RU176486U1 - Device for magnetic fluid processing - Google Patents

Abstract

The proposed utility model relates to techniques for magnetic processing of liquid media. It can be used in the power system to prevent scale formation, for magnetic desalination of water and its activation, for mineral processing, etc. The technical result of the claimed utility model consists in increasing the functional flexibility, the efficiency of magnetic processing of the liquid and the simplicity of technical implementation by expanding the range flow rates of the processed fluid and the use of additional regulatory parameters - the frequency and amplitude of oscillations of the microvolumes of the liquid medium in The technical result is achieved by the fact that an acoustic system is created inside this channel into the device for magnetic fluid treatment, which contains a channel for fluid flow and a magnetic system that creates a magnetic field inside this channel with a magnetic induction vector perpendicular to the velocity of the fluid flow an acoustic field in which the vector of the local velocity of fluid oscillations is directed perpendicular to the vector of induction of the magnetic field generated by the magnetic system. In addition, the acoustic system is made in the form of a rod located in the channel for fluid flow parallel to the magnetic field induction vector, emitting acoustic energy in the radial direction or in the form of a comb, consisting of at least two rods located in the channel for fluid flow parallel to the magnetic field vector radiating acoustic energy in the radial direction, and the phases of the oscillations of adjacent emitters are opposite. In this case, the operating frequency of the speaker system is selected in the range from 30 Hz to 100 kHz, water is used as the liquid, which feeds the heat generator or liquid hydrocarbon fuel, the rod located in the channel for the flow of liquid emits using the piezoelectric effect or using the magnetostriction effect. ensure the achievement of the above technical result. 7 c.p. f-ly.

Description

The proposed device is a utility model (PM) relates to the technique of magnetic processing of liquid media. It can be used in the power system to prevent scale formation, for magnetic desalination of water and its activation, in mineral processing, etc.

A device for magnetic fluid treatment (MOF) is known, comprising a channel for fluid flow and a magnetic system that creates a magnetic field inside this channel with a magnetic induction vector perpendicular to the fluid flow rate, which corresponds to the essential features of the proposed.

In addition, it contains serially mounted magnetized axially annular permanent magnets separated by washers of soft magnetic material, forming an internal direct-flow hydraulic actuator, and a screen covering the external magnetic system (see, for example, AS USSR N 1134550, class C02F 1 / 48, 1985).

A disadvantage of the known device is the reduction in functional flexibility, including the low efficiency of liquid processing due to the fact that the MF effect may be reduced due to non-optimal values of the water flow rate, in particular, it is ineffective for a liquid velocity of less than 0.1 m / s and more 10 m / s. In addition, the mismatch between the characteristics of the liquid medium and the optimal values for the given flow velocity and magnetic induction also reduces the anti-scale effect. This reduces the competitiveness of known devices.

To explain the reasons for this drawback, the principle of operation of the magnetic water treatment device (MOB) should be explained. According to the MOB model, when a particle surrounded by a double electric layer (DEL) moves in a transverse magnetic field, the thickness of the DEL decreases by ΔX due to the Lorentz forces [Koshoridze SI, Levin Yu.K. The mechanism of descaling during magnetic treatment of water in thermal power devices // Thermal Engineering. 2013. No3. S. 74-77]. This reduces the strength of the Coulomb repulsion of colloidal particles and causes their coagulation in the water volume due to the predominance of molecular attraction forces (London). In this case, the deposition of scale salts on the wall decreases. The Lorentz force F _L acting on the charge q, which moves with a speed v in a field with magnetic induction B is determined by the product:

Moreover, in the experiments, the range of optimal values of the MOB device parameters was established: v = (0.5-2) m / s with induction B from 2.5 to 0.1 Tesla. From here, the inoperability of the MOB devices for standing water v = 0 is directly visible.

Closest to the claimed device by technical essence is a device for magnetic processing of liquid, containing a channel for the flow of liquid and a magnetic system that creates inside this channel a magnetic field with a magnetic induction vector perpendicular to the velocity of the liquid flow, which corresponds to the essential features of the proposed.

In addition, it contains a ferromagnetic pipe and permanent ring magnets mounted on its outer surface, enclosed in a hermetically sealed ferromagnetic screen and installed so that their main surfaces with the same poles face the pipe axis [Patent US N 5122277, cl. С02F 1/48, cl. NKI 210-695, published. 1992). Since the permanent magnets face the pipe axis with the same poles, an axial magnetic field is created in the pipe cavity. The fluid flowing through the pipe is processed by this magnetic field of a given tension.

