(a) The pressure of a liquid is given by the relation:

P = hρg

Where,

P = Pressure

h = Height of the liquid column

ρ = Density of the liquid

g = Acceleration due to the gravity

It can be inferred that pressure is directly proportional to height. Hence, the blood pressure in human vessels depends on the height of the blood column in the body. The height of the blood column is more at the feet than it is at the brain. Hence, the blood pressure at the feet is more than it is at the brain.

(b) Density of air is the maximum near the sea level. Density of air decreases with increase in height from the surface. At a height of about 6 km, density decreases to nearly half of its value at the sea level. Atmospheric pressure is proportional to density. Hence, at a height of 6 km from the surface, it decreases to nearly half of its value at the sea level.

(c) When force is applied on a liquid, the pressure in the liquid is transmitted in all directions. Hence, hydrostatic pressure does not have a fixed direction and it is a scalar physical quantity.

(a) The angle between the tangent to the liquid surface at the point of contact and the surface inside the liquid is called the angle of contact (θ), as shown in the given figure.

S_la, S_sa, and S_sl are the respective interfacial tensions between the liquid-air, solid-air, and solid-liquid interfaces. At the line of contact, the surface forces between the three media must be in equilibrium, i.e.,

The angle of contact θ , is obtuse if S_sa< S_la (as in the case of mercury on glass). This angle is acute if S_sl < S_la (as in the case of water on glass).

(b) Mercury molecules (which make an obtuse angle with glass) have a strong force of attraction between themselves and a weak force of attraction toward solids. Hence, they tend to form drops.

On the other hand, water molecules make acute angles with glass. They have a weak force of attraction between themselves and a strong force of attraction toward solids. Hence, they tend to spread out.

(c) Surface tension is the force acting per unit length at the interface between the plane of a liquid and any other surface. This force is independent of the area of the liquid surface. Hence, surface tension is also independent of the area of the liquid surface.

(d) Water with detergent dissolved in it has small angles of contact (θ). This is because for a small θ, there is a fast capillary rise of the detergent in the cloth. The capillary rise of a liquid is directly proportional to the cosine of the angle of contact (θ). If θ is small, then cosθ will be large and the rise of the detergent water in the cloth will be fast.

(e) A liquid tends to acquire the minimum surface area because of the presence of surface tension. The surface area of a sphere is the minimum for a given volume. Hence, under no external forces, liquid drops always take spherical shape.

(a) decreases

The surface tension of a liquid is inversely proportional to temperature.

(b) increases; decreases

Most fluids offer resistance to their motion. This is like internal mechanical friction, known as viscosity. Viscosity of gases increases with temperature, while viscosity of liquids decreases with temperature.

(c) Shear strain; Rate of shear strain

With reference to the elastic modulus of rigidity for solids, the shearing force is proportional to the shear strain. With reference to the elastic modulus of rigidity for fluids, the shearing force is proportional to the rate of shear strain.

(d) Conservation of mass/Bernoulli’s principle

For a steady-flowing fluid, an increase in its flow speed at a constriction follows the conservation of mass/Bernoulli’s principle.

(e) Greater

For the model of a plane in a wind tunnel, turbulence occurs at a greater speed than it does for an actual plane. This follows from Bernoulli’s principle and different Reynolds’ numbers are associated with the motions of the two planes.

(a) When air is blown under a paper, the velocity of air is greater under the paper than it is above it. As per Bernoulli’s principle, atmospheric pressure reduces under the paper. This makes the paper fall. To keep a piece of paper horizontal, one should blow over it. This increases the velocity of air above the paper. As per Bernoulli’s principle, atmospheric pressure reduces above the paper and the paper remains horizontal.

(b) According to the equation of continuity:

Area × Velocity = Constant

For a smaller opening, the velocity of flow of a fluid is greater than it is when the opening is bigger. When we try to close a tap of water with our fingers, fast jets of water gush through the openings between our fingers. This is because very small openings are left for the water to flow out of the pipe. Hence, area and velocity are inversely proportional to each other.

(c) The small opening of a syringe needle controls the velocity of the blood flowing out. This is because of the equation of continuity. At the constriction point of the syringe system, the flow rate suddenly increases to a high value for a constant thumb pressure applied.

