CN217719187U - Large-flow single-magnetic-pole flat flow passage magnetizer - Google Patents

Abstract

The utility model relates to a large-flow single-magnetic-pole flat runner magnetizer, which comprises a plurality of parallel runner pipe bodies, a plurality of groups of single-magnetic-pole magnetization processing parts, an installation part and a protective pipe, wherein each runner pipe body is provided with a flat pipe body section, and each group of single-magnetic-pole magnetization processing parts comprises a plurality of single-magnetic-pole magnetization parts; each single-magnetic-pole magnetizing part comprises a magnetic conduction clamp and two magnetic blocks, the magnetic conduction clamp is provided with two vertical faces which are oppositely arranged, and the two magnetic blocks are oppositely adsorbed on the two vertical faces and correspondingly sleeved on the outer sides of the flat pipe body sections; the two mounting parts are correspondingly positioned at the two ends of the flow channel pipe body, flow channel pipe body mounting holes are formed in the two mounting parts, and the two ends of the flow channel pipe bodies which are arranged in parallel penetrate through the mounting holes; the protective pipe is sleeved outside the plurality of flow passage pipe bodies and the plurality of groups of single magnetic pole magnetization processing parts, and a preset gap is arranged between the protective pipe and the plurality of flow passage pipe bodies and the plurality of groups of single magnetic pole magnetization processing parts. The utility model discloses can be applicable to the length of single magnetic pole magnetization processing and extension magnetic treatment flow under the large-traffic operating mode, simple to operate is fit for mass production.

Description

Large-flow single-magnetic-pole flat runner magnetizer

Technical Field

The utility model relates to a magnetization treater technical field especially relates to a flat runner magnetizer of large-traffic single magnetic pole.

Background

At present, along with the continuous deepening of scientific technology, the magnetization of magnet is more and more applied to arouse the attention of scientific research institutions, some have applied the magnetization of magnet to aspects such as drinking water, magnetic therapy equipment, water pipe scale removal scale control, and have obtained certain effect, however, the magnetizer that most of producers produced at present all adopts N, S mated polarity arrangement this kind of traditional magnetism processing structure mode, belongs to the dipole structure, this dipole structure, because the magnetization of S utmost point is different with the effect of N utmost point magnetization, so the science and science field has proposed single magnetic pole theory, along with the proposition of single magnetic pole theory and a large amount of practical application examples explain: the single magnetic pole is applied to magnetization treatment of agricultural water, grain seeds, drinking water, magnetic therapy and the like, and the favorite harvest is obtained.

The single-magnetic-pole magnetizer in the prior art is disclosed as an invention patent with the patent number of CN201010205169.2, and has the characteristics of good magnetizing effect, high speed, wide application range, simple manufacturing process and low cost; however, the single-magnetic-pole processor actually comprising the pair of magnetic semi-arc magnetic blocks opposite to each other cannot prolong the length of a magnetic processing flow, and can be completed only by injection molding, so that the process is complex, field installation is not facilitated, and the application of the single-magnetic-pole magnetic processor is limited; due to the limitation of the structure, the size increase of the magnetic pole magnetizer main body and the tile-shaped magnet has the difficulty of manufacturing and the increase of cost, and the magnetic pole magnetizer is not suitable for magnetization treatment under the working condition of large flow; therefore, a single magnetic pole magnetization processor suitable for large flow rate needs to be provided to solve the above problems in the prior art.

Disclosure of Invention

The utility model aims to solve the technical problem that a flat runner magnetizer of large-traffic single magnetic pole is provided, can be applicable to the single magnetic pole magnetization under the large-traffic operating mode and handle, and can prolong the length of magnetism processing procedure, have simple to operate, simple structure and be fit for the beneficial effect of mass production.

The utility model provides an above-mentioned technical problem's technical scheme as follows:

a large-flow single-magnetic-pole flat runner magnetizer comprises a plurality of parallel runner pipe bodies, a plurality of groups of single-magnetic-pole magnetization processing parts, an installation part and a protective pipe, wherein each runner pipe body is provided with a flat pipe body section, and each group of single-magnetic-pole magnetization processing parts comprises a plurality of single-magnetic-pole magnetization parts;

each single-magnetic-pole magnetizing part comprises a magnetic conduction clamp and two magnetic blocks, the magnetic conduction clamp is provided with two vertical faces which are oppositely arranged, and the two magnetic blocks are oppositely adsorbed on the two vertical faces and correspondingly sleeved on the outer sides of the flat tube body sections; the two mounting parts are correspondingly positioned at the two ends of the runner pipe body, runner pipe body mounting holes are formed in the two mounting parts, and the two ends of the plurality of parallel runner pipe bodies penetrate through the mounting holes; the protective pipe is sleeved outside the plurality of flow passage pipe bodies and the plurality of groups of single magnetic pole magnetization processing parts, and a preset gap is formed between the protective pipe and the flow passage pipe bodies.

