RU2192389C1 - Device for magnetic treatment of liquid - Google Patents

Abstract

FIELD: devices for magnetic treatment of liquids; prevention of formation of asphalt gum paraffin deposits in oil production equipment in the course of treatment of water pumped into wells in oil recovery; protection of water and heat supply systems against scaling; reduction of corrosion activity of water systems. SUBSTANCE: proposed device has body-pipe line made from magnetically soft material and magnetic system consisting of radially magnetized permanent magnets mounted along length of body at alternating directions of magnetization; it is provided with passage for liquid between outer surface of magnetic system and inner surface of body. Located between magnets are axially magnetized magnets with alternating directions of magnetization. Polarities of poles of radially magnetized magnets facing inner surface of body- pipe line coincide with polarities of poles of axially magnetized magnets directed to them. Outer diameter of radially magnetized magnets is lesser than outer diameter of axially magnetized magnets. Fitted between axially and radially magnetized magnets are inserts made from nonmagnetic material. Axially magnetized magnets and inserts are sectional in construction. EFFECT: enhanced efficiency of treatment due to increased amplitude and gradient of magnetic field intensity. 5 cl, 6 dwg

Description

 The invention relates to the field of devices for magnetic processing of liquids and can be used to prevent the formation of asphalt-tar and paraffin deposits in oilfield equipment and during the magnetic treatment 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 device is known for magnetic fluid processing, comprising a casing-pipe made of soft magnetic material and a magnetic system fixed on its axis, which is a sequence of permanent magnets installed along the pipe length with alternating directions of magnetization, while the permanent magnets have axial magnetization, and soft magnetic materials are placed between the permanent magnets pole tips. The flow of the fluid processed by the magnetic field flows through the gap of the annular section between the magnetic system and the pipe body [V. Klassen Magnetization of water systems. - M .: Publishing house "Chemistry", 1978, p. 115].

 Due to the fact that the total magnetic flux of permanent magnets in this device is distributed over the surfaces of the pole pieces of the magnetic system, the disadvantages of this device are the low amplitudes and gradients of the magnetic field along the outer surface of the magnetic system in the channel for the flowing fluid, which reduces the efficiency of magnetic processing liquids.

 The closest in technical essence to the proposed one is a device for magnetizing a liquid, comprising a casing-pipe made of soft magnetic material and a magnetic system fixed on its axis, which is a sequence of permanent magnets installed along the length of the casing-pipe, with alternating directions of magnetization, while the permanent magnets have a radial magnetization, placed on the magnetic circuit and equipped with pole tips, forming working gaps with the housing, and between at the permanent magnets are placed spacers of nonmagnetic material. The flow of the fluid processed by the magnetic field in this device also flows along the annular gap between the magnetic system and the pipe body. The outer surface of the magnetic system with non-magnetic spacers between the magnets and the pole pieces on the magnets has the shape of a cylinder [RF Patent 2119459, cl. CO2F 1/48, claimed 05/20/97, publ. 09/27/98 (Bull. 27)].

 Due to the fact that the total magnetic flux of permanent magnets in this device also turns out to be distributed over the surfaces of the pole pieces of the magnetic system, the disadvantages of this device are also insufficiently high amplitudes and gradients of the magnetic field along the external surface of the magnetic system in the channel for the flowing fluid, which reduces the effectiveness of magnetic processing of liquids. In addition, the use of pole pieces mounted on the outer cylindrical surface of the radially magnetized permanent magnets also leads to a decrease in the magnetic field strength in the gap for the flowing fluid due to an increase in the loss of magnetic energy due to scattering of the magnetic flux and to the irrational use of the volume of permanent magnets.

 The objective of the present invention is to increase the amplitude and gradient of the magnetic field acting on the liquid in order to increase the efficiency of magnetic processing of liquids.

 To solve this problem, in a device for magnetic fluid treatment, comprising a casing-pipe made of soft magnetic material and a magnetic system fixed on its axis, which is a sequence of radially magnetized permanent magnets installed along the casing-pipe length with alternating directions of magnetization, with a channel for flowing fluid between the outer surface of the magnetic system and the inner surface of the casing-pipe, according to the invention, axial of the magnetized magnets with alternating directions of magnetization arranged by alternating with radially magnetised magnets, the polarity facing the inner surface of the pipe body poles radially magnetized permanent magnets with the same polarities facing thereto poles axially magnetized permanent magnets.

