RU2085507C1 - Apparatus for magnetic treatment of liquid - Google Patents

Abstract

FIELD: magnetic treatment of liquids. SUBSTANCE: in order to avoid deposits and reduce corrosion activity of produced liquid, on outer surface of ferromagnetic pipe T designed to transfer liquid stream, at least two pairs of constant annular magnets M are installed with gaps in each pair not exceeding width of annular magnet and at a distance between two pairs being no less than tripled width of annular magnets. Annular magnets are constructed of rectangular-cross-section rods, main surfaces of which are coupled with surface of pipe and face pipe axis with their analogous poles. Magnets are embraced with hermetic screen from outside. EFFECT: improved consumer's quality of liquid. 6 dwg, 1 tbl

Description

 The invention relates to the field of oil production, in particular to magnetic processing of oil to prevent deposits of asphalt-resin-paraffin substances (ASPV) on the surface of oilfield equipment, to reduce the corrosiveness of the liquid.

 The proposed device can also be used in the power industry, water supply, mineral processing, etc. to stimulate the chemical activity of the substances used.

A device is known for magnetic fluid processing, comprising two pairs of permanent magnets mounted on the outer surface of a ferromagnetic pipe parallel to the axis of the pipe, one pair of magnets consisting of flat magnets, the opposite poles of each of which are spaced in the axial direction of the pipe, and the second pair of magnets is installed between the magnets of the first the pairs and opposite poles of each magnet from this pair are spaced in a direction perpendicular to the axis of the pipe. In this case, the magnets are located under the contacting non-magnetic shunt plate-cover mounted parallel to the axis of the pipe [1]
Due to this arrangement of magnets and due to such orientation of their poles, the resulting magnetic flux after penetrating it through the wall of a ferromagnetic pipe of considerable thickness, at least 0.65 cm, retains the intensity for processing the liquid passing through the pipe.

 The disadvantage of this known device is the low efficiency of the liquid treatment. This is due to: 1) the uneven distribution of the magnetic field in the cross section of the pipe, and, consequently, in the flow of fluid flowing through the pipe; 2) a small length of the magnetic field along the pipe (increasing the length of the magnetic plates to increase the length of the magnetic field in the known device will lead to a decrease in the field gradient); 3) the absence of a magnetic screen, which leads to the dispersion of a significant fraction of the magnetic flux and reduces the intensity of the field magnetizing the liquid.

Closest to the proposed technical solution, the technical essence is a device for magnetic fluid treatment, containing a ferromagnetic pipe, permanent magnets mounted on the outer surface of the ferromagnetic pipe, made in the form of rings, in which the main surfaces with the same poles face the pipe axis. Magnets are covered externally by a screen made of ferromagnetic material, hermetically fixed by end sections on the pipe [2]
Due to the fact that the permanent magnets face the same poles to the pipe axis, an axial magnetic field is created in the tube cavity. The fluid flowing through the pipe is processed by this magnetic field of a given tension.

 The disadvantage of this device is the lack of effectiveness of magnetic fluid processing. This is because when using single ring magnets in the known device, the generated magnetic field of each ring magnet is distributed into two parts with the opposite direction of the lines of force, that is, the magnetic field strength of each ring is halved. In this case, the axial field of each such ring is characterized by diffuse boundaries, which indicates the low intensity gradients of these fields. All this reduces the effectiveness of the magnetic treatment of liquids with a known device.

 The aim of the present invention is to increase the efficiency of magnetic processing of a fluid flow by increasing the strength and gradients of the axial magnetic field at the site of its influence on the fluid flow.

 This goal is achieved by the fact that in the known device for magnetic processing of liquid containing a ferromagnetic pipe and mounted on its outer surface, permanent ring magnets enclosed in a hermetically sealed ferromagnetic screen and installed so that their main surfaces with the same poles face the pipe axis, new is that permanent ring magnets are mounted on a ferromagnetic pipe in pairs by at least two pairs and are located in each pair with a gap between them of no more than the width of the ring about a magnet, these pairs of magnets are mounted relative to each other along the length of the pipe at a distance of not less than three times the width of one ring magnet, each ring magnet made up of adjoining non-working end surfaces of magnetic rods or plates of rectangular cross section, and the main surfaces of the magnets are conjugated with the outer surface of the pipe.

