\nWashing with water doesn\u2019t remove grease stains from clothes but addition of detergent removes the molecules of greasy substances. (MARCH-2010)<\/span>
\na) Which property of a liquid causes the above effect?
\nb) A single drop of liquid is split into 8 identical drops. What will be the excess pressure in each drop?
\nc) How can the coefficient of viscosity of a highly viscous liquid be determined by Stokes\u2019 method?
\nAnswer:
\na) Surface tension
\nb) If R is the radius of drop;
\n
![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-1.png\")
\nFrom eq (1)and,(2) we get, the excess pressure inside the smaller drop increases two times,
\nc) If a body is moving through a fluid, its velocity is influenced by the viscosity of the medium. Consider a small sphere of radius\u2018a\u2019falling undergravity in air: The viscocity of air opposes the motion of the sphere. This opposing force is called viscous force and can be written as.
\nF = 6 \u03c0a\u03b7v
\nThis is called stokes, formula.
\nWhere \u03b7 is the coefficient of viscocity of the medium and v is the velocity of the body.<\/p>\n
Question 2. Question 3. Question 4. Question 5. Question 6. Question 7. Question 8. Question 9. Question 10. Question 11. Question 12. Question 13. Question 14. Question 15. Question 16. Question 17. Question 18. Question 19. Question 20. Question 21. Answer: Question 22. Question 23. Question 24. Question 25. Question 26.
\nWater does not wet the feathers of ducks. A physical quantity called angle of contact determines whether a liquid will spread on the surface of a solid or it will form droplets on it.\u00a0\u00a0(MAY-2010)<\/span>
\na) Define angle of contact.
\nb) A wire ring of internal radius 3 cm and external radius 3.2 cm is rested on the surface of a liquid and is then raised. An extra pulling force equivalent to the weight of 3.03 g is required before the film breaks than it is after. Calculate the surface tension of the liquid.
\nc) Derive an expression for the capillary height of a liquid in a narrow tube.
\nAnswer:
\na) Angle of contact is the angle between the solid surface and the tangent drawn to the liquid surface at the point of contact inside the liquid.
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-2.png\")
\nConsider a capillary tube of radius \u2018a\u2019 dipped in a liquid of density p and surface tension S. If the liquid has a concave meniscus it will rise in the capillary tube. Let h be the rise of the liquid in the tube. Let p, be the pressure on the concave side of the meniscus and p0, that on the other side .
\nThe excess pressure on the concave side of the meniscus can be written as
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-3.png\")
\nWhere R is the radius of the concave meniscus. The tangent to the meniscus at point A makes an angle \u03b8 with the wall of the tube.
\nIn the right angled triangle ACO
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-4.png\")
\nConsidering two points M and N in the same horizontal level of a liquid at rest, pressure at N = pressure at M But pressure at M = \u03c11<\/sub>, the pressure over the concave meniscus and pressure at N = p0<\/sub> +h\u03c1g
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-5.png\")
<\/p>\n
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-6.png\")
——–
\nIf air is blown through the space between two discs BC and DE shown in the figure, the lower disc DE instead of being blown off from BC, will move towards BC.\u00a0(MAY-2010)<\/span>
\na) State the principle which is used to explain this phenomenon.
\nb) A garden hose having an internal diameter of 2 cm is connected to a lawn sprinkler that consists of an enclosure with 12 holes, each 0.2 cm in diameter. If the water in the hose has a speed 1.2 m\/s at what speed does it leave the sprinkler holes ?
\nc) Show that the speed of liquid flowing out of a small hole in a tank filled with liquid will be \u221a2gh where h is the height of liquid above the hole and g is the acceleration due to gravity.
\nAnswer:
\na) Bernoulli\u2019s theorem
\nb)
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-7.png\")
\nc)
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-8.png\")
\nConsider a tank containing a liquid of density \u03c1 with a small hole in its side. Let Y1<\/sub> be the height of the hole, and Y2<\/sub> be height of water in the tank. Applying Bemoullis equation at points (1) and (2) we get
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-9.png\")
\n(P1<\/sub> = Pa<\/sub>, the atmospheric pressure).
\nIf the cross sectional area of the tank A2<\/sub> is much larger than that of the hole (ie; A2<\/sub>>>A1<\/sub>), we take
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-10.png\")
<\/p>\n
\na) Hydraulic lift is a device used to lift heavy loads. State the principle behind the working of this device.\u00a0(MARCH-2011)<\/span>
\nb) The velocity of outflow of a liquid from an open tank is identical to that of a freely falling body.
\ni) Name this law and the principle behind the law.
\nii) Derive this law based on this principle.
\nAnswer:
\na) Pascals law
\nWhenever external pressure is applied on any part of a fluid contained in a vessel, it is transmitted – undiminished and equally in all directions.
\nb) i) Torricellis law
\nTorricellis law may be stated as the velocity of afflux through a hole at a depth \u2018h\u2019 will be equal to the velocity gained by a freely falling body when it travels a distance\u2018h\u2019.
\nie; v = \u221a2gh
\nii)
\n
\nConsider a tank containing a liquid of density \u03c1 with a small hole in its side. Let Y1<\/sub> be the height of the hole, and Y2<\/sub> be height of water in the tank. Applying Bemoullis equation at points (1) and (2) we get
\n
\n(P1<\/sub> = Pa<\/sub>, the atmospheric pressure).
