Fixed at both ends
Fixed at one end and free at the other end
Supported at its ends
Supported on more than two supports
B. Fixed at one end and free at the other end
8.314 J/kg mole-K
83.14 J/kgmole-K
831.4 J/kgmole-K
8314 J/kgmole-K
Isothermal process
Adiabatic process
Hyperbolic process
Polytropic process
Tensile
Compressive
Shear
Zero
The stress is the pressure per unit area
The strain is expressed in mm
Hook's law holds good upto the breaking point
Stress is directly proportional to strain within elastic limit
It is possible to transfer heat from a body at a lower temperature to a body at a higher temperature.
It is impossible to transfer heat from a body at a lower temperature to a body at a higher temperature, without the aid of an external source.
It is possible to transfer heat from a body at a lower temperature to a body at a higher temperature by using refrigeration cycle.
None of the above
External energy
Internal energy
Kinetic energy
Molecular energy
τ²/ 2G × Volume of shaft
τ/ 2G × Volume of shaft
τ²/ 4G × Volume of shaft
τ/ 4G × Volume of shaft
Kelvin
Joule
Clausis
Gay-Lussac
30 kJ
54 kJ
84 kJ
114 kJ
Greater than
Less than
Equal to
None of these
Increases the internal energy of the gas
Increases the temperature of the gas
Does some external work during expansion
Both (B) and (C)
The liquid fuels have higher calorific value than solid fuels
The solid fuels have higher calorific value than liquid fuels
A good fuel should have low ignition point
The liquid fuels consist of hydrocarbons
Carnot
Stirling
Ericsson
None of the above
Isothermal process
Hyperbolic process
Adiabatic process
Polytropic process
Producer gas
Coal gas
Mond gas
Coke oven gas
τ²/ 2G × Volume of shaft
τ/ 2G × Volume of shaft
τ²/ 4G × Volume of shaft
τ/ 4G × Volume of shaft
Straight line formula
Eulers formula
Rankines formula
Secant formula
Two isothermals and two isentropic
Two isentropic and two constant volumes
Two isentropic, one constant volume and one constant pressure
Two isentropic and two constant pressures
Increase
Decrease
Remain unchanged
Increase/decrease depending on application
Greater than Carnot cycle
Less than Carnot cycle
Equal to Carnot cycle
None of these
Two constant volume and two isentropic
Two constant pressure and two isentropic
Two constant volume and two isothermal
One constant pressure, one constant volume and two isentropic
δl = 4PE/ πl²
δl = 4πld²/PE
δl = 4Pl/πEd₁d₂
δl = 4PlE/ πd₁d₂
Molecular mass of the gas and the specific heat at constant volume
Atomic mass of the gas and the gas constant
Molecular mass of the gas and the gas constant
None of the above
Isothermal process
Hyperbolic process
Adiabatic process
Polytropic process
Elastic point of the material
Plastic point of the material
Breaking point of the material
Yielding point of the material
Load/original cross-sectional area and change in length/original length
Load/ instantaneous cross-sectional area and loge (original area/ instantaneous area)
Load/ instantaneous cross-sectional area and change in length/ original length
Load/ instantaneous area and instantaneous area/original area
A right angled triangle
An isosceles triangle
An equilateral triangle
A rectangle
Doubled
Halved
Becomes four times
None of the above
(Net work output)/(Workdone by the turbine)
(Net work output)/(Heat supplied)
(Actual temperature drop)/(Isentropic temperature drop)
(Isentropic increase in temperature)/(Actual increase in temperature)
11/3 kg of carbon dioxide gas
7/3 kg of carbon monoxide gas
11/7 kg of carbon dioxide gas
8/3 kg of carbon monoxide gas