Learn Additional Exercise 10 with Free Lessons & Tips

Base area of the given tank, A = 1.0 m²

Area of the hinged door, a = 20 cm² = 20 × 10^–4 m²

Density of water, ρ₁ = 10³ kg/m³

Density of acid, ρ₂ = 1.7 × 10³ kg/m³

Height of the water column, h₁ = 4 m

Height of the acid column, h₂ = 4 m

Acceleration due to gravity, g = 9.8

Pressure due to water is given as:

Pressure due to acid is given as:

Pressure difference between the water and acid columns:

Hence, the force exerted on the door = ΔP × a

= 2.744 × 10⁴ × 20 × 10^–4

= 54.88 N

Therefore, the force necessary to keep the door closed is 54.88 N.

(a) 96 cm of Hg & 20 cm of Hg; 58 cm of Hg & –18 cm of Hg

(b) 19 cm

(a) For figure (a)

Atmospheric pressure, P₀ = 76 cm of Hg

Difference between the levels of mercury in the two limbs gives gauge pressure

Hence, gauge pressure is 20 cm of Hg.

Absolute pressure = Atmospheric pressure + Gauge pressure

= 76 + 20 = 96 cm of Hg

For figure (b)

Difference between the levels of mercury in the two limbs = –18 cm

Hence, gauge pressure is –18 cm of Hg.

Absolute pressure = Atmospheric pressure + Gauge pressure

= 76 cm – 18 cm = 58 cm

(b) 13.6 cm of water is poured into the right limb of figure (b).

Relative density of mercury = 13.6

Hence, a column of 13.6 cm of water is equivalent to 1 cm of mercury.

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

The pressure in the right limb is given as:

Atmospheric pressure + 1 cm of Hg

= 76 + 1 = 77 cm of Hg … (i)

The mercury column will rise in the left limb.

Hence, pressure in the left limb, 

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

77 = 58 + h

∴h = 19 cm

Hence, the difference between the levels of mercury in the two limbs will be 19 cm.

Yes,Two vessels having the same base area have identical force and equal pressure acting on their common base area. Since the shapes of the two vessels are different, the force exerted on the sides of the vessels has non-zero vertical components. When these vertical components are added, the total force on one vessel comes out to be greater than that on the other vessel. Hence, when these vessels are filled with water to the same height, they give different readings on a weighing scale.

Gauge pressure, P = 2000 Pa

Density of whole blood, ρ = 1.06 × 10³ kg m^–3

Acceleration due to gravity, g = 9.8 m/s²

Height of the blood container = h

Pressure of the blood container, P = hρg

The blood may enter the vein if the blood container is kept at a height greater than 0.1925 m, i.e., about 0.2 m.

(a) 1.966 m/s (b) Yes

(a) Diameter of the artery, d = 2 × 10^–3 m

Viscosity of blood, 

Density of blood, ρ = 1.06 × 10³ kg/m³

Reynolds’ number for laminar flow, N_R = 2000

The largest average velocity of blood is given as:

Therefore, the largest average velocity of blood is 1.966 m/s.

(b) As the fluid velocity increases, the dissipative forces become more important. This is because of the rise of turbulence. Turbulent flow causes dissipative loss in a fluid.

(a)Radius of the artery, r = 2 × 10^–3 m

Diameter of the artery, d = 2 × 2 × 10^–3 m = 4 × 10^{– 3} m

Viscosity of blood, 

Density of blood, ρ = 1.06 × 10³ kg/m³

Reynolds’ number for laminar flow, N_R = 2000

The largest average velocity of blood is given by the relation:

Therefore, the largest average velocity of blood is 0.983 m/s.

(b) Flow rate is given by the relation:

R = π r²

Therefore, the corresponding flow rate is.

The area of the wings of the plane, A = 2 × 25 = 50 m²

Speed of air over the lower wing, V₁ = 180 km/h = 50 m/s

Speed of air over the upper wing, V₂ = 234 km/h = 65 m/s

Density of air, ρ = 1 kg m^–3

Pressure of air over the lower wing = P₁

Pressure of air over the upper wing= P₂

The upward force on the plane can be obtained using Bernoulli’s equation as:

The upward force (F) on the plane can be calculated as:

Using Newton’s force equation, we can obtain the mass (m) of the plane as:

∼ 4400 kg

Hence, the mass of the plane is about 4400 kg.

Terminal speed = 5.8 cm/s; Viscous force = 3.9 × 10^–10 N

Radius of the given uncharged drop, r = 2.0 × 10^–5 m

Density of the uncharged drop, ρ = 1.2 × 10³ kg m^–3

Viscosity of air, 

Density of air  can be taken as zero in order to neglect buoyancy of air.

Acceleration due to gravity, g = 9.8 m/s²

Terminal velocity (v) is given by the relation:

Hence, the terminal speed of the drop is 5.8 cm s^–1.

The viscous force on the drop is given by:

Hence, the viscous force on the drop is 3.9 × 10^–10 N.

Angle of contact between mercury and soda lime glass, θ = 140°

Radius of the narrow tube, r = 1 mm = 1 × 10^–3 m

Surface tension of mercury at the given temperature, s = 0.465 N m^–1

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

Dip in the height of mercury = h

Acceleration due to gravity, g = 9.8 m/s²

Surface tension is related with the angle of contact and the dip in the height as:

Here, the negative sign shows the decreasing level of mercury. Hence, the mercury level dips by 5.34 mm.

Diameter of the first bore, d₁ = 3.0 mm = 3 × 10^–3 m

Diameter of the second bore, = 6.0 mm

Surface tension of water, s = 7.3 × 10^–2 N m^–1

Angle of contact between the bore surface and water, θ= 0

Density of water, ρ =1.0 × 10³ kg/m^–3

Acceleration due to gravity, g = 9.8 m/s²

Let h₁ and h₂ be the heights to which water rises in the first and second tubes respectively. These heights are given by the relations:

The difference between the levels of water in the two limbs of the tube can be calculated as:

Hence, the difference between levels of water in the two bores is 4.97 mm.