RU16660U1 - APPARATUS FOR MAGNETIC TREATMENT OF LIQUIDS AND (OR) GASES (OPTIONS) - Google Patents

Abstract

1. Apparatus for the magnetic treatment of liquids and (or) gases, comprising a housing in the form of a pipe made of ferromagnetic material and a magnetic assembly in the form of a hollow cylinder of non-ferromagnetic material with rectangular permanent magnets fixed in its walls along the axis and parallel to each other, characterized in that it contains one magnetic assembly, which contains an even number of magnets mounted symmetrically about the axis of the apparatus, magnetized in the radial direction and so that their location around the perimeter of the pole assembly is black eat; the magnetic assembly is installed without a gap inside the apparatus body, the assembly magnets are also adjacent directly or through pole lugs to the apparatus body without a gap, the inner diameter of the assembly is equal to, less than or greater than the inner diameter of the inlet and outlet pipelines; the radial and tangential sizes of the magnets exceed the minimum distance between adjacent assembly magnets. 2. The apparatus according to claim 1, characterized in that a section of the pipeline is used as the body if it is made of ferromagnetic material. Apparatus for magnetic processing of liquids and (or) gases, comprising a body in the form of a pipe made of ferromagnetic material and a magnetic assembly in the form of a hollow cylinder of non-ferromagnetic material with rectangular permanent magnets fixed in its walls along the axis and parallel to each other, characterized in that it contains one magnetic assembly, which contains an even number of magnets mounted symmetrically with respect to the axis of the apparatus, magnetized in the radial direction and so that their location along the perimeter �

Description

APPARATUS FOR MAGNETIC PROCESSING OF LIQUIDS AND (OR) EYES

The proposed apparatus is sent to devices for processing a field of permanent magnets of any liquids or basins pumped through pipelines. Different versions of the apparatus can be built into pipelines of different throughputs and provide the required magnetization modes. In particular, they can be installed at any depth in the string of pumping and compressor-pipes (tubing) of wells and in pipelines of ground-based systems for supporting reservoir pressure, oil collection and transportation, in gas pipelines of burners of boilers for various purposes, and any other pipelines.

A device is known for magnetic processing of gaseous and liquid media 1. containing KopiTyc, an inlet and an outlet nozzle, and a magnetic system with singular rectangular magnets connected to each other by unlike poles, covered by a composite two-slotted map-wire conductor. Common to this known device with the first two variants of the claimed is the presence of a housing and a magnetic system with permanent rectangular magnets. A disadvantage of the known device i} is angered by the low efficiency of magnetic processing due to the absence of reversals (changes in the opposite direction) of the resulting magnetic flux.

It is known 2 that the processing efficiency is higher in polypoyarny (with a multiple change in the direction of the magnetic flux) devices, is proportional to the induction in the gap between the poles of the magnets through which the processed medium flows, the speed of its flow, the time of exposure of the map field and the intensity of reapplication (turbulization) of the current Wednesday.

There are 3 known anti-boiling devices containing a housing in the form of a pipe made of ferromagnetic material, a magnetic system in the form of a hollow cylinder of diamagnetic material with rectangular magnets fixed in its walls and parallel to each other with rectangular magnets and nerfed input and output pipes. This device, according to a number of signs (case, magnetic system), is closest to the first two proposed variants of the device. However, this device is not polypolar and, therefore, not effective enough.

Known 5 apparatus for magnetic treatment of water, containing a magnetic system and a housing with a central streamlined body, the annular gap between which is divided into a number of external channels using a pair of screw channels mounted augmented in pairs with the help of installed pairwise screw partitions, which also have pairs

IPC: O2R1 / 48

(OPTIONS)

the streamlined shape of magantE has been established, with pairs shifting along the length and height of the partitions. This apparatus is palichrpo streamlined body and the nature of the installation of magnets most blink to the two second warp of the claimed device. The main disadvantage of this known device is the complexity and non-technological design, as well as lack of effectiveness.

It has been experimentally established that for various liquids and gases, for different contents of impurities (espl is the question of their deposition), as well as for various purposes of magnetic treatment, in particular, to prevent the deposition of paraffin in tubing, to reduce the CO content in emissions combustion of gas, various inductions of the magnetic field that crosses the current medium, flow rates, processing durations, number of changes in the direction of the magnetic flux (magnetic flux reversals) and re-intensities (t rbulizatsii) stream.

I, the proposed apparatus makes it possible to provide, in any way or another, a certain mode of magnetic processing of any medium pumped through the pipeline. To do this, depending on its type, more comprehensive magnetization and throughput of the pipeline, various machine options can be applied, containing a ferromagnetic corne which is a non-magnetic circuit with a magnetized device consisting of one or several consecutively installed unified magnetic assemblies with permanent magnets.

The assembly is installed in the housing without a gap w and a gap., And a ferromagnetic streamlined body can also be installed with a gap on its axis. This ensures that the note is divided into separate flows through gaps and channels in the assemblies, which are non-perpendicular to the magnetic field lines and moving with a speed that determines the time of magnetic processing and can differ from the flow rate in the pipeline.