\nIf the cross sectional area of the tank A2<\/sub> is much larger than that of the hole (ie; A2<\/sub>>>A1<\/sub>), we take
\n<\/p>\n
\na) A solid sphere falling through a viscous medium attains a constant velocity called terminal velocity after some time of its fall. What are the different forces acting on the sphere? Derive an expression for terminal velocity in terms of the coefficient of viscosity of the medium.\u00a0(MARCH-2011)<\/span>
\nb) Water kept in earthern pots gets cooled. Why?
\nAnswer:
\na) Viscous force, boyancy force and weight of the body
\nExpression for terminal velocity
\nConsider a sphere of radius \u2018a\u2019 density \u03c3 falling through a liquid of density a and viscocity \u03b7). The viscous force acting on the sphere can be written as
\nF = 6\u03c0a\u03b7v
\nWhere v is the velocity of sphere This force is acting in upward direction. When the viscous force is equal to the weight of the body in the medium, the net force on the body is zero. It moves with a constant velocity called the terminal velocity.
\nThe weight of a body in a medium,
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-11.png\")
\nb) Due to evaporation.<\/p>\n
\nThe rise or fall of a liquid against gravitational force through fine tubes is known as capillarity.\u00a0(MAY-2011)<\/span>
\na) Give an example for capillarity from practical life.
\nb) Derive an expression for the capillary rise through a capillary tube.
\nOR
\nWhen we blow between two light balls suspended near by they approach each other.
\na) State the principle that can explain your observation.
\nb) Use this principle to arrive at Torricelli\u2019s equation.
\nAnswer:
\na) 1) A blotting paper absorbs ink by capillary action.
\n2) It is by capillary action that water reaches every branch of a plant from the stem.
\n3) We use a towel to dry our body after bath.
\n4) Due to capillary action, water rises to the surface of the fields and gets evaporated. To avoid this loss of water, the fields are ploughed.
\n5) A sponge retains water,
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-43.png\")
\nb) Consider a capillary tube of radius \u2018a\u2019 dipped in a liquid of density p and surface tension S. If the liquid has a concave meniscus it will rise in the capillary tube. Let h be the rise of the liquid in the tube. Let p, be the pressure on the concave side of the meniscus and p0, that on the other side .
\nThe excess pressure on the concave side of the meniscus can be written as
\n
\nWhere R is the radius of the concave meniscus. The tangent to the meniscus at the point A makes an angle \u03b8 with the wall of the tube.
\nIn the right angled triangle ACO
\n
\nConsidering two points M and N in the same hori-zontal level of a liquid at rest, pressure at N = pressure at M But pressure at M = \u03c11<\/sub>, the pressure over the concave meniscus and pressure at N = p0<\/sub> +h\u03c1g
\n
\nOR
\na) Bernoullis principle
\nThe total energy of an incompressible non-vis- cous liquid flowing from one place to another with-out friction is a constant.
\nb)
\n
\nConsider a tank containing a liquid of density \u03c1 with a small hole in its side. Let Y1<\/sub> be the height of the hole, and Y2<\/sub> be height of water in the tank. Applying Bemoullis equation at points (1) and (2) we get
\n
\n(P1<\/sub> = Pa<\/sub>, the atmospheric pressure).
\nIf the cross sectional area of the tank A2<\/sub> is much larger than that of the hole (ie; A2<\/sub>>>A1<\/sub>), we take
\n<\/p>\n
\nSay True or False :\u00a0(MAY-2011)<\/span>
\nA block of wood is floating in water its apparent weight is zero.
\nAnswer:
\nTrue<\/p>\n
\nMatch the following\u00a0(MARCH-2012)<\/span>
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-12.png\")
\nAnswer:
\n1 a) Reynold\u2019s number – viscosity
\nb) Magnus effect – Bernoullis principle
\nc) Action of detergent – Surface tension
\nd) \\(a_{1} v_{1}=a_{2} v_{2}\\) – Equation of continuity<\/p>\n
\nRaindrops falling due to gravity do not acquire high velocity.\u00a0(MARCH-2012)<\/span>
\na) Define the velocity of the raindrop when unbalanced force on it is zero.
\nb) Why do bubbles of air rise up through water?
\nc) The terminal velocity of a copper ball of radius 2.0 mm falling through a tank of oil at 20\u00b0C is 6.5 cm S-1<\/sup>. Compute the viscosity of the oil at 20\u00b0C., Density of oil is 1.5 x 103<\/sup> kg m-3<\/sup>, density of copper is 8.9 x 103<\/sup> kg m-3<\/sup>.
\nd) Viscosity of gases ……… with temperature, Whereas viscosity of liquids ……… with temperature.
\n(Increases\/decreases)
\nAnswer:
\na) Terminal velocity
\nb) Density of air bubble is less than water. Hence bubbles of air rise up through water.
\nc)
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-13.png\")
\nd) increases, decreases.<\/p>\n
\nSurface tension changes with temperature.\u00a0(MAY-2012)<\/span>
\na) Hot soup is tastier than cold one. Why.
