Explaining Motor Failure

The squirrel cage induction motor's versatility and ruggedness continue to make it the workhorse of the industry, but that doesn't mean it's invincible. Pushing it too hard for too long can cause the stator, rotor, bearings, and shaft to fail. Numerous industry surveys document which parts fail and how, but very little data is available to explain why.

As the industry's approach to maintenance and repair gradually evolves from reactive and preventive to diagnostic and predictive, it's important to pay more attention to root cause failure analysis. Neglecting to do so often will cause your motors to repeatedly fail and cost you valuable resources and time.

Root cause methodology. Root cause methodology is a step-by-step process for examining a failed motor and its system. It focuses on the stresses that acted upon the failed component. By better understanding these stresses, the service center is more likely to uncover the root cause of the failure.

The five key steps in root cause methodology are:

•  Failure mode
  The manifestation, form, or arrangement of the failure (e.g., turn-to-turn, phase-to-phase, etc.)
•  Failure pattern
  How the failure is configured (e.g., symmetrical or asymmetrical).
•  Appearance
  Examination of the failed part, the entire motor, and the system in which it operates. Care must be taken to inspect all motor parts for damage, contamination, moisture, cracks, or other signs of stress.
•  Application
  A close examination of the work performed by the motor and the characteristics of those types of loads.
•  Maintenance history
  A look at the work performed to keep the motor and system in proper operating condition.

In an ideal world, all relevant information pertaining to the application, appearance, and maintenance history would be available prior to the actual inspection of the motor or failed component. In real life, however, the methodology usually consists of inspecting the failed part and the whole motor and then acquiring information about the application, the appearance of the system, and its maintenance history. This sequence is usually driven by the urgency to return the motor to service as well as the availability of application and historical data.

The good news is that the root cause of failure is obvious in some cases. Such examples could be:

• A balancing weight came loose and struck the winding.
• The winding is saturated with water.
• The bearing lubricant is contaminated.

In a case where the root cause isn't as easy to determine, it's imperative that you complete each step of the methodology.

Summary of motor stresses. Most motor failures are caused by a combination of various stresses that act upon the bearings, stator, rotor, and shaft. If these stresses are kept within the design capabilities of the system, premature failure shouldn't occur. However, if any combination of the stresses exceeds the design capacity, the life of the system may be drastically reduced and catastrophic failure could occur.

These stresses are classified as follows:

•  Bearing stresses
  Thermal, dynamic and static loading, vibration and shock, environmental, mechanical, electrical
•  Stator stresses
  Thermal, electrical, mechanical, and environmental
•  Rotor stresses
  Thermal, dynamic, mechanical, environmental, magnetic, residual, and miscellaneous
•  Shaft stresses
  Dynamic, mechanical, environmental, thermal, residual, and electromagnetic

Analysis of the motor and system. Surrounding the motor is a system that consists of the power supply, mounting, coupling, and driven equipment. The environment, including the ambient temperature, acts as an umbrella that covers all of the system's elements. Even the end product or process can be considered part of this system. 

Many factors that affect the system will also affect the motor and may contribute to the motor failure and vice-versa. Failure to consider each of these elements of the motor system could lead to an incorrect diagnosis of the root cause of failure. Conducting a failure mode effect analysis (FMEA) of the complete system is an effective approach. The idea is to determine what the possible failure modes are for a component and then determine how that failure can affect the system where the component resides. This will offer at least some of the possible scenarios that can lead to a motor failure.

It's important to note that a number of failure mechanisms can cause the same part to fail with a common mode and pattern of failure. As examples, improper voltage, too much load, blocked ventilation, excessive cycling, and excessive heat can all produce the same type of winding failure. It's not always possible to correctly identify the problem without considering the entire system.

In many cases, arriving at the correct conclusion requires a process of elimination driven by the collection of accurate data and facts associated with the system. Failure to eliminate the root cause will usually ensure expensive downtime and repeated motor failures. A classic example is the repeated replacement of failed bearings without ever trying to assess the root cause of failure.

Arriving at the correct conclusion. When analyzing a motor failure, it's important to not make assumptions. The service center rarely knows much about the motor application, much less the power supply and/or maintenance history. The individual dealing with the service center may not be the person who removed the motor from service or the operator who is familiar with the motor or its application, meaning that it's imperative those individuals compile all of the facts before concluding anything.

