RU2056932C1 - Method to bring particles of one dielectric dispersed in volume of another dielectric into pulsation - Google Patents

Abstract

FIELD: treatment of substances with electromagnetic emissions. SUBSTANCE: method is based on continuous irradiation of dielectric volume, that carries dispersed particles of another dielectric, by electromagnetic signal with given parameters. In the case preliminary they determine frequencies of own mechanical oscillations of one dielectric particles dispersed in volume of another dielectric. In case the frequencies exceed earlier set value, they chose value of carrying frequency, that is near half value of mode of dielectric particles own oscillations. In case it does not exceed the given value, they are modulating the carrier by amplitude with frequency, that is close to frequency of dielectric particles own oscillations mode. EFFECT: increased efficiency. 7 dwg

Description

 The invention relates to methods of exposure to substances using electromagnetic radiation and can be used, for example, in biology, medicine and other fields.

A known method of cleaning mineral materials using radio frequency vibrations, which heat and evaporate extraneous particulate matter, polluting the base material [1]
This method has a narrow application due to the fact that extraneous particulate matter should differ sharply from the main one in the nature of the exposure to radio frequency vibrations.

Closest to the proposed is a method of bringing to a pulsation of fuel particles in a fuel-air mixture, which consists in irradiating the mixture with an electromagnetic signal with frequencies corresponding to the frequencies of nuclear magnetic resonance of at least one of the fuel components [2]
This method is limited to use for fuel mixtures only.

 To overcome this drawback in the method of pulsating particles of one dielectric distributed in the volume of another dielectric, which consists in continuously irradiating this volume with an electromagnetic signal with specified parameters, the frequencies of natural mechanical vibrations of particles of one dielectric in the volume of another dielectric are determined in advance, if these frequencies are exceeded in advance of the set value, the magnitude of the carrier frequency of the electromagnetic signal near the half frequency of any, starting from the second oh, the modes of natural mechanical vibrations of particles of one dielectric in the volume of another dielectric, and if the predetermined frequencies are not reached a predetermined value, the carrier frequency of the electromagnetic signal is modulated in amplitude with a modulation frequency near any frequency, starting from the second mode of natural mechanical vibrations of particles of one dielectric in the volume of another dielectric.

 Objects with such a combination of essential features are not known from the prior art, which makes it possible to consider the proposed proposed corresponding criterion of "novelty." The prior art also does not know objects with a combination of distinctive features of the present invention, which allows us to consider it relevant to the criterion of "inventive step".

 Figure 1 presents the forces acting when an electromagnetic wave is incident on the boundary of two dielectrics; figure 2 changes in the shape of a spherical drop of a dielectric when exposed to an electromagnetic signal; figure 3 changes in the magnitude of the charges around the particles of the dielectric; figure 4 case, when the dielectric particle has the shape of a cylinder; figure 5 is the case of a spherical particle, when the ratio of the dielectric constant of the particle and the environment back with respect to figure 3; in Fig.6 the case of Fig.4, but with an inverse ratio of permittivity; 7, a change in the shape of a particle under the action of a modulated electromagnetic signal.

 The basis of the proposed method are the following processes.

=

ε_o(ε₂-ε₁)

+

(1) где ε _o диэлектрическая проницаемость вакуума; E_1t, E_1n тангенциальная и нормальная составляющие вектора электрической компоненты волны Е₁ во внешнем диэлектрике. Через граничные условия Е_1t= E_2t ε₁E_1n ε₂ E_2n формула (1) может быть записана для электрической составляющей волны Е₂ во внутреннем диэлектрике.Let the surrounding dielectric can have both a higher density ρ ₁ and therefore a higher dielectric constant ε ₁ and a lower density and lower dielectric constant than an internal dielectric with a density ρ ₂ and dielectric constant ε ₂ When an electromagnetic wave acts on an internal dielectric body its surface there are various forces leading to ripple. This is the generalized Coulomb force, the generalized Ampere force and the ponderomotive force. The latter occurs at the boundary of two dielectrics, perpendicular to the interface and is always directed towards the dielectric with a lower density and lower dielectric constant (figure 1). The value of the pondermotor force is calculated by the formula

=

ε _o (ε ₂ -ε ₁ )

+

(1) where ε _{o is the} dielectric constant of the vacuum; E _1t , E _{1n the} tangential and normal components of the vector of the electrical component of the wave E ₁ in the external dielectric. Through the boundary conditions E _1t = E _2t ε ₁ E _1n ε ₂ E _2n, formula (1) can be written for the electric component of the wave E ₂ in the internal dielectric.

