JP2013248540A - Ferromagnetic filter, impurity removal device provided with the same, and method of removing impurity - Google Patents

Abstract

PROBLEM TO BE SOLVED: To remove a foreign material or impurity, which does not remain on a porous part of a conventional sintered metal filter, from a fluid; and to remove a target substance having a size far smaller than that of the size of the porous part by using an impurity removal device in combination with other specific particles.SOLUTION: An impurity removal device is produced by sintering a plurality of metal spheres containing a ferromagnetic material. The device includes: one or more filters 5a capable of passing through a fluid; and one or more magnets 2a, 2b disposed close to the filters 5a to magnetize at least one part of the filters 5a. When the fluid containing an impurity comprising a ferromagnetic material is made to pass through the filters 5a, the impurity is attracted by the filters 5a and can be removed from the fluid.

Description

  The present invention relates to a filter for fluid, and more particularly to a sintered metal filter that can be magnetized.

  Conventionally, a sintered metal filter has been used to remove foreign matters and impurities in a fluid containing a liquid such as water or petroleum, or a gas such as air or combustible gas. Sintered metal is a metal material produced from a solid metal powder by using a phenomenon in which an aggregate of solid powder is heated to a temperature lower than the melting point and becomes a compact body called a sintered body.

  Depending on the shape and size of the solid metal powder as the material, pores are formed in the sintered metal. When a fluid is passed through the sintered metal having such pores, foreign matters and impurities in the fluid are accumulated in the porous (hole) portion, and as a result, the foreign matters and impurities are removed from the fluid. From this property, if the sintered metal is cut or molded into a desired shape, it can be used as a filter.

  Sintered metal filters that have been manufactured and used in the past are mainly made of non-magnetic materials such as copper and its alloys, such as copper and austenitic stainless steel. According to such a sintered metal filter of a weak magnetic material, only foreign matters and impurities accumulated in the porous portion by passing a fluid can be removed, and foreign matters and impurities not accumulated in the porous portion can be removed. Absent.

  In addition, with a conventional sintered metal filter, it is almost impossible to remove a substance composed of particles much smaller than the size of the porous portion of the filter from the fluid. Therefore, when there is a hygienic advantage that molds and germs are less likely to propagate compared to filters made of synthetic resin, sintered metal is required when it is necessary to remove very fine particles. There was a problem that the filter itself was not selected.

  On the other hand, when a metal mesh or a sponge made of synthetic resin is used instead of the sintered metal filter, the gap portion of the metal mesh and the porous portion of the sponge are clogged immediately. This necessitates frequent replacement of the wire mesh, sponge, etc., which places a heavy burden on the user in terms of cost and effort.

  The problem to be solved by the present invention is to remove foreign matters and impurities that do not accumulate in the porous portion in the conventional sintered metal filter from the fluid. A further problem to be solved by the present invention is to remove a target substance, which is much smaller than the size of the porous portion, from the fluid by using it in combination with other specific particles.

  The impurity removing device according to the present invention is manufactured by sintering a plurality of metal spheres including a ferromagnetic material, and allows at least a part of the filter to magnetize one or more filters capable of passing a fluid. And having one or more magnets disposed in proximity to the filter, and when the fluid having impurities including a ferromagnetic material is passed through the filter, the impurities are attracted to the filter, thereby Impurities can be removed, which solves the above problem.

  Another impurity removal device according to the present invention includes one or more filters capable of passing a fluid, including a plurality of metal spheres including a ferromagnetic material, and the filter to magnetize at least a portion of the filter. One or more magnets arranged in proximity to each other, and removing impurities from the fluid by attracting the impurities to the filter when a fluid having impurities including a ferromagnetic material is passed through the filter. This solves the above problem.

  Each of the impurity removing devices may further include a case for covering the filter, the number of the magnets may be two, and the two magnets may be arranged to face each other with the case interposed therebetween. Further, each of the cross sections of the two magnets may be a U shape or a U shape in which left and right are reversed.

  Alternatively, each of the impurity removing devices further includes a case for covering the filter, the number of the magnets is four, two of the four magnets are arranged to face each other across the case, Another two of the four magnets may be arranged to face each other across the case.

