RU66329U1 - MAGNETIC LIQUID TREATMENT DEVICE IN A PIPELINE - Google Patents

Abstract

This device is designed for the magnetic treatment of liquids in pipelines and devices for cold and hot water supply with a small volume of consumption: housing pipelines, household pipelines at industrial enterprises, etc. The technical result consists in simplicity of design and higher reliability, an increase in the duration of processing by a magnetic field is achieved. This result is achieved due to the fact that the device for magnetic processing of liquid in the pipeline containing a magnet, inlet and outlet pipes, a container inside which have at least 1 channel or channel forming element for passage of magnetizable water, characterized in that the magnet is located at the end and / or on the sides of the case or the case itself or the container with channels or channel-forming elements are made of a material that creates a magnetic field. The channel can be made zigzag. The plane of the zigzag channel can be set perpendicular to the axis of the pipeline. The plane of the zigzag channel can be set parallel to the axis of the pipeline. The channel may be made in the form of a spiral. The inlet channel of the tank can be divided into at least 2 streams, and contains a mixing zone, where from each of the separated streams of the channel, the liquid is mixed with the divided stream of the other channel.

Description

Application area

This device is designed for the magnetic treatment of liquids in pipelines and devices for cold and hot water supply with a small volume of consumption: housing pipelines, household pipelines at industrial enterprises, etc.

State of the art

Currently known and widely used devices designed to change the chemical properties of liquids using a magnetic field in order to reduce lime deposits on the walls of pipelines, containers for storage, processing or heat treatment of liquids. These devices basically have sections of pipes with permanent magnets or electromagnets installed on them or in them, with or without electric drives. Improving the quality of processing fluids is achieved by increasing the power of the magnets, the order of their arrangement, or by combining a change in the polarity of the sides of the magnets facing the fluid being processed.

In heating systems, calcareous deposits (scale) are the result of the natural content of calcium carbonate in water. In hard water, calcium has a solid, crystalline structure. Under the influence of polarized magnetic fields, the crystals are destroyed and converted into aragonite - a neutral substance with a powdery consistency, which dissolves and is excreted with a stream of water. The continuous action of the neutralizer prevents the re-formation of calcium crystals. The use of self-washing filters in heating systems allows you to periodically remove accumulated deposits.

Some chemical elements present in dishwasher and washing machine detergents can react with calcium and other alkali metals, reducing the anti-lime effect.

Various magnetic nozzles are widely known and used to trap lime in water. However, as a rule, they have direct contact with water and because of this they themselves serve as pollutants of water, if it is intended for drinking needs.

Therefore, although the direct contact of water with a magnet carries the effect of a positive effect on water, purifying it of calcium, it also carries the negative effect of water pollution by small particles from a magnet.

The patent RU 2053202 is known from the prior art for a WATER MAGNETIC PROCESSING APPARATUS, comprising a housing with a central streamlined body, a magnetic system, characterized in that the annular channel between the housing and the central body

divided into a series of screw channels with screw partitions installed in pairs, and permanent magnets are installed in the grooves of the partitions.

This invention is intended only for the treatment of wastewater from industrial enterprises. The disadvantage of this device is that the permanent magnets here are located directly in the water stream, as well as a decrease in the free space for the passage of liquid in the internal section due to the introduction of a massive foreign body into it.

The patent RU 2181699 is known from the prior art for a device for magnetic fluid processing, comprising a housing, an electromagnet, a tubular coil, characterized in that the housing is made in the form of a truncated cone of non-magnetic material and with a solenoid wound on its surface, while the tubular coil is made of non-magnetic material and is located inside the case in the form of a conical spiral. The novelty of this technical solution is due to the movement of the tube through which the fluid flows from the outside of the solenoid, where the magnetic field is dispersed, inside the solenoid, where the magnetic field is concentrated, and the magnetic field increases from the center of the solenoid to the periphery where the tube is in the form of a conical spiral, through which a magnetizable fluid flows.

The disadvantage of this invention is that it uses a conical spiral having a larger size than in the claimed device, which increases the dimensions of the device. Also, in this spiral, at each section of the fluid movement, the presence of bounding walls within which the fluid moves is necessary.

Another disadvantage of the invention is the use of an electromagnet, which eliminates the involvement of this device in places where there is no power supply.

The patent RU 2182121 is known from the prior art for an apparatus for magnetic treatment of water and various chemical media, comprising a non-magnetic housing, sections of magnetic elements located around the housing and an internal magnetic system, characterized in that each section is made of permanent magnets oriented by the same poles to the housing with alternating poles from section to section, and the internal magnetic system is made in the form of ferromagnetic disks placed in a non-magnetic pipe and permanent magnets facing each of disks of the same poles, while the poles of the disks and the sections opposite them are opposite.

