Dear Readers, Welcome to Refrigeration and Air Conditioning Objective Questions and Answers have been designed specially to get you acquainted with the nature of questions you may encounter during your Job interview for the subject of Refrigeration and Air Conditioning Multiple choice Questions. These Objective type Refrigeration and Air Conditioning 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 & Non IT Industries.
(a) Tow specific heat of liquid
(b) high boiling point
(c) high latent heat of vaporisation
(d) higher critical temperature
(e) low specific volume of vapour.
Ans: b
(a) water at 0°C
(b) ice at - 4°C
(c) solid and dry ice
(d) mixture of ice, water and vapour under equilibrium conditions under NTP con-ditions
(e) mixture of ice and water Under equilibrium conditions.
Ans: e
(a) Carnot cycle
(b) Rankine cycle
(c) reversed Camot cycle
(d) reversed Rankine cycle
(e) none of the above.
Ans: e
(a) Ericsson
(b) Stirling
(c) Carnot
(d) Bell-coleman
(e) none of the above.
Ans: d
(a) very little work input
(b) maximum work input
(c) nearly same work input as for vapour compression cycle
(d) zero work input
(e) none of the above.
Ans: a
(a) noisy operation
(b) quiet operation
(c) cooling below 0°C
(d) very little power consumption
(e) its input only in the form of heating.
Ans: b
(a) actual COP/fheoretical COP
(b) theoretical COP/actual COP
(c) actual COP x theoretical COP
(d) 1-actual COP x theoretical COP
(e) 1-actual COP/fheoretical COP.
Ans: a
(a) temperature, pressure and enthalpy
(b) specific volume and enthalpy
(c) temperature and enthalpy
(d) temperature, pressure, and specil volume
(e) temperature, pressure, specific volur and'enthalpy.
Ans: e
(a) saturation point of vapour
(b) saturation point of liquid
(c) sublimation temperature
(d) triple point
(e) critical point.
Ans: a
(a) after passing through the condenser
(b) before passing through the condensei
(c) after passing through the expansion throttle valve
(d) before entering the expansion valve
(e) before entering the compressor.
Ans: a
(a) after passing through the condenser
(b) before passing through the condenser
(c) after passing through the expansion or throttle valve
(d) before entering the expansion valve
(e) before entering the compressor.
Ans: e
(a) after passing through the condenser
(b) before passing through the condenser
(c) after passing through the expansion or thiottle valve
(d) before entering the expansion valve
(e) before entering the compressor.
Ans: d
(a) after passing through the condenser
(b) before passing through the condenser
(c) after passing through the expansion or throttle valve
(d) before [entering the expansion valve
(e) before entering the compressor.
Ans: b
(a) after passing through the condenser
(b) before passing through the condenser
(c) after passing through the expansion or throttle valve
(d) before entering the expansion valve
(e) before entering the compressor..
Ans: e
(a) -100°C
(b) -50°C
(c) - 33.3°C
(d) 0°C
(e) 33.3°C.
Ans: c
(a) in 1 hour
(b) in 1 minute
(c) in 24 hours
(d) in 12 hours
(e) in 10 hours.
Ans: c
(a) 50 kcal/min
(b) 50 kcal/kr
(c) 80 kcal/min
(d) 80 kcal/hr
(e) 1000 kcal/day.
Ans: a
(a) 210 kJ/min
(b) 21 kJ/min
(c) 420 kJ/min
(d) 840 kJ/min
(e) 105 kJ/min.
Ans: a
(a) Rankine
(b) Carnot
(c) Reversed Rankine
(d) Brayton
(e) Reversed Carnot.
Ans: e
(a) atmospheric pressure
(b) slightly above atmospheric pressure
(c) 2-4 bars
(d) 5-6 bars
(e) 7-10 bars.
Ans: d
(a) evaporator
(b) safety relief valve
(c) dehumidifier
(d) driers
(e) expansion valve
Ans: d
(a) will be higher
(b) will be lower
(c) will remain unaffected
(d) may be higher or lower depending upon the nature of non-condensable gases
(e) unpredictable.