  Or each said impurity removal instrument is further provided with the case for covering the said filter which has a cylindrical part at least, The shape of the said filter is the continuous solid which one end is a column shape and the other end is a cylindrical shape, Alternatively, it may be columnar or cylindrical.

  In each said impurity removal instrument, the material of the said filter may be iron type, nickel type, or stainless steel.

  The ferromagnetic filter according to the present invention is manufactured by sintering a plurality of metal spheres including a ferromagnetic material, and is capable of passing a fluid, thereby solving the above-described problem.

  Another ferromagnetic filter according to the present invention includes a plurality of metal spheres including a ferromagnetic material, and a container that holds the plurality of metal spheres inside and allows fluid to pass from the outside to the inside. This solves the above problem. The diameter of the metal sphere may be 3 millimeters or less, and the material of the filter may be iron, nickel, or stainless steel.

  A method of manufacturing a ferromagnetic filter capable of passing a fluid according to the present invention includes placing a plurality of metal spheres including a ferromagnetic material in a mold, and sintering the plurality of metal spheres. This solves the above problem.

  The method for removing impurities from a fluid according to the present invention includes one or more filters capable of passing a fluid manufactured by sintering a plurality of metal spheres including a ferromagnetic material, and at least one of the filters. Passing a fluid having impurities including a ferromagnetic material through the filter in an impurity removing device having one or more magnets arranged in proximity to the filter so as to magnetize a portion; The above problem is solved by attracting the impurities in the fluid.

  The method may further include adding a ferromagnetic material that adsorbs a specific substance into the fluid before passing a fluid having impurities including the ferromagnetic material through the filter. The specific substance may be cesium.

  According to the impurity removing instrument and the impurity removing method including the ferromagnetic filter of the present invention, it is possible to easily remove foreign matters and impurities having ferromagnetism from a fluid such as air, water, and oil. Further, by determining the dimension of the porous portion of the filter according to the application, it is possible to remove foreign matters and impurities that do not have ferromagnetism from the fluid. Furthermore, by adding a ferromagnetic material that adsorbs a specific substance to the fluid, it is possible to remove impurities of weak magnetic material and nonmagnetic material from the fluid.

  In the impurity removing instrument of the present invention, since the internal ferromagnetic filter can be replaced, the instrument can be maintained in a sanitary and safe state. In particular, when removing radioactive cesium, a large amount of radioactive material adheres to the internal ferromagnetic filter, but by disposing of the internal ferromagnetic filter, the impurity removing device itself should be used continuously. Is possible.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1A is a perspective view of an impurity removing device according to the present invention. FIG. 1B is a perspective view of the impurity removal instrument of FIG. 1A rotated 90 ° about the axis AA ′. The impurity removing device of the present invention includes a case 1 including a ferromagnetic filter therein, two magnets 2 a and 2 b attached in proximity to the case 1, and a joint 3.

  1A and 1B, the magnets 2a and 2b are provided to face each other with the case 1 interposed therebetween. The case 1 is made of any material capable of passing magnetism, and the internal shape thereof will be described later. The case 1 is preferably made of metal or synthetic resin having a thickness of about 0.5 to 5 mm. The case 1 may be integrally molded, but may be a combination of a plurality of parts, for example, a metal side surface and a synthetic resin bottom surface may be assembled.

  The magnets 2a and 2b are known permanent magnets or electromagnets, and have a property of attracting ferromagnetic materials such as iron and nickel. The magnets 2a and 2b are preferably strong neodymium permanent magnets. The magnets 2a and 2b are fixed on the side surface of the case 1 by any means such as bolts, nuts, and adhesives. When the case 1 is a ferromagnetic metal and the magnets 2a and 2b have a strong magnetic force, the fixing means as described above may not exist. In addition, the magnets 2a and 2b do not necessarily need to be in contact with the case 1 as long as they exert a magnetic force on the inside of the case 1, and are fixed to the side surface of the case 1 by fixing means outside the case 1 that do not contact the case 1. It may be fixed in a close state. Arbitrary covers or the like that do not completely lose their magnetic force may be attached to the magnets 2a and 2b.

