JPH0644522U

JPH0644522U - Foreign body attraction magnet

Info

Publication number: JPH0644522U
Application number: JP8173192U
Authority: JP
Inventors: 正男緒方
Original assignee: Hitachi Metals Ltd
Current assignee: Hitachi Metals Ltd
Priority date: 1992-11-26
Filing date: 1992-11-26
Publication date: 1994-06-14

Abstract

(57)【要約】【目的】水分、空気等の腐食要因に対して強い抵抗力
をもち、且つ高磁気特性であって充分な耐用期間を持
ち、安全性に優れた胃内異物吸着磁石を提供する。【構成】耐食性非磁性材料により中空円筒状に形成し
たケース内に、軸方向に磁化した複数個の円盤状サマリ
ウム−コバルト系永久磁石を、各ヨークを挟んで同極が
対向するように軸方向に一体桿状に配設し、前記ケース
の両端部には耐食性材料からなる蓋を配設する。 (57) [Abstract] [Purpose] A magnet for adsorbing a foreign substance in the stomach that has a strong resistance to corrosion factors such as moisture and air, has a high magnetic property and has a sufficient service life, and is excellent in safety. provide. [Structure] A plurality of disk-shaped samarium-cobalt permanent magnets magnetized in the axial direction are placed in a hollow cylindrical case made of a corrosion-resistant non-magnetic material so that the same poles face each other across each yoke. And a lid made of a corrosion resistant material at both ends of the case.

Description

【考案の詳細な説明】[Detailed description of the device]

【０００１】[0001]

【産業上の利用分野】[Industrial applications]

本考案は、反芻動物特に牛が飼料と共に嚥下しその結果第二胃に集積滞留した釘、針、針金および磁性粉等の磁性材料からなる異物を吸着除去するために使用される胃内異物吸着磁石に関するものである。 The present invention is intended for the adsorption of foreign substances in the stomach, which is used to adsorb and remove foreign substances composed of magnetic materials such as nails, needles, wires and magnetic powder accumulated by ruminants, especially cows, in the rumen as a result of swallowing. It is about magnets.

【０００２】[0002]

【従来の技術】[Prior art]

牧草地において牧草を飼料とする牛は、典型的な反芻動物であるため、その習性として採食時においては飼料を咀嚼せずに嚥下してしまう。従って牧草である飼料中に混在し、若しくは放牧場等に落下している釘、針、針金、磁性粉等の細長い尖鋭な金属片も飼料若しくは牧草と共に摂取されて第二胃に集まり、胃の運動によって上記金属片が胃壁を穿刺する結果、胃炎若しくは消化障害を含む各種の疾病を発生し、甚だしい場合には胃壁穿孔、胃壁化膿等により死亡事故に至ることもある。 Cattle that feed on grass in the pasture are typical ruminants, and as a result, they swallow the feed without chewing during feeding. Therefore, long, sharp metal pieces such as nails, needles, wires, and magnetic powder that are mixed in the feed, which is grass, or are falling on the pasture, etc., are also ingested with the feed or grass and gather in the rumen, As a result of puncturing the stomach wall with the above-mentioned metal pieces, various diseases including gastritis or digestive disorders may occur, and in extreme cases, perforation of the stomach wall or suppuration of the stomach wall may lead to a fatal accident.

【０００３】上記のような事故を防止するために、従来から牛に投与する飼料に対して、金属異物、特に鉄鋼片の検出、分別装置による飼料管理を行うと共に、放牧場における金属異物の検出、整備が行われている。しかしながら、上記のような管理、整備にも拘らず、飼料中に異物が混入する結果、牛の死亡事故が往々にして発生する。このため、従来から棒状永久磁石を牛の第二胃に滞留させ、誤って摂取した磁性材料の異物を吸着し、胃壁が尖鋭な磁性金属片によって穿刺損傷されることを防止する手段が採用されている。In order to prevent the above-mentioned accidents, metal foreign substances, particularly steel pieces, are detected from the feed conventionally administered to cattle, and the feed is controlled by a sorting device, and the metal in the pasture is used. Foreign matter is being detected and maintained. However, despite the above-mentioned management and maintenance, cattle deaths often occur as a result of the inclusion of foreign matter in the feed. For this reason, conventionally, there has been a means for preventing stick-shaped permanent magnets from staying in the rumen of a cow to adsorb foreign substances of a magnetic material that have been accidentally ingested and preventing the stomach wall from being punctured by a sharp magnetic metal piece. Has been adopted.

