Facebook Twitter LinkedIn YouTube Menu Search Arrow Right Arrow Left Arrow Down Arrow Up Home Arrow Next Arrow Previous RSS Icon Calendar Icon Warning Icon

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.

ANSI/EASA Standard AR100-2020: Recommended Practice for the Repair of Rotating Electrical Apparatus

ANSI/EASA Standard AR100-2020: Recommended Practice for the Repair of Rotating Electrical Apparatus

ANSI/EASA AR100-2020EASA’s “Recommended Practice for the Repair of Rotating Electrical Apparatus” is designated ANSI/EASA AR100 and was first approved as an American National standard in 1998. Since then it has been revised and approved four more times, in 2001, 2006, 2010, 2015 and now in 2020. 

ANSI/EASA AR100 is a must-have guide to the repair of rotating electrical machines. Its purpose is to establish recommended practices in each step of the rotating electrical apparatus rewinding and rebuilding processes.

The scope of this document describes record keeping, tests, analysis and general guidelines for the repair of induction, synchronous and direct current rotating electrical apparatus. It is not intended to take the place of the customer's or the machine manufacturer's specific instructions or specifications or specific accepted and applicable industry standards or recommended practices.

This document should be supplemented by additional requirements applicable to specialized rotating electrical apparatus including, but not limited to, listed explosion-proof, dust-ignition proof, and other listed machines for hazardous locations; and specific or additional requirements for hermetic motors, hydrogen-cooled machines, submersible motors, traction motors, or Class 1E nuclear service motors.

ANSI recognizes only one standard on a topic; therefore, ANSI/EASA AR100 is the American standard for repair of rotating electrical apparatus.The Recommended Practice is an important publication to distribute both internally and to customers.

Download or Purchase
This document is available as a FREE download (see links below) or printed copies may be purchased from EASA's online store in the near future.

DOWNLOAD AR100-2020 BUY PRINTED COPIES

Approval Process
The EASA Technical Services Committee (TSC) reviews the recommended practice and proposes changes; a canvass group approves and often comments on the TSC proposals. The canvass group has representation from service centers, end users, testing laboratories, government and those with a general interest. Per ANSI requirements, there must be balanced representation among the canvass group representatives. After the canvass group and the TSC find consensus agreement, the revised document is approved by the EASA Board of Directors. Following Board approval, ANSI is requested to approve the revision as an American National Standard. The entire process must be completed within five years following the previous revision. 

What’s New in 2020?
The 2020 edition of AR100 contains more than 40 revisions. Here, we will focus on the more significant changes, noted in clause order, and some of the reasons for making these changes. Also noted will be links between the changes and the EASA Accreditation Program. 

1.6 Terminal Leads: Added a note, “If the machine has a service factor, the terminal leads should be rated for the service factor current.” This is the practice used by many motor manufacturers. For example, if a motor had a full load current rating of 100 amps and a service factor of 1.15, the approximate service factor current would be 115 amps, and the lead wire size would be based on the 115 amp value. 

1.9 Cooling System: Added a new sentence: “The locations of air baffles and any stator end winding spacers that are utilized for guiding airflow should be documented prior to any stator winding removal to allow duplication within a replacement winding.” This applies to stator rewinds and helps ensure that the cooling airflow is not reduced during the rewind process. Effective August 2021, this will be a requirement in the Accreditation Program Checklist item 3. Cooling System.

2.5.1 Rotating Elements: The sentence, “The outer diameter of the rotating element laminations should be true and concentric with the bearing journals,” has been replaced with, “The runout of the rotating element core outside diameter relative to the bearing journals should not exceed 5 percent of the average radial air gap, or 0.003” (0.08 mm), whichever is the smaller value.” The new text is independent of the number of poles in a machine and is in line with tolerances used by motor manufacturers. 

3.1.2 Thermal Protectors or Sensors: The former clause 3.9 has been added for clarity. It states, “Replacement thermostats, resistance temperature detectors (RTDs), thermocouples and thermistors should be identical with or equivalent to the originaldevices in electrical and thermal characteristics and placed at the same locations in the winding. Thermal protectors or sensors should be removed or omitted only with customer consent and documented in the repair record.” The reason for moving the text of 3.9 into 3.12 was to have the topic of thermal protectors and sensors addressed in one clause. Since 3.9 was deleted, the remaining clauses of Section 3 beginning with former clause 3.10 were renumbered. 

  Table 4-2 Recommended Minimum Insulation Resistance Values at 40°C: This table and Table 4-1 were unnumbered in previous editions of AR100, including the 2015 edition. For clarity and editorial consistency, these two tables are now numbered. The tables that were, and remain, at the end of Section 4 were renumbered. A substantive technical change was that the minimum insulation resistance for all armatures is now IR1min = 5, which aligns with the 2013 edition of IEEE 43. 

