A closed container shown in figure is filled with water `(rho=10^(3) kg//M^(3))`

This is accelerated in horizonal direction with an acceleration, `a=2m//s^(2)`.Find (a)`p_(C)-p_(D)` and (b) `p_(A)-p_(D)`.

A closed tube is filled with AB=2m BC=4cm water (rho=10^(3)kg//m^(3)) . It rotating about an axis shown in figure with an angular velocity omega=2 rad//s . Find, p_(A)-p_(C) .

A closed tube is filled with AB=2m BC=4cm water (rho=10^(3)kg//m^(3)) . It rotating about an axis shown in figure with an angular velocity omega=2 rad//s . Find, p_(A)-p_(C) .

A mass m of volume V=10cm^(2) is tied with a string to the base of a container filled with a liquid of density (P_(l)=10^(3)kg//m^(3)) as shown in the figure. The container is then accelerated with acceleration (a_(x)=9m//s^(2)) and (a_(y)=2m//s^(2)) a shown in the figure. [ g=10((m)/(s^(2))) acceleration due to gravity] the net buoyancy force acting on the mass is

A mass m of volume V=10cm^(2) is tied with a string to the base of a container filled with a liquid of density (P_(l)=10^(3)kg//m^(3)) as shown in the figure. The container is then accelerated with acceleration (a_(x)=9m//s^(2)) and (a_(y)=2m//s^(2)) a shown in the figure. [ g=10((m)/(s^(2))) acceleration due to gravity] the net buoyancy force acting on the mass is

Find the acceleration of movable pulled P and block B if acceleration of block A =1m//s^(2)darr .

A wooden block of mass 1kg and density 800 Kg m^(-3) is held stationery, with the help of a string, in a container filled with water of density 1000 kg m^(-3) as shown in the figure. If the container is moved upwards with an acceleration of 2 m s^(-2) , then the tension in the string will be ( take g=10ms^(-2) )

A wooden block of mass 1kg and density 800 Kg m^(-3) is held stationery, with the help of a string, in a container filled with water of density 1000 kg m^(-3) as shown in the figure. If the container is moved upwards with an acceleration of 2 m s^(-2) , then the tension in the string will be ( take g=10ms^(-2) )

A cylindrical tank contains water up to a height H. If the tank is accelerated upwards with acceleration a, the pressure at the A is p_(1) . If the tank is accelerated downwards with acceleration a the pressure at A is p_(2) . Then

A cylindrical tank contains water up to a height H. If the tank is accelerated upwards with acceleration a, the pressure at the A is p_(1) . If the tank is accelerated downwards with acceleration a the pressure at A is p_(2) . Then

The electron configuration of the element 'M' is [Ar] 3d^(10) 4s^(2) 4p^(3) . Then 'M' belong to