Presentation is loading. Please wait.

Presentation is loading. Please wait.

Experiment (2) BUOYANCY & FLOTATION (METACENTRIC HEIGHT)

Published byRachel Mills Modified over 9 years ago

Similar presentations

Presentation on theme: "Experiment (2) BUOYANCY & FLOTATION (METACENTRIC HEIGHT)"— Presentation transcript:

1 Experiment (2) BUOYANCY & FLOTATION (METACENTRIC HEIGHT)
By: Eng. Motasem M. Abushaban. Eng. Fedaa M. Fayyad.

2 Archimedes’ Principle
Archimedes’ Principle states that the buoyant force has a magnitude equal to the weight of the fluid displaced by the body and is directed vertically upward. Buoyant force is a force that results from a floating or submerged body in a fluid. The force results from different pressures on the top and bottom of the object. W is the weight of the shaded area F1 and F2 are the forces on the plane surfaces FB is the buoyant force the body exerts on the fluid

3 Archimedes’ Principle
The force of the fluid on the body is opposite, or vertically upward and is known as the Buoyant Force. The force is equal to the weight of the fluid it displaces. The buoyant forces acts through the centroid of the displaced volume The location is known as the center of buoyancy.

4 Stability: Submerged Object
Stable Equilibrium: if when displaced returns to equilibrium position. Unstable Equilibrium: if when displaced it returns to a new equilibrium position. Stable Equilibrium: Unstable Equilibrium: C > CG, “Higher” C < CG, “Lower”

5 Stability: Submerged Object
If the Centre of Gravity is below the centre of buoyancy this will be a righting moment and the body will tend to return to its equilibrium position (Stable). If the Centre of Gravity is above the centre of buoyancy ,an overturning moment is produced and the body is (unstable). Note that, As the body is totally submerged, the shape of displaced fluid is not altered when the body is tilted and so the centre of buoyancy unchanged relative to the body.

6 Buoyancy and Stability: Floating Object
Slightly more complicated as the location of the center buoyancy can change:

7 metacentre and metacentric height
Metacentre point (M): This point, about which the body starts oscillating. Metacentric Height: Is the distance between the centre of gravity of floating body and the metacentre.

8 Stability of floating object
If M lies above G a righting moment is produced, equilibrium is stable and GM is regarded as positive. If M lies below G an overturning moment is produced, equilibrium is unstable and GM is regarded as negative. If M coincides with G, the body is in neutral equilibrium.

9 determination of metacentric height
1- Practically : 2- Theoretically: MG = BM + OB – OG…… (2) In Water OB = 0.5

10 h

11 Purpose: To determine the metacentric height of a flat bottomed vessel in two parts: PART (1) : for unloaded and for loaded pontoon. PART (2) : when changing the center of gravity of the pontoon.

12 Experimental Set-up: The set up consists of a small water tank having transparent side walls in which a small ship model is floated, the weight of the model can be changed by adding or removing weights. Adjustable mass is used for tilting the ship, plump line is attached to the mast to measure the tilting angle.

13 PART (1) Determination of floatation characteristic for unloaded and for loaded pontoon.

14 Procedure 1. Assemble the pontoon by positioning the bridge piece and mast. 2. Weigh the pontoon and determine the height of its center of gravity up the line of the mast. 3. Fill the hydraulic bench measuring tank with water and float the pontoon in it, then ensure that the plumb line on the zero mark. 4. Apply a weight of 50 g on the bridge piece loading pin then measure and record the angle of tilting and the value of applied weight

15 Procedure 5. Repeat step 4 for different weights; 100, 150, & 200 g, and take the corresponding angle of tilting. 6. Repeat the above procedure with increasing the bottom loading by 2000 gm and 4000 gm. 7. Record the results in the table. 8. Calculate GM practically where , W has three cases. 9. Draw a relationship between θ (x-axis) and GM (y-axis), then obtain GM when θ equals zero. 10. Calculate GM theoretically.

16 - Pontoon dimension : Depth (D) = 170 mm
Pontoon measurement: - Pontoon dimension : Depth (D) = 170 mm Length (L) = 380 mm, Width (W) = 250 mm. The height of the center of gravity of the pontoon is OGvm = 125 mm from outer surface of vessel base. - The balance weight is placed at x = 123 mm from pontoon center line. - The weight of the pontoon and the mast Wvm = 3000 gm Bilge Weight Off balance wt. Mean Def. Exp. GM GM at θ =0 BM OB Theo. GM Wb (gm) P (gm) θ (degree) (mm) from graph 0.00 50 100 150 200 x1 = 30 x1 = 37.5 250

17 Purpose: To determine the metacentric height of a flat bottomed vessel in two parts: PART (1) : for unloaded and for loaded pontoon. PART (2) : when changing the center of gravity of the pontoon.

18 Remember: - Pontoon dimension : Depth (D) = 170 mm Length (L) = 380 mm, Width (W) = 250 mm. The height of the center of gravity of the pontoon is OGvm = 125 mm from outer surface of vessel base. - The balance weight is placed at x = 123 mm from pontoon center line. - The weight of the pontoon and the mast Wvm = 3000 gm

19 Procedure 1. Replace the bilge weights by 4x 50 gm weights.
PART (2) : when changing the center of gravity of the pontoon. 1. Replace the bilge weights by 4x 50 gm weights. 2. Apply a weight of 300gm on a height of 190 mm from the pontoon surface. 3. Apply weights of 40, 80 &120 gms on the bridge piece loading pin, then record the corresponding tilting angle. 4. Calculate GM practically where 5. Draw a relationship between θ in degrees (x-axis) and GM Practical (y-axis), then obtain GM when θ equals zero.

