RU2192390C1 - Device for magnetizing liquids - Google Patents

Abstract

FIELD: devices for magnetizing liquids and prevention of formation of asphalt gum paraffin deposits in pipe lines and fittings in the course of treatment of water pumped into wells; protection of water and heat supply systems against scaling; reduction of corrosion activity of water systems. SUBSTANCE: proposed device has magnetic system with main permanent magnets located on both sides of gap for flowing liquid; their pole surfaces are directed towards gap; direction of magnetization is perpendicular to direction of liquid flow. Opposite (relative to gap) magnets have similar direction of magnetization. Device is provided with additional permanent magnets with alternating directions of magnetization parallel to direction of liquid flow; polarities of poles of main magnets facing the gap coincide with polarity of poles of additional magnets adjoining them. Main and additional magnets are located at alternating order on magnetic circuit. Gaskets made from nonmagnetic material may be laid between main and additional permanent magnets and magnetic circuit. EFFECT: increased gradient of magnetic field intensity. 4 cl, 4 dwg

Description

 The invention relates to the field of devices for magnetizing liquids and can be used to prevent the formation of asphalt-resin-paraffin deposits in pipelines and fittings and during processing of water injected into wells during oil production, as well as in water and heat supply systems to prevent scale formation and reduce the corrosivity of water systems.

A magnetic fluid treatment device is known comprising a permanent magnet magnet system in which the permanent magnets are placed on the outer surface of a non-ferromagnetic pipeline with a flowing liquid, face the same poles to the surface of the pipeline and are arranged in pairs so that each pair of magnets is offset along the circumference of the pipeline by 90 ^o with respect to adjacent pairs of magnets in each pair are spaced apart along the tube length, and the individual pairs of magnets are offset relative to the opposed pairs lengthwise length of the pipeline. The channel for the flowing fluid is the gap between the opposed pole surfaces of the permanent magnets [England Patent 2288553, cl. C02F 1/48, publ. October 25, 1995].

 The placement of all permanent magnets with the same poles to the surface of the pipeline leads to a decrease in changes in the magnetic field along the direction of fluid motion both at the inner surface of the non-magnetic pipeline and (especially) at its axis. The intensity and intensity gradient of the magnetic field acting on the liquid also decrease due to significant losses of magnetic energy due to the scattering of the magnetic flux due to the absence of a magnetic circuit that closes the outer pole surfaces of the permanent magnets. In addition, the disadvantage of this device is the small length of the magnetic system and, as a consequence, the small length of the working volume, which reduces the duration of the magnetic treatment of the liquid. All this reduces the effectiveness of this device.

It is also known a magnetic device for processing liquids, containing a magnetic system with permanent magnets, which is a housing, inside of which with a gap are installed pairwise-sequentially permanent magnets facing the gap with their pole surfaces, and a magnetic circuit that is made common for two pairs of permanent magnets in the form rings either in the form of two coaxial rings. At both ends, the magnetic circuit has diametrically made protrusions, on the inner surface of which permanent magnets are installed in pairs, each pair of permanent magnets mounted relative to each other with an offset of 90-270 ^o , the magnets in pairs have opposite directions of magnetization and there is a longitudinal gap between the ends of the permanent magnets in within 0.1-1.5 mm. Moreover, transverse cuts are made on the outer and / or inner surface of the housing at the locations of the permanent magnets. The channel for the flowing fluid in this device also serves as a gap between the opposed pole surfaces of the permanent magnets [RF Patent 2092444, cl. C02F 1/48, publ. 10/10/1997].

 The disadvantage of this device is also the low intensity gradients of the magnetic field acting on the liquid, especially in the region of maximum intensities, due to the use of adjacent permanent magnets in the magnetic system with parallel directions of magnetization, and the small length of the working volume due to the short length of the magnetic system, which reduces the duration of the magnetic fluid handling. All this reduces the efficiency of the device.

 The objective of the present invention is to increase the gradient of the intensity of the magnetic field acting on the liquid and increase the duration of the magnetic effect on the liquid to increase the efficiency of the magnetizing device.