Ans: a
(a) above which liquid will remain liquid
(b) above which liquid becomes gas
(c) above which liquid becomes vapour
(d) above which liquid becomes solid
(e) at which all the three phases exist together.
Ans: a
(a) a gas will never liquefy
(b) a gas will immediately liquefy
(c) water will evaporate
(d) water will never evaporate
(e) none of the above.
Ans: a
(a) high sensible heat
(b) high total heat
(c) high latent heat
(d) low latent heat
(e) low sensible heat
Ans: c
(a) 0.1 ton
(b) 5 tons
(c) 10 tons
(d) 40 tons
(e) 100 tons.
Ans: a
(a) is less than 1
(b) is more than 1
(c) is equal to 1
(d) depends upon the make
(e) depends upon the weather conditions.
Ans: b
(a) centrifugal
(b) axial
(c) miniature sealed unit
(d) piston type reciprocating
(e) none of the above.
Ans: d
(a) compressor
(b) condenser
(c) evaparator
(d) expansion valve.
(e) heat transfer.
Ans: d
(a) C02
(b) Freon-11
(c) Freon-22
(d) Air
(e) none of the above.
Ans: d
(a) electrically operated throttling valve
(b) manually operated valve
(c) thermostatic valve
(d) capillary tube
(e) expansion valve.
Ans: d
(a) Carnot cycle
(b) Reversed Carnot cycle
(c) Rankine cycle
(d) Erricson cycle
(e) Brayton cycle.
Ans: e
(a) domestic refrigerators
(b) commercial refrigerators
(c) air conditioning
(d) gas liquefaction
(e) such a cycle does not exist.
Ans: d
(a) liquid
(b) sub-cooled liquid
(c) saturated liquid
(d) wet vapour
(e) dry vapour.
Ans: d
(a) lower than atmospheric pressure
(b) higher than atmospheric pressure
(c) equal to atmospheric pressure
(d) could be anything
(e) none of the above.
Ans: b
(a) small
(b) high
(c) euqal
(d) anything
(e) under some conditions small and under some conditions high.
Ans: a
(a) condenser tubes
(b) evaporator tubes
(c) refrigerant cooling tubes
(d) capillary tubes
(e) throttling device.
Ans: a
(a) receiver
(b) expansion valve
(c) evaporator
(d) condenser discharge
(e) compressor discharge.
Ans: e
(a) near critical temperature of refrigerant
(b) above critical temperature
(c) at critica. temperature
(d) much below critical temperature
(e) could be anywhere.
Ans: d
(a) less than 2 kg
(b) more than or equal to 3.65 kg
(c) more than 10 kg
(d) there is no such consideration
(e) pone of the above.
Ans: b
(a) Freon-11
(b) Freon-22
(c) C02
(d) S02
(e) ammonia.
Ans: e
(a) reduce compressor overheating
(b) reduce compressor discharge tempera-ture
(c) increase cooling effect
(d) ensure that only liquid and not the vapour enters the expansion (throttling) valve
(e) none of the above.
Ans: d
(a) always less than unity
(b) always more than unity
(c) equal to unity
(d) any one of the above
(e) none of the above.
Ans: b
(a) more
(b) less
(c) same
(d) more for small capacity and less for high capacity
(e) less for small capacity and more for high capacity.
Ans: b
(a) of cooling medium
(b) of freezing zone
(c) of evaporator
(d) at which refrigerant gas becomes liquid
(e) condensing temperature of ice.
Ans: d
(a) results in loss of heat due to poor heat transfer
(b) increases heat transfer rate
(c) is immaterial
(d) can be avoided by proper design
(e) decreases compressor power.
Ans: a
(a) high, of the order of 25°
(b) as low as possible (3 to 11°C)
(c) zero
(d) any value
(e) none of the above.
Ans: b
(a) collect liquid refrigerant and prevent it from going to compressor
(b) detect liquid in vapour
(c) superheat the vapour
(d) collect vapours
(e) increase refrigeration effect.