Incorrect, incomplete, or even misleading information is the norm. But it doesn't have to be that way. Never assume a piece of evidence exists just to force the conclusion to fit the facts. When a conclusion is built around erroneous information mingled with facts, the root cause of failure is seldom correct. The result will be additional failures or the assignment of blame to the wrong parties.

How an explosive atmosphere is divided into zones

he ATEX directive 99/92/EC distinguishes between two types of explosive atmospheres: gas and dust  Areas subjected to these two kinds of explosive atmospheres are each divided into three zones  The zone’s characteristics are identical for gas and dust, but their numbering is different  Zones 0, 1, 2 refer to gas and zones 20, 21, 22 refer to dust

Zone 0 / 20: Constant danger

Permanent presence of explosive gasses or com- bustible dust  Minimum category 1 equipment 

Zone 1 / 21: Potential danger
Occasional presence of explosive gasses or com- bustible dust during normal duty  Minimum cat- egory 2 equipment

Zone 2 / 22: Minor danger

Presence of explosive gasses or combustible dust not likely to occur or only for a shorter period of time  Minimum category 3 equipment
Grundfos manufactures pumps, with motors in both category 2 and category 3  The illustration on your right shows the division of an area into zones with different levels of danger of explo- sion  For each of the three zones it is only a cer- tain category of equipment – in this case motors – that can be used due to danger of explosion
The owner of the equipment is responsible for defining whether an area is to be considered haz- ardous within the regulations stated in the ATEX directive  However, if the user has any doubts about the definition of hazardous areas, he has to contact the proper authorities for advice
In Denmark the proper authority is the local Emergency Management Agency
The link between zones and equipment categories, is a minimum requirement  If the national rules are more strict, they are the ones to follow

What is explosive atmosphere?

According to the new directives, dust is now considered an explosive atmosphere
An explosive atmosphere is an atmosphere that develops explosively because an uncontrolable combustion  Explosive atmosphere consists of air and some sort of combustible material such as gas, vapours, mists or dust in which the explosion spreads after ignition  Typical exam- ples of productions where combustible dust is of major concern, is the handling of cereals, animal feed, paper, wood, chemicals, plastics and coal
Examples of sources of ignition that can cause the atmosphere to explode:

• Electrical sparks
• Flames
• Hot surfaces/ spots
• Static electricity
• Electromagnetic radiation
• Chemical reaction
• Mechanical forces
• Mechanical friction
• Compression ignition
• Acoustic energy
• Ionising radiation

An explosion is an uncontrolled combustion wave that produces a rapid increase in temperature and pressure  For an explosion to take place, three elements have to be present at the same time: fuel, (such as explosive gas) an oxidiser, (such as the oxygen in the air) and a source of ignition, (such as electrical sparks)  The combination of these three elements is generally referred to as the Fire Triangle 

To generate a potentially explosive atmosphere, the mixture of fuel and oxidiser has to have a cer- tain concentration  This concentration depends on the ambient pressure and the content of oxygen in the air, and is referred to as the explosion limits  Outside these limits, the mixture of fuel and oxi- diser will not ignite, but has the potential to do so if the proportions change  For an explosive atmosphere to form, a certain concentration of combustible material must be present 

                            

What is ATEX?

ATEX (ATmosphère EXplosible) refers to two new EU directives about danger of explosion within different areas  The first ATEX directive (94/9/ EC) deals with requirements put on equipment for use in areas with danger of explosion  The manufacturer has to fulfil the requirements and mark his products with categories  The sec- ond ATEX directive (99/92/EC) deals with the minimum safety and health requirements that the owner of the equipment has to fulfil, when working in areas with danger of explosion 

IEC 60034-7 Mounting arrange- ments and types of construction (IM code)

Basically, three types of standard motors exist: Foot-mounted motor, flange-mounted motor with tapped-hole flange and flange-mounted motor with free-hole flange  The motor types differ from one another in the way they are mounted in differ- ent applications 

Foot-mounted motor:

