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How to schedule

To schedule private education for your group, contact:

Dale Shuter, CMP
Meetings & Expositions Manager

+1 314 993 2220, ext. 3335
dshuter@easa.com

1 hour of training

$300 for EASA Chapters/Regions
$400 for member companies
$800 for non-members

How a webinar works

All EASA private webinars are live events in which the audio and video are streamed to your computer over the Internet. Prior to the program, you will receive a web link to join the meeting. 

The presentation portion of the webinar will last about 45 minutes, followed by about 15 minutes of questions and answers.

Requirements

  • Internet connection
  • Computer with audio input (microphone) and audio output (speakers) appropriate for your size group
  • TV or projector/screen

Zoom logo

The Zoom webinar service EASA uses will ask to install a small plugin. Your computer must be configured to allow this in order to have full functionality. Please check with your IT department or company's security policy prior to scheduling a private webinar.

Private Webinars

EASA's private webinars are an inexpensive way to bring an EASA engineer into your service center, place of business or group meeting without incurring travel expenses or lost production time.

Aplicando las tolerancias de balanceo en rotores de diversas máquinas

Aplicando las tolerancias de balanceo en rotores de diversas máquinas

Gene Vogel
EASA Pump & Vibration Specialist

La especificación ISO para balancear rotores rígidos (ISO 1940-1) fue innovadora cuando fue introducida hace varias décadas. Esta norma estableció los Grados de Calidad de Balanceo basada en la velocidad teórica que el centro de masa de un rotor se encontraría en espacio libre, girando a la velocidad de funcionamiento normal del rotor. Esta es terminología técnica difícil de expresar, pero un entendimiento práctico de la naturaleza de las fuerzas de desbalanceo es importante para aplicar las tolerancias de balanceo en rotores de diversas máquinas. Esto también ayuda a entender el impacto de los cambios fundamentales en la reciente norma de reemplazo: 21940-11: 2016.

Primero, vamos a clarificar la diferencia entre desbalanceo y vibración. Si una máquina tenía cierta cantidad de desbalanceo y fue asentada sin restricciones sobre un acolchado suave (una almohadilla de caucho), existirá cierta cantidad de vibración a 1x rpm. Atornille esa misma máquina a una fundación maciza y la vibración a 1x rpm será mucho menor. Así que no hay conversión directa de desbalanceo a vibración y viceversa.

Por consiguiente, para maquinaria en funcionamiento, las unidades de amplitud de vibración comunes de desplazamiento y velocidad no son medidas directas del desbalanceo, La cantidad de desbalanceo del rotor se puede describir como una cantidad de masa (peso) en un radio determinado.

El artículo continúa cubriendo:

  • Unidades de desequilibrio
  • Dos posibles aproximaciones para el uso de planos de cojinetes para evaluar la tolerancia de equilibrio
  • Desplazamiento del centro de gravedad

Available Downloads

Applying balance tolerances to various machine rotors

Applying balance tolerances to various machine rotors

Gene Vogel
EASA Pump & Vibration Specialist

The ISO balancing specification for rigid rotors (ISO 1940-1) was innovative when it was introduced decades ago. It established Balance Quality Grades based on the theoretical velocity the mass center of gravity of a rotor would encounter in free space, spinning at the rotor’s normal operating speed. That’s a mouthful of technical jargon, but a practical understanding of the nature of unbalance forces is important in applying balance tolerances to various machine rotors. It is also helpful in understanding the impact of fundamental changes in the recent replacement standard, 21940-11: 2016.

First, let’s clear up the difference between unbalance and vibration. If a machine had a certain amount of unbalance and was sitting unrestrained on a soft pad (a durometer pad), there would be a certain amount of vibration at 1x rpm. Bolt that same machine to a massive foundation and the vibration at 1x rpm would be much less. So there is no direct conversion from unbalance to vibration or vice versa.

Consequently, the common vibration amplitude units of displacement and velocity are not direct measures of unbalance for operating machinery. The amount of rotor unbalance can be described by an amount of mass (weight) at a certain radius.

The article goes on to cover:

  • Unbalance units
  • Two possible approaches to using bearing planes to evaluate balance tolerance
  • Displacement of center of gravity

Available Downloads

Armature winding designs demystified with helpful tips

Armature winding designs demystified with helpful tips

Chuck Yung
EASA Senior Technical Support Specialist

While there are many similarities between 3-phase AC stators and DC armatures, there are some unique aspects to DC armature design; these can be extremely helpful to those who understand some little-known tips. My goal in writing this article is to share those tips.