\nb) What is the value of angle of contact for pure water?
\nc) Calculate the work done in breaking a water drop of radius 1 mm to 1000 droplets. Surface tension of water = 72 x 10-3<\/sup> N\/m.
\nAnswer:
\na) Surface tension decreases with temperature. For hot soup surface tension is small. So easily spread on tasty buds.
\nb) For pure water with glass \u03b8 = 0\u00b0
\nc) R = 1 mm = 10-3<\/sup>m
\nSince volume remains constant
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-14.png\")
<\/p>\n
\na) Is pressure in a liquid, scalar or vector.\u00a0(MAY-2012)<\/span>
\nb) State the law associated with liquid pressure.
\nc) Briefly explain the working of hydraulic lift.
\nAnswer:
\na) Pressure is a scalar
\nb) Pascal\u2019s law
\nThe pressure in a fluid at rest is the same at all points if they are at the same height.
\nc)
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-15.png\")
\nA hydraulic lift is used to lift heavy load. Consider a liquid enclosed in a vessel with two cylinders C1<\/sub> and C2<\/sub> attached as shown in the figure. The cylinders are provided with two pistons having areas A1<\/sub> and A2<\/sub> respectively.
\nIf F1<\/sub> is the force exerted on the area A1<\/sub>,
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-42.png\")
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-16.png\")
\nUsing this method we can lift heavy load by applying small force.<\/p>\n
\nA small water drop placed on a lotus leaf is spherical in shape.\u00a0(MARCH-2013)<\/span>
\na) Define surface tension.
\nb) Why does the small water drop acquire a spherical shape?
\nAnswer:
\na) Liquids acquire a free surface when poured in a container. These surfaces possess some additional energy. This phenomenon is known as surface tension.
\nb) Due to surface tension, the liquid surface always tends to have the minimum surface area . For a given volume, a sphere has a minimum surface area. Hence, small drops and bubbles of a liquid assume spherical shape.<\/p>\n
\nThree vessels of different shapes are filled with water to the same height \u2018h\u2019 and their bottom parts are connected to manometers measuring the pressure.The water levels in all the vessels remain the same.\u00a0(MARCH-2013)<\/span>
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-17.png\")
\na) Identify the above phenomenon.
\nb) Predict the pressure level shown by the manometers.
\nc) Blood pressure in humans is greater at the feet
\nthan at the brain. Explain why.
\nd) Pick the odd one out.
\nDentist chair, hydraulic brake, hydraulic press, venturi meter.
\nAnswer:
\na) Capillary rise
\nb) Pressure readings of these three vessels are same, (hydrostatic paradox)
\nc) Blood inside the human heart produces pressure to human body.
\nHence Blood pressure in human is greater at the feet than at the brain.
\nd) Venturi meter<\/p>\n
\nThe flow of an ideal fluid in a pipe of varying cross section is shown.\u00a0(MARCH-2013)<\/span>
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-18.png\")
\na) Differentiate between streamline flow and turbulent flow.
\nb) State and prove Bernoulli\u2019s principle.
\nAnswer:
\na) Streamline flow<\/strong>
\nThe flow of the fluid is said to be steady if at any given point, the velocity of each fluid particle remains constant in time.
\nThe path taken by a fluid particle under a steady flow is a streamline.
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-19.png\")
\nTurbulent flow<\/strong>
\nAs the speed of flow increase, at a certain speed the stream line flow stops and irregular flow starts. This irregular flow is called turbulent. The speed at which the turbulent flow starts is called critical speed.
\nb) As we move along a streamline the sum of the pressure (\u03c1), the kinetic energy per unit volume \\(\\frac { \u03c1v\u00b2 }{ 2 }\\) and the potential energy per unit volume (\u03c1gh) remains a constant
\nOR
\nThe total energy of an incompressible non-viscous liquid flowing from one place to another with-out friction is a constant.
\nMathematically Bernoulli\u2019s theorem can be written as
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-20.png\")
\nConsider an incompressible liquid flowing through a tube of non uniform cross section from region 1 to region 1. The corresponding values at the cross section and V1<\/sub> the speed of the flow at the region 1 . The corresponding values at region 2 are P2<\/sub>, A2<\/sub> and V1<\/sub> respectively. Region 1 is at a height h1<\/sub> and region 2 is at a height h2<\/sub>.
\nThe workdone on the liquid in a time \u2206t at the region 1 is given by
\nW1<\/sub> = P1<\/sub>\u2206V1<\/sub>
\nSimilarly the workdone in a time \u2206t at the region 2 is given by,
\nW2<\/sub>=- P2<\/sub>\u2206V2<\/sub> Net workdone
\n\u2206W1<\/sub> = P1<\/sub>\u2206V – P2<\/sub>\u2206V2<\/sub>.
\nAccording the equation of continuity
\n\u2206V1\u00a0<\/sub>= \u2206V2\u00a0<\/sub>= \u2206V
\n\u2206W = P1<\/sub>\u2206V – P2<\/sub>\u2206V
\n\u2206W = (P1<\/sub> – P2<\/sub>)\u2206V .
\nThis work done changes the kinetic energy, pressure energy and potential energy of the fluid.
