阅读说明：本技术 一种用于流体燃料的磁电离装置 (Magnetic ionization device for fluid fuel ) 是由 王睿睿 于 2021-08-24 设计创作，主要内容包括：本发明公开了一种用于流体燃料的磁电离装置,包括永磁体和壳体,所述的壳体内设有极靴,所述的极靴一侧通过中央腹板将壳体内部分为两个对称的容纳单元,所述的容纳单元内分别设有永磁体。本发明结构简单,通过设置两组磁电离装置,并利用不同磁电离装置中永磁体的磁极分布,使得管道横截面上产生均匀的磁力线,进而贯穿管道并对燃料起作用,使用效果可靠。本发明安装方便,不需要停产拆管安装,不影响正常使用,且安装更加安全。磁电离的结构不需要配备复杂的电气装置,也不需要为此提供电源,降低使用成本。本发明应用到流体燃料锅炉管道上后,将燃料进行电离后能够节省流体燃料,更快地达到工作温度,更均匀地运行,提升燃烧效率。(The invention discloses a magnetic ionization device for fluid fuel, which comprises a permanent magnet and a shell, wherein a pole shoe is arranged in the shell, one side of the pole shoe divides the interior of the shell into two symmetrical containing units through a central web plate, and the containing units are respectively internally provided with the permanent magnet. The invention has simple structure, and the two groups of magnetic ionization devices are arranged, and the magnetic poles of the permanent magnets in the different magnetic ionization devices are distributed, so that uniform magnetic lines of force are generated on the cross section of the pipeline, and then the pipeline is penetrated and the fuel is acted, and the use effect is reliable. The invention has convenient installation, does not need to stop production and disassemble the pipe for installation, does not influence normal use, and has safer installation. The magnetic ionization structure does not need to be provided with a complex electric device, and a power supply is not needed to be provided for the magnetic ionization structure, so that the use cost is reduced. After the ionization type fluid fuel boiler is applied to a fluid fuel boiler pipeline, the ionization type fluid fuel boiler can save the fluid fuel after ionizing the fuel, can reach the working temperature more quickly, can run more uniformly, and can improve the combustion efficiency.)

1. The magnetic ionization device for the fluid fuel comprises a permanent magnet and a shell and is characterized in that a pole shoe is arranged in the shell, one side of the pole shoe divides the interior of the shell into two symmetrical containing units through a central web plate, and the containing units are internally provided with the permanent magnet respectively.

2. A magnetic ionization device for fluid fuels according to claim 1, wherein the housing comprises an upper housing component and a lower housing component, the lower housing component having a V-shaped configuration on one side.

3. A magnetic ionization device for fluid fuels according to claim 1, wherein the pole piece includes a horizontal plate and a swash plate, the swash plate being parallel to the inclined surface on the side of the housing.

4. A magnetic ionization device for fluid fuels according to claim 3, characterized in that the pole shoes are made of magnetically shielded steel plates with a thickness set at 7 mm.

5. A magnetic ionization device for fluid fuels according to any of claims 1 to 4, characterized in that the magnetic ionization device is installed on a pipeline of a fluid fuel boiler in which fluid fuel is disposed.

6. A magnetic ionization device for fluid fuels according to claim 5, characterized in that it is installed between the duct of a fluid fuel boiler and the burner.

7. A magnetic ionization device for fluid fuel according to claim 5, wherein two magnetic ionization devices are provided, and one side is connected by a hinge; the other side of the magnetic ionization device is detachably connected.

8. A magnetic ionization device for fluid fuels according to claim 7, wherein the longitudinal axis of the permanent magnet is perpendicular to the tangent of the conduit, and the magnetic lines of force generated by the permanent magnet are directed toward the central longitudinal axis of the conduit.

9. A magnetic ionization device for fluid fuels according to claim 7, characterized in that the N pole of the permanent magnet in the magnetic ionization device is directed to the surface of the pipeline, and the S pole of the permanent magnet in the corresponding position in the other magnetic ionization device is directed to the surface of the pipeline.

Technical Field

The invention relates to the technical field of magnetic ionization devices, in particular to a magnetic ionization device for fluid fuel.

Background

The use of an electromagnetic or ferromagnetic magnetic field on a pipeline carrying fluid fuel can magnetically ionize the fluid fuel. This changes the arrangement of the hydrocarbon molecules in the fuel. During ionization, ions are formed by separating and/or attaching one or more electrons to a neutral atom or molecule. In the case of separation, the ions formed are positively charged. In the case of attachment, it is negatively charged, depending on whether electrons are detached or attached. Ionization occurs on the basis of field ionization, the strongly inhomogeneous field releasing electrons bound in an electric/magnetic manner from its binding potential. By separating the ions, the hydrocarbon molecules are positively charged so that the naturally negatively charged oxygen can be attracted with less energy.