  1A and 1B, a joint 3 for connecting to a hose (not shown) is attached to the upper right portion of the case 1. The joint 3 is made of an arbitrary material, preferably a metal or a synthetic resin having a thickness of about 0.5 to 5 mm. The hose is made of rubber, metal, synthetic resin, or the like that matches the inner or outer diameter of the connecting portion 3a of the joint 3.

  2A is a cross-sectional view of the impurity removal instrument of FIG. 1A cut along a plane including an axis AA ′. In FIG. 2A, illustration of the ferromagnetic filter and the magnets 2a and 2b in the case 1 is omitted. A valve or cock 4 for adjusting the flow rate of the fluid passing through the case 1 is provided at the lower part of the case 1. An O-ring is usually sandwiched between the upper end of the case 1 and the joint 3, but the illustration is omitted in FIG. 2A.

  2B is a cross-sectional view of an impurity removing device having a configuration different from that shown in FIG. 1A. The configuration of FIG. 2B is different from the configuration of FIG. 1A in that the portion corresponding to case 1 of FIG. 1A is divided into case 1a and lower joint 1b. Therefore, the shape of the case 1a in FIG. 2B is cylindrical. Also, the shape of the upper joint 3b is different from the joint 3 of FIG. 1A that matches the outer diameter of the case 1 in that it matches the inner diameter of the case 1a. In FIG. 2B as well, the ferromagnetic filter in the case and the magnet on the side surface of the case are omitted as in FIG. 2A.

  The advantage of the configuration shown in FIG. 2B is that it is possible to combine flexible materials as necessary, for example, the case 1a is made of metal and the lower joint 1b is made of synthetic resin. Moreover, since the shapes of the case 1a, the lower joint 1b, and the upper joint 3b are simpler than those of the case 1 and the joint 3 in FIG. 1A, there is an advantage that it is easy to increase productivity and reduce manufacturing costs. On the other hand, the impurity removing instrument of FIG. 2B has a drawback that the strength of the entire apparatus is inferior to that of the impurity removing instrument of FIG. 1A.

  In the above configuration example of the impurity removing device, the case and the joint are joined by any means such as fixing with screws, fitting, welding, and the like.

  FIG. 3A is a perspective view of a ferromagnetic filter included in the impurity removing instrument of the present invention. The ferromagnetic filter 5a is configured by sintering a large number of metal spheres, and the outer shape thereof is cylindrical. The ferromagnetic filter 5a has a number of porous parts between sintered metal spheres, and the presence of the porous parts allows fluids such as water, air, and oil to pass through. . A method for manufacturing the ferromagnetic filter 5a and the detailed structure thereof will be described later.

  FIG. 3B is a perspective view of a ferromagnetic filter of the present invention different from that shown in FIG. 3A. Unlike the ferromagnetic filter 5a shown in FIG. 3A, the outer shape of the ferromagnetic filter 5b is cylindrical. Similarly to the ferromagnetic filter 5a, the ferromagnetic filter 5b is manufactured by sintering a large number of metal spheres, and a plurality of porous portions capable of allowing fluid to pass between the sintered metal spheres. Have. In the ferromagnetic filter 5b, the passage of fluid is higher than that of the ferromagnetic filter 5a by providing a space having no filter effect at the center of the cylinder.

  4A is a cross-sectional view of the impurity removal instrument of FIG. 1A cut along a plane perpendicular to an axis AA ′ including a cutting line BB ′. As shown in FIG. 4A, the case 1 covers a ferromagnetic filter 5 having an outer diameter smaller than its inner diameter. The ferromagnetic filter 5 is assumed to be the ferromagnetic filter 5a shown in FIG. 3A, but instead of this, for example, the ferromagnetic filter 5b shown in FIG. 3B may be used. When the ferromagnetic filter 5b is used, a circular space is generated at the center of the cross section.

