Yes, magnets can affect electric currents and vice versa. Moving electric charges create magnetic fields, and magnetic fields can induce electric currents in conductors. This relationship is fundamental to electromagnetism and is used in many technologies, such as electric motors and generators.
The size of a magnet does not directly affect electricity. However, larger magnets can produce stronger magnetic fields, which can impact the behavior of electric currents in nearby conductors, leading to phenomena like electromagnetic induction.
An electric motor is made up of magnets .. some electric induced magnets , some permanent magnets . the electric magnets are arranged so that when the power is turned on they activate in a series of pulsing magnets.. this pulsing causes the magnets in the core and the magnets in the body of the motor to repel and attract as magnets will do .. this repelling and attracting causes the magnets to try and chase each other around .. this action is turning the core of the motor and producing the rotating action expected from an electric motor
In a typical electric generator, there are magnets that help generate electricity through the process of electromagnetic induction. These magnets create a magnetic field that interacts with the coils of wire in the generator to produce an electric current.
No, permanent magnets are not produced by electric currents. They are made from materials that are magnetized and retain their magnetic properties without the need for external electric currents.
Electric charges and magnets can interact through electromagnetic forces. Moving electric charges create magnetic fields, while magnets can exert forces on moving electric charges. This interaction is fundamental to how electromagnets work and plays a key role in many technological applications such as electric motors and generators.
Electricity affects magnetism because it can determine the direction of a current. A number of magnets are just iron bars with an electric current circulating around it.
A magneto is an electric generator that is powered by magnets. Some factors that will affect its performance include their power source as well as the reliability.
The size of a magnet does not directly affect electricity. However, larger magnets can produce stronger magnetic fields, which can impact the behavior of electric currents in nearby conductors, leading to phenomena like electromagnetic induction.
Yes, an electric egg beater will have some kind of magnets in it. These may be permanent magnets, or may be electromagnets, but the motor in the appliance will have to have some kind of magnets in it to operate on electricity.
An electric motor is made up of magnets .. some electric induced magnets , some permanent magnets . the electric magnets are arranged so that when the power is turned on they activate in a series of pulsing magnets.. this pulsing causes the magnets in the core and the magnets in the body of the motor to repel and attract as magnets will do .. this repelling and attracting causes the magnets to try and chase each other around .. this action is turning the core of the motor and producing the rotating action expected from an electric motor
In a typical electric generator, there are magnets that help generate electricity through the process of electromagnetic induction. These magnets create a magnetic field that interacts with the coils of wire in the generator to produce an electric current.
Yes, they do, but their affect is minimal. Magnets with their magnet fields affect inductors profoundly, but don't do to much to capacitors.
no
yes temp does affect the strength of magnets. The cooler the magnet the stronger it gets.
No, permanent magnets are not produced by electric currents. They are made from materials that are magnetized and retain their magnetic properties without the need for external electric currents.
magnet moves cause all magnets have an electric field around it]
Electric charges and magnets can interact through electromagnetic forces. Moving electric charges create magnetic fields, while magnets can exert forces on moving electric charges. This interaction is fundamental to how electromagnets work and plays a key role in many technological applications such as electric motors and generators.