KR20200103819A - Rod-shaped magnet and magnetic foreign matter removal device - Google Patents

Abstract

A rod-shaped magnet and a magnetic foreign material removing device capable of reducing the adsorption of magnetic foreign matters while suppressing the retention of magnetic foreign matters are provided. The magnetic foreign matter removing device 50 includes a casing 51 having an inlet 53 and an outlet 55, and a plurality of rod-shaped magnets 10 disposed in the casing 51 and extending in the shape of a rod having a predetermined length. ), and the rod-shaped magnet 10 includes a pair of suction surfaces 29 and 29 extending in a predetermined length so as to be parallel to each other when viewed from a cross section orthogonal to the axial direction thereof. And, it is installed at one end side of the adsorption unit 30, and has a guide unit 28 for guiding the magnetic foreign matter M to the adsorption unit 30, the rod-shaped magnets 10 are parallel with a predetermined distance, In addition, a plurality of one end 23 is arranged in parallel in the casing 51 with the side facing the advancing direction of the powder or granular material.

Description

Rod-shaped magnet and magnetic foreign matter removal device

The present invention relates to a rod-shaped magnet and a magnetic foreign matter removal device for adsorbing and removing magnetic foreign matter from powder or granular material or fluid containing magnetic foreign matter.

For example, mixing of foreign matters must be strictly excluded in powder or granular material used as a food raw material such as wheat flour. As an apparatus for removing magnetic foreign matter from such a powder or granular material, for example, it is known to have a casing into which the powder or granular material is introduced and a magnet having a circular cross section disposed therein. Then, when the powder or granular material is introduced from the upper opening of the casing, the magnetic foreign material M is adsorbed to the magnet, so that the magnetic foreign material can be removed from the powder and granular material.

However, in the case of the above device, since the cross section of the magnet has a circular shape, there is a problem that the powder and granular material introduced from the upper side of the casing gathers on the upper surface side of the magnet, so that the magnetic adsorption efficiency gradually decreases.

In order to solve the above problems, in Patent Document 1, a pear-shaped rod-shaped magnet having a tear-shaped cross-sectional shape is described. As shown in FIG. 8B, the cross-sectional shape of the upper portion of the rod-shaped magnet 100 forms a mountain shape having a thin upper end and a tapered surface gradually widening toward the lower end. The cross-sectional shape forms a hemispherical shape. Further, the rod-shaped magnet 100 is disposed in the casing 110 with an open upper side. Further, the powder or granular material G injected from the upper opening of the casing 110 is apt to slide downward by the tapered surface of the upper part forming a mountain shape, so that the powder or granular material G is difficult to collect in the upper part.

Japanese Utility Model Registration No. 3164152 Gazette

By the way, in the above-described circular cross-sectional magnet or the rod-shaped magnet 100 described in Patent Document 1, a plurality of magnets are arranged in parallel so that the side surfaces of the same pole face each other in order to increase the attraction force of magnetic foreign matter. In this way, magnetic force is concentrated between opposite side surfaces of adjacent magnets to generate a strong magnetic field, and it is possible to facilitate adsorbing magnetic foreign matter on the side surface of the magnet by this magnetic field. In this case, the magnetic field becomes strong at the point where the side surfaces of the adjacent magnets are closest to each other, thereby increasing the adsorption force. For example, as shown in Fig. 8B, in the rod-shaped magnet 100 having a tear-shaped cross section, a strong magnetic field is generated only at the boundary P between the mountain-shaped upper portion and the hemispherical lower portion. It is designed to adsorb magnetic foreign matter.

However, in the rod-shaped magnet 100 having a tear-shaped cross section shown in Fig. 8B, the boundary P where the strong magnetic field is generated between adjacent magnets has a linear shape (along the axial direction of the rod-shaped magnet). It is not possible to secure a wide area in which a strong magnetic field is generated. Therefore, there is a tendency that it is impossible to sufficiently reduce the adsorption omission of magnetic foreign matters because there is a limit to the adsorption amount of magnetic foreign matters.

Accordingly, an object of the present invention is to provide a rod-shaped magnet and a magnetic foreign material removing device capable of reducing the adsorption omission of magnetic foreign matter while suppressing the retention of magnetic foreign matter.

In order to achieve the above object, one of the present invention is a rod-shaped magnet extending in a rod shape of a predetermined length for adsorbing the magnetic foreign substance by a magnetic field from a powder or granular material or a fluid containing a magnetic foreign substance, the rod-shaped magnet Silver, when viewed from a cross section orthogonal to the axial direction, is provided with a pair of adsorption surfaces extending in a predetermined length so as to be parallel to each other, and is provided at one end of the adsorption unit to transfer the magnetic foreign matter to the adsorption unit. It characterized in that it has a guide portion to guide.