  As described above, the magnets 2a and 2b are arranged to face each other with the case 1 interposed therebetween, and thereby magnetize part or all of the ferromagnetic filter 5. Since the magnetic force is approximately inversely proportional to the cube of the distance from the magnet, in the ferromagnetic filter 5, the closer the distance from the magnets 2a and 2b, the stronger the magnetic force.

  In FIG. 4A, there is a slight gap between the case 1 and the ferromagnetic filter 5, but this gap may be reduced or eliminated in order to enhance the filter removal effect. Also, in the case of FIG. 2B in which the configuration of the case and the joint is different from that of FIG. 1A, the cross section perpendicular to the cross section of FIG.

  4B and 4C are cross-sectional views of the impurity removing device when the magnet arrangement different from that shown in FIG. 4A is performed. As shown in FIG. 4B, two pairs of magnets 2a and 2b and magnets 2c and 2d that face each other may be arranged with the case 1 interposed therebetween. Preferably, the magnets 2a to 2d are arranged every 90 degrees around the central axis of the case 1 as shown in FIG. 4B. FIG. 4C shows an example in which a magnet 2e having a U-shaped cross section that is reversed left and right and a magnet 2f having a U-shaped cross section are arranged facing each other with the case 1 in between. 4B and 4C each increase the strength of the magnetic force applied to the ferromagnetic filter 5 as compared with the case of FIG. 4A.

  For ease of understanding, in FIG. 4A to FIG. 4C, the portion where the ferromagnetic filter exists is represented by diagonal lines, but the appearance of the ferromagnetic filter is as shown in FIG. 3A and FIG. 3B. Is as described above, and a cross section of a plurality of sintered metal spheres appears in the cross section of the ferromagnetic filter.

  In the above example, the number of magnets included in the impurity removing device has been described as two or four, but this is a plurality of magnets in order to enhance the effect of removing impurities. If one or more magnets are present in the impurity removal instrument, it is possible to achieve the object of the present invention.

  5A to 5D are explanatory views showing the operation of the impurity removing device of the present invention. 5A to 5D are cross-sectional views, and the structure of the case and the joint of the impurity removing device is the same as that shown in FIG. 2B. 5A to 5D, all arrows indicate the fluid passage directions. Similar to FIGS. 4A to 4C, in FIGS. 5A to 5D, the portion where the ferromagnetic filter exists is represented by diagonal lines, but a plurality of metal spheres originally sintered in the cross section of the ferromagnetic filter. As described above, the cross section of

  First, FIG. 5A is an example in which the ferromagnetic filter 5a shown in FIG. 3A is used. The fluid that has flowed in through the flow path of the upper joint 3b enters the ferromagnetic filter 5a, proceeds downward in the ferromagnetic filter 5a, passes through the ferromagnetic filter 5a, and finally passes through the lower joint. It goes out to the flow path of 1b.

  As described above, since the ferromagnetic filter 5a is magnetized around the portions close to the magnets 2a and 2b, the ferromagnetic material such as iron and nickel contained in the fluid is the surface inside the ferromagnetic filter 5a. Alternatively, it is attracted to the ferromagnetic filter 5a in the porous portion and cannot flow any further. As a result, the amount of the ferromagnetic material contained in the fluid coming out from the flow path of the lower joint 1b is smaller than the amount of the ferromagnetic material contained in the fluid entering from the flow path of the upper joint 3b. It can be said that the ferromagnetic material which is an impurity is removed by 5a.

  Further, particles of impurities contained in the fluid that are larger than the porous part of the ferromagnetic filter 5a or particles that are close to the size of the porous part and are caught in the porous part are contained in the ferromagnetic filter 5a. Since it cannot pass through the porous portion, it is removed by the ferromagnetic filter 5a regardless of the presence or absence of magnetism.

  Next, FIG. 5B is an example in which the ferromagnetic filter 5b shown in FIG. 3B is used. The fluid that has flowed in through the flow path of the upper joint 3b passes through the hollow portion inside the ferromagnetic filter 5b and exits to the flow path of the lower joint 1b. In the meantime, only the ferromagnetic substance contained in the fluid is attracted to the magnetized ferromagnetic filter 5b and does not flow while staying on the surface or the porous part. Similar to the case of FIG. 5A, particles caught by the porous part with particles close to the size of the porous part of the ferromagnetic filter 5b can be removed.