Available Downloads

Consideraciones sobre la fuente de alimentación al construir un gran growler

Consideraciones sobre la fuente de alimentación al construir un gran growler

Tom Bishop
EASA Senior Technical Support Specialist

Cuando se considera la construcción de un gran growler para probar rotores y armaduras, la decisión inicial típica es seleccionar la potencia en kVA. La razón principal para esto es que el growler necesitará ser conectado a una fuente de alimentación que tenga suficiente amperaje. Para ayudar a simplificar el complejo proceso de diseño, en este artículo hemos seleccionado cinco potencias expresadas en kVA. Uno de los valores de potencia seleccionados cumplirá con las necesidades de la mayoría de los centros de servicios.

Este artículo abarca:

  • Un ejemplo de diseño
  • Determinación de las vueltas y el tamaño del cable
  • Construyendo el núcleo
  • Determinación de las dimensiones de la bobina

Available Downloads

DC Machine Data Sheet

DC Machine Data Sheet

DC machine data form

This form will aid in collecting all needed information regarding a DC machine recieved for repair: nameplate data, armature coil data, armature dimensions, field winding data, field coil dimensions, general winding information as well as job and customer details.

This fillable PDF conveniently helps you save DC machine data for future reference. SImply copy the file or "Save As" to create a form for each motor you repair. The PDF includes a convenient button that can help you easily send DC data to EASA technical support.

Available Downloads

DC Machine Inspection Report

DC Machine Inspection Report

This incoming inspection report provides a place to record basic DC motor conditions and test values, including:

  • Customer information
  • Armature voltage and amps
  • Field voltage, amps ,etc.
  • Electrical test information for the armature, fields, interpoles and series windings
  • Brush and brushholder information

Available Downloads

DC Motor Electrical Procedures

DC Motor Electrical Procedures

6
presentations
$30
for EASA members

 

A special discounted collection of 6 webinar recordings focusing on DC motor electrical procedures.

Once purchased, all 6 recordings will be available on your "Downloadable products purchased" page in your online account.

Downloadable recordings in this bundle include:

The Basics: Understanding DC Motor Tests
Presented October 2016

  • Ampere turns of the armature, field and interpole data
  • Determining the best armature coil pitch
  • Verifying interpole circuits
  • Importance of brush angle
  • Equalizers and armature windings

Adjusting Brush Neutral
Presented June 2011

The webinar covers:

  • How to set brush neutral in DC machines.
  • Several methods of setting brush neutral along with the benefits and drawbacks of each.
  • Tips for permanent magnet and series-would machines.
  • Tips on how to recognize problems and settings that affect brush neutral, and what to check if the neutral adjustment seems higher than usual.

Target audience: This presentation is most useful for service center and field technicians involved in the repair of DC machinery, service center managers engineers, or anyone involved in DC motor or generator repair, as well as those who are simply looking to expand their understanding.


Carbon Brushes, Current Density and Performance
Presented June 2019

The lowly brush is underrated and misunderstood. The brush grade, brush pressure and spring tension, as well as the effect of load and humidity are each important to brush performance in DC machines, wound rotor motors, and synchronous machines.

This presentation covers:

  • Importance of brush grade
  • Effect of humidity and load (current)
  • Best practice method for removing brushes to improve performance
  • Brush pressure & spring tension by application
  • Supplemental cooling of slip ring / brush enclosures

Target audience: This presentation will benefit service center technicians and supervisors.


Drop Testing of Fields and Synchronous Poles: Tips to Interpretation
Presented November 2011

This presentation covers:

  • The basics of drop testing, as well as offers tips for interpreting the results.
  • Both the AC and DC drop test are described as well as the advantages and drawbacks for each.
  • For those cases where the drop test results are out of tolerance, this material will guide the technician in determining the reasons for the variation-how to recognize the difference between shorted coils and differences in iron, airgap or other influences.
  • Rewind and assembly tips will also be discussed, where they influence the results of the drop test.

Target audience: This presentation is most useful for service center and field technicians with at least 5 years experience, service center managers, engineers, or anyone involved in DC motor or generator repair, as well as those who are simply looking to expand their knowledge.


Final Testing of DC Machines
Presented September 2011

To assure a quality repair, there specific tests (such as neutral-setting and interpole-armature polarity) that should routinely be performed on every DC machine. When done correctly, the simple procedures presented will prevent scenarios such as that late night phone call from an irate customer whose DC machine is "arcing like a fireworks show."