According to the above invention, when the powder or granular material or fluid to be removed from the magnetic foreign matter from the powder or granular material is moved toward one end of the rod-shaped magnet, the powder or granular material or the fluid is provided by the guide portion of the rod-shaped magnet. Since it is difficult to stay on one end of the magnet, it is possible to guide smoothly toward the adsorption part, and since the pair of adsorption surfaces of the adsorption part extend to a predetermined length so as to be parallel to each other, the adsorption surface where a strong magnetic field is generated , Since it is possible to have a conventional cross-section in a plane extending in a direction orthogonal to the axial direction of the rod-shaped magnet, not a line like the boundary P of a tear-shaped rod-shaped magnet (see FIG. 8B). It is possible to secure a wide area of the area where the magnetic field is generated, and as a result, it is possible to reliably adsorb magnetic foreign matter contained in the powder or granular material or fluid. It is possible.

In the rod-shaped magnet of the present invention, it is preferable that a shape suitable for the outer periphery of the rod-shaped magnet is provided and a cover made of a non-magnetic material is provided, and the rod-shaped magnet is configured to be inserted and detachable in the cover.

According to the above aspect, the rod-shaped magnet is formed in a shape suitable for the outer periphery of the rod-shaped magnet and is provided with a cover made of a non-magnetic material, and the rod-shaped magnet is inserted and detachable in the cover. When the removal operation of the magnetic foreign matter from the powder or granular material or the fluid is performed, it is possible to adsorb the magnetic foreign matter to the cover surface by the magnetic force of the rod-shaped magnet. Further, after the magnetic foreign matter is adsorbed, since the magnetic force is lost by removing the rod-shaped magnet from the inside of the cover, it is possible to separate and separate the magnetic foreign matter from the cover surface. That is, the magnetic foreign matter is adsorbed through the cover, and since the magnetic foreign matter is not directly adsorbed to the rod-shaped magnet, cleaning of the rod-shaped magnet becomes unnecessary, and the workability of removing the magnetic foreign matter can be improved.

In the rod-shaped magnet of the present invention, the rod-shaped magnet is formed by connecting a plurality of magnets in the axial direction, and it is preferable that the bonding surfaces of the magnets constituting the rod-shaped magnet are made of the same poles.

According to the above aspect, the rod-shaped magnet is formed by connecting a plurality of magnets in the axial direction, and since the bonding surfaces of the magnets constituting the rod-shaped magnet are made of the same poles, the range in which the magnetic field acts strongly, It is possible to increase in the axial direction of the rod-shaped magnet, and as a result, it is possible to suppress the magnetic foreign matter from passing over without being adsorbed, and effectively prevent the magnetic foreign matter from adsorbing omission.

In the rod-shaped magnet of the present invention, it is preferable that the bonding surfaces of each magnet constituting the rod-shaped magnet are inclined at a predetermined angle with respect to the axial direction of the rod-shaped magnet and are parallel to each other.

According to the above aspect, since each bonding surface of each magnet constituting the rod-shaped magnet is inclined at a predetermined angle and parallel to each other with respect to the axial direction of the rod-shaped magnet, the magnetic field is in a direction orthogonal to the axial direction of the rod-shaped magnet. This strong point exists, and even if the magnetic foreign matter passes over the point where the magnetic field is weak, it is possible to adsorb the magnetic foreign matter by the strong point, and it is possible to more effectively prevent the absorption of the magnetic foreign matter.

Another aspect of the present invention is a magnetic foreign matter removal device for adsorbing and removing the magnetic foreign matter from the particulate matter or fluid containing the magnetic foreign matter by a magnetic field, wherein the inlet port for introducing the particulate matter or fluid, and the particulate matter Or a casing having an outlet for discharging the fluid, and a plurality of rod-shaped magnets disposed in the casing and extending in a rod-like shape of a predetermined length, and the rod-shaped magnets are parallel to each other when viewed from a cross section orthogonal to the axial direction. It has an adsorption unit having a pair of adsorption surfaces extending in a predetermined length so as to be, and a guide unit installed at one end of the adsorption unit and guides the magnetic foreign matter to the adsorption unit, and the rod-shaped magnet has a predetermined distance. It is characterized in that a plurality of parallel arrangements are arranged in the casing in a state in which the one end side faces in the direction of movement of the powder or granular material or fluid.

According to the above invention, the rod-shaped magnet has a guide portion for guiding magnetic foreign substances to the suction portion at one end side of the suction portion when viewed from a cross section orthogonal to the axial direction, and parallel to a predetermined interval, and at the same time, one end side. Since a plurality of particles are arranged in parallel in the casing in a state that faces the direction of the powder or granular material or fluid, the powder or granular material or fluid introduced from the inlet is difficult to stay at one end of the rod-shaped magnet, and each rod-shaped magnet is adsorbed. It is possible to guide it smoothly towards wealth. In addition, since the adsorption part of the rod-shaped magnet has a pair of adsorption surfaces extending in a predetermined length so as to be parallel to each other, the adsorption surface where a strong magnetic field is generated is similar to the boundary part P of the conventional tear-shaped rod-shaped magnet. Since it is possible to form a surface that extends in a direction orthogonal to the axial direction of a rod-shaped magnet rather than a line, it is possible to secure a wide area of the area where a strong magnetic field is generated, and enter between the suction surfaces of adjacent magnets. It is possible to reliably adsorb the magnetic foreign matter contained in the powder or granular material or the fluid, and it is possible to remove the magnetic foreign matter efficiently by reducing the adsorption of the magnetic foreign matter.