 The problem is solved in that in a device for magnetic processing of liquid, containing a magnetic system with main permanent magnets placed on both sides of the gap for fluid flow, facing pole surfaces to this gap, with directions of magnetization perpendicular to the direction of fluid flow and with closed common magnetic circuit external pole surfaces, while the magnets opposite to the gap have the same directions of magnetization, according to Retenu introduced additional permanent magnets with alternating parallel to the direction of fluid movement directions of magnetization polarity poles facing the gap main magnets coincide with the polarity of the adjacent magnets of additional poles, wherein the primary and secondary magnets are arranged by alternating the general magnetic core.

 Between the main and additional permanent magnets can be installed gaskets of non-magnetic material.

 Between additional permanent magnets and a common magnetic circuit, gaskets made of non-magnetic material can be installed.

 Additional magnets can be made composite of two separate magnets with the same directions of magnetization, and inserts of magnetically soft material are installed between these two separate parts of the composite magnets.

 The use of a magnetic system in the device in the form of a sequence of permanent magnets placed with a gap along the direction of fluid motion, facing the gap with their pole surfaces and having alternating magnetization directions and external pole surfaces closed by a common magnetic circuit, with permanent magnets placed between them having alternating parallel to the direction of movement fluids of the direction of magnetization, so that the polarity of the magnets facing the gap of the poles with magnetization directions that are perpendicular to the direction of fluid motion coincide with the polarity of the magnet poles adjacent to them with magnetization directions parallel to the direction of fluid motion, can significantly increase the magnetic flux density near magnet poles with different directions of magnetization facing each other, and obtain a magnetic field distribution such that fluxes rapidly decrease with distance from magnets with different poles facing each other directions of magnetization. This provides an increase in the intensity gradient of the magnetic field acting on the liquid, and the use of a sequence of permanent magnets installed along the direction of fluid movement increases the length of the volume in which the magnetic effect on the liquid is carried out, and, consequently, the duration of the magnetic effect on the liquid. An increase in the gradient of the magnetic field strength and an increase in the duration of the magnetic effect on the liquid increase the efficiency of the device.

The invention and possible embodiments of the proposed device are illustrated in figures 1-4, where
1 - main magnets
2 - additional magnets
3 - magnetic circuit
4, 5 - gaskets made of non-magnetic material
6 - composite additional magnets
7 - inserts of soft magnetic material
The letters "N" and "S" in these figures show the polarities of the polar surfaces of the permanent magnets.

 In FIG. 1 shows the proposed device for magnetizing a fluid, containing a magnetic system with permanent magnets, in which the sequence of magnetics located along the direction of fluid movement and separated by the gap of the main permanent magnets 1 with magnetization directions perpendicular to the fluid direction and alternating directions of magnetization faces the gap with each pole from the sides of this gap, and the outer pole surfaces of these magnets are closed by a common magnetic circuit 3. Between they have additional permanent magnets 2 with alternating magnetization directions parallel to the direction of fluid motion, so that the polarities of the magnet poles 1 facing the gap coincide with the polarities of the adjacent magnet poles 2. This arrangement of the permanent magnets 1 and 2 with different magnetization directions allows significantly increase the magnetic flux density near the opposite poles of these magnets facing each other and obtain such a distribution of the magnetic field at which the magnetic flux densities rapidly decrease with distance from the facing poles of magnets 1 and 2. This provides an increase in the gradient of the magnetic field strength, and the use of a sequence of permanent magnets installed along the direction of fluid motion increases the length of the volume in which the magnetic liquid, and consequently, an increase in the duration of the magnetic effect on the liquid. An increase in the gradient of the magnetic field strength and an increase in the duration of the magnetic effect on the liquid provide an increase in the efficiency of the magnetizing device.

 It is also possible to design a magnetic device in which gaskets made of non-magnetic material are installed between the main and additional permanent magnets, which ensures an increase in the length of regions with high magnetic fields near magnet poles facing each other with different directions of magnetization, and, consequently, an increase in the duration of magnetic exposure liquid, and improving the efficiency of the device.

