WO1995001835A1 - Fluid activating apparatus - Google Patents

Abstract

This invention relates to a fluid activating apparatus consisting of a plurality of continuously connected unit ceramic magnetic bodies (3) each of which is composed of a molded ceramic member (2), and magnets (1, 1') provided on both sides of the ceramic member. In this apparatus, an attractive magnetic field Ma or a repulsive magnetic field Mr or a complicated magnetic field in which attractive and repulsive magnetic fields exist in a mixed state is formed in each portion thereof by selectively arranging the polarities of the magnets, and a fluid is activated by giving the fluid a synergetic effect of the radiation of lines of magnetic force from this magnetic field and that of far infrared rays from the molded ceramic member (2). Especially, when rings are inserted between the continuously connected ceramic magnetic bodies (3) so that adjacent ceramic magnetic bodies (3) do not contact each other with a distance therebetween kept minimum, it is possible to greatly increase the magnetic flux density of the lines of magnetic force of the ceramic magnetic bodies (3), improve the fluid activating capacity, cut off the chained molecules of the fluid, make the actions of the molecules active, and produce an activated fluid.

Description

 Description Fluid Activator Technical Field

 The present invention relates to a fluid activating device for generating a magnetic field for activating a fluid and using the far-infrared ray together with the fluid to activate a fluid such as a gas or a liquid. The present invention relates to a fluid activating device capable of quickly and efficiently activating a fluid fuel such as a liquid or a gas or activating various industrial waters and agricultural waters. Background art

In general, liquid fuels such as heavy oil, oil, kerosene, gasoline, and alcohol are used in internal combustion engines or other combustion devices. These liquid fuels are hydrocarbon-based liquid fuels and are organic liquids in which unit molecules are bonded. This type of molecule has a relatively large particle size, about 50 to 100 microns, and usually contains a relatively large population of water molecules. In addition, the area where a unit molecule comes into contact with oxygen in the air must be quite small. As a result, the combustion reaction of the fuel unit molecules becomes insufficient, causing incomplete combustion. As a result, poor combustion efficiency increases fuel consumption, and carbon monoxide, hydrocarbons, lead compounds, nitrogen oxides, and soot-like harmful fine particles are released into the atmosphere as exhaust gas. It is actually extremely difficult to improve internal combustion engines and the like to remove these harmful substances, and no satisfactory improvement has been achieved at present. Also, gaseous fuels such as city gas, propane gas, natural gas or other liquefied gas burn relatively efficiently compared to the above-mentioned liquid fuels, and emit harmful emissions. The amount of generation is also small. However, with regard to such fuels, further improvement of combustion efficiency and purification of exhaust gas are required from the viewpoint of environmental protection and effective use of energy.

 Water used for household, industrial, agricultural and fishery purposes as a fluid other than fuel can achieve each purpose of use more effectively by activation.However, activation of water, improvement of water quality, There is no simple and efficient fluid activation device that effectively works to promote the purification of wastewater.

 In view of such a situation, the present invention activates various fluids such as gas or liquid fuel or water in a short or instantaneous manner with a simple structure, and realizes functions, actions or targets required for various fluids. It is an object of the present invention to provide a highly efficient fluid activating device that can be fully utilized. Disclosure of the invention

 The fluid activation device according to the present invention activates a fluid at a unit molecular level as a result of radiation of magnetic field lines and far-infrared radiation, or radiation of highly enhanced magnetic field lines. The liquefied liquid fuel reduces harmful emissions in the exhaust gas due to combustion, reduces and prevents environmental pollution, and improves combustion efficiency. It is used to promote the improvement and purification of plants, promote the growth of animals and plants, promote the health of the human body, and when used as water for the production of chemicals, drugs, foods, etc. Reaction, mixing and aging with other gases or liquids are greatly accelerated.

The activation device of the present invention uses a ceramic magnetic body as a minimum unit, and the ceramic magnetic body is composed of a disk-shaped, tubular or annular ceramic molded body, and a disk-shaped, tubular or annular magnet. The magnets are located on both sides of the ceramic compact and the magnets are in a mutually attracting or mutually attracting relationship. The magnets are arranged in a repulsive relationship and form an attraction magnetic field or a repulsive magnetic field in the ceramic molded part between the magnets.

 When a ceramic magnetic body prepared in this way is arranged in series to obtain an apparatus, the magnetic field formed in the ceramic molded body and the magnetic field formed between the ceramic magnetic bodies are different. It is desirable to arrange the magnetic field so that an attractive magnetic field is formed and a repulsive magnetic field is formed between the ceramic magnetic bodies. The purpose of such an arrangement is to form an intricately cooperative and complex magnetic field by mixing the attracting magnetic field and the repulsive magnetic field. Therefore, contrary to the above arrangement, the repulsive magnetic field is applied to the ceramic molded body. Alternatively, an arrangement in which an attraction magnetic field is formed between ceramic magnetic bodies, or an arrangement in which this arrangement and the above arrangement are mixed can be used.

 The ceramic molded body of such a ceramic magnetic material emits far-infrared rays, and the magnet emits strong lines of magnetic force due to a complex magnetic field in which an attractive magnetic field and a repulsive magnetic field are mixed. The various fluids to be activated pass through the magnetic field formed by the ceramic magnetic material or come into direct contact with the ceramic magnetic material. This is the same regardless of whether the activation device is installed in the fluid flow passage or when the activation device is immersed in the stored fluid. As a result, the fluid is activated by the action of radiating the magnetic field lines of the ceramic magnetic body and the far-infrared radiation action of the ceramic molded body.

 Due to the synergistic action of the magnetic field lines and the far-infrared radiation, the constituent molecules of the fluid are excited and vibrate, and magnetic induction energy is given. Is done. As a result, a highly reactive fluid can be obtained.

The present invention further provides a fluid activation device provided with an amplifying means having a density per hour. The magnets are arranged in phase and in series to attract each other, and an intervening member is installed between the magnets or magnets. The interposition members are magnets on both sides. Separate and concentrate the attractive magnetic field between the magnets to generate a stronger magnetic field. It is desirable to use a ceramic molded body also as the interposition member, but the material of the interposition member is not limited to the ceramic molded body and is arbitrary.

 According to the fluid activation device having such a magnetic flux density amplifying means, the improvement rate of the magnetic flux density obtained by simply connecting the magnets is 10% to 20%, Since an extremely large improvement rate of the magnetic flux density of 200 to 300% with respect to the magnetic flux density can be obtained, a small and highly efficient fluid activation device can be obtained. BRIEF DESCRIPTION OF THE FIGURES

 FIG. 1 is an internal explanatory view of the first embodiment of the present invention, FIGS. 2 and 3 are explanatory views showing two types of arrangement of the ceramic magnetic bodies of the embodiment of FIG. 1, and FIG. FIGS. 5 and 6 are front views of the ceramic magnetic body used in the embodiment, and are explanatory diagrams of the case where the embodiment of FIG. 1 is installed in a fuel tank and a case where the embodiment is installed in a fuel feeding path.

 FIG. 7 is an internal explanatory view of the second embodiment of the present invention, and FIGS. 8 and 9 are explanatory views showing two types of arrangement of the ceramic magnetic material of the second embodiment. FIG. 10 is an explanatory diagram showing a first modification of the first and second embodiments, and FIG. 11 is an explanatory diagram showing a second modification of the first and second embodiments.

 FIG. 12 is a cross-sectional view showing a third embodiment of the present invention, FIGS. 13 and 14 are front and side views of a magnet used in the third embodiment, FIGS. FIG. 16 is a front view and a side view of a ceramic tube used in the third embodiment, and FIG. 17 is a cross-sectional view of a modification of the third embodiment.