 The outer diameter of the radially magnetized permanent magnets is less than the outer diameter of the axially magnetized permanent magnets.

 Between the axially and radially magnetized permanent magnets there are inserts of non-magnetic material.

 The axially magnetized permanent magnets are made of composite of two separate permanent magnets with the same directions of magnetization, and inserts of magnetically soft material are installed between these two separate parts of the components of the axially magnetized permanent magnets.

 Each insert of soft magnetic material is made of two separate parts connected by a movable joint, with the possibility of changing the axial length of each of the composite inserts.

 The use of a magnetic system in the device in the form of a sequence of permanent magnets installed along the length of the casing-pipe on its axis, with alternating directions of magnetization, made in such a way that radially magnetized permanent magnets with alternating directions of magnetization alternate with axially magnetized permanent magnets, also having alternating directions of magnetization, and the polarity of the radially magnetized poles facing the inner surface of the casing-pipeline of the magnets coincide with the polarities of the poles of the axially magnetized magnets facing them, it allows one to significantly increase the magnetic flux density near the polar surfaces facing each other of the axially and radially magnetized magnets and to obtain a magnetic field distribution in which the magnetic flux density rapidly decreases with distance from the facing to a friend of the polar surfaces of the axially and radially magnetized magnets. This allows you to significantly increase the amplitude and gradient of the magnetic field acting on the liquid in the annular gap between the outer surface of the magnetic system and the inner surface of the pipe body through which the fluid flows, and thereby increase the efficiency of magnetic processing of the fluid.

 The invention and possible embodiments of the device are illustrated by figures 1-6, in which 1 is a casing-pipe made of soft magnetic material with a magnetic system fixed on its axis, which is a sequence of radially magnetized permanent magnets 2 installed along the axis of the casing-pipe 1 with alternating directions of magnetization. Axially magnetized permanent magnets 3 with alternating directions of magnetization alternate with radially magnetized permanent magnets 2. The letters "N" and "S" denote the polarities of the magnetic poles of the magnets. The polarities of the poles of the radially magnetized magnets 2 facing the inner surface of the pipeline body coincide with the polarities of the poles of the axially magnetized magnets facing them 3. The magnetic system can be mounted on the axis of the pipe-housing 1, for example, using the diagrams shown in FIGS. 1, 3, 4, 5 of a non-magnetic shaft 4 with non-magnetic washers 5 fixed at its ends, provided with holes 6 for passing the fluid to be treated, or using the non-magnetic pipe 7 shown in FIG. 2, at the ends of which it is fixed These are non-magnetic washers 5, also equipped with holes 6 for the passage of the treated fluid. The working channel for the flowing fluid in all versions, as well as in the analogue and prototype, is the gap of the annular section between the outer surface of the magnetic system and the inner surface of the soft magnetic casing-pipe.

 As shown in FIG. 1, 2 embodiments, the magnetic system of the device includes only a sequence of radially magnetized magnets 2 installed along the length of the casing-pipe 1 with alternating directions of magnetization, with which axially magnetized magnets 3 alternate with alternating directions of magnetization, and the polarity facing the inner surface of the housing the pipeline 1 of the poles of the radially magnetized magnets 2 coincide with the polarity of the poles of the axially magnetized magnets 3 facing them. the magnitude of the amplitude and gradient of the magnetic field acting on the liquid with such a mutual arrangement of axially and radially magnetized magnets is ensured by a significant increase in the density of magnetic lines of force on the surface of the magnetic system near the polar surfaces of magnets 2, 3 with radial and axial magnetization facing each other, and a rapid decrease of this density of magnetic field lines with distance from regions near the polar surfaces of the magnets facing each other 2, 3 with radial and axial magnetization. Due to this, the amplitude and gradient of the magnetic field strength on the surface of the magnetic system in the channel for the flowing fluid increase, and the efficiency of magnetic processing of the fluid increases.