【０００４】上記のような処理に使用される胃内異物吸着磁石としては、両端面に異なる極性の磁極を設けた円板状の磁石を、交互に極性を反転させかつ磁石間に磁性板を設けて同軸的に結合した構成の胃内異物吸着磁石が提案されている（例えば実公昭５７−５３５５０号、実開昭５７−１２８８１７号、同５７−１６５１１７号、同６０−６１７０３号公報等参照）。このような構造であると、両端部のみならず、中間部にも複数個の磁極が形成されるため、細長い磁性金属片であっても吸着磁石の中間部に長手方向を略軸と平行な方向に揃えて吸着される結果、胃壁を穿刺することが少ないという効果が期待される。As the gastric foreign matter adsorbing magnet used for the above-mentioned processing, disk-shaped magnets having different polar magnetic poles on both end surfaces are alternately reversed in polarity and magnetic plates are interposed between the magnets. There has been proposed a magnet for adsorbing a foreign substance in the stomach, which is coaxially coupled (for example, Japanese Utility Model Publication Nos. 57-53550, 57-128817, 57-165117 and 60-61703). Etc.). With such a structure, a plurality of magnetic poles are formed not only at both ends but also in the middle part, so even in the case of an elongated magnetic metal piece, the longitudinal direction is approximately parallel to the axis in the middle part of the attraction magnet. As a result of being adsorbed in different directions, it is expected that there will be less puncture of the stomach wall.

【０００５】しかしながら上記提案のものは、何れもフェライト磁石によって構成したものであり、磁力が不充分である。すなわち胃内異物吸着磁石とした後の表面磁束密度は１６００〜１８００Ｇに過ぎず、尖鋭な金属片を完全に、かつ胃壁を穿刺しないように吸着磁石表面に軸方向に揃えて吸着保持することができないという問題点がある。また上記従来の提案によっては、何れも多孔質のフェライト磁石が露出した構成であるため、使用中に胃液に侵食されて欠落する結果、寿命が極めて短いという問題点もある。However, all of the above proposals are composed of ferrite magnets, and the magnetic force is insufficient. That is, the surface magnetic flux density of the magnet for adsorbing a foreign substance in the stomach is only 1600 to 1800 G, and a sharp metal piece should be perfectly adsorbed and held axially on the surface of the magnet so that it does not puncture the stomach wall. There is a problem that you cannot do it. Further, according to the above-mentioned conventional proposals, since the porous ferrite magnets are all exposed, they are eroded by the gastric juice during use and are lost, resulting in an extremely short life.

【０００６】そこでこれらの問題点を解消すべく図２に示すように耐食性非磁性材料により中空円筒状に形成したケース１内に円板状に形成しかつ両端面の各々に異なる磁極を設けてなる複数個の永久磁石（希土類・鉄・ボロン系磁石）２を、ヨーク３を挟んで同極性の磁極が対向するように軸方向に一体桿状に配設し、前記ケースの両端部に耐食性非磁性材料からなる蓋４を配置した胃内異物吸着磁石が提案されいる。この吸着磁石においては、両端部よりも中間部における表面磁束密度が大であるため、細長い異物であっても軸に平行にかつ略中央部にその中心がくるように吸着保持することができ異物の先端による胃壁の穿刺を防止し得るものである。しかるに、この胃内異物吸着磁石にも若干の改良の余地がある。すなわち、希土類・鉄・ボロン系焼結磁石は、サビが発生しやすい為に焼結後出荷前にニッケルメッキなどの耐腐食表面処理が必要であること、又、何らかの事情で水分、空気などが進入した場合には、磁石の腐食の早い進行をくい止めることが出来ないことである。Therefore, in order to solve these problems, as shown in FIG. 2, a case 1 made of a corrosion-resistant non-magnetic material and formed in a hollow cylinder is formed into a disk shape and different magnetic poles are provided on both end surfaces. A plurality of permanent magnets (rare earth / iron / boron magnets) 2 are arranged in a rod shape in the axial direction so that magnetic poles of the same polarity face each other with the yoke 3 sandwiched between them. A foreign substance adsorption magnet in the stomach having a lid 4 made of a non-magnetic material has been proposed. In this attraction magnet, the surface magnetic flux density at the intermediate portion is higher than at both ends, so even long and slender foreign matter can be attracted and held parallel to the axis and centered at approximately the center. It is possible to prevent puncture of the stomach wall by the tip of the. However, there is room for some improvement in this magnet for attracting foreign substances in the stomach. In other words, since rare earth / iron / boron sintered magnets are prone to rust, corrosion-resistant surface treatment such as nickel plating is required after sintering and before shipment. If it enters, it is impossible to stop the rapid progress of corrosion of the magnet.

