Dear Readers, Welcome to Power Plant Engineering Objective Questions have been designed specially to get you acquainted with the nature of questions you may encounter during your Job interview for the subject of Power Plant Engineering MCQs. These objective type Power Plant Engineering questions are very important for campus placement test and job interviews. As per my experience good interviewers hardly plan to ask any particular question during your Job interview and these model questions are asked in the online technical test and interview of many IT companies.
(a) solar, wind and biomass
(b) fossil fuels, hydropower and nuclear energy
(c) wood, animal wastes and agriculture wastes
(d) none of the above
Ans: b
(a) Kota
(b) Sarni
(c) Chandrapur
(d) Neyveli
Ans: c
(a) 18%
(b) 23%
(c) 77%
(d) 79%
Ans: b
(a) 21%
(b) 23%
(c) 77%
(d) 79%
Ans: a
(a) high CO content in flue gases at exit
(b) high CO2 content in flue gases at exit
(c) high temperature of flue gases
(d) the smoking exhaust from chimney
Ans: a
(a) human waste
(b) wet cow dung
(c) wet livestock waste
(d) all above
Ans: d
(a) Tarapore
(b) Kota
(c) Kalpakkam
(d) none of the above
Ans: a
(a) mechanical
(b) chemical
(c) heat
(d) sound
Ans: b
(a) using focusing collector or heliostates
(b) using flat plate collectors
(c) using a solar pond
(d) any of the above system
Ans: d
(a) 700 W/m2
(b) 800 W/m2
(c) 1 kW/m2
(d) 2 kW/m2
Ans: c
(a) these develop more power
(b) its technology is simple
(c) abundance of thorium deposits are available in India
(d) these can be easily designed
Ans: c
(a) Rankine cycle efficiency
(b) Carnot cycle efficiency
(c) Regenerative cycle efficiency
(d) Boiler efficiency x turbine efficiency x generator efficiency
Ans: c
(a) 15 to 20 per cent
(6) 35 to 45 per cent
(c) 70 to 80 per cent
(d) 90 to 95 per ceut
Ans: b
(a) has higher the rnal efficiency than the carnot cycie operating between same pressure limits
(b) has lower the"nal efficiency than carnot cycle operating between same pressure limit?
(c) has same thermal efficiency as carnot cycle operating between same pressure limits
(d) may be more or less depending upon the magnitude of p1 and p2
Ans: a
(a) improves in summer as compared to that in winter
(6) improves in winter as compared to that in summer
(c) is unaffected by climatic conditions
(d) none of the above
Ans: b
(a) two isentropic processes and two constant volume processes
(b) two isentropic processes and two constant pressure processes
(e) two isothermal processes and three constant pressure processes
(d) none of the above
Ans: b
(a) change of internal energy between inlet and outlet
(b) change of enthaply between inlet and outlet
(c) change of entropy between inlet and outlet
(d) change of temperature between inlet and outlet
Ans: b
(a) is always greater than simple Rankine thermal efficiency
(b) is greater than simple Rankine cycle thermal efficiency only when steam is bled at particular pressure
(c) is same as simple Rankine cycle thermal efficiency
(d) is always less than simple Rankine cycle thermal efficiency
Ans: a
(a) decreases with increase in Rankine cycle efficiency
(b) increases with increase in Rankine cycle efficiency
(c) is unaffected by increase in Rankine cycle efficiency
(d) none of the above
Ans: b
(a) when steam is extracted from only one suitable point of steam turbine
(b) when steam is extracted from several places in different stages of steam turbine
(c) when steam is extracted only from the last stage of steam turbine
(d) when steam is extracted only from the first stage of steam turbine
Ans: b
(a) increases with number of feed heaters increasing
(b) decreases with number of feed heaters increasing
(c) remains same unaffected by number of feed heaters
(d) none of the above
Ans: a
(a) exhaust gases
(b) heaters
(c) draining steam from the turbine
(d) all above
Ans: c
(a) utilise heat of flue gases
(b) increase thermal efficiency
(c) improve condenser performance
(d) reduce loss of heat
Ans: b
(a) higher critical temperature and pressure
(b) higher saturation temperature than other fluids
(c) relatively low vapourisation pressure
(d) all above
Ans: d
(a) increase the performance of the condenser
(b) increase the efficiency of the plant
(c) increase efficiency of the turbine
Ans: b
(a) equal to diesel power station
(b) more than diesel power station
(c) less than diesel power station
Ans: b
(a) air
(b) feed water
(c) flue gases
(d) all above
Ans: b
(a) impulse turbines
(b) reaction turbines
(c) impulse-reaction turbines
(d) none of the above