This invention is intended only to prevent scale formation in heat exchange equipment and to accelerate chemical reactions. The disadvantage of this invention is the need for a strictly polar arrangement of magnets along the housing and the involvement of a large number of magnets mounted inside the housing.

The patent RU 2189948 is known from the prior art for a device for magnetic treatment of medicinal water with repulsive ring magnets, characterized in that the magnets are made of neodymium-boron alloy and are housed in a non-magnetic housing having an input fitting and longitudinal protrusions on which are centered

ring magnets, each ring magnet being coated on all sides with a 0.2-0.3 mm thick film of sprayed fluoroplastic or food epoxy resin, and a magnetic gap between the rings is formed without intermediate gaskets when the rings are pressed against the magnetic forces of repulsion using a flange cover, having an outlet fitting and segmental protrusions directed towards the magnets, and a brass gasket is installed between the cover and the upper ring magnet, which can block the through water outlet from the internal floor spacing of magnets, and the cover is screwed to the housing, in which an elastic gasket is installed, having the ability to ensure the tightness of the device.

The invention is used only in water treatment techniques, in particular for magnetic treatment of water for medicinal purposes.

The disadvantage of this invention is the location of the magnets inside the housing, as well as the short residence time of the processed fluid in the zone of influence of the magnetic field.

The patent RU 2136605 is known from the prior art for a device for magnetic fluid treatment, comprising a hermetic chamber with nozzles for supplying and discharging liquid, a rotor, a stator with an even number of poles and a half-wave rectifier with a zero point connected to the supply network by an input and a three-phase winding output stator, characterized in that it contains an amplifier, a comparison body and a dynamic pressure sensor, while the rectifier is made controllable, for example, on optocouplers, and the dynamic pressure sensor copulating in the center of the outlet pipe and is connected to the amplifier through the comparison body, and the amplifier output - to the control elements of the opto-thyristors.

The disadvantage of the invention is the need to use electromagnets, and the presence of another magnet inside the device, and the design of the device itself is difficult to manufacture.

The patent RU 2136606 is known from the prior art for an electromagnetic device for treating a fluid, comprising a rotor, a stator with a magnetic system located in its grooves, nozzles for draining and supplying the fluid to be treated, and a hermetic chamber located between the rotor and the stator, characterized in that it is equipped with a cathode group diodes, and the stator - an additional three-phase winding with an even number of poles, moreover, three-phase windings are connected on one side in the opposite direction and into a "star", and on the other hand through the anode and cathode groups of diodes - with a power network, and the rotor is covered with a non-magnetic spiral.

The disadvantage of the invention is the need to use electromagnets, and the presence of another magnet inside the device, and the design of the device is difficult to manufacture and requires the presence of a fixed stator and rotor.

The prior art also knows patents SI 21317, CN 1521128, JP 11309461, JP 2000093978, a common drawback of which is the presence of a magnet inside the device, as well as the associated significant increase in the dimensions of the device itself.

The closest analogue is patent RU2089512 for a device for magnetic water treatment, comprising a housing made of diamagnetic material, permanent magnets and a zigzag channel for passage of magnetized water located in the housing, characterized in that the channel is made in the form of a rectangular pipe, the side faces of which are formed by twenty pairs of samarium - cobalt permanent magnets shunted by a two-layer steel magnetic core.

In this device, water subjected to deep magnetization under pressure through the inlet pipe is passed through a spiral-shaped chamber, where its flow acquires the necessary turbulence, passing eight turns through 90 °. When water passes through the magnetization chamber, a constant magnetic field is applied to it, created by twenty pairs of samarium-cobalt magnets. The density of magnetic energy is 16-18 mm E / cm ³ and the average value of the magnetic field is 0.35-0.45 T. External magnetic fluxes from samarium-cobalt magnetic elements are closed by a two-layer magnetic core of sheet steel with a thickness of about 3 mm. Magnetized water exits through the outlet pipe.

The disadvantage of the prototype is the need to use many magnets. In the claimed invention, only one magnet. The disadvantage of the invention is the location of the magnets inside the housing, and the complexity of manufacturing the device itself.

The closest analogue is patent RU 2242433 for a device for magnetic treatment of liquid, mainly water, containing a pipe, on the outer surface of which there are permanent ring magnets, sealed by a screen, ferromagnetic rings are installed from the end of each ring magnet, characterized in that the screen and the pipe is made of non-magnetic material, ring magnets are installed in pairs with the same poles to each other, ferromagnetic rings are installed at both ends of the ring constant x magnets, forming pole pieces, moreover, the geometrical dimensions of the ring magnets and pole pieces are selected depending on the bore diameter of the non-magnetic pipe, inside of which an additional spiral-shaped body made of non-magnetic material is installed along the axis.