(d) When a fluid flows out from a small hole in a vessel, the vessel receives a backward thrust. A fluid flowing out from a small hole has a large velocity according to the equation of continuity:

Area × Velocity = Constant

According to the law of conservation of momentum, the vessel attains a backward velocity because there are no external forces acting on the system.

(e) A spinning cricket ball has two simultaneous motions – rotatory and linear. These two types of motion oppose the effect of each other. This decreases the velocity of air flowing below the ball. Hence, the pressure on the upper side of the ball becomes lesser than that on the lower side. An upward force acts upon the ball. Therefore, the ball takes a curved path. It does not follow a parabolic path.

Mass of the girl, m = 50 kg

Diameter of the heel, d = 1 cm = 0.01 m

Radius of the heel, r 

Area of the heel 

= π (0.005)²

= 7.85 × 10^–5 m²

Force exerted by the heel on the floor:

F = mg

= 50 × 9.8

= 490 N

Pressure exerted by the heel on the floor:

= 6.24 × 10⁶ N m^–2

Therefore, the pressure exerted by the heel on the horizontal floor is
6.24 × 10⁶ Nm^–2.

10.5 m

Density of mercury, ρ₁ = 13.6 × 10³ kg/m³

Height of the mercury column, h₁ = 0.76 m

Density of French wine, ρ₂ = 984 kg/m³

Height of the French wine column = h₂

Acceleration due to gravity, g = 9.8 m/s²

The pressure in both the columns is equal, i.e.,

Pressure in the mercury column = Pressure in the French wine column

= 10.5 m

Hence, the height of the French wine column for normal atmospheric pressure is 10.5 m.

Answer: Yes

The maximum allowable stress for the structure, P = 10⁹ Pa

Depth of the ocean, d = 3 km = 3 × 10³ m

Density of water, ρ = 10³ kg/m³

Acceleration due to gravity, g = 9.8 m/s²

The pressure exerted because of the sea water at depth, d = ρdg

= 3 × 10³ × 10³ × 9.8

= 2.94 × 10⁷ Pa

The maximum allowable stress for the structure (10⁹ Pa) is greater than the pressure of the sea water (2.94 × 10⁷ Pa). The pressure exerted by the ocean is less than the pressure that the structure can withstand. Hence, the structure is suitable for putting up on top of an oil well in the ocean.

The maximum mass of a car that can be lifted, m = 3000 kg

Area of cross-section of the load-carrying piston, A = 425 cm² = 425 × 10^–4 m²

The maximum force exerted by the load, F = mg

= 3000 × 9.8

= 29400 N

The maximum pressure exerted on the load-carrying piston, 

= 6.917 × 10⁵ Pa

Pressure is transmitted equally in all directions in a liquid. Therefore, the maximum pressure that the smaller piston would have to bear is 6.917 × 10⁵ Pa.

The given system of water, mercury, and methylated spirit is shown as follows:

Height of the spirit column, h₁ = 12.5 cm = 0.125 m

Height of the water column, h₂ = 10 cm = 0.1 m

P₀ = Atmospheric pressure

ρ₁ = Density of spirit

ρ₂ = Density of water

Pressure at point B = 

Pressure at point D = 

Pressure at points B and D is the same.

Therefore, the specific gravity of spirit is 0.8.

Height of the water column, h₁ = 10 + 15 = 25 cm

Height of the spirit column, h₂ = 12.5 + 15 = 27.5 cm

Density of water, ρ₁ = 1 g cm^–3

Density of spirit, ρ₂ = 0.8 g cm^–3

Density of mercury = 13.6 g cm^–3

Let h be the difference between the levels of mercury in the two arms.

Pressure exerted by height h, of the mercury column:

= hρg

= h × 13.6g … (i)

Difference between the pressures exerted by water and spirit:

= g(25 × 1 – 27.5 × 0.8)

= 3g … (ii)

Equating equations (i) and (ii), we get:

13.6 hg = 3g

h = 0.220588 ≈ 0.221 cm

Hence, the difference between the levels of mercury in the two arms is 0.221 cm.

No. The Bernoulli’s equation cannot be used to describe the flow of water through a rapid in a river because of the turbulent flow of water. This principle can only be applied to a streamline flow.

No. It does not matter if one uses gauge pressure instead of absolute pressure while applying Bernoulli’s equation. The two points where Bernoulli’s equation is applied should have significantly different atmospheric pressures.

