JP3214284U - Magnetic processing equipment - Google Patents

Abstract

Provided is a magnetic processing apparatus which is attached in the middle of a conduit and can efficiently perform magnetic processing in a fluid. SOLUTION: A plurality of ring-shaped magnets 21 to 25 having holes 21A to 25A through which fluid can flow are made to communicate with the holes 21A to 25A and end surfaces 21a to 25a to allow fluid to flow. The magnetized member 20 is formed by arranging an outer peripheral flow path 13 between the magnetized member 20 that magnetically processes the fluid and the outer peripheral surface of the magnetized member 20, which are arranged in alignment with 21 b to 25 b facing each other. And a case member 30 to which a fluid introduction conduit and a fluid discharge conduit magnetically processed by the magnetizing member 20 are connected, and the plurality of ring-shaped magnets 21 to 25 are end faces facing each other. The parts 21a to 25a and 21b to 25b are arranged with the same magnetic pole. [Selection] Figure 1

Description

  The present invention relates to a magnetic processing apparatus which is disposed in the middle of a conduit and magnetically processes a fluid flowing inside.

  Various devices have been proposed for magnetically processing a fluid in a conduit using a magnet. These magnetic treatment apparatuses remove impurities in the fluid flowing in the conduit, for example, minerals such as calcium carbonate in water and iron, and prevent the scale in the conduit from being generated. It is also said to reduce the water cluster and increase the amount of dissolved oxygen.

  A conventionally proposed magnetic processing apparatus removes impurities based on magnetohydrodynamics in which an electromotive force is generated by Lorentz force when a magnetic field line existing between the N pole and S pole of a hydromagnet is traversed at a right angle with a velocity. For this reason, the magnetic processing apparatus is configured such that the magnetic field lines between the different poles cross at right angles to the conduit.

  In Patent Document 1, a plurality of ring-shaped magnetized members formed by combining two semicircular arc magnets along the axis of the conduit around the conduit through which the fluid flows are arranged in parallel to act on the fluid. In the magnetic processing apparatus, the joining end portions located at both ends of the arcs of the two semi-arc-shaped magnets constituting one magnetizing member are provided with magnetic poles different from each other, and when arranging the magnetizing member, the semi-arc-shaped A magnetic processing apparatus is described in which adjacent axial end faces of magnets have the same magnetic pole.

  Patent Document 2 is a magnetic processing apparatus including a plurality of ring-shaped magnets having holes through which a conduit through which a fluid flows can pass, and causing magnetism to act on the fluid, wherein the plurality of ring-shaped magnets are provided. A magnetic processing apparatus is described in which the magnets are arranged such that the opposing end face portions have the same magnetic pole.

  Documents 1 and 2 relate to the applicant's application.

Utility Model Registration No. 3205021 Utility Model Registration No. 3209096

  However, the magnetic processing apparatuses described in Patent Document 1 and Patent Document 2 arrange magnets around a conduit. For this reason, the magnetic field lines of the magnet act on the water inside through the conduit. Therefore, the flowing water in the conduit does not directly touch the magnet and is not treated with the magnetic field lines in the strongest state. Further, both the magnetic processing apparatuses are disposed around the existing conduit, and cannot meet the demand for disposing the magnetic processing apparatus in the middle of the conduit.

  This invention is made | formed in view of the subject mentioned above, and makes it a subject to provide the magnetic processing apparatus which can be directly arrange | positioned in the middle of a conduit | pipe and can make a fluid act a magnetic force line directly on a magnet efficiently.

  The device according to claim 1, which solves the above-mentioned problem, has a plurality of ring-shaped magnets provided with holes through which fluid can flow, and communicates the holes so that the fluid can flow and faces end faces. And an outer peripheral flow path through which the fluid can flow is formed between a magnetized member that magnetically processes the fluid and an outer peripheral surface of the magnetized member to cover the periphery of the magnetized member. A case member to which the fluid introduction conduit and the fluid discharge conduit magnetically processed by the magnetizing member are connected, and the plurality of ring-shaped magnets have the same magnetic poles at the end faces facing each other. It is a magnetic processing apparatus characterized by having arranged