The utility model has the advantages that: the installation part enables the ends of the plurality of runner pipe bodies to be communicated through the plurality of installation holes formed in the installation part, so that a medium to be magnetized can enter the plurality of runner pipe bodies through the installation part for magnetization treatment, the flow of the magnetization treatment is increased through the plurality of parallel runner pipe bodies, the magnetic treatment device is suitable for the working condition of large-flow magnetization treatment, and the magnetic treatment device is simple in structure and convenient to install; the magnetic conduction clamp and the magnets adsorbed by the opposite surfaces of the magnetic conduction clamp are sleeved on the flat tube section, the flat tube section is provided with a plurality of single magnetic pole magnetizing parts along the length direction of the flat tube section, and the magnetic treatment process is prolonged through the plurality of single magnetic pole magnetizing parts; the protective tube has protective effect on the flow channel tube body and the single magnetic pole magnetizing part arranged in the protective tube; the single magnetic pole magnetizing part is simple in structure, capable of being designed in a standardized mode, capable of being processed into standard parts in batches before installation, suitable for batch production and convenient to install.

On the basis of the technical scheme, the utility model discloses can also do following improvement.

Further, the magnetic conduction clamp is a U-shaped clamp formed by punching pure iron plates, the magnetic blocks are fixed on two inner vertical faces of the U-shaped clamp, an installation gap is formed between the two magnetic blocks, and the flat tube body section is located in the installation gap.

The beneficial effect of adopting the above further scheme is: the upper end face and the lower end face of the inner side of the opening at the front end of the U-shaped clamp are vertical faces, so that the U-shaped clamp can be conveniently clamped and installed on the flat pipe section; the two side surfaces of the U-shaped clamps and the magnetic blocks which are clamped at the end of the flat tube body are provided with openings, so that a magnetic treatment process with good integrity and consistency can be formed conveniently.

Further, the magnetic block is a rectangular magnetic block and is formed by high-magnetic processing of neodymium iron boron.

The beneficial effect of adopting the further scheme is that: the upper end surface and the lower end surface of the rectangular magnet are N poles or S poles and are in adaptive adsorption with the U-shaped clamping face; the magnet made of the neodymium iron boron material has good magnetism and machining performance.

Further, the two oppositely arranged magnetic blocks are positive magnetic pole magnetic blocks or negative magnetic pole magnetic blocks.

The beneficial effect of adopting the above further scheme is: the two magnetic blocks are positive magnetic pole magnetic blocks or negative magnetic pole magnetic blocks, namely, the opposite surfaces of the two magnetic blocks are both N poles or S poles; if the positive poles of the magnetic blocks face the flat flow channel, performing positive pole single magnetic pole magnetization treatment; and if the cathodes of the magnetic blocks face the flat flow channel, carrying out negative single-magnetic-pole magnetization treatment.

Further, the installation department is the arc mounting panel, and two the sunken arcwall face of installation department is arranged relatively.

The beneficial effect of adopting the further scheme is that: the arc mounting plate is a concave pipe support, the edge of the arc mounting plate is gradually sunken to form a spherical arc surface from the middle of the arc mounting plate, the cross section of the arc mounting plate is arc-shaped, a plurality of mounting holes communicated with the end parts of the runner pipe body are formed in the arc surface of the arc mounting plate, the magnetized medium is gathered through the sunken spherical surface of the arc mounting plate and plays a role in buffering, and then the magnetized medium uniformly enters the plurality of runner pipe bodies for magnetization treatment.

Furthermore, the protective tube is made of stainless steel, and the wall thickness of the protective tube is 1.0mm-1.2mm.

The beneficial effect of adopting the further scheme is that: the stainless steel protective tube protects the flow channel tube body and the single magnetic pole magnetized part in the stainless steel protective tube.

Further, the middle of the runner pipe body is made of a stainless steel round pipe, and the middle of the stainless steel round pipe is processed into a flat pipe section with an oval cross section.

The beneficial effect of adopting the above further scheme is: flattening the middle part of the stainless steel round pipe through a corresponding die to form a flat pipe section, wherein the longitudinal section of the flat pipe section is oval, and the upper end surface and the lower end surface of the flat pipe section are planes; the flat tube segments facilitate the clamping of a plurality of single magnetic pole magnetized portions.

