Three rods of material x and three of material y are connected as shown in figure- All the rods are identical in length and cross-sectional area- If the end A is maintained at 60-C and the junction E at 10 - C- calculate the temperature of the junction B- The thermal conductivity of x is 800 W-M- - C and that of y is 400 W-M- - C 600C-500C-200C-400C-

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Thermal Resistance

Three rods of...

Question

Three rods of material x and three of material y are connected as shown in figure. All the rods are identical in length and cross-sectional area. If the end A is maintained at 60 $^{\circ}$ C and the junction E at 10 $^{\circ}$ C, calculate the temperature of the junction B. The thermal conductivity of x is 800 W/M- $^{\circ}$ C and

that of y is 400 W/M- $^{\circ}$ C

50⁰C

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20⁰C

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60⁰C

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40⁰C

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Solution

The correct option is D
40⁰C

It is clear from the symmetry of the figure that the points C and D are equivalent in all respect and hence, they are at the same temperature, say $θ$ . No heat will flow through the rod CD. We can, therefore, neglect this rod in further analysis. Let l and A be the length and the area of cross-section of each rod. The thermal resistances of AB, BC and BD are equal. Each has a value

$R_{1} = \frac{1}{K_{x}} \frac{l}{A}$ ........(i)

Similarly, thermal resistance of CE and DE are equal, each having a value $R_{2} = \frac{1}{K_{y}} \frac{l}{A}$ ...(ii)

As the rod CD has no effect, we can say that the rods BC and CE are joined in series. Their equivalent thermal resistance is

$R_{3} = R_{B C} + R_{C E} = R_{1} + R_{2}$ .

Also the rods BD and DE together have an equivalent thermal resistance $R_{4} = R_{B D} + R_{D E} = R_{1} + R_{2}$ .

The resistances $R_{3} a n d R_{4}$ are joined in parallel and hence their equivalent thermal resistance is given by

$\frac{1}{R_{5}} = \frac{1}{R_{3}} + \frac{1}{R_{4}} = \frac{2}{R_{3}}$

or $R_{5} = \frac{R_{3}}{2} = \frac{R_{1} + R_{2}}{2}$

This resistance $R_{5}$ is connected in series with AB. Thus, the total arrangement is equivalent to a thermal resistance

$\frac{R_{1} + R_{2}}{2} = \frac{3 R_{1} + R_{2}}{2}$

$R = R_{A B} + R_{5} = R_{1} +$

Figures below shows the successive steps in this reduction.

The heat current through A is.

$i = \frac{θ_{A} - θ_{E}}{R} = \frac{2 (θ_{A} - θ_{E})}{3 R_{1} + R_{2}}$

The current passes through the rod AB. We have

$i = \frac{θ_{A} - θ_{B}}{R_{A B}}$

or, $θ_{A} - θ_{B} = (R_{A B}) i$

$= R_{1} \frac{2 (θ_{A} - θ_{E})}{3 R_{1} + R_{2}}$

Putting from (i) and (ii),

$θ_{A} - θ_{B} = \frac{2 K_{y} (θ_{A} - θ_{E})}{K_{x} + 3 K_{y}}$

$= \frac{2 \times 400}{800 + 3 \times 400} \times 50^{\circ} C = 20^{\circ} C$

or, $θ_{B} = θ_{A} - 20^{\circ} C = 40^{\circ} C$ .

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Three rods of material x and three of material y are connected as shown in figure. All the rods are identical in length and cross-sectional area. If the end A is maintained at 60 $^{\circ}$ C and the junction E at 10 $^{\circ}$ C, calculate the temperature of the junction B. The thermal conductivity of x is 800 W/M- $^{\circ}$ C and