Have a query? Ask a Tutor!!

Access to best educators and exclusive paper discussions

Offsite Campus Turito Championship

Can’t find what you’re looking for?

Our tutors are from top schools around the world, and they are waiting for you 24/7, anytime, anywhere.

Homework- One to One Solutions
Understand concepts to solve better
Get your doubts solved instantly

Physics-

General

Easy

Question

The velocity of the liquid coming out of a small hole of a vessel containing two different liquids of densities 2 $rho$ and $rho$ as shown in figure is

$\sqrt{6 g h}$
$2 \sqrt{g h}$
$2 \sqrt{2 g h}$
$\sqrt{g h}$

The correct answer is: $2 square root of g h end root$

Related Questions to study

A narrow tube completely filled with a liquid is lying on a series of cylinders as shown in figure. Assuming no sliding between any surfaces, the value of acceleration of the cylinders for which liquid will not come out of the tube from anywhere is given by

A narrow tube completely filled with a liquid is lying on a series of cylinders as shown in figure. Assuming no sliding between any surfaces, the value of acceleration of the cylinders for which liquid will not come out of the tube from anywhere is given by

physics-General

A U-tube of base length " $lambda$ " filled with same volume of two liquids of densities $rho$ and $2 rho$ is moving with an acceleration "a" on the horizontal plane. If the height difference between the two surfaces (open to atmosphere) becomes zero, then the height $h$ is given by:

A U-tube of base length " $lambda$ " filled with same volume of two liquids of densities $rho$ and $2 rho$ is moving with an acceleration "a" on the horizontal plane. If the height difference between the two surfaces (open to atmosphere) becomes zero, then the height $h$ is given by:

physics-General

Which of the following is the true structure of H₂O₂?

Which of the following is the true structure of H₂O₂?

chemistry-General

parallel

In meter bridge experiment the observation table and circuit diagram are shown in figure

Which is the readings is not taken correctly ?

In meter bridge experiment the observation table and circuit diagram are shown in figure

Which is the readings is not taken correctly ?

physics-General

Consider the meter bridge shown in the figure below

The resistance X has temperature $alpha subscript 1 end subscript$ coefficient and form resistance box $alpha subscript 1 end subscript$ has $left square bracket 9 capital omega blank s h o w n blank right square bracket$ For shown situation balance point is at 10cm from left end, if temperature of system increases by $capital delta T$ due to joule heating, then the shift in the balance point is (Assume that only the resistance of X and resistance box changes due to change in temperature and there is no other effect

Consider the meter bridge shown in the figure below

The resistance X has temperature $alpha subscript 1 end subscript$ coefficient and form resistance box $alpha subscript 1 end subscript$ has $left square bracket 9 capital omega blank s h o w n blank right square bracket$ For shown situation balance point is at 10cm from left end, if temperature of system increases by $capital delta T$ due to joule heating, then the shift in the balance point is (Assume that only the resistance of X and resistance box changes due to change in temperature and there is no other effect

physics-General

In post office box, the graph of galvanameter deflection versus resistance R (pulled out of resistance box) for the ration 100 : 1 is given as shown (due to unsuitable values of R, galvonometer shows deflection) The two consecutive values of R are shown in the figure.

The value of unknown resistance would be

In post office box, the graph of galvanameter deflection versus resistance R (pulled out of resistance box) for the ration 100 : 1 is given as shown (due to unsuitable values of R, galvonometer shows deflection) The two consecutive values of R are shown in the figure.

The value of unknown resistance would be

physics-General

parallel

If temperature scale is changed from ⁰C to ⁰F the numerical value of specific heat

If temperature scale is changed from ⁰C to ⁰F the numerical value of specific heat

physics-General

In the figure shown water is filled in a symmetrical container. Four pistons of equal area A are used at the four opening to keep the water in equilibrium. Now an additional force F is applied at each piston. The increase in the pressure at the centre of the container due to this addition is

In the figure shown water is filled in a symmetrical container. Four pistons of equal area A are used at the four opening to keep the water in equilibrium. Now an additional force F is applied at each piston. The increase in the pressure at the centre of the container due to this addition is

physics-General

A cylindrical container of radius 'R' and height ' h ' is completely filled with a liquid. Two horizontal L shaped pipes of small cross-section area 'a' are connected to the cylinder as shown in the figure. Now the two pipes are opened and fluid starts coming out of the pipes horizontally in opposite directions. Then the torque due to ejected liquid on the system is:

A cylindrical container of radius 'R' and height ' h ' is completely filled with a liquid. Two horizontal L shaped pipes of small cross-section area 'a' are connected to the cylinder as shown in the figure. Now the two pipes are opened and fluid starts coming out of the pipes horizontally in opposite directions. Then the torque due to ejected liquid on the system is:

physics-General

parallel

A cylindrical vessel filled with water is released on an inclined surface of angle $theta$ as shown in figure. The friction coefficient of surface with vessel is $mu left parenthesis less than t a n invisible function application theta right parenthesis$ . Then the constant angle made by the surface of water with the incline will be:

