CN104200987A - Homopolar vertical magnet splicing method of magnet - Google Patents

Homopolar vertical magnet splicing method of magnet Download PDF

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Publication number
CN104200987A
CN104200987A CN 201410481815 CN201410481815A CN104200987A CN 104200987 A CN104200987 A CN 104200987A CN 201410481815 CN201410481815 CN 201410481815 CN 201410481815 A CN201410481815 A CN 201410481815A CN 104200987 A CN104200987 A CN 104200987A
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magnet
sub
volume
fight
partial
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CN 201410481815
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Chinese (zh)
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叶青
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叶青
潘君昂
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Publication of CN104200987A publication Critical patent/CN104200987A/en

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Abstract

The invention discloses a homopolar vertical magnet splicing method of a magnet. The homopolar vertical magnet splicing method is used for reinforcing magnetic field strength of the bar magnet and includes the following steps of a), longitudinally cutting the bar magnet along the N-S (north-south) direction to form a first sub-magnet and a second sub-magnet; b), vertically placing the first sub-magnet and the second sub-magnet to allow the first sub-magnet and the second sub-magnet to be homopolarly attached with each other; c), fixing the first sub-magnet and the second sub-magnet to form the spliced magnet. By the homopolar vertical magnet splicing method, magnetic force of the magnet can be increased by more than 15%, and meanwhile, the homopolar vertical magnet splicing method is easy and convenient to operate and easy to widely promote and use.

Description

一种磁体的同极垂直拼磁方法 Same vertical pole magnet magnetizing method fight

技术领域 FIELD

[0001] 本发明涉及永久磁体技术领域,特别是一种磁体的同极垂直拼磁方法。 [0001] The present invention relates to the technical field of the permanent magnet, in particular a vertical pole of the same magnet magnetically fight.

背景技术 Background technique

[0002] 众所周知,磁体的磁力线形状和磁场强度取决于磁体本身质地的密度及磁体体积的大小,在同一质地不变及体积大小不增加的情况下它的磁力线形状和磁场强度不会发生改变,尤其是在磁体厚度不容提高的情况下提高磁体磁力几乎是不可能的,因此,为了增加磁铁的磁力,目前较为通用的方法是将数个磁铁组合形成新的磁铁,或者将已有磁铁作为磁芯,并在磁芯周围缠绕线圈并通入直流电,以增加磁铁的磁力。 [0002] is well known, the shape of the magnetic field lines and magnetic field strength depends on the density and size of the magnet volume of the texture, the shape of its magnetic field lines and magnetic field strength of the magnet itself does not change in the case of same quality and the same size of the volume does not increase, in particular to improve the thickness of the magnet in the case of not increasing the magnetic force of the magnet it is almost impossible, and therefore, in order to increase the magnetic force of the magnet, the more common method is currently the number of magnets combined to form a new magnet or magnets have a magnetic core, and a coil is wound into a direct current and to increase the magnetic force of the magnet around the magnetic core. 但是,这些方法都对材料有较高的要求,当所拥有的磁体数量有限,或是无法找到合适的线圈或电源时,上述方法便不再适用了。 However, these methods have high demands on the material, when the number of magnets have a limited, or can not find a suitable coil or a power supply, the above-described methods are inapplicable.

[0003] 为此,人们通过镜子对光的反射原理,想到了在磁铁的一个面上设置铁片,利用磁场无法穿透铁片的特性,降低磁铁在该面上的磁场强度,增强另一个面上的磁场强度,从而通过简单方式增强磁铁的磁场。 [0003] For this reason, it is by the principle of mirror reflection of light, provided on one surface thought iron magnet, magnetic field properties can not penetrate the iron sheet, deterioration of magnetic field strength in the plane, the other enhancement the magnetic field strength of the surface, thereby enhancing the magnetic field of the magnet in a simple manner. 但这样设计会有一个缺陷,那就是经过改进的磁铁仅有一个方向可以使用,若将此类磁铁用于发电装置、电动装置中,则无法实现其设计目的。 However, this design there is a defect that the magnet is improved only in one direction can be used, if such a magnet for power generation means, electric means, it can not achieve its design purpose.

