Following figure, displayed here, indicates the condition of one-dimensional propagation of the pressure waves. Let us consider a cylinder of having uniform cross-sectional area attached with a piston as displayed in following figure.
- Let us assume that cylinder is filled with a compressible fluid and compressible fluid is at rest initially.
If we apply a force through the piston in right direction, force will develop a pressure as force will be applied uniformly. Due to the application of force, piston will move by a certain distance let us say x towards right direction as displayed here in following figure.
Let us consider following terms from above figure as mentioned here.
x = Distance of piston from initial position
L = Distance of sound wave from initial position
P = Pressure applied over the piston at initial position
P + dP = Pressure inside the cylinder at final position
ρ = Density of the fluid at initial position
ρ + d ρ = Density of the fluid at final position
dt = Small amount of time taken by piston to travel distance x
V = Velocity of piston
C = Velocity of pressure wave or sound wave travelling in the fluid
Distance travelled by the piston in time dt from initial position, x = v.dt
Distance travelled by pressure wave or sound wave in time dt from initial position, L = C. dt
- The law of conservation of mass is Initial mass = final mass
As we know that mass will be equal to the product of density and volume.
Mass = Density x Volume=Density x Area x Length
Mass at initial position, M1 = ρ A L = ρ A C. dt
Mass at final position, M2 = (ρ + dρ) A (L-x) = (ρ + dρ) A (C. dt- V. dt)
Mass at final position, M2 = (ρ + dρ) A. dt (C - V)
- Now, considering the conservation of mass, we will have following equation as mentioned here.
Mass at initial position, M1 = Mass at final position, M2
ρ A C. dt = (ρ + dρ) A. dt (C - V)
ρ C = (ρ + dρ) (C - V)
ρ C = ρ C - ρ V + C. dρ - V dρ
- the term dρ will be very small and velocity of piston will also be very small and therefore product V dρ could be neglected.
ρ V = C. dρ
C = ρ V/ dρ -------------------------------- Eq 1
- Let us determine the force at initial position of piston and final position of piston as mentioned here
F1 = P.A
F2 = (P + dP). A
Change in force, ΔF = (P + dP). A - P.A = dP. A
- From Netwon's Second law of motion, Force is
Force = Mass x (Rate of change of velocity)
dP. A = (ρ A C. dt) [(V-u)/dt]
As we know that, V is the final velocity of the piston and u is the initial velocity of the piston and initial velocity of piston will be zero.
dP. A = (ρ A C. dt) V/dt
dP = ρ C V
C = dP / (ρ V) -------------------------------- Eq 2
We will have following equation by multiplying the equation 1 and equation 2
C^2 = (ρ V/ dρ) x [dP / (ρ V)] = dP/ dρ
C^2 = dP/ dρ
Above equation represent the velocity of sound wave in fluid.
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