Electric motors are mechanical devices that are designed to convert electrical energy into mechanical energy. The mechanical energy generated by these devices is in turn used to drive other devices such as engines to generate motion. In fact, any device that can be used to convert electrical energy into mechanical energy can be referred to as an electric motor. The importance of these devices in modern life continues to increase. When in need of Electric Motors Toronto should be visited.
Motors exist in a variety of commercial and household appliances and machines like computers, printers, machine tools, fax machines, and video cassette recorders among others. To name a few, automobiles, printing presses, water pumping stations, dishwashers, subway systems, and vacuum cleaners are other appliances or places that make use of these devices. All the above-named appliances have different sizes of motors and produce different quantities of power.
The Amperes law is the basic law behind the functioning of motors. According to the Amperes law, the generation of a magnetic field occurs around a wire that is conducting an electric current. Magnetic field generated has a south and north pole which repel and attract the wire as it moves around a core. The rotational movement produced by motors is generated by this behavior.
Either DC or AC current can be used to run motors. The direction of the current flow changes back and forth when Ac current is used. This occurs at a very speedy and regular rate. The direction is changed by AC current at the rate of 60 times per second and that is how AC current is designed in America. One may also denote this frequency as 60 hertz because it is the SI unit for frequency.
The change on the flow of current implies that the magnetic field produced around the loop also changes direction after every 1/60 of a second. It is this change in direction of the magnetic field that causes the wire loop contained in all motors to spin around its axis. This change in spinning motion of a motor is usually powerful enough to power a wide range of devices as mentioned before.
A typical electric motor is composed of numerous crucial components. The stator, is one of the most critical parts. The stator is generally stationery and is manufactured from magnetic substances and electric conductors that produce magnetic fields of the specified form. The second part is the rotor, that is composed of magnetic and electrical conductors that produce magnetic fields. These fields normally interact with the fields produced by the stator in a specific way.
The rotor is the component that produces the mechanical energy that motors produce. The rotor is also connected to the moving component of the rotor, which connects to machine that is being driven. Thus, the electricity that is supplied to the motor is usually used to generate magnetic fields in both the rotor and motor.
DC current was used by the initial commercial motors that were made. The reason was that the invention of AC current had not been done at the point. Individuals made use of these motors for both high-power and low-power applications. The invention of AC power made DC motors to become very unpopular.
Motors exist in a variety of commercial and household appliances and machines like computers, printers, machine tools, fax machines, and video cassette recorders among others. To name a few, automobiles, printing presses, water pumping stations, dishwashers, subway systems, and vacuum cleaners are other appliances or places that make use of these devices. All the above-named appliances have different sizes of motors and produce different quantities of power.
The Amperes law is the basic law behind the functioning of motors. According to the Amperes law, the generation of a magnetic field occurs around a wire that is conducting an electric current. Magnetic field generated has a south and north pole which repel and attract the wire as it moves around a core. The rotational movement produced by motors is generated by this behavior.
Either DC or AC current can be used to run motors. The direction of the current flow changes back and forth when Ac current is used. This occurs at a very speedy and regular rate. The direction is changed by AC current at the rate of 60 times per second and that is how AC current is designed in America. One may also denote this frequency as 60 hertz because it is the SI unit for frequency.
The change on the flow of current implies that the magnetic field produced around the loop also changes direction after every 1/60 of a second. It is this change in direction of the magnetic field that causes the wire loop contained in all motors to spin around its axis. This change in spinning motion of a motor is usually powerful enough to power a wide range of devices as mentioned before.
A typical electric motor is composed of numerous crucial components. The stator, is one of the most critical parts. The stator is generally stationery and is manufactured from magnetic substances and electric conductors that produce magnetic fields of the specified form. The second part is the rotor, that is composed of magnetic and electrical conductors that produce magnetic fields. These fields normally interact with the fields produced by the stator in a specific way.
The rotor is the component that produces the mechanical energy that motors produce. The rotor is also connected to the moving component of the rotor, which connects to machine that is being driven. Thus, the electricity that is supplied to the motor is usually used to generate magnetic fields in both the rotor and motor.
DC current was used by the initial commercial motors that were made. The reason was that the invention of AC current had not been done at the point. Individuals made use of these motors for both high-power and low-power applications. The invention of AC power made DC motors to become very unpopular.
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