The disadvantage of this device is the decrease in the efficiency of magnetic processing of the liquid for reasons similar to the above.

Accordingly, the technical result required for the implementation of the device consists in increasing the functional flexibility, the efficiency of magnetic processing of the liquid and the simplicity of the technical implementation by expanding the range of flow rates of the treated liquid and using additional regulatory parameters - the frequency and amplitude of oscillations of the microvolumes of the liquid medium in the applied acoustic field.

In order to eliminate the disadvantages of the prototype, a device for magnetic fluid treatment is proposed, comprising a channel for fluid flow and a magnetic system that creates a magnetic field inside this channel with a magnetic induction vector perpendicular to the fluid flow rate, which corresponds to the essential features of the known device. At the same time, an acoustic system was introduced that creates an acoustic field inside this channel, in which the vector of the local fluid velocity is directed perpendicular to the magnetic field induction vector generated by the magnetic system.

In addition, the speaker system is made in the form of a rod located in the channel for the flow of liquid parallel to the induction vector of a magnetic field that emits acoustic energy in the radial direction.

In addition, the acoustic system is made in the form of a comb, consisting of at least two rods located in the channel for fluid flow parallel to the magnetic field induction vector, emitting acoustic energy in the radial direction, and the phases of the oscillations of adjacent emitters are opposite.

In addition, the operating frequency of the speaker system is selected in the range from 30 Hz to 60 kHz.

In addition, water that feeds the heat generator is used as a liquid.

In addition, liquid hydrocarbon fuel is used as a liquid.

In addition, the rod located in the channel for fluid flow emits using the piezoelectric effect

In addition, a rod located in the channel for fluid flow emits using the magnetostriction effect.

We explain the principle of operation of the proposed device. As shown earlier, when water moves in a magnetic field, the Lorentz forces, deforming the double electric layer (DEL) and decreasing the electrokinetic potential (EPC), stimulate the coagulation of colloidal particles (CN). The supersaturation of the solution with respect to the enlarged CNs causes an avalanche crystallization of scale salts on them, which reduces their flow to the pipe walls. This is due to the anti-scale effect of MOB. However, in the field of sound waves, water particles also move. Therefore, when a magnetic field is applied, Lorentz forces will appear that can cause an anti-scale effect, as with the traditional implementation of MOB.

We will evaluate the real characteristics of the MOB device with an ultrasonic generator. As expected, the magnetic field is perpendicular to the direction of propagation of the sound wave in water. We assume that there is a standing sound wave in the vessel. For the oscillation frequency ν = 20 kHz, at the speed of sound in water with = 1480 m / s, we obtain the wavelength λ = s / ν = 74 mm. If the emitter oscillates with a frequency ν and amplitude x ₀ (for example, x ₀ = 50 μm), each element of the water mass will perform harmonic oscillations near the emitter (for simplicity, we will not take into account the spatial attenuation of the oscillation amplitude). The dependence of the speed of oscillatory motion on time is described by law

,

,

where the amplitude of the velocity V _{0 is} determined by the expression

.

.

The parameter k varies from 0 (node of a standing wave) to 1 (antinode) (in our example, 0≤V ₀ ≤6.2 m / s). (Accordingly, the necessary Lorentz force is formed in a wide range of frequencies of acoustic vibrations and is not limited by the flow rate of the water stream.

The calculation shows that in the real range of parameters of the MOB device with sufficient values of the power of the ultrasonic wave, ultrasonic treatment of water in the presence of a static magnetic field has a significant anti-scale effect. Indeed, at the initial value of the electrokinetic potential (EPC) of colloidal particles of 0.1–50.3 mV, the obtained EPC bias is (15–50)%. Given the exponential dependence of the efficiency of MOB on ECP, one can expect a decrease in scale by a factor of ten with the corresponding parameters of the MOB settings. As already noted, an ultrasonic wave provides an anti-scale effect on its own - regardless of the speed of the water flow, i.e. in the range of water flow rates 0 <v <0.1 v / s and 10 <v, which widens the range of effective operation of the MOB device. Essentially, the anti-scale effect of traditional MOB is complemented by the anti-scale effect of ultrasound, which is especially noticeable in the case of standing water, when traditional MOB devices are inoperative. At the same time, it is possible to further customize the device by changing the characteristics of the acoustic field - the frequency and amplitude of the wave.

Further, we show that it is thanks to the significant differences of the proposed installation that the required technical result is provided.