4.2.4 Form-Wound Stator Surge Tests and 4.2.5 All Other Windings Surge Tests: Two identical paragraphs have been added to each of these clauses. The first paragraph explains how a surge pattern distinguishes between a satisfactory and unsatisfactory test result. The second paragraph explains that surge test results can be influenced by multiple factors, and that analysis of surge test results is subjective.  

Table 4-3 Form Coil New Winding Surge Test Voltages: This is a new table that provides surge test voltage levels for machines rated from 400 to 13800 volts in accordance with IEEE 522 and IEC 60034-15. The notes below the table provide test levels for uncured resin-rich or dry (green) VPI coils, and maintenance test levels for reconditioned windings.

 4.3.1 Stator and Wound-Rotor Windings: Two notes have been added to this clause. They are: “Per CSA C392 the resistance unbalance limit for random windings should be 2% from the average, and 1% from the average for form coil windings,” and, “Some concentric windings may exceed the 2% limit.” These notes add resistance balance tolerances and provide guidance for assessing resistive unbalance with concentric windings. 

4.4.1.1 New Windings: The sentence, “Immediately after rewind, when equipment is installed or assembled and a high-potential test of the entire assembly is required, it is recommended that the test voltage not exceed 80% of the original test voltage,” has been replaced with, “Immediately after rewind, when a high-potential test of the winding is required, it is recommended that the test voltage not exceed 80% of the original test voltage.” The primary reason for the change is that AR100 is a repair document, not an installation guide or standard. 

Conclusion 
The work of the Technical Services Committee to revise and improve AR100 is a continual process. Within a year or two, the revision process will become an active agenda item for the TSC. One of the foremost goals with AR100 is to include as many good practices as possible. Further, when it is desired or necessary to add new good practices to the Accreditation Program, AR100 is the conduit. The reason for this approach is that AR100 is the primary source document for the EASA Accreditation Program. 

Since AR100 is revised periodically it is a “living document.” Changes to AR100 not only aid with the Accreditation Program, its good practices and other guidance help enable service centers to provide quality repairs that maintain or sometimes even improve rotating electrical apparatus reliability and energy efficiency.

Available Downloads

Condiciones de Servicio Normales + Inusuales en Motores y Generadores

Condiciones de Servicio Normales + Inusuales en Motores y Generadores

Tom Bishop. P.E.
Especialista Sénior de Soporte Técnico de EASA

¿Cuáles son las condiciones normales para las que está diseñado un motor eléctrico? Esta es una pregunta que no surge muy a menudo, excepto cuando existe un problema con la aplicación.

La norma NEMA MG1 para motores y generadores proporciona detalles sobre este tema, definiendo las condiciones de servicio normales e inusuales. La norma IEC 60034-1, “Rotating Electrical Machines, Part 1 Ratings and Performance”, trata también algunas condiciones de aplicación en la cláusula 6, aunque no en la medida que lo hace la norma MG1. Nuestro enfoque estará basado en la norma MG1, ya que proporciona más detalles que la norma IEC 60034-1.

Available Downloads

Connecting NFPA 70E® Updates to Your Marketing

Connecting NFPA 70E® Updates to Your Marketing

Ron Widup
Marketing & Industry Awareness Committee Chair
Shermco Industries

How are your marketing efforts related to the latest changes in the National Fire Protection Association's electrical safety standard, NFPA 70E® Standard for Electrical Safety in the Workplace? The NFPA 70E® has a specific purpose, and it never mentions marketing. After all, these are two entirely different subjects. Or are they?

We should always think about safety. It needs to be top of mind every day for every task, whether you are standing in front of an energized piece of high-voltage equipment, driving through a school zone or cleaning the gutters on your roof. We all  agree that safety is important, but where is the connection to marketing? 

The NFPA 70E® (Article 90.1) says: 

The purpose of this standard is to provide a practical, safe working area for employees relative to the hazards arising from the use of electricity.

Let's apply the following five points to the latest changes found in NFPA 70E® and how they relate to marketing. You can apply these principles to similar thought streams, including new government rules and regulations, customer-specific requirements and ANSI/EASA AR100.