20 Procedure 6. Move 50 gm bilge weight to the mast ahead, then repeat steps 3,4&5. 7. Repeat step 6 moving 100, 150 & 200 gm bilge weight to the mast. 8. Determine the height of the center of gravity for each loading condition according to equation

21

22 8. Calculate GM theoretically according to equation
GM (Th.) = BM + OB – OG Notice: BM & OB are constants for all loading conditions, since the dimensions & the weight of pontoon do not alter.

23 Table (2) \ Part (2) Off balance wt. Mean Def. Exp. GM BM OG Theo. GM
θ (degree) (mm) Mast Weight = 0.0 40 2.40 80 4.88 120 7.50 Mast Weight = 50.0 3.45 7.23 10.50 Mast weight = 100.0 20 3.28 6.35 12.00 Mast Weight = 150.0 10 3.70 10.23 14.78 Mast weight = 200.0 Unstable

24

25 QUESTIONS

Download ppt "Experiment (2) BUOYANCY & FLOTATION (METACENTRIC HEIGHT)"

Similar presentations

Aula 5 Mecânica dos Fluidos 2-Estática do fluido.

Aula 5 Mecânica dos Fluidos 2-Estática do fluido.
Stability & Buoyancy.

Stability & Buoyancy.
Archimedes’ Principle An object immersed in a liquid has an upward buoyant force equal to the weight of the liquid displaced by the object. An object will.

Archimedes’ Principle An object immersed in a liquid has an upward buoyant force equal to the weight of the liquid displaced by the object. An object will.
Experiment (3) Impact of jet

Experiment (3) Impact of jet
Principles of Stability References INE: Ch 22 (389-400)INE: Ch 22 (389-400) INE: Ch 23 (401-402, 409)INE: Ch 23 (401-402, 409) PNE: Ch 3 (1-10)PNE: Ch.

Principles of Stability References INE: Ch 22 ( )INE: Ch 22 ( ) INE: Ch 23 ( , 409)INE: Ch 23 ( , 409) PNE: Ch 3 (1-10)PNE: Ch.
Static Fluids Fluids are substances, such as liquids and gases, that have no rigidity. A fluid lacks a fixed shape and assumes the shape of its container.

Static Fluids Fluids are substances, such as liquids and gases, that have no rigidity. A fluid lacks a fixed shape and assumes the shape of its container.
The tendency or ability of an object to float.

The tendency or ability of an object to float.
Boy, Oh Buoyancy Does it Float? Does it Sink? What is density? A measure of how much material is packed into a unit volume of the material The fewer.

Boy, Oh Buoyancy Does it Float? Does it Sink? What is density? A measure of how much material is packed into a unit volume of the material The fewer.
Buoyancy & Archimedes’s Principle

Buoyancy & Archimedes’s Principle
THIS PROJECT IS DONE BY: VIJAY ANAND (X STD) UNDER THE GUIDANCE OF : MR.K.V. RAJESH (PHYSICS)

THIS PROJECT IS DONE BY: VIJAY ANAND (X STD) UNDER THE GUIDANCE OF : MR.K.V. RAJESH (PHYSICS)
Lec 4: Fluid statics, buoyancy and stability, pressure

Lec 4: Fluid statics, buoyancy and stability, pressure
Forces on Submerged surfaces—plane surfaces Problem consider a plane surface of area A Draw an y and x axis passing through the centroid x y Place surface.

Forces on Submerged surfaces—plane surfaces Problem consider a plane surface of area A Draw an y and x axis passing through the centroid x y Place surface.
Water Pressure and Pressure Forces

Water Pressure and Pressure Forces
Physics 102 Part II Thermal Physics Moza M. Al-Rabban Professor of Physics Fluids (2)

Physics 102 Part II Thermal Physics Moza M. Al-Rabban Professor of Physics Fluids (2)
Water Pressure and Pressure Force (Revision)

Water Pressure and Pressure Force (Revision)
Pertemuan 05 - 07 Hydrostatics 2. Bina Nusantara Outline Pressure Forces on Plane Surface Pressure Forces on Curved Surface Pressure on Spillway Sections.

Pertemuan Hydrostatics 2. Bina Nusantara Outline Pressure Forces on Plane Surface Pressure Forces on Curved Surface Pressure on Spillway Sections.
1 MECH 221 FLUID MECHANICS (Fall 06/07) Chapter 2: FLUID STATICS Instructor: Professor C. T. HSU.

1 MECH 221 FLUID MECHANICS (Fall 06/07) Chapter 2: FLUID STATICS Instructor: Professor C. T. HSU.
Floating and Sinking.

Floating and Sinking.
The tendency or ability of an object to float.

The tendency or ability of an object to float.
Static Fluids Fluids are substances, such as liquids and gases, that have no rigidity. A fluid lacks a fixed shape and assumes the shape of its container.

Static Fluids Fluids are substances, such as liquids and gases, that have no rigidity. A fluid lacks a fixed shape and assumes the shape of its container.

Similar presentations

Ads by Google