SU1130537A1 - Apparatus for treating water in magnetic field - Google Patents

Abstract

1. A DEVICE FOR WATER TREATMENT IN A MAGNETIC FIELD, containing a cylindrical body and magnetic elements located inside it on a diamagnetic rod, insulated from one another with sleeves of diamagnetic material, so that the performance and quality of fluid processing by more efficiently placing the magnetic elements and using the planes of their magnetic poles; the device is equipped with a non-magnetic rod with magnetically conducting nozzles on which rods with i magnesium are fixed GOVERNMENTAL elements napravleinmi unlike poles to each other (mu A DO:. l 00 -vj

Description

about t l and - 60-90 one relative to another, and

2, The device according to claim.

what. on each bit, the nozzle rods are located at an angle

1130537

each subsequent packing with rods is offset from the previous one.

The invention relates to a device for treating water in a magnetic field during its preparation for the aeration of oil reservoirs, in technological processes of sewage treatment and in heat and power engineering in combating scale deposits. A device for magnetic treatment of a fluid is known, which comprises a housing with a magnetic nozzle consisting of ferrobarium washers arranged in a checkerboard pattern, equipped with cassettes of diamagnetic material in which the nozzle is placed. Ferrobarium washers are made with an orifice diameter of 0.3-0.5 outer diameter and are laid closely in the form of columns, with the cassettes mounted one after another at a distance. Dp processing aggressive environments washers and body are made with protective coating L. However, this design is not designed to handle liquids at high pressures, i.e. cannot be used in the oil production industry, where all water treatment processes are carried out at high pressures of 70-150x10 Pa, and the working plane of the magnetic poles in the resultant of dense arrangement (close to the ferrobarium washers) is not effectively used. water at high pressures, containing three magnetic elements directed by the same poles to one another insulated non-conducting sleeves and located coaxially on the diamagnetic rod, fastened with the help of centralization rods B to the casing-tube and through a flange connection of a high pressure conduit installed in a high pressure 2. A disadvantage of the known installation is that high-quality processing does not ensure the water flow in the magnetic field due to the large air gap between the lateral surface of the magnetic elements and the casing-tube, and the main pole surfaces of the magnetic elements are insulated and located at a great distance. Moreover, when changing the salt composition of water, it is not possible to change the magnitude of the magnetic field strength in the installation design. The aim of the invention is to improve the performance and quality of fluid processing by more efficiently placing the magnetic elements and using the planes of their magnetic poles. The goal is achieved by the fact that a device for treating water in a magnetic field, containing a cylindrical body and magnetic elements located inside it on a diamagnetic rod, isolated from one another by sleeves of diamagnetic material, is equipped with a nonmagnetic rod with magnetic conductors, on which rods with magnetic elements directed opposite poles one to the other: th. Moreover, on each nozzle, the rods are located at an angle of 60-90 one relative to the other, and each subsequent nozzle with the stem is shifted relative to the previous one. FIG. 1 shows the proposed device, the cut; in fig. 2 is a section A-A in FIG. I; in fig. 3 shows the configuration of the magnetic field lines in a pushed device. The device contains a magnetically conductive housing-casing with a flange 1, in which a diamagnetic rod 2 is mounted with magnetically conductive nozzles 3 fixed on it. On the nozzles, diamagnetic rods 4 are fastened by means of a threaded connection, on which opposite poles magnetic elements 5 are placed. The lifetime of the surface of the magnetic elements is protected by a polymer coating. The distance between the magnetic elements O is established and fixed by the diamagnetic sleeves (tubes). 6 The rods 4 with magnetic elements 5 are replicated on the nozzle 3 at an angle of 6 60-90 to each other depending on the number of magnetic elements and the diameter of the outer casing-pipe 1. The relationship between the angle, the number of elements, the rods and the casing diameter is given in table-. The second and third designs are most effective, since they are optimal in terms of casing diameter and the number of magnetic elements. The harnesses 3 with rods 4 are located on the diamagnetic rod so that the distance between the magnetic elements of the previous nozzle and the next does not exceed 10-20 mm, with the rods with magnetic elements of each subsequent nozzle offset from the previous one. Such an arrangement of rods with elements makes it possible to create local inhomogeneous magnetic fields in the entire volume of the casing and effectively use not only the plane of the poles, but also the lateral surface of the magnetic elements. The distance between the magnetic elements from the nozzle to the nozzle is set differently between the magnetic elements of the sleeves 6 of various lengths, and the nozzles are fixed on the diamagnetic rod with the screw 7 at a distance that ensures the closure of the magnetic field lines between the side surfaces of the magnetic elements. Thus, local magnetic fields are created with different magnitudes of magnetic induction, necessary and sufficient to ensure the efficiency and quality of water treatment with variable chemical, composition-. The device works as follows. The fluid flowing through the magnetic elements is exposed to the magnetic field created by the magnetic elements 5 located on the same stem, on the same nozzle and between the elements of the adjacent nozzles. The magnetic field lines all along the path of the fluid flow are directed normally to the fluid flow and are closed on the magnetic conductive nozzle 3, between the planes of adjacent elements 5 located on one rod 4, on the magnetically conductive casing 1 and between the side surfaces of the adjacent magnetic elements fixed on one nozzle and on the next. The created configuration of the magnetic field allows to increase the multiplicity of the intersection of the magnetic field by the flow of the magnetic field while the water stays in the magnetic field and to provide high-quality water treatment by increasing the total magnetic surface. The proposed design of the device allows a more complete and efficient use of the pole planes of magnetic elements due to an increase in the total conductivity-air gap and to ensure the efficiency of treating water of varying chemical composition due to the presence of local magnetic fields with various magnetic induction values Installing the device in the high-pressure line at the discharge port wells will enable, to ensure and maintain the effectiveness of water treatment in a magnetic different times of the year.

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Claims (2)

1. DEVICE FOR WATER TREATMENT IN A MAGNETIC FIELD, comprising a cylindrical body and magnetic elements located inside it on a diamagnetic rod; insulated from each other by sleeves made of diamagnetic material, which is related to the fact that, in order to increase the productivity and quality of liquid processing by more efficient placement of magnetic elements and using the planes of their magnetic poles, the device is equipped with a non-magnetic rod with magnetic conductive nozzles on which rods are mounted with magnetic elements directed by opposite poles to one another. .. ΦκλΙ 2. The device according to π. 1, about aphids - 60-90 * one relative to the other, and which means that, on each subsequent nozzle with the nozzle rods, the rods are angled relative to the previous one.