This invention is based on the well-known concept that the flow rate of a fluid inside a passage pipe can be different, and the effectiveness of magnetic processing of a fluid depends on it. The placement of a spiral-shaped body inside the pipe can drastically reduce the effect of speed on the efficiency of magnetic processing. This is because the shape of the spiral is chosen so as to obtain a twisting of the fluid flow at the inlet to the zone of the magnetic system at relatively low velocities of the flow at the inlet, so that it becomes turbulent. This allows you to mix the entire volume of the liquid, and at a higher liquid flow rate, the mixing occurs more intensively, therefore, despite the shorter processing time of the stream with a magnetic field, the processing efficiency is achieved.

It is claimed that this invention has high efficiency in the treatment of liquids having different composition and flow rate due to treatment with an equally variable magnetic field.

The disadvantage of this solution is the very process of variable magnetization. This is explained as follows. As you know, calcium as a metal acquires a magnetic charge of a certain polarity. As you know, particles with the same charge are repelled, different particles are attracted. Therefore, the efficiency of the magnetization device directly depends on the power acquired by the calcium particle. Thus, the implementation of the processes in the device for reversing the polarity of the magnets involved in the processing is inexpedient, since part of the energy will be spent simply on reversing the polarity of the particle charge, then on re-magnetization (already the opposite), etc. Moreover, the processing time is limited.

Therefore, the claimed technical solution differs from the prototype in that the processing polarity is always the same, it is not necessary to change the polarity, and the direction for achieving the technical result consists in increasing the time spent by calcium particles in a magnetic field.

The disadvantage of the prototype is the fact that it requires observing the optimal geometric dimensions of the ring permanent magnets. In the claimed invention there is only one magnet, and there are no requirements for optimal sizes for it. For him, only the necessary power is selected, according to the required technical characteristics based on the solution of certain problems.

In addition, the claimed invention has a significant difference in design, since while the housing of the device according to patent RU 2242433 consists of a large number of parts, and a number of joints are inaccessible to direct operational, in case of emergency situations, the device exits from the operating mode , interventions to eliminate problems, the claimed invention is based on a monolithic case consisting of one part, providing ultimate strength and reliability in installation and e pluatatsii due to the absence of any joints and assembly elements.

There is also a difference in the degree of difficulty in installing devices, since, in contrast to the device according to the patent RU 2242433 having only an external thread at the input and output, the claimed invention, due to the difference in the thread types of the input and output pipes (internal and external), does not require installation additional details and simply inserted into the undocking of the pipeline elements.

Also the closest analogue is the Anti-limestone RBM magnet [see http://www.rbmspa.ru/an/magnit.doc], which consists of ring permanent magnets with a constant polarity and a constant magnetic field. To prevent direct contact with water, the inner surface of the magnets is protected by a plastic food grade polymer.

The disadvantage of this device is the direct flow of water and the short residence time of water in a magnetic field, which significantly reduces its magnetization and requires a significant increase in the volume of the device to achieve an efficiency similar to that of the claimed invention.

The purpose of this utility model is to create more compact devices compared to analogs and more effective in treating liquids with a magnetic field, with the exception of direct contact of the magnet with water.

The technical result consists in simplicity of design and higher reliability, an increase in the duration of processing by a magnetic field is achieved.

Devices of this type of processing have advantages over the known analogues in size, because Due to the total length of the liquid path in the processing channels, a common path is formed several times greater than the liquid path in direct-flow versions of analogues. This advantage in the dimensions of the device makes it possible to install it in places where there are restrictions on the length (height) of the installation site due to the distribution of fluid movement across the width of the device.

Advantages include the increased time of treating the liquid with a magnetic field in comparison with analogues known in practice with identical or smaller sizes than theirs (analogues).

The advantages include ease of manufacture due to the small number of components.

The advantages include the simplicity of the final installation - due to the combined type of the inlet and outlet pipes made in the form of pipe sections with external (inlet pipe) and internal (output pipe) thread, which in turn allows you to install this device at the place of use without any additional details. Also, taking into account the absence of any valves or other parts restricting the movement of fluid in any particular direction, these devices can be mounted at the place of use either in direct or in reverse order.

