Archimedes’s Principle
Consider the diagram
below
When piece of wood
immersed in fluid then floats due to the buoyant force or upthrust. Where by
upthrust force is the upward force enable the object to float or at least seem
higher
Archimedes principle
also called the law of buoyancy which state that
“When a body is
partially or totally immersed in a fluid it experiences an upthrust which is
equal to the weight of the fluid displaced”
U
= W
Relationship between
Real Weight and Apparent Weight
Consider
diagram of the mass (weight) of the object below
Real Weight is
the weight of object in air and apparent weight is the weight of object
in fluid
Mathematically
U = R - A
Where:
U = Upthrust or
Apparent weight loss
A = Apparent weight
R = Real weight
Nb:
i.
fluid normally exerts an Upthrust
ii.
Upthrust tends to reduce weight of body
iii.
1g of water = 0.01N of water
iv. 1g of water = 1cm3
= 1ml of water
Example,
Given Weight of body in
air is 10.10N weight of body when immersed in water is 9.2N. Find the upthrust.
Data given
Real weight, R =10.10N
Apparent weight, A =
9.2N
Upthrust, U = ?
Solution
From:
U = R - A
W = 10.10 – 9.2
W =0.9N
Example,
The weight of a body
when totally immersed in a liquid is 4.2N if the weight of the liquid displaced
is 2.5N. Find the weight of the body in air.
Data given
Apparent weight, A =
4.2N
Upthrust, U = 2.5N
Real weight, R =?
Solution
From:
U = R - A - make W1 subject
R = U + A
R = 2.5 + 4.2
R =6.7N
Example,
When an object is
totally immersed in water, its weight is recorded as 3.1N if its weight in air
is 4.9N. Find upthrust.
Data given
Real weight, R =4.9N
Apparent weight, A =
3.1N
Upthrust, U = ?
Solution
U = 1.8N
Example,
A body immersed in
water displaced 1.1N of the liquid if its weight white in the water is 3.3N.
Find they weight in air.
Data given
Apparent weight, A =
1.1N
Upthrust, U = 3.3N
Real weight, R =?
Solution
From:
U = R - A - make W1 subject
R = U + A
R = 3.3 + 1.1
R = 4.4N
Relative Density by
Using Archimedes Principle
Consider the formula
below
R.D = msmw (Vw=Vs)
R.D = Ms x gmw x g
Where:
i.
mw x g = upthrust = U
ii.
Ms x g = real weight = R
iii.
R.D = relative density
iv.
ms = mass of substance
v. mw (vw = vw) = Mass
of an equal volume of water or mass of water displaced
R.D = 𝑅U
But: U
= R – A
R.D = 𝑹R−A
Example,
A piece of glass weight
in air 1.2N and 0.7N when completely immersed in water calculate it’s.
(a)
Relative density
(b) Density of glass
Data given
Weight of body in air,
R = 1.2N
Weight of body in
water, A = 0.7N
Density of water, ρw =
10000kg/m3
Relative density of
glass, R.D = ?
Density of glass, ρg =
?
Solution
(a) Relative density of
glass, R.D = ?
From:
R.D = R/(R - A) = 1.2/ (1.2 - 0.7) = 2.4
R.D = 2.4
(b) Density of glass, d
= ?
From:
R.D = ρg/ρw = make ρg subject
ρg = R.D x dw = 2.4 x
1000
ρg = 2400
ρg = 2400 kg/m3
Relative Density of
other liquid from water by solid substance in Archimedes Principle
When solid immersed in
liquid and water the relative density is given by liquid displaced over water
displaced
Mathematically
R.D = weight of liquid
displacedWeight of water displaced
R.D = weight of object
in air − weight of object in liquidweight of object in air− weight of object in
water
R.D = upthrust on
liquidupthrust on water = 𝑈𝑙𝑈𝑤
R.D = 𝑅− 𝐴𝑙𝑅−
𝐴𝑤
Where:
𝑈𝑙= upthrust on liquid
𝑈𝑤 =upthrust on water
𝐴𝑙= Apparent weight on
liquid
𝐴𝑤 = Apparent weight on
water
Example,
Weight Q in air,
R = 8.6N
Weight Q in
water, AW = 6.0N
Weight Q in
liquid, AL = 5.4N
Data given
Weight of body Q in
air, R = 8.6 N
Weight of body Q in
water, AW = 6.0N
Weight of body Q in
liquid, AL = 5.4N
Solution
From:
R.D = 𝑅− 𝐴𝑙𝑅−
𝐴𝑤
R.D = 8.6 − 5.4 8.6 –
6.0 = 3.2/2.6 = 1.2
R.D = 1.2
Example,
Using the data shown above and determine the relative density of the liquid
Data given
Weight of body in air,
R = 15 N
Weight of body in
water, Aw = 11N
Weight of body in
liquid, Al = 9N
Relative density, R.D =
?
