DE10352663A1 - Rotor of rotary electrical device, especially motor or a.c. generator, has poles with stopper sections protruding towards shaft from outer end of poles engaged by middle sections of magnet holders - Google Patents

Abstract

The rotor has a rotary shaft, a rotor winding, a pair of pole core elements with claw-shaped poles (14a,15a), magnets (21) on both sides of the poles and magnet attachment elements (22a,22b), each of essentially C-shaped cross-section. Each pole has a stopper section protruding towards the shaft from an outer end of the pole that is engaged by the middle section (22b) of a magnet holding element.

Description

BACKGROUND THE INVENTION

1. area the invention

The present invention relates to generally a rotor of a rotating electrical device and in particular a rotor of an alternating current generator (AC) or Motors, the rotor being a pair of pole core elements with a plurality of claw-shaped includes magnetic poles which extend along an axial direction of the rotor at regular intervals extend around the rotor, the claw-shaped magnetic poles of directly facing or aligned with the individual pole core elements are and are in engagement with each other, as if surrounded by a rotor winding becomes.

2. State of the technology

A construction of a rotor usual rotating electrical device to which the invention is directed is in Japanese Patent Laid-Open Publication No. 2001-86715, for example. According to the publication, the rotor includes a rotor winding and a pair of pole core elements with a plurality of claw-shaped magnetic poles, which are like claws along an axial Direction of the rotor at regular intervals extend around the rotor. The rotor is by fitting the pole core elements constructed on a rotating shaft, the claw-shaped magnetic Poles of the two pole core elements from the front and rear sides are facing and engaged with each other so that the claw-shaped magnetic Poles surround the rotor winding, with a magnet forming a creates a magnetic field that is opposite in one direction oriented towards the direction of a magnetic flux which is formed between two adjacent claw-shaped magnetic poles which is between the side faces of the oppositely aligned two adjacent claw-shaped magnetic poles. The rotating electrical device (AC generator or motor) includes the rotor, which is such and a stator located around the rotor to surround, wherein the stator comprises a stator core on which one Stator winding is wound, as in the aforementioned patent publication shown.

If the pole core elements through the Rotor winding are excited in this design, the claw-shaped magnetic poles magnetized on one side as north poles (N), and the oppositely oriented claw-shaped magnetic poles the other side are called South Poles (S) magnetized. Because the magnets, which are the magnetic fields generate the opposite of the directions of the magnetic rivers are aligned or are oriented between the adjacent claw-shaped magnetic poles are formed, and located between the side surfaces of the oppositely oriented, adjacent, claw-shaped magnetic Poland are located, the number of lines of ineffective decreases magnetic fluxes between the side surfaces the adjacent claw-shaped magnetic poles, and being the number of lines of magnetic rivers elevated, which differs from the outer peripheral surfaces of the claw-shaped extend magnetic poles towards the stator.

One in the above-mentioned patent publication No. 2001-86715 proposed construction uses reinforcing elements with an essentially M-shaped Cross section to the magnets on both side faces of each claw-shaped magnetic Hold pole. Another construction, which is in the publication it is proposed to use reinforcing elements with an im Essentially C-shaped Cross section to the magnets on both side faces of each claw-shaped magnetic Hold pole. In both cases In this construction, the magnets are attached to fixed positions the side surfaces the claw-shaped magnetic poles through the reinforcing elements against a centrifugal force kept on the magnets due to the rotation of a rotor act because the reinforcing elements on the inside of the claw-shaped magnetic poles are provided with a hook or are hooked.

As through the discussion above shown, the rotor comprises the conventional rotating electrical Device (alternator or motor) a pair of pole core elements with a variety of claw-shaped magnetic poles, which are like claws on the axial direction of the Rotors at regular intervals extend around the rotor with the pole core elements on the rotating shaft with the claw-shaped magnetic poles of the two pole core elements from the front and rear Fitted sides facing or directly fitted and with each other are engaged so that the claw-shaped magnetic poles the Surround the rotor winding. The magnets, which are the magnetic fields generate that in the directions opposite to the directions of magnetic fluxes are aligned or oriented, which between the two adjacent claw-shaped magnetic poles are located between the faces the adjacent claw-shaped magnetic poles, the magnets being made by reinforcing elements be supported. In this construction, the reinforcement elements supported Magnets in the vicinity of or near any claw-shaped magnetic Pole held.

In the rotor of the conventional rotating electrical device constructed in such a way will each of the claw-shaped magnetic poles narrowed and thinned towards an extreme end or thinner, whereby an inclined surface forms on the inside. This prior art construction has a problem in that that the centrifugal force acting on the magnets and Vibrations that occur as a result of the rotation of the rotor, the reinforcing elements could cause which hold the magnets in the direction of the extreme Ends of the claw-shaped magnetic poles are shifted, so consequently the magnets from their normal positions.

SUMMARY THE INVENTION

This invention has been made to a solution of the above Provide problems of the prior art. Accordingly It is an object of the present invention to provide a rotor provide rotating electrical device in which Magnets between side faces from adjacent claw-shaped magnetic poles of a pair of pole core elements isolated are stationary on the side surfaces the claw-shaped magnetic poles independently of the changes the speed of rotation of the rotor or of periodic or repetitive Cycles of its rotational movement and its stopping kept stationary become.