Brief Description of the Drawings

Figure 1 shows a device for magnetic processing of liquid with a vertical zigzag treatment (appearance and side view in section), where 1 - Case, 2 - Channel-forming insert, 3 - Direction of fluid movement, 4 - Magnetic field, 5 - Input branch pipe, 6 - Outlet pipe, 7 - Magnet, 8 - Protective cover;

Figure 2 presents a device for magnetic fluid processing with horizontal zigzag processing (appearance and side view in section);

Figure 3 presents a device for magnetic fluid processing with horizontal spiral processing (appearance, side view in section and top view in section), where 9 is the beginning of the channel-forming element, 10 is a spiral increasing channel, 11 is the end and exit of a spiral increasing channel , 12 - the outer gap, 13 - the space formed by the housing (1) and the upper muffled part of the channel-forming element (2), 14 - the output part of the device.

Figure 4 presents a device for magnetic fluid treatment with a separation-mixing directional nature of the fluid movement by horizontal spiral processing (appearance and top view in section), where 15 are sub-flows, 16 is a mixing zone;

Figure 5 presents a device for the magnetic treatment of a liquid by the separation-mixing nature of processing increased turbulence (appearance and top view in section);

Figure 6 presents a device for longitudinally-spiral magnetic processing of a liquid (appearance and side view in section);

Figure 7 presents a device for reciprocating magnetic processing of liquid (appearance and side view in section), where: 17 - Through element, 18 - Muffled element located in the channel-forming insert;

On Fig presents a device for turbulent magnetic processing of liquid (appearance and side view in section), where 19 - inclined jumpers, 20 - dividing protrusions, 21 - a single stream after mixing in the zone (16);

Figure 9 presents a compact device for longitudinally-spiral magnetic processing of a liquid (appearance and side view in section);

Figure 10 presents a compact device for reciprocating magnetic processing of a liquid;

Figure 11 presents a compact device for turbulent magnetic processing of a liquid (appearance and view showing the movement of fluid flows).

Achievements

This result is achieved due to the fact that the device for magnetic processing of liquid in the pipeline containing a magnet, inlet and outlet pipes, a container inside which have at least 1 channel or channel forming element for passage of magnetizable water, characterized in that the magnet is located at the end and / or on the sides of the case or the case itself or the container with channels or channel-forming elements are made of a material that creates a magnetic field.

The channel can be made zigzag.

The plane of the zigzag channel can be set perpendicular to the axis of the pipeline.

The plane of the zigzag channel can be set parallel to the axis of the pipeline.

The channel may be made in the form of a spiral.

The inlet channel of the tank can be divided into at least 2 streams, and contains a mixing zone, where from each of the separated streams of the channel, the liquid is mixed with the divided stream of the other channel.

SUMMARY OF THE INVENTION

The above goals are achieved due to longer processing times with the minimum dimensions of the devices, which allows you to create more economical and simpler due to the minimum component parts in the technological plan for manufacturing products.

Also, the claimed result is achieved due to the formation in the container in the device through which the liquid passes, the channels repeatedly conducting the liquid located in them through a magnetic field, while when compared with direct-flow options, it is revealed that in the patented devices, the liquids pass in two - three times more and, accordingly, the magnitude of the magnetic field potential assimilated by the particles of the liquid increases.

In addition, the quality of processing can be improved by organizing increased turbulence and randomness of the fluid flow. Due to the enhanced turbulence, improved mixing in the liquid of nearby streams of impurity particles more strongly treated with a magnetic field is organized, with medium and low processing.

The embodiment of the device is possible in the form of various options, the common essence of which is the presence of many channels that repeatedly conduct liquid.

Figure 1 shows a device for magnetic processing of liquid with a vertical zigzag treatment.

This device is designed for the magnetic treatment of liquids in pipelines and devices for cold and hot water supply with a small flow rate: home pipelines, household pipelines at industrial enterprises, etc.

This version of the device allows you to redistribute the direct-flow linear motion of the fluid in the known devices in the progressive-return zigzags of the plane running coaxially to the axis of motion, thereby reducing the size of the device along its length (height) and allows you to mount the device based on this principle in places with limited length (height) of the installation site without restrictions on the width of the device. In order to reduce the dimensions of the device or save materials on the manufacture of this device, as well as to increase the efficiency of the device, the magnet can be located both on the end and on the sides of the case, or the case itself or the channel-forming insert can be made of a material that creates a magnetic field. A housing or channel-forming insert made of a material that creates a magnetic field in a device for magnetic processing of liquid can be used in a particular device as a separate application (in the device

either a case or a channel-forming magnet insert is used) or together (the device and a channel and channel-forming magnet insert are used in the device).