[0004] 为此,本申请人所申请的中国专利CN101807466公开了一种磁体的复极拼磁方法,其首先是在磁体任一磁极的一端加一块横向导磁板,然后在磁体一侧放一块或在磁体两侧各放一块与横向导磁板垂直相接的竖向导磁板,并在竖向导磁板与磁体之间设置一定厚度的非导磁间隔物,这样使横向导磁板和竖向导磁板相通而产生磁通,在磁通的作用下,磁体与横向导磁板接触的那一端的磁力线将变短并经横向导磁板和竖向导磁板的导磁路径到达磁体另一极,在此过程中,磁力线因受横向导磁板和竖向导磁板的导通约束而在到达磁体另一极时产生挤压并向上延伸,从而使磁体磁力增强。 [0004] To this end, Chinese patent CN101807466 applicant of the present application discloses one kind of the complex spell pole magnet magnetizing method, which is a first pole of a magnet according to any one input terminal of a transverse magnetic plate, and then put on one side of the magnet or put on a vertical transverse magnetic flux plate and a vertical plate in contact with both sides of the magnet, and a certain thickness is provided between the vertical plate and the magnet magnetic non-magnetic spacer, so that the magnetic plate and the lateral vertical plate magnetic flux generated in communication, under the action of the magnetic flux, the magnet flux plate in contact with the transverse lines of magnetic force that will be shorter and the end of the magnetic path by the transverse magnetic flux plate and vertical plate reaches another magnet a pole, in this process, due to the transverse magnetic field lines and magnetic conduction plate constraints vertical magnetic plate and reaches the magnet poles when pressed and to generate a further extend, such that the magnetic force of the magnet is enhanced.

[0005] 如中国专利CN101807466具体实施方式所述,通过该方法拼磁之后的磁铁,磁场强度可以由4700T提升至5600T,上升幅度近20 %,但是,上述拼磁方法步骤复杂,操作难度大,不易于广泛推广使用。 [0005] The Chinese Patent No. CN101807466 as particular embodiments, the magnet, the magnetic field strength after spell by this method to be increased from 4700T 5600T, nearly 20% rise, however, to fight the above-described steps magnetically complex, difficult operation, not easy to widely used.

发明内容 SUMMARY

[0006] 本发明所要解决的技术问题在于现有技术中的磁体拼磁方法步骤复杂且操作难度大,而提供了一种操作简单方便,且磁场强度提升效果基本维持同样水平的磁体拼磁方法。 [0006] The present invention solves the technical problem that the prior art magnet magnetizing method steps fight complicated and difficult operation, provides a simple and convenient, the effect of improving the strength of the magnetic field and substantially maintaining the same level of the magnet magnetizing method fight .

[0007] 为解决上述技术问题,本发明采用的技术方案如下: [0007] To solve the above problems, the present invention employs the following technical solutions:

[0008] 一种磁体的同极垂直拼磁方法,用于增强条形磁铁的磁场强度,包括如下步骤: [0008] The same magnet pole vertical magnetic fight method for enhancing the magnetic field strength of a bar magnet, comprising the steps of:

[0009] a.将所述条形磁铁沿其NS纵向切割,形成第一分磁铁和第二分磁铁; . [0009] a bar magnet along said longitudinal cutting NS, forming a first magnet and a second sub-sub-magnets;

[0010] b.将所述第一分磁铁和所述第二分磁铁垂直放置,且所述第一分磁铁和所述第二分磁铁的同极相互贴合; . [0010] b of the first magnet and the second sub-sub-magnets positioned vertically, and the first sub-magnets and with the second partial magnet poles bonded to each other;

[0011] c.将所述第一分磁铁和所述第二分磁铁固定,形成拼接后的磁铁。 [0011] c. Said first magnet and said second partial magnet fixing points, the magnet is formed after splicing.

[0012] 上述拼磁方法中,所述步骤b中,所述第二分磁铁的端面与所述第一分磁铁的侧面互相贴合。 [0012] The fight magnetic method, the step (b), the second end surface of the first sub-magnet sub-side surface of each bonded magnet.