In the magnetic foreign matter removing apparatus of the present invention, a plurality of covers made of a non-magnetic material in the casing and suitably covered on the outer periphery of the rod-shaped magnet are arranged to match the arrangement of the rod-shaped magnets, and the rod-shaped It is preferable that the magnet is capable of being inserted into and detached from the corresponding cover.

According to the above aspect, a plurality of covers made of a non-magnetic material and suitably covered on the outer periphery of the rod-shaped magnets are arranged to match the arrangement of the rod-shaped magnets, and the rod-shaped magnets are inserted and detachable in the corresponding cover. Therefore, when the rod-shaped magnet is inserted into the cover and disposed in the casing to remove the magnetic foreign matter from the powder or granular material or fluid, it is possible to adsorb the magnetic foreign matter on the cover surface by the magnetic force of the rod-shaped magnet. Further, after the magnetic foreign matter is adsorbed, since the magnetic force is lost by removing the rod-shaped magnet from the inside of the cover, it is possible to separate and separate the magnetic foreign matter from the cover surface. That is, the magnetic foreign matter is adsorbed through the cover, and since the magnetic foreign matter is not directly adsorbed to the rod-shaped magnet, cleaning of the rod-shaped magnet becomes unnecessary, and the workability of removing the magnetic foreign matter can be improved.

In the magnetic foreign matter removing device of the present invention, the rod-shaped magnet is formed by connecting a plurality of magnets in the axial direction, and it is preferable that the bonding surfaces of the magnets constituting the rod-shaped magnet are made of the same poles. .

According to the above aspect, the rod-shaped magnet is formed by connecting a plurality of magnets in the axial direction, and since the bonding surfaces of the magnets constituting the rod-shaped magnet are made of the same poles, the range in which the magnetic field acts strongly, It is possible to increase in the axial direction of the rod-shaped magnet, and as a result, it is possible to suppress the magnetic foreign matter from passing over without being adsorbed, and effectively prevent the magnetic foreign matter from adsorbing omission.

In the magnetic foreign matter removing apparatus of the present invention, it is preferable that the bonding surfaces of each magnet constituting the rod-shaped magnet are inclined at a predetermined angle with respect to the axial direction of the rod-shaped magnet and are parallel to each other.

According to the above aspect, since the bonding surfaces of each magnet constituting the rod-shaped magnet are inclined at a predetermined angle and parallel to each other with respect to the axial direction of the rod-shaped magnet, in a direction orthogonal to the axial direction of the rod-shaped magnet, A strong magnetic field exists, and even if the magnetic foreign matter passes over a weak magnetic field, it is possible to adsorb by a strong magnetic field, and thus it is possible to more effectively prevent the magnetic foreign matter from adsorbing omission.

In the magnetic foreign substance removing apparatus of the present invention, it is preferable that the rod-shaped magnet is radially connected to the rotation shaft with the one end side toward the rotation direction, and is rotatable in the inner circumference of the casing.

According to the above aspect, since the rod-shaped magnet is connected to the rotation shaft and can be rotated in the inner circumference of the casing, for example, even when the powder or grain is aggregated, it is stirred and dispersed by the rotation of the rod-shaped magnet, It is possible to increase the adsorption efficiency of magnetic foreign substances by each rod-shaped magnet.

According to the present invention, when the powder or granular material or fluid to be removed from the magnetic foreign matter from the powder or granular material is moved toward one end side of the rod-shaped magnet, the powder or granular material or the fluid is transferred to the rod-shaped body by the guide portion of the rod-shaped magnet. By making it difficult to stay on one end of the magnet, it is possible to smoothly guide the adsorption unit toward the adsorption unit, and since the pair of adsorption surfaces of the adsorption unit extend to a predetermined length so as to be parallel to each other, the suction surface where a strong magnetic field is generated , Since it is possible to have a surface extending in a direction orthogonal to the axial direction of the rod-shaped magnet, it is possible to secure a wide area of the area where the strong magnetic field is generated, reliably adsorbing magnetic foreign matter contained in powder or grain or fluid. It is possible to reduce the adsorption of magnetic foreign matters and remove them efficiently.

[Fig. 1] Fig. 1 shows an embodiment of a rod-shaped magnet according to the present invention, and is an explanatory diagram of a state viewed from the axial direction side and an explanatory diagram of a state viewed from the side.
Fig. 2 shows an embodiment of a rod-shaped magnet according to the present invention, and is a perspective view thereof.
Fig. 3 is a side view of the rod-shaped magnet.
Fig. 4A is an explanatory view of the first other shape in a state where the rod-shaped magnet is viewed from the side in the axial direction.
Fig. 4B is an explanatory view of the second other shape in a state where the rod-shaped magnet is viewed from the side in the axial direction.
Fig. 4c is an explanatory view of the third other shape in a state where the rod-shaped magnet is viewed from the side in the axial direction.
[Fig. 5A] It is a plan view in the first embodiment of the magnetic foreign substance removing device according to the present invention.
Fig. 5B is a cross-sectional view of a magnetic foreign substance removing device according to a first embodiment of the present invention.
Fig. 6 is an explanatory diagram showing a state when a plurality of rod-shaped magnets are set in the magnetic foreign substance removing device.
Fig. 7 is a plan view of a plurality of rod-shaped magnets arranged in parallel in the magnetic foreign substance removing device.
Fig. 8A is an explanatory diagram showing a state of use of the magnetic foreign substance removing device.
8B is an explanatory diagram showing a conventional structure.
Fig. 9 shows a second embodiment of a magnetic foreign substance removing device according to the present invention, and is a perspective view of a main part thereof.
[Fig. 10A] It is a front view of the magnetic foreign substance removing device.
[Fig. 10A] It is a plan view of the magnetic foreign substance removing device.
Fig. 11 is a plan view showing a third embodiment of a magnetic foreign substance removing device according to the present invention.