The principle of operation of this embodiment of the device is to distribute the movement of liquid in the magnetic processing devices in such a way that, see FIG. 1, the liquid enters through the inlet pipe (5) into the movement channel formed by the housing (1) and the channel-forming insert (2) due to advancement in the direction (3), being in the influence zone (4) of the magnet (5), passes until it (liquid) leaves the device through the outlet pipe (6), processing with a magnetic field at least 1 time. The processing effect of which is enhanced by attenuation-amplification of the above field, caused by the distance from the magnet or approaching it.

Figure 2 presents a variant of a device for magnetic fluid processing with horizontal zigzag processing.

This device is designed for the magnetic treatment of liquids in pipelines and devices for cold and hot water supply with a small flow rate: home pipelines, household pipelines at industrial enterprises, etc.

Unlike the previous version, this device redistributes the translational-reciprocal movement of the liquid in the vertical plane into the translational-reciprocal zigzags of the plane running perpendicular to the axis of motion, thereby lengthening the path of the fluid passing through the channels formed by the device body and channel-forming insert and, accordingly, increasing the time spent by the fluid in the magnetic field , which in turn improves the quality of fluid processing. In order to reduce the dimensions of the device or save materials on the manufacture of this device, as well as to increase the efficiency of the device, the magnet can be located both on the end and on the sides of the case, or the case itself or the channel-forming insert can be made of a material that creates a magnetic field. A housing or channel-forming insert made of a material that creates a magnetic field in a device for magnetic fluid treatment can be used in a particular device either individually (either a housing or a channel-forming magnet insert is used in the device) or together (a housing and a channel-forming insert are used in the device from a magnet).

The principle of operation of the device is to distribute the movement in the magnetic processing devices in such a way that, see Figure 2, the liquid enters through the inlet pipe (5) into the movement channel formed by the housing (1) and the channel-forming insert (2) having at least 1- of the zigzag cycle, due to the advancement (3) in the influence zone (4) of the magnet (5), it passes through the outlet pipe (6) for a long time processing with the magnetic field until it (liquid) leaves the device through the outlet pipe (6), thereby increasing the magnetic charge potential acquired by the liquid particles.

Figure 3 presents a variant of a device for magnetic fluid processing with horizontal spiral processing.

This device is intended for the magnetic treatment of liquids in places that have restrictions on the length (height) of the installation site, but do not have restrictions on the width of the device.

Unlike previous versions, this device redistributes the translationally-returning zigzag fluid movements in a horizontal plane to horizontally spiral increasing, thereby lengthening the liquid path of the channel formed by the channel-forming insert and, accordingly, increasing the time spent in the magnetic field, which in turn improves the quality of processing liquids. In order to reduce the dimensions of the device or save materials on the manufacture of this device, as well as to increase the efficiency of the device, the magnet can be located both on the end and on the sides of the case, or the case itself or the channel-forming insert can be made of a material that creates a magnetic field. A housing or channel-forming insert made of a material that creates a magnetic field in a device for magnetic fluid treatment can be used in a particular device either individually (either a housing or a channel-forming magnet insert is used in the device) or together (a housing and a channel-forming insert are used in the device from a magnet).

The principle of operation of the device is to distribute the movement in the magnetic processing devices in such a way that, see Fig. 3, the liquid enters through the inlet pipe (5) into the central plugged part (3) of the channel-forming element (2) of the liquid processing device ( channel-forming element) beginning (9). Then it (the liquid) moves along a spiral-increasing channel (10) until it ends and exits (11) into the external gap (12) formed by the body (1) and the channel-forming element (2), from where, in turn, through the provided space (13) formed by the housing (1) and the upper plugged part of the channel-forming element (2) passes to the outlet (14) of the liquid processing device through the outlet pipe (6).

Figure 4 presents a variant of a device for magnetic fluid treatment with a separation-mixing directional nature of the fluid movement by horizontal spiral processing.

This device is intended for the magnetic treatment of liquids in places with restrictions on the length (height) of the installation site.

Unlike previous options, this device distributes the movement of fluid in the horizontal plane by dividing it into sub-flows, then mixing them and guiding them along organized channels to the next separation stage, thereby, in addition to lengthening the path of the fluid through the channel formed by the channel-forming insert and, accordingly, increasing the residence time of the fluid in a magnetic field, in this device, compared with the previous one, the uniformity of the treatment of the liquid with the magnetic field increases due to the mixing Bani less treated particles by a magnetic field with a treated,

which in turn improves the quality of fluid processing. In order to reduce the dimensions of the device or save materials on the manufacture of this device, as well as to increase the efficiency of the device, the magnet can be located both on the end and on the sides of the case, or the case itself or the channel-forming insert can be made of a material that creates a magnetic field. A housing or channel-forming insert made of a material that creates a magnetic field in a device for magnetic fluid treatment can be used in a particular device either individually (either a housing or a channel-forming magnet insert is used in the device) or together (a housing and a channel-forming insert are used in the device from the magnet at the same time).

