DE202015100692U1 - Magnetic element of a rotor and fan motor - Google Patents

Abstract

A magnetic element of a rotor comprising a main body (11) having a plurality of north poles (N) and south poles (S) arranged alternately, with a magnetic boundary line (12) formed between each north pole (N) and south pole (S) wherein the magnetic boundary line (12) has a first vertical portion (121) and an inclined portion (122) extending downward from the lower end of the first vertical portion (121).

Description

Technical area

The invention relates to a magnetic element of a rotor and a fan motor with this magnetic element.

State of the art

The conventional brushless fan motor has a stator and a rotor. The pole change of the magnetic field rotates the rotor. For this purpose, an electromagnet or a permanent magnet is used. The stator has a sheet stack and a winding. After energizing the stator, a magnetic field is generated, through which the electromagnet or permanent magnet is rotated, whereby the impeller is rotated.

The conventional brushless fan motor usually uses a Hall element to detect the rotational position of the rotor. The Hall element detects the timing of the change of the north pole and the south pole, whereby the drive circuit can drive the rotor in rotation. The permanent magnet of the rotor is usually perpendicular (inclination angle 0) or obliquely magnetized. If the permanent magnet is perpendicularly magnetized, the position of the Hall element must be changed to find the best pole change point, which can generate a vibration. If the permanent magnet is magnetized obliquely, the vibration is reduced when changing the pole.

This, however, the engine efficiency is lowered.

Therefore, the inventor aims to offer a magnetic element of a rotor that can both reduce the vibration and increase the turning efficiency.

Object of the invention

The invention has for its object to provide a magnetic element of a rotor having magnetic boundary lines having a plurality of sections. The invention is based on a further object to provide a magnetic element of a rotor, which can reduce the vibration during pole change and ensure the engine performance, the sensor element can find the best pole change point. Another object of the present invention is to provide a fan motor which can reduce the vibration during pole change and ensure engine performance, whereby the sensor element can find the best pole change point. These objects are achieved by the magnetic element of a rotor according to the invention comprising a main body having a plurality of north poles and south poles alternately arranged, with a magnetic boundary formed between each north pole and south pole, the magnetic borderline defining a first vertical section and has an inclined portion extending downwardly from the lower end of the first vertical portion.

These objects are further achieved by the fan motor according to the invention, comprising: a stator having a radial magnetic surface and connected on the underside with a circuit board, wherein on the circuit board at least one sensor element is arranged; and a rotor facing the stator and having a magnetic member having a main body having a plurality of north poles and south poles alternately arranged, with a magnetic boundary formed between each north pole and south pole, the magnetic boundary line having a first magnetic field vertical portion facing the radial magnetic surface of the stator, and having an inclined portion which extends downwardly from the lower end of the first vertical portion and is located close to the sensor element.

Between the first vertical portion and the inclined portion, a first angled portion is formed.

The first vertical portion and the oblique portion include a first angle.

The magnetic boundary further has a second vertical portion extending downwardly from the oblique portion.

Between the oblique portion and the second vertical portion, a second angled portion is formed.

The oblique portion and the second vertical portion include a second angle.

The first vertical section is parallel to the second vertical section.

The inclined portion of the magnetic boundary line inclines in the rotational direction of the main body.

The main body has an upper side and a lower side and defines between the upper side and the lower side a first zone and a second zone below the first zone, the first zone facing the radial magnetic surface of a stator, the second zone not facing a magnetic surface the first vertical section the magnetic boundary line in the first zone and the oblique section in the second zone.

The main body has an upper side and a lower side and defines between the upper side and the lower side a first zone and a second zone below the first zone, the first zone facing the radial magnetic surface of a stator, the second zone not facing a magnetic surface the first vertical portion of the magnetic boundary line is in the first zone and the oblique portion and the second vertical portion are in the second zone.