Hereinafter, an embodiment of the rod-shaped magnet according to the present invention will be described with reference to FIGS. 1 to 4.

As shown in Figs. 2 and 3, the rod-shaped magnet 10 in the present embodiment has a structure formed in a rod shape as a whole by connecting a plurality of magnets 20 formed with a predetermined thickness through a connecting shaft 21 It is made into. Referring also to FIG. 1, each magnet 20 has a cross section orthogonal to its axial direction (thickness direction), substantially forming a tear shape, and at the same time, the both sides thereof are suction surfaces 29 and 29 parallel to each other. It has the same shape as cut out.

Referring to FIG. 1, each magnet 20 has a major axis A and a minor axis B orthogonal thereto, and one end 23 of the major axis A has a substantially round shape. In addition, each magnet 20 includes a suction unit 30 having a pair of suction surfaces 29 and 29 extending in a predetermined length so as to be parallel to each other when viewed from a cross section orthogonal to the axial direction, and the It is provided on one end side of the adsorption part 30 in the direction of the major axis A, and includes a guide part 28 for guiding the magnetic foreign matter M to the adsorption part 30. The guide portion 28 is provided with a pair of slopes 27 and 27 gradually widening from the one end 23 side of the magnet 20 toward the other end 25 side of the major axis A.

On the other hand, the adsorption unit 30 is a pair of adsorption surfaces 29 extending in a predetermined length so as to be parallel to each other from an end of the pair of slopes 27 and 27 of the guide unit 28 on the other end 25 side. , 29). Further, on the other end side of the adsorption part 30 in the direction of the major axis A (the side opposite to the guide part 28), a base end part 32 having a round shape is provided. This base end portion 32 has a curved surface 31 extending in a substantially semicircular shape from an end of a pair of suction surfaces 29 and 29 constituting the suction unit 30 on the other end 25 side, The bottom (that is, the position furthest from the one end 23) constitutes the other end 25. In addition, as shown in FIG. 1, the length from one end 23 to the other end 25 of the magnet 20 is set as the total length L1 of the magnet 20, and from one end 23 to the other end of the suction surface 29 The length along (25) is taken as the length L2 of the suction surface 29.

In addition, the top portion (one end 23) of the guide portion 28 in the present embodiment has a substantially round shape, as shown in Fig. 1, but the top portion is made into a semicircular shape or a pointed shape. It may be used, but is not particularly limited.

Moreover, the pair of mutually parallel adsorption surfaces 29 and 29 constituting the adsorption unit 30 are in the shape of a flat surface in the present embodiment. However, such a pair of adsorption surfaces 29 and 29 may not necessarily have a flat surface, and may have minute irregularities on the surface, or partially have a concave, convex, or tapered surface. It is preferable that the pair of suction surfaces 29 and 29 extend in parallel as a whole.

In addition, as shown in FIG. 3, the magnets 20, 20 arranged adjacently along the axial direction of the rod-shaped magnet 10 have the opposite bonding surfaces 33, 33 with the same poles (N and N The poles are connected to each other, the S poles and the S poles are joined together via a plate-shaped yoke 39 made of pure iron or low carbon steel. And the plate-shaped yoke 39 is inclined at a predetermined angle with respect to the axial center of the rod-shaped magnet 10 (the center of the coupling shaft 21), and is arranged parallel to each other. That is, the bonding surfaces 33 and 33 of each magnet 20 constituting the rod-shaped magnet 10 are inclined at a predetermined angle with respect to the axial direction of the rod-shaped magnet 10 and are parallel to each other.

In addition, in this embodiment, in order to increase the permeability, a plate-shaped yoke 39 is disposed between adjacent magnets 20 and 20, but the magnets 20 may be directly bonded to each other. They may be arranged at intervals of.

Further, as a rod-shaped magnet, for example, it may have a shape as shown in Figs. 4A, 4B, and 4C. The rod-shaped magnet 10A shown in FIG. 4A is, at the ends of a pair of suction surfaces 29 and 29 constituting the suction unit 30, a perpendicular surface 31a orthogonal to the suction surfaces 29 and 29. And, the orthogonal surface 31a forms the other end 25. That is, the rod-shaped magnet 10A has a shape in which the base end portion 32 similar to the rod-shaped magnet 10 of the above embodiment does not exist. However, it is preferable that the boundary part (leg part) between the suction surface 29 and the orthogonal surface 31a has a round shape.