 The foregoing is illustrated in figure 2, which shows the main permanent magnets 1 and placed between them additional permanent magnets. The main magnets 1 can be placed between the additional magnets 2. The pole surfaces of the main magnets facing the opposite side of the gap are closed by a common magnetic circuit 3. Between the main and additional permanent magnets 1 and 2, spacers 4 of non-magnetic material are installed. This provides an increase in the length of regions with high magnetic fields near the poles of magnets 1 and 2 facing each other, and, consequently, an increase in the duration of the magnetic effect on the liquid and an increase in the efficiency of the device.

 It is also possible to design a device in which gaskets made of non-magnetic material are installed between additional permanent magnets and a common magnetic circuit. It also provides obtaining the distributions of the magnetic field acting on the liquid with high gradients of the magnetic field strength near the facing poles of the permanent magnets with different directions of magnetization and high magnetic field strengths in these areas and, at the same time, provides a more efficient use of the volume of constant constants by reducing the shunt action of the magnetic circuit magnets with directions of magnetization parallel to the direction of fluid motion.

 The foregoing is illustrated in figure 3, which shows the main permanent magnets 1 and additional permanent magnets placed between them 2. The pole surfaces of the main magnets facing the opposite gap are closed by a common magnetic circuit 3. Between the additional permanent magnets 2 and the common magnetic circuit 3, spacers 5 are installed, made of non-magnetic material. The device can be made with gaskets 4 made of non-magnetic material installed between the permanent magnets 1 and 2, and also without gaskets 4. Installing non-magnetic gaskets 5 between the magnets 2 and the common magnetic core 3 reduces the shunting of the magnetic flux of the permanent magnets 2 with the common magnetic core 3 and therefore provides more efficient use of the volume of additional magnets 2. Moreover, as in the designs shown in Figs. 1, 2, the distributions of the magnetic A high intensity gradients near the facing poles of the permanent magnets 1 and 2 with different directions of magnetization and high magnetic field intensities in these areas and, therefore, provided and increase device efficiency.

 It is also possible to design a device in which additional permanent magnets are made composite of two separate magnets with the same directions of magnetization, and inserts of magnetically soft material are installed between these two separate parts of the composite magnets, which practically without reducing the intensity and gradient of the magnetic field acting on the liquid allows increase the length of the volume in which the magnetic effect on the liquid is carried out, and thereby increase the duration of the magnetic image fluid spills and increase device efficiency.

 The aforesaid is illustrated in Fig. 4, which shows the main permanent magnets 1 and additional permanent magnets 2. The pole surfaces of the main magnets facing the opposite gap are closed by a common magnetic core 3. The additional permanent magnets 2 are made up of two separate permanent magnets 6 with the same directions of magnetization and between these two separate parts of the composite magnets there are inserts 7 made of soft magnetic material, which practically without reducing tension and grad The intensity of the magnetic field acting on the liquid allows to increase the length of the volume in which the magnetic effect on the liquid is carried out, and thereby increase the duration of the magnetic treatment of the liquid and increase the efficiency of the device. Execution with additional magnets made up of two separate parts can also be performed with non-magnetic inserts 4 between magnets with different directions of magnetization and with non-magnetic inserts 5 between magnets with directions of magnetization parallel to the direction of fluid motion and a common magnetic circuit.

Claims (4)

 1. A device for magnetic processing of liquid, containing a magnetic system with main permanent magnets located on both sides of the gap for fluid flow, facing pole surfaces to this gap, with directions of magnetization perpendicular to the direction of fluid flow and with closed common magnetic circuit, external pole surfaces, in this case, the magnets opposite to the gap have the same directions of magnetization, characterized in that additional e permanent magnets with alternating directions of magnetization parallel to the direction of fluid motion, the polarities of the poles of the main magnets facing the gap coincide with the polarity of the adjoining poles of the additional magnets, while the main and additional magnets are arranged by alternating on the common magnetic circuit.  2. The device according to claim 1, characterized in that gaskets of non-magnetic material are installed between the main and additional permanent magnets.  3. The device according to paragraphs. 1 or 2, characterized in that between the additional permanent magnets and a common magnetic core gaskets made of non-magnetic material.  4. The device according to any one of paragraphs. 1-3, characterized in that the additional magnets are made composite of two separate magnets with the same directions of magnetization, and between these two separate parts of the composite magnets are inserted inserts of soft magnetic material.

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