9.8 × 10² Pa

Length of the horizontal tube, l = 1.5 m

Radius of the tube, r = 1 cm = 0.01 m

Diameter of the tube, d = 2r = 0.02 m

Glycerine is flowing at a rate of 4.0 × 10^–3 kg s^–1.

M = 4.0 × 10^–3 kg s^–1

Density of glycerine, ρ = 1.3 × 10³ kg m^–3

Viscosity of glycerine, η = 0.83 Pa s

Volume of glycerine flowing per sec:

= 3.08 × 10^–6 m³ s^–1

According to Poiseville’s formula, we have the relation for the rate of flow:

Where, p is the pressure difference between the two ends of the tube

= 9.8 × 10² Pa

Reynolds’ number is given by the relation:

Reynolds’ number is about 0.3. Hence, the flow is laminar.

Speed of wind on the upper surface of the wing, V₁ = 70 m/s

Speed of wind on the lower surface of the wing, V₂ = 63 m/s

Area of the wing, A = 2.5 m²

Density of air, ρ = 1.3 kg m^–3

According to Bernoulli’s theorem, we have the relation:

Where,

P₁ = Pressure on the upper surface of the wing

P₂ = Pressure on the lower surface of the wing

The pressure difference between the upper and lower surfaces of the wing provides lift to the aeroplane.

Lift on the wing 

= 1512.87

= 1.51 × 10³ N

Therefore, the lift on the wing of the aeroplane is 1.51 × 10³ N.

(a)

Take the case given in figure (b).

Where,

A₁ = Area of pipe1

A₂ = Area of pipe 2

V₁ = Speed of the fluid in pipe1

V₂ = Speed of the fluid in pipe 2

From the law of continuity, we have:

When the area of cross-section in the middle of the venturimeter is small, the speed of the flow of liquid through this part is more. According to Bernoulli’s principle, if speed is more, then pressure is less.

Pressure is directly proportional to height. Hence, the level of water in pipe 2 is less.

Therefore, figure (a) is not possible.

Area of cross-section of the spray pump, A₁ = 8 cm² = 8 × 10^–4 m²

Number of holes, n = 40

Diameter of each hole, d = 1 mm = 1 × 10^–3 m

Radius of each hole, r = d/2 = 0.5 × 10^–3 m

Area of cross-section of each hole, a = πr² = π (0.5 × 10^–3)² m²

Total area of 40 holes, A₂ = n × a

= 40 × π (0.5 × 10^–3)² m²

= 31.41 × 10^–6 m²

Speed of flow of liquid inside the tube, V₁ = 1.5 m/min = 0.025 m/s

Speed of ejection of liquid through the holes = V₂

According to the law of continuity, we have:

= 0.633 m/s

Therefore, the speed of ejection of the liquid through the holes is 0.633 m/s.

The weight that the soap film supports, W = 1.5 × 10^–2 N

Length of the slider, l = 30 cm = 0.3 m

A soap film has two free surfaces.

∴Total length = 2l = 2 × 0.3 = 0.6 m

Surface tension,

 = 

Therefore, the surface tension of the film is 2.5 × 10^–2 N m^–1.

Take case (a):

The length of the liquid film supported by the weight, l = 40 cm = 0.4 cm

The weight supported by the film, W = 4.5 × 10^–2 N

A liquid film has two free surfaces.

∴Surface tension

In all the three figures, the liquid is the same. Temperature is also the same for each case. Hence, the surface tension in figure (b) and figure (c) is the same as in figure (a), i.e., 5.625 × 10^–2 N m^–1.

Since the length of the film in all the cases is 40 cm, the weight supported in each case is 4.5 × 10^–2 N.

The pressure inside the drop of mercury of radius 3.00 mm at room temperature- 

Radius of the mercury drop, r = 3.00 mm = 3 × 10^–3 m

Surface tension of mercury, S = 4.65 × 10^–1 N m^–1

Atmospheric pressure, P₀ = 1.01 × 10⁵ Pa

Total pressure inside the mercury drop

= Excess pressure inside mercury + Atmospheric pressure

= 1.0131 × 10⁵

= 1.01 ×10⁵ Pa

Excess pressure 

 = 310 Pa