According to the present invention, the periphery of the magnetized member formed by arranging a plurality of link-like permanent magnets is covered with the case member, and the case member has an outer periphery through which the fluid can flow between the outer peripheral surface of the magnetized member. An introduction conduit for another fluid that forms a flow path and a discharge conduit for the fluid magnetically processed by the magnetized member are connected. The plurality of ring-shaped magnets are arranged such that the end face portions facing each other have the same magnetic pole, and the lines of magnetic force penetrate into the back of the fluid and are magnetized.
Therefore, in addition to being able to connect directly to the conduit, the fluid is in direct contact with the hole and the periphery of the magnetized part, and the ring-shaped magnets are arranged with the same magnetic poles on the end faces facing each other, and the lines of magnetic force extend to the back of the fluid. It can penetrate and cause magnetic field lines to act efficiently and powerfully on the fluid.

  Similarly, in the invention according to claim 2, the case member is composed of two cover members, each of the cover members being arranged in the vicinity of the magnetizing member, and a cross-section ring between the magnetizing member. A magnetized member storage portion for fixing the magnetized member to form a circular peripheral flow path; a connection portion connected to one end of the magnetized member storage portion and connected to one of the introduction conduit and the discharge conduit; And a connecting flange portion provided at the other end of the magnetized member storage portion and connected to another cover member.

According to the present invention, the case member is composed of two cover members, and each cover member includes a magnetized member accommodating portion, a connecting portion, and a connecting flange portion, and the magnetized member accommodating portion is interposed between the magnetized members. The magnetizing member is fixed so as to form a ring-shaped peripheral flow path, one of the introduction conduit and the discharge conduit is connected at the connection portion, and the other end of the magnetizing member storage portion is provided at the connection flange portion. Connected to the cover member.
Therefore, the two cover members are aligned at the connection flange portion, and at this time, a ring-shaped peripheral flow path is formed between the cover member and the magnetized member only by arranging the magnetized member in the two magnetized member storage portions. Thus, the magnetizing member is fixed. For this reason, the assembly of the magnetic processing apparatus can be performed simply by covering the magnetizing member with the two cover members.

  Similarly, the device according to claim 3 is inserted along the axis of the hole portion of the ring-shaped magnet arranged in plural, and a flow channel having a ring-shaped cross section is formed between the inner periphery of the hole portion of the ring-shaped magnet. A flow path limiting member to be formed is provided.

According to the present invention, the flow path limiting member that forms a cross-sectional ring-shaped flow path between the ring magnet and the inner periphery of the hole of the ring magnet is inserted along the axis of the hole of the ring magnet.
Therefore, the flow path of the hole portion of the ring-shaped magnet is limited to a portion close to the inner surface of the hole portion, and the magnetic force can be strongly applied by the fluid.

  Similarly, the invention described in claim 4 includes a magnet fixing member that fixes a plurality of the ring-shaped magnets aligned at predetermined intervals, and the magnet fixing member also serves as the flow path limiting member. And

According to the present invention, the plurality of ring-shaped magnets are fixed with a magnet fixing member aligned at a predetermined interval, and the fixing member also serves as a flow path limiting member.
Therefore, a magnetized member can be formed by simply fixing a plurality of ring-shaped magnets with a magnet fixing member, and a portion where the flow path of the hole portion of the ring-shaped magnet is close to the inner surface of the hole portion only by fixing with a magnet fixing member It can be limited to. For this reason, the magnetizing member can be easily assembled, and the flow path of the hole can be limited only by assembling the magnetizing member.

  According to the magnetic processing apparatus of the present invention, it can be directly connected to the conduit, and the fluid can efficiently cause the magnetic lines of force to act directly on the magnet.

  In other words, according to the first aspect of the present invention, the magnetic processing apparatus is configured by covering the periphery of the magnetized member formed by arranging a plurality of link-shaped permanent magnets with the case member, and the case member is an outer periphery of the magnetized member. An inlet conduit for another fluid that forms an outer peripheral flow path through which the fluid can flow and a discharge conduit for the fluid magnetically processed by the magnetized member, and a plurality of ring magnets, The facing end faces are arranged with the same magnetic pole, and the magnetic lines of force penetrate to the back of the fluid and magnetize. Therefore, in addition to being able to connect directly to the conduit, the fluid is in direct contact with the hole and the periphery of the magnetized part, and the ring-shaped magnets are arranged with the same magnetic poles on the end faces facing each other, and the lines of magnetic force extend to the back of the fluid. It can penetrate and cause magnetic field lines to act efficiently and powerfully on the fluid.