(2) где R расстояние между наведенными зарядами; ε диэлектрическая проницаемость среды.The generalized Coulomb force describes the force of attraction between two induced charges q ₁ and q ₂ and is equal to
F _k =

(2) where R is the distance between induced charges; ε dielectric constant of the medium.

(3) где

,

векторы наведенных токов; μ магнитная проницаемость среды.The generalized Ampere force describes the force of attraction between two induced currents (polarization or bias currents) and is equal to
F _A =

(3) where

,

vectors of induced currents; μ is the magnetic permeability of the medium.

 These forces allow us to explain the effect of pulsation of the internal dielectric under the influence of an incident electromagnetic wave with a certain modulation in power.

падающей волны будут направлены внутрь обобщенные силы Кулона, вызванные наведенными на границе раздела зарядами, и перпендикулярно вектору

будут действовать обобщенные силы Ампера, вызванные токами смешения (поляризации) I_пол. Если внутренний диэлектрик может сжиматься (как, например, газ), то действующие силы приведет к уменьшению объема внутреннего диэлектрика, пока эти силы не уравновесятся механическими силами, направленными в обратную сторону. Если же внутренний диэлектрик несжимаем, то сфера деформируется в сфероид в соответствии с превышением одних действующих сил над другими. Изменение величины

в падающей электромагнитной волне приводит к изменению величины действующих сил, а следовательно, к изменению величины сжатия или деформации.If the external dielectric has a higher density than the internal, and therefore ε ₁ > ε _2, then when an electromagnetic wave acts on the internal dielectric, the shape of which has, for example, the shape of a sphere, the forces shown in Fig. 2 will act on it. Ponderomotive forces will be directed inward along the entire perimeter, parallel to the vector

the incident wave will be directed inward by the generalized Coulomb forces caused by the charges induced at the interface and perpendicular to the vector

generalized Ampere forces will act, caused by mixing (polarization) currents I _floor . If the internal dielectric can be compressed (such as gas), then the acting forces will lead to a decrease in the volume of the internal dielectric, until these forces are balanced by mechanical forces directed in the opposite direction. If the internal dielectric is incompressible, then the sphere is deformed into a spheroid in accordance with the excess of some acting forces over others. Change in value

in an incident electromagnetic wave leads to a change in the magnitude of the acting forces, and therefore to a change in the magnitude of compression or deformation.

 Examples of spherical bodies are air bubbles in a liquid or droplets of a less dense liquid inside a more dense one. In this case, air or other gas may be compressed, and the droplets will deform.

 Note that in time the maximum values of the generalized Coulomb force and the ponderomotive force coincide, but they will be shifted by a quarter of the oscillation period of the electromagnetic signal with respect to the maximum of the generalized Ampere force. Figure 3 shows the change in charges around the gas bubble and the magnitude of the polarization current, as well as the change in time of the gas bubble. Compression along the vertical axis of coordinates occurs more than horizontal due to the addition of the generalized Coulomb force and the ponderomotive force.

. Изменение величины

также приводит к изменению величины действующих сил и, следовательно, к изменению сжатия или деформации. Причем, как и для сферы, деформация цилиндра с круглым сечением в цилиндр с эллипсообразным сечением будет происходить вследствие неравенства действующих сил с разных направлений и несжимаемости внутреннего диэлектрика.If the internal dielectric has the shape of a cylinder and (as before) its density and dielectric constant is lower than that of the external dielectric, then the acting forces induced by the incident electromagnetic wave are all the same generalized Coulomb and Ampere forces and the ponderomotive force is directed inside the cylinder, t .e. dielectric with a lower density and lower dielectric constant (Fig. 4). In contrast to the sphere, bias currents are induced by slightly different tangential and normal components of the vector

. Change in value

also leads to a change in the magnitude of the acting forces and, consequently, to a change in compression or deformation. Moreover, as for a sphere, the deformation of a cylinder with a circular cross section into a cylinder with an elliptical cross section will occur due to the inequality of the acting forces from different directions and the incompressibility of the internal dielectric.