Target audience: Technicians with at least a moderate lever of experience in DC machine repair will benefit from this session.


Advanced DC Testing
Presented April 2012

This presentation shares tips that are not covered in “Fundamentals of DC: Operation and Repair Tips,” such as:

  • Tips for interpreting armature and interpole tests
  • Finding that ground in the newly rewound armature
  • Interpreting questionable drop test results

It also covers final assembly tests including how to determine whether the cause of sparking is the interpoles or the armature.

Target audience: This presentation is aimed at the experienced technician and supervisor.

Dynamic balancing of rotors and armatures

Dynamic balancing of rotors and armatures

Tom Bishop, P.E.
EASA Technical Support Specialist 

This article describes machine balancing of the rotating components of motors and generators, primarily rotors and armatures. The methods described here, in general, can be applied to on-site balancing if the rotating component is accessible. The intent is to describe the methods of attaching balance weights, not determining acceptable balance level or the location and amount of correction weight. 

The advent of computerized balancing machines has made the latter steps rather straightforward. However, the challenge of how to attach a weight in such a way that it will remain secure and not negatively affect machine operation remains at times a vexing problem. 

What is the purpose of dynamic balancing a rotating part? It is to reduce unbalance and consequently to bring vibration to acceptable levels to allow for normal bearing and other component life. The acceptable levels of vibration are described in EASA Tech Note 32, “Standards For Dynamic Balancing,” thus we won’t explain them here.

Available Downloads

Factores a Considerar al Probar Armaduras de CC

Factores a Considerar al Probar Armaduras de CC

Chuck Yung
Especialista Sénior de Soporte Técnico de EASA

Cuando se prueban armaduras de CC, ya sea al entrar a reparación o una vez rebobinadas, una pregunta que escucho muy a menudo incluye la interpretación de los resultados de la prueba de impulso (barra-barra de alta frecuencia).

Available Downloads

Factors to Consider When Testing DC Armatures

Factors to Consider When Testing DC Armatures

Chuck Yung
EASA Senior Technical Support Specialist

When testing DC armatures, whether incoming for repair or after completing a rewind, one question I often hear involves interpreting the surge test (or the high-frequency bar-to-bar test) results. There is a lot to our interpretation of the bar-bar test or surge test.

Available Downloads

Flashover: Causes and cures for damage to brushholders, commutators

Flashover: Causes and cures for damage to brushholders, commutators

Chuck Yung
EASA Senior Technical Support Specialist

There are times when a DC motor or generator experiences a catastrophic failure and the customer wants to know why it happened. One type of failure that seems to stimulate lively conversation is when the failure involves dramatic damage to the brushholders and commutator. The term “flashover” describes the appearance of the failure; the very name conveys an accurate mental image of the failure.  See Figure 1.

The questions that arise next are predictable: “What caused this?” and ”What can be done to prevent a recurrence?” Or, if the motor was recently repaired: “What did you do to my motor to cause this?!” The purpose of this article is to help you answer those questions.

The causes of a flashover can be partially explained by the insulating properties of air, and Ohm’s Law. Air is an electrical insulator, although the dielectric breakdown voltage of air is low compared to the insulating materials we use in electric motors. Inside an operating DC motor, we find heat, carbon dust and other contaminants, and perhaps even humidity. Each of these will reduce the dielectric strength of air.

As for Ohm’s Law, E/R = I; winders use this frequently to evaluate shunt fields and to extrapolate the temperature rise of those fields. But it also applies to the armature circuit. 
At the moment a DC motor is energized, before the armature starts to rotate, the armature current is limited only by the available kVA of the power supply. 

Consider the example of a 500 hp motor, with a 500V armature circuit. Static resistance of the armature-interpole circuit measured only 0.02 ohms, so the short circuit armature current could reach 25,000 amps if the drive has sufficient kVA: 500/0.02  = 25,000 amps.

Effects on armature
Fortunately, drives ramp up the armature voltage, rather than applying it instantly. As soon as the armature begins to rotate, the inductance provided by the armature becomes a factor in suppressing the armature current. Paraphrasing the now-defunct IEEE Standard 66: When voltage E is applied across a circuit consisting of a resistance and inductance L in series, the maximum rate of rise is given by the equation di/dt = E/L amperes per second; where E equals volts, and L equals henrys. In other words, the armature current decreases rapidly as the armature speed increases.