The principle of operation of the device is to distribute the movement in the magnetic processing devices in such a way that, see Figure 4 (the magnet, the protective casing and the influence of the magnetic field are not considered in this sketch), the liquid entering the central part is separated by the details of the first stage (4) channel-forming element (2) for more than 1 stream (in the considered option - 3). By the example of flows (3), it can be seen that the details of the second cascade (5) of the channel-forming element (2), the streams formed by them are divided into smaller substreams. Through organized channels, the divided substreams (15) fall into the mixing zone (16). In turn, already mixed substreams are separated by the details of the next (third) cascade (6) of the channel-forming element (2) into two other substreams for conducting them to the next mixing zone. This process occurs given by the number of cascades of the channel-forming element once before the output of the treated liquid into the space (formed by the body of the device for processing liquid (1) and the channel-forming element (2) to supply it (liquid) to the output of the device. Figure 5 shows a variant of the device for magnetic treatment of liquids by the separation-mixing nature of processing with increased turbulence This device is designed for magnetic treatment of liquids in places with restrictions on the length (height) m Unlike the previous version, this device distributes the movement of liquid in the horizontal plane by constantly dividing it into sub-flows and then mixing them at each stage of the passage of the liquid through the channel-forming element, due to which the uniformity of the magnetic field treatment of the liquid in this device increases compared to the previous one due to the mixing of less processed magnetic field particles with more processed, which in turn improves the quality of the processing fluid. In order to reduce the dimensions of the device or save materials on the manufacture of this device, as well as to increase the efficiency of the device, the magnet can be located both on the end and on the sides of the case, or the case itself or the channel-forming insert can be made of a material that creates a magnetic field. Housing or channel-forming insert made of a material creating a magnetic field in a device for magnetic processing of liquid

can be used in a particular device both individually (either the case or a channel-forming magnet insert is used in the device) or together (the device and the channel and channel-forming magnet insert are used simultaneously in the device). The principle of operation of the device is to distribute the movement in the magnetic processing devices in such a way that, see Figure 5 (the magnet, the protective casing and the influence of the magnetic field are not considered in this sketch), the liquid arriving from the inlet pipe (not shown in the sketch) to the central the part is divided by the details of the first cascade (4) of the channel-forming element (2) into more than 1 flow (in this embodiment, 3 flows are considered). By the example of flows (3), it can be seen that the details of the second cascade (5) of the channel-forming element (2), the flows formed by them, respectively, are divided into smaller substreams (15). Through organized channels, the divided substreams (15) fall into the mixing zone of the turbulent impact (16). In turn, already mixed substreams are separated by the details of the next (third) cascade (6) of the channel-forming element (2) into more than two substreams for conducting them to the next mixing zone. This process occurs given by the number of cascades of the channel-forming element once before the output of the treated liquid into the space (formed by the body of the device for processing liquid (1) and the channel-forming element (2) to supply it (liquid) to the output of the device.

Figure 6 presents a device for longitudinally-spiral magnetic processing of a liquid.

This device is designed for magnetic processing of liquids in places limited by the width (diameter) of the installation site, but without restrictions on the length (height).

Compared with the previous one, this model of the device distributes the direct-flow fluid movement identical to the known devices due to the channel-forming insert into a spiral, distributed along the channels (at least 2 (two) spiral channel-forming inserts, with turns (at least 1) number which grows along the central axis of the liquid processing device, along the axis of the liquid path in the device, thus, by increasing the path of particles passing through the space inside the magnetic field (in comparison with the existing identical by devices) the degree of processing of the liquid increases, and also due to the fact that the increase in the number of turns of the spiral goes in the direction coaxial with the direction of movement of the liquid, this principle of operation of the device allows you to create devices reduced in comparison with existing identical ones in diameter and taking into account ways of finding liquid particles in a magnetic field and comparing it with a similar parameter of direct-flow analogs, by its (device) length. In order to reduce the dimensions of the device or to save materials on the manufacture of this device, as well as to increase the efficiency of the device, the housing or channel-forming insert can be made of a material that creates a magnetic field. A housing or channel-forming insert made of a material creating a magnetic field in

a device for magnetic processing of liquids can be used in a particular device both individually (either a case or a channel-forming magnet insert is used in the device) or together (the case and a channel-forming magnet insert are used in the device at the same time).