 Capillaries of plants, as well as human and animal blood and lymph vessels, can serve as examples of cylindrical bodies. Note that over time, the cross section of a cylindrical compressible dielectric will change similarly to that shown in Fig.3.

If the external dielectric has a lower density than the internal one, and therefore, ε ₁ <ε _2, then when an electromagnetic wave acts on the internal dielectric, which has the shape of a sphere, charges and polarization currents are induced in it according to the laws given above. The difference will be that the ponderomotive force will be directed from the internal dielectric to the external one and will be of the opposite sign with the generalized Coulomb force pulling the sphere down vertically (Fig. 5). In this case, the ponderomotive force will stretch the sphere horizontally in those areas where the generalized Coulomb force is practically zero, and will also form a resultant force aimed at stretching the sphere, and in other parts of its surface.

 The polarization currents also, in accordance with the generalized Ampere law, will contract the sphere horizontally, but with a time shift of a quarter of the period of electromagnetic oscillations. As a result, the sphere will be periodically exposed to forces seeking to bring it into a pulsation.

 Examples of such spherical bodies are nuclei in the cells of living organisms or droplets of a denser liquid inside a less dense one. Another example is grains of a compressed substance, for example, solid fuel in rocket engines and the like.

If the internal dielectric has the shape of a cylinder and its density ρ ₂ and permittivity ε ₂ exceed the similar parameters of the external dielectric (Fig. 6), then the same forces will act on it as depicted in Fig. 4 with the only difference that the ponderomotive force around the entire perimeter of the cylinder is directed towards the external dielectric and, as it were, stretches the cylinder in all directions. When looking at the cross section of the cylinder from above, it can be seen that it is subjected to a similar action of forces as the sphere trying to bring it into pulsation.

 An example of the described cylinder is the entire plant stem. The magnitude of the deformation of the internal dielectric depends on two factors: the power of the incident electromagnetic wave and the degree of proximity of the doubled carrier frequency (Fig. 3) of the electromagnetic wave to the intrinsic mechanical resonant frequencies of the body of the internal dielectric. In this case, the change in the shape of the sphere is rigidly connected (phased) with the carrier frequency of the incident electromagnetic wave. If the frequency of the carrier vibration is much higher than the intrinsic mechanical resonance frequencies of the sphere, then the sphere can be pulsed by providing the incident electromagnetic wave with amplitude modulation, and the frequency of the amplitude modulation should be equal to or close to the natural resonant frequencies of the sphere. The possibility of bringing into mechanical resonance due to the coincidence of the natural resonant frequency with the frequency of the amplitude modulation is due to the fact that when the direction of the vector E is reversed during the same period of the carrier oscillation of the incident electromagnetic wave, the direction of the forces that deform the body remains unchanged. Therefore, in this case, reduction of the internal dielectric into a mechanical resonance oscillation (pulsation) is possible only due to a change in the wave power due to the introduction of amplitude modulation into the wave, i.e. due to periodic changes in the average value of the force applied to the body (Fig.7).

 A similar ripple reduction mechanism also applies to the dielectric cylinder.

 The choice of the carrier frequency of the irradiating electromagnetic wave or the frequency of the amplitude modulation to bring the internal dielectric in the form of a sphere or cylinder into a pulsation is as follows.

(n-1)n(n+1)(n+2)

(4) где n 0,2,3, порядковые номера моды собственных резонансных колебаний; Т_пн сила поверхностного натяжения на границе внешнего и внутреннего диэлектриков; а радиус сферы внутреннего диэлектрика. Размерности входящих в (4) величин следующие: частота в Гц; радиус а в см; плотность ρ в г/см³, сила Т_пн в дин/см. Формула (4) описывает приближенно частоты колебаний диэлектрического цилиндра в сечении, перпендикулярном оси цилиндра. Нулевая мода колебания (n 0) приводит к мнимому значению частоты f_п, т.е. к сжатию внутреннего диэлектрика. При n= 1 моды не существует. При n 2 существует мода, называемая дипольной, приводящая к показанной на фиг.7 деформации внутреннего диэлектрика в процессе пульсации. С ростом n амплитуды деформаций уменьшаются, поэтому ориентироваться при выборе частоты в облучающей электромагнитной волне необходимо на дипольную моду.If the external dielectric has a density ρ ₁ and the internal ρ ₂ then the frequencies of the resonant oscillations of the sphere are expressed by the formula
f _n = 2π