Ans: c
(a) induced draught
(b) natural draught
(c) forced draught
(d) balanced draught
Ans: b
(a) less
(b) more
(c) same
(d) may be more or less
Ans: b
(a) due to the fact that furnace gases being light go through the chimney giving place to cold air from outside to rush in
(b) due to the fact that pressure at the grate due to cold column is higher than the pressure at the chimney base due to hot column
(c) due to the fact that at the chimney top the pressure is more than its environmental pressure
(d) all of the above
Ans: b
(a) decreases with increase in outside air temperature
(b) increases with increase in outside air temperature
(c) remains the same irrespective of outside air temperature
(d) may increase or decrease with increase in outside air temperature
Ans: a
(a) decreases if the chimney gas temperature increases
(b) increases if the chimney gas temperature increases
(c) remains same irrespective of chimney gas temperature
(d) may increase or decrease
Ans: b
(a) to produce draught to accelerate the combustion of fuel
(b) to discharge gases high up in the atmosphere to avoid hazard
(c) to reduce the temperature of the hot gases discharged
(d) none of the above
Ans: b
(a) induced fan
(b) forced fan
(c) induced and forced fan
(d) all of the above
Ans: d
(a) forced fan
(b) chimney
(c) steam jet
(d) only motion of locomotive
Ans: c
(a) less
(b) more
(c) same
(d) not predictable
Ans: b
(a) air fans
(b) steam jet
(c) fan or steam jet
(d) all of the above
Ans: d
(a) less smoke
(b) more draught
(c) less chimney gas temperature
(d) all of the above
Ans: d
(a) near bottom of chimney
(b) near bottom of furnace
(c) at the top of the chimney
(D) anywhere permissible
Ans: a
(a) forced draught system
(b) induced draught system
(c) balanced draught system
(d) natural draught system
Ans: c
(a) 80%
(b) 40%
(c) 20%
(d) 0.25%
Ans: d
(a) pvls=C
(b) pv1126 = C
(c) pv1A = C
(d) pv = C
Ans: a
(a) 0.6
(6) 0.578
(c) 0.555
(d) 0.5457
Ans: b
(a) 0.555
(b) 0.578
(c) 0.5457
(d) 0.6
Ans: c
(a) the ratio of outlet pressure to inlet pressure of nozzle
(b) the ratio of inlet pressure to outlet pressure of nozzle
(c) the ratio of outlet pressure to inlet pressure only when mass flow rate per unit area is minimum
(d) the ratio of outlet pressure to inlet pressure only when mass flow rate = c
Ans: d
(a)pv = C
(b)pv1A = C
(c)pv1i = C
(d)pv
Ans: d
(a) increase in exit velocity from the nozzle
(6) decrease in exit velocity from the nozzle
(c) no change in exit velocity from the nozzle
(d) increase or decrease depending upon the exit quality of steam
Ans: b
(a) increase in dryness fraction of exit steam
(b) decrease in dryness fraction of exit steam
(c) no change in the quality of exit steam
(d) decrease or increase of dryness frac-tion of exit steam depending upon inlet quality
Ans: a
(a) there is enthalpy drop in fixed and moving blades
(b) there is enthalpy drop only in moving blades
(c) there is enthalpy drop in nozzles
(d) none of the above
Ans: c
(a) is same
(b) is different
(c) increases from one side to the other side
(d) decreases from one side to the other side
Ans: a
(a) the pressure in the turbine rotor is approximately same as in condenser
(b) the pressure in the turbine rotor is higher than pressure in the condenser
(c) the pressure in the turbine rotor gradually decreases from inlet to exit from condenser
(d) none from the above
Ans: a
(a) there is enthalpy drop both in fixed and moving blades
(b) there is enthalpy drop only in fixed blades
(c) there is enthalpy drop only in moving blades
(d) none of the above
Ans: a
(a) reaction steam turbine
(b) pressure velocity compounded steam turbine
(c) pressure compounded impulse steam turbme
(d) velocity compounded impulse steam turbine
Ans: b
(a) reaction steam turbine
(b) velocity compounded impulse steam turbine
(c) pressure compounded impulse steam turbine
(d) pressure velocity compounded steam turbine
Ans: c
(a) pressure compounded steam turbine
(b) simple single wheel, impulse steam turbine
(c) simple single wheel reaction steam turbine
(d) multi wheel reaction steam turbine
Ans: d
(a) 75%
(b) 100%
(c) 50%
(d) 60%
Ans: c
(a) exit pressure only
(b) stage efficiency only
(c) initial pressures and temperature only
(d) all of the above
Ans: c
(a) 0.5 to 0.6
(b) 0.9 to 0.95
(c) 1.02 to 1.06
(d) 1.2 to 1.6
Ans: c
(a) Throttle governing
(b) Nozzle control governing
(c) By-pass governing
(d) all of the above
Ans: d
(a) increases with the increase in number of stages
(b) decreases with the increase in number of stages