\nIf \u2206m is the mass of liquid passing through the pipe in a time \u2206t. the change in Kinetic energy is given by
\n\\(\\Delta \\mathrm{k} . E=\\frac{1}{2} \\Delta \\mathrm{mV}_{2}^{2}-\\frac{1}{2} \\Delta \\mathrm{mV}_{1}^{2}\\) ……(2)
\nChange in gravitational potential energy is given by
\n\u2206P.E= \u2206mgh2<\/sub> – \u2206mgh1<\/sub> ………..(3)
\nAccording to work-energy theorem work done is equal to the change in kinetic energy plus the change in potential energy.
\nie; \u2206w =\u2206kE+\u2206PE ………(4)
\nSubstituting eq. 1,2 and 3 in eq. 4, we get
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-21.png\")
<\/p>\n
\nPick the odd one out from the following\u00a0(MAY-2013)<\/span>
\na) Atomiser
\nb) Hydraulic Lift
\nc) Venturimeter
\nd) Aerofoil
\nAnswer:
\nHydraulic lift
\nIt is based on Pascals law. All others are related to Bernoulis principle.<\/p>\n
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-22.png\")
\nWhen a thin tube is dipped in water, water rises in the tube through a height \u2018h\u2019\u00a0(MAY-2013)<\/span>
\na) Name the phenomenon.
\nb) Arrive at an expression for the height of the water rise (h) in the tube.
\nc) Will water overflow, if the tube is cut at level A? Justify your answer.
\nAnswer:
\na) Capillary rise
\nb)
\nb) Consider a capillary tube of radius \u2018a\u2019 dipped in a liquid of density p and surface tension S. If the liquid has a concave meniscus it will rise in the capillary tube. Let h be the rise of the liquid in the tube. Let p, be the pressure on the concave side of the meniscus and p0, that on the other side .
\nThe excess pressure on the concave side of the meniscus can be written as
\n
\nWhere R is the radius of the concave meniscus. The tangent to the meniscus at the point A makes an angle \u03b8 with the wall of the tube.
\nIn the right angled triangle ACO
\n
\nConsidering two points M and N in the same hori-zontal level of a liquid at rest, pressure at N = pressure at M But pressure at M = \u03c11<\/sub>, the pressure over the concave meniscus and pressure at N = p0<\/sub> +h\u03c1g
\n
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-24.png\")
\nWhere R is the radius of meniscus.
\nIf the length of capillary tube is less than h, the liquid rises to a length l1<\/sup> and adjusts the radius
\nof its meniscus to R1<\/sup> such that l1<\/sup>R1<\/sup> = hR
\nThus it is clear that if the capillary tube is of ini sufficient length, the liquid rises upto the upper
\nend of the tube and adjusts the radius of curvature of meniscus. The liquid cannot emerge in the form of fountain.<\/p>\n
\nFill in the blanks:\u00a0(MARCH-2014)<\/span>
\nVenturimeter: Bernoulli\u2019s theorem
\nHydraulic lift: ………….
\nAnswer:
\nPascals Law<\/p>\n
\nThe viscous force exists when there is a relative motion between the layers of the fluid.\u00a0(MARCH-2014)<\/span>
\na) State true or false: “The viscosity of gases decreases with an increase in temperature.\u201d
\nb) Obtain an impression for the termilan velocity at
\ntained by an object falling through a viscous medium.
\nc) The speed time graph of a falling sky diver is shown below. During the fall he opens his parachute.
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-25.png\")
\nd) Which part of the graph shows the sky diver falling with terminal velocity?
\nOR
\nThere is always an excess of pressure inside drops and bubbles.
\na) State true or false: \u201cA drop of liquid under no external forces is always spherical in shape.\u201d
\nb) Obtain an expression for excess of pressure in-side a drop of radius r and surface tension S.
\nc) Two soap bubbles A and B are blown at the end of a tube, as shown below.
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-26.png\")
\nChoose the correct answre: When the block C is removed,………..
\ni) the size of A increases and that of B decreases.
\nii) the size of B increases and that of A decreases
\niii) no change occurs in their sizes
\niv) their sizes become equal
\nAnswer:
\na) False
\nb)\u00a0Viscous force, boyancy force and weight of the body
\nExpression for terminal velocity<\/strong>
\nConsider a sphere of radius \u2018a\u2019 density \u03c3 falling through a liquid of density a and viscocity \u03b7). The viscous force acting on the sphere can be written as
\nF = 6\u03c0a\u03b7v
\nWhere v is the velocity of sphere This force is acting in upward direction. When the viscous force is equal to the weight of the body in the medium, the net force on the body is zero. It moves with a constant velocity called the terminal velocity.
\nThe weight of a body in a medium,
\n
\nc) D
\nOR
\na) True
\nb) The molecules near the surface of a drop experience a resultant pull inwards due to surface tension. Because of this inward pull, the pressure inside is greater than the outside. Due to the forces of surface tension, the drop tends to contract. But due to excess inside pressure, the drop tends to expand. When the drop is in equilibrium, these two forces will be equal and opposite.