 Due to the fact that each ring magnet is made up of adjoining non-working end surfaces of magnetic rods or rectangular plates, and also due to the fact that the main surfaces of permanent magnets with the same poles are connected to the outer surface of the ferromagnetic pipe, all magnetic field lines in such device directed to the axis of the pipe, creating a radial magnetic field of high intensity, sufficient for penetration through the wall of the ferromagnetic pipe significantly th thickness, about 6 mm. As a result of the interaction of a high-energy radial magnetic field with a ferromagnetic pipe, a complex magnetic field arises inside this pipe, in which axial components dominate, directed from the middle of the ring magnet to its edges. In this case, the maxima of the axial magnetic field strengths are at the level of each edge of the ring magnet and have the opposite direction.

 It has been established that a change in the mutual arrangement of permanent ring magnets along a ferromagnetic pipe significantly affects the value of efficiency and its stability when processing liquids with different properties, therefore, we proposed to install permanent ring magnets in pairs at least two pairs at a certain distance from each other in each pair, as well as at a certain distance and between adjacent pairs, in contrast to the implementation in a known prototype device of a magnetic system in the form of a single s, for example three ring magnets. This is due to a significant change in the nature of the axial magnetic field created by single ring magnets. Physically, the essence of the observed effects is explained by comparing the results of recording the magnetic field along a ferromagnetic pipe from a single and double ring magnets. A single ring magnet is characterized by a smooth transition between the maxima of the magnetic field strength. In the case of a pair of ring magnets, when they approach each other, the interaction of adjacent, oppositely directed axial components of the magnetic field of each ring magnet increases. Due to this, the movement and concentration of the entire magnetic flux of each ring magnet takes place and its localization in the region of the outer edge of the corresponding magnet in the pair. This leads to the formation of two local antinodes of the axial magnetic field strength inside the pipe spaced along the ferromagnetic pipe. The amplitude of the tension in such antinodes is almost twice as high as that of single ring magnets. In this case, the adjacent boundaries of the antinodes are described by a sharper decrease in the field strength, i.e., an increase in their gradients. And, as it turned out, the described parameters and the shape of the local magnetic fields are formed only when the permanent ring magnets are installed in each pair with a gap not exceeding the width of one ring magnet. In this case, the optimum efficiency of the magnetic processing of liquids is ensured provided that the distance between any two adjacent pairs of magnets is not less than three times the width of one annular permanent magnet. At such a distance, on the one hand, the amplitude of the field strength between adjacent antinodes of each pair of ring magnets is retained (i.e., does not decrease), and on the other hand, this distance is already sufficient for the growth of field gradients in these antinodes.

 The upper limit of the distance between the pairs of magnets, as well as the number of pairs of magnets are determined by the properties of the processed fluid. For some liquids, such as water, this distance increases significantly, apparently due to an increase in the contact of the liquid with the magnetic field.

 A screen covering permanent magnets and acting as a magnetic flux concentrator also contributes to a significant increase in the axial magnetic field strength in each antinode.

 Thus, the goal set in the claimed device is achieved through the formation of a series of local alternating antinodes of the axial magnetic field, which are characterized by almost double the amplitude of the field strength in each antinode and increase the field gradients due to the additional concentration of the magnetic flux of each ring magnet in the pair and approach pairs of rings.

 Figure 1 presents the inventive device, a longitudinal section; figure 2 section along aa figure 1; figure 3 the nature of the strength of the axial magnetic field of the inventive device; 4 and 5, the nature of the change in the axial magnetic field strength of a single ring magnet (prototype) and installed in a pair of ring magnets (the claimed device), respectively; figure 6 - change in the efficiency of magnetic processing of the liquid depending on the distance between two pairs of ring magnets.

