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.

Article

Voltage stress: Not as simple as it sounds

  • August 2007
  • Number of views: 7887
  • Article rating:

Chuck Yung
EASA Technical Support Specialist

Have you ever wondered how a lightning rod works? That small rod atop a large building extends less than a yard (meter) above the building. Yet the lightning is attracted to that sacri­ficial rod rather than to the building. If you have not wondered about lightning rods, I'll bet you are curious about what lightning rods could possibly have to do with electric motors. 

The common denominator between electrical windings and lightning rods is geometry. Lightning strikes the light­ning rod because the voltage stresses are higher between the pointed rod and the cloud than between that same cloud and the building. The pointed shape raises the potential voltage stress at the end of the lightning rod. For the same reason, we often see winding failures affected by the geometry of a coil, a connection, or a sharp corner within a stator frame. 

When the subject of voltage stress comes up, many people assume that the voltage stress does not exceed the line voltage of the winding. Our early as­sumptions were that voltage stresses followed a linear pattern and could simply be calculated by the relation­ship of circuits, coils and turns per coil. 

Available Downloads



Categories: Technical topics
0Upvote 0Downvote
Print