[0013] 上述拼磁方法中,所述步骤b中,所述第一分磁铁和所述第二分磁铁的S极相互贴口ο [0013] The fight magnetic method, the step (b), the first sub-division of the second magnet and the S pole of a magnet attached to another port ο

[0014] 上述拼磁方法中,所述步骤b中,所述第一分磁铁和所述第二分磁铁的N极相互贴口O [0014] The fight magnetic method, the step (b), the first sub-division of the second magnet and said N pole of a magnet attached to another O port

[0015] 上述拼磁方法中,所述步骤a中,切割后的所述第一分磁铁体积占所述条形磁铁体积的20% -40%。 [0015] The fight magnetic method, the step a, after the cutting of the first sub-magnets 20% -40% by volume of the volume of the bar magnet.

[0016] 上述拼磁方法中,所述步骤a中,切割后的所述第一分磁铁体积占所述条形磁铁体积的30%。 [0016] The fight magnetic method, the step a, after the cutting of the first sub-magnets 30% by volume of the volume of the bar magnet.

[0017] 上述拼磁方法中,所述步骤a中,切割后的所述第一分磁铁体积占所述条形磁铁体积的60% -80%。 [0017] The fight magnetic method, the step a, after the cutting of the first sub-magnets 60% -80% by volume of the volume of the bar magnet.

[0018] 上述拼磁方法中,所述步骤a中,切割后的所述第一分磁铁体积占所述条形磁铁体积的70%。 [0018] The fight magnetic method, the step a, after the cutting of the first partial magnet 70 percent by volume of the volume of the bar magnet.

[0019] 本发明的上述技术方案相比现有技术具有以下优点: [0019] The technical solution of the present invention has the following advantages over the prior art:

[0020] ①本发明的拼磁方法,用于增强条形磁铁的磁场强度,包括如下步骤:a.将所述条形磁铁沿其NS纵向切割,形成第一分磁铁和第二分磁铁;b.将所述第一分磁铁和所述第二分磁铁垂直放置,且所述第一分磁铁和所述第二分磁铁的同极相互贴合;c.将所述第一分磁铁和所述第二分磁铁固定,形成拼接后的磁铁。 [0020] ① fight magnetizing method of the invention, for enhancing the magnetic field strength of a bar magnet, comprising the steps of: a longitudinal cut along the bar magnet which NS, forming a first magnet and a second sub-sub-magnets;. . B of the first magnet and the second sub-sub-magnets positioned vertically, and the first sub-magnets and with the second partial magnet poles bonded to each other; C and the first partial magnet. said second magnet fixing points, the magnet is formed after splicing. 这样的设计,可以使磁体的磁力增加15%以上,同时,操作简单方便,易于广泛推广使用。 This design, can increase the magnetic force of the magnet is above 15%, while simple and easy to operate, easy to use widely.

[0021] ②本发明的拼磁方法,切割后的所述第一分磁铁体积占所述条形磁铁体积的20% -40%或60% -80%。 [0021] ② fight magnetizing method of the present invention, the cut of the first partial magnet by volume or 20% -40% 60% -80% of the volume of the bar magnet. 这样的设计,可以使拼接后磁体的磁力增加幅度更大。 This design, the magnetic force of the magnet can be increased much greater after splicing.

[0022] ③本发明的拼磁方法,切割后的所述第一分磁铁体积占所述条形磁铁体积的30%或70%。 [0022] ③ of the present invention, a magnetic piece, said first partial magnet after cutting 30% by volume or 70% by volume of the bar magnet. 这样的设计,可以使拼接后磁体的磁力增加幅度最大化。 This design, the magnetic force of the magnet can be increased to maximize the amplitude of the splice.

附图说明 BRIEF DESCRIPTION

[0023] 为了使本发明的内容更容易被清楚的理解,下面根据本发明的具体实施例并结合附图,对本发明作进一步详细的说明,其中 [0023] In order to make the present invention understood more readily apparent, according to the following particular embodiments of the invention taken in conjunction with the accompanying drawings, the present invention will be further described in detail, wherein

[0024] 图1是本发明中实施例中条形磁铁拼接前的结构示意图; [0024] FIG. 1 is a schematic front bar magnet splicing embodiment of the present invention embodiment;

[0025] 图2是本发明中实施例中条形磁铁拼接后的结构示意图。 [0025] FIG. 2 is a schematic view of the splice bar magnet embodiment of the present invention in embodiments.