  According to the invention described in claim 2, the case member is composed of two cover members, and each cover member includes a magnetized member accommodating portion, a connecting portion, and a connecting flange portion, and the magnetized member accommodating portion. The magnetizing member is fixed to form a ring-shaped peripheral flow path between the magnetizing member, one of the introduction conduit and the discharge conduit is connected at the connection portion, and the magnetizing member storage portion is connected at the connection flange portion. Provided at the other end and connected to another cover member. Therefore, the two cover members are aligned at the connection flange portion, and at this time, a ring-shaped peripheral flow path is formed between the cover member and the magnetized member only by arranging the magnetized member in the two magnetized member storage portions. Thus, the magnetizing member is fixed. For this reason, the assembly of the magnetic processing apparatus can be performed simply by covering the magnetizing member with the two cover members.

  Furthermore, according to the third aspect of the present invention, the flow path limiting member that forms the ring-shaped flow path in cross section with the inner periphery of the hole portion of the ring-shaped magnet is provided on the shaft of the hole portion of the ring-shaped magnet. Is inserted along. Therefore, the flow path of the hole portion of the ring-shaped magnet is limited to a portion close to the inner surface of the hole portion, and the magnetic force can be strongly applied by the fluid.

  According to the fourth aspect of the present invention, the plurality of ring-shaped magnets are fixed and aligned at predetermined intervals by the magnet fixing member, and the fixing member also serves as the flow path limiting member. Therefore, a magnetized member can be formed by simply fixing a plurality of ring-shaped magnets with a magnet fixing member, and a portion where the flow path of the hole portion of the ring-shaped magnet is close to the inner surface of the hole portion only by fixing with a magnet fixing member It can be limited to.

BRIEF DESCRIPTION OF THE DRAWINGS The magnetic processing apparatus which concerns on embodiment of this invention is shown, (a) is sectional drawing of a magnetic processing apparatus tail, (b) is sectional drawing of a magnetization member. The cover member which comprises the case member of the magnetic processing apparatus is shown, (a) Sectional view which notched a part of cover member, (b) is a side view from the arrow B direction in (a), (C) is a side view from the arrow C direction in (a). FIG. 2 shows a magnet fixing member of the magnetic processing apparatus, wherein (a) is a left side view showing a main body portion of the fixing member, (b) is a front view thereof, and (c) is a CC line in (b). (D) is a right side view, (d) is a left side view of the nut portion, and (e) is a cross sectional view thereof. The magnetic force measurement result of a magnetic processing apparatus is shown, (a) is a graph which shows a measurement result, (b) is a schematic diagram which shows the magnetization member of the magnetic processing apparatus made into the measuring object. The measurement result of the dissolved oxygen amount of water is shown, (a) is a table | surface which shows the dissolved oxygen amount of the water magnetically processed by the magnetic processing apparatus which concerns on a comparative example, and the magnetic processing apparatus which concerns on embodiment. ) Is a table showing examples of dissolved oxygen in rainwater and tap water.

  A magnetic processing apparatus according to an embodiment for carrying out the present invention will be described. A magnetic processing apparatus according to the present invention includes a plurality of ring-shaped magnets having holes therein through which fluid can flow, and are arranged in an aligned manner so that the holes communicate with each other and end surfaces thereof face each other. The outer peripheral flow path through which the fluid can flow is formed between a magnetized member that magnetically processes the fluid and an outer peripheral surface of the magnetized member, covers the periphery of the magnetized member, and introduces the fluid And a case member to which the fluid discharge conduit magnetically processed by the magnetizing member is connected, and the plurality of ring-shaped magnets are arranged with end faces facing each other having the same magnetic pole. This is a magnetic processing apparatus.

  The magnetizing member is configured by covering the periphery of the magnetizing member formed by arranging a plurality of link-shaped permanent magnets with a case member, and the case member is an outer peripheral flow path through which the fluid can flow between the outer peripheral surface of the magnetizing member And a fluid discharge conduit magnetically processed by the magnetized member are connected to each other. The plurality of ring-shaped magnets are arranged such that the end face portions facing each other have the same magnetic pole, and the lines of magnetic force penetrate into the back of the fluid and are magnetized. Therefore, in addition to being able to connect directly to the conduit, the fluid is in direct contact with the hole and the periphery of the magnetized part, and the ring-shaped magnets are arranged with the same magnetic poles on the end faces facing each other, and the lines of magnetic force extend to the back of the fluid. It can penetrate and cause magnetic field lines to act efficiently and powerfully on the fluid.