On the other hand, the rod-shaped magnet 10B shown in FIG. 4B is a tapered surface 37 that gradually narrows toward the other end 25 from the end of the pair of suction surfaces 29 and 29 constituting the suction unit 30. , 37), and the crossing end thereof becomes the other end 25. That is, the base end portion 32 has tapered surfaces 37 and 37 on its outer circumferential surface.

In addition, the rod-shaped magnet 10C shown in FIG. 4C basically has the same structure as the rod-shaped magnet 10 shown in FIG. 1, but a pair of suction surfaces 29 and 29 constituting the suction unit 30 The length L2 is shorter than the length L2 of the suction surface 29 of the rod-shaped magnet 10.

In addition, the rod-shaped magnet in the present invention is not particularly limited as long as it has a structure including an adsorption section having a pair of adsorption surfaces and a guide section. In addition, the number of magnets 20 constituting the rod-shaped magnet 10 is not particularly limited. Furthermore, the rod-shaped magnet may not be configured by connecting a plurality of magnets, but may be configured with a single long magnet extending to a predetermined length.

Further, in the present embodiment, a cover 40 made of a nonmagnetic material such as austenitic stainless steel, aluminum alloy, or synthetic resin is covered on the outer periphery of the rod-shaped magnet 10. This cover 40 forms an outer circumferential shape suitable for the magnet 20 constituting the rod-shaped magnet 10 and is formed to be longer than the total length in the axial direction of the rod-shaped magnet 10. That is, the cover 40 of this embodiment has a pair of slopes 47 and 47 formed at an inclined angle corresponding to the pair of slopes 27 and 27 of the magnet 20, and the pair of slopes ( It is provided with a pair of suction surfaces 49 and 49 extending parallel to each other from the other end side of the 47 and 47). Then, in this cover 40, a rod-shaped magnet 10 made of a plurality of magnets 20 can be inserted and detached.

Next, a description will be given of a first embodiment of a magnetic foreign substance removing device according to the present invention using a rod-shaped magnet configured as described above.

As shown in Fig. 5A, the magnetic foreign substance removing device 50 (hereinafter, referred to as "removing device 50") of the present embodiment has a substantially rectangular box-shaped casing 51. Referring also to Fig. 5B, the casing 51 is formed with an inlet 53 for introducing a powder or granular material or a fluid (hereinafter, referred to as "powder and granular material") above it. Further, under the casing 51, a discharge port 55 is formed for discharging the powder or granular material after adsorption and removal of magnetic foreign substances such as metal pieces with the rod-shaped magnet 10 from the inside of the casing 51.

Further, one wall of the casing 51 is a slide wall portion 57 that is close to or spaced apart from the other wall to be opened and closed. Further, between the casing 51 and the slide wall portion 57, a holding means (not shown) for holding the slide wall portion 57 in a closed state with respect to the casing 51 is provided.

Further, a plurality of rod-shaped magnets 10 described above are attached to the slide wall portion 57 upwardly so that the one end 23 side thereof faces the introduction port 53 side. That is, the powder or granular material introduced from the introduction port 53 of the casing 51 falls downward of the casing 51, and the rod-shaped magnet 10 in the present embodiment is on the one end 23 side Are arranged in the casing 51 in a plurality of parallel directions, such as powder or granular material, in a state in which they face the advancing direction (advancing from the upper side of the casing to the lower side).

Specifically, as shown in FIG. 5B, in the upper and lower sides of the height direction of the casing 51, along the width direction (orthogonal to the height direction) of the casing 51, four rod-shaped magnets 10 They are arranged in parallel at equal intervals. In addition, in the middle of the height direction of the casing 51, three rod-shaped magnets 10 are arranged along the width direction of the casing 51 so as to form a cross-shaped shape with respect to the four rod-shaped magnets 10 disposed above or below. They are arranged in parallel. That is, between the rod-shaped magnets 10 and 10 arranged above or below, the rod-shaped magnet 10 arranged in the middle of the height direction is located.

In addition, as shown in the plan view of FIG. 7, the rod-shaped magnets 10 and 10 disposed adjacent to each other at the same height position with respect to the casing 51 have the same poles (N Pole and N pole, S pole and S pole) are arranged at predetermined intervals. As a result, magnetic fields that repel each other act between the suction surfaces 29 and 29 of the rod-shaped magnets 10 and 10 (see Fig. 7).

In addition, in this embodiment, a plurality of rod-shaped magnets 10 arranged in parallel in the width direction of the casing 51 are arranged in three stages in the height direction of the casing 51, but for example, the casing ( 51) may be arranged in 4 or 5 or more stages in the height direction. Further, in the present embodiment, the one end 23 side of the rod-shaped magnet 10 is disposed upward, which is the inlet 53 of the casing 51, but the one end side of the rod-shaped magnet is the advancing direction of the powder or grain or the like. It just needs to be arrange|positioned toward and is not limited to this aspect. (It will be described in other embodiments).