Available Downloads

Controlled Environments and Cleanrooms Prevent Contamination in Service Centers

Controlled Environments and Cleanrooms Prevent Contamination in Service Centers

Tom Bishop
EASA Senior Technical Support Specialist

Occasionally we hear the term “cleanroom” used for a winding area that is physically isolated from the remainder of a service center (Figure 1). The main purpose of such an enclosure is to prevent windings and winding material from being contaminated with any dust and dirt (Figure 2) that may be in other parts of the service center. Some service centers construct these enclosures because they strive to provide the cleanest practical environment for winding work, and some also use the enclosure for the bearing installation process. Cleanroom type enclosures can also benefit facilities by helping minimize quality problems and increase the volume of acceptable product.

Here we will explore the distinction between a controlled environment and a cleanroom, the requirements for both, and provide details to help you determine if you want to add a controlled environment or a cleanroom to your facility.

Available Downloads

Electrical Engineering Pocket Handbook

Electrical Engineering Pocket Handbook

Electrical Engineering Pocket HandbookDESCRIPTION
Filled with practical information, this 118-page handbook (3.5" x 6", 9cm x 15cm) makes a great “give-away” item for your customers and potential customers! Buy this great resource as is OR custom brand your company logo and information on the cover to turn it into a great marketing piece for your salespeople!

BUY COPIES OF THIS HANDBOOK

TABLE OF CONTENTS

MOTOR DATA–ELECTRICAL
Standard Terminal Markings and Connections
DC Motors and Generators (NEMA & IEC Nomenclature)
Field Polarities of DC Machines
General Speed-Torque Characteristics
Full-Load Efficiencies of Energy Efficient Motors
Full-Load Efficiencies of NEMA Premium™ Efficient Motors
Effect of Voltage Variation on Motor Characteristics
Power Supply and Motor Voltages
Effect of Voltage Unbalance on Motor Performance
Starting Characteristics of Squirrel Cage Induction Motors
Allowable Starts and Starting Intervals

MOTOR DATA–MECHANICAL
Suffixes to NEMA Frames
NEMA Frame Assignments–Three-Phase Motors
NEMA Frame Dimensions–AC Machines
IEC Mounting Dimensions–Foot-Mounted AC and DC Machines
IEC Shaft Extension, Key And Keyseat Dimensions–Continuous Duty AC Motors (Inches)
NEMA Shaft Extension And Keyseat
Dimensions–Foot-Mounted DC Machines (Inches)
NEMA Frame Dimensions–Foot-Mounted DC Machines (Inches)
NEMA Frame Dimensions–AC Machines (mm)
IEC Mounting Dimensions–Foot-Mounted AC and DC Machines (mm)
IEC Shaft Extension, Key and Keyseat Dimensions–Continuous Duty AC Motors (mm)
NEMA Shaft Extension and Keyseat Dimensions–Foot-Mounted DC Machines (mm)
NEMA Frame Dimensions–Foot-Mounted DC Machines (mm)

MOTOR CONTROLS
Power Factor Improvement of Induction Motor Loads
Capacitor kVAR Rating for Power-Factor Improvement
Full-Load Currents–Motors
Maximum Locked-Rotor Currents–Three-Phase Motors
NEMA Code Letters for AC Motors
Starter Enclosures
NEMA Size Starters for Three-Phase Motors
NEMA Size Starters for Single-Phase Motors
Derating Factors for Conductors in a Conduit
Allowable Ampacities of Insulated Conductors
Motor Protection Devices–Maximum Rating or Setting

TRANSFORMERS
Full-Load Currents for Three-Phase Transformers
Full-Load Currents for Single-Phase Transformers
Transformer Connections

MISCELLANEOUS
Temperature Classification of Insulation Systems
Resistance Temperature Detectors.
Thermocouple Junction Types
Dimensions, Weight and Resistance: Solid Round Copper Wire (AWG and Metric)
Square Bare Copper Wire (AWG)
Insulation Resistance and Polarization Index Tests
Properties of Metals and Alloys

USEFUL FORMULAS AND CONVERSIONS
Temperature Correction of Winding Resistance
Temperature Correction of Insulation Resistance.
Formulas for Electric Motors and Electrical Circuits.
Motor Application Formulas
Centrifugal Application Formulas
Temperature Conversion Chart
Conversion Factors
Fractions of an Inch–Decimal and Metric Equivalents

Available Downloads

Important Changes to the NEC Impacting Motor Service Providers

Important Changes to the NEC Impacting Motor Service Providers

 

 

There are changes in the National Electrical Code that EASA members need to know about. View this webinar to learn:

  • The background behind these changes
  • The 2020 change impacting reconditioned motors
  • How the changes will be interpreted
  • What the changes mean for the electric motor service industry

Available Downloads

New ANSI/ASA Shaft Alignment Standard Adopted

New ANSI/ASA Shaft Alignment Standard Adopted

Gene Vogel
EASA Pump & Vibration Specialist

Shaft alignment is a critical step in the installation of rotating machinery, in a new installation or a repaired machine. Skipping or botching this step can decrease operating efficiency and shorten machine life. The procedure for aligning two rotating machines requires measuring their relative shaft positions and adjusting one or both machine cases, usually by shimming at the feet. Until recently, though, how closely the shafts need to be aligned was an open question. That changed with the publication of American National Standards Institute/Acoustical Society of America (ANSI/ASA) standard 2.75-17. Here is a summary of what it covers and how it will benefit users involved with shaft machinery alignment.