[0026] 图中附图标记表示为:1-条形磁铁,2-第一分磁铁,3-第二分磁铁。 [0026] reference numerals as in FIG: 1 to a bar magnet, a first sub magnet 2-, 3- second partial magnet.

具体实施方式 Detailed ways

[0027] 如图1-2所示,是本发明的优选实施例。 [0027] As shown in FIG 1-2, a preferred embodiment of the present invention. 本实施例公开了一种磁体的同极垂直拼磁方法,用于增强条形磁铁I的磁场强度,包括如下步骤: The present embodiment discloses a vertical pole of the same magnet fight magnetizing method for enhancing the magnetic field intensity I bar magnet, comprising the steps of:

[0028] a.将所述条形磁铁I沿其NS纵向切割,形成第一分磁铁2和第二分磁铁3。 [0028] a. The bar magnet NS I cut longitudinally along a first magnet 2 and the second sub-sub-magnet 3 is formed. 在本实施例中,将所述条形磁铁I沿χ-χ'方向切割,切割后的所述第一分磁铁2体积占所述条形磁铁I体积的30%。 In the present embodiment, the bar magnet along I χ-χ 'direction of the cutting, after cutting the first fraction by volume of the magnet bar magnet 2 I of 30% by volume.

[0029] b.将所述第一分磁铁2和所述第二分磁铁3垂直放置,且所述第一分磁铁2和所述第二分磁铁3的同极相互贴合。 [0029] b. Said first and said second partial magnet 2 vertically divided magnet 3 and the magnet 2 and the first sub-division with the second pole of the magnet 3 bonded to each other. 在本实施例中,所述第二分磁铁3的端面与所述第一分磁铁2的侧面互相贴合。 In the present embodiment, the second end surface of the magnet 3 and the partial side of the first 2 minutes of each bonded magnet. 进一步地,所述第一分磁铁2和所述第二分磁铁3的S极相互贴八口ο Further, the first magnet 2 and the second sub-sub-magnet poles S 3 mutually abutting eight ο

[0030] c.将所述第一分磁铁2和所述第二分磁铁3固定,形成拼接后的磁铁。 [0030] c. 2 of the first magnet and said second divided sub-magnet 3 is fixed, the magnet is formed after splicing. 在本实施例中,所述第一分磁铁2和所述第二分磁铁3通过焊接固定。 In the present embodiment, the first magnet 2 and the second sub-sub-magnet 3 is fixed by welding.

[0031] 利用这个拼磁方法应用在医疗领域增加磁力而不改变厚度却可提磁力复盖面增加治疗效果。 [0031] With this fight magnetically medical applications thickness is increased without changing the magnetic force may provide increased coverage on a magnetic therapeutic effect. 还可以广泛应用于其它领域在不增加磁体的情况下获得更大的效益增长。 Also it can be widely applied to other areas of greater growth in benefits without increasing the magnet.

[0032] 在其他实施例中,所述步骤b中,所述第一分磁铁2和所述第二分磁铁3的N极相互贴合。 [0032] In other embodiments, step b, the first magnet 2 and the second sub-division of the N pole magnet 3 bonded to each other. 磁力线的方向并不影响本发明对磁场强度的增幅效果。 The direction of magnetic lines of force increase in effect does not affect the magnetic field strength of the present invention.

[0033] 在其他实施例中,所述步骤a中,切割后的所述第一分磁铁2体积还可以为所述条形磁铁I体积的20%、25%、35%、40%、60%、65%、70%、75%、80%或其它数值,其磁力增幅效果也随着该数值的不同而变化,但并不影响本发明设计目的的实现。 [0033] In other embodiments, the step a, after the cutting of the first partial volume of the magnet 2 may also be a bar magnet I volume of 20%, 25%, 35%, 40%, 60 %, 65%, 70%, 75%, 80%, or other value, which increase the magnetic force effect with a different value of the change, but does not affect the object of the present invention is designed to achieve.