 It is also possible to perform the proposed device for magnetic fluid treatment, in which the outer diameter of the radially magnetized permanent magnets is less than the outer diameter of the axially magnetized permanent magnets. In this case, sleeves of non-magnetic material can be placed on the outer surface of the radially magnetized magnets. And this embodiment of the device’s magnetic system in comparison with the analogue and prototype allows to obtain a significant increase in the density of magnetic lines of force on its surface near areas with facing each other surfaces of magnets with axial and radial magnetization and a rapid decrease in the density of magnetic lines of force with distance from these areas due to which the amplitude and gradient of the magnetic field on the surface of the magnetic system increase and the efficiency of the device for tnoj processing liquid. A significant advantage of this design, in particular with the use of bushings made of non-magnetic material placed on the outer surface of the radially magnetized magnets, is the possibility of using components assembled from individual sectors or from elements of another form of radially magnetized magnets using the most modern magnetically hard materials with rare-earth metals, which allows you to further increase the amplitude and gradient of the magnetic field acting on the liquid and m most improve the efficiency of the device for magnetic fluid processing.

 The foregoing is illustrated by the figure of FIG. 3, which shows such a design of a magnetic system in which the outer diameter of the radially magnetized magnets 2 is less than the outer diameter of the axially magnetized magnets 3, and on the outer surface of the radially magnetized magnets 2 can be placed bushings 8 of non-magnetic material. A significant increase in the density of magnetic field lines on the outer surface of the device’s magnetic system is also observed here near regions with magnet surfaces 2, 3 facing each other with radial and axial magnetization, as well as a rapid decrease in the density of magnetic field lines with distance from these areas. This provides an increase in the amplitude and gradient of the magnetic field on the outer surface of the magnetic system, in the channel for the flowing fluid, and increase the efficiency of the device. The use of bushings 8 made of non-magnetic material enables the use of components assembled from individual sectors or from elements of another form of radially magnetized magnets using the most modern magnetically hard materials with rare-earth metals, which can even more significantly increase the amplitude and gradient of the magnetic field acting on the liquid and to further improve the efficiency of the magnetic fluid processing device. The fastening of the magnetic system on the axis of the casing-pipeline 1 can be performed both according to the scheme of FIG. 3 using a non-magnetic shaft 4 with non-magnetic washers 5 fixed on it at the ends of the magnetic system with holes 6 for passage of the processed fluid, and according to the scheme of FIG. 2 by means of a thin-walled non-magnetic pipe 7 with non-magnetic washers 5 fixed therein at the ends of the magnetic system and having openings 6 for the passage of the liquid to be treated.

 It is also possible to implement the proposed device for magnetic fluid treatment, in the magnetic system of which, between the axially and radially magnetized permanent magnets, inserts of non-magnetic material are placed, which makes it possible to increase the axial length of areas with high magnetic field strength near the poles axially and radially without decreasing the amplitude of the magnetic field strength magnetized permanent magnets and thereby increase the axial length of the space in which the magnets the effect on the liquid, and increase the duration of the magnetic treatment of the liquid, which helps to increase the efficiency of the device.

 This is illustrated by the figure 4 of the device for magnetic processing of liquid, the design of the magnetic system of which differs from the design of the magnetic system shown in figures 1, 2 devices by the presence of non-magnetic inserts 9 between the radially and axially magnetized magnets 2 and 3. Radially magnetized magnets and in this case can also have an outer diameter smaller than the outer diameter of the axially magnetized magnets, and on the outer diameter of the radially magnetized magnets can be placed, as shown in figure 3, the sleeve 8 of it magnetic material. The introduction of non-magnetic inserts 9 between the axially and radially magnetized magnets increases the length of the regions with high magnetic fields near the poles of the axially and radially magnetized magnets facing each other, increases the length of the channel with the magnetic field acting on the liquid, and thereby increases the duration of the magnetic treatment of the liquid, which contributes to increase device efficiency.

 It is also possible to implement a device in the magnetic system of which the axially magnetized permanent magnets are made up of two separate permanent magnets with the same directions of magnetization, and inserts of magnetically soft material are installed between these separate parts of the components of the axially magnetized permanent magnets. This allows, without practically decreasing the amplitude of the magnetic field strength, to increase the length of regions with high magnetic field strengths and thereby increase the length of the channel with a magnetic field acting on the liquid and increase the duration of the magnetic treatment of the liquid, which improves the efficiency of the device.