  FIG. 1 shows a magnetic processing apparatus according to an embodiment of the present invention, wherein (a) is a cross-sectional view of the magnetic processing apparatus tail, (b) is a cross-sectional view of a magnetized member, and FIG. 2 is a case of the magnetic processing apparatus. The cover member which comprises a member is shown, (a) Sectional drawing which notched a part of cover member, (b) is a side view from the arrow B direction in (a), (c) is (a) ) Is a side view from the direction of arrow C, FIG. 3 is a view showing a magnet fixing member of the magnetic processing apparatus, (a) is a left side view showing a main body portion of the fixing member, and (b) is a front view of the same. (C) is sectional drawing of CC line in (b), (d) is the right side view, (d) is the left side view of a nut part, (e) is the sectional drawing.

  As shown in FIG. 1, the magnetic processing apparatus 10 according to the present embodiment includes a magnetizing member 20 and a case member 30. The magnetizing member 20 is disposed inside the case member 30 and magnetizes the fluid that has flowed into the case member 30, such as water. The case member 30 is connected to a flow path 11 for inflow of a fluid, for example, water, and a discharge path 12 of the magnetized water. In the case member 30, the surrounding flow path 13 is formed between the magnet member 20 and the case member 30, and the internal flow path 14 is formed inside the magnet member 20.

  The magnetizing member 20 includes a plurality of, in this example, five ring-shaped magnets 21, 22, 23, 24, and 25 arranged at predetermined intervals along the axis O. As shown in FIG. 1B, each ring-shaped magnet 21 is a ring anisotropic magnet having a surface magnetic flux density of 1200 G, which is a ring having an outer diameter of 55 mm, an inner diameter of 24 mm, and a thickness of 12 mm. Although the thing of the said dimension was used in this example, the dimension of a ring-shaped magnet can be changed suitably. The magnet is not limited to a ferrite anisotropic magnet, and any material can be used as long as it has a necessary magnetic force.

  The ring-shaped magnets 21, 22, 23, 24, and 25 are arranged in an aligned manner such that the holes 21 </ b> A, 22 </ b> A, 23 </ b> A, 24 </ b> A, and 25 </ b> A communicate with each other so that fluid can flow therethrough. That is, as shown in FIG. 1B, one end surface portion 21b of the ring-shaped magnet 21 (right side in the drawing) faces the other end surface portion 22a of the ring-shaped magnet 22 (left side in the drawing).

  One end surface portion 22 b (right side in the figure) of the ring-shaped magnet 22 faces the other end surface portion 23 a (left side in the diagram) of the ring-shaped magnet 23. One end surface portion 23 b (right side in the figure) of the ring-shaped magnet 23 faces the other end surface portion 24 a (left side in the diagram) of the ring-shaped magnet 24. Further, one end surface portion 24 b (right side in the drawing) of the ring-shaped magnet 24 faces the other end surface portion 25 a (left side in the drawing) of the ring-shaped magnet 25.

  Further, as shown in FIG. 1B, the ring-shaped magnets 21, 22, 23, 24, and 25 of the magnetizing member 20 are arranged so that the end face portions facing each other have the same magnetic pole. That is, in the ring-shaped magnet 21, the end surface portion 21a has "S pole" and the end surface portion 21b has "N pole", and in the ring magnet 22, the end surface portion 22a has "N pole" and the end surface portion 22b has "S pole". None, in the ring-shaped magnet 23, the end surface portion 23a has "S pole" and the end surface portion 23b has "N pole". In the ring magnet 24, the end surface portion 24a has "N pole" and the end surface portion 24b has "S pole". None, in the ring-shaped magnet 25, the end surface portion 25a forms an “S pole” and the end surface portion 25b forms an “N pole”.

  This makes it possible to perform a strong magnetization process that causes the magnetic lines of force from the same pole to repel and affect the positions of the magnetic lines of force.

