Heat Transfer Past Paper BT-5/D-21 2021 PDF

Summary

This is a past paper for a Heat Transfer course, likely from 2021, examining principles of heat transfer. The paper covers various topics and includes questions related to boundary layers, thermal radiation, and heat exchangers.

Full Transcript

Roll No.......................... Total Page : 2
BT–5/D–21 45195
HEAT TRANSFER
Paper–MEC–301A
Time Allowed : 3 Hours] [Maximum Marks : 75
Note : Attempt five questions in all, selecting at least one question from
each Unit. All questions carry equal marks. Assume any missing data
suitably.
UNIT–I
1. Saturated steam at 110ºC flows inside a copper pipe (thermal conductivity
450 W/m K) having an internal diameter of 10 cm and an external diameter
of 12 cm. The surface resistance on the steam side is 12000 W/m2 K and
that on the outside surface of pipe is 18 W/m2K. Determine the heat loss
from the pipe if it is located in space at 25ºC. How this heat loss would
be affected if the pipe is logged with 5 cm thick insulation of thermal
conductivity 0.22 W/m K? 15
2. Derive an equation giving the temperature at the centre of a circular rod
conducting electric current in terms of the current density, the wall temperature
and the material properties. What is the centre temperature of a stainless
steel (k = 16 W/m K, ρ = 0.67 × 10−4 Ω cm) rod of 20 mm diameter with an
outer temperature of 400ºC when conducting 1000 A?
15
UNIT–II
3. What is Boundary layer thickness? What do you mean by laminar and
turbulent boundary layers? What is laminar Sublayer? 15
4. Air at 2 atm and 200ºC is heated as it flows at a velocity of 12 m/s through
a tube with a diameter of 3 cm. A constant heat flux condition is maintained
at the wall and the wall temperature is 20ºC above the air temperature all
along the length of the tube. Calculate : 15
(a) the heat transfer per unit length of tube

45195/K/270
 (b) the increase in bulk temperature of air over a 4 m length of the
tube. Use Dittus-Boelter equation, Nud = 0.023 Re0.8 Pr0.4. Properties
of air are Pr = 0.681, µ = 2.57 × 10–5 kg/ms, k = 0.0386 W/m K and
cp = 1.025 kJ/kg K.
UNIT–III
5. Why is Planck’s law the basic law of thermal radiation? Explain graphically
how E bλ and T are related. 15
6. (i) State and explain the reciprocity theorem. 6
(ii) Two very large parallel plates with emissivities 0.5 exchange heat.
Determine the percentage reduction is heat transfer rate if a polished
aluminium radiation shield (ε = 0.04) is placed in between the plates.
9
UNIT–IV
7. What is the limitation of LMTD method? Derive the expression for
effeciveness using NTU method for counter flow heat exchanger. 15
8. A 4 kg/s product stream from a distillation column is to be a 3 kg/s water
stream in a counter flow heat exchanger. The hot and cold stream inlet
temperatures are 400 K and 300 K respectively and the are fo the exchanger
is 30 m2. If the overall heat transfer coefficient is estimated to be
820 W/m2/K, determine the product stream outlet temperature, if its specific
heat is 2500 J/kg K and coolant outlet temperature. 15

45195/K/270 2