A power supply has an open-circuit voltage of 40.0 V and an internal resistance of 2.00 Ω. It is used to charge two storage batteries connected in series, each having an emf of 6.00 V and internal resistance of 0.300 Ω. If the charging current is to be 4.00 A,

(a) what additional resistance should be added in series?

At what rate does the internal energy increase in

(b) the supply,

(c) in the batteries, and

(d) in the added series resistance?

(e) At what rate does the chemical energy increase in the batteries?

 

A power supply has an open circuit voltage of 40.0 V and internal resistance of . It is used to charge two storage batteries connected in series, each having an emf of 6.0 V and internal resistance of . If the charging current is to be 4.0 A,

(a) What additional resistance should be added in series? 

At what rate the internal energy increases in (b) the supply,(c) in the batteries, and (d) in the added series resistance?

(e) At what rate does the chemical energy increases in the batteries?

25.46 " A typical small flashlight contains two batteries, each having an emf of 1.5 V, connected in series with a bulb having resistance 17 1. (a) If the internal resistance of the batteries is negligible, what power is delivered to the bulb? (b) If the batter- ies last for 5.0 h, what is the total energy delivered to the bulb? (c) The resistance of real batteries increases as they run down. If the initial internal resistance is negligible, what is the combined internal resistance of both batteries when the power to the bulb has decreased to half its initial value? (Assume that the resistance of the bulb is constant. Actually, it will change somewhat when the cur- rent through the filament changes, because this changes the temper- ature of the filament and hence the resistivity of the filament wire.)

A real battery is not just an emf, we can model a real 1.5V battery as a 1.5 V emf in series with a resistor known as the internal resistance. A typical battery has 1.0 Ω internal resistance due to imperfections that limit the current through the battery. When there's no current through the battery, and thus no voltage drop across the internal resistance, the potential difference between its terminals is 1.5 V, the value of the emf. Suppose the terminals of this battery are connected to a 3 Ω resistor.

what fraction of the battery's power is dissipated by the internal resistance?