If energy s not spent than why do we have to keep recharging the battery with the alternator?
I agree that flow is present on both sides of the circuit, but the electrical energy (pressure) is being converted to movement (fans) or illumination.
When you connect things in series, the amount of available energy drops for each item.
I am not an electrical engineer by any means, but I have had switches get hot while in the positive side of the circuit, and stay cool when moved to the ground side. There are plenty of times that things have to be switched on the hot side (starter) because they ground through the case. It definitely is ok, you just need to be sure to use a switch rated for the amperage and voltage.
Both of your statements are true, but I'm talking about current flow. Energy is a static concept, it's like a weight hanging over your head. What's driving the fan is the
release of energy, which we call
power. Power is the rate of energy release. People often abuse these terms (I even did so in my 3yr old example to keep things dirt simple), but they are not the same thing. DC circuits operate kinda like water flowing in a hose. The voltage of a circuit is the pressure of the water, how hard it's pushing on the hose. The power is the total rate of water flow, how many buckets you can fill in a minute. The current, which is what I was talking about, is the speed of the water flowing through the pipe. This is what makes wires hot, when you draw more current (which is a function of power and voltage) through the wire than they can safely handle. This is how wires fail and also how electrical fires start.
My comment was that, regardless of where you place the switch, in a single circuit, the current is equal no matter where you put the switch. You can put the switch on the positive leg, the negative leg, or somewhere in Kazakhstan, the current will always be the same. Going back to the hose example, if you have more water flowing into the hose than you have flowing out of it, you will have a serious problem very quickly. Wires don't "store" electrons (at least, not until you get into AC and RF circuits), they always flow through them and back to the positive side of the battery. If you split the wire and drive some second circuit, then you will have a balance of current flowing through each circuit (and there are a few simple laws governing that if you wanna get into circuit theory). But moving a switch from one side to the other does not affect the flow rate any more than moving the hose valve from the end of the hose to the middle. It's still the same hose driven by the same water pressure, the location of the switch does not change that. It just changes how much of the hose is always pressurized vs. only being pressurized when the valve is open.
If your switch magically stopped overheating when you moved it from one leg to the other, my best guess is that you had a crummy connection (high resistance) that was fixed when you rearranged the circuit. Because the math doesn't work out that way if location is the only thing you changed.