Ans: a
(a) 10%
(b) 25%
(c) 50%
(d) 75%
(e) 100%.
Ans: c
(a) decreases
(b) increases
(c) remains same
(d) depends on other factors
(e) none of the above.
Ans: b
(a) 0.2
(b) 1.2
(c) 5
(d) 6
(e) 10.
Ans: c
(a) high triiscibility with oil
(b) low boiling point
(c) good electrical conductor
(d) large latent heat
(e) non-inflammable.
Ans: c
(a) condenser and expansion valve
(b) compressor and evaporator
(c) expansion valve and evaporator
(d) compressor and condenser
(e) none of the above.
Ans: c
(a) strong solution to weak solution
(b) weak solution to strong solution
(c) strong solution to ammonia vapour
(d) ammonia vapour to weak solution
(e) ammonia vapour to strong solution.
Ans: b
(a) 1.25
(b) 0.8
(c) 0.5
(d) 0.25
(e) none of the above.
Ans: d
(a) critical pressure of refrigerant
(b) much below critical pressure
(c) much above critical pressure
(d) near critical pressure
(e) there is no such restriction.
Ans: b
(a) 0.2
(b) 1.2
(c) 5
(d) 6
(e) 10.
Ans: d
(a) Ammonia
(b) Carbon dioxide
(c) Freon
(d) Brine
(e) Hydrocarbon refrigerant.
Ans: b
(a) compression
(b) direct
(c) indirect
(d) absorption
(e) none of the above.
Ans: d
(a) same
(b) more
(c) less
(d) more/less depending on rating
(e) unpredictable.
Ans: b
(a) compressor
(b) condenser
(c) evaporator
(d) expansion valve
(e) all of the above.
Ans: d
(a) condenser
(b) evaporator
(c) compressor
(d) expansion valve
(e) receiver.
Ans: b
(a) halide torch which on detection produces greenish flame lighting
(b) sulphur sticks which on detection gives white smoke
(c) using reagents
(d) smelling
(e) sensing reduction in pressure.
Ans: a
(a) lithium bromide used in vapour absorption cycle is nonvolatile
(b) lithium bromide plant can't operate below 0°C
(c) a separator is used in lithium bromide plant to remove the unwanted water vapour by condensing
(d) concentration of solution coming out of lithium bromide generator is more in comparison to that entering the generator
(e) weak solution in liquid heat exchanger gives up heat to the strong solution.
Ans: c
(a) condensation of the refrigerant vapour
(b) evaporation of the refrigerant liquid
(c) compression of the refrigerant vapour
(d) metering of the refrigerant liquid
(e) none of the above.
Ans: b
(a) 1 : 1
(b) 1 : 9
(c) 9 : 1
(d) 1 : 3
(e) 3 : 1
Ans: b
(a) inflammable
(d) toxic
(c) non-inflammable and toxic
(d) non-toxic and inflammable
(e) non-toxic and non-inflammable.
Ans: e
(a) non-toxic
(b) non-inflammable
(c) toxic and non-inflammable
(d) highly toxic and inflammable
(e) none of the above.
Ans: d
(a) suction of compressor
(b) delivery of compressor
(c) high pressure side colse to receiver
(d) low pressure side near receiver
(e) anywhere in the cycle.
Ans: c
(a) constant pressure lines
(b) constant temperature lines
(c) constant total heat lines
(d) constant entropy lines
(e) constant volume lines.
Ans: a
(a) involves no change in volume
(b) takes place at constant temperature
(c) takes place at constant entropy
(d) takes place at constant enthalpy
(e) takes place at constant pressure.
Ans: e
(a) the standard unit used in refrigeration problems
(b) the cooling effect produced by melting 1 ton of ice
(c) the refrigeration effect to freeze 1 ton of water at 0°C into ice at 0°C in 24 hours
(d) the refrigeration effect to produce 1 ton of ice at NTP conditions
(e) the refrigeration effect to produce 1 ton of ice in 1 hour time.