Structurally, a section of the pipeline into which one or several assemblies are mounted sequentially can be used as the housing of the agparate. Figures 1a and 16 show, as an example, a magnetic assembly 1 with four 2-5 permanent magnets and a channel 6 in its corgus.

In FIG. 2, nocazapo is similar to FIG. 16 is a sectional view of an apparatus consisting of the same magnetic assembly and the housing 7 without a gap between them PI paths of magnetic flux between the poles of the magnets.

On FIG. 3 are shown similarly to FIG. 16 of the apparatus, consisting of the same magnetic assembly and the case, installed with a gap of 8 between them and the paths of the magnetic flows. Between the poles of the magnets.

Figure 11 shows a section of the apartment, similar to figure 2, with a streamlined body 9 on its axis and a channel 10 between the IHIM and the magnetic assembly and the paths of magical notes between the poles of the magnets.

Figure 5 shows a similar ph1H.3 cross section of the agitation with a streamlined body 9, 10 n 8 gaps between it and the assembly, and between the assembly and the housing 7 and the paths of the magnetic flux between the poles of the magnets.

The main unit of the apparatus is the magnetic assembly I, which is a hollow cylinder of non-ferromagnetic material, in the walls of which along its axis parallel to each other and symmetrically relative to the axis there is an even number of rectangular permanent magnets that are magnetized in the radial direction of the assembly so that they are spaced apart but its perimeter alternate.

Instead of a cylinder, an openwork design of non-ferromagnetic material can be used, which, in addition to holding magnets and a streamlined body, will serve as a flow turbulizer.

The assembly can be installed without a gap inside the apparatus body, while its magnets must also adjoin the apparatus body without a gap. For technological reasons, pole pieces can be installed between the magnets and the housing to ensure this. In large diameter pipelines, it is advisable to divide three flows into two or two. For this, the assembly is installed with a gap of 8 relative to the housing and (or) on its axis with a gap of 10, a streamlined teJU 9 nz of the ferromagnetic material is installed. The radial dimensions of the channels formed in this case determine the induction of the field in them and the velocity of the fluid.

The magnitude of the magnets in the assembly for the purpose of concentrating the magnetic flux in the channels is determined by their radial, tangential and axial dimensions, which are chosen so that the distances between the opposite poles of one magnet, the neighboring magnets in the assembly and the magnets of the previous assembly in the apparatus exceed the sum of the radial dimensions of the gaps by magnetic flux paths between

In small diameter pipe ducts, in the absence of a streamlined body, the number of magnets in the assembly should be such that the opposite magnets are facing each other with unlike nolusamn (nannumber, 6 pieces).

The device may contain one, two or more assemblies installed in series. In this case, each noslyadnuyu assembly can be deployed relative to the previous one around the apparatus by an angle equal to or less than the angular distance between the symmetry axes of the magnets in the assembly. The set of sequentially installed

of assemblies is determined by the number of magnetic flux reversals, providing maximum magnetization efficiency and the time of magnetic processing, and is determined experimentally.

The assembly is installed in the housing 7, which is built into the pipeline, and I represent a piece of pipe made of ferromagnetic material having a diameter equal to or greater than the diameter of the pipeline.

If it is necessary to install the apparatus outside a pipeline made of non-ferromagnetic material, the housing and assembly can be made detachable. In this case, after installation on the pipeline, the halves of the magnetic pipe should be connected without a gap of I7P1 with a minimum gap.

Cornus makes the device structurally and functionally finished product, ensuring its installation and at the same time being a power supply pipe, it makes the path of the magnetic flux easy.

The device operates as follows. The liquid flowing through the channel 6 in the assembly or the channel and the gaps 8 n 10 is exposed to magnetic fluxes of permanent magnets directed across its flow, as shown in figure 2, .. 5. In this case, the exposure time is determined by the flow velocity and can be changed either by changing the channel dimensions and gaps, or by changing the axial dimensions of the wire or by installing several wires in series with each subsequent rotation around their common axis, which leads to a change in the level of magnetic note up to the opposite (to reverse ) in case of a turn of the subsequent assembly - in our issue - by 90 relative to the previous one.

The choice of installation option for assemblies in the apparatus body, their number, as well as the need and magnitude of the rotation angle around the common axis - since it is not currently possible to calculate the magnetization effect, they should be determined experimentally depending on the fluid and non-magnetization (denaraffin oil deposition of sludge. Strengthening the theraneutical properties of mineral water or biological CBOIICTB water for irrigation of fruit and vegetable crops, reducing the release into the atmosphere of products Ania and so-called)

1.A.S. USSR 1608134, class CO2F1 / 48.

2. Tebenikhin E.F. Non-reagent methods of water treatment in power plants: M., Energoatomizdat, 1985.

3. RF patent 2010010, class CO2F1 / 48.

4.A.S. USSR 1655911, clCO2P1 / 48.