FIG. 18 is a cross-sectional view of a fourth embodiment of the present invention, FIGS. 19 and 20 are explanatory views showing two types of arrangement of ceramic magnetic bodies used in the fourth embodiment, FIG. 21 is a cross-sectional view showing a modification of the fourth embodiment.

 FIG. 22 is a cross-sectional view of the fifth embodiment of the present invention.

 FIG. 23 is a plan view of a sixth embodiment of the present invention, and FIG. 24 is a cross-sectional view taken along line II of FIG.

 FIG. 25 and FIG. 26 are cross-sectional views showing further modifications of the sixth embodiment.

 FIG. 27 is an internal explanatory view of the seventh embodiment of the present invention, and FIGS. 28, 29 and 30 are enlarged cross-sectional views of essential parts showing a modification of the seventh embodiment.

 FIG. 31 is a front view of a magnet group in which magnets having protrusions are attracted and connected, FIG. 32 is a partial internal explanatory view of an eighth embodiment of the present invention, and FIG. 33 is used in the eighth embodiment. FIG. 3 is a plan view of an interposition ring.

 Fig. 34 Fig. 35 Fig. 36 and Fig. 37 are explanatory diagrams showing the magnet group arrangement for amplifying the magnetic flux density used in the ninth embodiment of the present invention, and Fig. 38 is Fig. 37. It is an internal explanatory view of the ninth embodiment of the present invention using the magnet group shown in the figure. Fig. 39 is a graph comparing the far-infrared wavelength and emissivity of ceramics with those of other materials. BEST MODE FOR CARRYING OUT THE INVENTION

 As a premise for describing a plurality of preferred embodiments of the present invention with reference to the accompanying drawings, properties and compositions of a magnet and a ceramic molded body used in the present invention are generally as follows.

 1. Magnet

 Type Samarium cobalt magnet

 Magnetic flux density 1,800 Gauss (G)

As the magnet, other than this, for example, a magnet such as neodymium or ferrite may be used. Should be activated The type of magnet, magnetic flux density, etc. can be selected according to the target. A magnetic flux density of 1,000 to 5,000 G is appropriate. 2. Composition of ceramic molded body (% by weight) First example Fired white porcelain 100% Silicon oxide 14 79% Alumina oxide 70 14% Titanium oxide 1 09% Calcium oxide 3 39% Magnesium oxide 0 33% Potassium oxide 0 58% Oxidation Sodium 0 12% 2nd example Silica 55.00% Alumina oxide 40.00% Alkyri 2.50% Iron oxide 0.80% Each of the ceramics in the 1st and 2nd examples is about 1,20 CTC It is a fired composition. First embodiment

 1 to 6 show a first embodiment of the present invention.

The fluid activation device 10 shown in FIG. 1 has a plurality of openings along the axial direction. An outer cylinder 6 provided with 7 and a plurality of ceramic magnetic bodies 3 arranged in the outer cylinder 6 are provided. The outer cylinder 6 includes a cylindrical main body, and closing members 8.8 for closing both ends of the main body. One end of a chain 9 is connected to one closing member 8. The opening 7 is formed in the peripheral wall of the outer cylinder 6 at an appropriate interval, and allows the inside and the outside of the outer cylinder 6 to communicate with each other.

 The outer cylinder 6 is formed of a non-magnetic material, and the material is preferably an aluminum-based material, a stainless-based material, or the like. However, an iron-based or synthetic resin-based material can be arbitrarily selected according to the kind or property of the object to be activated.

 As shown in FIGS. 2 and 3, a ceramic magnetic body 3 having magnetic poles arranged on the outer cylinder 6 is arranged in series in the axial direction of the outer cylinder 6 at an appropriate interval. As shown in Fig. 4, it is composed of a disc-shaped ceramic molded body 2 made of a non-magnetic material, and disc-shaped magnets 1 • 1 ′ arranged on both sides of the ceramic molded body. The ceramic molded body 2 is made of, for example, the composition of the above-mentioned second example, and a circular recess capable of partially accommodating the magnets 1 1 ′ is formed in the center of the side surface of the disk on both sides thereof. The magnets 1 and 1 ′ are permanent magnets of the type indicated by the above “magnet”, and are installed in the respective recesses of the ceramic molded body 2. In this way, the central axis of the ceramic magnetic bodies 3 arranged in series is aligned with the central axis of the outer cylinder 6 of the fluid activation device 10.

 FIG. 2 and FIG. 3 illustrate an arrangement of two types of ceramic magnetic bodies 3 used in the present invention.

In the arrangement shown in Fig. 2, the poles of magnets 1 and 1 'on the left ceramic magnetic body 3 are arranged in the order of S, N, S, and N, and are sandwiched between two magnets 1 and 1'. An attraction magnetic field Ma is generated in the portion of the ceramic molded body 2. Further, regarding the ceramic magnetic body 3 on the right side of FIG. 2, the poles are arranged in the order of N, S, N, S, and the attractive magnetic field Ma is also generated in the ceramic molded body 2. When these two members are adjacent to each other as shown in Fig. 2, the arrangement of the poles of the two ceramic magnetic bodies 3 and 3 is S'N'S'N-ΝSNSNS and the ceramic magnetic bodies 3 and 3 During this period, a repulsive magnetic field Ma is generated. This shows the case where the repulsive magnetic field M r is generated by the N poles facing each other, but the one shown in Fig. 3 has an attractive magnetic field Ma in the ceramic molded body 2 part, It is shown that a repulsive magnetic field Mr is generated when the S poles face each other between the ceramic magnetic bodies 3.

 The placement of the magnets 1 and 1 'on the ceramic molded body 2 can be achieved by an appropriate fixing means or an adhesive means in addition to the attracting action of the magnets. At the adjacent portions of the ceramic magnetic body 3 shown in FIGS. 2 and 3, as shown, the magnetic field alternates with “attraction magnetic field” Ma, “repulsive magnetic field” Mr and “attraction magnetic field” Ma. By installing a plurality of such ceramic magnetic materials 3 as shown in Fig. 1, a complex magnetic field in which the attracting magnetic field Ma and the repulsive magnetic field Mr are concentrated and mixed in a very limited space will be generated. Will be obtained. Further, each magnetic field may be mixed irregularly.

 Magnets 1 and 1 'are arranged so that the positions of the attraction magnetic field Ma and the repulsive magnetic field M r are switched as necessary, and the repulsive magnetic field Mr is applied to the ceramic molded body 2 and the attraction is applied between the ceramic magnetic substances 3 and 3. It is optional to generate the magnetic field Ma, and in this case, the ceramic magnetic material 3 attracts each other, so that the assembling work of the fluid activation device becomes easier.

The ceramic molded body 2 is not limited to the composition described above, and various ceramic compositions such as a carbon-based system and a glass system can be used. FIG. 5 shows a specific situation when the fluid activation device 10 is directly applied to the fuel tank T. In this case, the other end of the chain 9 connected to the fluid activation device 10 is fixed to the opening cap I of the fuel tank T, and the fluid activation device 10 is immersed in the liquid fuel F in the fuel tank T. ing. The liquid fuel F flows into and out of the fluid activation device 10 through the opening 7 on the side surface of the fluid activation device 10, and the liquid fuel F is activated.

 The part shown as fuel tank F is not necessarily limited to fuel tanks for various automobiles, combustion engines, etc., and storage tanks for water, alcoholic beverages, food, chemicals, chemicals, etc., reaction tanks, water tanks, or Of course, it can be applied to all types of tanks used for fish farming tanks, hydroponics tanks, and the like.