【０００７】[0007]

【考案が解決しようとする課題】[Problems to be solved by the device]

上記のような欠点を克服し、水分、空気等の腐食要因に対して強い抵抗力をもち、且つ高磁気特性であって充分な耐用期間を持ち、安全性に優れた胃内異物吸着磁石を提供することが本考案の目的である。 Overcoming the above-mentioned drawbacks, it has strong resistance to corrosive factors such as moisture and air, has a high magnetic property and has a sufficient service life. It is an object of the present invention to provide a magnet.

【０００８】[0008]

【課題を解決するための手段】[Means for Solving the Problems]

高い表面磁束密度を有し、表面処理をせずとも腐食に対して強い抵抗力を有する胃内異物吸着磁石とするため、本考案においては、耐食性非磁性材料により中空円筒状に形成したケース内に、軸方向に磁化した複数個の円盤状サマリウム− コバルト系永久磁石を、各ヨークを挟んで同極が対向するように軸方向に一体桿状に配設し、前記ケースの両端部には耐食性材料からなる蓋を配置する、という技術的手段を採用した。 In order to make it a magnet for adsorbing foreign substances in the stomach, which has a high surface magnetic flux density and strong resistance to corrosion without surface treatment, in the present invention, it is formed into a hollow cylindrical shape with a corrosion-resistant non-magnetic material. A plurality of axially magnetized disk-shaped samarium-cobalt permanent magnets are arranged in an axially-integrated rod shape so that the same poles face each other across each yoke. We adopted the technical means of placing a lid made of corrosion resistant material on the part.

【０００９】本考案における永久磁石を構成するサマリウムーコバルト磁石としては、ＳｍＣｏ₅系金属間化合物を主体とする１−５系サマリウムーコバルト磁石とＳｍ₂Ｃｏ₁₇を主体とする２−１７系サマリウムーコバルト磁石が使用できる。１−５系サマリウムーコバルト磁石においてはＳｍの含有量は３３．８〜４２．２ｗｔ％の範囲がのぞましく、この場合残部はＣｏ主体である。Ｓｍの内５０ａｔ％以下をＣｅ，Ｐｒなどで置換することもできる。Ｃｅは資源的に比較的豊富に存在しかつ安価である。Ｓｍなどの希土類元素Ｒの含有量が３３．８ｗｔ％より少ないか、或いは逆に４２．２ｗｔ％より多いと磁気特性が低下する。なお、上記成分のほか、製造上不可避の不純物が含まれる場合もある。２−１７系サマリウムーコバルト磁石においてはＳｍの含有量は２４．０〜２８．０ｗｔ％の範囲がのぞましく、この場合残部はＣｏ主体であり、Ｃｕ，Ｆｅに加えてＺｒ，Ｈｆ，Ｔａ，Ｎｂ，Ｎｉなどを含むことが多い。Ｓｍの内５０ａｔ％以下をＣｅ，Ｐｒなどで置換することもできる。Ｃｅは資源的に比較的豊富に存在しかつ安価である。Ｓｍなどの希土類元素Ｒの含有量が２４．０ｗｔ％より少ないか、逆に２８．０より多いと磁気特性が低下する。Ｃｕは通常１〜１２ｗｔ％含有される。Ｆｅは通常１〜２０ｗｔ％，Ｚｒ等は通常０．０１〜５ｗｔ％含有される。上記成分のほか、酸素、窒素など製造上不可避の不純物が含まれる場合もある。As the samarium-cobalt magnet constituting the permanent magnet in the present invention, a 1-5 samarium-cobalt magnet mainly composed of an Sm Co ₅ system intermetallic compound and a Sm ₂ Co ₁₇ mainly composed of 2-17 System samarium-cobalt magnets can be used. In the 1-5 samarium-cobalt magnet, the Sm content is desired to be in the range of 33.8 to 42.2 wt%, and in this case, the balance is mainly Co. It is also possible to replace 50 at% or less of Sm with Ce, Pr or the like. Ce is abundant in resources and inexpensive. If the content of the rare earth element R such as Sm is less than 33.8 wt% or conversely more than 42.2 wt%, the magnetic properties deteriorate. In addition to the above components, impurities that are unavoidable in production may be contained. In the 2-17 samarium-cobalt magnet, the Sm content is desired to be in the range of 24.0 to 28.0 wt%, in which case the balance is mainly Co, and in addition to Cu, Fe, Zr, Hf , Ta, Nb, Ni, etc. are often contained. It is also possible to replace 50 at% or less of Sm with Ce, Pr or the like. Ce is abundant in resources and inexpensive. If the content of the rare earth element R such as Sm is less than 24.0 wt% or conversely more than 28.0, the magnetic properties deteriorate. Cu is usually contained in an amount of 1 to 12 wt%. Fe is usually contained in an amount of 1 to 20% by weight, and Zr and the like are usually contained in an amount of 0.01 to 5% by weight. In addition to the above components, it may also contain impurities such as oxygen and nitrogen, which are inevitable in manufacturing.

