355501 Water falls from a height of 60 \(m\) at the rate of 15 \(kg/s\) to operate a turbine. The losses due to frictional force are \(10 \%\) of the input energy. How much power is generated by the turbine? \(\left( {g = 10\;m/{s^2}} \right)\)

355502 At any instant of time \({t}\), the displacement of any particle is given by \({2 t-1}\) (SI unit) under the influence of force of \(5\,N\). The value of instantaneous power is (in \({S I}\) unit):

355503 Power supplied to a particle of mass 2 \(kg\) varies with time as \(P=\dfrac{3 t^{2}}{2}\) watt. Here \(t\) is in second. If velocity of particle at \(t=0\) is \(v = 0\), the velocity of particle at time \(t = 2s\) will be:

355504 A car of mass ' \(m\) ' is driven with acceleration ' \(a\) ' along a straight level road against a constant external resistive force ' \(R\) '. When the velocity of the car is ' \(v\) ', the rate of which the engine of the car is doing work will be

355505 A car of mass 500 \(kg\) is driven with acceleration \(1\;m/{s^2}\) along straight level road against constant external resistance of 1000 \(N\). When the velocity is 5 \(m/s\) the rate at which the engine is working is

355501 Water falls from a height of 60 \(m\) at the rate of 15 \(kg/s\) to operate a turbine. The losses due to frictional force are \(10 \%\) of the input energy. How much power is generated by the turbine? \(\left( {g = 10\;m/{s^2}} \right)\)

355502 At any instant of time \({t}\), the displacement of any particle is given by \({2 t-1}\) (SI unit) under the influence of force of \(5\,N\). The value of instantaneous power is (in \({S I}\) unit):

355503 Power supplied to a particle of mass 2 \(kg\) varies with time as \(P=\dfrac{3 t^{2}}{2}\) watt. Here \(t\) is in second. If velocity of particle at \(t=0\) is \(v = 0\), the velocity of particle at time \(t = 2s\) will be:

355504 A car of mass ' \(m\) ' is driven with acceleration ' \(a\) ' along a straight level road against a constant external resistive force ' \(R\) '. When the velocity of the car is ' \(v\) ', the rate of which the engine of the car is doing work will be

355505 A car of mass 500 \(kg\) is driven with acceleration \(1\;m/{s^2}\) along straight level road against constant external resistance of 1000 \(N\). When the velocity is 5 \(m/s\) the rate at which the engine is working is

355501 Water falls from a height of 60 \(m\) at the rate of 15 \(kg/s\) to operate a turbine. The losses due to frictional force are \(10 \%\) of the input energy. How much power is generated by the turbine? \(\left( {g = 10\;m/{s^2}} \right)\)

355502 At any instant of time \({t}\), the displacement of any particle is given by \({2 t-1}\) (SI unit) under the influence of force of \(5\,N\). The value of instantaneous power is (in \({S I}\) unit):

355503 Power supplied to a particle of mass 2 \(kg\) varies with time as \(P=\dfrac{3 t^{2}}{2}\) watt. Here \(t\) is in second. If velocity of particle at \(t=0\) is \(v = 0\), the velocity of particle at time \(t = 2s\) will be:

355504 A car of mass ' \(m\) ' is driven with acceleration ' \(a\) ' along a straight level road against a constant external resistive force ' \(R\) '. When the velocity of the car is ' \(v\) ', the rate of which the engine of the car is doing work will be

355505 A car of mass 500 \(kg\) is driven with acceleration \(1\;m/{s^2}\) along straight level road against constant external resistance of 1000 \(N\). When the velocity is 5 \(m/s\) the rate at which the engine is working is

355501 Water falls from a height of 60 \(m\) at the rate of 15 \(kg/s\) to operate a turbine. The losses due to frictional force are \(10 \%\) of the input energy. How much power is generated by the turbine? \(\left( {g = 10\;m/{s^2}} \right)\)

355502 At any instant of time \({t}\), the displacement of any particle is given by \({2 t-1}\) (SI unit) under the influence of force of \(5\,N\). The value of instantaneous power is (in \({S I}\) unit):

355503 Power supplied to a particle of mass 2 \(kg\) varies with time as \(P=\dfrac{3 t^{2}}{2}\) watt. Here \(t\) is in second. If velocity of particle at \(t=0\) is \(v = 0\), the velocity of particle at time \(t = 2s\) will be:

355504 A car of mass ' \(m\) ' is driven with acceleration ' \(a\) ' along a straight level road against a constant external resistive force ' \(R\) '. When the velocity of the car is ' \(v\) ', the rate of which the engine of the car is doing work will be

355505 A car of mass 500 \(kg\) is driven with acceleration \(1\;m/{s^2}\) along straight level road against constant external resistance of 1000 \(N\). When the velocity is 5 \(m/s\) the rate at which the engine is working is

355501 Water falls from a height of 60 \(m\) at the rate of 15 \(kg/s\) to operate a turbine. The losses due to frictional force are \(10 \%\) of the input energy. How much power is generated by the turbine? \(\left( {g = 10\;m/{s^2}} \right)\)

355502 At any instant of time \({t}\), the displacement of any particle is given by \({2 t-1}\) (SI unit) under the influence of force of \(5\,N\). The value of instantaneous power is (in \({S I}\) unit):

355503 Power supplied to a particle of mass 2 \(kg\) varies with time as \(P=\dfrac{3 t^{2}}{2}\) watt. Here \(t\) is in second. If velocity of particle at \(t=0\) is \(v = 0\), the velocity of particle at time \(t = 2s\) will be:

355504 A car of mass ' \(m\) ' is driven with acceleration ' \(a\) ' along a straight level road against a constant external resistive force ' \(R\) '. When the velocity of the car is ' \(v\) ', the rate of which the engine of the car is doing work will be

355505 A car of mass 500 \(kg\) is driven with acceleration \(1\;m/{s^2}\) along straight level road against constant external resistance of 1000 \(N\). When the velocity is 5 \(m/s\) the rate at which the engine is working is