 A device for magnetic processing of liquid contains a ferromagnetic pipe 1, designed to transport the flow of the processed fluid, and permanent ring magnets 2, 3 and 4, 5 mounted on the outer surface of the pipe 1 in pairs, at least two pairs (figure 1). Permanent ring magnets in each pair of 2,3 and 4,5 are installed at a distance l from each other, not exceeding the width of one ring magnet a, that is, l≅a, while these pairs of ring magnets 2,3 and 4,5 are located relative to each other along the length of the pipe 1 at a distance L, not less than three times the width of the annular magnet, that is, L ≥ 3a. Each ring magnet is made up of rectangular cross-sectional non-working end surfaces of magnetic rods 6 (or plates) and is mounted on the outer surface of the ferromagnetic pipe 1 so that the main surfaces of each magnetic rod 6 are associated with the surface of the pipe 1 and face the axis of the pipe 1 like poles.

 Permanent magnets 2,3 and 4,5 are covered by a ferromagnetic screen 7, mounted tightly on the pipe 1 with the help of flanges 8.

 The device operates as follows.

 For magnetic processing of liquids, such as oil, the inventive device is mounted in a pipeline. When oil passes through a ferromagnetic pipe 1, oil is treated with axial magnetic fields directed along and towards the fluid flow, as a result of which it is activated to prevent deposits of ASWA on the surface of oilfield equipment.

 In laboratory conditions, the effectiveness of magnetic processing of a liquid, namely oil, was determined by the device proposed and known by the prototype. Recording of the magnetic field along the ferromagnetic pipe 1 from a single (Fig. 4) and double (Fig. 5) ring magnets showed that a single ring magnet is characterized by a smooth transition between the maxima of the magnetic field, and for a pair of ring magnets in the region of them external edges are formed antinodes of the axial magnetic field in which all the magnetic energy of the magnet is localized. The amplitude of the tension in such antinodes is almost twice as high as that of a single ring magnet. Moreover, in the inventive device, adjacent antinode boundaries are described by a sharper decrease in field strength, which indicates an increase in their gradients. Moreover, such a picture is observed only when the distance l between the magnets in the pair is no more than the width of one ring a. If l> a, then the character of the magnetic field strength in the pair changes, namely: four antinodes already appear, the amplitude amplitudes in which are lower. That is, for l> a, the character of the magnetic field becomes the same as for single ring magnets.

 From the dependence of the efficiency of magnetic processing of an oil liquid on the distance L between two pairs of ring magnets it follows, firstly, that the maximum efficiency of magnetic processing is observed only when the distance between two pairs is not less than three times the width of the ring magnet, that is, L≥3a (Fig. 6 ), where a 35 mm, l 10 mm; the optimal distance for efficient oil processing should be 3-5 times the width of the ring; secondly, the efficiency of magnetic processing of liquid is significantly higher than the average level of efficiency of the prototype (shown by a dotted line).

 The table shows the changes in the effectiveness of another type of liquid - water used for concrete preparation, estimated by the flexural strength of concrete, depending on the distance L / a between the pairs of ring magnets of the inventive device.

 The optimal distance between the pairs of ring magnets for effective processing, for example oil, should be 3-5 times greater than the width of the ring (Fig. 6). At the same time, the effective treatment of water used for concrete preparation occurs when the distance between the pairs of rings is 6.1 and 6.4 times the width of the ring (see table).

The main advantages of the claimed device include:
the ability to successfully use the device in harsh conditions of an oil well with high pressure (hundreds of atmospheres), an aggressive environment (saline solutions, hydrogen sulfide and other gases), limited dimensions (casing with a diameter of 120 mm);
the ability of the device to work in wells equipped with deep-well hose pumps;
comparative simplicity of design: as a ferromagnetic pipe, you can use directly a segment of the tubing (tubing). Due to this, the internal section of the tubing remains free and the claimed device does not interfere with both geophysical and preventive work, including the control of paraffin deposits in the well without stopping it.

 Along with this, the claimed device has all the advantages of permanent magnet magnetic devices, that is, there is no energy consumption during operation, environmental cleanliness and others.

Claims (1)

 A device for magnetic fluid treatment containing 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, characterized in that the permanent ring magnets are mounted on the ferromagnetic pipe in pairs, at least two pairs and located in each pair with a gap between them no more than the width of one ring magnet, a pair of magnets installed one from ositelno other along the tube length at least triple the width of the ring magnet, and each ring magnet is made composed of contiguous non-working end surfaces of magnetic rods or plates pryamogoulnogo section, and the main surface of the magnets are associated with the outer surface of the pipe.

Images