In addition, as shown in FIG. 5A, in the casing 51, a support plate 59 for supporting a plurality of the above-described covers 40 is disposed. This supporting plate 59 is detachably attached to the center of the casing through a mounting hole (not shown). In addition, a plurality of cover fixing holes (not shown) are formed in the support plate 59, and the covers 40 are respectively inserted into and fixed to each cover fixing hole. In addition, as shown in FIG. 5B, the arrangement of the plurality of covers 40 corresponds to the plurality of rod-shaped magnets 10 mounted on the slide wall portion 57 described above, and the upper side of the support plate 59 in the height direction and Each of the four covers 40 is fixed to the lower side, and three covers 40 are alternately arranged and fixed in the middle of the support plate 59 in the height direction.

Further, as shown in Fig. 5B, a plurality of guide plates 65 having a mountain shape in cross section are arranged above the casing. The guide plate 65 guides the powder or granular material introduced from the introduction port 53, and makes it easy to reach each rod-shaped magnet 10.

Next, a method of use and effects of the rod-shaped magnet 10 having the above structure and the removal device 50 using the rod-shaped magnet 10 will be described.

First, as shown in Fig. 6, with respect to the plurality of covers 40 fixed to the casing 51 side through the support plate 59, with the slide wall portion 57 of the removal device 50 open, the slide wall portion The plurality of rod-shaped magnets 10 mounted on 57 are matched, and the slide wall portion 57 is pressed against the casing 51. Then, in each cover 40, each rod-shaped magnet 10 is inserted from one end in the axial direction, and the slide wall portion 57 is closed with respect to the casing 51 by a holding device (not shown). Maintain (see Fig. 5B).

In the above state, when the powder or granular material G is introduced from the inlet 53 above the casing, the powder or granular material G is disposed above the casing through a plurality of guide plates 65 as shown in Figs. 5B and 8A. The rod-shaped magnet 10 disposed in the middle of the height direction of the casing 51 by falling to the one end 23 side of the rod-shaped magnet 10, or passing between the rod-shaped magnets 10 and 10 disposed above the casing. It falls on one end (23) side of ). Then, the powder or granular material G is guided toward the suction surfaces 49 and 49 of the cover 40 through the slopes 47 and 47 of the cover 40 of each of the rod-shaped magnets 10. And, by the magnetic force of the rod-shaped magnet 10 inserted in the cover 40, as shown in Figs. 5B and 8A, the front side of the slopes 47 and 47 of the cover 40 and the suction surfaces 49 and 49 Magnetic foreign substances M such as metal pieces contained in the powder and grain G are adsorbed on the surface of. That is, the magnetic foreign matter M is the front side of the pair of slopes 27 and 27 constituting the guide portion 28 of the rod-shaped magnet 10, or the pair of suction surfaces 29 constituting the suction portion 30. , 29), it is indirectly adsorbed through the slope 47 or the adsorption face 49 of the cover 40 (see Fig. 8A).

Further, in the case of the structure without the cover 40, the magnetic foreign matter M is directly adsorbed to the slope 27 of the rod-shaped magnet 10 or the front side of the suction surface 29. In the present embodiment, the magnetic foreign matter M is adsorbed on the front side such as the suction surface on the cover 40 side, but in the following description, for convenience, it is described as being adsorbed on the suction surface on the rod-shaped magnet 10 side.

And, in such a rod-shaped magnet 10, as shown in Figs. 1 and 2, the powder or granular material G to be removed from the magnetic foreign material M from the powder or granular material G is directed toward the one end 23 side of the bar-shaped magnet 10. In the case of advancing, by the guide portion 28 of the rod-shaped magnet 10, the powder or granular material G is difficult to stay on the one end 23 side of the rod-shaped magnet 10, and smoothly guided toward the adsorption portion 30. At the same time, since the pair of adsorption surfaces 29 and 29 of the adsorption unit 30 extend in a predetermined length so as to be parallel to each other, the adsorption surface where a strong magnetic field is generated is formed in a conventional cross section in a tear shape. Since it is possible to make it not in the shape of a line like the boundary part P of the in-rod magnet (see Fig. 8b), but in a plane extending in a direction orthogonal to the axial direction of the rod-shaped magnet 10, the area of the region where the strong magnetic field occurs is As a result, magnetic foreign matter M contained in the powder or granular material G can be reliably adsorbed, and the absorption of magnetic foreign matter M is reduced, and magnetic foreign matter M is efficiently removed from the granular material G. It is possible to do.

In addition, in this removal device 50, as shown in FIG. 5B, when the rod-shaped magnet 10 is viewed from a cross section orthogonal to the axial direction, magnetic foreign matter M is placed on one end side of the adsorption unit 30. In addition to the provision of the guide portion 28 for guiding the suction portion 30, in parallel with a predetermined interval, and in a state in which the end 23 side faces in the direction of the advancement of the powder or granular material G, in the casing 51 Since a plurality of them are arranged in parallel, the powder or granular material G introduced from the inlet 53 is difficult to stay on the one end 23 side of the rod-shaped magnet 10, so that the suction portion 30 of each rod-shaped magnet 10 It is possible to guide smoothly toward. Moreover, since the adsorption part 30 of each rod-shaped magnet 10 has a pair of adsorption surfaces 29 and 29 extending in a predetermined length so as to be parallel to each other, the adsorption surface where a strong magnetic field is generated is conventionally Since it is possible to make the cross-section of a surface extending in a direction perpendicular to the axial direction of the rod-shaped magnet 10, not a line like the boundary part P of the tear-shaped rod-shaped magnet, the area of the region where the strong magnetic field is generated It is possible to secure it widely, and it is possible to reliably adsorb the magnetic foreign matter M contained in the powder or granular material G passing between the adsorption surfaces 29 and 29 of the adjacent rod-shaped magnets 10 and 10. It is possible to reduce the adsorption omission of the magnetic foreign material M, and efficiently remove the magnetic foreign material M from the powder or granular material G.

