A rod CD of thermal resistance 5.0KW^(-1...

A rod CD of thermal resistance `5.0KW^(-1)` is joined at the middle of an identical rod AB as shown in figure. The ends A, B and D are maintained at `100^(@)C` , `0^(@)C` and `25^(@)C` respectively. Find the heat current in CD.

Text Solution

Verified by Experts

The thermal resistance of AC is equal to that of CB and is equal to `2.5KW_(-1)` . Suppose, the temperature at C is (theta). The heat current through AG, CB and CD are
``(DeltaQ_(1))/(Deltat)=(100^(@)C-theta)/(2.5KW^(-1)` . `(DeltaQ_(2))/(Deltat)=(theta-0^(@)C)/(2.5KW^(-1)` . and `(DeltaQ_(3))/(Deltat)=(theta-25^(@)C)/(5.0KW^(-1)` . We also have
`(DeltaQ_(1))/(Deltat)=(DeltaQ_(2))/(Deltat)+(DeltaQ_(3))/(Deltat)` . or, ``(100^(@)C-theta)/(2.5)=(theta-0^(@)C)/(2.5)+(theta-25^(@)C)/(5)` . or, `225^(@)C=5theta` . or, `theta=45^(@)C` . Thus, `(DeltaQ_(3))/(Deltat)=(45^(@)C-45^(@)C)/(5.0KW^(-1))+(20K)/(5.0KW^(-1))` . `=4.0W` .

Topper's Solved these Questions

HEAT TRANSFER
HC VERMA|Exercise QUESTIONS FOR SHORT ANSWER|11 Videos
HEAT TRANSFER
HC VERMA|Exercise OBJECTIVE I|10 Videos
HEAT TRANSFER
HC VERMA|Exercise EXERCIESE|55 Videos
HEAT AND TEMPERATURE
HC VERMA|Exercise Exercise|34 Videos
INTRODUCTION TO PHYSICS
HC VERMA|Exercise Exercises|19 Videos

Similar Questions

Explore conceptually related problems

Four identical rods AB, CD, CF and DE are joined as shown in figure. The length, cross-sectional area and thermal conductivity of each rod are l, A and K respectively. The ends A, E and F are maintained at temperature T_(1) , T_(2) and T_(3) respectively. Assuming no loss of heat to the atmosphere, find the temperature at B.

Three rods of lengths 20cm each and area of cross section 1cm^(2) are joined to from a triangle ABC. The conductivities of the rods are k_(AB)=50Js^(-1)m^(-1)C^(-1) , k_(BC)=200Js^(-1)m^(-1)C^(-1) , and k_(AC)=400Js^(-1)m^(-1)C^(-1) . The junction A,B and C are maintained at 40^(@)C , 80^(@)C and 80^(@)C respectively. Find the rate of heat flowing through the rods AB, AC and BC .

A 6-volt battery of negligible internal resistance is connected across a uniform wire AB of length 100cm. The positive terminal of another battery of emf 4V and internal resistance 1(Omega) is joined to the point A as shown in figure.Take the potential at B to be zero. (a) What are the potentials at the poits A and C ? (b) At which point D of the wire AB, the potential is equal to the potential at C?(c ) If the point C and D are connected by a wire, what will be the current through it ? (d) If the 4V battery is replaced by 7.5V battery,wht would be the answer of parts (a) and (b) ?

A copper strip AB and an iron strip AC are joined at A . The junction A is maintained at 0^@ C and the free ends B and C are maintained at 100^@ C . There is a potential difference between

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 800Wm^(-1)C^(-1) and that of y is 400Wm^(-1)C^(-1) .

If the middle points of the sides B C ,C A , and A B of triangle A B C are (1,3),(5,7), and (-5,7), respectively, then find the equation of the side A Bdot

The temperature of hot and cold end of a 20cm long rod in thermal steady state are at 100° C and 20°C respectively. Temperature at the centre of the rod is

Twelve wire, each having resistance r, are joined to form a cube as shown in figure.Find the equivalent resistance between the end of a face diagonal such as a and c .

A copper rod of length 20cm and cross-sectional area 2mm^(2) is joined with a similar aluminium rod as shown in figure .Find the resistance of the combination between the ends, Resistivity of copper =1.7xx10^(-8)(Omega)m and that of aluminium =2.6xx10^(-8)(Omega)m .

Two steel rods and an aluminum rod of equal length l_0 and equal cross section are joined rigidly at their ends as shown in the figure below. All the rods are in a state of zero tension at 0^@C . Find the length of the system when the temperature is raised to theta . Coefficient of linear expansion of aluminum and steel are alpha_a and alpha_s respectively. Young's modulus of aluminum is Y_a and of steel is Y_s .

HC VERMA-HEAT TRANSFER-worked out examples

The lower surface of a slab of stone of face-area 3600cm^(2) and thick...
Text Solution
|
An icebox made of 1.5cm thick styrofoam has dimensions 60cmxx60cmxx30c...
Text Solution
|
Temperature of water at the surface of lake is – 20°C. Then temperatur...
Text Solution
|
Two rods of same length and cross section are joined along the length....
Text Solution
|
Two parallel plates A and B are joined together to form a compound pla...
Text Solution
|
The temperature inside a refrigator is t2^@C and the room temperature ...
Text Solution
|
An electric heater is used in a room of total wall area 137m^(2) to ma...
Text Solution
|
Three rods of material x and three of material y are connected as show...
Text Solution
|
A rod CD of thermal resistance 5.0KW^(-1) is joined at the middle of a...
Text Solution
|
Two thin metallic spherical shells of radii r(1) and r(2) (r(1)lt r(2...
Text Solution
|
On a cold winter day, the atmospheric temperature is -theta (on celsiu...
Text Solution
|
Figure shows a large tank of water at a constant temperature theta(0)...
Text Solution
|
One mode of an ideal monatomic gas is kept in a rigid vessel. The vess...
Text Solution
|
A monatomic ideal gas is contained in a rigid container of volume V wi...
Text Solution
|
A container contains hydrogen gas at pressure P and temperature T. Ano...
Text Solution
|
The mass of 1 litre of helium under a pressure of 2 atm and at a tempe...
Text Solution
|
An electric heater emits 1000W of thermal radiation. The coil has a su...
Text Solution
|
The light from the sun is found to have a maximum intensity near the w...
Text Solution
|
A hot water cools from 92^(@)C to 84^(@)C in 3 minutes when the room t...
Text Solution
|
Cooling is transfer of heat energy from the body at higher temperature...
Text Solution
|