 FIG. 6 shows a specific situation when the fluid activating device 10 is interposed in the fluid flow path. The drawing shows a situation in which the device of the present invention is interposed in a delivery pipe P of a fluid sent from a fluid source S to a fluid consuming unit C. If an automobile is taken as an example, the fluid source S Is the fuel tank, fluid consuming section C is the engine, and delivery pipe P is the fuel supply pipe. In such a situation, the fluid activation device 10 is accommodated in the fluid activation tube E connected to the delivery tube P, and the fluid from the fluid source S is brought into contact with the fluid activation device to activate the fluid. Is done quickly.

 As described above, according to the present invention, the fluid is instantaneously activated by the synergistic effect of the complicated complex magnetic field in which the attractive magnetic field Ma and the repulsive magnetic field Mr are mixed and the characteristic action of the far infrared radiation by the ceramic molded body 2. You.

In addition, when a driving test was conducted by applying the device of the present invention to a gasoline tank of an automobile, the gasoline consumption was reduced by more than 25% compared with a case where the device was not used, and harmful substances in exhaust gas were reduced. Emissions were confirmed to decrease by about 30%. 0 Second embodiment

 The second embodiment will be described with reference to FIGS. 7 to 11.

 The fluid activating device 20 shown in FIG. 7 has a hollow cylindrical outer cylinder 26 provided with closing members 28 and 28 at both ends, and is arranged in series at an appropriate interval in the outer cylinder 26. A fixed ceramic magnetic body 3 is provided. The point that the ceramic magnetic body 3 is composed of the ceramic molded body 2 and the magnets 1 and 1 'is the same as in the first embodiment. The ceramic molded body 2 used is the one shown in the second example of the above-mentioned composition table, and the magnet is of the type shown in the item of “magnet” above. The magnets 1 · 1 ′ are installed on both sides of the ceramic molded body 2 by using mutual attraction, but an appropriate fixing means may be provided as necessary. The states of generation of the attracting magnetic field M a and the repulsive magnetic field M r are exactly the same as those in the first embodiment. The difference from the first embodiment is that the ceramic molded body 2 has the magnet 1 or 1 ′ partially. Not having a concave portion for inwardly indenting, a point that the closing member 28 of the outer cylinder 26 is provided with a connecting portion 29 for connecting the fluid delivery pipe P, and the magnets 1 and 1 '. The point is that circular openings 4 and 5 are formed in the center of the ceramic molded body 2.

 In this embodiment in which the ceramic magnetic body 3 is fixed to the inner wall as described above, the fluid supplied to the outer cylinder 26 by the delivery pipe P mainly passes through the circular openings 4.5. It reaches P, and in the meantime, it passes through the complicated magnetic field of the attractive magnetic field M a and the repulsive magnetic field M r and is instantaneously activated.

 The arrangement of the attraction magnetic field Ma and the repulsive magnetic field Mr of the ceramic magnetic body 3 used in the present embodiment is as shown in FIGS. 8 and 9, which also shows the positions of the attraction and repulsion. It is the same as in the first embodiment that the state can be set to the exchanged state.

The feature of the structure shown in this embodiment is that the fluid activation tube E in the first embodiment can be omitted. FIG. 10 and FIG. 11 are explanatory views showing deformations produced by combining the first embodiment and the second embodiment. In this example, the magnets 1 and 1 'are made of ceramics. It is partially recessed and held in the recess of the body 2 and is spaced at appropriate intervals through a tubular spacer 22 on a spindle 22 extending through the circular openings 4.5. Each ceramic magnetic body 3 and the support shaft 22 are fixed to the body by bolts 24 screwed to both ends of the hollow support shaft 22. The magnetic field may be selected arbitrarily, but in the case of the illustrated example, an attractive magnetic field M a is formed in the ceramic molded body 2 and a repulsive magnetic field M r is formed between the ceramic magnetic bodies 3. The poles of each magnet 1 · 1 'are aligned.

 The fluid activating device 20 shown in FIG. 10 is an exposed type device without a coating, and may be used as it is depending on the application.For example, as shown in FIG. It is housed in an outer cylinder 26 having a long hole or other opening (both not shown), and a tune 29 9 ′ is attached to one of closing members 28 ′ fixed to both ends of the outer cylinder 26. And may be used in the same manner as in the first embodiment.

 According to the results of a driving experiment in which the second embodiment was applied to the fuel system of an automobile, fuel consumption was reduced by about 25%, and nitrogen oxides in exhaust gas were reduced by about 30%. Was done. Third embodiment

 A third embodiment of the present invention will be described with reference to FIGS.

In the fluid activation device 30 shown in FIG. 12, a ceramics magnetic body 3 is formed by a magnet 1 ′ having a center hole 4 and a tubular ceramic molded body 2 having a through hole 5. The plurality of ceramic magnetic bodies 3 are accommodated in a tube 32 made of a nonmagnetic material, for example, a stainless steel tube. The pipe 32 has a small diameter portion (left end in FIG. 12) for insertion into the delivery pipe P for the fluid to be activated, and is liquid-tight to the delivery pipe P from a fluid source, for example, through an appropriate sealing means. The connection pipe 33 fitted to the other end of the pipe 32 is fitted into the other end of the pipe 32, and the inserted connection pipe 33 is connected to the ceramics in the pipe 32. The fixed position of the magnetic body 3 is fixed, and the magnetic body 3 is connected to, for example, a pipe P toward a fluid consuming section via a suitable sealing means. A ceramic magnetic body 3 is formed by the ceramic molded body 2 and the magnets 1 • 1 ′ shown in FIGS. 13 to 16 in FIG. A fluid passage 31 is formed in 32.

 As shown in FIG. 12, in the description of the present embodiment, the orientation of the magnetic poles is determined so that the magnets 1 and 1 ′ installed on both sides of the ceramic molded body 2 attract each other. The two portions are provided such that an attractive magnetic field M a is generated and a repulsive magnetic field M r is generated between the adjacent ceramic magnetic bodies 3. As a result, as in the previous embodiments, the fluid in contact with the present embodiment passes through a complex magnetic field in which the attractive magnetic field Ma and the repulsive magnetic field M r are intricate, and the fluid is instantaneously activated.

 In this embodiment as well, the magnetic field arrangement can be freely selected, and the arrangement of the attractive magnetic field Ma and the repulsive magnetic field Mr may be arbitrarily determined.

 FIG. 17 shows a modification of the third embodiment. In this modification, the inner diameter of the center hole 4 of the magnets 1 and 1 ′ and the through hole 5 of the ceramic molded body 2 correspond to the outer diameter of the delivery pipe P. Therefore, the fluid activation device 30 is arranged on the outer circumference of the delivery pipe P. The ceramic magnetic body 3 is arranged in series around the outer wall of the delivery pipe P, and is housed in a casing 34 fixed to the outer peripheral surface of the delivery pipe P.

The complex magnetic field and the far-infrared radiation in this deformation are transmitted through the delivery pipe P. Act on the fluid to activate the flowing fluid instantaneously. When this deformation is used, the material of the pipe P is arbitrary, but it is preferable that the pipe P is made of a non-magnetic material such as a rubber pipe, a synthetic resin pipe, or a copper pipe. The feature is that it comes with installation without adding.