The fact that the device contains a channel for fluid flow and a magnetic system that creates a magnetic field inside this channel with a magnetic induction vector perpendicular to the velocity of the fluid flow, while introducing an acoustic system that creates an acoustic field inside this channel in which the local velocity vector of the fluid oscillates perpendicular to the induction vector of the magnetic field generated by the magnetic system, provides the movement of microvolumes of the liquid medium, even at a water flow velocity v = 0. Therefore, even in this case, the anti-scale effect of the MOB is realized - the Lorentz force appears, the coagulation of particles in the bulk of the liquid is stimulated, which reduces the scale on the walls of the heat generating units. At the same time, the magnetization process is regulated by changing the characteristics of the acoustic field - wave frequency and amplitude, which increases the functional flexibility of the device not only by expanding the range of fluid flow rates, but also by expanding the characteristics of the liquid medium itself (degree of supersaturation, viscosity, electrical conductivity). It should be noted that the adjustment of the parameters of the MF devices in known devices was provided by changing the flow velocity and changing the magnetic field induction vector, which is more difficult to implement and not always possible.

The fact that the speaker system is made in the form of a rod located in the channel for fluid flow parallel to the magnetic field induction vector, emitting acoustic energy in the radial direction, also ensures the movement of microvolumes of the liquid medium in the direction perpendicular to the magnetic field induction vector, including during expansion characteristics of the liquid medium itself. Accordingly, the anti-scale effect of MOB is implemented in a wide range of fluid flow rates, with the possibility of additional adjustment and simple technical means, which confirms the achievement of the required technical result in the proposed.

The fact that the speaker system is made in the form of a comb, consisting of at least two rods located in the channel for fluid flow parallel to the magnetic field induction vector, emitting acoustic energy in the radial direction, and the oscillation phases of adjacent emitters are opposite, also provides movement microvolumes of a liquid medium in a direction perpendicular to the magnetic field induction vector. In this case, the required ultrasound power is distributed on several emitters, which simplifies the technical implementation of the MOB device and provides the required technical result in the proposed.

The fact that the operating frequency of the speaker system is selected in the range from 30 Hz to 100 kHz, makes it possible to adapt the MOB device to the real geometry of the magnetized part of the channel for the fluid flow of the MOB device and provides the required technical result in the proposed one.

The fact that water is used as a liquid, which feeds the heat generator, provides an increase in the efficiency of MOB in a wide flow range and significantly increases the efficiency of thermal installations and boilers.

The fact that liquid hydrocarbon fuel is used as a liquid expands the arsenal of functional capabilities of the MOF device and allows the magnetization process to be carried out in a closed vessel.

The fact that the rod located in the channel for the flow of fluid emits using the piezoelectric effect simplifies the technical implementation of MF devices and increases their competitiveness.

The fact that the rod located in the channel for the flow of fluid emits using the magnetostriction effect simplifies the technical implementation of MF devices and increases their competitiveness.

Thus, it is shown that the required technical result, in fact, is achieved due to the significant differences of the proposed installation.

The experiments showed the feasibility of the proposed utility model.

Claims (8)

1. A device for magnetic processing of liquid, containing a channel for the flow of liquid and a magnetic system that creates inside this channel a magnetic field with a magnetic induction vector perpendicular to the velocity of the liquid flow, characterized in that an acoustic system is introduced that creates an acoustic field inside this channel in which the vector of the local oscillation velocity of the liquid is directed perpendicular to the induction vector of the magnetic field formed by the magnetic system. 2. The device according to p. 1, characterized in that the speaker system is made in the form of a rod located in the channel for fluid flow parallel to the magnetic field induction vector that emits acoustic energy in the radial direction. 3. The device according to p. 1, characterized in that the acoustic system is made in the form of a comb, consisting of at least two rods located in the channel for fluid flow parallel to the magnetic field induction vector, emitting acoustic energy in the radial direction, and the phase oscillations of adjacent emitters are opposite. 4. The device according to p. 1, characterized in that the operating frequency of the speaker system is selected in the range from 30 Hz to 100 kHz. 5. The device according to p. 1, characterized in that the liquid used is water that feeds the heat generator. 6. The device according to p. 1, characterized in that the liquid used is liquid hydrocarbon fuel. 7. The device according to claim 2, characterized in that the rod located in the channel for the flow of liquid emits using the piezoelectric effect. 8. The device according to p. 2, characterized in that the rod located in the channel for the flow of liquid emits using the magnetostriction effect.