RU2092446C1 - Apparatus for magnetically treating liquids - Google Patents

Abstract

FIELD: magnetic treatment of liquids. SUBSTANCE: apparatus is also applicable to treat loose and gaseous media as well as liquid solutions using magnetic field to alter process characteristics and physical properties of media, to desalt, activate, and clean them which may find use in heat-supply systems, chemical engineering, mineral dressing, oil production and oil processing industries, in building industry to treat cement mortars, in agriculture, and medicine. Apparatus consists of casing with cone-shaped connecting pipes attached to its ends and constant magnets disposed inside casing and facing with unlike poles each other. End surfaces of each pair of oppositely arranged magnets are in immediate proximity to each other and their opposite surfaces abut casing. Several such constant magnet sections may be installed along the longitudinal axis of casing. EFFECT: improved design of apparatus. 2 cl, 6 dwg

Description

 The invention relates to the field of processing liquid as well as granular and gaseous media and liquid solutions by magnetic fields to change their technical characteristics, physical properties, desalination, activation, change stiffness, purification and can be used in heat supply systems, chemical technology, mineral processing technology , in the oil and oil refining industries, in construction for the processing of solutions, in agriculture and medicine.

A device for magnetic water treatment, comprising a housing with inlet and outlet nozzles and located on its surface against each other flat pair magnets with opposite poles and the alternating direction of the magnetic field [1]
The disadvantages of this device are:
a low degree of processing of the material and a short duration of preservation of the magnetization effect due to the fact that the processed material on each pair of flat magnets is treated with a magnetic field of one direction, at the next pair of magnets it is magnetized in the opposite direction, and at the outlet of the device the liquid remains magnetized in its entire volume only in one polarity; the energy of the stored residual magnetic field of the liquid tends to scatter and deform the residual magnetic field due to the intrinsic internal forces of magnetic repulsion between the unidirectionally magnetized elements of the liquid volume (of different signs, the magnetization of the opposite surfaces of the liquid flow is almost completely compensated at the exit of the device);
the treatment of the liquid with the biologically active component of the scalar magnetic field is almost completely eliminated.

The closest in technical essence and the achieved result to the claimed device is a device for magnetic fluid treatment, consisting of a cylindrical body with lid-flanges and nozzles for input and output of the processed fluid, inside which solid partitions with an annular gap and partitions with a hole in the center are installed, moreover, between the partitions are placed flat permanent magnets with opposite poles [2]
The disadvantage of the prototype is:
low residual magnetization of the processed material and short duration of the conservation of the magnetization effect, since in the process of processing the media, the magnetic field alternates and self-scatters.

 The main technical task of the device is to increase the magnetization of the medium being processed by increasing the efficiency of using the magnetic field. Wheat seeds were treated with magnetized water obtained by the proposed method and the prototype method. The percentage of germination of wheat seeds processed by the proposed method is 40% higher than in the prototype. The experiments also showed a higher efficiency of the proposed method for removing scale, desalination of water.

 The problem is achieved in that in the proposed device for magnetic processing of liquid, including a housing for input and output of the processed liquid, which contains permanent magnets facing each other with opposite poles, according to the proposed solution, the end surfaces of each pair of opposing magnets are located close to each other , and their opposite surfaces are placed close to the body. In addition, along the body there are several sections of permanent magnets facing each other with opposite poles, and the sections are separated from each other by non-magnetic material.

 In FIG. 1, shows the design of the proposed device for magnetic fluid processing with one pair of flat magnets; figure 2 is the same side view; in FIG. 3 section AA in figure 1; figure 4 presents a variant of the device in which two pairs of magnets are placed; figure 5 is a variant of the device in which the magnets are made of half rings; in Fig.6 a variant of the device made according to claim 2 of the claims, i.e. a variant of the device in which several sections of permanent magnets, in particular flat ones, are installed along the housing.

 The device consists of a housing 1 with conical nozzles 2 attached to its ends and of permanent magnets 3 located inside the housing, which are opposite each other with opposite poles, the end surfaces of each pair of opposing magnets being located adjacent to each other, and their opposite surfaces being placed close to case. In front of the magnets 3 and after the magnets, fairings 4 are installed in the housing 1 to impart laminarity to the flow of the medium being treated.

 To enhance the magnetization effect in the housing, two pairs of magnets can be installed in one section, as shown in Fig. 4, or a pair of magnets made in the form of half rings (Fig. 5), and in this embodiment, the medium to be processed is passed through the inner pipe 5, made of non-magnetic material. Multiple enhancement of the processing effect is achieved by sequentially installing several sections of permanent magnets in case 1. In FIG. 6 shows such an option when using a pair of flat magnets. But it is possible to use other options for sections, including shown in FIG. 4 and 5. For multi-sectional execution of the proposed device between sections, an air gap or a partition of non-magnetic material is required.

 The operation of the device for magnetic fluid processing is as follows.

 The laminar fluid flow through the inlet conical pipe 2 of the housing 1 is completely divided into two flows by two flat magnets 3 fastened to each other and to the housing 1, the front and rear sides of which are equipped with fairings 4 to maintain the laminarity of the flow from one and the other side of the flat magnets. Opposite directional magnetic fields from one and the other working surface of the magnets are oriented so that after two separated fluid flows pass over the opposite working surfaces of the magnets 3 and the rear fairings 4 and their subsequent connection, the residual magnetization of one of the flows tends to short out on the magnetic flux of the other due to the acting between them are forces of magnetic attraction, which contributes to a dense concentration of magnetic energy of the magnetized fluid flow.

 In experimental microbiological studies on the influence of a magnetic field on the reproduction of Escherichia coli, it was revealed that the use of the device we proposed has an efficiency of 1-3 orders of magnitude higher than the apparatus for magnetic processing, made in accordance with the design of the prototype.

 In addition, the use of the device we proposed allowed us to obtain almost a 40% higher percentage of germination of wheat seeds in one week than when using water treated with the prototype device. Also, experiments were carried out to remove scale and desalination of water.

Claims (2)

 1. Device for magnetic processing of liquid, comprising a housing for input and output of the processed liquid, in which there are permanent magnets facing each other with opposite poles, characterized in that the end surfaces of each pair of opposing magnets are located adjacent to each other, and their opposite surfaces placed close to the body.  2. The device according to claim 1, characterized in that along the body there are several sections of permanent magnets facing one another with opposite poles, the sections being separated from one another by non-magnetic material.

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