Lecture -2 ( properties of fluids (part 1) - density, specific weight, specific gravity )

Properties are certain measurable characteristics that can be quantified. with the help of properties we can easily identify the fluids.
Properties of fluids are as follows-

Density or mass density (ρ) 

Density is defined as the ratio of mass per unit volume. The international System of units ( SI units ) is Kilogram per metre cube (kg/m^3).
Density basically represent the number of molecules in a given volume of fluid. As we increase the number of molecules in a given volume its mass will increase and fluid become heavy.
               Density (ρ) = mass/volume 
                                 ρ = m/V
Density of water = 1000 kg/m^3
Density of Mercury = 13600 kg/m^3
Density of air = 1.2 kg/m^3
Density of petrol = 750 kg/m^3
Density of diesel = 850 kg/m^3
Density of solids is always greater than density of liquids and density of liquids is always greater than density of gases.
As pressure of fluid increases it increases the density because with increase in pressure more and more number of molecules will start to accumulate in a given volume of fluid which increases its density.
As temperature of fluid increase its density will decrease because with increase in temperature the randomness of molecules increases they start moving here & there due to which fluid become light therefore its density decreases. 

Specific weight or weight density(w) 

It is defined as the ratio of weight (W) per unit volume (V) and its SI unit is Newton per metre cube (N/m^3).
Basically specific weight represent the force exerted by fluid due to gravity(g) in a given volume. 
 w = W/V ;  W=mg
w = mg/V = ρg  
Specific weight of water = ρwater * g = 1000*9.81 = 9810 N/m^3
Specific weight of Mercury = 13600*9.81 N/m^3
Weight (W) = specific weight (w) * volume
                ; W = w * V
                ; W = ρgV
From the above we can conclude that 'w' is dependent upon 'g' whereas density is an absolute quantity which will notwill not varry with location.

Specific gravity (S) 

specific gravity is defined as the ratio of density of fluid to the density of standard fluid. If fluid is liquid then standard fluid is taken as water and if fluid is gas then  standard fluid is taken as air.
Specific gravity of liquid represent which liquids are heavier then Water and which are lighter then water. Specific gravity of gas represent which gas is heavier then air and which gas is lighter then air.
   S = ρfluid/ρstandard fluid  
Specific gravity is dimensionless quantity.
Example- 
Problem - Find specific gravity for petrol.
Solution - ρpetrol = 750 kg/m^3
                    ρstandard fluid = ρwater = 1000 kg/m^3
                   S = 750/1000 = .75 
If S > 1 than fluid is heavier than water
If S < 1 than fluid is lighter than water
If S = 1 than fluid is water

(Remember all specific gravity are relative density but all relative densities are not specific gravity)
ρsolidliquid , ρliquidgas , ρgassolid are relative density 

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