Ans: c
(a) increases COP
(b) decreases COP
(c) COP remains unaltered
(d) other factors decide COP
(e) unpredictable.
Ans: b
(a) bigger cabinet should be used
(b) smaller cabinet should be used
(c) perfectly tight vapour seal should be used
(d) refrigerant with lower evaporation temperature should be used
(e) refrigerant with high boiling point must be used.
Ans: c
(a) A refrigerant should have low latent heat
(b) If operating temperature of system is low, then refrigerant with low boiling point should be used
(c) Precooling and subcooling bf refrigerant are same
(d) Superheat and sensible heat of a. refrigerant are same
(e) Refrigerant is inside the lubes in case of a direct-expansion chiller.
Ans: b
(a) bigger
(b) smaller
(c) equal
(d) smaller/bigger depending on capacity
(e) unpredictable.
Ans: a
(a) ineffective refrigeration
(b) high power consumption
(c) freezing automatic regulating valve
(d) corrosion of whole system
(e) breakdown of refrigerant.
Ans: c
(a) it permits higher speeds to be used
(b) it permits complete evaporation in the evaporator
(c) it results in high volumetirc and mechanical efficiency
(d) all of the above
(e) none of the above.
Ans: d
(a) Temperature of medium being cooled must be below that of the evaporator
(b) Refrigerant leaves the condenser as liq-uid
(c) All solar thermally operated absorption systems are capable only of intermittent operation
(d) frost on evaporator reduces heat trans¬fer
(e) refrigerant is circulated in a refrigera¬tion system to transfer heat.
Ans: a
(a) increases COP
(b) decreases COF
(c) COP remains unaltered
(d) other factors decide COP
(e) unperdictable.
Ans: a
(a) high
(b) low
(c) optimum
(d) any value
(e) there is no such criterion.
Ans: b
(a) heat of compression
(b) work done by compressor
(c) enthalpy increase in compressor
(d) all of the above
(e) none of the above.
Ans: d
(a) increase
(b) decrease
(c) remain unaffected
(d) may increase or decrease depending on the type of refrigerant used
(e) unpredictable.
Ans: a
(a) pressure lines
(b) temperature lines
(c) total heat lines
(d) entropy lines
(e) volume lines.
Ans: c
(a) vapour compression
(b) vapour absorption
(c) carnot cycle
(d) electrolux refrigerator
(e) dual cycle.
Ans: a
(a) 0.1 to 0.5 h.p. per ton of refrigeration
(b) 0.5 to 0.8 h.p. per ton of refrigeration
(c) 1 to 2 h.p. per ton of refrigeration
(d) 2 to 5 h.p. per ton of refrigeration
(e) 5 to 10 h.p. per ton refrigeration.
Ans: c
(a) lowers evaporation temperature
(b) increases power required per ton of refrigeration
(c) lowers compressor capacity because vapour is lighter
(d) reduces weight displaced by piston
(e) all of the above.
Ans: e
(a) condenser
(b) evaporator
(c) absorber
(d) condenser and absorber
(e) condenser, absorber and separator (rectifier).
Ans: e
(a) same
(b) more
(c) less
(d) more or less depending on ambient con-ditions
(e) unpredictable.
Ans: c
(a) increase
(b) decrease
(c) may increase or decrease depending on the type of refrigerant used
(d) remain unaffected
(e) unpredictable.
Ans: a
(a) Freon-12
(b) NH3
(c) C02
(d) Freon-22
(e) S02.
Ans: d
(a) more
(b) less
(c) same
(d) more/less depending on size of plant
(e) unpredictable.
Ans: a
(a) same
(b) more
(c) less
(d) dependent on weather conditions
(e) unpredictable.
Ans: c
(a) ammonia vapour goes into solution
(b) ammonia vapour is driven out of solution
(c) lithium bromide mixes with ammonia
(d) weak solution mixes with strong solution
(e) lithium bromide is driven out of solution.
Ans: a
(a) more
(b) less
(c) equally.
(d) unpredictable
(e) none of the above.
Ans: a