  • The need for a standard
  • Purpose and scope
  • Tolerances
  • Alignment principles
  • Alignment quality grades
  • Making machine moves

READ THE FULL ARTICLE

Principles of Medium & Large AC Motors, 1st Edition - IEC

Principles of Medium & Large AC Motors, 1st Edition - IEC

This version of Principles of Medium & Large AC Motors manual is now available to address applicable IEC standards and practices. This 360-page manual was developed by industry experts in Europe along with EASA's engineering team. (The "original" version of this book based on NEMA standards remains available as a separate document.)

This manual includes drawings, photos and extensive text and documentation on AC motors, including how they work, information on enclosures, construction on components and applications. Many of the principles included apply to all AC motors, especially those with accessories that are associated with larger machines in the past (such as encoders, RTDs, thermostats, space heaters and vibration sensors).

While the manual covers horizontal and vertical squirrel-cage induction motors in the 37 to 3,700 kW (300 to 5,000 hp) range, low- and medium-voltage, most of the principles covered apply to other sizes as well. 

This valuable instructional/resource manual is available in printed and downloadable versions, and focuses primarily on IEC motors.

Sections in the manual include:
(Download the PDF below for the complete Tables of Contents)

  • Motor nomenclature & definitions
  • Motor enclosures
  • Typical motor applications
  • Safety & handling considerations
  • Basic motor theory
  • Motor standards
  • Stators
  • Squirrel cage rotors
  • Shafts
  • Bearings & lubrication
  • Motor accessories & terminal boxes
  • Test & inspection procedures
  • Motor alignment, vibration & noise
  • Storage procedures
  • Synchronous machines

BUY A COPY FOR YOUR OFFICE

PRINTED BOOK DOWNLOADABLE PDF

This book is also available focusing on NEMA Standards — in both English and Español.

NEMA - English NEMA - Español

Available Downloads

Rewind Study 2020: The Results Are In

Rewind Study 2020: The Results Are In

The Effect of Repair/Rewinding on Premium Efficiency/IE3 Motors

Presented by Tom Bishop, P.E.
EASA Senior Technical Support Specialist

The EASA/AEMT Rewind Study was published in 2003, prior to the introduction of premium efficient (IE3) motors. The recently completed follow-up study evaluated motors with premium efficiencies to confirm that, as with the earlier study, the efficiency of these motors can be maintained during rewind and repair by using established good practices.

This webinar covers the results and the technical details of this most recent study.

It will benefit service center managers, customer service representatives, sales representatives, supervisors and technicians.

Available Downloads

See What’s New and Improved about IEEE 841 2021

See What’s New and Improved about IEEE 841 2021

Bill Finley
Technical Services Committee Member
Siemens Industry, Inc.

The recently published IEEE 841-2021 has been improved and brought up to date with the latest standards. The standard defines the requirements for severe-duty totally enclosed squirrel cage polyphase induction motors (Figure 1) in the range from 0.75 kW to 370 kW (1 hp to 500 hp) up to 4000 volts. This is intended for applications where performance and reliability are critical. It reduces installation and operating costs and eliminates the need for end-users to develop their own internal specification. In addition to defining a reliable product, it supports the quick availability of these products in inventory.

Available Downloads

The Effect of Repair/Rewinding on Premium Efficiency/IE3 Motors

The Effect of Repair/Rewinding on Premium Efficiency/IE3 Motors

2019 Rewind Study

This valuable publication explains the findings of a major study that analyzed the impact of repair/rewinding on the energy efficiency of Premium Efficiency/IE3 electric motors. This study was a follow up to a 2003 study.

The 2019 study reaffirms the results of the 2003 study.

The Effect of Repair/Rewinding on Premium Efficiency/IE3 MotorsAbstract
In response to various opinions about the feasibility of maintaining motor efficiency during repair, including replacement of the stator winding, the Electrical Apparatus Service Association (EASA) and the Association of Electrical and Mechanical Trades (AEMT) conducted two comprehensive rewind studies using third-party testing laboratories.