【００１０】本考案における円盤状の永久磁石は、例えば次のようにして作製することができる。まず、Ｓｍ−Ｃｏ系合金を通常の方法でＡｒ，Ｎ₂中もしくは真空中で溶解する。溶解後のインゴットの粉砕は粗粉砕および微粉砕されるが、粗粉砕はスタンプミル、ジョークラッシャー、ブラウンミル、ディスクミル等により、また微粉砕はジェットミル、振動ミル、ボールミル等によって行う。粉砕後の粒径は２〜５μｍ（Ｆ．Ｓ．Ｓ．）とするのが良い。上記のようにして作製した磁粉を磁場中成形装置によって所定の形状の成形体とする。この成形体を次に焼結するのであるが、焼結は窒素、Ａｒ，Ｈｅ等のガス中もしくは真空中または水素中において２０分乃至３時間行う。焼結後、熱処理を施して磁気特性を高める。最後に磁粉の配向方向（この場合は軸方向）に揃えて着磁を行う。着磁磁場強度は１０〜３０ＫＯｅの範囲がよい。The disk-shaped permanent magnet according to the present invention can be manufactured, for example, as follows. First, Sm-Co-based alloy in a conventional manner Ar, to dissolve in N ₂ or in a vacuum. The crushed ingot after the melting is roughly crushed and finely crushed. The coarse crushing is performed by a stamp mill, a jaw crusher, a brown mill, a disc mill or the like, and the fine crushing is performed by a jet mill, a vibration mill or a ball mill. The particle size after crushing is preferably 2 to 5 μm (FSS). The magnetic powder produced as described above is formed into a molded product having a predetermined shape by a magnetic field molding device. The compact is then sintered. Sintering is performed for 20 minutes to 3 hours in a gas such as nitrogen, Ar, or He, in a vacuum, or in hydrogen. After sintering, heat treatment is applied to enhance magnetic properties. Finally, magnetization is performed by aligning with the orientation direction of the magnetic powder (in this case, the axial direction). The magnetizing magnetic field strength is preferably in the range of 10 to 30 KOe.

