DE202005019162U1 - Brushless external rotor DC motor has ferromagnetic ring of anisotropic multipole magnets inside rotor - Google Patents

Abstract

A brushless external rotor DC motor comprises a ring ferromagnet of anisotropic multipole permanent magnets inside the rotor with outer non-magnetic and inner magnetic regions, a base plate (10) in a housing (92) with a central protruding shaft (12) surrounded by a stator (20) with exciter coils (22). The stator generates a rotating field for the rotor. An independent claim is also included for a motor as above having many blades on the outer surface of the rotor.

Description

technical area

The The invention relates to a brushless External rotor DC motor with an inner diameter oriented annular ferromagnet, which the can increase magnetic flux, so that the performance of the brushless External rotor DC motor is increased.

State of technology

To According to EPRI, electricity consumption has a share of 40% in the total energy consumption. With the increase in living standards the share of electricity consumption for the electrical system is also increasing equipment in the total electricity consumption.

It is estimated, that the Share of electricity consumption for the electrical appliances would increase to 80% in 2010, of which the motors use 55% of the electricity. The brushless External rotor DC motor has a speed of over 10,000 revolutions per minute. He's through a big rev range, a low rotor inertia, a low magnetic interference, a maintenance free and characterized by a lack of dust and is widely applied to the precision industry, such as CNC machine tool, semiconductor manufacturing, used.

thanks The new control technology has the brushless outer rotor DC motor more and more replacing the induction motor, e.g. Motors for fan, Air conditioning, compressor, washing machine, pump, electronic products (like projector, computer cooler etc.) The magnet of the outer rotor is usually made from a composite of NdFeB, which contains 94% NdFeB and Contains 6% nylon. By injection molding becomes a ring-shaped Blank obtained whose inner diameter is magnetized, thereby a ring-shaped anisotropic multipole magnet is formed. However, this magnet has the disadvantages of high manufacturing costs (Nd is a rare metal) and more difficult Production. Therefore, this magnet is very expensive.

• 1. Die Spalte zwischen den Magneten können zu einem Magnetverlust führen, so daß bei Betrieb des Dauermagnetes ein Hakmoment auftritt.
• 2. Die Montage des ringförmigen Dauermagnetes aus mehreren halbmondförmigen Magneten ist kraftaufwendig. Zudem ist die Rundheit schlechter.
• 3. Die Flußdichte des Magnetes aus NdFeB liegt in einem Bereich von 2100 bis 2300 Gauss und die Flußdichte des Ferromagnetes liegt in einem Bereich von 1650 bis 1950 Gauss. Daher ist der magnetischer Fluß des Ferromagnetes unzureichend.
• 4. Die Sintertemperatur des Ferromagnetes beträgt ca. 1240°C. Um einen Bruch zu vermeiden, soll die Dicke des Magnetes nicht zu klein sein, wodurch der Magnet einen größeren Außendurchmesser besitzt, so daß der Motor ein größeres Volumen hat.
• 5. Wegen der obengenannten Nachteile ist der ringförmige Dauermagnet aus mehreren halbmondförmigen Ferromagneten bislang noch nicht genormt.

To reduce the manufacturing cost, the NdFeB magnet is replaced by a pressed anisotropic ferromagnet. This magnet can only have a half moon shape. Therefore, at least three magnets are required to form a ring shape. This annular permanent magnet has the following disadvantages:

• 1. The gaps between the magnets can lead to a loss of magnetic, so that when operating the permanent magnet a hooking moment occurs.
• 2. The assembly of the annular permanent magnet of several crescent-shaped magnets is power consuming. In addition, the roundness is worse.
• 3. The flux density of the NdFeB magnet is in a range of 2100 to 2300 Gauss and the flux density of the ferromagnet is in the range of 1650 to 1950 Gauss. Therefore, the magnetic flux of the ferromagnet is insufficient.
• 4. The sintering temperature of the ferromagnet is approximately 1240 ° C. To avoid breakage, the thickness of the magnet should not be too small, whereby the magnet has a larger outer diameter, so that the motor has a larger volume.
• 5. Because of the above-mentioned disadvantages of the annular permanent magnet of several crescent-shaped ferromagnets is not yet standardized.

Either the magnet of NdFeB as well as the crescent-shaped ferromagnet is from a rotary body made of sheet iron to form magnetic circuits with the stator. These magnetic circuits are very large, so that the loss of magnetic force lines is very high. Therefore, the line of the pump is reduced.

Of the annular Permanent magnet of several crescent-shaped ferromagnets has next The lower production costs compared to other advantages with the magnet from NdFeB. The physical properties of the annular permanent magnet from several crescent-shaped Ferromagnets are better than the magnet from NdFeB. Therefore, the annular Permanent magnet made of several crescent-shaped ferromagnets for the application suitable, the higher one Temperature, moisture and chemical resistance calls. In addition is the ferromagnet is more environmentally friendly as it is reused produced by metal sludges is.

If the magnetic flux increases, the Magnetic loss reduced, the flux density increased and the magnetic field strength is enlarged, The ferromagnet can be optimally adapted to the brushless external rotor DC motor be applied. This is the goal of the invention.