[0034] 显然,上述实施例仅仅是为清楚地说明所作的举例,而并非对实施方式的限定。 [0034] Clearly, the above-described embodiments are merely made to clearly illustrate example, and not limited to the embodiment. 对于所属领域的普通技术人员来说,在上述说明的基础上还可以做出其它不同形式的变化或变动。 Those of ordinary skill in the art, on the basis of the above described variations or changes may be made in various other forms. 这里无需也无法对所有的实施方式予以穷举。 It is unnecessary and can not be exhaustive of all embodiments. 而由此所引申出的显而易见的变化或变动仍处于本发明创造的保护范围之中。 And obvious variations or variations therefrom come out of the still in the scope of the present inventions.

Claims (8)

1.一种磁体的同极垂直拼磁方法,用于增强条形磁铁(I)的磁场强度,其特征在于,包括如下步骤: a.将所述条形磁铁(I)沿其NS纵向切割,形成第一分磁铁(2)和第二分磁铁(3); b.将所述第一分磁铁(2)和所述第二分磁铁(3)垂直放置,且所述第一分磁铁(2)和所述第二分磁铁(3)的同极相互贴合; c.将所述第一分磁铁(2)和所述第二分磁铁(3)固定,形成拼接后的磁铁。 A magnet with pole vertical magnetic fight method for enhancing the bar magnet (I) of the magnetic field strength, characterized by comprising the steps of:. A said bar magnet (I) in which the longitudinal cutting NS forming a first sub magnet (2) and a second sub magnet (3);. b of the first sub magnet (2) and the second sub-magnets (3) disposed vertically, and the first partial magnet (2) and the second sub-magnets (3) of the same polarity mutually bonded; C the first partial magnet (2) and said second partial magnet (3) is fixed, the magnet is formed after splicing.
2.根据权利要求1所述的拼磁方法,其特征在于:所述步骤b中,所述第二分磁铁(3)的端面与所述第一分磁铁(2)的侧面互相贴合。 The magnetizing method according to fight claim 1, wherein: said step (b), a side face of the second partial magnet (3) with the first partial magnet (2) is bonded to each other.
3.根据权利要求1所述的拼磁方法,其特征在于:所述步骤b中,所述第一分磁铁(2)和所述第二分磁铁(3)的S极相互贴合。 The magnetizing method according to fight claim 1, wherein: said step b, the first sub magnet (2) and said second partial magnet (3) is bonded to another S pole.
4.根据权利要求1所述的拼磁方法,其特征在于:所述步骤b中,所述第一分磁铁(2)和所述第二分磁铁(3)的N极相互贴合。 The magnetizing method according to fight claim 1, wherein: said step b, the first sub magnet (2) and said second partial magnet (3) is bonded to N poles face each other.
5.根据权利要求1-4任一所述的拼磁方法,其特征在于:所述步骤a中,切割后的所述第一分磁铁(2)体积占所述条形磁铁(I)体积的20% -40%。 5. The method of magnetic fight 1-4 according to one of the preceding claims, characterized in that: said step a, after the cutting of the first partial magnet (2) by volume of the bar magnet (I) Volume 20% -40%.
6.根据权利要求5所述的拼磁方法,其特征在于:所述步骤a中,切割后的所述第一分磁铁(2)体积占所述条形磁铁(I)体积的30%。 The fight magnetically claim 5, wherein: said step a, after the cutting of the first partial magnet (2) 30% by volume of the bar magnet (I) volume.
7.根据权利要求1-4任一所述的拼磁方法,其特征在于:所述步骤a中,切割后的所述第一分磁铁(2)体积占所述条形磁铁(I)体积的60% -80%。 7. The method of magnetic fight 1-4 according to one of the preceding claims, characterized in that: said step a, after the cutting of the first partial magnet (2) by volume of the bar magnet (I) Volume 60% -80%.
8.根据权利要求7所述的拼磁方法,其特征在于:所述步骤a中,切割后的所述第一分磁铁(2)体积占所述条形磁铁(I)体积的70%。 8. The method of fight magnetic claimed in claim 7, wherein: said step a, after the cutting of the first partial magnet (2) 70% by volume of the bar magnet (I) volume.
CN 201410481815 2014-09-22 2014-09-22 Homopolar vertical magnet splicing method of magnet CN104200987A (en)

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