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Fluid Mechanics
FLUID STATICS
Engineering Fluid Mechanics 8/E by Crowe, Elger, and RobersonCopyright © 2005 by John Wiley & Sons, Inc. All rights reserved.
Variation in pressure with elevation.
Pressure Variation with Elevation
0lF
dz
dp
Variation in pressure with elevation.
• Hydrostatic equation
dz
dp From a vertical datum,pressure decreases asz-datum elevation increases.
Pressure Variation in Uniform Density
Assuming that the density (ρ) and specific weight () of a fluid are uniform through the fluid
Integrate to get dz
dpzpzp
pz : Piezometric pressure
constant
z
p
Piezometric head
2
21
1 zp
zp
Hydrostatic Equation
Pressure Variation in Uniform Density
2
21
1 zp
zp
Hydrostatic Equation applies only in a fluid with a constant specific weight.
It applies to two point in the same fluid but not across an interface of two fluids having different specific weight.
Engineering Fluid Mechanics 8/E by Crowe, Elger, and RobersonCopyright © 2005 by John Wiley & Sons, Inc. All rights reserved.
Example 3.3 (p. 37)
Example:
What is the water pressure at a depth of 35 ft in the tank shown?
Specific Weight
γ = 62.4 lb/ft3
Solution:
2
21
1 zp
zp
0 + 250 = (P2/) + 215
35 ft = (P2/)
P2 = 35 * 62.4
P2 = 2180 psfg = 15.2 psig
Psig = pound force per square inch gage
Engineering Fluid Mechanics 8/E by Crowe, Elger, and Roberson
Copyright © 2005 by John Wiley & Sons, Inc. All rights reserved.
Example: Oil with a specific gravity of 0.80 forms a layer 0.90m deep in an open tank that is otherwise filled with water. The total depth of water and oil is 3 m. What is the gage pressure at the bottom of the tank. γ = 9810 N/m3
p2 = 0.90 x (0.8 x 9810) = 7.06 kPa
p3 = 7.06 + 2.1 x 9,810 = 27.7 kPa
Hydrostatic Equation
hP
2
21
1 zp
zp
Change in pressure between two points depends on the specific weight of the fluid, and the vertical distance between the two points.
Pressure Variation with Elevation
p0
h
p=h
p
h
pp0
p=p0+h
p0
p0
p1=p0+1h1
p2=p1+2h2
h
h1
h2
1
2
Pressure Measurements
hpp atmabsolute
hp
Absolute pressure
Gage pressure
Many pressure-measuring device measure not absolute pressure but only differences in pressure.
Barometer → to measure atmospheric pressure
Manometer
• A pressure measuring method that utilizes the change in pressure with elevation to evaluate pressure.
Piezometer (manometer ) attached to a pipe
- Accurate & simple .
- The problem is that a piezometer is impractical for high pressure and useless for gasses.
hP
If h is 10 m, what isthe pressure at thecentre of the pipe?
U-tube Manometer
Problem: water in pipe, mercury manometer liquid ( mercury specific weight =133 kN/m3) ∆h = 60 cm l =180 cm
Find the pressure at the centre of the pipe ?
Ans: 62.1 kPa
up
iidown
ii hhpp 12
General manometer equation
1: Initial point index
2: Final point index
Example 3.7: Manometer Analysis slide 14
Question: Pressure of the air?
Given: l1 = 40 cm l2 = 100 cm l3 = 80 cm
Differential Manometers
Here, the pressure difference
between 1 and 2 is:
hP fm )(
(this is for a horizontal pipe… z1 = z2)
γm : the specific weight of the manometer liquid,
γf : the specific weight of the fluid,
Δh : the deflection of this liquid.
To measure the pressure difference btw two points in a pipe
Differential Manometers
• Example 3.8:
• Specific gravity of manometer fluid is 3.
Δh = 5 cm
Δz = 1 m
y = 2 cm
What is the pressure difference? What is the change in piezometric pressure?
Solution:
zpzp
hP fm )(
Piezometric pressure
Piezometric difference
)()( 1212 zzyhhyPP wmw
Applying the manometer equation between points 1 and 2:
)()()( 1122 mwww hzPzP
)(12 mwzz yhPP
Change in piezometric pressure:
FLUID STATICS:
Hydrostatic Force on Plane Surfaces
slide 18
Distribution of hydrostatic pressure on a plane surface
AySindAySinFA
_
ApASinyF__
Pressure on the differential area can be computed if the y distance to the point is known dF = p dA = ( y sin) dA
Integrating the differential force over the entire area A
Hydrostatic Force
Integral is the first moment of the areaPressure at the centroid
Hydrostatic Force
Hydrostatic Force Terms
• Δh: Vertical distance from centroid to the water surface
(This distance determines the pressure at the centroid)
• y: Inclined distance from water surface to the centroid
• ycp: Inclined distance from water surface to centre of pressure
• P¯: the pressure at the centroid
Vertical Location of Line of Action of resultant Hydrostatic Force
• ycp = (inclined) distance to the centre of pressure• y ¯= (inclined) distance to the centroid• I ¯= area moment of inertia about horizontal axis passing the centriod• A = surface area
Ay
Iyycp _
__
Restrictions:
1- One liquid involved
2- Gage pressure is zero at the liquid surface
- Considering moments of the pressure about the horizontal axis 0-0:
Lateral Location of Line of Action of resultant Hydrostatic Force
- The same principles as above can be used for the lateral location
- Starts with taking moments about a line normal to line 0-0
slide 21
Review of Centroid & Area Moment of Inertia
Example: 3.10• An elliptical gate covers the end of a pipe 4m in diameter. If the gate is hinged at
the top, what normal force F is required to open the gate when water is 8 m deep above the top of the pipe and the pipe is open to the atmosphere on the other side? Neglect the weight of gate.