Further, the rod-shaped magnet 10 disposed above the casing or the powder or granular material G passing through the rod-shaped magnet 10 disposed in the middle of the casing falls to the one end 23 side of the rod-shaped magnet 10 disposed below the casing. , As described above, the rod-shaped magnet 10 is guided toward the suction surface 29 by the slope 27 (see Fig. 5B). Thereby, magnetic foreign matter M, which has not been removed even by the rod-shaped magnet 10 disposed above the casing or in the middle of the casing, can be adsorbed and removed by the rod-shaped magnet 10 under the casing. As described above, in this embodiment, since the plurality of rod-shaped magnets 10 arranged in parallel along the width direction of the casing 51 are arranged in a plurality of stages in the height direction of the casing 51, magnetic foreign matter M It is possible to more reliably prevent the adsorption omission.

In addition, in this embodiment, as shown in FIG. 3, the rod-shaped magnet 10 is formed by connecting a plurality of magnets 20 in the axial direction, and each magnet 20 constituting the rod-shaped magnet 10 The bonding surfaces 33 of) are made of the same poles, and are bonded through a plate-shaped yoke 39. Therefore, it is possible to increase the range in which the magnetic force strongly acts (the range that passes through the yoke 39 where the magnetic force is concentrated) in the axial direction of the rod-shaped magnet 10, as shown in FIG. Without being adsorbed by the adsorption part 30, it is possible to suppress passing over and effectively prevent the adsorption of the magnetic foreign matter M from being omitted.

In addition, in this embodiment, each bonding surface 33 of each magnet 20 constituting the rod-shaped magnet 10 is inclined at a predetermined angle with respect to the axial direction of the rod-shaped magnet 10 to be parallel to each other. It is placed. Therefore, in a direction orthogonal to the axial direction of the rod-shaped magnet 10, a strong magnetic field exists (when the magnets 20 are stacked in the axial direction of the rod-shaped magnet 10, the density of the magnetic force is The vicinity of the bonding surface where (39) is placed is the highest, and the middle portion in the thickness direction of the magnet 20 is lowest), even if the magnetic foreign matter M passes through the weak point, it is possible to adsorb it by the strong magnetic field. It is possible to more effectively prevent the adsorption omission of the magnetic foreign matter M.

9 and 10 show a second embodiment of a magnetic foreign substance removing device according to the present invention. Incidentally, portions that are substantially the same as those in the above embodiment are denoted by the same reference numerals, and the description thereof is omitted.

The magnetic foreign substance removing device 50A of the present embodiment (hereinafter referred to as “removing device 50A”) is a rotation shaft configured to be rotatable in a predetermined direction by a driving means (not shown) in the center of the casing 51 It has (67). On the outer periphery of the rotation shaft 67, a plurality of rod-shaped magnets 10 are arranged along the axial direction (here, the rod-shaped magnets 10 are arranged in four stages in the axial direction of the rotation shaft 67), and Such a rod-shaped magnet 10 is radially connected to the rotation shaft 67 with the end 23 side toward the rotation direction of the rotation shaft 67 (that is, toward the direction of movement of powder or granular material or fluid). have. In this embodiment, four rod-shaped magnets 10 are radially arranged on the outer periphery of the rotation shaft 67 at equal intervals in the circumferential direction. Then, each of the rod-shaped magnets 10 can be rotated in the inner periphery of the casing 51 via the rotation shaft 67. In addition, each of the rod-shaped magnets 10 is constituted by a plurality of magnets 20 as in the above embodiment.

In the present embodiment, since the rod-shaped magnet 10 is connected to the rotation shaft 67 and can be rotated around the inner circumference of the casing 51, for example, in the case of agglomeration of powder or grain. Also, since it is stirred and dispersed by the rotation of the rod-shaped magnets 10, it is possible to increase the efficiency of adsorption of magnetic foreign matters by the rod-shaped magnets 10.

In Fig. 11, a third embodiment of a magnetic foreign substance removing device according to the present invention is shown. Incidentally, portions that are substantially the same as those in the above embodiment are denoted by the same reference numerals, and the description thereof is omitted.