Brief description of the drawings

1A a perspective view of the magnetic element according to the invention,

1B a further perspective view of the magnetic element according to the invention,

2A a partial sectional view of the invention Ventialtormotors,

2 B a plan view of the magnetic element and the stator,

3A a representation of the magnetization of the magnetic element according to the invention,

3B a representation of the magnetization of the magnetic element according to the invention.

Ways to carry out the invention

Further details, features and advantages of the invention will become apparent from the following detailed description taken in conjunction with the accompanying drawings.

How out 1A can be seen, comprises the magnetic element according to the invention 10 a main body 11 that a top 111 and a bottom 112 having. The main body 11 has a plurality of north poles N and south poles S, which are arranged alternately. Between each north pole N and south pole S is a magnetic boundary line 12 educated. The magnetic element 10 is formed by, for example, a hard magnet, a soft magnet or a magnetic powder, and made of alloy (Al-Ni-Co), ceramic (ferrite) or rare earth metal. In the present embodiment has the magnetic boundary line 12 a first vertical section 121 which is vertical from the top to near the bottom 112 extends, an oblique section 122 extending obliquely from the vertical portion and a second vertical portion 123 that is up to the bottom 112 extends. The first vertical section 121 is parallel to the second vertical section 123 , Between the first vertical section 121 and the sloping section 122 is a first angled section 124 educated. Between the sloping section 122 and the second vertical section 123 is a second angled section 125 educated. The first vertical section 121 and the sloping section 122 close a first angle 126 one. The sloping section 122 and the second vertical section 123 close a second angle 127 one.

1B shows a further embodiment of the invention, wherein the inclined portion 122 the magnetic boundary line from the first angled section 124 at the end of the first vertical section 121 until the bottom 112 of the main body 11 extends.

Like from the 2A and 2 B it can be seen, the magnetic element 10 on a fan motor 30 applied. The fan motor 30 has a stator 31 and a rotor 32 on. The stator 31 is on a base plate 33 arranged and has a radial magnetic surface 314 on. The radial magnetic surface 314 is through a stack of steel sheets 311 educated. To the steel sheets is a winding 312 placed. The stator 31 is on the bottom with a circuit board 35 connected. On the circuit board is at least one sensor element 34 , like Hall element, arranged.

The rotor 32 lies the stator 31 opposite and has a wheel hub 321 and a variety of blades 322 around the outside of the wheel hub 321 on. In the wheel hub 321 is an iron housing 323 arranged. The magnetic element 10 is on the inside of the iron housing 323 arranged and lies the stator 31 across from. The magnetic element 10 defined between the top 111 and the bottom 112 a first zone 114 and a second zone 115 under the first zone 114 , The first zone 114 lies the radial magnetic surface 314 of the stator 31 across from. The second zone 115 There is no magnetic surface 314 but is close to the sensor element 34 , The first vertical section 121 the magnetic boundary line 12 is in the first zone 1144 and lies the radial magnetic surface 314 across from. The sloping section 122 , the second vertical section 123 and the second angled section 125 are in the second zone 115 and are close to the sensor element 34 ,

The sloping section 122 the magnetic boundary line 12 tilts in the direction of rotation of the main body 11 , The boundary point of the first zone 114 and the second zone 115 is at the location of the first angled section 124 the magnetic boundary line 12 , After energizing the stator 31 becomes between the radial magnetic surface 314 and the magnetic element 10 generates a magnetic field, causing the rotor 32 is turned. Through the first vertical section 121 the magnetic boundary line 12 in the first zone 114 can increase the turning efficiency of the rotor 32 being held. Through the sloping section 122 the magnetic boundary line 12 in the second zone, the vibration can be reduced when changing the North Pole and the South Pole. In addition, the sensor element 34 find the best pole change point.