This kind of motor is mounted in the application by a foot with holes  The foot can either be integrated, (normal for cast iron motors) or it can be retrofit- ted, (normal for motors with stator housing made of aluminium) 

Motor with tapped-hole flange:

This type of motor is mounted in the application by means of bolts, which are screwed into the drive-end flange  In the drive-end flange there are threaded holes with standardised thread size and placed in a standardised pitch circle diameter 

Motor with free-hole flange:

This type of motor is mounted in the application by means of bolts through free-holes in the drive- end flange  The diameter of these free-holes is stand- ardised and the holes are placed in a standardised pitch circle diameter 

Combination of flange and foot:

The above-mentioned motor types can be com- bined in different ways:
• Horizontally or vertically
• With the shaft end pointed in different
directions
• With the foot turned in different directions The combinations are described in mounting des- ignations and are defined with codes according to IEC 60034-7 

IEC 60034-6 Methods of cooling of electric motors (IC code)

The three most frequently used motor cooling methods have the following designations - IC codes according to the IEC 60034-6 standard IC 411, IC 410, and IC 418 are applied 

IC410: The motor is cooled by free convection

IC411: The motor is cooled by a fan mounted on the motor shaft 

IC 418: The motor is cooled by an air flow typi- cally coming from an external fan 

Care of Windings and Insulation

Except for expensive, high horsepower motors, routine inspections generally do not involve opening the motor to inspect the windings. Therefore, long motor life requires selection of the proper enclosure to protect the windings from excessive dirt, abrasives, moisture, oil and chemicals.
When the need is indicated by severe operating conditions or a history of winding failures, routine testing can identify deteriorating insulation. Such motors can be removed from service and repaired before unexpected failures stop production. 

Whenever a motor is opened for repair, service the windings as follows:

1. Accumulated dirt prevents proper cooling and may absorb moisture and other contaminants that damage the insulation. Vacuum the dirt from the windings and internal air passages. Do not use high pressure air because this can damage windings by driving the dirt into the insulation.

2. Abrasive dust drawn through the motor can abrade coil noses, removing insulation. If such abrasion is found, the winding should be revarnished or replaced.

3. Moisture reduces the dielectric strength of insulation which results in shorts. If the inside of the motor is damp, dry the motor per information in "Cleaning and Drying Windings".

4. Wipe any oil and grease from inside the motor. Use care with solvents that can attack the insulation.

5. If the insulation appears brittle, overheated or cracked, the motor should be revarnished or, with severe conditions, rewound.

6. Loose coils and leads can move with changing magnetic fields or vibration, causing the insulation to wear, crack or fray. Revarnishing and retying leads may correct minor problems. If the loose coil situation is severe, the motor must be rewound.

7. Check the lead-to-coil connections for signs of overheating or corrosion. These connections are often exposed on large motors but taped on small motors.Repair as needed.

8. Check wound rotor windings as described for stator windings. Because rotor windings must withstand centrifugal forces, tightness is even more important.In addition, check for loose pole pieces or other loose parts that create unbalance problems.

9. The cast rotor rods and end rings of squirrel cage motors rarely need attention. However, open or broken rods create electrical unbalance that increases with the number of rods broken. An open end ring causes severe vibration and noise.

Testing Windings :

Routine field testing of windings can identify deteriorating insulation permitting scheduled repair or replacement of the motor before its failure disrupts operations. Such testing is good practice especially for applications with severe operating conditions or a history of winding failures and for expensive, high horsepower motors and locations where failures can cause health and safety problems or high economic loss.

The easiest field test that prevents the most failures is the ground-insulation, or &127megger," test. It applies DC voltage, usually 500 or 1000 volts, to the motor and measures the resistance of the insulation.

NEMA standards require a minimum resistance to ground at 40 degrees C ambient of 1 megohm per kv of rating plus 1 megohm. Medium size motors in good condition will generally have megohmmeter readings in excess of 50 megohms. Low readings may indicate a seriously reduced insulation condition caused by contamination from moisture, oil or conductive dirt or deterioration from age or excessive heat.

One megger reading for a motor means little. A curve recording resistance, with the motor cold and hot, and date indicates the rate of deterioration. This curve provides the information needed to decide if the motor can be safely left in service until the next scheduled inspection time.