The principle of operation of the device according to this option is to distribute the movement in the magnetic processing devices in such a way that, see Fig. 6, the liquid entering through the inlet pipe (5) passes through the housing of the device (1) through spiral channels of at least 2 x, formed by the channel-forming insert (2) going along the axis of the device to the output of the device through the outlet pipe (6). Due to the occurring lengthening of the path of the internal space of the devices, the liquid is under the influence of the magnetic field (4) for a longer time (compared with direct-flow analogs) and therefore undergoes a longer treatment with the magnetic field. This increases the processing efficiency and increases the potential of the magnetic properties acquired by the fluid particles.

Figure 7 presents a variant of the device for reciprocating magnetic fluid processing.

This device is designed for the magnetic treatment of liquids in places limited by the width (diameter) of the installation site, but without restrictions on the length (height).

Unlike the previous version, this device distributes the movement of fluid in the device for magnetic processing through the through and drowned elements in the form of translational-returnable and provides better processing due to the multiple passage of the liquid of the same areas of influence of the magnetic field. In order to reduce the dimensions of the device or to save materials on the manufacture of this device, as well as to increase the efficiency of the device, the housing or channel-forming insert can be made of a material that creates a magnetic field. A housing or channel-forming insert made of a material that creates a magnetic field in a device for magnetic fluid treatment can be used in a particular device either individually (either a housing or a channel-forming magnet insert is used in the device) or together (a housing and a channel-forming insert are used in the device from the magnet at the same time).

The principle of operation of the device is to distribute the movement in the magnetic processing devices in such a way that, see Fig. 7, the liquid entering through the inlet pipe (5) in the device case (1), passing through the through element of the channel-forming insert (17), is reflected from the muffled element (18) and through the gap organized by the walls by the elements of the channel-forming insert (17, 18) and the housing (1) pass to the next through element of the insert, thus repeating the cycles of translational-reverse motion until the fluid is removed from the device Res outlet (6). Due to this reciprocating movement, the path of the internal space of the device to increase with fluid and, accordingly,

its residence time under the influence of a magnetic field increases, which in turn increases the potential of the magnetic properties acquired by the fluid particles.

On Fig presents a device for turbulent magnetic processing of liquid.

This device is designed for the magnetic treatment of liquids in places limited by the width (diameter) of the installation site, but without restrictions on the length (height).

Unlike the previous version, this device organizes the processing of a liquid by a magnetic field due to the constant separation and mixing of the liquid flows in the channels of the channel-forming insert, which, along with an increased (compared to direct-flow analogs) time spent by the liquid in a magnetic field, improves the quality of processing due to the constant mixing more strongly charged with a magnetic field particles of liquid with medium and low charge. In order to reduce the dimensions of the device or to save materials on the manufacture of this device, as well as to increase the efficiency of the device, the housing or channel-forming insert can be made of a material that creates a magnetic field. A housing or channel-forming insert made of a material that creates a magnetic field in a device for magnetic fluid treatment can be used in a particular device either individually (either a housing or a channel-forming magnet insert is used in the device) or together (a housing and a channel-forming insert are used in the device from the magnet at the same time).

The principle of operation of this variant of the device is to distribute the movement in the magnetic processing devices in such a way that, see Fig. 8, the fluid moving in the device’s body enters the channel of the path of movement formed by inclined jumpers (19). The second section of the spiral is directly adjacent to it, oriented in the opposite direction, having at its beginning dividing protrusions (20). These protrusions divide the water flow going along the channel-forming corridor into two equivalent ones (15). A similar division occurs in the adjacent channel with the formation of flows (15). Further, the substreams (15), separated from the main stream, go through the channel formed by the walls of the previous spiral segment and the segment in which the stream is divided and fall into the mixing zone of the substreams (16), where they are mixed and then they already go in a single stream (21) to the next cascade of separation and mixing, similar to this one.

Due to this translational separation-mixing motion, the path of the internal space of the device through the liquid increases, and accordingly, the time it is spent under the influence of a magnetic field increases, which in turn increases the potential of the magnetic properties acquired by the particles of the liquid. Also, due to the presence of at least 1 separation-mixing cascade in devices of this type, the charge level of particles is balanced by a magnetic field, i.e. due to more charged particles, less charged ones get an additional magnetic potential,

which in turn provides more efficient particle handling after processing.

Figure 9 presents a variant of a compact device for longitudinally-spiral magnetic processing of liquid.

This embodiment of the device is intended for magnetic processing of liquids in places completely limited in size by mounting this device inside the above pipelines and is a permanent magnet made in the form of a spiral with the number of turns of at least 1 and the separated fluid flows of at least 2.

This device differs from all previous options in that it uses the internal cavity of the pipeline as a working space and organizes in it, similarly to the device in Fig. 6, the spiral movement of the fluid increasing along the central axis. By removing the majority of the housing and combining the magnet and the channel-forming insert, this device is a compact and affordable product for all installation sites.