Every DC motor can be used as a generator, by driving it mechanically and applying current to the fields. When operating as a motor, there are times where the motor might be driven by an overhauling load (e.g., a loaded conveyor running downhill; or a hoist lowering a heavy load). When that happens, the counter-emf (electro-motive force) produced overcomes the applied emf, and flashover is likely. In layman’s terms, operating conditions cause the armature current to increase rapidly, and generated voltage/current trigger the flashover. 
A list of operating events that can cause a flashover is included in Table 1.

If the interpoles are not correctly adjusted to maintain brush neutral throughout the operating load range, the shifting neutral results in arcing as the load increases outside the black band region. That can, in and of itself, trigger a flashover. (The black band region can be described as this: Weakening / strengthening the interpoles, independent of all else, until the brushes begin to spark produces a band within which no sparking occurs. That band is referred to as the “black band.” For more information, see the Assembly and Final Test section of Fundamentals of DC Operation and Repair Tips.)

Preventive measures
Working to help your customer understand the basics of how a DC motor operates can go a long way towards helping them avoid problems. One of my most vivid “triggers” of a flashover is the customer who installs a newly rebuilt compound motor with more than 50% compounding. (The percent compounding describes the percentage of total field flux contributed by the series fields, at full load.) They check rotation and discover that the motor needs to be reversed. We all know that the correct way to do this is to swap the A1 and A2 leads (the large wires that are thoroughly taped). But, says the customer, it is so much easier to swap the shunt field leads (they are smaller, and probably held in a terminal strip by screws) instead. That shortcut has worked in the past — on straight shunt motors.

With a compound-wound machine, this time-saving shortcut changed the motor from a cumulative connection to differential. The motor runs fine unloaded, and even with a moderate load. But when the load is increased to the point that the series overpowers the shunt fields, catastrophe occurs. Since this is a newly rebuilt motor, there is a very good chance that your customer will blame you. After all, you just rebuilt the motor. So it is important to educate the customer to avoid just such a situation. (And yes, I have had many, many calls where a newly installed motor failed exactly as just described.)

If someone blames a flashover on “drive settings,” that implies that the drive is accelerating or decelerating the motor too rapidly. If so, a competent drive technician should be able to adjust that to reduce the chance of flashover. Blaming the drive may instead mean that the motor is in an application calling for a regenerative drive, but the customer replaced the drive with a less expensive model that cannot handle the regenerative mode. (And the customer might not admit having done so until you press the issue.) One example would be a compound wound motor driving a roller coaster. When the cars are coasting downhill, the regenerative mode is used to prevent dangerous over-acceleration.

A compound wound motor, in such an application, requires a drive that has connection points for the shunt, armature and separate series field leads. This is to permit the motor to operate with a cumulative connection in both directions of rotation. If a compound wound motor is operated from a drive with only shunt- and armature circuit leads, in a reversing application, it will be cumulative in one direction but differentially compounded in the opposite direction. The higher the percent compounding, the greater the risk of speed instability and/or flashover. See Table 2.

Specific to any DC motor, there are several preventive measures to reduce the chance of a flashover. The first of these is to simply chamfer the end of the commutator bars. Voltage stress varies exponentially to the inverse of the radius. Chamfering the customary square corner at the end of the commutator to a 1/16” (1.6 mm) radius reduces the voltage stress to approximately 15%, significantly reducing the opportunity for flashover to occur. See Figure 2.

Add flashover protection
If a customer has chronic issues with flashover, take a lesson from the traction motor industry and add flashover protection. Install four equally spaced short lengths of angle iron in line with the end of the string band area. The bolted connection must be electrically sound and the edge closest to the commutator must be bare metal (no paint or other coating). The bare metal provides a reliable path to ground, if an arc is to occur, thus minimizing damage to the costly brush boxes and commutator. See Figure 3.

Flashover detection is commercially available and reliable. It has long been known that, at the moment a flashover begins, the field polarity reverses. Automated instrumentation, by monitoring the polarity of the field current, can shut the motor down before the fault current causes damage.

If the application is a fan, blower or downhill conveyor, where the motor might start while the load is free-wheeling in reverse, the solution could be a brake – either mechanical or otherwise, interlocked with the drive to release the brake when the motor starts. One option the end user might consider is to use the shunt fields as the dynamic brake. If they do so, the field current should not exceed 1/3 of the rated shunt field current. Otherwise, the shunt fields might overheat and fail prematurely.

The manufacturer has more latitude than we do as repairers, so it is common to see larger machines designed with a compensating winding (a.k.a. “pole face bars”), imbedded in the face of each field pole to effectively extend the influence of the interpoles. Those compensating windings, just like interpoles, must be connected correctly so as to yield the correct interpole strength. Misconnected interpoles or compensating windings (i.e., the wrong number of circuits) radically change performance and are much more likely to spark and/or flashover.