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-27.png\")
\nConsider a drop of liquid of radius r .Let p1<\/sub> and p0<\/sub> be the values of pressure inside and outside the drop. Let the radius of liquid of drop increases by a small amount \u2206r under the pressure difference. The outward force acting on the surface of the drop,
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-28.png\")
\nc) i)<\/p>\n
\n
\nWhen air is blown in between the two balls, will they attract or repel?\u00a0\u00a0(MAY-2013)<\/span>
\nState the principle that explains your observation.
\nUsing this principle, derive Torricelli\u2019s equation [Speed of Efflux]
\nAnswer:
\na) \u2206ttract each other
\nb) Bernoulli\u2019s principle
\n(OR)
\nThe total energy of an incompressible non-viscous liquid flowing from one place to another without friction is a constant
\nSpeed of Afflux : Torricellis law
\nTorricellis law may be stated as the velocity of afflux through a hole at a depth \u2018h\u2019 will be equal to the velocity gained by a freely falling body when it travels a distance \u2018h\u2019. ie; v = \u221a2gh
\nProof:
\n
\nConsider a tank containing a liquid of density \u03c1 with a small hole in its side. Let Y1<\/sub> be the height of the hole, and Y2<\/sub> be height of water in the tank. Applying Bemoullis equation at points (1) and (2) we get
\n
\n(P1<\/sub> = Pa<\/sub>, the atmospheric pressure).
\nIf the cross sectional area of the tank A2<\/sub> is much larger than that of the hole (ie; A2<\/sub>>>A1<\/sub>), we take
\n<\/p>\n
\nA liquid surface behaves like a stretched elastic membrane.\u00a0(MAY-2014)<\/span>
\na) Name the liquid property for the above behavior.
\nb) Define angle of contact. What is its value for pure water with glass?
\nc) Derive an expression for the rise of liquid in a capillary tube of radius r, having density p and surface tensions s.
\nAnswer:
\na) Surface tension
\nb) Angle of contact is the angle between the solid surface and tangent drawn to the liquid surface at point of contact inside the liquid.
\nFor pure water angle of contact is zero.
\nc)
\nConsider a capillary tube of radius \u2018a\u2019 dipped in a liquid of density p and surface tension S. If the liquid has a concave meniscus it will rise in the capillary tube. Let h be the rise of the liquid in the tube. Let p, be the pressure on the concave side of the meniscus and p0, that on the other side .
\nThe excess pressure on the concave side of the meniscus can be written as
\n
\nWhere R is the radius of the concave meniscus. The tangent to the meniscus at the point A makes an angle \u03b8 with the wall of the tube.
\nIn the right angled triangle ACO
\n
\nConsidering two points M and N in the same hori-zontal level of a liquid at rest, pressure at N = pressure at M But pressure at M = \u03c11<\/sub>, the pressure over the concave meniscus and pressure at N = p0<\/sub> +h\u03c1g
\n<\/p>\n
\nThe pressure of the atmosphere at any point is the weight of the air column of a unit cross-sectional area. Its unit is bar.\u00a0(MARCH-2015)<\/span>
\na) Identify the given diagram and write its uses.
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-29.png\")
\nb) State Pascal\u2019s law for transmission of fluid pressure and explain the principles of working of a hydraulic lift.
\nc) The above arrangement is placed in an elevator which is accelerating upwards. What happens to the possible height of the liquid column in the tube? Justify.
\nOR
\nThe antiseptics used for cuts and wounds in human flesh have low surface tension. Due to low surface tension they spread overthe wounds easily,
\na) In the following figure, the angle of contact \u03b8 is ………..
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-30.png\")
\nb) Surface tension causes capillarity. Define capillarity and arrive at the expression for capillary rise in terms of surface tension.
\nc) In a capillary tube, water rises to a height. If the capillary tube is inclined at an angle 60\u00b0C with the vertical, what will be the length of the water column in the tube?<\/p>\n
\na) Barometer
\nb) Pascal\u2019s Law
\nWhenever external pressure is applied on any part of a fluid contained in a vessel, it is transmitted undiminished and equally in all directions.
\nHydraulic lift:\u00a0<\/strong>
\n
\nA hydraulic lift is used to lift heavy load. Consider a liquid enclosed in a vessel with two cylinders C1<\/sub> and C2<\/sub> attached as shown in the figure. The cylinders are provided with two pistons having areas A1<\/sub> and A2<\/sub> respectively.
\nIf F1<\/sub> is the force exerted on the area A1<\/sub>,
\n
\n
\nUsing this method we can lift heavy load by applying small force.
\nc) Liquid level decreases. When this arrangement moves with an acceleration in upward direction weight of liquid column increases. Hence pressure inside the liquid column increases.
\nOR
\na) Obtuse
\nb) Capillary rise
\nA tube of very fine core is called a capillary tube. When a capillary tube is dipped in a liquid, the liquid immediately rises in the tube. This phe-nomena is called capillarity or capillary rise.
\nIn the case of mercury, capillary depression is observed.
\nExpression for capillary rise :
\n
\nb) Consider a capillary tube of radius \u2018a\u2019 dipped in a liquid of density p and surface tension S. If the liquid has a concave meniscus it will rise in the capillary tube. Let h be the rise of the liquid in the tube. Let p, be the pressure on the concave side of the meniscus and p0, that on the other side .
