Answer:
1.45 Ω
Explanation:
Resistance of each bulb
P = V²/R.............. Equation 1
Where P = power, V = Voltage, R = Resistance.
R = V²/P............ Equation 2
Given: V = 12 V, P = 4 W
R = 12²/4
R = 36 Ω
Since the bulbs are connected in parallel,
Total resistant is given as
Rt = RR'/(R+R')
Where Rt = Total resistance
Rt = (36×36)/(36+36)
Rt = 18 Ω
The current flowing through the Circuit is given as
I = V/R................... Equation 3
Where I = current.
Note: The Voltage delivered to the bulb is 11.1 V.
Given: V = 11.1 V, R = 18 Ω
Substitute into equation 3
I = 11.1/18
I = 0.62 A.
Finally,
Lost Voltage = internal resistance×current
E-V = r×I................... Equation 4
Where E = E.M.F of the battery, r = internal resistance.
Make r the subject of the equation,
r = (E-V)/I................ Equation 5
Given: E = 12.0 V, V = 11.1 V, I = 0.62 A.
Substitute into equation 5
r = (12-11.1)/0.62
r = 1.45 Ω
Hence the internal resistance = 1.45 Ω
Internal resistance of the battery is 1.45Ω
The bulbs are connected in parallel. This means that the same voltage will pass across them. And since they both have the same power rating, then the values of the resistance in the two bulbs are the same.
(1) Get the resistance of each of the bulbs, using the following relation between power(P), voltage (V) and resistance (R);
P = [tex]\frac{V^{2} }{R}[/tex] -----------------(i)
Given;
P = 4W
V = 12V
Substitute for the values of P and V in equation (i)
4 = [tex]\frac{12^{2} }{R}[/tex]
Making R the subject of the formula and solving gives;
R = 144/4 = 36Ω
Therefore the resistance in each of the bulbs is 36Ω
(2)Calculate the effective resistance (Rₓ) in the parallel connection.
[tex]\frac{1}{R_{X} }[/tex] = [tex]\frac{1}{R_{1} }[/tex] + [tex]\frac{1}{R_{2} }[/tex]
Where;
R₁ and R₂ are values of resistance in the two bulbs = 36Ω each
Substitute the values of R₁ and R₂ into equation (ii)
[tex]\frac{1}{R_{X} }[/tex] = [tex]\frac{1}{36}[/tex] +
Solve for R[tex]_{X}[/tex]
Rₓ = 18Ω
(3) Calculate the total current (I) flowing through the circuit using the following relation;
=> V = I x Rₓ
Where;
V is the terminal voltage = 11.1V
Rₓ is the effective resistance in the circuit = 18Ω
=> 11.1 = I x 18
=> I = 11.1 / 18
=> I = 0.62A
(4) Calculate the internal resistance of the battery
The emf (E) is related to the lost voltage and terminal voltage by the following relation;
E = Terminal Voltage + Lost Voltage
But,
Lost Voltage = I x r
Where;
I = current flowing through.
r = internal resistance.
=> E = V + Ir ------------------(iii)
Where;
E = 12V
V = terminal voltage = 11.1V
I = 0.62A
Substitute these values into equation (iii)
=> 12 = 11.1 + 0.62r
=> 12 = 11.1 + 0.62r
=> 0.62r = 12 - 11.1
=> 0.62r = 0.9
=> r = 0.9 / 0.62
=> r = 1.45Ω
Therefore, the internal resistance is 1.45Ω