  In addition, the space | interval of each ring-shaped magnet 21, 22, 23, 24, 25 is 1 mm, for example. The smaller the interval, the more repulsive the magnetic field lines, but the closer the distance, the greater the repulsive force due to the same polarity. This interval dimension can be changed as appropriate. In this example, the number of ring magnets is five, but can be changed as appropriate. According to the experiment of the inventor, the magnetizing force is small when the number is three or less, and even when the number is six or more, the special effect is not seen as compared with the case where the number is five. For this reason, the number of ring-shaped magnets is considered to be appropriate from the viewpoint of cost effectiveness.

  These ring-shaped magnets 21, 22, 23, 24, and 25 that constitute the magnetizing member 20 are fixed by a magnet fixing member 60 that is inserted through each of the holes 21 </ b> A, 22 </ b> A, 23 </ b> A, 24 </ b> A, and 25 </ b> A. The magnet fixing member 60 includes a fixing member main body 70 that is inserted into the holes 21A, 22A, 23A, 24A, and 25A, and a nut member 80 that is screwed into the distal end portion 73 of the shaft portion 72 protruding from the magnetizing member 20. The fixing member main body 70 is provided with a head 71.

  The case member 30 is configured by combining two cover members 40 and 50. The cover members 40 and 50 are formed by molding PP (polypropylene) with the same mold, and have the same configuration. Note that the cover members 40 and 50 may be made of other synthetic resin materials.

  Since the cover member 40 and the cover member 50 have the same configuration, one cover member 40 will be described below. As shown in FIG. 2, the cover member 40 includes a magnetized member storage portion 41, a connection portion 42, and a connection flange portion 43. The magnetizing member storage portion 41 includes a cylindrical portion 41 </ b> A that is disposed close to the periphery of the magnetizing member 20, and a tapered portion 41 </ b> B directed toward the connecting portion 42. The cover member 40 forms the surrounding flow path 13 with the magnetizing member 20.

  The distance between the surrounding flow paths 13 can be set to 2 mm, for example. This interval can be appropriately changed depending on the inflow flow rate from the inflow flow channel 11, the required discharge amount from the discharge flow channel 12, the degree to which magnetization processing is required, the flow rate of the internal flow channel 14, and the like. .

  In the magnetizing member storage portion 41, eight fixing pieces 44 for fixing the magnetizing member 20 are provided radially at equal intervals. The fixed piece 44 is a plate-like member that comes into contact with one end and the other end of the magnetizing member 20 and has a triangular side surface. An ambient flow path forming member 45 is formed inside the cover member 40. The surrounding flow path forming member 45 is a member having a triangular cross section provided at eight equal intervals, and contacts the outer peripheral surface of the cover member 40 to place the magnetizing member 20 at the center position of the case member 30. The dimensions of the surrounding flow path 13 are made uniform.

  The discharge channel 12 is connected to the connection part 42. The inflow channel 11 is connected to the connection portion 52 of the cover member 50. The connecting portion 42 is connected to the cylindrical portion 41A of the magnetizing member storage portion 41, and one of the introduction conduit and the discharge conduit is connected. The connecting portion 42 is formed with a hexagonal portion 42A for hanging a tool.

  The connection flange portion 43 is formed at the end of the cylindrical portion 41 </ b> A of the magnetizing member storage portion 41. The connection flange portion 43 is formed with a circumferential groove portion 47 for disposing the sealing material 100 disposed between the bolt insertion hole 46 for inserting the fixing bolt 90 and the flange portion 53 of the other cover member 50. Has been. The sealing material 100 is made of a soft synthetic resin.

  Next, the magnet fixing member 60 will be described. In the present embodiment, the magnet fixing member 60 includes a fixing member main body 70 and a nut member 80. The fixing member main body 70 includes a head 71 having a larger diameter than the hole 25A of the ring-shaped magnet 25, a shaft 72 extending from the head 71, and a tip 73 provided at the tip of the shaft 72. Consists of.

  In the fixing member main body 70, the shaft portion 72 includes a cylindrical portion 74 and an extending plate portion 75 extending radially from the cylindrical portion 74 in four directions. As a result, the shaft 72 has a cross-shaped cross section. Further, the columnar portion 74 and the extended plate portion 75 are connected to the head portion 71, and four fan-shaped hole portions 77 are formed at locations where the columnar portion 74 and the extended plate portion 75 are not connected. The fluid can be circulated.