Further, pillar tip an organic whole is connected with the shrouding and is located the installation department outside, shrouding middle part through-hole is the flow channel hole.

The beneficial effect of adopting the above further scheme is: the middle flow channel hole of the sealing plate is communicated with an external pipeline and used for introducing a to-be-magnetized medium, an interval is arranged between the sealing plate and the installation part, an inlet cavity and an outlet cavity are formed, the to-be-magnetized medium uniformly enters the plurality of flow channel pipes after entering the inlet cavity, and a buffering effect is achieved through the inlet cavity.

Furthermore, six internal-tooth stainless steel pipe joints are correspondingly welded on the outer sides of the flow passage holes.

The beneficial effect of adopting the further scheme is that: the six-inner-tooth stainless steel pipe joint is communicated with an external pipeline, so that a medium to be magnetized can be conveniently introduced for magnetization.

Furthermore, the multiple groups of single magnetic pole magnetization processing parts are 3-10 groups, and each group is provided with 3-24 single magnetic pole magnetization parts.

The beneficial effect of adopting the further scheme is that: determining the number of required flow channel pipe bodies according to the flow of a medium to be magnetized, wherein each flow channel pipe body is provided with a group of single magnetic pole magnetization processing parts; the number of single-pole magnetized portions to be mounted on the flat tube segments is determined in accordance with the length of the desired magnetic treatment flow.

Via above-mentioned technical scheme, compare with prior art, the beneficial effects of the utility model are that:

(1) The installation part of the utility model is provided with a sunken spherical cambered surface, namely the section of the installation part is arc-shaped, and a plurality of installation holes for communicating the runner pipe bodies are arranged on the sunken surface of the installation part, so that the medium to be magnetized enters the plurality of runner pipe bodies respectively through the installation part for magnetization treatment, the plurality of runner pipe bodies in parallel can be suitable for magnetization treatment under the working condition of large flow, and the quantity of the runner pipe bodies is determined according to the flow of the medium to be magnetized; an inlet cavity or an outlet cavity is formed between the mounting part and the protective tube sealing plate, so that a medium to be magnetized has the functions of gathering and buffering, and can uniformly enter each flow channel pipe body for magnetization treatment;

(2) The middle part of each runner pipe body of the utility model is a flat pipe body section with oval longitudinal section which is formed by flattening a circular pipe in a mould; the magnetic conduction clamp is a U-shaped clamp, the opposite surfaces of the magnetic conduction clamp adsorb the magnetic blocks and are clamped on the flat tube section, and the installation is convenient; a plurality of U-shaped clamps and magnetic blocks are clamped along the length direction of the flat tube section according to the required magnetic treatment process length, the plurality of U-shaped clamps have certain intervals, and side openings of the plurality of U-shaped clamps can form a magnetic treatment process with good integrity and consistency; the opposite surfaces of the paired magnetic blocks are the same magnetic poles, so that the medium in the pipeline body of the flow channel is magnetized by a single magnetic pole;

(3) The utility model discloses a single magnetic pole magnetization portion simple structure can carry out standardized design, processes into the standard component in batches in advance, and the magnetic treatment flow length as required presss from both sides the single magnetic pole magnetization portion of establishing different quantity in flat tube section during the installation can, simple to operate, efficient, and be suitable for batched production.

Drawings

Fig. 1 is a schematic structural view of the large-flow single-pole flat flow path magnetizer of the present invention;

fig. 2 is a schematic view of the connection between the installation part and the flow channel body of the large-flow single-pole flat flow channel magnetizer of the present invention;

FIG. 3 is a left side view of FIG. 2;

fig. 4 is a schematic view of the connection between the flow channel tube and the single magnetic pole magnetization portion of the large flow single magnetic pole flat flow channel magnetizer of the present invention;

fig. 5 is a front view of the single magnetic pole magnetizing part of the large flow single magnetic pole flat flow channel magnetizer of the present invention;

fig. 6 is a left side view of the single magnetic pole magnetization portion of the large flow single magnetic pole flat flow path magnetizer according to the present invention.

In the drawings, the reference numbers indicate the following list of parts:

1-protecting the pipe; 2-an installation part; 3-a flow passage pipe body; 4-six internal-tooth stainless steel pipe joints; 5-a single magnetic pole magnetized portion; 31-flat tube segments; 51-a magnetically permeable clip; 52-magnetic block.