Solution
From:
R.D = 𝑅− 𝐴𝑙𝑅−
𝐴𝑤
R.D = 15 − 9 18 – 11 =
6/7 = 1.5
R.D = 1.5
Example,
A body weights 0.52N in
air. Total immersed in water it weighs only 0.32N while its weight when
immersed in another liquid is 0.36N. The density of water is 1000 kg/m3. What
is the density of the other liquid?
Data given
Weight of body in air,
R = 0.52 N
Weight of body in
water, Aw = 0.32N
Weight of body in
liquid, Al = 0.36N
Density of water ρw =
1000 kg/m3
Relative density, R.D =
?
Density of liquid, ρl =
?
Solution
From:
R.D = 𝑅− 𝐴𝑙𝑅−
𝐴𝑤
R.D =
0.52−0.360.52−0.32 = 0.16/0.2 = 0.8
R.D = 0.8
But:
R.D = ρl/ ρw – make ρl subject
ρl = R.D x ρw = 0.8 x
1000 = 800
ρl
= 800 kg/m3
Sinking
Defn: Sinking
is the tendency of an object to fall or drop to lower levels in a fluid
Condition for Sinking
i.
Upthrust exerted by fluid is less than weight of object
ii. Object denser than
fluid means object has great density than fluid
Floating
Defn: Floating
is the tendency of an object to be suspended in (remain) on the surface of a
fluid due to the upthrust
Nb:
The ability of an
object to float is called Buoyancy
Condition for Floating
i. Upthrust exerted by
fluid must be equal or greater to the real weight of the object
Nb:
apparent weight approximately equal to zero
A ≈ 0 N
ii.
The density of body must lees than that of fluid
iii. Volume of
submerged object must be large enough to displace a lot of fluid
Law of Flotation
The law states that
“A floating body
displaces its own weight of the fluid in which if floats”
Nb:
The real weight of the
body can be expressed in terms of its density
For substance to float,
R = U
But:
R =mS x g
Since:
mS = ρS x vS
Therefore:
R = ρS x vS x g
Also:
U =mf x g
Since:
mf = ρf x vf
Therefore:
U = ρf x vf x g
But:
vf = %S x vs
Then:
%S = (vt/vs) x 100
Then:
ρs x vs x g = ρf x vf x g
Ρs x vs x g = ρf x %S x
vf x g
Ρs = ρf x %S
Where
R = real weight of
substance
U = W = weight of fluid
displaced
Ms = mass of substance
Ρs = density of
substance
Vs = volume of
substance
Mf = mass of fluid
displaced
Ρf = density of fluid
displaced
Vf = volume of fluid
displaced
%S= percentage of
substance submerged
Vt = volume submerged
Application of
Flotation
Law of flotation is
applicant in various substance include
i.
Filling Balloons
ii.
Filling Hot air balloon
iii.
Submarines
iv.
Ships
Balloons
Consider the diagram
below
Since:
mf = ρf x vf
Therefore:
U = ρf x vf x g
But:
vf = %S x vs
Then:
%S = (vt/vs) x 100
But:
R = U
Then:
ρs x vs x g = ρf x vf x g
Ρs x vs x g = ρf x %S x
vf x g
Ρs = ρf x %S
Where
R = real weight of
substance
U = W = weight of fluid
displaced
Ms = mass of substance
Ρs = density of
substance
Vs = volume of
substance
Mf = mass of fluid
displaced
Ρf = density of fluid
displaced
Vf = volume of fluid
displaced
%S= percentage of
substance submerged
Vt = volume submerged
Application of
Flotation
Law of flotation is
applicant in various substance include
i.
Filling Balloons
ii.
Filling Hot air balloon
iii.
Submarines
iv.