【００１１】[0011]

【実施例】【Example】

図１は本考案の実施例を示す一部縦断面図である。図１において１はケースであり、ステンレス鋼（ＳＵＳ３０４）により外径１６ｍｍ，内径１４ｍｍ，長さ７４ｍｍの中空円筒状に形成する。１´はケース先端のカーリング仕上げ部であり、ケース端部を蓋の形状に沿って折り曲げている。２はサマリウム−コバルト永久磁石であり、外径１４ｍｍ，厚さ４ｍｍの円板状に形成し、厚さ方向に着磁して両端面に１対の磁極ＮＳを設ける。３はヨークであり、軟鉄（ＳＳ−４１）により外径１４ｍｍ，厚さ６．５ｍｍの円板状に形成する。４は蓋であり、ケース１と同様のステンレス鋼により、外径１４ｍｍ、厚さ６．５ｍｍの截頭円錐台状に形成する。 FIG. 1 is a partial vertical sectional view showing an embodiment of the present invention. In FIG. 1, reference numeral 1 denotes a case, which is formed of stainless steel (SUS304) into a hollow cylindrical shape having an outer diameter of 16 mm, an inner diameter of 14 mm, and a length of 74 mm. Reference numeral 1'denotes a curling finish portion at the tip of the case, and the case end is bent along the shape of the lid. Reference numeral 2 is a samarium-cobalt permanent magnet, which is formed in a disk shape having an outer diameter of 14 mm and a thickness of 4 mm, and is magnetized in the thickness direction to provide a pair of magnetic poles NS on both end faces. Reference numeral 3 denotes a yoke, which is formed of soft iron (SS-41) into a disc shape having an outer diameter of 14 mm and a thickness of 6.5 mm. Reference numeral 4 denotes a lid, which is made of the same stainless steel as the case 1 and has a truncated cone shape with an outer diameter of 14 mm and a thickness of 6.5 mm.

【００１２】この胃内異物吸着磁石を組み立てるには、ケース１の一端に蓋４を固着し、次いでケース１内に磁石２とヨーク３とを交互にかつ同極性の磁極が対向する如く挿入し、その後ケース１の開放端に蓋４を固着すればよい。ケース１と蓋４との固着はケース１の端部に蓋４をはめ込み、次いでケース１の端部を内側に折り曲げることにより行う。なお、比較例として永久磁石２を各々Ｎｄ−Ｆｅ−Ｂ系永久磁石によって形成した胃内異物吸着磁石を作製した。図３には曲線ａ，ｂとして、それぞれ本考案の胃内異物吸着磁石と比較例の胃内異物吸着磁石における軸方向位置と表面磁束密度との関係を示す。胃内異物吸着磁石において永久磁石をＳｍ−Ｃｏ系磁石としてもＮｄ−Ｆｅ−Ｂ系永久磁石によって形成しても磁気特性上は大差ないといえる。むしろＳｍ−Ｃｏ系磁石としたものの方がＮｄ−Ｆｅ−Ｂ系永久磁石としたものよりも曲線の半値幅は大きく、総磁束密度は大きいといえる。つぎに、実施例の胃内異物吸着磁石１０個と比較例の胃内異物吸着磁石１０個とを１５０ｃｍの高さからコンクリート上に落下させた後、弱い酸に浸して耐食試験をおこなったところ、比較例の胃内異物吸着磁石１０個すべてが１５０時間〜３２０時間経過後にケース外にサビを漏洩したが、実施例の胃内異物吸着磁石１０個は１０００時間を経過しても変化が無かった。比較例の胃内異物吸着磁石は１５０ｃｍの高さからコンクリート上に落下させたことによって、何らかの損傷を受け、弱酸、水分、空気などでＮｄ−Ｆｅ−Ｂ磁石が腐食環境に曝されたためと考えられる。一方、実施例の胃内異物吸着磁石も１５０ｃｍの高さからコンクリート上に落下させたことによって、何らかの損傷を受けたが、弱酸、水分、空気などに対して抵抗性があるために１０００時間を経過しても変化が無かったものと考えられる。In order to assemble the magnet for adsorbing foreign matter in the stomach, the lid 4 is fixed to one end of the case 1, and then the magnets 2 and the yokes 3 are alternately inserted into the case 1 so that magnetic poles having the same polarity face each other. Then, the lid 4 may be fixed to the open end of the case 1 thereafter. The case 1 and the lid 4 are fixed to each other by fitting the lid 4 onto the end of the case 1 and then bending the end of the case 1 inward. As a comparative example, an intragastric foreign matter adsorption magnet was produced in which the permanent magnets 2 were each formed of an Nd-Fe-B system permanent magnet. In FIG. 3, curves a and b respectively show the relationship between the axial position and the surface magnetic flux density in the gastric foreign matter attracting magnet of the present invention and the gastric foreign matter attracting magnet of the comparative example. It can be said that there is no great difference in magnetic characteristics between the Sm-Co-based magnet and the Nd-Fe-B-based permanent magnet as the permanent magnet in the gastric foreign matter adsorption magnet. Rather, it can be said that the Sm-Co magnet has a larger half-width of the curve and the total magnetic flux density is larger than the Nd-Fe-B permanent magnet. Next, 10 magnets for adsorbing foreign substances in the stomach of the example and 10 magnets for adsorbing foreign substances in the stomach of the comparative example were dropped onto concrete from a height of 150 cm, and then immersed in a weak acid to perform a corrosion resistance test. All 10 gastric foreign matter adsorption magnets of the comparative example leaked rust outside the case after 150 hours to 320 hours, but the 10 gastric foreign matter adsorption magnets of the examples did not change even after 1000 hours. It was The gastric foreign matter adsorption magnet of the comparative example was damaged by being dropped onto concrete from a height of 150 cm, and the Nd-Fe-B magnet was exposed to a corrosive environment with weak acid, water, air, etc. Thought to be On the other hand, the gastric foreign matter adsorption magnet of the example was also damaged by being dropped onto the concrete from a height of 150 cm, but it was resistant to weak acids, water, air, etc. It is probable that there was no change even after passing.