The devices currently on the market for generating magnetic fields are very expensive and, since the fluid fuel pipes, usually pressure-resistant steel pipes, absorb substantially all the magnetic lines of force of the iron permanent magnets, it is necessary to generate correspondingly strong electromagnetic fields by electrical means and to equip them with a high-power supply. And the magnetic poles act through a repulsive magnetic field, so that the magnetic line of force cannot achieve the expected target of the magnetized fuel. The prior art mainly stops production, and the pipeline is broken to be installed, so that the production is influenced, and potential safety hazards exist.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a magnetic ionization device for fluid fuel, which utilizes the layout of a permanent magnet to generate uniform attractive magnetic wires and improve the ionization effect of materials; the additional cost is not required to be increased, the installation is convenient and fast, and the safety is high.

In order to achieve the purpose, the invention adopts the technical scheme that:

the utility model provides a magnetic ionization device for fluid fuel, includes permanent magnet and casing, the casing in be equipped with the pole shoe, pole shoe one side through central web with the inside holding unit that divide into two symmetries of casing, holding unit in be equipped with the permanent magnet respectively.

Furthermore, the shell comprises an upper shell component and a lower shell component, and one side of the lower shell component is of a V-shaped structure.

Furthermore, the pole shoe comprises a horizontal plate and an inclined plate, and the inclined plate is parallel to the inclined surface on one side of the shell.

Further, the pole shoe is made of a steel plate with a magnetic shielding function, and the thickness of the pole shoe is set to be 7 mm.

Furthermore, the magnetic ionization device is arranged on a pipeline of the fluid fuel boiler, and fluid fuel is arranged in the boiler pipeline.

Further, the magnetic ionization device is arranged between the pipeline of the fluid fuel boiler and the combustor.

Furthermore, two magnetic ionization devices are arranged, and one sides of the two magnetic ionization devices are connected through a hinge; the other side of the magnetic ionization device is detachably connected.

Furthermore, the longitudinal axis of the permanent magnet is perpendicular to the tangent line of the pipeline, and the magnetic force lines generated by the permanent magnet point to the central longitudinal axis of the pipeline.

Furthermore, the N pole of the permanent magnet in the magnetic ionization device points to the surface of the pipeline, and the S pole of the permanent magnet at the corresponding position in the other magnetic ionization device points to the surface of the pipeline.

The invention has the following beneficial effects:

1. the invention has simple structure, and the two groups of magnetic ionization devices are arranged, and the magnetic poles of the permanent magnets in the different magnetic ionization devices are distributed, so that uniform magnetic lines of force are generated on the cross section of the pipeline, and then the pipeline is penetrated and the fuel is acted, and the use effect is reliable.

2. The invention has convenient installation, does not need to stop production and disassemble the pipe for installation, does not influence normal use, and has safer installation. The magnetic ionization structure does not need to be provided with a complex electric device, and a power supply is not needed to be provided for the magnetic ionization structure, so that the use cost is reduced.

3. After the ionization type fluid fuel boiler is applied to a fluid fuel boiler pipeline, the ionization type fluid fuel boiler can save the fluid fuel after ionizing the fuel, can reach the working temperature more quickly, can run more uniformly, can improve the combustion efficiency, can effectively reduce the emission of carbon monoxide, hydrocarbon and nitric oxide, can reduce carbon deposition, can prolong the service life of a combustion device, and can increase the flame temperature of the combustion device.

Drawings

FIG. 1 is a front view of the present invention;

FIG. 2 is a top view of the present invention;

FIG. 3 is a bottom view of the present invention;

fig. 4 is a schematic view of the apparatus in an operating state after it has been connected to a pipeline 11.

Description of reference numerals:

module a, module B, lower housing part 1, upper housing part 2, edge 3, pole shoe 4, permanent magnet 5, permanent magnet longitudinal axis 9, pipe center longitudinal axis 10, pipe 11, pipe cross section 12, magnetic lines of force 13, annular groove 14, silicone compound 16, groove 18, central web 19.

Detailed Description

For a better understanding of the present invention, reference is made to the following further description taken in conjunction with the accompanying drawings. It is noted that in the description of the present invention, the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Example 1

A magnetic ionization device for fluid fuel, as shown in fig. 1-3, comprising a permanent magnet 5 and a casing, wherein the permanent magnet 5 is a rare earth permanent magnet made of neodymium-iron-boron (NdFeB). Rare earth permanent magnets have much higher flux densities than ferromagnets, and the surface field of the present invention is on the order of 11000 to 12000 gauss. The rare earth permanent magnet generates an attractive magnetic field and the generated magnetic line of force is favorable for ionizing the materials.

The shell comprises an upper shell component 2 and a lower shell component 1, wherein one side of the lower shell component 1 is of a V-shaped structure. The upper housing part 2 and the lower housing part 1 are made of engineering plastic ABS or PC/ABS.