As shown in FIG. 11, the magnetic foreign matter removing device 50B (hereinafter, referred to as “removing device 50B”) of the present embodiment contains powder or granular material or fluid at a predetermined location in the circumferential direction of the casing 51. An inlet port 53A to be introduced is provided, and an outlet port for discharging a fluid after adsorption and removal of magnetic foreign matter M such as a metal piece is provided at a location of the casing 51 opposite to the inlet port 53A in the circumferential direction. (55A) is provided. In addition, a plurality of rod-shaped magnets 10 are arranged so as to form a staggered shape toward the introduction port 53A on the one end 23 side (see Fig. 11).

The removal apparatus 50B of this embodiment is suitable for removing magnetic foreign matter contained in a fluid. That is, when the fluid F is introduced from the inlet 53A, the magnetic foreign matter M is adsorbed and removed by the adsorption surface 29 of each rod-shaped magnet 10 and discharged from the discharge port 55A. It is possible to remove efficiently. In addition, the present removal device 50B may be used to remove magnetic foreign substances in the powder or grain.

In addition, the present invention is not limited to the above-described embodiments, and various modified embodiments are possible within the scope of the gist of the present invention, and such embodiments are also included in the scope of the present invention.

10, 10A, 10B, 10C rod magnet
20 magnet
21 connecting shaft
23 first
25 the other end
27, 27 amnesty
28 Guide section
29,29 suction side
30 Adsorption part
31 curved surface
31a orthogonal plane
32 base
33 junction surface
37 Tapered side
40 covers
47, 47 amnesty
49, 49 suction surface
50, 50A, 50B, 50C magnetic foreign matter removal device (removal device)
51 casing
53, 53A, 53B inlet
55, 55A, 55B outlet
57 Slide Wall
59 Support plate
65 guide plate
67 pivot shaft
100 rod magnet
110 casing
120 upper opening
A long axis
B shortening
C axis direction
G granular material
M magnetic foreign body
P boundary

Claims (9)

A rod-shaped magnet that extends in a rod shape of a predetermined length and has a long axis and a short axis when viewed from a cross section orthogonal to the axial direction, for adsorbing the magnetic foreign material from the powder or grain or fluid containing the magnetic foreign material by a magnetic field,
The rod-shaped magnet includes a suction unit having a pair of suction surfaces extending in a predetermined length so as to be parallel to each other when viewed from a cross section orthogonal to the axial direction, and is provided on one end side of the suction unit, and A rod-shaped magnet comprising a pair of slopes gradually widening from one end side toward the other end side, and including a guide unit for guiding the magnetic foreign matter to the suction unit.
The rod-shaped magnet according to claim 1, wherein the rod-shaped magnet has a shape suitable for an outer circumference of the rod-shaped magnet, and a cover made of a non-magnetic material is provided, and the rod-shaped magnet is inserted and detachable in the cover.
The rod-shaped magnet according to claim 1 or 2, wherein the rod-shaped magnet is formed by connecting a plurality of magnets in the axial direction, and the bonding surfaces of the magnets constituting the rod-shaped magnet are formed of the same poles. A stick-shaped magnet.
4. The rod-shaped magnet according to claim 3, wherein each of the bonding surfaces of each of the magnets constituting the rod-shaped magnet is inclined at a predetermined angle with respect to the axial direction of the rod-shaped magnet to be parallel to each other.
A magnetic foreign material removal device for adsorbing and removing the magnetic foreign material from a powder or grain or fluid containing a magnetic foreign material by a magnetic field,
A casing having an inlet for introducing the powder or grain or fluid and an outlet for discharging the powder or grain or fluid,
A plurality of rod-shaped magnets disposed in the casing, extending in a rod shape of a predetermined length, and having a long axis and a short axis when viewed in a cross section perpendicular to the axial direction thereof,
The rod-shaped magnet includes a suction unit having a pair of suction surfaces extending in a predetermined length so as to be parallel to each other when viewed from a cross section orthogonal to the axial direction, and is provided on one end side of the suction unit, and A guide portion provided with a pair of slopes gradually widening from one end side toward the other end side to guide the magnetic foreign matter to the suction portion,
The magnetic foreign matter removing device, characterized in that the rod-shaped magnets are arranged in a plurality or parallel in the casing in a state in which the rod-shaped magnets are parallel to each other at predetermined intervals, and the one end side faces the moving direction of the powder or grain or fluid.
The method of claim 5, wherein the casing is made of a non-magnetic material, and a plurality of covers suitably covered on the outer periphery of the rod-shaped magnet are arranged to match the arrangement of the rod-shaped magnets,
The magnetic foreign matter removing device, wherein the rod-shaped magnet is inserted into and detached from the corresponding cover.
The rod-shaped magnet according to claim 5 or 6, wherein the rod-shaped magnet is formed by connecting a plurality of magnets in the axial direction, and the bonding surfaces of the magnets constituting the rod-shaped magnet are formed of the same poles. Magnetic foreign material removal device.
The magnetic foreign matter removing apparatus according to claim 7, wherein each bonding surface of each magnet constituting the rod-shaped magnet is inclined at a predetermined angle with respect to the axial direction of the rod-shaped magnet and is parallel to each other.
The rod-shaped magnet according to any one of claims 5 to 8, wherein the rod-shaped magnet is radially connected to a rotation shaft with the one end side toward the rotation direction, and is rotatable in the inner circumference of the casing. Magnetic foreign material removal device.

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