 When the fluid activation device 30 according to the third embodiment was applied to propane gas fuel, improvement in combustion efficiency and reduction in emission of harmful organic substances were recognized as compared with the conventional case, and favorable results were obtained. Fourth embodiment

 A fourth embodiment of the present invention will be described with reference to FIGS. The fluid activating device 40 shown in FIG. 18 is a tubular magnet 1 having a center hole 4, and a ceramic molded body inserted into the center hole 4 of the magnet 1 and having a through hole 5 itself. It is composed of a ceramic magnetic body 3 composed of 2 as a basic unit. The magnet 1 and the ceramic molded body 2 have the same length, and the ceramic molded body 2 having the through holes 5 is nested inside the magnet 1.

When these ceramic magnetic bodies 3 are connected, the through-holes 5 of the ceramic molded body 2 communicate with each other to form the fluid passages 41, so that the diameter of a part of the delivery pipe P is enlarged to form the bulging portion 48. However, if these ceramic magnetic bodies 3 are connected and installed therein, the fluid activating device 40 can be easily obtained. Since a single magnet 1 is used for these ceramics magnetic bodies 3, the N and S poles of the magnets 1.1 of the two ceramics magnetic bodies 3 are opposed to each other as shown in FIG. As shown in Fig. 19, an attractive magnetic field Ma is generated, and the two ceramic magnetic bodies 3 installed in such a manner are combined into a set, and the N pole of the set faces the other set of N poles. As shown in Fig. 20, a repulsive magnetic field M r is generated, and a complex magnetic field is obtained by them. FIG. 21 shows the deformation of the fluid activation device 40 according to the fourth embodiment, and the positional relationship between the ceramic molded body 2 and the magnet 1 in the fourth embodiment is reversed. In this case, a magnet having a center hole 4 is inserted into a through-hole 5 of the ceramic material 2. In this case, the length of the ceramic molded body 2 is set to be much larger than that of the magnet 1, and a single ceramic molded body 2 is penetrated. A plurality of magnets 1 can be accommodated in the hole 5.

 Also in this modification, the orientation of the magnetic poles of the magnet 1 is determined so that the attracting magnetic field Ma and the repulsive magnetic field Mr are generated alternately, whereby a sufficient complex magnetic field can be obtained. As a further modification, the poles of the magnet 1 are arranged so that the positions of the attracting magnetic field Ma and the repulsive magnetic field Mr are switched, thereby securing a complicated magnetic field, as in the above-described embodiments.

 In this embodiment, since the magnet 1 is surrounded by the ceramic molded body 2 which is a non-magnetic material, a complicated magnetic field is formed in the fluid passage 41 and the fluid activating device 40 is formed by the delivery pipe P. The fluid supplied to the substrate is quickly activated by receiving the radiation of the magnetic field lines due to the complex magnetic field and the radiation of far-infrared rays by the ceramic molded body 2 while passing through the fluid passage 41.

 Also in this embodiment, the type of the magnet and the material of the ceramic molded body may be arbitrarily selected. Fifth embodiment

 A fifth embodiment of the present invention will be described with reference to FIG.

The fluid activation device 50 shown in the present embodiment is composed of a cylindrical casing 52 made of a non-magnetic material and a ceramic magnetic material 3 arranged and housed in series in a casing 52. I have. A closed end 55 is provided at one end of the casing 52, and an opening 56 is formed at the center of the closed end 55, and the other end of the casing 52 is open. Edge at center It is closed by a lid 53 having an opening 54.

 The magnet 1 used in the present embodiment is provided with a center hole 4 force and the ceramic molded body 2 is provided with a through-hole 5. It is inserted into the casing 52 in series from the open end of the casing, and is fixed in the casing 52 by the lid 54.

 Each ceramic magnetic body 3 is composed of a ceramic molded body 2 and magnets 1 and 1 'arranged on both sides thereof, and an opening 56 formed in a closed end 55 of a casing 52 and magnets 1 and'. The center hole 4, the through hole 5 of the ceramic molded body 2, and the opening □ 54 of the lid 53 are aligned almost on the center line of the casing 52, and the fluid passage 51 passing through the fluid activation device 50 is formed. It is formed.

 As is apparent from FIG. 22, an attractive magnetic field M a is formed in the ceramic molded body 2 of each ceramic magnetic body 3, and a repulsive magnetic field M r is formed between the adjacent ceramic magnetic bodies 3. As a result, a complex magnetic field is formed. Also in this embodiment, the arrangement of the attraction magnetic field M a and the repulsion magnetic field M r can be arbitrarily selected.

The fluid activating device 50 according to the present embodiment has a simple and effective structure particularly for activating water, and is ideal for activating running water or water in a receiving vessel, a receiving vessel, or a receiving tank. It is typical. For example, when the fluid activation device 50 with a total length of about 15 cm shown in the embodiment of FIG. 22 is put into an activated water container having a volume of 3 liters, the water quality is improved within about 1 minute, and the chlorine reaction is reduced to zero. At the same time, it was found that the pH of the water was maintained in the neutral range of 6.5 to 7.5, and that organic harmful substances and odors were removed within a few seconds after injection. In the case of this structure, the magnetic flux density of each of the magnets 1 and 1 'used is 1,300 gauss (G), but by incorporating five ceramics magnetic bodies 3 using this magnet, Thus, the magnetic flux density was amplified up to about 95%, and it was found that the emission of strong magnetic field lines and the complicated magnetic field could be secured. This This has made it possible to greatly increase the activation action of a fluid activation device having a fixed volume. Sixth embodiment

 A sixth embodiment of the present invention will be described with reference to FIGS. 23 to 26. The fluid activating device 60 shown in this embodiment is a ceramic magnetic body 3 itself, and circular recesses 2 a are respectively formed on both front and back surfaces of the disc-shaped ceramic molded body 2 so as to face the multi-sided recesses 2 a. The magnet 1 is partially recessed and fixed in each recess 2a.

 As shown in Fig. 24, four sets of eight magnets are fixed to the ceramic molded body 2 as one set of front and back sides, two sets of which are used for the attraction magnetic field Ma, and the other two sets are used for the two sets. The magnetic poles are arranged to generate a repulsive magnetic field M r, thereby generating a complex magnetic field. The placement of the magnet in the ceramic molded body 2 may be performed by utilizing the attraction of the magnet or by using an appropriate fixing means.

 FIGS. 25 and 26 show two modifications of the sixth embodiment. In FIG. 25, the disk-shaped ceramic molded body 2 has four circular through holes 5. Two magnets 1.1 each having a center hole 4 for each of the through holes 5 are inserted, and fixed so that the boundary surface of the two magnets 1.1 matches the center of the through hole 5. I have. It is the same as in the previous embodiments that the four magnets installed in this manner are arranged so as to generate an attractive magnetic field M a and a repulsive magnetic field M r, as in the previous embodiments. As well as being secured, the fluid to be activated can flow through the fluid passage 61 formed by the communication of the central hole 4.

In the modification shown in FIG. 26, opposed recesses 2a are formed on the front and back of the ceramic molded body 2, and a through hole 5 is formed at the center of the recess 2a. The front and back of the ceramic molded body 2 are electrically connected to each other, and a pair of two magnets 1.1 each having a center hole 4 in the recess 2 a on the front and back are partially recessed and fixed, and the center of the magnet 1 is The fluid passage 61 is formed by connecting the hole 4 and the through hole 5 of the ceramic molded body 2, and the fluid can flow through the fluid passage 61 on both the front and back surfaces of the ceramic molded body 2.

