pen above)

6 months

Carefully check the base (steel) and foundation (Concrete)

Other Inspections

If it is a critical motor perhaps you want to do a full motor analysis or a test of leakage to ground.

Common Logical Error

Preventive Maintenance Inspection frequencies are based on FDP, not life of component, nor the criticality of the equipment function.

The life of a component has nothing to do with inspection frequency.  For example, a world class plant had an average motor life of 18 years, some motors last 8 years some 25.

However, the FDP for the most common failure modes for these motors are most likely in the 1-4 weeks span, so life statistics has nothing to do with inspection frequency.

A common erroneous argument is “we have inspected this component for 3 years and have not found any problems”.  Therefore, they extend the inspection frequency from one week to four weeks. Just because you have not found a problem has nothing to do with the FDP, it hasn’t changed just because the component is running without any indications of a failure.

Once that component fails, it may be after 15 years, the FDP may still be two weeks and you need to catch it if it is financially viable to do so.  If you change the inspection period to four weeks, it is roughly 50 % + risk that you miss it.

Criticality does not affect the FDP, but it might be a factor when we assign inspection frequency.

The criticality of the motor is a deciding factor when estimating the financial pay off and may change the selection of the inspection frequency because we are uncertain of the FDP.

The FDP is a guess.  So, a very critical component may be checked more frequently because we don’t really know the FDP.  It is an insurance policy.

To sum up this article:

We invite you to contact IDCON with comments or questions. And check out the rest of our videos on our YouTube channel.