  Next, FIG. 5C is an example in the case of using a ferromagnetic filter 5c in which only the lowermost part is cylindrical and the other part is cylindrical. The fluid that has flowed in through the flow path of the upper joint 3b flows toward the hollow portion of the ferromagnetic filter 5c, and from there the gap between the case 1a and the filter 5c (in the left-right direction in FIG. 5C), or the lower portion It flows toward the flow path (downward in FIG. 5C) of the joint 1b. At that time, since the fluid passes through any part of the magnetized ferromagnetic filter 5c, the ferromagnetic material in the fluid is attracted to the surface or the porous portion of the ferromagnetic filter 5c and does not flow.

  Even in the case of FIG. 5C, particles larger than the porous portion of the ferromagnetic filter 5c and particles caught on the porous portion by particles close to the size of the porous portion are removed by the ferromagnetic filter 5c regardless of the presence or absence of magnetism. Is done. Note that the fluid that flows in the gap between the case 1a and the ferromagnetic filter 5c finally flows toward the flow path of the lower joint 1b.

  Finally, FIG. 5D is a type in which a circular plate 1c that does not allow fluid to pass is attached to the bottom surface of a cylindrical ferromagnetic filter 5d. The length of the ferromagnetic filter 5d is also cylindrical, which is slightly shorter than the length of the ferromagnetic filter 5b shown in FIG. 3B. The plate 1c is an arbitrary member that does not allow fluid to pass, and preferably the material thereof is metal or synthetic resin.

  Also in the case shown in FIG. 5D, the fluid that has flowed in through the flow path of the upper joint 3b flows toward the hollow portion of the ferromagnetic filter 5d. However, since the fluid cannot flow downward due to the presence of the plate 1c, the fluid flows through the magnetized ferromagnetic filter 5d toward the gap between the case 1a and the ferromagnetic filter 5d (in FIG. 5D, the horizontal direction). ). At that time, the ferromagnetic material in the fluid is attracted to the surface of the ferromagnetic filter 5d or the porous portion and does not flow.

  Even in the case of FIG. 5D, particles larger than the porous portion of the ferromagnetic filter 5d and particles caught on the porous portion by particles close to the size of the porous portion are removed by the ferromagnetic filter 5d regardless of the presence or absence of magnetism. Is done. Thereafter, the fluid in the gap portion flows downward, and finally reaches the flow path of the lower joint 1b.

In the description of FIGS. 5A to 5D, particles smaller than the porous portion of the ferromagnetic material and the ferromagnetic filter are removed from the fluid, but a specific substance is added to the fluid before entering the upper joint 1b. By adding an adsorbing ferromagnetic material, the specific substance can be removed regardless of the size of the particles of the specific substance and the presence or absence of magnetism. For example, Prussian blue (Fe (III) ₄ [Fe (II) (CN) ₆ ] ₃ ) is known to selectively adsorb cesium. For example, Prussian blue is added to water before entering the upper joint 1b. If it is added, cesium containing radioactive cesium can be removed from water.

  About radioactive cesium, the diffusion has become a problem now in each region in Japan centering on eastern Japan, but according to the ferromagnetic filter and the impurity removing device of the present invention, by using the above method, The radioactive cesium can be efficiently removed from the fluid including water.

FIG. 6 is an explanatory view showing a method for manufacturing a ferromagnetic filter of the present invention. Each drawing in FIG. 6 is a cross-sectional view, and the manufacturing process proceeds in the direction of the double-lined arrow (from top to bottom). First, as shown in the upper part of FIG. 6, a large number of metal balls 11 are poured into the mold 10. The material of the mold 10 is preferably stainless steel, carbon, ceramic or the like. Many of the metal balls 11 include a ferromagnetic material, and the material thereof is, for example, iron-based, nickel-based, ferrite-based stainless steel, and the diameter thereof is about several microns to 3 mm. Examples of iron-based and nickel-based materials include nickel-iron alloy, iron-cobalt alloy, and triiron tetroxide (Fe ₃ O ₄ ) in addition to iron and nickel. Carbon and copper may be added to each material in order to improve sinterability.

