The theory of sonics is a branch of continuum mechanics which describes the transmission of mechanical energy through vibrations. The birth of the theory of sonics[1] is the publication of the book A treatise on transmission of power by vibrations in 1918 by the Romanian scientist Gogu Constantinescu.
ONE of the fundamental problems of mechanical engineering is that of transmitting energy found in nature, after suitable transformation, to some point at which can be made available for performing useful work. The methods of transmitting power known and practised by engineers are broadly included in two classes: mechanical including hydraulic, pneumatic and wire rope methods; and electrical methods....According to the new system, energy is transmitted from one point to another, which may be at a considerable distance, by means of impressed variations of pressure or tension producing longitudinal vibrations in solid, liquid or gaseous columns. The energy is transmitted by periodic changes of pressure and volume in the longitudinal direction and may be described as wave transmission of power, or mechanical wave transmission. - Gogu Constantinescu[2] [3]
Later on the theory was expanded in electro-sonic, hydro-sonic, sonostereo-sonic and thermo-sonic.The theory was the first chapter of compressible flow applications and has stated for the first time the mathematical theory of compressible fluid, and was considered a branch of continuum mechanics. The laws discovered by Constantinescu, used in sonicity are the same with the laws used in electricity.
The book A treatise on transmission of power by vibrations has the following chapters:
George Constantinescu defined his work as follow.
If v is the velocity of which waves travel along the pipe, and n the number of the revolutions of the crank a, then the wavelength λ is:
λ=
| v | |
| n |
Considering any flow or pipes, if:
ω = the area section of the pipe measured in square centimeters;
v = the velocity of the fluid at any moment in centimeters per second;
and
i = the flow of liquid in cubic centimeters per second,
then we have:
i = vω
Assuming that the fluid current is produced by a piston having a simple harmonic movement, in a piston cylinder having a section of Ω square centimeters.If we have:
r = the equivalent of driving crank in centimeters
a = the angular velocity of the crank or the pulsations in radians per second.
n = the number of crank rotations per second.
Then:
The flow from the cylinder to the pipe is: i = I sin(at+φ)
Where:
I = raΩ (the maximum alternating flow in square centimeters per second; the amplitude of the flow.)
t = time in seconds
φ = the angle of the phase
If T= period of a complete alternation (one revolution of the crank) then:
a = 2πn; where n = 1/T
The effective current can be defined by the equation:
| 2= | |
| I | |
| eff |
| 1 | |
| T |
| T | |
| \int\limits | |
| 0 |
i2dt
veff=
| Ieff | |
| \omega |
\delta=2r\Omega=2
| I | |
| a |
The alternating pressures are very similar to alternating currents in electricity.In a pipe where the currents are flowing, we will have:
p=H\sin{(at+\Phi)}+pm
\Phi=
pm
the minimum pressure is
Pmin=Pm-H
Pmax=Pm+H
The difference
h=p1-p2=H\sin{(at+\Phi)}
Heff=
| H | |
| \sqrt{2 |
In alternating current flowing through a pipe, there is friction at the surface of the pipe and also in the liquid itself. Therefore, the relation between the hydromotive force and current can be written as:
H=Ri
| kg.sec. | |
| cm.5 |
Using experiments R may be calculated from formula:
R=\epsilon
| \gammalveff | |
| 2g\omegad |
Where:
\gamma
\omega
\epsilon=0.02+
| 0.18 | |
| \sqrt{veffd |
If we introduce
\epsilon
R=
| \gammal | |
| g\omega |
(0.01
| v | |
| d |
+
| 0.09 | |
| d |
\sqrt{
| veff | |
| d |
100k=
| veff | |
| d |
+
| 9 | \sqrt{ | |
| d |
| veff | |
| d |
R=k
| \gammal | |
| g\omega |
W=
| 1 | |
| T |
| T | |
| \int | |
| 0 |
hidt
W=
| 1 | |
| T |
| T | |
| \int | |
| 0 |
| ||||
| Ri |
| T | |
| \int | |
| 0 |
| ||||
| i |
Therefore:
W=
| RI2 | = | |
| 2 |
| HI | |
| 2 |
=Heff x Ieff
Definition: Hydraulic condensers are appliances for making alterations in value of fluid currents, pressures or phases of alternating fluid currents. The apparatus usually consists of a mobile solid body, which divides the liquid column, and is fixed elastically in a middle position such that it follows the movements of the liquid column.
The principal function of hydraulic condensers is to counteract inertia effects due to moving masses.