Available Downloads

How to Measure Magnet Wire

How to Measure Magnet Wire

This video shows one step in collecting motor winding data: how to measure magnet wire. A service center could use this data to:

  • Duplicate an original winding
  • Verify that a previous rewind was done correctly
  • Serve as a basis for redesigning a winding
  • Store recorded data for future reference

 

Helpful tools

How to strip an armature without degrading the core

How to strip an armature without degrading the core

A simple and efficient method to improve quality and save labor

Chuck Yung
EASA Senior Technical Support Specialist

We all know that stator cores should be burned at a controlled temperature to prevent lamination deterioration that can lead to harmful eddycurrent losses. But what about armatures? While that DC machine is energized by direct current, it is also true that the armature itself sees alternating current as the current in each coil reverses while passing from pole to pole. 

A temperature-controlled burnout oven permits us to cremate a stator without worry, but an armature is another story. Because the commutator is integral to the armature, and cannot be easily removed, some repairers resort to a hand-stripping operation. Careful use of a torch to warm the windings accelerates the stripping job, but controlling the core tempera­ture can be difficult. And stripping a large armature without heat is all but impossible by conventional methods. 

Available Downloads

Power supply considerations when building a large growler

Power supply considerations when building a large growler

Tom Bishop
EASA Senior Technical Support Specialist

When considering building a large growler for testing armatures and rotors, the initial decision typically is to select a kVA rating. A primary reason for this is that the growler will need to be connected to a power supply of sufficient ampacity at the supply voltage. To help simplify a complex design process, four kVA ratings have been selected for this article. One of the selected ratings should fit the needs of most service centers.

This article covers:

  • A design example
  • Determining turns and wire size
  • Building the core
  • Determining coil dimensions

Available Downloads

Surge testing of DC motor and generator armatures

Surge testing of DC motor and generator armatures

Cyndi Nyberg 
Former EASA Technical Support Specialist 

In the April 2007 issue of CURRENTS, we covered surge testing anomalies, speci.cally for AC windings. The surge test can be used for DC windings as well. It can be a useful tool for evaluating armatures and some DC fields. 

A note of caution:  If a winding does not have a minimum insulation resis­tance per ANSI/EASA AR100-2006, it is not safe to apply an overpotential test (surge or high potential). 
Surge testing shunt .elds may not provide meaningful results if the surge pulse decays too quickly — if it dissipates through only the .rst few hundred turns. To obtain a test voltage high enough to test every turn would require too high a voltage. That high voltage would overstress the ground-wall insulation. 

Available Downloads

Training Film 14: Taking Data From a Hand-Wound DC Armature

Training Film 14: Taking Data From a Hand-Wound DC Armature

Describes the correct procedure for taking data from hand-wound DC armatures. Shows how to record the data on typical DC data sheets, and explains the terminology used describing DC data. Points out differences between lap and wave windings.

This training film is archived here solely for historical purposes. The film was produced many years ago and does not meet EASA's current presentation standards. Some procedures may have also changed.

Training Film 15: Hand Winding a DC Armature

Training Film 15: Hand Winding a DC Armature

Provides step-by-step instructions on winding a DC armature, including how to install end fibres and slot liners, how to wind and shape the armature coils and how to make the commutator connections.

This training film is archived here solely for historical purposes. The film was produced many years ago and does not meet EASA's current presentation standards. Some procedures may have also changed.

Training Film 21: Testing DC Machines

Training Film 21: Testing DC Machines

 

This training film is archived here solely for historical purposes. The film was produced many years ago and does not meet EASA's current presentation standards. Some procedures may have also changed.

Troubleshooting tips for armature rewinds

Troubleshooting tips for armature rewinds

Chuck Yung
EASA Technical Support Specialist

When an armature is rewound, there is always a slim chance that it may be connected incorrectly. If two coil leads are switched, or if the error results in an armature where each coil closes on itself, normal tests will detect the problem. The trouble arises when the misconnection results in a uniform winding. When that happens, the result may be—in effect—an accidental redesign for a different voltage.

The number of parallel circuits in an armature winding can be changed simply by shifting the top lead position. As with a 3-phase winding, doubling the circuits halves the design voltage. If a wave-wound armature is rewound with the same data but connected lap simplex, or if a lap simplex armature is connected lap duplex, the circuits have been doubled. The same is true of a wave simplex armature reconnected wave duplex.

Available Downloads