 In these examples, the composition and type of the ceramic molded body 2 are arbitrary, and the magnetic flux density of the magnet 1 to be used can be arbitrarily selected and used within a range of 1,000 to 5,000 G. is there. The fluid activating device shown in the sixth embodiment is suitable for being directly used in the stored fluid and used, and it is not possible to obtain a complicated magnetic field by the arrangement of the magnetic poles of the magnet 1 installed. This is exactly the same as in the above embodiment. Seventh embodiment

 A seventh embodiment will be described with reference to FIGS. 27 to 30.

 FIG. 27 shows an example in which the fluid activating device 70 of the present invention is applied to a cylinder B containing liquefied gas, and is schematically a modification of the third embodiment in FIG. It can be considered to be derived from.

 The ceramic magnetic body 3 used in the present embodiment is formed by a tubular magnet 1.1 ′ having a center hole 4 and a tubular ceramic molded body 2 having a through hole 5, and liquefied in a cylinder B. Through-hole in conduit GP inserted in gas G

It is fitted and fixed using 5 and the center hole 4. As the fixing means 71, an adhesive, a metal piece for fixing, a synthetic resin piece for fixing, or the like can be appropriately used. One end of the above-mentioned conduit GP is opened in contact with the liquefied gas G, and the other end is connected to a valve provided with a discharge nozzle J.

In this embodiment, the magnets 1, 1 and 1 are fixed to the conduit GP with the ceramic molded body 2 interposed therebetween. 8 As in the illustrated example, an attractive magnetic field Ma can be generated in the ceramic molded body 2 portion. Further, in some cases, the repulsion magnetic field may be formed in the ceramics molded body 2 part with the polarity opposite to that of the illustrated example.

 The ceramic magnetic material 3 installed in this way activates the liquefied gas G stored in the cylinder B and acts on the liquefied gas G passing through the conduit GP to provide a liquefied gas with high combustion efficiency. I do.

FIG. 28 to FIG. 30 show a modification of the seventh embodiment. In FIG. 28, only the ceramic molded body 2 is attached to the conduit GP, and the far infrared radiation effect of the ceramic molded body 2 is shown. The one shown in Fig. 29 has only a plurality of magnets 1 attached to the conduit GP to give only the magnetic field radiation to the liquefied gas G, and the one shown in Fig. 30 is the one given to the conduit GP. It provides both a far-infrared radiation effect and magnetic field line radiation, and has been devised to achieve miniaturization for incorporating the fluid activation device 70 into a small gas cylinder B. Eighth embodiment

 The eighth embodiment will be described with reference to FIGS. 31 to 33.

 FIG. 31 shows a fluid activation device 80 consisting of a group of magnets in which magnets 1 are attracted and aligned in series by an attractive magnetic field Ma. The magnet 1 has a central hole 4 and a plurality of protrusions 1a at one pole surface at radially equal intervals, and the protrusions a between the magnets connected by the attraction magnetic field Ma. A gap 82 is formed. The center hole 4 of the connected magnet 1 forms the fluid passage 81, and the fluid passage 81 communicates with the outside of the magnet 1 by the gap 82, and the attractive magnetic field M a Its presence will increase the magnetic flux density.

FIG. 32 is a modification of the eighth embodiment shown in FIG. Instead of the gap 82, the gap 82 is set by interposing an interposition ring 85 having a cut-out portion 86, and the ceramic magnetic body formed by the ceramic molded body 2 and the magnets 1 and 1 ' The fluid passage 81 formed by the center hole 4 and the through hole 5 forms a gap between the adjacent ceramic magnetic body 3 by the cutout portion 86 of the interposition ring 85. It is possible to extend the time for the fluid to come into contact with the complicated magnetic field by conducting to the magnetic field 8 and to amplify the magnetic flux density of both the attracting magnetic field M a and the repulsive magnetic field M r by the presence of the gap 8 2. Can be. According to the fluid activation device 80 of the present embodiment, the magnetic flux density of the magnetic field generated by the ceramic magnetic body 3 is as follows. It was measured that the magnetic flux density of the magnet alone was increased by about 40%. Further, it was found that the magnetic flux density could be increased by up to 95% by connecting a plurality of ceramic magnetic bodies 3 in series in the casing E according to the attraction magnetic field Ma.

 The fluid activating device 80 thus constructed has a strong synergistic action between the far infrared rays radiated from the ceramic molded body 2 and the lines of magnetic force radiated from the magnets 1 ′ and 1 ′. The fluid flowing in the gap 82 of 1 and the outer periphery of the magnet 1 · 1 ′ is activated with high efficiency.

 The means for forming the gap 82 is not limited to the protrusion 1a formed on the magnetized surface of the magnet or the interposition ring 85. The flow region can be arbitrarily selected as long as it can expand the flow region and amplify the magnetic flux density. Ninth embodiment

 The ninth embodiment will be described with reference to FIGS. 34 to 38.

FIGS. 34 to 37 are partial explanatory diagrams of a magnet group applicable to the ninth embodiment shown in FIG. This ninth embodiment has a magnetic flux density Is provided with a means for greatly amplifying.

 The magnet 1 used alone in this embodiment is a disc-shaped permanent magnet made of summary cobalt having a magnetic flux density of 2,400 G, a diameter of 17 mm and a thickness of 3 mm. The magnetic pole arrangement of the magnets 1 is set such that adjacent magnets 1 attract each other, whereby a magnet group in which a plurality of magnets 1 are connected in series is formed.

 A stainless steel interposition ring 91 having a diameter of 12 mm and a diameter of 0.8 mm is interposed between the adjacent magnets 1.1 and is sandwiched between the magnets 1.1. Due to the presence of the interposition ring 91, an attractive magnetic field Ma is formed in the gap 92 provided between the magnets 1.

 When the magnetic flux density was measured for two magnets 1.1 shown by solid lines in Fig. 34, the outer end face of each of magnets 1.1 was formed between magnetic flux density 2,750G and magnets 1.1. The magnetic flux density of the magnetic field F in the gap 92 was 2,950 G.

 In the ceramic magnetic body 3 connected in series as shown in FIG. 35, the ceramic magnetic body 3 is composed of a ceramic molded body 2 and magnets 1 installed on both sides of the ceramic molded body 2 so as to generate an attractive magnetic field Ma. It is formed. The ceramic molded body 2 has a diameter of 32 mm and a thickness of 4 mm. Also, the polarity of all magnets is aligned so that an attractive magnetic field Ma is generated between the adjacent ceramic magnetic bodies 3, and an interposition ring 91 is interposed between the two ceramic magnetic bodies 3. The magnetic field F is formed in the gap 92 by being sandwiched between the magnets 1 ′ and 1 of the ceramic magnetic body 3.

As a result of measuring the magnetic flux densities of the two ceramic magnetic bodies 3 shown by the solid lines in FIG. 35, the magnetic flux densities on the outer surfaces of the magnets 1 and 1 ′ at both ends are 3,050 G, and the magnetic field F ( Magnetic flux density of attractive magnetic field Ma) 2 was 4,100 G.

 In the magnet group shown in Fig. 36, two magnets 1.1 'are adsorbed, and an interposition ring 91 is interposed between the other two magnets 1.1' that are similar. The magnetic poles are arranged such that an attractive magnetic field Ma is generated during the period. The magnet group shown in Fig. 36 is a repetition of this procedure. When the magnetic flux densities of two sets of magnets shown by solid lines were measured, the magnetic flux densities of the magnets 1.1 500 G.