Ships
v. Hydrometer
Balloons
Consider the diagram
below
Where:
U = upthrust
R = weight of balloon
Mechanism
Balloons is filled with
a light gas e.g. Helium which displace volume of air equal to its
volume. Since filled gas has the light or has low density that than displaced
air so the balloon drifted up by a force
Hot - Air Balloon
Mechanism
When air heated in the
envelope is increased and gas inside expand so its volume increase and mass of
gas inside envelope remains Constant so its density lowered as if you compare
to the external gas (cold air). This different in density drift the balloon and
it’s passengers into the air
Consider the diagram
below
For substance to float,
R = U
But:
U = Mt x g
U = (MB + Mc + mh) x g
But: mh
= vh x ρh
Then: U
= (Mt + vh x ρh) x g - - - - - 1
Also: R
= mc x g
But: mc
= vc x ρc x g
Then: R
= vc x ρc x g - - - - - 2
But: vc
= vh = v
Then: equation
1 = equation 2 (U = R)
(Mt + vh x ρh) x g = vc
x ρc x g
(Mt + vh x ρh) = vc x
ρc
Mt + v x ρh = v x ρc ce:
mf = ρf x vf
Mt + v x ρh = v x ρc –
make v subject
v = Mt/(ρc - ρh)
v = (ml + mb)/Δρ
Where
Total mass = mt = (MB +
Mc + mh)
Volume of hot air = vh
Volume cold air = vc
Mass of hot air = mh
Mass cold air = mc
Mass of balloon = mb
Density hot air = ρh
Density cold air = ρc
Example,
A hot air balloon
including the envelope, gondola, burner and fuel and one passenger has a total
mass of 450kg. Air outside balloon is at 20℃ and has a density of 1.29kg/m3 the
air inside at temperature 120℃ has density of 0.90kg/m3. To what volume must
the envelope expand to just lift the balloon into the air?
Data given
Total mass, mt = 450kg
Density at 120℃ , ρ2 =
0.90 kg/m3
Density at 20℃ , ρ1 =
1.29 kg/m3
Volume of air displaced,
v1 = ?
Solution
From:
v = (ml + mb)/Δρ
v = 450kg /(1.29-0.9)
v = 450kg /(1.29-0.9)
v = 450/0.39 = 1.15
v = 1.15m3
Example,
A balloon has a
capacity of 20m3 and it is filled with hydrogen. The balloon fabric and the
container have a mass of 2.5kg. What mass of instruments can be lifted by the
balloon? (Density of hydrogen = 0.089kg/m3 and density of air is 1.29kg/m3)
Data given
Total mass = mt = ml +
mb
Volume capacity, v =
20m3
Volume cold air, v1
=20m3
Mass of balloon, mb =
2.5kg
Density at v2, ρ2 = 0.089kg/m3
Density at v1, ρ1 =
1.29kg/m3
Mass of instrument), ml
= ?
Solution
From:
v = (ml + mb)/Δρ – make ml subject
Ml = (v x Δρ) – mb)
Ml = (20 x (1.29 –
0.089)) – 2.5
Ml = (20 x 1.201) – 2.5
Ml = 24.02 – 2.5
Ml = 21.52kg
Sub Marine
Mechanism
Submarine made with
empty space filled with air called ballast in order to increase its volume in
order to devise density of submarine and vice versa
When water filled in
the ballast the submarine submerged and when balloon admitted to special tank
its due and when ballast is filled with air the sub marine floats like other
ship
Nb:
When water quantity
increased/ filled in the blast is tend to reduce volume hence increase the
density of submarine.
Ship
Ship is made of steel
and is expected to sink due to its weight. it contains hollow which increase
the volume of ship which help on making less dense that the waters
But when load put on
ship it tends to increase the density and mass of ship when overloaded the ship
sink completely. To check on over wading ships are marked with line or mark
called Plimsoll marks.
Plimsoll line
Plimsoll line on a ship
used to show minimum heights (maximum density) above different of water types
in different sea as shown in the diagram below
Where:
F = for fresh water
S = for sea in summer
time
W = for sea in water
time
TF = tropical fresh
water
WNA = winter in
Atlantic
T = Tropical
Hydrometer
Defn: hydrometer
is an instrument used for measuring the densities of liquids or hydrometer is
an instrument used for determine the relative density of liquids.