abxhAApFp )109810(
maby
ba
Ay
Iyycp 125.0
4/1 3
_
__
(a, b: half of major and minor axes)
y¯(slant distance from surface to centroid): 12.5m
Resultant hydrostatic force:
Fp = 1.54 MN
Example cont’d
kN 809F
0m) 5 x (F -m) 2.625 x N (1.541x10
06
hingeM
Moment about the hinge. Moment arm for the
hydrostatic force:
2.5 +0.125 = 2.625m
Normal Force required to open gate
Pressure PrismThe volume called the pressure prism, that is a geometric representation of the hydrostatic force on a plane surface
The resultant force must pass through the centroid of the pressure prism.
Pressure Prism
• An informative and useful graphical interpretation can be made for the force developed by a fluid acting on a plane area.
• Consider the pressure distribution along a vertical wall of a tank of width b, which contains a liquid having a specific weight
• Since the pressure must vary linearly with depth, we can represent the variation as is shown in Figure below, where the pressure is equal to zero at the upper surface and reach to maximum at the bottom.
• It is apparent from this diagram that the average pressure occurs at the depth h/2 and therefore the resultant force acting on the rectangular area (A = b h) is
FLUID STATICS:
Hydrostatic Forces on Curved surfaces
Hydrostatic Forces on Curved Surfaces
Find the magnitude and line of action of the hydrostatic force acting on surface AB
1. What is the shape of the curve?
2. How deep is the curved surface?
3. Where does the curve intersect straight surfaces?
4. What is the radius of the curve?
Important Questions to Ask
Hydrostatic Forces on Curved Surfaces
A free-body diagram of a suitable volume of fluid can be used to determine the resultant force acting on a curved surface.
Hydrostatic forces on Curved surfaces.
Find the magnitude and line of action of the hydrostatic force acting on surface AB
1. FV : Force on the fluid element due to the weight of water above CB
2. FH : Force on the fluid element due to horizontal hydrostatic forces on AC
3. W : Weight of the water in fluid element ABC
4. F : The force that counters all other forces - F has a horizontal component: Fx
- F has a vertical component: Fy
Forces acting on the fluid element
Hydrostatic forces on Curved surfaces
Find the magnitude and line of action of the hydrostatic force acting on surface AB
- Given: Surface AB with a width of 1 m
1. By inspection, curve is a ¼ circle.2. The depth to the beginning of the
curve (4 m depth to B)3. The curve radius (2 m horizontal
curve projection distance = curve radius)
4. Label relevant points: • BCDE is water above fluid
element defined by the curve • ABC is the fluid element
defined by the curve
Problem Solving Preparation
Example 3.11: Hydrostatic forces on Curved surfaces
Find Fv, FH, W, Fx, Fy, F, Line of action for FH & Fv
Given: Surface AB goes 1 m into the paper
The hydrostatic force acting on ABis equal and opposite to the forceF shown
Fx= FH = (5 x 9810) (2 x 1) = 98.1 kN Pres. at the cenroid AC side area
Fy= W + Fv
Fv= 9810 x 4 x 2 x 1 = 78.5 kN
W= γVABC= 9810 (1/4 x r2) 1 = 30.8 kN
Fy= 78.5 + 30.8 = 109.3 kN
The centroid of the quadrant
Location of the resultant force
Slide 33
FLUID STATICS:
Buoyancy
Buoyancy, Flotation & Stability
Engineering Fluid Mechanics 8/E by Crowe, Elger, and RobersonCopyright © 2005 by John Wiley & Sons, Inc. All rights reserved.
Archimedes’ Principle
The resultant fluidforce acting on a
body that is completelySubmerged or floating in a fluid is called the
buoyant force.
Buoyancy: Floating Object
DB VF
where g is the specific weight of the fluid and VD is the volume of the body
Depends on submerged portion of the volume
VD is the submerged volume
Buoyant force
Engineering Fluid Mechanics 8/E by Crowe, Elger, and RobersonCopyright © 2005 by John Wiley & Sons, Inc. All rights reserved.
Example 3.12: Bouyant force on a metal part
Engineering Fluid Mechanics 8/E by Crowe, Elger, and RobersonCopyright © 2005 by John Wiley & Sons, Inc. All rights reserved.
- Wood block (1) has dimensions of 10‐mm x 50 mm x 50 mm -Specific gravity of 0.3- Metal object (2) has volume of 6600 mm3
– Find the tension in the cableand mass of object 2.
Steps• Find the buoyant forces.• Find the weight of the block.• Perform force balances on both objects.
Solution: