Physics, asked by TheHoneyBabe, 1 month ago

A cell of emf ‘’ and internal resistance ‘r’ sends current 1.0A when it is connected to an

external resistance 1.9Ω. But it sends 0.5A when it is connected to an external resistance of

3.9Ω. Calculate the values of and r.
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Answers

Answered by XItzShinchanNoharaX
1

Answer:

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Answered by gyaneshwarsingh882
0

Answer:

Explanation:

When the circuit is closed, the resulting current not only flows through the external circuit, but through the source (cell) itself. The cell have an internal resistance, which causes an internal voltage drop, slightly reducing the voltage across the terminals. The larger the current, the larger the internal voltage drop, and the lower the terminal voltage.

The current in the circuit is calculated from the formula I=  

R+r

ε

where,

ε- emf of the cell

R- external resistance

r- internal resistance of the cell.

When the cell is connected to the resistance of 1.9 ohms the current relation is given as  

That is, 1.0=  

1.9+r

e

.Thatis,aftersimplification,e−r=1.9−eqn1.

When the cell is connected to the resistance of 3.9 ohms the current relation is given as  

That is, 0.5=  

3.9+r

e

.Thatis,aftersimplification,e−0.5r=1.95−eqn2.

Solving the linear eqn 1 and eqn 2 for the variables e and r, we get e=2.0 V.

Substituting the value of e in eqn 1, the variable r is determined to be 0.1 ohms.

Hence, the emf and the internal resistance of the cell are 2.0 V and 0.1 ohms respectively.

I=1A

R=1.9ohm

ϵ=I(R+r)=I(1.9+r)

ϵ=1.9+r   ... (1)

In second case

I=0.5A, R=3.9ohm

ϵ=I(R+r)=0.5(3.9+r)

ϵ=1.95+0.5r   ... (2)

From eq. (1) and (2),

1.9+r=1.95+0.5r

r=  

0.5

0.005

=0.1Ω

Substituting value of r

ϵ=19+r=19+0.1=2V

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