Detailed Description

The principles and features of the present invention are described below in conjunction with the following drawings, the examples given are only intended to illustrate the present invention and are not intended to limit the scope of the present invention.

As shown in fig. 1 to 6, the embodiment of the present invention discloses a large-flow single-magnetic-pole flat flow channel magnetizer, which comprises a plurality of flow channel tube bodies 3 arranged in parallel, a plurality of groups of single-magnetic-pole magnetization processing portions, an installation portion 2 and a protection tube 1, wherein each flow channel tube body 3 has a flat tube body section 31, and each group of single-magnetic-pole magnetization processing portions comprises a plurality of single-magnetic-pole magnetization portions 5; each single-magnetic-pole magnetizing part 5 comprises a magnetic conducting clamp 51 and two magnetic blocks 52, the magnetic conducting clamp 51 is provided with two vertical surfaces which are oppositely arranged, and the two magnetic blocks 52 are oppositely adsorbed on the two vertical surfaces and correspondingly sleeved on the outer sides of the flat tube body sections 31; the two mounting parts 2 are correspondingly positioned at the two ends of the runner pipe body 3, a runner pipe body mounting hole is formed in each mounting part, and the two ends of the runner pipe bodies 3 which are arranged in parallel penetrate through the mounting holes; the protective tube 1 is sleeved outside the plurality of runner tube bodies 3 and the plurality of groups of single magnetic pole magnetization processing parts, and a preset gap is arranged between the protective tube and the plurality of groups of single magnetic pole magnetization processing parts.

In order to further optimize the above technical solution, as shown in fig. 5 and 6, the magnetic conductive clip 51 is a U-shaped clip formed by punching a pure iron plate, two magnetic blocks 52 are fixed on two vertical surfaces of the inner side of the U-shaped clip, an installation gap is formed between the two magnetic blocks 52, and the flat tube body segment 31 is located in the installation gap.

In order to further optimize the above technical solution, the magnetic block 52 is a rectangular magnetic block and is formed by high-magnetic processing of neodymium iron boron.

In order to further optimize the above technical solution, the two oppositely arranged magnetic blocks 52 are positive magnetic pole magnetic blocks or negative magnetic pole magnetic blocks.

In order to further optimize the above technical solution, as shown in fig. 1 and 2, the mounting portions 2 are arc-shaped mounting plates, and the concave arc-shaped surfaces of the two mounting portions 2 are arranged oppositely.

In order to further optimize the technical scheme, the protective tube 1 is made of stainless steel, and the wall thickness of the protective tube is 1.0mm-1.2mm. The diameter of the protective tube 1 can be sleeved outside the plurality of runner tube bodies 3 and the plurality of groups of single magnetic pole magnetization processing parts and is provided with a preset gap.

In order to further optimize the above technical solution, as shown in fig. 4, the flow conduit body 3 is a flat tube section 31 with an oval cross section formed by machining the middle of a stainless steel round tube. The oval cross-sectional dimension of the flat tube segments 12 is determined in accordance with the magnitude of the flow of the medium to be magnetized.

In order to further optimize the technical scheme, as shown in fig. 1, the end part of the protection tube 1 is integrally connected with a sealing plate and is positioned outside the mounting part 2, and a through hole in the middle of the sealing plate is a flow channel hole.

In order to further optimize the technical scheme, six internal-tooth stainless steel pipe joints 4 are correspondingly welded on the outer sides of the flow passage holes.

In order to further optimize the technical scheme, the multiple groups of single-magnetic-pole magnetization processing parts are 3-10 groups, and each group is provided with 3-24 single-magnetic-pole magnetization parts 5.

When the large-flow single-magnetic-pole flat flow channel magnetizer is used, an inlet cavity is formed between the inner side of a sealing plate of a protective pipe 1 and the arc-shaped surface of an installation part 2, and a medium to be magnetized enters the inlet cavity through a stainless steel pipe joint 4 with six internal teeth and respectively enters a plurality of flow channel pipe bodies 3 communicated with the arc-shaped surface of the installation part 2; arranging a corresponding number of flow channel pipe bodies 3 according to the flow of the medium to be magnetized; in the embodiment, seven runner pipe bodies 3 are arranged, wherein one runner pipe body 3 is arranged in the middle of the arc-shaped surface of the mounting part 2, six runner pipe bodies 3 are uniformly distributed around the center of the mounting part 2 along the circumferential direction, and a medium to be magnetized uniformly enters the seven runner pipe bodies 3;

