A tube of small uniform cross section is used to siphon the water from the vessel. Then choose the correct alternative (s) :
`(rho_("water") = 10^(3) kg//m^(3), g = 10 m//s^(2), P_(atm) = 10^(5) Pa)`

An air filled balloon is at a depth of 1 km below the water level in an ocean . The normal stress of the balloon (in Pa) is (Given, rho_("water") = 10^(3) kgm^(-3), g = 9.8 ms^(-2) and P_(atm) = 10^(5) Pa)

A tank of large base area is filled with water up to a height of 5 m . A hole of 2 cm^(2) cross section in the bottom allows the water to drain out in continuous streams. For this situation, mark out the correct statement(s) (take rho_("water")=1000kg//m^(3),g=10ms^(-12))

A tube of uniform cross section is used to siphon water from a vessel V as shown in the figure. The pressure over the open end of water in the vessel is atmospheric pressure (P_(0)) . The height of the tube above and below the water level in the vessel are h_(1) and h_(2) , respectively. If h_(1)=h_(2) = 3.0 m , the maximum value of h_(1) , for which the siphon will work will be

A tube of uniform cross section is used to siphon water from a vessel V as shown in the figure. The pressure over the open end of water in the vessel is atmospheric pressure (P_(0)) . The height of the tube above and below the water level in the vessel are h_(1) and h_(2) , respectively. Given h_(1) = h_(2) = 3.0 m , the gauge pressure of water in the highest level CD of the tube will be

A tube of uniform cross section is used to siphon water from a vessel V as shown in the figure. The pressure over the open end of water in the vessel is atmospheric pressure (P_(0)) . The height of the tube above and below the water level in the vessel are h_(1) and h_(2) , respectively. Determine the velocity v_(B) of the water issuing out at B .

The guage pressure exerted below a column of water, open to the earth's atmosphere at depth of 10 m is (density of water = 1000 kg/ m^3 , g = 10 m/ s^2 and 1 atm pressure = 10^5 Pa)

The pressure at a point in water is 10 N//m^(2) . The depth below this point where the pressure becomes double is (Given density of water = 10^(3) kg m^(-3) , g = 10 m s^(-2) )

Find the pressure exerted below a column of water, open to the atmosphere, at depth (i) 5 m (ii) 20 m (Given, density of water = 1 xx 10^(3)"kg m"^(-3), g = 10 m s^(-2) )

In a carburator of an engine, aire is drawn from atmosphere through section A with a velocity of 10m//s . The narrow section B is connected to a petrol tank as shown. The minimum ratio of area of cross section A to area of cross section B , so that the petrol can just enter the carburator tube is sqrt(66/x) . Then the value of x is : (density of petrol =1000kg//m^(3) , density of air =2kg//m^(3), g=10m//s^(2) atmospheric pressure =10^(5) Pa and assume density of air remain constant)

A metallic sphere of radius 1.0 xx 10^(-3) m and density 1.0 xx 10^(4) kg//m^(3) enters a tank of water, after a free fall through a distance of h in the earth's gravitational field. If its velocity remains unchanged after entering water, determine the value of h . Given: coefficient of viscosity of water = 1.0 xx 10^(-3) N s//m^(2), g = 10ms^(-12) and density of water = 1.0 xx 10^(3) kg//m^(3) .