Structure of Hydrometer
i. Heavy sinker (bulb):
containing mercury or lead shots that keep the hydrometer upright when it
floats
ii. Air bulb: it
increases volume of displaced liquid and overcomes the weight of the sinker
iv. Scale: inside stem
graduated in densities
Nb:
The greater the density
of the liquid the shorter the stem of hydrometer immersed
Relative Density of
Liquid by Hydrometer
i. When hydrometer
floats over water the weight of hydrometer (wg) must equal to the weight of
water displaced (ww)
wg = ww
ii. When hydrometer
floats over liquid the weight of hydrometer (wg) must equal to the weight of
liquid displaced (wl)
wg = wl
iii. since relative
density of liquid is given by ratio of density of liquid (ρl) to the density of
water (ρw)
R.D = ρl/ρw = wl/vl ÷
ww/vw
Where:
vl = volume of liquid
displaced
vw = volume of water
displaced
wl = ww
Then: R.D = vw/vl
iv. since cross-section
area of the hydrometer is uniform, the volume of water and of liquid displaced
are proportional to the lengths immersed in them
R.D = lw/ll
Where:
Lw = length of
hydrometer immersed in water
Ll = length of
hydrometer immersed in liquid
Consider the Diagram
Below
Where:
Steam volume, v1 = Ah
Bulb volume, v2 = v
Total volume, vt = v1 +
v = Ah + v2
But: R
= U
Where:
U = upthrust in liquid
ρmn = minimum density
ρmx = maximum density
R = weight of
hydrometer
U = vt x ρmn x g
R = v x ρmx x g
But:
R = U
Then: vt x ρmn x g = v
x ρmx x g
(Ah + v) x ρmn x g = v
x ρmx x g
(Ah + v) x ρmn = v x
ρmx
Ah x ρmn + v x ρmn = v
x ρmx – make v2 subject
v x ρmx - v x ρmn = Ah
x ρmn
v x (ρmx - ρmn) = Ah x
ρmn
v = (Ah x ρmn)/(ρmx -
ρmn)
Example,
Consider the diagram
below used to measure density of liquid between 1g/cm3 to 0.81g/cm3 (The area
of cross section area of stem is 0.5cm2). Find the volume of hydrometer below
1.0 g/cm3 graduated
Data given
Cross section area of
stem, A = 0.5cm2
Height of steam, h = 16
cm
The volume of steam, v1
= Ah = 8 cm3
Total volume, vt = (8 +
v2) cm3
Minimum density, ρmn =
0.8 g/cm3
Maximum density, ρmx =
1.0 g/cm3
The volume of bulb, v2
= ?
Solution
The volume of bulb, v2
= ?
From:
v2 = (Ah x ρmn)/(ρmx - ρmn)
v2 = (8 x 0.8)/(1 –
0.8)
v2 = 6.4/0.2
v2 = 32 cm3
Example, : NECTA form
IV 2012 QN: 4
(a)
What does a solid body weight more in air than when immersed in a liquid?
(b)
An ordinary hydrometer of mass 27g floats with 4cm of its stem out of water. If
cross section area of stem is 0.75cm2 calculate
i.
The total volume of stem just under the surface of the liquid
ii. The relative density
of the liquid
Data given (b):
Mass of hydrometer, mh
= 27g
Mass of water
displaced, mw = 27g
Area of stem, A =
0.75cm2
Height of stem, h = 4cm
Density of water, ρw =
1g/cm3
Density of liquid, ρl =
?
Solution
i. Total volume, vt =
v1 + v
Volume of stem, v1 = Ah
= 3 cm3
Volume of bulb, v = mw
x ρw = 27 cm3
vt = v1 + v
vt = Ah + mw x ρw
vt = (3 + 27) cm3
vt = 30 cm3
ii. Relative density,
R.D = ?
From: R.D
= ρl/ρw
But: ρl
= ml/vt = 27/30 = 0.9 g/cm3
Then: R.D
= ρl/ρw 0.9/1 = 0.9
R.D = 0.9
Example,
A balloon of volume
2000m3 is filled with hydrogen of density 0.09 kg/m3. If the mass of fabric is
100kg and that of the pilot is 75kg,
i.
What will be the greatest mass of equipment that can be carried when operation
in air is 1.25kg/m3?
ii. How would this figure
change if helium, which has twice the density of hydrogen under the same
condition, were to be used?
Solution
i. For hydrogen
Data given
Mt total mass = mt =
(ml + mb)
Volume of hydrogen, v2
= 2000m3
Volume surrounding, v1
=20000m3
Mass of balloon, mb =
(75+100) = 175kg
Density at v2, ρ2 =
0.09kg/m3
Density at v1, ρ1 =
1.25kg/m3
Density change, Δρ =
(ρ2-ρ1) = (1.25 - 0.09) = 1.16kg/m3
Solution
Mass of instrument), ml
= ?
From: v = (ml + mb)/Δρ
– make ml subject
Ml = (v x Δρ) - mb
Ml = (2000 x 1.16) –
175
Ml = 2320 – 175
Ml = 2145kg
ii. For helium
Data given
Mt total mass = mt =
(ml + mb)
Volume of helium, v2 =
2000m3
Volume surrounding, v1
=20000m3
Mass of balloon, mb =
(75+100) = 175kg
Density at v2, ρ2 =
0.18kg/m3
Density at v1, ρ1 =
1.25kg/m3
Density change, Δρ =
(ρ2-ρ1) = (1.25 - 0.18) = 1.07kg/m3
Solution
Mass of instrument), ml
= ?