\nThe excess pressure on the concave side of the meniscus can be written as
\n
\nWhere R is the radius of the concave meniscus. The tangent to the meniscus at the point A makes an angle \u03b8 with the wall of the tube.
\nIn the right angled triangle ACO
\n
\nConsidering two points M and N in the same hori-zontal level of a liquid at rest, pressure at N = pressure at M But pressure at M = \u03c11<\/sub>, the pressure over the concave meniscus and pressure at N = p0<\/sub> +h\u03c1g
\n
\nc) Let h be the initial height of liquid, h’is the height of liquid column.
\nFrom figure
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-31.png\")
<\/p>\n
\nState and prove Bernoulli\u2019s theorem.\u00a0(MAY-2015)<\/span>
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-32.png\")
\nA steady flow of non viscous iiquids are shown fin figures 1 and 2. Which one of the figures is INCORRECT? Why?
\na) What is the SI unit of pressure? Derive a mathematical expression for excess pressure inside a liquid drop.
\nb) What will happen to two soap bubbles of different radii, which are in contact with each other? Why?
\nAnswer:
\na) As we move along a streamline the sum of the pressure (\u03c1), the kinetic energy per unit volume \\(\\frac { \u03c1v\u00b2 }{ 2 }\\) and the potential energy per unit volume (\u03c1gh) remains a constant
\nOR
\nThe total energy of an incompressible non-viscous liquid flowing from one place to another with-out friction is a constant.
\nMathematically Bernoulli\u2019s theorem can be written as
\n
\nConsider an incompressible liquid flowing through a tube of non uniform cross section from region 1 to region 1. The corresponding values at the cross section and V1<\/sub> the speed of the flow at the region 1 . The corresponding values at region 2 are P2<\/sub>, A2<\/sub> and V1<\/sub> respectively. Region 1 is at a height h1<\/sub> and region 2 is at a height h2<\/sub>.
\nThe workdone on the liquid in a time \u2206t at the region 1 is given by
\nW1<\/sub> = P1<\/sub>\u2206V1<\/sub>
\nSimilarly the workdone in a time \u2206t at the region 2 is given by,
\nW2<\/sub>=- P2<\/sub>\u2206V2<\/sub> Net workdone
\n\u2206W1<\/sub> = P1<\/sub>\u2206V – P2<\/sub>\u2206V2<\/sub>.
\nAccording the equation of continuity
\n\u2206V1\u00a0<\/sub>= \u2206V2\u00a0<\/sub>= \u2206V
\n\u2206W = P1<\/sub>\u2206V – P2<\/sub>\u2206V
\n\u2206W = (P1<\/sub> – P2<\/sub>)\u2206V .
\nThis work done changes the kinetic energy, pressure energy and potential energy of the fluid.
\nIf \u2206m is the mass of liquid passing through the pipe in a time \u2206t. the change in Kinetic energy is given by
\n\\(\\Delta \\mathrm{k} . E=\\frac{1}{2} \\Delta \\mathrm{mV}_{2}^{2}-\\frac{1}{2} \\Delta \\mathrm{mV}_{1}^{2}\\) ……(2)
\nChange in gravitational potential energy is given by
\n\u2206P.E= \u2206mgh2<\/sub> – \u2206mgh1<\/sub> ………..(3)
\nAccording to work-energy theorem work done is equal to the change in kinetic energy plus the change in potential energy.
\nie; \u2206w =\u2206kE + \u2206PE ………(4)
\nSubstituting eq. 1,2 and 3 in eq. 4, we get
\n
\nb) Figure 1 is incorrect. When area decreases velocity of liquid flow increase. Then pressure decreases. The pressure of liquid at narrow part of tube is less than the wider part. Therefore the liquid level above narrow part tube will be lower than that above wider part.
\nOR
\na) The SI unit of pressure is Pascal (N\/m\u00b2)
\nb) The molecules near the surface of a drop experience a resultant pull inwards due to surface tension. Because of this inward pull, the pressure inside is greater than the outside. Due to the forces of surface tension, the drop tends to contract. But due to excess inside pressure, the drop tends to expand. When the drop is in equilibrium, these two forces will be equal and opposite.
\n
\nConsider a drop of liquid of radius r .Let p1<\/sub> and p0<\/sub> be the values of pressure inside and outside the drop. Let the radius of liquid of drop increases by a small amount \u2206r under the pressure difference. The outward force acting on the surface of the drop,
\n
\nc) i)<\/p>\n
\nIn case of fluids law of conservation of energy can be explained with Bernoulli\u2019s principle.\u00a0(MARCH-2016)<\/span>
\nState and prove Bernoulli\u2019s principle.
\nWhile travelling in aeroplane, it is advisable to remove inkform fountain pen. Why?
\nOR
\nViscosity is the frictional force in fluids.
\nWhen a small metal ball is falling through a viscus medium, what are the various forces acting on it? Using this arrive at an expression for terminal velocity.
\nRaindrops falling under gravity do not acquire very high velocity. Why?
\nAnswer:
\nAs we move along a streamline the sum of the pressure (\u03c1), the kinetic energy per unit volume \\(\\frac { \u03c1v\u00b2 }{ 2 }\\) and the potential energy per unit volume (\u03c1gh) remains a constant
\nOR
\nThe total energy of an incompressible non-viscous liquid flowing from one place to another with-out friction is a constant.
