using the illustration when both surfaces 1 and 2 are exposed to the atmoshere, `P_1` and `P_2` are gauge pressure , and `h_1` and `h_2` are heights .

The Bernoulli equation for this situation is `h_1+P_1 /W+V_1^2/"2a"=h_2+P_2/W+V_2^2/"2a"`
If an Identical outlet were placed at exactly the same point on the left side of the container, the velocity would be

using the illustration when both surfaces 1 and 2 are exposed to the atmoshere, P_1 and P_2 are gauge pressure , and h_1 and h_2 are heights . The Bernoulli equation for this situation is h_1+P_1 /W+V_1^2/"2a"=h_2+P_2/W+V_2^2/"2a" The value of P_1 and P_2 are such that

using the illustration when both surfaces 1 and 2 are exposed to the atmoshere, P_1 and P_2 are gauge pressure , and h_1 and h_2 are heights . The Bernoulli equation for this situation is h_1+P_1 /W+V_1^2/"2a"=h_2+P_2/W+V_2^2/"2a" The velocity of the fluid leavening point (2) is constant and can be expressed as

Water is flowing through a pipe as shown in figure. If P_(1), P_(2) and P_(3) are pressures and v_(1), v_(2) and v_(3) are velocities of water at the different sections as shown in figure, then

The range R of projectile is same when its maximum heights are h_(1) and h_(2) . What is the relation between R, h_(1) and h_(2) ?

A horizontal tube has different cross sections at points A and B . The areas of cross section are a_(1) and a_(2) respectively, and pressures at these points are p_(1)=rhogh_(1) and p_(2)=rhogh_(2) where rho is the density of liquid flowing in the tube and h_(1) and h_(2) are heights of liquid columns in vertical tubes connected at A and B . If h_(1)-h_(2)=h , then the flow rate of the liquid in the horizontal tube is

The pressure P_(1) at the top of a dam and P_(2) at a depth h from the top inside water (density rho ) are related as :

In the circuit shown E, F, G and H are cells of emf 2V, 1V, 3V and 1V respectively and their internal resistance are 2Omega, 1Omega, 3Omega and 1Omega respectively.

In the circuit shown E, F, G and H are cells of emf 2V, 1V, 3V and 1V respectively and their internal resistance are 2Omega, 1Omega, 3Omega and 1Omega respectively.

An ideal gas expands isothermally from volume V_(1) to V_(2) and is then compressed to original volume V_(1) adiabatically. Initialy pressure is P_(1) and final pressure is P_(3) . The total work done is W . Then

An ideal gas expands isothermally from volume V_(1) to V_(2) and is then compressed to original volume V_(1) adiabatically. Initialy pressure is P_(1) and final pressure is P_(3) . The total work done is W . Then