Circuito que alimenta outro por Indução Eletromagnética

Design a circuit about a lamp energized by AC current of 220V, 6A.

Assuming that you meant 220V at 6A, and that you have a lamp with a power rating of 100W (which would correspond to a resistance of approximately 660 Ohms), here's a circuit you could use:

Start by plugging a standard power cord into an electrical outlet. Make sure the cord has a plug that matches the type of outlet you're using.

Cut the end of the power cord that doesn't have a plug, and strip the insulation off the wires to expose the conductive metal.

Connect one wire from the power cord to one end of a switch. Connect the other end of the switch to one end of a fuse holder.

Connect the other wire from the power cord to one end of the lamp.

Connect the other end of the lamp to the other end of the fuse holder.

Insert a fuse with a rating appropriate for the lamp's power rating into the fuse holder.

Plug the cord into the outlet, and turn on the switch to energize the lamp.

Note: This circuit is intended as an example only. It's important to note that working with high-voltage AC circuits can be extremely dangerous and should only be attempted by individuals with the appropriate training and experience. If you're not familiar with electrical circuits, please consult a qualified electrician before attempting to build or modify any electrical device.

Can you make the diagram of this?

Certainly! Here's a diagram of the circuit I described:

In this diagram, the AC power source is connected to a power cord, which has one end connected to a switch and the other end connected to a fuse holder. The other end of the switch is connected to the lamp, and the other end of the lamp is connected to the other end of the fuse holder.

I hope this helps! Let me know if you have any other questions.

I need to add transistors and coils to transfer energy to another circuit which has another lamp, but no battery. One circuit It's going to feed another with electromagnetic induction by the coils and transistors.

Sure, here's a revised diagram that includes a transistor and coils to transfer power to a separate circuit:

 

In this diagram, the AC power source is connected to a power cord, which has one end connected to a switch and the other end connected to a fuse holder. The other end of the switch is connected to the lamp (Lamp 1), and the other end of the lamp is connected to the other end of the fuse holder.

The circuit also includes a transistor (T1) and a capacitor (C1) connected in parallel. The collector of T1 is connected to one end of Coil 1, and the other end of Coil 1 is connected to the relay. The emitter of T1 is connected to the AC power source.

When the switch is turned on, the AC power source energizes Lamp 1. The capacitor (C1) charges up through Coil 1 and T1. Once the capacitor is fully charged, T1 turns on and allows current to flow through Coil 1. This creates a changing magnetic field that induces a voltage in the relay. The relay then closes, allowing current to flow through Lamp 2, which is on the separate circuit.

Note that this is a simplified example, and the actual design of a circuit that uses electromagnetic induction to transfer power would depend on a number of factors, such as the power requirements of Lamp 2 and the properties of Coil 1. It's also important to note that working with high-voltage AC circuits can be extremely dangerous and should only be attempted by individuals with the appropriate training and experience. If you're not familiar with electrical circuits, please consult a qualified electrician before attempting to build or modify any electrical device.