  In the present embodiment, the cylindrical portion 74 of the fixing member main body 70 has a function of a flow path limiting member. Thereby, the internal flow path 14 can be made into a cross-sectional ring shape. Therefore, the internal flow path 14 of the magnetized member 20 is limited to a portion close to the inner surface of the hole portions 21A, 22A, 23A, 24A, and 25A of the ring-shaped magnets 21, 22, 23, 24, and 25. Can act on fluid.

  In addition, the thickness of the cylindrical part 74 can be changed suitably. For example, in FIGS. 3A and 3C, the large-diameter cylindrical portion 74 is indicated by a two-dot chain line. By changing the diameter of the cylindrical portion 74, the dimensions of the surrounding flow path 13 can be changed, and the flow rate and the degree of magnetization can be adjusted. This diameter can be appropriately changed according to the inflow flow rate from the inflow flow channel 11, the required discharge amount from the discharge flow channel 12, the degree to which magnetization processing is required, the flow rate of the surrounding flow channel 13, and the like. .

  In order to assemble the magnetic processing apparatus 10, the magnetizing member 20 is assembled, the magnetizing member 20 is disposed inside the cover member 40 and the cover member 50, and the cover member 40 and the cover member 50 are joined using the fixing bolt 90. .

  To assemble the magnetizing member 20, the ring-shaped magnets 21, 22, 23, 24, 25 are aligned, the fixing member main body 70 is inserted into the aligned holes 25A, 22A, 23A, 24A, 25A, and the nut member Assemble 80. At this time, since there is a repulsive force between the ring-shaped magnets 21, 22, 23, 24, 25, by screwing the nut member 80, the interval between the ring-shaped magnets 21, 22, 23, 24, 25 is The distance between the ring-shaped magnets 21, 22, 23, 24, 25 can be adjusted by the degree of screwing of the nut member 80. A ring-shaped spacer having a predetermined dimension, for example, 1 mm, can be disposed between each ring-shaped magnet 21, 22, 23, 24, 25.

  The assembled magnetizing member 20 is disposed inside the cover member 40 and the cover member 50, and the connection flange portion 43 of the cover member 40 and the flange portion 53 of the cover member 50 are joined using the fixing bolt 90. At this time, the sealing material 100 is disposed between the circumferential groove portion 47 of the connection flange portion 43 and the circumferential groove portion 57 of the flange portion 53.

  Thereby, the magnetic processing apparatus 10 in which 20 is arranged in the case member 30 is completed. In this state, the discharge flow path 12 is connected to the connection part 42 of the cover member 40 and the inflow flow path 11 is connected to the connection part 52 of the cover member 50, thereby completing the installation of the magnetic processing apparatus 10 on the pipe.

  As described above, by arranging the magnetic processing apparatus 10 according to the embodiment in the pipe, the water that has flowed from the inflow channel 11 flows through the peripheral channel 13 and the internal channel 14, and from the discharge channel 12. Discharged. By flowing through the surrounding flow path 13 and the internal flow path 14, the water directly contacts the magnetizing member 20 and is strongly magnetized. At this time, the ring-shaped magnets 21, 22, 23, 24, and 25 that constitute the magnetizing member 20 are arranged with the same magnetic poles at the end faces that face each other, so that the lines of magnetic force penetrate into the depths of water. The magnetic field lines can be efficiently and strongly applied to water.

  Further, in the magnetic processing apparatus 10 according to the present embodiment, in a state where the piping is frozen, the joint portion between the connection flange portion 43 of the cover member 40 and the flange portion 53 of the cover member 50 is slightly opened, and the inside is opened from this point. Leakage of air can prevent damage caused by freezing of piping.

  Next, the measurement result of the magnetic force exerted on the outside by the magnetizing member 20 will be described. 4A and 4B show measurement results of the magnetic force of the magnetic processing apparatus. FIG. 4A is a graph showing the measurement results, and FIG. 4B is a schematic diagram showing a magnetized member of the magnetic processing apparatus as a measurement target.

  As shown in FIG. 4B, the same ring-shaped magnet as the above-described magnetizing member 20 is covered and fixed with a heat-shrink sheet 26 with a 1 mm spacer interposed therebetween, and the magnetic processing apparatus 10 according to the embodiment is measured. A value corresponding to the magnetic force in the surrounding flow path 13 was measured. That is, the magnetic force was measured at a position 2 mm away from the outer peripheral surface of the magnetizing member 20. The measurement results are shown in FIG.