The results of the first study, which were published in 2003 (see Part 2 on Page 2-1 of this document), clearly showed that the efficiency of energy efficient and IE2 motors ranging from 7.5 hp to 200 hp (5.5 kW to 150 kW) can be maintained (and sometimes improved) if the stator is rewound using established good practice procedures.

The increasing use of premium efficient motors mandated by various countries led to a second rewind study in 2019, this time to determine if the efficiency of premium efficiency and IE3 motors can be maintained when they are rewound using the good practices described in the 2003 rewind study and ANSI/EASA AR100-2015: Recommended Practice for the Repair of Electrical Apparatus.

As with the 2003 study, the results of the 2019 rewind study that follow clearly show the answer is YES–with the average efficiency change for the entire test group falling within the range of accuracy for the test method (± 0.2%). In several instances, motor efficiency actually improved.

Overview of the Table of Contents

  • Part 1: 2019 Rewind Study–The Effect of Repair/Rewinding on Premium Efficiency/IE3 Motors
    • Objective
    • Products evaluated
    • Standards for evaluating losses
    • Third-party testing protocol
    • Results of efficiency tests on rewound motors
    • Conclusion
  • Part 2: 2003 Rewind Study – The Effect of Repair/Rewinding on Motor Efficiency
    • Objectives
    • Products evaluated
    • Standards for evaluating losses
    • Third-party testing protocol
    • IEEE Std. 12B test method: Input - output with loss segregation
    • Core loss testing
    • Results of efficiency tests on rewound motors
    • Significance of test results
    • Conclusion
Download a PDF of the complete study or the Executive Summary
for free using the links below.
Printed copies are also available in EASA's Online Store.

 

Available Downloads

The IECEx Certified Service Facilities Program

The IECEx Certified Service Facilities Program

The international Ex community (Ex equipment manufacturers, end users and regulators) have worked hard at providing standardization of technical requirements for Ex equipment and systems now reflected in a mature set of standards; work on standardizing the approaches to testing and certification is relatively young. The benefits of publishing international equipment standards can be overshadowed by the application of different testing and certification practices and systems. This can result in costly re-testing and re-certification as well as lost time-to-market for manufacturers and down time for plant operators.

While Underwriters Laboratories (UL), the Canadian Standards Association (CSA) and Equipment and Protective Systems intended for use in Potentially Explosive Atmospheres (ATEX) Directive have been seen as a solution to a converging common approach, the question remains: "What about companies and organizations that operate globally?"

Available Downloads

US Department of Energy Issues Final Rule for Testing Small Electric Motors

US Department of Energy Issues Final Rule for Testing Small Electric Motors

The US Department of Energy (DOE) has issued rulemaking on test procedures for small electric motors for more than a decade. The present “final rule,” effective February 3, 2021, is the culmination of those efforts. The final rule will be mandatory for product testing beginning July 6, 2021. If you want to view the complete detail of the final rule that was published in the Federal Register on January 4, 2021, it can be found at https://beta.regulations.gov/.  For further reading about the final rule, see this DOE site.

Usual & Unusual Service Conditions for Motors and Generators

Usual & Unusual Service Conditions for Motors and Generators

Tom Bishop. P.E.
EASA Senior Technical Support Specialist

What are the normal conditions for which a motor is designed? This is a question that does not often come up except when there is an issue with a motor application.   

The NEMA MG1 motor and generator standards provide details on this subject by defining usual and unusual service conditions. The IEC 60034-1 standard, “Rotating Electrical Machines, Part 1 Ratings and Performance,” also addresses some application conditions in clause 6, though not to the extent given in MG1. Our focus here will be on MG1 since it provides greater detail than IEC 60034-1.

Available Downloads

Vea las novedades y mejoras en la norma IEEE 841 2021

Vea las novedades y mejoras en la norma IEEE 841 2021

Bill Finley
Miembro del Comité Técnico de Servicios de EASA
Siemens Industry, Inc.

La norma IEEE 841-2021 recientemente publicada ha sido mejorada y actualizada con los últimos estándares. La norma define requisitos para los motores de inducción polifásicos de jaula de ardilla totalmente cerrados para uso en ambientes severos (Figura 1) en el rango de 0,75 kW a 370 kW (1 hp a 500 hp) hasta 4000 voltios. La norma está diseñada para aplicaciones en las cuales el rendimiento y la confiabilidad son críticas, reduce los costos de instalación y operación y elimina la necesidad de que los usuarios finales desarrollen sus propias especificaciones internas. Además de definir un producto confiable, apoya la disponibilidad rápida de estos productos en inventario.

Available Downloads