A cylindrical vessel filled with water is released on an inclined surface of angle $theta$ as shown in figure. The friction coefficient of surface with vessel is $mu left parenthesis less than t a n invisible function application theta right parenthesis$ . Then the constant angle made by the surface of water with the incline will be:

physics-General

Two spheres $P$ and $Q$ of equal radii have densities $rho subscript 1 end subscript$ and $rho subscript 2 comma end subscript$ respectively. The spheres are connected by a massless string and placed in liquids $L subscript 1 end subscript$ and $L subscript 2 end subscript$ of densities $sigma subscript 1 end subscript$ and $sigma subscript 2 end subscript$ and viscosities $eta subscript 1 end subscript$ and $eta subscript 2 comma end subscript$ respectively. They float in equilibrium with the sphere $P$ in $L subscript 1 end subscript$ and sphere $Q$ in $L subscript 2 end subscript$ and the string being taut (see figure). If sphere $P$ along in $L subscript 2 end subscript$ has terminal velocity $stack Y with rightwards arrow on top subscript p end subscript$ and $Q$ in $L subscript 1 end subscript$ has terminal velocity $stack V with rightwards arrow on top subscript Q end subscript$ , then

Two spheres $P$ and $Q$ of equal radii have densities $rho subscript 1 end subscript$ and $rho subscript 2 comma end subscript$ respectively. The spheres are connected by a massless string and placed in liquids $L subscript 1 end subscript$ and $L subscript 2 end subscript$ of densities $sigma subscript 1 end subscript$ and $sigma subscript 2 end subscript$ and viscosities $eta subscript 1 end subscript$ and $eta subscript 2 comma end subscript$ respectively. They float in equilibrium with the sphere $P$ in $L subscript 1 end subscript$ and sphere $Q$ in $L subscript 2 end subscript$ and the string being taut (see figure). If sphere $P$ along in $L subscript 2 end subscript$ has terminal velocity $stack Y with rightwards arrow on top subscript p end subscript$ and $Q$ in $L subscript 1 end subscript$ has terminal velocity $stack V with rightwards arrow on top subscript Q end subscript$ , then

physics-General

A wooden cylinder of diameter 4r, height H and density $rho divided by 3$ is kept on a hole of diameter 2r of a tank, filled with liquid of density $rho$ as shown in the figure. The block in the above question is maintained at the position by external means and the level of liquid is lowered. The height $h subscript 2 end subscript$ when this external force reduces to zero is :–

A wooden cylinder of diameter 4r, height H and density $rho divided by 3$ is kept on a hole of diameter 2r of a tank, filled with liquid of density $rho$ as shown in the figure. The block in the above question is maintained at the position by external means and the level of liquid is lowered. The height $h subscript 2 end subscript$ when this external force reduces to zero is :–

physics-General

parallel

A wooden cylinder of diameter 4r, height H and density $rho divided by 3$ is kept on a hole of diameter 2r of a tank, filled with liquid of density $rho$ as shown in the figure. Now level of the liquid starts decreasing slowly. When the level of liquid is at a height $h subscript 1 end subscript$ above the cylinder the block starts moving up. At what value of $h subscript 1 end subscript$ , will the block rise :–

A wooden cylinder of diameter 4r, height H and density $rho divided by 3$ is kept on a hole of diameter 2r of a tank, filled with liquid of density $rho$ as shown in the figure. Now level of the liquid starts decreasing slowly. When the level of liquid is at a height $h subscript 1 end subscript$ above the cylinder the block starts moving up. At what value of $h subscript 1 end subscript$ , will the block rise :–

physics-General

A glass tube of uniform internal radius (r) has a valve separating the two identical ends. Initially, the valve is in a tightly closed position. End 1 has a hemispherical soap bubble of radius r. End 2 has sub–hemispherical soap bubble as shown in figure. Just after opening the valve,

A glass tube of uniform internal radius (r) has a valve separating the two identical ends. Initially, the valve is in a tightly closed position. End 1 has a hemispherical soap bubble of radius r. End 2 has sub–hemispherical soap bubble as shown in figure. Just after opening the valve,

physics-General

Water is filled up to a height h in a beaker of radius R as shown in the figure. The density of water is $rho$ , the surface tension of water is T and the atmospheric pressure is $P subscript 0 end subscript$ . Consider a vertical section ABCD of the water column through a diameter of the beaker. The force on water on one side of this section by water on the other side of this section has magnitude :–

Water is filled up to a height h in a beaker of radius R as shown in the figure. The density of water is $rho$ , the surface tension of water is T and the atmospheric pressure is $P subscript 0 end subscript$ . Consider a vertical section ABCD of the water column through a diameter of the beaker. The force on water on one side of this section by water on the other side of this section has magnitude :–

physics-General

parallel

card img

With Turito Academy.

card img

With Turito Foundation.

card img

Get an Expert Advice From Turito.

Turito Academy

card img

With Turito Academy.

Test Prep

card img

With Turito Foundation.