Class 11 Physics Notes
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- Unit 1 : Measurement
- Unit 2 : Vectors
- Unit 3 : Motion in Straight Line
- Unit 4 : Projectile Motion & Circular Motion
- Unit 5 : Laws of Motion
- Unit 6 : Work, Power & Energy
- Unit 7 : Rotational Motion
- Unit 8 : Gravitation
- Unit 9 : Elasticity
- Unit 10 : Hydrostatics
- Unit 11 : Hydrodynamics
- Unit 12 : Surface Tension
- Unit 13 : Thermometry and Calorimetry
- Unit 14 : Kinetic Theory of Gases
- Unit 15 : Thermodynmics
- Unit 16 : Transmission of Heat
- Unit 17 : Oscillations
- Unit 18 : Waves & Sound
Unit 10 : Hydrostatics
MECHANICAL PROPERTIES OF FLUIDS
Fluids
Fluids are those substances which can flow when an external force is applied on it.
Liquids and gases are fluids.
Fluids do not have finite shape but takes the shape of the containing vessel.
The total normal force exerted by liquid at rest on a given surface is called thrust of liquid.
The SI unit of thrust is newton.
In fluid mechanics the following properties of fluid would be considered
(i) When the fluid is at rest - hydrostatics
(ii) When the fluid is in motion - hydrodynamics
Liquids and gases are fluids.
Fluids do not have finite shape but takes the shape of the containing vessel.
The total normal force exerted by liquid at rest on a given surface is called thrust of liquid.
The SI unit of thrust is newton.
In fluid mechanics the following properties of fluid would be considered
(i) When the fluid is at rest - hydrostatics
(ii) When the fluid is in motion - hydrodynamics
Pressure Exerted by the Liquid
The normal force exerted by a liquid per unit area of the surface in contact is called pressure of liquid orhydrostatic pressure.
Pressure exerted by a liquid column
p = hฯg
Where, h = height of liquid column, ฯ = density of liquid
and g = acceleration due to gravity
Mean pressure on the walls of a vessel containing liquid upto height h is (hฯg / 2).
Pascal’s Law
The increase in pressure at a point in the enclosed liquid in equilibrium is transmitted equally in all directions in liquid and to the Walls of the container.
The working of hydraulic lift, hydraulic press and hydraulic brakes are based on Pascal’s law.
The working of hydraulic lift, hydraulic press and hydraulic brakes are based on Pascal’s law.
Atmospheric Pressure
The pressure exerted by the atmosphere on earth is atmospheric pressure.
It is about 100000 N/m2.
It is equivalent to a weight of 10 tones on 1 m2.
At sea level, atmospheric pressure is equal to 76 cm of mercury column. Then, atmospheric pressure
= hdg = 76 x 13.6 x 980 dyne/cm2
[The atmospheric pressure does not crush our body because the pressure of the blood flowing through our circulatory system] balanced this pressure.]
Atmospheric pressure is also measured in torr and bar.
1 torr = 1 mm of mercury column
1 bar = l05 Pa
Aneroid barometer is used to measure atmospheric pressure.
It is about 100000 N/m2.
It is equivalent to a weight of 10 tones on 1 m2.
At sea level, atmospheric pressure is equal to 76 cm of mercury column. Then, atmospheric pressure
= hdg = 76 x 13.6 x 980 dyne/cm2
[The atmospheric pressure does not crush our body because the pressure of the blood flowing through our circulatory system] balanced this pressure.]
Atmospheric pressure is also measured in torr and bar.
1 torr = 1 mm of mercury column
1 bar = l05 Pa
Aneroid barometer is used to measure atmospheric pressure.
Buoyancy
When a body is partially or fully immersed in a fluid an upward force acts on it, which is called buoyant force or simply buoyancy.
The buoyant force acts at the centre of gravity of the liquid displaced] by the immersed part of the body and this point is called the centre buoyancy.
The buoyant force acts at the centre of gravity of the liquid displaced] by the immersed part of the body and this point is called the centre buoyancy.
Archimedes’ Principle
When a body is partially or fully immersed in a liquid, it loses some of its weight. and it is equal to the weight of the liquid displaced by the immersed part of the body.