  Then, as shown in the center of FIG. 6, a large number of metal balls 11 are filled in all the cavities of the mold 10. The shape of the cavity of the mold 10 into which the metal sphere 11 is poured is matched to the shape of the ferromagnetic filter to be manufactured. For example, when manufacturing the ferromagnetic filters 5a and 5b shown in FIGS. 3A and 3B. The shape of the cavity is a columnar shape or a cylindrical shape.

  A large number of filled metal balls 11 are sintered together with the mold 10. That is, the mold 10 is heated to a certain temperature lower than the melting point of the many metal balls 11 and the metal balls 11 are sintered as they are. The constant temperature is, for example, 1100 to 1300 degrees Celsius, and the mold 10 may be evacuated. After the sintering is finished, heating of the mold 10 is stopped, and the ferromagnetic filters 5a and 5b are taken out from the mold 10 after the mold 10 returns to room temperature (lower side in FIG. 6).

  7A and 7B are perspective perspective views showing the fine structure of the ferromagnetic filter of the present invention, and each part in the lower right dotted line is a partially enlarged view. As shown in FIGS. 7A and 7B, the sintered metal spheres 11a and 11b are ideally coupled to other metal spheres in 6 or 12 directions. When coupled in 6 directions as shown in FIG. 7A, the porous portion 12a is provided in the gap between the metal balls 11a, and when coupled in 12 directions as shown in FIG. 7B, the porous portion 12b is provided in the gap between the metal balls 11b. Have The porous portions 12a and 12b are gaps through which fluid and impurities can pass, and an object smaller than the porous portions 12a and 12b cannot pass through the ferromagnetic filter regardless of the presence or absence of magnetism. In general, the porous portion 12b is narrower than the porous portion 12a. Since the size of the porous portion is determined according to the diameter of the metal sphere, the diameter of the metal sphere 11 as a material is selected according to the type of fluid and the use of the ferromagnetic filter.

  In each of the above embodiments, instead of the ferromagnetic filters 5a and 5b, it is also possible to use a ferromagnetic filter in which a metal sphere containing a plurality of ferromagnetic substances is simply put in a container. In this case, the container is provided with pores having a size that prevents the metal sphere from passing therethrough, or the container is formed of a synthetic resin having a property of allowing the target fluid to pass therethrough. Such a ferromagnetic filter has a drawback that the shape of the set of metal balls inside is deformed when a fluid is flowed at a high pressure, but the shape of the filter can be freely changed by changing the shape of the container. There is an advantage that can be set to.

  In addition, the shape of the ferromagnetic filter and the case in each of the above-described embodiments is an exemplification. Actually, the ferromagnetic filter and the case have a rectangular parallelepiped shape, a triangular prism shape, or the like as long as their functions are not impaired. Any shape can be taken. In addition, when a plurality of metal spheres are used in the above description, since metal powder having spherical particles is usually used, there may be variations in the particle shape. However, even if there is a variation in the particle shape as described above, the impurity removal function of the ferromagnetic filter is not impaired, and therefore the object of the present invention can be achieved.

  It can be applied to removal of iron powder contained in factory wastewater, removal of iron such as drinking water, removal of iron in agricultural and forestry water, removal of cesium, and removal of other magnetized foreign matter.