 The aforesaid is illustrated by the figure of FIG. 5, which shows an embodiment of the device in which the axially magnetized magnets 3 are made up of two separate magnets with the same directions of magnetization, and inserts 10 of soft magnetic material are installed between these separate parts of the axially magnetized magnets 2. In this case, radially magnetized magnets can have both the same external diameter with axially magnetized magnets and an external diameter smaller than the external diameter of the annular axially magnetized magnets. In the latter case, bushings 8 of non-magnetic material can be mounted on the outer diameter of the radially magnetized magnets. The fastening of such a magnetic system on the axis of the casing-pipe 1 can be carried out both according to the scheme of FIG. 5, using a non-magnetic shaft 4 with non-magnetic washers 5 fixed on it at the ends of the magnetic system, having openings 6 for the passage of the processed fluid, and according to the scheme of FIG. 2, using a thin-walled non-magnetic pipe 7 with non-magnetic washers 5 fixed on it at the ends of the magnetic system, having openings 6 for the passage of the processed fluid. The introduction of composite axially magnetized magnets from two separate magnets with the same directions of magnetization and magnetically soft inserts between these parts of the composite magnets into the design practically without decreasing the amplitude of the magnetic field increases the axial length of the channel with the magnetic field acting on the liquid, which increases the duration of the magnetic treatment of the liquid, which improves the efficiency of the device.

 It is also possible to design a device with composite axially magnetized permanent magnets from two separate permanent magnets with the same directions of magnetization and inserts of magnetically soft material installed between these separate parts of the composite magnets, in which the inserts are also made composite of two separate parts connected by a movable connection with the possibility of changing axial length of each of these composite inserts. This allows you to adjust the length of the channel with a magnetic field acting on the liquid and the distribution of the magnetic field in this channel, with the choice of the optimal mode of magnetic processing of the liquid, which also helps to increase the efficiency of the device.

 The foregoing is illustrated by the figure 6, which shows an embodiment of composite, axially magnetized magnets 3 of two separate parts with the same directions of magnetization, with inserts of magnetically soft material installed between these separate parts of the composite magnets, which are also made of two separate connected by a movable , for example, threaded, the connection of parts 11, 12, which allows changes in the axial length of each of these composite inserts and thereby adjusting the length of the channel with a magnetic field acting on the liquid and the distribution of the magnetic field in this volume with the choice of the optimal mode of magnetic processing of the liquid. At the same time, both the amplitudes and the gradient of the intensity of the magnetic field acting on the liquid are ensured, which ensures the selection of the optimal mode of magnetic processing of the liquid and helps to increase the efficiency of the device.

Claims (5)

 1. A device for magnetic processing of liquid, comprising a casing-pipe of soft magnetic material and a magnetic system fixed on its axis, which is a sequence of radially magnetized permanent magnets mounted along the pipe length with alternating directions of magnetization with the channel for the flowing fluid between the outer surface of the magnetic system and the inner the surface of the casing-pipeline, characterized in that axially magnetized magnets with alternating directions are introduced into it magnetization, placed by alternating with radially magnetized magnets, while the polarities of the poles of the radially magnetized permanent magnets facing the inner surface of the pipeline body coincide with the polarities of the poles of the axially magnetized permanent magnets facing them.  2. The device according to claim 1, characterized in that the outer diameter of the radially magnetized permanent magnets is less than the outer diameter of the axially magnetized permanent magnets.  3. The device according to p. 1 or 2, characterized in that between the axially and radially magnetized permanent magnets installed inserts of non-magnetic material.  4. The device according to any one of paragraphs. 1-3, characterized in that the axially magnetized permanent magnets are made of composite of two separate permanent magnets with the same directions of magnetization, and inserts of magnetically soft material are installed between these two separate parts of the components of the axially magnetized permanent magnets.  5. The device according to p. 4, characterized in that each insert of soft magnetic material is made up of two separate parts connected by a movable connection with the possibility of changing the axial length of each of the composite inserts.

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