The 3A and 3B show the magnetization of the magnetic element of the rotor. The magnetization types are CM (Component Magnetization) and PAM (Post-Assembly Magnetization). In CM, the magnetic element is magnetized prior to assembly of the motor rotor. The PAM uses a non-magnetized magnetic element in the rotor. By an external circuit or a Magnetisierungsmachine a momentary strong current is generated, whereby a strong magnetic field is generated, so that the magnetic element is magnetized in the rotor. In the invention, the magnetic element is magnetized prior to assembly of the motor rotor. A rod-shaped magnetizing device 40 can generate a multi-pole magnetic field and has on the outside several separating parts 41 which are evenly distributed. The separating parts 41 are located at the border points of the North Pole and the South Pole. In the magnetization device 40 is a circuit arranged by an electrical line with an external power source 46 connected to the magnetizer 40 generates a magnetic field. Around the first vertical section 121 , the sloping section 122 , the second vertical section 123 , the first angled section 124 and the second angled portion 125 the magnetic boundary line 12 of the magnetic element 10 to form, have the separating parts 41 each a first vertical section 411 , a sloping section 412 , a second vertical section 413 , a first angled section 414 and a second angled portion 415 , Before the energization becomes the magnetic element 10 around the magnetizing device 40 placed. After energizing the magnetizing device 40 a magnetic field is generated, causing the magnetic element 10 around the magnetizing device 40 is magnetized. At the same time form the separating parts 41 at the corresponding locations of the magnetic element 10 the magnetic borderlines 12 between the northern poles and southern poles ( 1 ). The first vertical section 411 , the oblique section 412 , the second vertical section 413 , the first angled section 414 and the second angled section 415 form the first vertical section 121 , the sloping section 122 , the second vertical section 123 , the first angled section 124 and the second angled portion 125 the magnetic boundary line 12 of the magnetic element 10 ( 1 ).

In summary, it should be noted that the magnetic element according to the invention has magnetic boundary lines, which have a plurality of sections, whereby the sensor element 34 Find the best pole change point and the vibration can be reduced when changing pole, so that the engine performance can be guaranteed.

The foregoing description represents only the preferred embodiments of the invention and is not intended to serve as a definition of the limits and scope of the invention. All equivalent changes and modifications are within the scope of this invention.

Claims (20)