It is a perspective view of the impurity removal instrument by this invention. FIG. 1B is a perspective view of the impurity removing instrument of FIG. 1A rotated 90 ° about the axis AA ′. It is sectional drawing which cut | disconnected the impurity removal instrument of FIG. 1A by the plane containing axis | shaft AA '. It is sectional drawing of the impurity removal instrument of a different structure from what was shown to FIG. 1A. It is a perspective view of the ferromagnetic filter contained in the impurity removal instrument of the present invention. It is a perspective view of the ferromagnetic material filter of this invention different from what was shown to FIG. 3A. It is sectional drawing which cut | disconnected the impurity removal instrument of FIG. 1A by the plane perpendicular | vertical to axis | shaft AA 'containing cutting line BB'. It is sectional drawing of the impurity removal instrument in the case of arranging the magnet different from FIG. 4A. It is sectional drawing of the impurity removal instrument in the case of arranging the magnet different from FIG. 4A. It is explanatory drawing which shows the effect | action of the impurity removal instrument of this invention. It is explanatory drawing which shows the effect | action of the impurity removal instrument of this invention. It is explanatory drawing which shows the effect | action of the impurity removal instrument of this invention. It is explanatory drawing which shows the effect | action of the impurity removal instrument of this invention. It is explanatory drawing which shows the manufacturing method of the ferromagnetic material filter of this invention. It is a perspective perspective view which shows the fine structure of the ferromagnetic material filter of this invention. It is a perspective perspective view which shows the fine structure of the ferromagnetic material filter of this invention.

1, 1a Case 1b Lower joint 1c Plate 2a, 2b, 2c, 2d, 2e, 2f Magnet 3 Joint 3b Upper joint 4 Valve or cock 5, 5a, 5b Ferromagnetic filter 10 Mold 11 Metal ball 11a, 11b Sintered Metal balls 12a, 12b Porous part

Claims (15)

One or more filters capable of passing a fluid produced by sintering a plurality of metal spheres including a ferromagnetic material;
One or more magnets disposed proximate to the filter so as to magnetize at least a portion of the filter;
An impurity removing device capable of removing impurities from the fluid by attracting the impurities to the filter when a fluid containing impurities including a ferromagnetic material is passed through the filter. One or more filters capable of passing a fluid, comprising a plurality of metal spheres comprising a ferromagnet;
One or more magnets disposed proximate to the filter so as to magnetize at least a portion of the filter;
An impurity removing device capable of removing impurities from the fluid by attracting the impurities to the filter when a fluid containing impurities including a ferromagnetic material is passed through the filter. A case for covering the filter;
The impurity removal instrument according to claim 1 or 2, wherein the number of magnets is two, and the two magnets are arranged to face each other with the case interposed therebetween.   The impurity removing device according to claim 1 or 2, wherein each of the two magnets has a U-shaped cross section or a U-shaped shape in which left and right are reversed. A case for covering the filter;
The number of the magnets is four, two of the four magnets are arranged to face each other across the case, and another two of the four magnets are arranged to face each other across the case. Moreover, the impurity removal instrument of Claim 1 or 2. A case for covering the filter having at least a cylindrical portion;
The impurity removing device according to claim 1 or 2, wherein the shape of the filter is a continuous solid having one columnar shape at one end and a cylindrical shape at the other end, or a columnar shape or a cylindrical shape.   The impurity removing instrument according to any one of claims 1 to 6, wherein a material of the filter is iron, nickel, or stainless steel. One or more filters capable of passing a fluid produced by sintering a plurality of metal spheres including a ferromagnetic material;
Passing an impurity-containing fluid containing a ferromagnetic substance through the filter in an impurity removing device including one or more magnets disposed in proximity to the filter so as to magnetize at least a portion of the filter. ,
A method of removing impurities from within a fluid comprising attracting the impurities in the fluid to the filter.   8. The method of claim 7, further comprising adding a ferromagnetic material that adsorbs a particular substance into the fluid prior to passing a fluid having impurities including the ferromagnetic material through the filter.   The method of claim 8, wherein the specific substance is cesium.   A ferromagnetic filter capable of passing a fluid, which is manufactured by sintering a plurality of metal spheres including a ferromagnetic material. A plurality of metal spheres including a ferromagnet;
A ferromagnetic filter comprising a container that holds the plurality of metal spheres inside and allows fluid to pass from the outside to the inside.   The ferromagnetic filter according to claim 11 or 12, wherein a diameter of the metal sphere is 3 millimeters or less.   The ferromagnetic filter according to claim 11, wherein a material of the filter is iron, nickel, or stainless steel. Putting a plurality of metal spheres containing ferromagnetic materials in the mold,
A method of manufacturing a ferromagnetic filter capable of passing a fluid, comprising sintering the plurality of metal spheres.