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Two metal cubes with 3 cm- edges of copp...

Two metal cubes with 3 cm- edges of copper and aluminium are arranged as shown in figure. Find
(a)the total thermal current from one reservoir to the other
(b) the ratio of the thermal current carried by the copper cube to that carried by the aluminium cube. Thermal conductivity of copper is 401 `W//m-K` and that of aluminium id 237 `W//m-K` .

Text Solution

Verified by Experts

The correct Answer is:
A, B, C, D
(a) Thermal resistance of aluminium cube, `R_1 = l/(KA)`
or `R_1 = (3.0 xx (10^-2))/((237)(3.0 xx 10^-2)^(2))`
`= 0.14 K//W`
and thermal resistance of copper cube, `R_2 = l/(KA)`
or ` R_2 = (3.0 xx 10^-2)/((401)(3.0 xx 10^-2)^2) = 0.08 K//W`
As these two resistance are in parallel, their equivalent resistance will be
`R= ((R_1R_2)/(R_1+R_2))`
`= ((0.14)(0.08))/((0.14)+(0.08))`
`=0.05 K//W`
`:.` Thermal current, `H = ("Temperature difference")/("Thermal resistance")`
`= ((100 -20)/0.05) = 1.6 xx (10^3)W`
(b) In parallel thermal current distributes in the inverse ratio of resistance. Hence,
`H_(Cu)/H_(Al) = (R_(Al)/R_(Cu)) = R_1/R_2 = 0.14/0.08 = 1.75` .
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Knowledge Check

  • Three metal rods made of copper, aluminium and brass, each 20 cm long 4cm in diameter, are placed end to end with aluminium between the other two. The free ends of copper and brass are maintained at 100 and 0^(@)C respectively. Assume that the thermal conductivity of copper is twice that of aluminium and four times that of brass. The approximately equilibrium temperatures of the copper-aluminiu and aluminium-brass junctions are respectively.

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