A running iron uses the same power as nine 100 watt bulbs.
In the home, depending upon where you live, the service voltage is fixed at either 110 or 220 volts. Various appliances and devices require different amounts of energy, of course. Since the voltage (or pressure of delivery) is the same, the current (volume of delivery) is what changes.
In round numbers, a clothes iron might draw 10 amperes of current at 110 volts, or 1100 watts of power. A light bulb might draw 1 ampere of current at the same voltage.
It's easy to see that the iron will draw far more current than even an inefficient incandescent light bulb.
Five electric appliances that make use of the heating effects of electric current are electric stoves, electric kettles, hair dryers, toaster ovens, and space heaters. These appliances contain heating elements that convert electrical energy into heat energy through the process of resistive heating. The heat generated by the electric current is then used for cooking, boiling water, drying hair, toasting bread, or heating a room.
A coil with an iron core and a movable iron bar constitutes an electromagnet. When an electric current flows through the coil, it generates a magnetic field that attracts the iron bar, causing it to move. This device is commonly used in various applications such as in electric motors and doorbells.
An electromagnet can attract steel and iron due to electricity. When an electric current flows through the coil of wire in an electromagnet, it creates a magnetic field that can attract ferromagnetic materials like steel and iron. The strength of the magnetic field can be controlled by adjusting the amount of electric current flowing through the electromagnet.
The electrons in the current have a lot of energy due to the tiny electric force on each one and the very large number of electrons involved. As they move from atom to atom in a metal conductor, some of this energy redistributes to the metal atoms. This energy causes the conductor atoms to move faster, which means they get hotter, and the heat flows to the surface of the iron.
1.Stroking it with a magnet 2. Applying a current to a coil of wire wrapped around the iron
1.7amp
When electric current is run through a solenoid coil wrapped around a chunk of iron, the iron becomes magnetized. The magnetic field produced by the electric current aligns the magnetic domains within the iron, creating a temporary magnet.
Here are some possible answers: a) If you hold a compass close to a wire you may see the needle move. How much it moves depends on the strength of the current flowing in the wire. If the needle doesn't move then there may be three explanations: 1) No direct current was flowing in the wire OR 2) a direct current was flowing but it was too weak to make the compass needle move OR 3) there might have been a current but it was an alternating current changing so fast that the needle did not seem to move. b) If the bulb in an electric circuit was lit but then blows, it may mean one of two things 1) the current was switched off so the bulb went out OR 2) the bulb just died, in which case any current that was flowing in the bulb's circuit would stop. c) when the plug of an iron is placed into a socket, if it warms up then a current must be flowing from the socket to the iron. But before the iron was plugged-in, no current was flowing. Now you work out which of those answers to this question is the right one!
To calculate current flow, use the formula: Current (I) = Power (P) / Voltage (V). Substituting the given values, the current flowing through the electric iron would be I = 1200W / 240V = 5A.
an electromagnet
Electric current in a coil can induce magnetism in an iron nail,place near the coil.when the electric current is cut off the magnetism in the iron nail disappears.the magnetism in the nail exist so long as there is electric current in the coil.this is an electromagnet.
The iron bar would become magnetized when inserted into a wire coil carrying an electric current. This is because the electric current induces a magnetic field in the coil, which in turn magnetizes the iron bar.
Iron oxide is a poor conductor of electricity, so electric current does not typically pass through it easily. Iron oxide is considered to be an insulator, which means it does not facilitate the flow of electric charges in the same way that conductive materials, like metals, do.
Alternating current flows through a flat iron.
Electricity having AC current.
Yes, cast iron can be made into an electromagnet by wrapping it with a coil of wire and passing an electric current through the wire. When the electric current flows through the coil, it creates a magnetic field in the cast iron, turning it into an electromagnet.
No, iron is a conductor of electricity and not an insulator. Electric current can flow easily through iron, which is why it is commonly used in making electrical circuits and components.