In other words if there is too much load on the circuit (parallel) would the voltage drop?
and does the 'Voltage Stabilizer' keeps the voltage up in that situation?
and does the 'Voltage Stabilizer' keeps the voltage up in that situation?
-
Your power source ALWAYS has some kind of built-in limit to how much power it can supply.
if the power demands of the circuit go up (resistance goes down) then the voltage will, at some point, drop.
"Power Regulators" or "Voltage Stabilizers" have that limit clearly listed, for example, they might says "5 volts at 1 Amp". In this case 5 volts across 5 ohms IS 1 amp, so if the resistance drops below 5 volts, the voltage may drop. The same principal applies no matter what your voltage and current and current is. if the "load" exceeds the capabilities of the power source, the voltage will drop.
if the power demands of the circuit go up (resistance goes down) then the voltage will, at some point, drop.
"Power Regulators" or "Voltage Stabilizers" have that limit clearly listed, for example, they might says "5 volts at 1 Amp". In this case 5 volts across 5 ohms IS 1 amp, so if the resistance drops below 5 volts, the voltage may drop. The same principal applies no matter what your voltage and current and current is. if the "load" exceeds the capabilities of the power source, the voltage will drop.
-
Can Voltage drop across Resistances connected in Parallel, if Resistances are too low?
In other words if there is too much load on the circuit (parallel) would the voltage drop?
and does the 'Voltage Stabilizer' keeps the voltage up in that situation?
In a parallel circuit, like our homes have, the voltage = 120 V
As the resistance is decreased, the current is increased.
The copper wire leading to the resistor has a very low resistance.
As the current increases, the temperature of the wires leading to the resistor increases. This means some of the electric energy is being wasted as heat energy.
The volt is defined as the value of the voltage across a conductor when a current of one ampere dissipates one watt of power in the conductor.
As the current flows through the copper wires, some of the energy provided by voltage is wasted. This means the voltage has decreased as the current flows through the copper wires. This means there is less voltage for the appliance.
As more lights and heaters and other appliances are turned on, the equivalent resistance decreases, causing the current flow in the wires leading to the appliances to increase. If the circuit breaker does not shut off the circuit, the temperature of the wires will continue to increase. This can cause a house to burn.
Yes, the voltage can drop across Resistances connected in Parallel, if Resistances are too low!
In other words if there is too much load on the circuit (parallel) would the voltage drop?
and does the 'Voltage Stabilizer' keeps the voltage up in that situation?
In a parallel circuit, like our homes have, the voltage = 120 V
As the resistance is decreased, the current is increased.
The copper wire leading to the resistor has a very low resistance.
As the current increases, the temperature of the wires leading to the resistor increases. This means some of the electric energy is being wasted as heat energy.
The volt is defined as the value of the voltage across a conductor when a current of one ampere dissipates one watt of power in the conductor.
As the current flows through the copper wires, some of the energy provided by voltage is wasted. This means the voltage has decreased as the current flows through the copper wires. This means there is less voltage for the appliance.
As more lights and heaters and other appliances are turned on, the equivalent resistance decreases, causing the current flow in the wires leading to the appliances to increase. If the circuit breaker does not shut off the circuit, the temperature of the wires will continue to increase. This can cause a house to burn.
Yes, the voltage can drop across Resistances connected in Parallel, if Resistances are too low!
-
Yes!
I've seen it, where many light bulbs are connected in parallel and each one glows less and less, the more parallel branches are added.
I was told it was to do with the internal resistance of the power source (In my case, a big cell) and that increases as more current is demanded of the cell.
I've seen it, where many light bulbs are connected in parallel and each one glows less and less, the more parallel branches are added.
I was told it was to do with the internal resistance of the power source (In my case, a big cell) and that increases as more current is demanded of the cell.
-
yes