 The magnet group shown in FIG. 37 includes a plurality of ceramic magnetic bodies 3, and the ceramic magnetic bodies 3 are composed of a ceramic molded body 2 and two magnets installed on both sides of the ceramic molded body 2. All magnets are arranged so that their polarities are such that they attract each other and form an attractive magnetic field Ma. The magnet group shown in Fig. 37 is composed of a plurality of ceramic magnetic bodies 3 installed in this way so that an attractive magnetic field Ma is generated between them. Is provided with an interposition ring 91 and a gap 92 forming a magnetic field F (attraction magnetic field M a).

 The results of measuring the magnetic flux density of the two ceramic magnetic bodies 3 indicated by solid lines in FIG. 37 show that the outer surfaces of the outermost magnets 1 and 1 'are 4,500 G and the magnetic flux of the magnetic field F The density was 4,950 G.

 The interposed ring 91 used is made of stainless steel, but the interposed ring 91 is intended to form a magnetic field F between the magnets. Any structure and material can be used arbitrarily.

Since the configuration of the magnet group shown in FIGS. 35 to 37 uses a ceramic magnetic material, the radiation of strong lines of magnetic force due to the amplification of the magnetic flux density and the radiation of far-infrared radiation of the ceramic molded body 2 The activation of the fluid is promoted by the unique action of magnetic field lines and far infrared rays. When the distance of the gap 92 increases, the magnetic flux density of the magnetic field F tends to decrease.As a result of various experiments, it was found that the gap is desirably 1 mm or less, and that the smaller the distance, the greater the effect of amplifying the magnetic field lines. .

 In the magnet groups shown in Fig. 34 to Fig. 37, the polarities are arranged so that the attractive magnetic field Ma is always generated, but the magnet group that generates the repulsive magnetic field Mr by changing the magnet arrangement is configured. You may. However, when actually assembling the fluid activation device, it is easier to work with the suction magnetic field Ma and it is advantageous for mass production.

 FIG. 38 is an internal explanatory view of the ninth embodiment of the present invention using the magnet group of FIG. The fluid activating device 90 includes a cylindrical casing 96 connected to the delivery pipe P via connecting portions 93. Inside the casing 96, a magnet group having the structure shown in FIG. 37 is housed. The magnet group consists of 12 ceramic magnetic bodies (3A to 3L), and only 3Α3L of ceramic magnetic bodies at both ends have only one outermost magnet and other ceramic magnetic bodies (3Β to 3L). 3) has two magnets on both sides of the ceramic body.

 A compression spring 95 for holding the ceramic magnetic bodies 3A to 3L in a predetermined position is arranged in the two connecting portions 93, thereby bringing the ceramics magnetic bodies 3A and 3L closer to each other. Pressing.

 FIG. 38 shows the magnetic flux density measured by the magnetic flux density measuring device together with the measurement sites (A to K). The measurement result is

 7,230 G, B 7,800 G, C--7,650 GD7,900 G, E 7,480 G, F--7,650 G, G7 600 G, H 7,650 G, Ι · 7,330 G, J · · 7,830 G, K 7,22 OG

7,576 G. The magnets that make up the magnet group are samarium-cobalt magnets as described above, and the magnetic flux density of the magnet alone is 2,400 G. As a result of the experiment, it was confirmed that when the present embodiment was configured with a single magnet having a magnetic flux density of 3,000 G, it was possible to obtain a fluid activation device in which the magnetic flux density at each of the aforementioned measurement sites exceeded 10, OOOG.

 The fluid activation device 90 according to the ninth embodiment was mounted on the fuel system of a car equipped with a gasoline engine, and an actual running test was conducted. As a result, it was confirmed that the fuel consumption was reduced by about 28% on average. The details of the test are as follows.

Test vehicle 1991 small passenger car Displacement 2,000 c c

 First running test

 Mileage 244 1 Km

 Fuel consumption 15 31 β

 Fuel ratio 15 94

 Second running test

 Mileage 244 0 Km Fuel consumption 15 01

 Fuel ratio 16 26 Km / β

 First comparative example (running without using fluid activation device)

 Mileage 244.1 Km Fuel consumption 19.30 β

 Fuel ratio 12.65 Km / β

 Second comparative example (running without using fluid activation device)

 Mileage 243.9 Km Fuel consumption 19.66 β

Fuel ratio 12.41 Km / β Average fuel ratio of the first and second driving tests 16.10 Km / Ά Average fuel ratio of the first and second comparative examples 12.53 Km / β Improvement rate of fuel ratio 16. 10Z12, 53 = 1.28 Industrial use sex

 When the fluid activated by the fluid activation device of the present invention is a fuel such as a gaseous fuel, a liquid fuel, or a liquefied gas, the fuel molecules are activated by breaking the mutual bonds of the fuel molecules. The reaction efficiency of oxygen and oxygen is significantly improved, and complete combustion is achieved. This significantly reduces emissions of carbon monoxide, hydrocarbons, chlorides, nitrogen oxides, and particulate matter, thereby purifying exhaust gas, which is effective in preventing air pollution and fuel consumption. The amount is greatly reduced.

 Similarly, by applying the device of the present invention to exhaust gas discharged from various combustion devices, it is possible to reduce the pungent odor and the residual odor of the exhaust gas.

 Also, if the fluid to be activated is water, various water-soluble substances, tap water, drainage, agriculture * Livestock water, fishery water, liquor, sake brewing water, food, drinkables, chemical products or chemicals, etc. The results of applying the present invention are as listed below.

 (1) Drinking water

The water molecules are refined and the water changes to a mellow taste, while increasing the amount of oxygen, preventing oxidation, preventing decay, removing harmful organic substances in a short time, and removing chlorine and odor. In addition, when drinking activated water, the activated water helps to activate water molecules, blood, body fluids and other cellular tissues in the body, changes the acidic constitution to slightly alkaline, and is effective for building a healthy constitution. Works. (2) Drainage It assists in the purification of various types of domestic wastewater and industrial wastewater, increases the amount of oxygen, and is effective in preventing corruption, removing harmful organic substances, preventing water pollution, and preventing river pollution.

(3) Fish tank water

 The water in the aquarium is activated, the amount of dissolved oxygen increases, and the water molecules and cell tissues of the organisms in the aquarium are activated, vitality is increased and food intake is increased, promoting the growth of organisms and promoting health It is effective for maintenance and disease prevention.

 (4) Water for hydroponics

 By supplying the activated water to the cultivation tanks and cultivation areas, the water in the tanks, the geology, and the plants are activated, which is effective for plant cultivation, growth promotion, health maintenance, and disease prevention.

 (5) Fresh flower water

 The color of fresh flowers becomes clearer and the life of cut flowers is extended.

 (6) Bathtub water

 By installing the device of the present invention in a bathtub, the device is heated with hot water of about 40 to 42 ° C, and the radiation of magnetic field lines and far-infrared rays is significantly enhanced. Molecules and cell tissues are activated, the acidic constitution is improved to a weak alkaline constitution, and the effect of promoting and maintaining health is recognized. It is also very effective in preventing hot water cooling.

 (7) Sake

 By installing the device of the present invention on the outside of the barrel or bottle or inside the container, the liquor can be aged at an early stage, and a liquor with a mellow drinking mouth can be obtained.

(8) Pickles

 The ripening is accelerated and the palatability is increased. In addition, spoilage is prevented.

(9) Cooking rice

By putting the device of the present invention into a rice cooker, the action of magnetic field lines and far-infrared radiation of the heated device is promoted, which speeds up rice cooking, makes rice cooked delicious, A great heat-retaining effect and an effect of preventing rot are obtained.