  That is, S600 near the end face 21a of the ring-shaped magnet 21, N1200 at the joint between the ring-shaped magnet 21 and the ring-shaped magnet 22, S1200 at the joint between the ring-shaped magnet 22 and the ring-shaped magnet 23, and the ring-shaped magnet 23. N1200 at the joint between the ring magnet 24 and S1200 at the joint between the ring magnet 24 and the ring magnet 25, and N500 near the end face 25b of the ring magnet 25. According to the magnetic processing apparatus 10 which concerns on this embodiment, it turned out that the magnetic processing to the water which is a fluid can be performed strongly, and a magnetic processing can be performed efficiently.

  Next, the amount of dissolved oxygen when water is magnetically processed by the magnetic processing apparatus 10 will be described. It is considered that the effect of the magnetic treatment is reflected in the amount of dissolved oxygen, and it can be determined that the greater the amount of dissolved oxygen, the better the degree of magnetization treatment. The dissolved oxygen content of the tap water magnetically processed by the magnetic processing apparatus which concerns on this embodiment, the comparative product 1, the comparative product 2, and the comparative product 3 was measured. It is understood that oxygen is not dissolved in water in the magnetic processing apparatus 10 but is discharged from the magnetic processing apparatus 10 and is dissolved in water when exposed to the atmosphere.

  Comparative product 1 was divided into two arc-shaped magnets of the two ring magnets described in Document 2 (each having an outer diameter of 55 mm, an inner diameter of 24 mm, and a thickness of 12 mm), and these were combined to constitute a magnetized member. Is. In the comparative product 2, three and four ring-shaped magnets are arranged on the case member of the magnetic processing apparatus according to this embodiment.

  As shown in FIG. 5A, it can be seen that the amount of dissolved oxygen is increased in the magnetic processing apparatus according to this embodiment as compared with Comparative Example 1, Comparative Example 2, and Comparative Example 3. That is, the amount of dissolved oxygen in tap water before magnetic treatment is 11.0 to 11.2 (mg / l), whereas the water magnetized by the magnetic treatment apparatus according to the present embodiment is 11.7 to 11 Increased to 0.8 (mg / l).

  On the other hand, even if it attaches to the comparative products 1-3, although the amount of dissolved oxygen is increasing, it turns out that the value is less than the magnetic processing apparatus which concerns on this embodiment. Thereby, it turns out that the magnetization processing was efficiently performed by the magnetic processing apparatus 10 according to the embodiment. Here, the comparative product 3 has a dissolved oxygen amount of 11.5 to 11.8 (mg / l), which is substantially the same as the magnetic processing apparatus according to the present embodiment, but there are variations in numerical values. This shows that an inexpensive magnetic processing apparatus can be provided when the number of ring magnets is five.

  In each of the above embodiments, an example is shown in which a ferrite magnet is used as a magnet, but the type of magnet is not limited. Further, the number of ring-shaped magnets constituting the magnetizing member can be appropriately changed. Further, the shape of the case member 30 is not limited to the above example.

  Next, the magnetically treated water will be described. There are reports, knowledge and experiments that magnetically treated water has the following merits.

(1) Plant growth Magnetically treated water increases the amount of dissolved oxygen. As a result, the plant grows well. There is also an empirical fact that plants grow and grow when it rains. Therefore, it is considered that growth can be promoted by supplying the plant with magnetically treated water.

  Thirty years ago, in the Soviet Union, a study was conducted to increase yields by applying magnetic treatment to rainwater and supplying it to crops. It has been reported that when magnetically treated water through a magnetic field is sprayed on crops, cereals and beans increased by 38% and cucumber increased by 37%. Research is underway at the Volga Land Improvement Institute and it is used in greenhouse agriculture.

  In addition, it was confirmed by measurement that the amount of dissolved oxygen in rainwater was larger than that in tap water. FIG.5 (b) has shown the measurement result of the dissolved oxygen amount of rainwater and tap water. The amount of dissolved oxygen in tap water was 9.3 to 9.5 (mg / l), whereas the amount of dissolved oxygen in rainwater was 9.5 to 9.8 (mg / l).

(2) Washing water According to the knowledge of the inventor, when magnetized water was used for bathing, it was possible to remove dirt without using soap or shampoo. As a result, skin epidermis, oil, sweat and dust could be removed.