(c) remains same irrespective of number of stages
(d) none of the above
Ans: a
(a) higher
(b) lower
(c) same as long as initial pressure and temperature is unchanged
(d) none of the above
Ans: a
(a) cooling water passes through tubes and steam surrounds them
(b) steam passes through tubes and cooling water surrounds them
(c) steam and cooling water mix
(d) steam and cooling water do not mix
Ans: c
(a) steam and cooling water mix to give the condensate
(b) cooling water passes through the tubes and steam surrounds them
(c) steam passes through the cooling tubes and cooling water surrounds them
(d) all of the above varying with situation
Ans: b
(a) fall in absolute pressure maintained in condenser
(b) rise in absolute pressure maintained in condenser
(c) no change in absolute pressure in the condenser
(d) rise in temperature of condensed steam
Ans: a
(a) increases the quantity of vapour extracted along with air
(b) reduces the quantity of vapour extracted along with air
(c) does not affect vapour quantity extracted but reduces pump capacity of air extraction pump
(d) none of the above
Ans: b
(a) removes air and also vapour from condenser
(b) removes only air from condenser
(c) removes only un-condensed vapour from condenser
(d) removes air alongwith vapour and also the condensed water from condenser
Ans: d
(a) to maintain pressure below atmospheric to increase work output from the primemover
(b) to receive large volumes of steam exhausted from steam prime mover
(c) to condense large volumes of steam to water which may be used again in boiler
(d) all of the above
Ans: d
(a) there is one pump to remove air and condensate
(b) there are two pumps to remove air and condensate
(c) there are three pumps to remove air, vapour and condensate
(d) there is no pump, the condensate gets removed by gravity
Ans: b
(a) steam in pipes surrounded by water
(b) water in pipes surrounded by steam
(c) either (a) or (b)
(d) none of the above
Ans: a
(a) steel
(b) cast iron
(c) copper
(d) aluminium
Ans: a
(a) four
(b) three
(c) two
(d) one
Ans: c
(a) condensing type
(b) non-condensing type
(c) none of the above
Ans: a
(a) 30°
(b) 60°
(c) 80°
(d) 90°
Ans: a
(a) 30 metres
(b) 40 metres
(c) 60 metres
(d) 100 metres
Ans: a
(a) 25 to 30%
(b) 40 to 50%
(c) 65 to 70%
(d) 85 to 90%
Ans: d
(a) 5%
(b) 10%
(c) 15%
(d) 20%
Ans: d
(a) centre of coal fields
(b) centre of maximum load of equip-ments
(c) centre of gravity of electrical system
Ans: c
(a) 20 kgf/cm2
(b) 50 kgf/cm2
(c) 100 kgf/cm2
(d) 150 kgf/cm2
Ans: d
(a) 1 to 5%
(b) 4 to 10%
(c) 10 to 12%
Ans: b
(a) 20 to 100 MW
(b) 50 to 300 MW
(c) 70 to 400 MW
(d) 100 to 650 MW
Ans: b
(a) burn completely
(b) burn freely
(c) do not form ash
(d) form lumps or masses of coke
Ans: d
(a) reduce the flame length
(b) increase the flame length
(c) transport and dry the coal
(d) provide air around burners for get¬ting optimum combustion
Ans: c
(a) reduce the flame length
(b) increase the flame length
(c) transport and dry the coal
(d) provide air round the burners for getting optimum combustion
Ans: d
(a) dust
(b) clinkers
(c) iron particles
(d) sand
Ans: c
(a) 20 to 40 tonnes/hr
(b) 50 to 100 tonnes/hr
(c) 100 to 150 tonnes/hr
(d) 150 to 200 tonnes/hr
Ans: b
(a) lift trucks
(b) coal accelerators
(c) tower cranes
(d) belt conveyor
Ans: b
(a) carrying coal in horizontal direction
(b) carrying coal in vertical direction
(c) carrying coal in any direction
Ans: b
(a) primary air
(b) secondary air
(c) tertiary air
Ans: b
(a) unit
(b) central
(c) none of the above
Ans: b
(a) anthracite
(b) lignite
(c) semibituminous and bituminous
Ans: c
(a) chain grate
(b) spreader
(c) travelling grate
(d) all of the above
Ans: d
(a) underfeed stoker
(b) overfeed stoker
(c) any
Ans: b
(a) 50—75 kg/m per hour
(b) 75—100 kg/m per hour
(c) 100—150 kg/m per hour
(d) 150—200 kg/m2 per hour
Ans: d
(a) to reduce the boiler pressure
(b) to increase the steam temperature
(c) to control the solid concentration in the boiler water by removing some of the concentrated saline water
(d) none of the above
Ans: c
(a) heat the water
(b) heat the air in the water
(c) remove dissolved gases in the water
Ans: c
(a) isentropic heat drop to useful heat drop
(b) adiabatic heat drop to isentropic heat drop
(c) cumulative actual enthalpy drop for the stages to total is isentropic enthalpy heat drop
Ans: c
(a) 0.8 to 1.0
(b) 1.0 to 1.05
(c) 1.1 to 1.5
(d) above 1.5
Ans: c
(a) reducing the work done
(b) increasing the rotor speed
(c) reducing the rotor speed
(d) balancing the turbine
Ans: c