KR940701579A - Cylindrical anisotropic magnet, manufacturing method and motor - Google Patents

Abstract

The present invention relates to a method of providing a cylindrical anisotropic magnet that increases the total magnetic flux generated in the magnetic poles, improving the cogging characteristics of the motor, and manufacturing the magnet. In addition, the present invention not only improves assembly efficiency but also increases the total magnetic flux generated at the stimulus to achieve miniaturization. To provide a motor with reduced noise, cogging characteristics must be improved. The non-magnetic ring is disposed in the outer circumference of the elliptical forming space whose elongated diameter coincides with the magnetization direction between the pair of magnetic poles, and the pair of magnets is disposed in the portion opposite to the elongated radial direction. After sintering the ellipsoidal molded product formed by the apparatus in which the core magnetic body is placed at the center, a cylindrical annealing can be performed to obtain a cylindrical anisotropic ferrite magnet having a diameter of D1. In the magnet, the pair of opposing portions is radially anisotropic within a certain angular range and the remaining portions are orthotropic. For example, a motor is obtained by press-fitting a ferrite magnet to the inner circumference of the cylindrical yoke to form a stator and installing the rotor in the inner circumferential space of the ferrite magnet. The cylindrical anisotropic sintered magnet can be obtained without cracking at the time of sintering by providing an integral cylindrical anisotropic magnet in which a specific part is radially anisotropic and the remaining part is orthotropic. Therefore, cogging can be reduced by utilizing the good characteristics of each anisotropic magnet.

Description

Cylindrical anisotropic magnet, manufacturing method and motor

Since this is an open matter, no full text was included.

1 is a plan view showing the stator portion of the motor of the present invention.

2A and 2B are views showing a cylindrical anisotropic magnet and its manufacturing apparatus installed in the motor of the present invention.

4 is another view showing the cylindrical anisotropic magnet of the present invention and its manufacturing apparatus installed in the motor.

5 is a plan view for explaining a manufacturing process of the cylindrical anisotropic magnet of the present invention having another configuration installed in the motor.

Claims (16)

A cylindrical anisotropic magnet, characterized in that it is integral with a pair of opposing portions that are radially anisotropic within a certain angular range and the remaining portions that are orthotropic and / or isotropic. The cylindrical anisotropic magnet according to claim 1, wherein the magnet is a ferrite magnet containing Sr and / or Ba. The cylindrical anisotropic magnet according to claim 1, wherein the magnet is a rare earth magnet. The cylindrical anisotropic magnet according to any one of claims 1 to 3, wherein the magnet has a radially anisotropic portion at 100 ° to 160 ° which is an angular range of θ2. A method of manufacturing a cylindrical anisotropic magnet, comprising: a molding frame having an elliptical molding space having a long diameter coinciding with a magnetization direction between a pair of magnetic poles, a pair of magnets provided at opposite portions of the pair of magnetic poles in the molding space; Molding the magnetic raw material under magnetic field in a molding apparatus having a core made of a magnetic body having a shape similar to that of the molding space; Sintering the ellipsoid to produce an integral sintered body having a substantially circular cross-section with a pair of opposing portions being radially anisotropic within a specified angular range and remaining portions being orthotropic and / or isotropic. How to. The method according to claim 5, further comprising a molding space composed of a pair of magnets arranged opposite the elongated radial direction of the molding space and a pair of nonmagnetic materials provided opposite the short radial direction. 7. The method of claim 5 or 6, comprising creating a forming space with a cylindrical nonmagnetic ring, wherein the ring thickness between the forming space and the pair of magnets is made small and the thickness is varied with respect to the circumferential direction. Characterized in that the method. The method according to claim 5 or 6, wherein D2 / D3, which is the ratio between the elongated diameter D2 and the short diameter D3, is 1.05 to 1.15, and the radial anisotropy angle range θ2 is 100 to 160 degrees of the molding. 8. The method of claim 7, wherein D2 / D3, which is the ratio of the elongated diameter D2 to the shorter diameter D3, is from 1.05 to 1.15 and the radial anisotropy angle range θ2 is from 100 ° to 160 ° of the molding. A method of manufacturing a cylindrical anisotropic magnet, comprising: a molding frame having a circular molding space between a pair of magnetic poles, a pair of magnets provided at opposite portions of the pair of magnetic poles in the molding space, and a magnetic body having a shape similar to the molding space. Molding the magnetic raw material under a magnetic field in a molding apparatus having a core; Sintering the molding having a substantially circular cross section to produce an integral elliptical sintered body in which the pair of opposing portions are radially anisotropic within a certain angular range and the remaining portions are orthotropic and / or isotropic. How to. 12. The molding space according to claim 10, further comprising a molding space comprising a pair of magnets provided in opposing portions of the pair of magnetic poles in the molding space, and a pair of nonmagnetic materials provided in the outer circumference, not the magnetic portions opposing each other. How to. The method according to claim 10 or 11, wherein D2 / D3, which is the ratio of the elongated diameter D2 to the short diameter D3, is 1.05 to 1.15, and the radial anisotropy angle range θ2 is 100 ° to 160 ° of the molding. A method of manufacturing a cylindrical anisotropic magnet, comprising: a molding frame having a circular molding space between a pair of magnetic poles, a pair of magnets provided at opposite portions of the pair of magnetic poles in the molding space, and a magnetic body having a shape similar to the molding space. Forming a mixed magnetic material under a magnetic field by adding a thermosetting resin, a binder, and a lubricating oil in a forming apparatus having a core; Curing the molding to produce an integral cylindrical anisotropic resin-bonded magnet in which the pair of opposing portions are radially anisotropic within a specified angular range and the remaining portions are orthotropic and / or isotropic. Way. 14. The molding space according to claim 13, characterized in that the molding space includes a pair of magnets provided in opposing portions of the pair of magnetic poles in the molding space, and a pair of nonmagnetic materials provided in the outer circumference of the magnet portions not opposed to each other. How to. The method according to claim 13 or 14, wherein the radial anisotropy range θ2 is between 100 ° and 160 ° of the molding. A pair of opposing portions is characterized by using an integral cylindrical anisotropic magnet which is radially anisotropic within a certain angular range and the remaining portions are orthotropic and / or isotropic, and the magnet is used as a stator or rotor. motor. ※ Note: The disclosure is based on the initial application.