(n-1) n (n + 1) (n + 2)

(4) where n is 0.2.3, the sequence numbers of the mode of natural resonance oscillations; T _{Mon the} force of surface tension at the boundary of the external and internal dielectrics; and the radius of the sphere of the internal dielectric. The dimensions of the quantities included in (4) are as follows: frequency in Hz; radius a in cm; density ρ in g / cm ³ , force T _mon in dyne / cm. Formula (4) describes approximately the oscillation frequency of the dielectric cylinder in a section perpendicular to the axis of the cylinder. The zero vibration mode (n 0) leads to the imaginary value of the frequency f _p , i.e. to compression of the internal dielectric. For n = 1, the mode does not exist. At n 2, there exists a mode called dipole, which leads to the deformation of the internal dielectric in the process of ripple shown in Fig. 7. With an increase in n, the strain amplitudes decrease, therefore, when choosing a frequency in the irradiating electromagnetic wave, it is necessary to navigate to the dipole mode.

 The imaginary value of the frequency at n = 0 means the absorption of an electromagnetic wave, which can be used to create a radio-absorbing layer to protect personnel of radio stations from harmful exposure to long-wave radio signals. The radar absorbing layer is formed by creating in a cuvette with a liquid a curtain of air bubbles whose sizes are consistent with the wavelength of the signals emitted by the radio station. Using a veil of bubbles formed in front of the underwater radio antenna, it is possible to disrupt communication with underwater objects due to the absorption of the radio signals sent to them.

 The dipole vibrational mode (n 2) can be used to accelerate chemical reactions by imparting pulsating movements to the reacting components, as well as accelerating the crystallization of matter. In addition, imparting pulsating movements to the nuclei of cells of living organisms can, with a small amplitude of pulsations, lead to an acceleration of biological processes in the cell, and with a large amplitude to cell death or the appearance of a mutation. Pulsations of DNA and RNA molecules or parts thereof can lead to similar results. The coincidence of the frequency of the forced vibrations of the grains of the sintered powder with its own vibrations can weaken the strength of the substance or cause its dispersion. In this way, plastic mines located at a shallow depth in the ground and undetectable by mine detectors can be wrecked.

 Pulsation of plant stems or capillaries in them will lead to stimulation of the supply of nutrients to the fruits and accelerate their ripening. The pulsation of blood vessels in living organisms will lead to faster passage of blood through them, and possibly to accelerate wound healing.

 If the internal dielectric has a more complex shape than a sphere or cylinder, then the pulsation of such a body will have a more complex character, they will have significantly more resonant frequencies and modes. To calculate the effective forces in this case, it is necessary to use the Maxwell tension tensor.

 The implementation of the proposed method is feasible using an electromagnetic oscillator of the corresponding frequency, loaded on a directional antenna and having the ability to modulate the generated signal in amplitude.

 Thus, the proposed method allows to bring into pulsation particles of one dielectric in the volume of another dielectric, which opens up new possibilities in various fields.

Claims (1)

 METHOD OF PASSING PARTICLES OF ONE DIELECTRIC DISTRIBUTED IN THE VOLUME OF ANOTHER DIELECTRIC, which consists in continuously irradiating this volume with an electromagnetic signal with predetermined parameters, characterized in that the frequencies of the natural mechanical vibrations of particles of one dielectric in the volume of another dielectric are determined in advance when the excess of these dielectrics exceeds a predetermined limit values select the magnitude of the carrier frequency of the electromagnetic signal near half the frequency of any mode of the eigenmechanically x oscillations of particles of one dielectric in the volume of another dielectric, and if the predetermined frequencies are not reached a predetermined value modulates the carrier frequency of the electromagnetic signal in amplitude with a modulation frequency near the frequency of any, starting from the second, the mode of natural mechanical vibrations of particles of one dielectric in the volume of another dielectric .

Images