From:
v = (ml + mb)/Δρ
– make ml subject
Ml = (v x Δρ) - mb
Ml = (2000 x 1.07) –
175
Ml = 2140 – 175
Ml = 1965kg
Example,
The mass of a piece of
cork (0.25 g/cm3) is 20g. What fraction of the cork is immersed when it floats
in water?
Data given
Mass of cork, mc = 20g
Density of cork, ρc =
0.25 g/cm3
Density of water, ρw =
1 g/cm3
Cork Fraction immersed,
x = ?
Volume of water
displaced, vw = ?
Volume of cork
immersed, vc = ?
Solution
From: principle of
flotation (vw = vc)
Mc = mass 0f water, mw
20 = vw x 1
Vw = vc = 20 cm3
But: x = vc/vt
Where: Volume of cork,
vt = ?
From: ρc = mc/vt
Vt = mc/ ρc = 20/0.25 =
80 cm3
Vt = 80 cm3
X = 20/80 = 1/4
X = 1/4
Example,
The mass of a piece of
cork (0.25 g/cm3) is 20g. What fraction of the cork is immersed when it floats
in alcohol?(density of alcohol is 0.8 g/cm3)
Data given
Mass of cork, mc = 20g
Density of cork, ρc =
0.25 g/cm3
Density of alcohol, ρa
= 0.8 g/cm3
Cork Fraction immersed,
x = ?
Volume of alcohol
displaced, va = ?
Volume of cork
immersed, vc = ?
Solution
From: principle of
flotation (va = vc)
Mc = mass 0f water, mw
20 = vw x 0.8
Vw = va = 25 cm3
But: x = vc/vt
Where: Volume of cork,
vt = ?
From: ρc = mc/vt
Vt = mc/ ρc = 20/0.25 =
80 cm3
Vt = 80 cm3
X = 25/80 = 5/16
X = 5/16
Example,
A uniform pencil floats
upright in water with 8cm of its length immersed. What length is immersed when
its floats in glycerol (density of glycerol is 1.3 g/cm3)?
Data given
Length of pencil
immersed in water,lw = 8cm
Density of glycerol, ρg
= 1.3 g/cm3
Density of water, ρw =
1 g/cm3
Length of pencil
immersed in glycerol, lg = ?
Solution
But: R.D
of glycerol = lw/lg
Then: lg
= lw/R.D = 8/1.3 = 6.2cm
lg = 6.2cm
Example,
A balloon and the gas
in it have a mass of 450g and its volume is 500 litres. What is the maximum
load it can lift in air of density 1.3 g/cm3?
Data given
Total mass, mt = (ml +
mb)
Mass of balloon, mb =
450g
Density of gas, ρg =
1.3 g/cm3
Density change, Δρ =
1.3 g/cm3
Volume of balloon, vb =
500 litres
Maximum load, ml = ?
Solution
Maximum load, ml = ?
From: v = (ml
+ mb)/Δρ – make ml subject
Ml = (v x Δρ) - mb
Ml = (500 x 1.3) – 450
Ml = 650 – 450
Ml = 200g
Example, : NECTA 2012
The diagram below shows
on form of man hydrometer used to me to measure the densities of liquid over
the range of 0.8 to 1.00 g/cm3. If the area of cross section of the stem is 0.5
cm2 and the distance between the 0.80 and 100 division is 18cm determine
(a)
The volume of hydrometer below 1.00 graduated
(b) The position of the
0.90 graduation
Data given
Cross section area of
stem, A = 0.5cm2
Height of steam, h = 18
cm
The volume of steam, v1
= Ah = 9 cm3
Total volume, vt = (9 +
v2) cm3
Minimum density, ρmn =
0.8 g/cm3
Maximum density, ρmx =
1.0 g/cm3
The volume of bulb, v2
= ?
Solution
(a) The volume of bulb,
v2 = ?
From: v2 = (Ah x
ρmn)/(ρmx - ρmn)
v2 = (9 x 0.8)/(1 –
0.8)
v2 = 7.2/0.2
v2 = 36 cm3
(b) What height, h2 of
hydrometer when shifted to measure 0.9 g/cm3
But: weight
of hydrometer never change
V3 x 0.9 x 0.01N =
0.36N
V3 = 40 3
V3 = Ah2
h2 = 8cm
video show
video show