\nMathematically Bernoulli\u2019s theorem can be written as
\n
\nConsider an incompressible liquid flowing through a tube of non uniform cross section from region 1 to region 1. The corresponding values at the cross section and V1<\/sub> the speed of the flow at the region 1 . The corresponding values at region 2 are P2<\/sub>, A2<\/sub> and V1<\/sub> respectively. Region 1 is at a height h1<\/sub> and region 2 is at a height h2<\/sub>.
\nThe workdone on the liquid in a time \u2206t at the region 1 is given by
\nW1<\/sub> = P1<\/sub>\u2206V1<\/sub>
\nSimilarly the workdone in a time \u2206t at the region 2 is given by,
\nW2<\/sub>=- P2<\/sub>\u2206V2<\/sub> Net workdone
\n\u2206W1<\/sub> = P1<\/sub>\u2206V – P2<\/sub>\u2206V2<\/sub>.
\nAccording the equation of continuity
\n\u2206V1\u00a0<\/sub>= \u2206V2\u00a0<\/sub>= \u2206V
\n\u2206W = P1<\/sub>\u2206V – P2<\/sub>\u2206V
\n\u2206W = (P1<\/sub> – P2<\/sub>)\u2206V .
\nThis work done changes the kinetic energy, pressure energy and potential energy of the fluid.
\nIf \u2206m is the mass of liquid passing through the pipe in a time \u2206t. the change in Kinetic energy is given by
\n\\(\\Delta \\mathrm{k} . E=\\frac{1}{2} \\Delta \\mathrm{mV}_{2}^{2}-\\frac{1}{2} \\Delta \\mathrm{mV}_{1}^{2}\\) ……(2)
\nChange in gravitational potential energy is given by
\n\u2206P.E= \u2206mgh2<\/sub> – \u2206mgh1<\/sub> ………..(3)
\nAccording to work-energy theorem work done is equal to the change in kinetic energy plus the change in potential energy.
\nie; \u2206w =\u2206kE+\u2206PE ………(4)
\nSubstituting eq. 1,2 and 3 in eq. 4, we get
\n
\nAt higher altitude pressure is low. So ink may leak out from pen.
\nOR
\na) Weight, viscous force
\nb) As rain drop falls under gravity through the air, it experience viscous force. \u2206t a particular time, the net force on the raindrop becomes zero and then it moves with constant velocity (terminal velocity)
\nViscous force, boyancy force and weight of the body
\nExpression for terminal velocity
\nConsider a sphere of radius \u2018a\u2019 density \u03c3 falling through a liquid of density a and viscocity \u03b7). The viscous force acting on the sphere can be written as
\nF = 6\u03c0a\u03b7v
\nWhere v is the velocity of sphere This force is acting in upward direction. When the viscous force is equal to the weight of the body in the medium, the net force on the body is zero. It moves with a constant velocity called the terminal velocity.
\nThe weight of a body in a medium,
\n<\/p>\n
\nConsider the flow of a liquid through a pipe of varying cross section.\u00a0(MAY-2016)<\/span>
\na) Write the equation of continuity of flow.
\nb) Draw a figure and derive Bernoulli\u2019s equation.
\nc) A tank of 5m height is filled with water. Calculate the velocity of efflux through a hole, 3m below the surface of water.
\nOR
\nSurface tension is a property of liquids and it causes capillary rise in small tubes.
\na) What do you mean by surface tension?
\nb) Draw a figure and derive an equation for capillary rise in a tube of radius ‘r’.
\nc) Excess pressure inside a liquid drop is 60N\/m\u00b2.
\nWhat will be the excess pressure inside a liquid bubble of the same radius formed by the same liquid?
\nAnswer:
\na) AV = constant or A1<\/sub>V1<\/sub> =A2<\/sub>V2<\/sub>
\nb) As we move along a streamline the sum of the pressure (\u03c1), the kinetic energy per unit volume \\(\\frac { \u03c1v\u00b2 }{ 2 }\\) and the potential energy per unit volume (\u03c1gh) remains a constant
\nOR
\nThe total energy of an incompressible non-viscous liquid flowing from one place to another with-out friction is a constant.
\nMathematically Bernoulli\u2019s theorem can be written as
\n
\nConsider an incompressible liquid flowing through a tube of nonuniform cross-section from region 1 to region 1. The corresponding values at the cross-section and V1<\/sub> the speed of the flow at region 1 . The corresponding values at region 2 are P2<\/sub>, A2<\/sub> and V1<\/sub> respectively. Region 1 is at a height h1<\/sub> and region 2 is at a height h2<\/sub>.
\nThe work done on the liquid in a time \u2206t at the region 1 is given by
\nW1<\/sub> = P1<\/sub>\u2206V1<\/sub>
\nSimilarly the workdone in a time \u2206t at the region 2 is given by,
\nW2<\/sub>=- P2<\/sub>\u2206V2<\/sub> Net workdone
\n\u2206W1<\/sub> = P1<\/sub>\u2206V – P2<\/sub>\u2206V2<\/sub>.