 (10) Food · Chemical products · Pharmaceuticals

 By activating the gaseous or liquid raw materials used in these productions, the molecules in the chain state of the raw materials are miniaturized, the molecular activity is activated, and good reactivity is obtained. As a result, chemical reactions, mixing, aging, etc. can be promoted, and foods can be tasted, and chemical products and chemicals with increased yields due to good chemical reactions can be obtained. Is extremely good.

 As described above, the present invention excites and vibrates molecules constituting various fluids by magnetic field line radiation and far-infrared radiation, gives magnetic induction energy, activates the molecular activities of the fluid, and enhances the composition of the fluid molecules. It breaks the interconnects and makes them smaller, providing a fluid with high reactivity. Further, according to the present invention, since the effect of amplifying the magnetic flux density can be obtained, it is possible to manufacture an activation device having a high magnetic flux density by using a magnet having a relatively low magnetic flux density. However, sufficient equipment can be obtained, and it can be widely used and applied in industrial fields that handle fluids.

Claims

The scope of the claims 1. In the fluid activation device (10) that generates a magnetic field that activates the fluid,  It has a plurality of ceramic magnetic bodies (3) arranged in series, and the ceramic magnetic bodies (3) are arranged on both sides of the fired ceramic molded body (2) and the ceramic molded body (2). With magnets (1 • 1 ')  The magnet (1 · 1 ′) is disposed in a radially central region of the ceramic forming body (2), and the magnet (1 * 1) opposed to the ceramic forming body (2) across the ceramic forming body (2) is a region between the magnets. Are arranged to form an attractive magnetic field (Ma) or a repulsive magnetic field (Mr)  The ceramic magnetic body (3) is arranged in series in the hollow portion of the outer cylinder (6), and the wall of the outer cylinder (6) has a fluid inside the outer cylinder (6) and a fluid outside the outer cylinder (6). An opening (7) for communicating with the region,  The magnetic poles of the series ceramic magnetic body (3) form a repulsive magnetic field (Mr) in a region between the ceramic magnetic bodies (3) when an attraction magnetic field (Ma) is generated in the region between the magnets. When a repulsive magnetic field (Mr) is generated, a magnetic pole arrangement is formed that creates an attractive magnetic field (Ma) in the area between the ceramic magnetic bodies (3).  A fluid activation device, characterized in that a complex magnetic field formed by an attractive magnetic field (Ma) and a repulsive magnetic field (Mr) is formed at least inside the outer cylinder (6).  2. In the fluid activation device (20) that generates a magnetic field that activates the fluid, A plurality of ceramic magnetic bodies (3) arranged in series, The ceramic magnetic body (3) includes a fired ceramic molded body (2) and magnets (1 • 1 ') disposed on both sides of the ceramic molded body (2).  The magnets facing each other with the ceramic molded body (2) interposed therebetween are oriented so as to form an attractive magnetic field (Ma) or a repulsive magnetic field (Mr) in a region between the magnets,  The magnetic poles of the series ceramic magnetic body (3) form a repulsive magnetic field (Mr) in a region between the ceramic magnetic bodies (3) when an attraction magnetic field (Ma) is generated in the region between the magnets. When the repulsive magnetic field (Mr) is generated, the magnetic pole arrangement is set so that an attractive magnetic field (Ma) is formed in the region between the ceramic magnetic bodies (3). A fluid activation characterized in that a complex magnetic field is formed by an attractive magnetic field (Ma) and a repulsive magnetic field (MR) arranged alternately or in an irregular order along the ceramic magnetic body (3). apparatus. 3. The ceramic molded body (2) and the magnet (1 · 1 ′) have a through hole 5 and a center hole 4 aligned with each other to form a substantially continuous fluid passageway (21). 3. The fluid activating device according to claim 2, wherein:  4. The ceramic molded body (2) and the magnet have through holes (5) and a center hole (4) aligned with each other, and support the ceramic molded body (2) and the magnet (1 1 ′). 3. The fluid activation device according to claim 2, wherein a support shaft (22) penetrates the holes.  5. In the fluid activation device (30) that generates a magnetic field that activates the fluid, It has a plurality of ceramic magnetic bodies (3) arranged in series, and the Zenki ceramics magnetic body (3) is a fired tubular of a predetermined length. A ceramic molded body (2); and magnets (1Γ) arranged on both sides of the ceramic molded body (2), wherein the ceramic molded body (2) and the magnet (1 貫通) are aligned with each other. With a hole (5) and a central hole (4),  The magnet (1 * 1) facing through the ceramic molded body (2) ') Are oriented to create an attractive magnetic field (Ma) or a repulsive magnetic field (Mr) in the region between the magnets,  The magnetic pole of the ceramic magnetic body (3) forms a repulsive magnetic field (Mr) in the area between the ceramic magnetic bodies (3) when an attraction magnetic field (Ma) is generated in the area between the magnets, and When a repulsive magnetic field (Mr) is generated, an attractive magnetic field (Ma) is formed in an area between the ceramic magnetic bodies (3) to form a magnetic pole array, and the magnetic poles are arranged alternately or irregularly along the ceramic magnetic bodies (3). An intricate magnetic field is formed by the attractive magnetic field (Ma) and the repulsive magnetic field (Mr) arranged in order,  The ceramic magnetic body (3) is disposed on a delivery pipe (P) connecting the fluid source (S) and the fluid use section (C), and is sent from the fluid source (S) to the fluid use section (C). A fluid activation device, characterized in that the supplied fluid is activated by a synergistic action of a far-infrared radiation action of the ceramic molded body (2) and a magnetic flux emission action of the magnet. 6. The ceramic molded body is formed into a tubular body having a predetermined length, and a tubular or annular magnet is disposed at each end of the ceramic molded body (2), and the magnet is attracted to a region between the magnets. Oriented to form a magnetic field (Ma) or a repulsive magnetic field (Mr), The ceramic molded body and the magnet are disposed in a tube (32) forming a fluid passage, and the through hole (5) of the ceramic molded body (2) and the center hole (4) of the magnet are Aligned with tube (P), substantially continuous 6. The fluid activating device according to claim 5, wherein a fluid passage 31 is formed.  7. The ceramic molded body (2) is formed into a tube having a predetermined length, and a tubular or annular magnet is disposed at each end of the ceramic molded body (2). Oriented to form an attractive magnetic field (Ma) or a repulsive magnetic field (Mr) in the region of  The ceramic molded body (2) and the magnet (1 · 1 ′) are arranged on an outer periphery of a delivery pipe (P) forming a fluid passage, and the delivery pipe (P) is a through hole of the ceramic molded body (2). 6. The fluid activating device according to claim 5, wherein the fluid activating device penetrates through the center hole of the magnet and the magnet.  8. In the fluid activation device (40) that generates a magnetic field that activates the fluid,  The ceramic magnetic body (3) has a plurality of ceramic magnetic bodies (3) arranged in series, and the ceramic magnetic body (3) is disposed outside a fired tubular ceramic molded body (2) and the ceramic molded body (2). A tubular magnet (1) having a predetermined length, wherein the ceramic molded body (2) has an outer diameter capable of being accommodated in a center hole (4) of the tubular magnet (1); With through holes (5), The magnets are oriented so as to form an attractive magnetic field (Ma) or a repulsive magnetic field (Mr) between opposing magnet end faces, and are complicated by an alternating or irregular arrangement of the attractive magnetic field and the repulsive magnetic field. A magnetic field is formed, and the ceramic magnetic body (3) containing the ceramic molded body (2) in the center hole (4) of the magnet (1) comprises a fluid source (S) and a fluid using section (C). The through-hole (5) of the ceramic molded body (2) is arranged in the connecting delivery pipe (P), and forms a fluid passage 41 aligned along the fluid passage. The fluid supplied from the fluid source to the fluid-using portion is activated by a synergistic effect of a far-infrared radiation effect of the ceramics molded body (2) and a magnetic line radiation effect of the magnet. Fluid activation device. 