If T is the observed weight of a body of density ฯ when it is fully immersed in a liquid of density p, then real weight of the body
w = T / ( 1 – p / ฯ)
If T is the observed weight of a body of density ฯ when it is fully immersed in a liquid of density p, then real weight of the body
w = T / ( 1 – p / ฯ)
Laws of Floatation
A body will float in a liquid, if the weight of the body is equal to the weight of the liquid displaced by the immersed part of the body.
If W is the weight of the body and w is the buoyant force, then
(a) If W > w, then body will sink to the bottom of the liquid.
(b) If W < w, then body will float partially submerged in the liquid.
(c) If W = w, then body will float in liquid if its whole volume is just immersed in the liquid,
The floating body will be in stable equilibrium if meta-centre (centre of buoyancy) lies vertically above the centre of gravity of the body.
The floating body will be in unstable equilibrium if meta-centre (centre of buoyancy) lies vertically below the centre of gravity of the body.
The floating body will be in neutral equilibrium if meta-centre (centre of buoyancy) coincides with the centre of gravity of the body.
If W is the weight of the body and w is the buoyant force, then
(a) If W > w, then body will sink to the bottom of the liquid.
(b) If W < w, then body will float partially submerged in the liquid.
(c) If W = w, then body will float in liquid if its whole volume is just immersed in the liquid,
The floating body will be in stable equilibrium if meta-centre (centre of buoyancy) lies vertically above the centre of gravity of the body.
The floating body will be in unstable equilibrium if meta-centre (centre of buoyancy) lies vertically below the centre of gravity of the body.
The floating body will be in neutral equilibrium if meta-centre (centre of buoyancy) coincides with the centre of gravity of the body.
Density and Relative Density
Density of a substance is defined as the ratio of its mass to its volume.
Density of a liquid = Mass / Volume
Density of water = 1 g/cm3 or l03 kg/m3
It is scalar quantity and its dimensional formula is [ML-3].
Relative density of a substance is defined as the ratio of its density to the density of water at 4°C,
Relative density = Density of substance / Density of water at 4°C
= Weight of substance in air / Loss of weight in water
Relative density also known as specific gravity has no unit, no dimensions.
For a solid body, density of body = density of substance
While for a hollow body, density of body is lesser than that of Substance.
When immiscible liquids of different densities are poured in a container, the liquid of highest density will be at the bottom while, that of lowest density at the top and interfaces will be plane.
Density of a liquid = Mass / Volume
Density of water = 1 g/cm3 or l03 kg/m3
It is scalar quantity and its dimensional formula is [ML-3].
Relative density of a substance is defined as the ratio of its density to the density of water at 4°C,
Relative density = Density of substance / Density of water at 4°C
= Weight of substance in air / Loss of weight in water
Relative density also known as specific gravity has no unit, no dimensions.
For a solid body, density of body = density of substance
While for a hollow body, density of body is lesser than that of Substance.
When immiscible liquids of different densities are poured in a container, the liquid of highest density will be at the bottom while, that of lowest density at the top and interfaces will be plane.
Density of a Mixture of Substances
When two liquids of mass m1 and m2 having density p1 and p2 are mixed together then density of mixture is
p = m1 + m2 / (m1 /p1 ) + (m2 + p2)
= p1p2 (m1 + m2) / (m1p2 + m2p1)
When two liquids of same mass m but of different densities p1 and p2 are mixed together then density of mixture is
p = 2p1p2 / p1 + p2
When two liquids of same volume V but of different densities p1 and p2 are mixed together then density of mixture is
p = p1 + p2 / 2
Density of a liquid varies with pressure
p = po [ 1 + ฮp / K]
where, po = initial density of the liquid, K = bulk modulus of elasticity of the liquid and ฮp = change in pressure
p = m1 + m2 / (m1 /p1 ) + (m2 + p2)
= p1p2 (m1 + m2) / (m1p2 + m2p1)
When two liquids of same mass m but of different densities p1 and p2 are mixed together then density of mixture is
p = 2p1p2 / p1 + p2
When two liquids of same volume V but of different densities p1 and p2 are mixed together then density of mixture is
p = p1 + p2 / 2
Density of a liquid varies with pressure
p = po [ 1 + ฮp / K]
where, po = initial density of the liquid, K = bulk modulus of elasticity of the liquid and ฮp = change in pressure
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