A pole shoe 4 is arranged in the shell and used for shielding a permanent magnet 5 from the outside. The pole piece 4 is bonded to the upper housing part 2 by a suitable amount of silicone compound 16.

The pole shoe 4 comprises a horizontal plate and an inclined plate, and the inclined plate is parallel to the inclined surface on one side of the shell. The pole shoe 4 is made of a steel plate with a magnetic shield, and the thickness of the pole shoe is set to be 7 mm. The relative mounting positions of the pole piece 4 and the permanent magnet 5 are such that the permanent magnet longitudinal axis 9 is perpendicular to the tangent of the pipe 11.

One side of the pole shoe 4 divides the interior of the shell into two symmetrical containing units through a central web plate 19, and the central web plate 19 can play a role in separating and strengthening the strength of the shell. Permanent magnets 5 are respectively arranged in the containing units, and one sides of the permanent magnets 5 are bonded on the pole shoes 4.

The length of the permanent magnet 5 can be seen in fig. 3, which is less than the length L of the entire housing. The strength of the magnetic field that can be created by varying the cross-sectional area and/or length of the permanent magnet 5 can be varied.

Example 2

On the basis of embodiment 1, as shown in fig. 4, the magnetic ionization device is installed on a pipeline 11 of a fluid fuel boiler, and fluid fuel is arranged in the boiler pipeline 11, and the fluid fuel includes oil or natural gas. The magnetic lines of force 13 generated by the permanent magnets 5 can pass through the pipe 11 and form a uniform attractive magnetic field with the magnetic lines of force 13 over the pipe cross-section 12.

Pipeline 11 adopt the steel pipe, the magnetic ionization device can adsorb on pipeline 11. The magnetic ionization device is arranged between the pipeline 11 of the fluid fuel boiler and the burner.

When the fluid fuel boiler is an oil-fired boiler, the magnetic ionization device is arranged in front of the oil filter or between the oil filter and the burner nozzle; when the fluid fuel boiler is a gas boiler, the magnetic ionization device is arranged in front of a burner nozzle on a gas pipeline.

The two magnetic ionization devices are respectively a module A and a module B. One side of each magnetic ionization device is connected through a hinge, so that the module A and the module B are connected with each other, and the transportation and the installation are convenient.

The other side of the magnetic ionization device is detachably connected. The lower shell component 1 is provided with a transverse annular groove 14, the edge of the upper shell component 2 is provided with a groove 18, the binding belt is wound on the annular groove 14, and the other end of the binding belt is positioned in the corresponding groove 18.

After the modules A and B are installed on the pipeline 11, the permanent magnet longitudinal axis 9 generated by the permanent magnets in the modules points to the pipeline central longitudinal axis 10, the permanent magnet longitudinal axis 9 and the pipeline central longitudinal axis 10 intersect and form a corresponding angle with each other, and the angle can ensure that the N pole and the S pole are distributed on two sides of the fluid pipeline 11, so that magnetic lines of force 13 form a net-shaped structure on the pipeline cross section 12.

The N pole of the permanent magnet in the module A points to the surface of the pipeline 11, and the S pole of the permanent magnet in the module B points to the surface of the pipeline 11. Because the two modules have different poles pointing towards the pipe 11, an attractive magnetic field is generated that penetrates the pipe 11.

On the one hand, such an attractive magnetic field leads to a correspondingly strong ionization of the hydrocarbon molecules. On the other hand, a certain attractive force is generated between the two modules. If the pipe 11 is made of steel, this attraction force increases significantly.

Even if the pipeline 11 is made of a steel pipe, and the wall of the steel pipe has a shielding effect, the magnetic force formed in the pipe by the device is enough to establish enough magnetic flux density in the cross section 12 of the pipeline to meet the use requirement.

The magnetic ionisation device is fixed to the pipe 11 so as to cause ionisation of the fuel passing through the cross-section of the pipe 11 when subjected to an attractive permanent magnetic field.

In use, module a is on the upper side of the duct 11 and module B is on the lower side of the duct 11. The N pole of the permanent magnet 5 in module a is directed towards the pipe 11, while the S pole of the permanent magnet 5 in module B is directed towards the pipe 11. Namely, magnetic lines of force 13 from the north pole at the upper left corner of the module a to the south pole at the lower right corner of the module B and magnetic lines of force 13 from the north pole at the upper right corner of the module a to the south pole at the lower left corner of the module B are generated, so that the magnetic lines of force 13 distributed uniformly are generated on the cross section 12 of the pipeline 11. The magnetic pole layout of the permanent magnet 5 results in that the magnetic field lines 13 are almost rectilinear between the N-pole and the S-pole, so that the magnetic field lines 13 coincide with the pipe cross-section 12, i.e. perpendicular to the fluid fuel flow direction, and more effectively produce an ionization when the molecules pass through this section of the magnetization cross-section.