9. In the fluid activation device (40) that generates a magnetic field that activates the fluid,  The ceramic magnetic body (3) includes a plurality of ceramic magnetic bodies (3) arranged in series, and the ceramic magnetic body (3) includes a tubular ceramic molded body (2) fired to a predetermined length; ), A magnet (1) disposed inside of the ceramic body (2), wherein the Viscount (1) has an outer diameter and a center hole (5 4)  The magnet (1) is oriented so as to form an attractive magnetic field (Ma) or a repulsive magnetic field (Mr) between opposed magnet end faces, and an alternating arrangement of the attractive magnetic field (Ma) and the repulsive magnetic field (Mr). Or an irregularly arranged array creates a complex magnetic field,  The ceramic magnetic body (3) containing the ceramic molded body (2) in the central hole (4) of the magnet (1) is provided with a delivery pipe (F) for connecting a fluid source (S) and a fluid use part (C). P), the center hole (4) of the magnet (1) forms a fluid passage (41) aligned along the fluid passage, and is connected from the fluid source (S) to the fluid use part (C). The fluid activation device is characterized in that the supplied fluid is activated by a synergistic action of a far-infrared radiation action of the ceramic molded body (2) and a magnetic flux emission action of the magnet (1).  10. In the fluid activation device (50) that generates a magnetic field that activates the fluid, A cylindrical casing (52) having an opening at an end; A plurality of ceramic magnetic bodies (3) arranged in the ring (52),  The ceramic magnetic body (3) includes a ceramic molded body (2) fired to a predetermined length, and magnets (1.1 ′) disposed on both sides of the ceramic molded body (2). The compact (2) and the magnet (1.1 ') have a through hole (5) and a central hole (4) aligned with each other,  The magnets (1.1 ′) opposed to each other with the ceramic molded body (2) interposed therebetween are oriented so as to form an attractive magnetic field (Ma) or a repulsive magnetic field (Mr) in a region between the magnets.  The magnetic poles of the ceramic magnetic body (3) form a repulsive magnetic field (Mr) between the ceramic magnetic bodies (3) when an attraction magnetic field (Ma) is generated in an area between the magnets, and repel the magnetic field between the magnets. When a magnetic field (Mr) is generated, it is set to a magnetic pole array that forms an attractive magnetic field (Ma) between the ceramic magnetic bodies (3).  A fluid flowing from the opening of the casing (52) is activated by a synergistic action of a far-infrared radiation action of the ceramic molded body (2) and a magnetic flux emission action of the magnet; Device. 11. In the fluid activation device (60) that generates a magnetic field that activates the fluid,  A ceramic magnetic body (3) comprising a fired ceramic molded body (2) and a plurality of magnets (1) arranged on both sides of the ceramic molded body (2);  The magnet (1) is at least partially embedded in the surface of the ceramic molded body (2), The first magnet and the second surface on the first surface of the ceramic molded body (2) The second magnet is substantially arranged in plane symmetry so that an attraction magnetic field (Ma) or a repulsive magnetic field (M r) is formed between the two magnets,  The attraction magnetic field and the repulsive magnetic field formed by the magnet (1.1) form a complex magnetic field in which these magnetic fields are mixed,  The fluid in contact with the ceramic magnetic body (3) is activated by a synergistic action of the far-infrared radiation action of the ceramic molded body (2) and the magnetic flux emission action of the magnet (1 * 1). Fluid activation device.  12. In a fluid activation device (70) that generates a magnetic field that activates a gas fluid,  A ceramic molded body (2) having a predetermined length, and magnets (1.1 ′) arranged on both sides of the ceramic molded body (2), and the ceramic molded body (2) and a magnet (1 · 1 ') has a through hole (5) and a central hole (4) aligned with each other,  The magnet is oriented so as to form an attractive magnetic field (Ma) or a repulsive magnetic field (Mr) in a region between the magnets facing each other via the ceramic molded body,  A conduit (GP) of the cylinder (B) penetrates the ceramic molded body (2) and the magnet (1 ·), and the ceramic molded body (2) and the magnet (1 · 1 ') pass through the conduit with a liquefied gas (GP). Fluid activating device characterized by activating liquefied gas (G) stored inside (B).  13. In the fluid activation device (80) (90) that generates a magnetic field that activates the fluid, A plurality of magnets (1) are provided, and the magnets are connected in series at a predetermined distance from each other via protrusions or interposition rings (1a, 85, 91). And A fluid activation device, characterized in that the magnets are oriented so as to create an attractive magnetic field (Ma) in a region between the magnets.  14. The fluid activation device according to claim 13, wherein the interposition ring (85 * 91) is made of a non-magnetic material.  15. The fluid activation device according to claim 13, wherein the interposition ring (85/19) is made of a fired ceramic formed body. 16. The fluid activation device according to claim 13, wherein a magnet group including a plurality of magnets is arranged on both sides of the interposition ring, and the magnets of each magnet group are attracted to each other by magnetic attraction. .  17. Having a fired ceramic compact (2),  The magnet is arranged in a radially central region of the ceramic molded body (2), and constitutes a ceramic magnetic body (3) composed of the magnet and the ceramic molded body.  An attraction magnetic field (Ma) is formed between a magnet disposed on the first surface of the ceramic molded body and a magnet door disposed on the second surface,  A plurality of the ceramic magnetic bodies are connected in series via an interposition ring between magnets, and an attractive magnetic field is formed between adjacent ceramic magnetic bodies via the interposition ring. The fluid activation device of range 13.  18. The ceramic magnetic body (3) is arranged in series in a casing (96) along the axis of the casing, and both ends of the casing are connected to a delivery pipe (P), and the casing is a fluid passage. 18. The fluid activation device according to claim 17, wherein the fluid activation device forms a part of the fluid activation device. 19. The ceramic body (2) and the magnet (1) have a through hole (5) and a center hole (4) aligned with each other, and both holes are substantially continuous fluid passages. 19. The fluid activating device according to claim 18, wherein a passage is formed, and the fluid passage communicates with the delivery pipe (P).  20. In the fluid activation device (90) that generates a magnetic field that activates the fluid fuel,  A plurality of ceramic magnetic bodies (3), wherein the ceramic magnetic bodies (3) are connected in series at a predetermined distance via an annular interposition ring (85 * 91);  The ceramic magnetic body (3) includes a ceramic molded body (2), a first magnet group (1) arranged on a first surface of the ceramic molded body (2), and a ceramic magnet body (3) arranged on a second surface. A second magnet group (1 ')  The first magnet group is composed of a plurality of magnets that are attracted in series by a magnetic attraction action.The second magnet group is composed of a plurality of magnets that are attracted in series by a magnetic attraction action.  The first magnet group and the second magnet group arranged on the two surfaces of the ceramic molded body attract each other to form an attractive magnetic field (Ma) in the area of the ceramic molded body,  The first and second ceramic magnetic bodies adjacent to each other are formed by an attractive magnetic field between an end face of the second magnet group of the first ceramic molded body and an end face of the first magnet group of the second ceramic magnetic body. Ma)  The ceramic magnetic body is disposed in a casing (96) in series along an axis of the casing, and both ends of the casing are connected to a delivery pipe (P), and the casing forms a part of a fluid passage. A fluid activation device.