{"type":"video","version":"1.0","html":"<iframe src=\"https://www.loom.com/embed/f4cff6748574460dbc4bfae9eb35aa71\" frameborder=\"0\" width=\"1920\" height=\"1440\" webkitallowfullscreen mozallowfullscreen allowfullscreen></iframe>","height":1440,"width":1920,"provider_name":"Loom","provider_url":"https://www.loom.com","thumbnail_height":1440,"thumbnail_width":1920,"thumbnail_url":"https://cdn.loom.com/sessions/thumbnails/f4cff6748574460dbc4bfae9eb35aa71-6128c77201b43846.gif","duration":255.709,"title":"Deriving the EMF Equation of an Alternator ⚡","description":"In this video, I derived the EMF equation of an alternator, focusing on key variables such as phi, p, ns, and z. I explained how the average induced EMF is calculated, leading to the formula 4.44 phi f t for the RMS value of the induced EMF. I also discussed the implications of full pitched and concentrated windings, noting that for short pitched and distributed windings, the RMS value adjusts accordingly. Please review the calculations and ensure you understand the relationships between these variables. Your feedback or questions would be appreciated as we move forward with this topic."}