Task of invention

The invention has for its object to provide a brushless external rotor DC motor with an inner diameter oriented annular ferromagnet consisting of a base plate, a stator and an outer rotor surrounding the stator, the base plate having a motor shaft; the stator comprises a yoke and an exciting coil; and the outer rotor has a rotary body and egg An inner diameter oriented annular ferromagnetic material abutting against the inner wall of the rotating body, wherein the inner diameter oriented annular ferromagnet is an anisotropic multipole permanent magnet, wherein the stator generates a rotating magnetic field after energization whereby the inner diameter oriented annular multipole ferromagnet of the outer rotor is repeatedly attracted and repelled by the rotating magnetic field and thus is set in rotation, so that the motor shaft is carried.

• 1. Die Basisplatte, der Stator und der Rotor sind alle im Gehäuse des Motors angeordnet, wobei die Motorwelle aus dem Gehäuse herausragt. Hierbei ist die Erfindung als ein Motor ausgebildet.
• 2. An der Außenseite des Außenrotors sind Schaufeln vorgesehen, die mit dem Außenrotor synchron gedreht werden. Hierbei ist die Erfindung als ein Schaufelrad für Ventilator ausgebildet.

The invention has two embodiments:

• 1. The base plate, the stator and the rotor are all arranged in the housing of the motor, with the motor shaft protruding from the housing. Here, the invention is designed as a motor.
• 2. On the outside of the outer rotor blades are provided, which are rotated synchronously with the outer rotor. Here, the invention is designed as a fan for fan.

There the inner diameter oriented annular ferromagnet is a nonmagnetic one outdoors and having a magnetic inner region, the magnetic lines of force become of the magnetic inner area through the non-magnetic outer area impeded, whereby the magnetic circuits are reduced and the magnetic Flow is thus increased, So that the Performance of the engine is increased.

in the The following is the invention with reference to the first and second embodiment and the attached Drawings closer explained.

Short description the drawings

1 a sectional view of the first embodiment of the invention,

2 a perspective view of the inner diameter-oriented annular ferromagnet,

3 a sectional view of the second embodiment of the invention.

Ways to execute the invention

1 shows the first embodiment of the invention, wherein the brushless outer rotor DC motor 90 a motor shaft having, with a pulley 91 is connected and this can rotate. Of course, the motor shaft can also be connected to a paddle wheel or the like.

In the present embodiment, the brushless outer rotor DC motor 90 from a base plate 10 a stator 20 and an outer rotor 30 that's the stator 20 surrounds.

The base plate 10 is in the case 92 of the motor 90 arranged and serves to support the stator 20 and the outer rotor 30 , In the middle of the base plate 10 is a motor shaft 12 with a warehouse 11 and on one side of the base plate 10 is a hall element 13 intended. The motor shaft 12 protrudes from the case 92 of the motor 90 out and connects to the pulley 91 , a paddle wheel or the like.

The stator 12 is around the motor shaft 12 arranged and includes a yoke 21 and an excitation coil 22 , which can generate a rotating magnetic field by energizing.

The outer rotor 30 comprises a rotary body 31 and an inner diameter oriented ferromagnetic ring 40 attached to the inner wall of the rotating body 31 is applied. The motor shaft 12 is through the rotating body 31 guided and firmly connected to it, whereby the inner diameter-oriented annular ferromagnet 40 the stator 20 surrounds and with the reverb element 13 has a suitable gap. When the inner diameter oriented annular ferromagnet 40 of the outer rotor 30 is rotated by the rotating magnetic field, the motor shaft 12 that with the rotary body 40 firmly connected, carried along and thus the pulley 91 , the impeller or the like driving the same.

The stator 20 generates after energizing a rotating magnetic field, whereby the inner diameter-oriented annular Multipolferromagnet 40 of the outer rotor 30 repeatedly attracted and repelled by the rotating magnetic field and thus rotated, so that the motor shaft 12 is carried. The speed of the outer rotor 30 is from the Hall element 13 detected, which thus emits a corresponding signal to control the work of the engine.

How out 2 is apparent, is the inner diameter oriented annular ferromagnet 40 an anisotropic multipole permanent magnet (the smaller the number of poles, the greater the speed) and has a non-magnetic outer area 41 and a magnetic interior 42 on, whereby the magnetic force lines of the magnetic inner area 42 through the non-magnetic outer area 41 be impeded, so that the magnetic circuits are reduced and the magnetic flux is thus increased. With the conventional magnet of NdFeB or crescent-shaped ferromagnet, the magnetic circuits are larger, whereby the loss of Magnetraftlini is very large, so that the power of the engine is reduced.

3 shows the second embodiment of the invention, which consists of a base plate 10 a stator 20 and an outer rotor 30 that's the stator 20 surrounds. The stator 20 generates after energizing a rotating magnetic field, whereby the inner diameter-oriented annular ferromagnet 40 of the outer rotor 30 is rotated so that the motor shaft 12 is carried.