The principle of operation of the device is to distribute the movement in the places of application in such a way that, see Fig. 9, the liquid passing through the inlet part (5) of the active pipeline through the device body in the form of an annular protrusion (1) along spiral channels of at least 2 x, formed by the channel-forming insert (2), going along the axis of the device, enters the output of the device and follows through the pipeline. Due to the occurring lengthening of the path of the internal space of the devices, the liquid is under the influence of the magnetic field (4) for a longer time (compared with direct-flow analogs) and therefore undergoes a longer treatment with the magnetic field. This increases the processing efficiency and increases the potential of the magnetic properties acquired by the fluid particles.

Figure 10 presents a variant of a compact device for reciprocating magnetic fluid processing.

This version of the device is intended for magnetic processing of liquids in places completely limited in size by mounting this device inside the above pipelines and made of a permanent magnet with a number of cascades of reciprocating action of at least 1.

In contrast to the previous embodiment, this device, similarly to the embodiment of Fig. 7, organizes a translational-return mechanism for treating a liquid with a magnetic field; also due to the removal of most of the body and use as the working space of the internal cavity of the pipeline and the combination of the magnet and the channel-forming insert, it becomes more compact and simpler than in FIGS. 1, 2, 3, 4, 5, 6, 7, 8 in the constructive regarding the device.

The principle of operation of the device is to distribute the movement in the places of application of the magnetic processing device in such a way that, see Figure 10, the liquid passing through the device body in the form of a ring (1), which is simultaneously fixing, through

the through element of the channel-forming insert (9) is reflected from the plugged element (10) and through the gap organized by the walls by the elements of the channel-forming insert (9, 10) and the walls of the acting input part of the pipeline (5) passes to the next through-element of the insert. Due to this reciprocating movement, the path of the internal space of the device through the fluid increases and, accordingly, the time it spends under the influence of a magnetic field increases, which in turn increases the potential of the magnetic properties acquired by the fluid particles.

Figure 11 presents a compact device for turbulent magnetic processing of a liquid.

This device is intended for the magnetic treatment of liquids in places completely limited in size by mounting this device inside the above pipelines and made of a permanent magnet with a number of separation-mixing cascades of at least 1.

In contrast to the previous embodiment, this device, similarly to the embodiment of FIG. 8, organizes a turbulent mechanism for treating a liquid with a magnetic field; also due to the removal of most of the body and use as the working space of the internal cavity of the pipeline and the combination of the magnet and the channel-forming insert, it becomes more compact and simpler in design compared to Figs. 1, 2, 3, 4, 5, 6, 7, 8 regarding the device.

The principle of operation of the device is almost completely similar to the principle of operation of the device for turbulent processing of liquid (see Fig. 8) and also consists in organizing turbulent processing of liquid due to separation cascades. However, since the body of the device is expressed as a retaining ring (1) at the beginning of the device (Fig. 11), this minimizes the device itself by removing most of the body and, by installing it (device) into the pipeline, introduce a method turbulent processing similar to the method of Fig. 8.

Due to the resulting translational separation-mixing motion, the path of the device through the liquid increases, and accordingly, the time spent by the device under the influence of the magnetic field increases, which in turn increases the potential of the magnetic properties acquired by the particles of the liquid. Also, due to the presence of at least 1 separation-mixing cascade in devices of this type, the charge level of the particles is balanced by the magnetic field, i.e. due to more charged particles, less charged ones get an additional magnetic potential.

Claims (6)

1. A device for magnetic processing of liquid in a pipeline containing a magnet, inlet and outlet nozzles, a container inside which at least 1 channel or channel-forming element for passage of magnetizable water is located, characterized in that the magnet is located on the end and / or sides of the housing or the case itself or the container with channels or channel-forming elements are made of a material that creates a magnetic field. 2. The device for magnetic processing of liquid in the pipeline according to claim 1, characterized in that the channel is made zigzag. 3. The device for magnetic processing of liquid in the pipeline according to claim 2, characterized in that the plane of the zigzag channel is installed perpendicular to the axis of the pipeline. 4. The device for magnetic processing of liquid in the pipeline according to claim 2, characterized in that the plane of the zigzag channel is installed parallel to the axis of the pipeline. 5. The device for magnetic processing of liquid in the pipeline according to claim 1, characterized in that the channel is made in the form of a spiral. 6. The device for magnetic processing of liquid in the pipeline according to claim 1, characterized in that the inlet channel of the tank is divided into at least 2 streams and contains a mixing zone, where from each of the separated channel flows the liquid is mixed with the divided stream of another channel.