  In addition, according to the inventor's knowledge, the scale in the bathtub could be easily cleaned by applying water magnetically treated in the shower. When magnetized water was used as water in the bathtub, it could be used up for a week, and no odor was generated during that time. As a result, water charges were reduced.

  In addition, according to the knowledge of the inventor, when a magnetic treatment device is attached to hot water and cold water hoses for supplying water to an automatic washing machine and magnetic treatment is performed, the laundry is well cleaned and no smell is lost. For example, shirt collars often get dirty.

  Furthermore, according to the inventor's knowledge, when a magnetic treatment unit is installed near the inlet of the water pipe of the washing toilet seat, and the magnetically treated water is supplied, the warm water for washing is soft and comfortable, and the toilet bowl is conspicuous. Absent.

(3) Removal of metal rust in water According to the experiment of the inventor, when magnetically treated water is used, the pump valve is not clogged with red rust. Also, the clogging of the hose is eliminated.

(4) Purification of environmental water According to the experiment of the inventor, when the muddy river water (red water) flowing at the foot of Asama is magnetically processed by the magnetic processing apparatus 10 according to the embodiment and stored in a plastic bottle, impurities are collected in 4 days. Precipitated and became clear. On the other hand, water that was not magnetically treated took 1 month, and impurities precipitated and became transparent water. Thus, it can be understood that precipitation of impurities is promoted by magnetic treatment of river and lake water.

  The magnetic processing apparatus according to the present invention can be disposed directly in the middle of the conduit, and the fluid can efficiently apply the magnetic lines of force directly to the magnet, and thus has industrial applicability.

10: Magnetic processing device 11: Inflow channel 12: Discharge channel 13: Ambient channel 14: Internal channel 20: Magnetizing members 21, 22, 23, 24, 25: Ring magnets 21A, 22A, 23A, 24A 25A: Holes 21a, 22a, 23a, 24a, 25a: End face parts 21b, 22b, 23b, 24b, 25b: End face part 22: Ring-shaped magnet 26: Heat-shrink sheet 30: Case member 40: Cover member 41: Magnetization Member housing portion 41A: cylindrical portion 41B: tapered portion 42: connecting portion 42A: hexagonal shape portion 43: connecting flange portion 44: fixed piece 45: peripheral channel forming member 46: bolt insertion hole 47: circumferential groove portion 50: cover member 52: Connection portion 53: Flange portion 57: Circumferential groove portion 60: Magnet fixing member 70: Fixing member main body 71: Head portion 72: Shaft portion 73: Tip portion 74: Column portion 75: Extension plate portion 77: Fan-shaped hole Part 0: Nut member 90: fastening bolt 100: sealing material

(3) Removal of metal rust in water According to the experiment of the inventor, when magnetically treated water is used, the valve of the pump is not clogged with red rust . Also, the clogging of the hose is eliminated.

Claims (4)

A plurality of ring-shaped magnets, each having a hole through which fluid can flow, are arranged in an array with the holes communicating so that the fluid can flow and the end surfaces facing each other, and the fluid is magnetically processed. A magnetizing member that
An outer peripheral flow path through which the fluid can flow is formed between the outer peripheral surface of the magnetized member to cover the periphery of the magnetized member, and discharge of the fluid magnetically processed by the fluid introduction conduit and the magnetized member A case member to which the conduit is connected;
With
The plurality of ring-shaped magnets are arranged so that end faces facing each other have the same magnetic pole. The case member is composed of two cover members,
Each of the cover members is disposed in the vicinity of the magnetized member, and a magnetized member storage portion that fixes the magnetized member so as to form a peripheral flow path having a ring-shaped cross section with the magnetized member;
A connection part connected to one end of the magnetized member housing part, to which one of the introduction conduit and the discharge conduit is connected;
A connection flange portion provided at the other end of the magnetized member storage portion and connected to another cover member;
The magnetic processing apparatus according to claim 1, comprising:   A flow path limiting member that is inserted along the axis of the hole portion of the ring-shaped magnet disposed in plurality and forms a flow channel having a ring-shaped cross section with the inner periphery of the hole portion of the ring-shaped magnet; The magnetic processing apparatus according to claim 1, wherein:   The magnetic processing according to claim 3, further comprising: a magnet fixing member that aligns and fixes the plurality of ring-shaped magnets at predetermined intervals, and the magnet fixing member also serves as the flow path limiting member. apparatus.