The second embodiment differs from the first embodiment only in that the motor shaft 12 does not protrude from the housing of the engine and only as a rotation axis of the outer rotor 30 is used. To the rotating body 31 of the outer rotor 30 are a variety of blades 93 arranged. When the inner diameter oriented annular ferromagnet 40 through the stator 20 is rotated, the rotary body 31 and thus the blades 93 entrained, whereby an air flow is generated. This creates an external rotor fan.

In the present embodiment, the inner diameter-oriented annular ferromagnet 40 a non-magnetic outdoor area 41 and a magnetic interior 42 on, wherein the magnetic force lines of the magnetic inner region 42 through the non-magnetic outer area 41 be hampered. Therefore, it is not necessary on the outside of the inner diameter oriented annular ferromagnet 40 to provide an iron sheet to form magnetic circuits. In other words, the rotating body 31 and the blades 93 einteiig be injection molded from plastic, wherein the inner diameter-oriented annular ferromagnet 40 directly on the inside of the rotating body 31 is attached. This significantly reduces the weight of the fan and avoids vibration. This is particularly suitable for cooling fan with high speed.

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. The invention relates to a brushless external rotor DC motor with an inner diameter-oriented annular ferromagnet consisting of a base plate ( 10 ), a stator ( 20 ) and an outer rotor ( 30 ), the stator ( 20 ), wherein the stator ( 12 ) a yoke ( 21 ) and an exciter coil ( 22 ), and the outer rotor ( 30 ) a rotary body ( 31 ) and an inner diameter-oriented annular ferromagnet ( 40 ), which on the inner wall of the rotary body ( 31 ), wherein the inner diameter-oriented annular ferromagnet ( 40 ) is an anisotropic multipole permanent magnet and a non-magnetic outer region ( 41 ) and a magnetic interior area ( 42 ), whereby the magnetic force lines of the magnetic inner region ( 42 ) through the non-magnetic outer area ( 41 ) are obstructed, so that the magnetic circuits are reduced and the magnetic flux is thus increased. The stator ( 20 ) generates a rotating magnetic field after energization, whereby the inner diameter-oriented annular multipole ferromagnet ( 40 ) of the outer rotor ( 30 ) is repeatedly attracted and repelled by the rotating magnetic field and thus rotated, so that the motor shaft ( 12 ) is carried. When designed as a motor, the motor shaft protrudes from the housing of the motor and both training as fan blade for fan are on the outside of the outer rotor ( 30 ) Arranged blades.

Claims (4)

Brushless outer rotor DC motor with an inner diameter oriented annular ferromagnet consisting of a base plate ( 10 ) in the housing ( 92 ) of the motor ( 90 ) and for supporting the stator ( 20 ) and the outer rotor ( 30 ), wherein in the middle of the base plate ( 10 ) a motor shaft ( 12 ) provided from the housing ( 92 ) of the motor ( 90 protruding, a stator ( 12 ) around the motor shaft ( 12 ) is arranged and a yoke ( 21 ) and an exciter coil ( 22 ), and an outer rotor ( 30 ), which has a rotary body ( 31 ) and an inner diameter-oriented annular ferromagnet ( 40 ), which on the inner wall of the rotary body ( 31 ), wherein the inner diameter-oriented annular ferromagnet ( 40 ) is an anisotropic multipole permanent magnet, the stator ( 20 ) and a non-magnetic outer area ( 41 ) and a magnetic interior area ( 42 ), wherein the stator ( 20 ) generates a rotating magnetic field after energization, whereby the inner diameter-oriented annular multipole ferromagnet ( 40 ) of the outer rotor ( 30 ) is repeatedly attracted and repelled by the rotating magnetic field and thus rotated, so that the motor shaft ( 12 ) is carried. Brushless outer rotor DC motor with an inner diameter oriented annular ferromagnet consisting of a base plate ( 10 ) used to support the stator ( 20 ) and the outer rotor ( 30 ) and in the middle a rotation axis ( 12 ), a stator ( 12 ) around the motor shaft ( 12 ) is arranged and a yoke ( 21 ) and an exciter coil ( 22 ), and an outer rotor ( 30 ), which has a rotary body ( 31 ) and an inner diameter oriented ferromagnetic ring ( 40 ), which on the inner wall of the rotary body ( 31 ), wherein, around the rotary body ( 31 ) of the outer rotor ( 30 ) a plurality of blades ( 93 ), wherein the inner diameter-oriented annular ferromagnet ( 40 ) is an anisotropic multipole permanent magnet, the stator ( 20 ) and a non-magnetic outer area ( 41 ) and a magnetic interior area ( 42 ), wherein the stator ( 20 ) generates a rotating magnetic field after energization, whereby the inner diameter-oriented annular multipole ferromagnet ( 40 ) is repeatedly attracted and repelled by the rotating magnetic field and thus set in rotation, so that the rotary body ( 41 ) and thus the blades ( 93 ) are carried. Brushless external rotor DC motor according to claim 1 or 2, characterized in that on one side of the base plate ( 1 ) a Hall element ( 13 ) is provided, the speed of the inner diameter-oriented annular ferromagnet ( 40 ). Brushless external rotor DC motor according to claim 2, characterized in that the rotary body ( 31 ) and the blades ( 93 ) are injection molded from plastic.