\nAccording the equation of continuity
\n\u2206V1\u00a0<\/sub>= \u2206V2\u00a0<\/sub>= \u2206V
\n\u2206W = P1<\/sub>\u2206V – P2<\/sub>\u2206V
\n\u2206W = (P1<\/sub> – P2<\/sub>)\u2206V .
\nThis work done changes the kinetic energy, pressure energy and potential energy of the fluid.
\nIf \u2206m is the mass of liquid passing through the pipe in a time \u2206t. the change in Kinetic energy is given by
\n\\(\\Delta \\mathrm{k} . E=\\frac{1}{2} \\Delta \\mathrm{mV}_{2}^{2}-\\frac{1}{2} \\Delta \\mathrm{mV}_{1}^{2}\\) ……(2)
\nChange in gravitational potential energy is given by
\n\u2206P.E= \u2206mgh2<\/sub> – \u2206mgh1<\/sub> ………..(3)
\nAccording to work-energy theorem work done is equal to the change in kinetic energy plus the change in potential energy.
\nie; \u2206w =\u2206kE+\u2206PE ………(4)
\nSubstituting eq. 1,2 and 3 in eq. 4, we get
\n
\nc) h = 3m
\nV = \u221a2gh = \\(\\sqrt{2 \\times 9.8 \\times 3}\\)
\nOR
\na) Surface tension is surface energy per unit area. The liquid at free surface has some additional energy. This phenomenon is called surface tension.
\n
\nb) Consider a capillary tube of radius \u2018a\u2019 dipped in a liquid of density p and surface tension S. If the liquid has a concave meniscus it will rise in the capillary tube. Let h be the rise of the liquid in the tube. Let p, be the pressure on the concave side of the meniscus and p0, that on the other side .
\nThe excess pressure on the concave side of the meniscus can be written as
\n
\nWhere R is the radius of the concave meniscus. The tangent to the meniscus at the point A makes an angle \u03b8 with the wall of the tube.
\nIn the right angled triangle ACO
\n
\nConsidering two points M and N in the same horizontal level of a liquid at rest, pressure at N = pressure at M But pressure at M = \u03c11<\/sub>, the pressure over the concave meniscus and pressure at N = p0<\/sub> +h\u03c1g
\n
\nc) A liquid bubble has air inside and outside it. Hence it has two surfaces.
\nExcess pressure inside liquid bubble =2x60N\/m2<\/sup>
\n=120N\/M2<\/sup><\/p>\n
\nDraw the schematic diagram of a hydraulic lift. Give its working principle.\u00a0(MARCH-2017)<\/span>
\nAnswer:
\nc)
\n
\nA hydraulic lift is used to lift heavy load. Consider a liquid enclosed in a vessel with two cylinders C1<\/sub> and C2<\/sub> attached as shown in the figure. The cylinders are provided with two pistons having areas A1<\/sub> and A2<\/sub> respectively.
\nIf F1<\/sub> is the force exerted on the area A1<\/sub>,
\n
\n
\nUsing this method we can lift heavy load by applying small force.<\/p>\n
\nA region of streamline flow of an incompressible fluid is shown in the figure.\u00a0(MARCH-2017)<\/span>
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-33.png\")
\na) By considering mass conservation in the fluid flow, arrive at the \u2018equation of continuity\u2019.
\nb) The onset of turbulence in a fluid is determined by \u2018Reynold number\u2019, given as….
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-34.png\")
\nOR
\nSchematic diagram of capillary rise in a narrow tube is shown in the figure.
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-35.png\")
\na) Arrive at an expression for capillary height \u2018h\u2019 in terms of the surface tension of the liquid.
\nb) On the surface of the moon, the liquid in a capillary tube will rise to the ………
\ni) same height as on earth.
\nii) less height as on earth.
\niii) more height than that on earth.
\niv) infinite height.
\na) Flow rate of an incompressible fluid is constant
\nie Av = cont.
\nWhere A is the area of cross section of flow and v is the velocity of flow. \u2018Av\u2019 is also called volume flux.
\nProof
\nConsider a flow of incompressible liquid. Let P, R and Q be three points of a flow. Consider three planes perpendicular to direction of flow at P, R and Q.
\n![\"Plus](\"https:\/\/www.aplustopper.com\/wp-content\/uploads\/2019\/09\/Plus-One-Physics-Chapter-Wise-Previous-Questions-Chapter-10-Mechanical-Properties-of-Fluids-36.png\")
\nLet AP<\/sub>, AR<\/sub> and AQ<\/sub> be the area of cross sections and VP<\/sub>, VR<\/sub> and VQ<\/sub> be the corresponding speeds at P, R, Q respectively.
\nThe mass of liquid passing through area AP<\/sub> in a time \u2206t, MP<\/sub> = AP<\/sub> VP<\/sub> \u03c1P<\/sub> \u2206t
\nSimilarly, MR<\/sub> = AR<\/sub> VR<\/sub> \u03c1R<\/sub>\u2206t
\nMQ<\/sub>=AQ<\/sub>VQ<\/sub> \u03c1Q<\/sub> \u2206t
\nBut we know
\n\u03c1P<\/sub> = \u03c1R<\/sub>= \u03c1Q<\/sub>= \u03c1