【００１３】本実施例においては耐食性非磁性材料としてステンレスを使用した例に付いて記述したが、ステンレス以外の非磁性材料、例えば、樹脂などで形成してもよい。またケースの両端部に嵌着する蓋の形状は任意に選定してよい。In this embodiment, an example in which stainless is used as the corrosion-resistant non-magnetic material has been described, but a non-magnetic material other than stainless steel, for example, resin may be used. Further, the shape of the lid fitted on both ends of the case may be arbitrarily selected.

【００１４】[0014]

【考案の効果】[Effect of device]

本考案は以上記述のような構成及び作用であるから、下記の効果を奏しえる。（１）吸着磁石の表面磁束密度が大である。（２）磁性異物を優先的に吸着磁石の中間部に吸着する。（３）水分、空気などに対して強い耐腐食性を有し、結果として安全性にすぐれる。 Since the present invention has the configuration and operation as described above, the following effects can be obtained. (1) The surface magnetic flux density of the attracting magnet is large. (2) The magnetic foreign matter is preferentially attracted to the intermediate portion of the attracting magnet. (3) It has strong corrosion resistance against moisture and air, resulting in excellent safety.

【図面の簡単な説明】[Brief description of drawings]

【図１】本考案の実施例の縦断面図である。FIG. 1 is a vertical sectional view of an embodiment of the present invention.

【図２】従来例の縦断面図である。FIG. 2 is a vertical sectional view of a conventional example.

【図３】本考案の胃内異物吸着磁石と比較例の胃内異物
吸着磁石における軸方向位置と表面磁束密度との関係を
示す図である。FIG. 3 is a diagram showing the relationship between the axial position and the surface magnetic flux density in the gastric foreign matter adsorption magnet of the present invention and the comparative gastric foreign matter adsorption magnet.

【符号の説明】[Explanation of symbols]

１ケース２磁石３ヨーク４蓋 1 case 2 magnet 3 yoke 4 lid

Claims

【実用新案登録請求の範囲】[Scope of utility model registration request]

【請求項１】耐食性非磁性材料により中空円筒状に形
成したケース内に、軸方向に磁化した複数個の円盤状サ
マリウム−コバルト系永久磁石を、各々ヨークを挟んで
同極が対向するように軸方向に一体桿状に配設し、前記
ケースの両端部には耐食性材料からなる蓋を配置したこ
とを特徴とする胃内異物吸着磁石。1. A plurality of disc-shaped samarium-cobalt permanent magnets magnetized in an axial direction are arranged in a hollow cylindrical case made of a corrosion-resistant non-magnetic material so that the same poles face each other across a yoke. A magnet for adsorbing a foreign substance in the stomach, characterized in that it is arranged in a rod shape in the axial direction, and a lid made of a corrosion-resistant material is arranged at both ends of the case.