the flat tube section 31 is formed in the middle of the runner tube body 3 through flattening in a die, the flat tube section 31 is clamped with a plurality of single-magnetic-pole magnetized portions 5 along the length direction, magnetic conduction clamps 51 of the single-magnetic-pole magnetized portions 5 are U-shaped clamps, magnetic blocks 52 are adsorbed on opposite surfaces of the magnetic conduction clamps, and when the negative poles of the magnetic blocks 52 face the flat tube section 31, negative single-magnetic-pole magnetization processing on media in the flat runner is achieved; when the positive poles of the magnetic blocks 52 face the flat tube segments 31, the positive pole single magnetic pole magnetization treatment of the medium in the flat flow channel is realized;

the single magnetic pole magnetizing parts 5 are simple in structure and convenient to install, a plurality of single magnetic pole magnetizing parts 5 are processed into standard parts in batches in advance before installation, and the plurality of processed and assembled single magnetic pole magnetizing parts 5 are clamped on the flat tube body section 31 during installation; a certain installation distance is formed among the single magnetic pole magnetized parts 5, and the installation distance can ensure that the single magnetic pole magnetized parts 5 are not influenced mutually; the single-pole magnetized portions 5 are installed in a corresponding number according to the required length of the magnetic treatment process.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the present invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included within the protection scope of the present invention.

Claims (10)

1. The large-flow single-magnetic-pole flat runner magnetizer is characterized by comprising a plurality of parallel runner pipe bodies (3), a plurality of groups of single-magnetic-pole magnetization processing parts, an installation part (2) and a protective pipe (1), wherein each runner pipe body (3) is provided with a flat pipe body section (31), and each group of single-magnetic-pole magnetization processing parts comprises a plurality of single-magnetic-pole magnetization parts (5);

each single-magnetic-pole magnetizing part (5) comprises a magnetic conducting clamp (51) and two magnetic blocks (52), the magnetic conducting clamp (51) is provided with two vertical surfaces which are oppositely arranged, and the two magnetic blocks (52) are oppositely adsorbed on the two vertical surfaces and correspondingly sleeved on the outer sides of the flat tube body sections (31); the two mounting parts (2) are correspondingly positioned at two ends of the runner pipe body (3), runner pipe body mounting holes are formed in the two mounting parts, and two ends of the runner pipe bodies (3) which are arranged in parallel penetrate through the mounting holes; the protective pipe (1) is sleeved on the outer sides of the plurality of flow channel pipe bodies (3) and the plurality of groups of single magnetic pole magnetization processing parts, and a preset gap is formed between the protective pipe and the flow channel pipe bodies.

2. The mass flow single-pole flat runner magnetizer according to claim 1, wherein the magnetic conductive clamp (51) is a U-shaped clamp formed by punching a pure iron plate, two magnetic blocks (52) are fixed on two vertical surfaces of the inner side of the U-shaped clamp, and a mounting gap is formed between the two magnetic blocks (52), and the flat tube segment (31) is located in the mounting gap.

3. The mass flow single-pole flat runner magnetizer of claim 2, wherein the magnetic block (52) is a rectangular magnetic block and is machined from neodymium iron boron high magnetic.

4. The mass flow single-pole flat runner magnetizer according to claim 2, wherein two of the oppositely arranged magnetic blocks (52) are positive magnetic pole magnetic blocks or negative magnetic pole magnetic blocks.

5. The high-flow single-magnetic-pole flat flow channel magnetizer according to claim 1, wherein the mounting parts (2) are arc-shaped mounting plates, and the concave arc-shaped surfaces of the two mounting parts (2) are arranged oppositely.

6. The high-flow single-magnetic-pole flat runner magnetizer according to claim 1, wherein the protecting tube (1) is made of stainless steel, and the wall thickness is 1.0mm-1.2mm.

7. The high-flow single-pole flat runner magnetizer according to claim 1, wherein the runner tube body (3) is a flat tube section (31) with an oval cross section formed by machining the middle of a stainless steel round tube.

8. The magnetizer of large flow rate single magnetic pole flat flow channel according to claim 1, wherein the end of the protection tube (1) is integrally connected with a sealing plate and is located outside the installation part (2), and the through hole in the middle of the sealing plate is a flow channel hole.

9. The magnetizer of claim 8, wherein six inner-tooth stainless steel pipe joints (4) are correspondingly welded outside the flow passage holes.

10. The mass flow single-pole flat flow channel magnetizer according to any one of claims 1 to 9, wherein the multiple sets of single-pole magnetization processing parts are 3-10 sets, each set having 3-24 single-pole magnetization parts (5).

Images