5. RF patent 2053202, CO2F1 / 48.

LITERATURE

Claims (10)

1. Apparatus for the magnetic treatment of liquids and (or) gases, comprising a housing in the form of a pipe made of ferromagnetic material and a magnetic assembly in the form of a hollow cylinder of non-ferromagnetic material with rectangular permanent magnets fixed in its walls along the axis and parallel to each other, characterized in that it contains one magnetic assembly, which contains an even number of magnets mounted symmetrically about the axis of the apparatus, magnetized in the radial direction and so that their location around the perimeter of the pole assembly is black eat; the magnetic assembly is installed without a gap inside the apparatus body, the assembly magnets are also adjacent directly or through pole lugs to the apparatus body without a gap, the inner diameter of the assembly is equal to, less than or greater than the inner diameter of the inlet and outlet pipelines; the radial and tangential sizes of the magnets exceed the minimum distance between adjacent assembly magnets.  2. The apparatus according to claim 1, characterized in that as the body uses a section of the pipeline in case it is made of ferromagnetic material.  3. Apparatus for magnetic processing of liquids and (or) gases, comprising a housing in the form of a pipe made of ferromagnetic material and a magnetic assembly in the form of a hollow cylinder of non-ferromagnetic material with rectangular permanent magnets fixed in its walls along the axis and parallel to each other, characterized in that it contains one magnetic assembly, which contains an even number of magnets mounted symmetrically about the axis of the apparatus, magnetized in the radial direction and so that their location around the perimeter of the pole assembly is black eat; the magnetic assembly is installed with a gap inside the apparatus body, while the total cross-sectional area of the channels inside the assembly and between it and the apparatus body is equal to more or less than the cross-sectional area of the inlet and outlet pipelines; the radial size of each assembly magnet exceeds the sum of the radial dimensions of the gaps in the magnetic flux path between any of its poles and the opposite pole of the adjacent assembly magnet; the tangential size of each assembly magnet is such that the distance between it and any neighboring assembly magnet exceeds the same sum of the dimensions of the gaps.  4. The apparatus according to claim 3, characterized in that a section of the pipeline is used as the body if it is made of ferromagnetic material.  5. Apparatus for magnetic processing of liquids and (or) gases, comprising a body in the form of a pipe made of ferromagnetic material and a magnetic assembly in the form of a hollow cylinder of non-ferromagnetic material with rectangular permanent magnets fixed in its walls along the axis and parallel to each other, characterized in that it contains one magnetic assembly, which contains an even number of magnets mounted symmetrically about the axis of the apparatus, magnetized in the radial direction and so that their location along the perimeter of the pole assembly is black eat; the magnetic assembly is installed without a gap inside the apparatus body, the assembly magnets also adjoin directly or through pole lugs to the apparatus body without a gap, a cylindrical streamlined body made of ferromagnetic material is installed with a gap relative to the assembly, while the cross-sectional area of the gap is equal to, greater or less than the area cross-sections of the inlet and outlet pipelines, the radial size of each assembly magnet exceeds the sum of the radial dimensions of the gaps in the path of the magnetic flux between any Luce and neighboring opposite poles of the magnet assembly; the tangential size of each assembly magnet is such that the distance between it and any neighboring assembly magnet exceeds the same sum of the dimensions of the gaps.  6. The apparatus according to claim 5, characterized in that the pump shaft is used as a streamlined body.  7. The apparatus according to claim 5, characterized in that the section of the pipeline or the pump casing is used as the casing if they are made of ferromagnetic material.  8. Apparatus for magnetic processing of liquids and (or) gases, comprising a housing in the form of a pipe made of ferromagnetic material and a magnetic assembly in the form of a hollow cylinder of non-ferromagnetic material with rectangular permanent magnets fixed in its walls along the axis and parallel to each other, characterized in that it contains one magnetic assembly, which contains an even number of magnets mounted symmetrically about the axis of the apparatus, magnetized in the radial direction and so that their location around the perimeter of the pole assembly is black eat; the magnetic assembly is installed without a gap inside the apparatus body, the assembly magnets also adjoin directly or through pole lugs to the apparatus body without a gap, a cylindrical streamlined body made of ferromagnetic material is installed with a gap relative to the assembly, while the cross-sectional area of the gap is equal to, greater or less than the area sections of the inlet and outlet pipelines; the radial size of each assembly magnet exceeds the sum of the radial dimensions of the gaps in the magnetic flux path between any of its poles and the opposite pole of the adjacent assembly magnet; the tangential size of each assembly magnet is such that the distance between it and any neighboring assembly magnet exceeds the same sum of the dimensions of the gaps.  9. The apparatus of claim 8, characterized in that the pump shaft is used as a streamlined body. 10. The apparatus of claim 8, characterized in that as the body uses a portion of the pipeline or pump housing if they are made of ferromagnetic material.