Magnetic element of a rotor, comprising a main body ( 11 ), which has a plurality of north poles (N) and south poles (S), which are arranged alternately, wherein between each north pole (N) and south pole (S) has a magnetic boundary line ( 12 ), wherein the magnetic boundary line ( 12 ) a first vertical section ( 121 ) and an oblique section ( 122 ) extending from the lower end of the first vertical section ( 121 ) extends downwards. Magnetic element according to claim 1, characterized in that between the first vertical section ( 121 ) and the oblique section ( 122 ) a first angled section ( 124 ) is formed. Magnetic element according to claim 2, characterized in that the first vertical section ( 121 ) and the oblique section ( 122 ) a first angle ( 126 ) lock in. Magnetic element according to Claim 3, characterized by a second vertical section ( 123 ) extending from the oblique section ( 122 ) extends downwards. Magnetic element according to claim 4, characterized in that between the oblique section ( 122 ) and the second vertical section ( 123 ) a second angled section ( 125 ) is formed. Magnetic element according to claim 5, characterized in that the oblique section ( 122 ) and the second vertical section ( 123 ) a second angle ( 127 ) lock in. Magnetic element according to claim 1, characterized in that the oblique section (FIG. 122 ) of the magnetic boundary line ( 12 ) in the direction of rotation of the main body ( 11 ) tends. Magnetic element according to claim 3, characterized in that the main body ( 11 ) an upper side ( 111 ) and a bottom ( 112 ) and between the top ( 111 ) and the underside ( 112 ) a first zone ( 114 ) and a second zone ( 115 ) under the first zone ( 114 ), the first zone ( 114 ) of the radial magnetic surface ( 314 ) of a stator ( 31 ), the second zone ( 115 ) no magnetic surface ( 314 ), the first vertical section (FIG. 121 ) of the magnetic boundary line ( 12 ) in the first zone ( 114 ) and the oblique section ( 122 ) in the second zone ( 115 ) is located. Magnetic element according to claim 6, characterized in that the main body ( 11 ) an upper side ( 111 ) and a bottom ( 112 ) and between the top ( 111 ) and the underside ( 112 ) a first zone ( 114 ) and a second zone ( 115 ) under the first zone ( 114 ), the first zone ( 114 ) of the radial magnetic surface ( 314 ) of a stator ( 31 ), the second zone ( 115 ) no magnetic surface ( 314 ), the first vertical section (FIG. 121 ) of the magnetic boundary line ( 12 ) in the first zone ( 114 ) and the oblique section ( 122 ) and the second vertical section ( 123 ) in the second zone ( 115 ) are located. Magnetic element according to claim 8 or 9, characterized in that the boundary point of the first zone ( 114 ) and the second zone ( 115 ) at the location of the first angled section ( 124 ) of the magnetic boundary line ( 12 ) is located. Fan motor comprising a stator ( 31 ), which has a radial magnetic surface ( 314 ) and on the underside with a circuit board ( 35 ), wherein on the circuit board at least one sensor element ( 34 ), and a rotor ( 32 ), which is the stator ( 31 ), comprising a magnetic element ( 10 ), which has a main body ( 11 ) having a plurality of north poles (N) and south poles (S) which are arranged alternately, wherein between each north pole (N) and south pole (S) has a magnetic boundary line ( 12 ), wherein the magnetic boundary line ( 12 ) a first vertical section ( 121 ), the radial magnetic surface ( 314 ) of the stator, and an oblique section (FIG. 122 ) extending from the lower end of the first vertical section ( 121 ) extends down and close to the sensor element ( 34 ) is located. Fan motor according to claim 11, characterized in that between the first vertical section ( 121 ) and the oblique section ( 122 ) a first angled section ( 124 ) is formed. Fan motor according to claim 12, characterized in that the first vertical section ( 121 ) and the oblique section ( 122 ) a first angle ( 126 ) lock in. Fan motor according to claim 13, characterized by a second vertical section ( 123 ) extending from the oblique section ( 122 ) extends downwards. Fan motor according to claim 14, characterized in that between the oblique section ( 122 ) and the second vertical section ( 123 ) a second angled section ( 125 ) is formed. Fan motor according to claim 15, characterized in that the oblique section ( 122 ) and the second vertical section ( 123 ) a second angle ( 127 ) lock in. Fan motor according to claim 16, characterized in that the inclined section ( 122 ) of the magnetic boundary line ( 12 ) in the direction of rotation of the main body ( 11 ) tends. Fan motor according to claim 14, characterized in that the main body ( 11 ) an upper side ( 111 ) and a bottom ( 112 ) and between the top ( 111 ) and the underside ( 112 ) a first zone ( 114 ) and a second zone ( 115 ) under the first zone ( 114 ), the first zone ( 114 ) of the radial magnetic surface ( 314 ) of a stator ( 31 ), the second zone ( 115 ) no magnetic surface ( 314 ), the first vertical section (FIG. 121 ) of the magnetic boundary line ( 12 ) in the first zone ( 114 ) and the oblique section ( 12 ) in the second zone ( 115 ) is located. Fan motor according to claim 16, characterized in that the main body ( 11 ) an upper side ( 111 ) and a bottom ( 112 ) and between the top ( 111 ) and the underside ( 112 ) a first zone ( 114 ) and a second zone ( 115 ) under the first zone ( 114 ), the first zone ( 114 ) of the radial magnetic surface ( 314 ) of a stator ( 31 ), the second zone ( 115 ) no magnetic surface ( 314 ), the first vertical section (FIG. 121 ) of the magnetic boundary line ( 12 ) in the first zone ( 114 ) and the oblique section ( 122 ) and the second vertical section ( 123 ) in the second zone ( 115 ) are located. Fan motor according to claim 18 or 19, characterized in that the boundary point of the first zone ( 114 ) and the second zone ( 115 ) at the location of the first angled section ( 124 ) of the magnetic boundary line ( 12 ) is located.

Images