Wikibooks: Physics Course/Electromagnetism/ElectroMagnet/Coil of several Turns

=ElectroMagnet/Coil of several Turns= When a coil of several turns is connected with Electric source Magnetic Field exist and has the same form as Magnetic Field of Natural Magnet. Current conducting Coil of several turns generates Electromagnetic Field of expanding Elliptical lines. =Characteristic...

Full description

Bibliographic Details
Format: Book
Language:English
Subjects:
North Pole
South pole
Online Access:https://en.wikibooks.org/wiki/Physics_Course/Electromagnetism/ElectroMagnet/Coil_of_several_Turns
id ftwikibooks:enwikibooks:44548:250048
record_format openpolar
spelling ftwikibooks:enwikibooks:44548:250048 2023-12-31T10:21:02+01:00 Wikibooks: Physics Course/Electromagnetism/ElectroMagnet/Coil of several Turns https://en.wikibooks.org/wiki/Physics_Course/Electromagnetism/ElectroMagnet/Coil_of_several_Turns eng eng Book ftwikibooks 2023-12-02T18:08:17Z =ElectroMagnet/Coil of several Turns= When a coil of several turns is connected with Electric source Magnetic Field exist and has the same form as Magnetic Field of Natural Magnet. Current conducting Coil of several turns generates Electromagnetic Field of expanding Elliptical lines. =Characteristics of Electromagnets= =Magnetic Poles= The polarities of the electric source form a Magnetic Pole. The Positive Terminal corresponds to North Pole and Negative Terminal corresponds to South Pole. =Magnetic Field= Magnetic Field is made up from Expanding Magnetic Field Lines running from North Pole to South Pole. The Magnetic Field Strength is directly proportional to Current in the coil and the inductance of the coil and can be calculated by mathematical formula B = L I Where I is Current measured in Ampere L is Inductance measured in Henri =Magnetic Field Force= The Magnetic Field Force is directly proportional to Magnetic Field Strength and the length of the Magnetic Field Line and can be calculated by mathematical formula F = B l =Magnetic Voltage Induction = Magnetic Voltage Induction on a Coil B = L I \frac{dB}{dt} = L \frac{dI}{dt} + I \frac{dL}{dt} = L \frac{dI}{dt} + 0 \frac{dB}{dt} = L \frac{dI}{dt} Change of Magnetic Field strength is proportional to Inductance of the coil and change in Current flow through the coil Magnetic Voltage Induction on a Coil s Turn \phi = N B \frac{d\phi}{dt} = N \frac{dB}{dt} + B \frac{dN}{dt} = N \frac{d\phi}{dt} + 0 \frac{d\phi}{dt} = N \frac{d\phi}{dt} Change of Magnetic Flux strength is proportional to Inductance of the turns and change in Magnetic Flux through the coil BookCat Book North Pole South pole WikiBooks - Open-content textbooks
institution Open Polar
collection WikiBooks - Open-content textbooks
op_collection_id ftwikibooks
language English
description =ElectroMagnet/Coil of several Turns= When a coil of several turns is connected with Electric source Magnetic Field exist and has the same form as Magnetic Field of Natural Magnet. Current conducting Coil of several turns generates Electromagnetic Field of expanding Elliptical lines. =Characteristics of Electromagnets= =Magnetic Poles= The polarities of the electric source form a Magnetic Pole. The Positive Terminal corresponds to North Pole and Negative Terminal corresponds to South Pole. =Magnetic Field= Magnetic Field is made up from Expanding Magnetic Field Lines running from North Pole to South Pole. The Magnetic Field Strength is directly proportional to Current in the coil and the inductance of the coil and can be calculated by mathematical formula B = L I Where I is Current measured in Ampere L is Inductance measured in Henri =Magnetic Field Force= The Magnetic Field Force is directly proportional to Magnetic Field Strength and the length of the Magnetic Field Line and can be calculated by mathematical formula F = B l =Magnetic Voltage Induction = Magnetic Voltage Induction on a Coil B = L I \frac{dB}{dt} = L \frac{dI}{dt} + I \frac{dL}{dt} = L \frac{dI}{dt} + 0 \frac{dB}{dt} = L \frac{dI}{dt} Change of Magnetic Field strength is proportional to Inductance of the coil and change in Current flow through the coil Magnetic Voltage Induction on a Coil s Turn \phi = N B \frac{d\phi}{dt} = N \frac{dB}{dt} + B \frac{dN}{dt} = N \frac{d\phi}{dt} + 0 \frac{d\phi}{dt} = N \frac{d\phi}{dt} Change of Magnetic Flux strength is proportional to Inductance of the turns and change in Magnetic Flux through the coil BookCat
format Book
title Wikibooks: Physics Course/Electromagnetism/ElectroMagnet/Coil of several Turns
spellingShingle Wikibooks: Physics Course/Electromagnetism/ElectroMagnet/Coil of several Turns
title_short Wikibooks: Physics Course/Electromagnetism/ElectroMagnet/Coil of several Turns
title_full Wikibooks: Physics Course/Electromagnetism/ElectroMagnet/Coil of several Turns
title_fullStr Wikibooks: Physics Course/Electromagnetism/ElectroMagnet/Coil of several Turns
title_full_unstemmed Wikibooks: Physics Course/Electromagnetism/ElectroMagnet/Coil of several Turns
title_sort wikibooks: physics course/electromagnetism/electromagnet/coil of several turns
url https://en.wikibooks.org/wiki/Physics_Course/Electromagnetism/ElectroMagnet/Coil_of_several_Turns
genre North Pole
South pole
genre_facet North Pole
South pole
_version_ 1786831680241139712

Similar Items