According to the invention, a Rotor of a rotating electrical device a rotating shaft, a rotor winding surrounding the rotary shaft, a pair of pole core elements with a variety of claw-shaped magnetic poles, which extend along an axial direction of the Rotors at regular intervals extend around the rotor with the pole core elements on the rotor shaft are fitted or adapted, their claw-shaped magnetic Poles from the front and rear sides or the front and rear side directly or opposite are aligned and engaged with each other so that the claw-shaped magnetic poles surround the rotor winding, a variety of magnets, which are on either side of each claw-shaped magnetic pole, so that each of the magnets creates a magnetic field that is in a direction opposite to the direction of a magnetic flux aligned or oriented, which is between the adjacent claw-shaped magnetic poles is formed, and a variety of magnetic attachment elements for holding the magnets against both side surfaces of each claw-shaped magnetic Pole. Each of the magnetic attachment members essentially has one C-shaped cross section on, Magnet holding sections are provided on both sides for holding the magnets against the side faces of each claw-shaped magnetic Pole are formed, and wherein a central portion is provided which is a flat plate-like Shape having an inclined inner surface of each of the claw-shaped magnetic Pole corresponds or is adapted, wherein each of the magnetic attachment elements and the magnets that are in the magnet holding sections on both sides a magnetic assembly form. The claw-shaped magnetic poles of the pole core elements, which each have a stopper section, the towards the rotating shaft from the extreme end of each claw-shaped magnetic Pole protrudes from its inclined inner surface, and the Magnetic assembly stuck to each claw-shaped magnetic pole is attached, the central portion of the magnetic attachment member is engaged with the stopper portion on the inclined inner area (or the step down) of each claw-shaped magnetic Pole is formed.

This construction prevents that the magnetic assembly and the magnets fitted in it Direction of the extreme end due to each claw-shaped magnetic pole the centrifugal force is or are displaced, which on the magnets of the magnet assembly as a result of the rotation of the Rotary shaft works. This construction makes it possible to have a rotating rotor to produce electrical device in which neither the magnetic assemblies nor the magnets fitted in it deviate from their normal positions or can go missing.

These and other tasks, characteristics and advantages of the present invention will become apparent from the following detailed description in conjunction with the accompanying drawings seen.

SHORT DESCRIPTION THE ATTACHED DRAWINGS

1 Fig. 12 is a cross-sectional view illustrating the construction of the rotating electrical device according to a first embodiment of the invention;

2 FIG. 10 is a perspective view showing the construction of a rotor of the rotating electrical device of FIG 1 represents;

3 12 is a perspective view of a portion having a claw-shaped magnetic pole of the rotor of FIG 2 ;

4 10 is a partial perspective view of the claw-shaped magnetic pole of FIG 3 when viewed from the direction of its extreme end;

5 10 is a sectional view of the claw-shaped magnetic pole in FIG 3 ;

6A . 6B and 6C are explanatory slides gram representing how the magnetic assemblies are attached to the individual claw-shaped magnetic poles by a caulking method according to a second embodiment of the present invention;

7 Fig. 11 is an explanatory diagram showing how the magnetic assemblies are attached to individual claw-shaped magnetic poles according to a third embodiment of the invention;

8th Fig. 12 is a sectional view illustrating a pole core portion provided with guard rings fitted within the claw-shaped magnetic poles of the pole core elements according to a fourth embodiment of the present invention;

9A and 9B FIG. 10 is a partial perspective view of the claw-shaped magnetic pole of FIG 8th when viewed from its extreme end, or a perspective view of the support ring; and

10A and 10B 14 are diagrams illustrating a construction according to a fifth embodiment of the invention, wherein a magnetic attachment member for attaching a magnet assembly to each of the claw-shaped magnetic poles has retaining strips to clasp a rear portion of the claw-shaped magnetic pole.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIRST EMBODIMENT

1 10 is a sectional view of a rotating electrical device such as a generator or a motor according to a first embodiment of the invention, and 2 Fig. 3 is a perspective view of a rotor of the rotating electrical device.

The rotating electrical device comprises a housing 1 with a front holder 1A and a rear holder 1B , both made of aluminum, a stator 2 with a stator core 3 on an inside wall of the case 1 is attached, and with a stator winding 4 , a rectifier 5 with the stator winding 4 to convert an AC voltage in the stator winding 4 is induced into a direct current (DC) voltage connected to a regulator 6 to regulate the alternating current which is generated by the stator winding 4 is generated, a brush holder 7 for holding the brushes 7A through which excitation currents to the rotor 10 are supplied, and a heat sink 8th on the brush holder 7 is fitted.

The rotor 10 includes a rotating shaft 11 , a rotor winding 12 which the rotor shaft 11 surrounds, and a pair of front and rear pole core elements 14 . 15 , with the front pole core elements 14 a variety of claw-shaped magnetic poles 14a which are claw-like along an axial direction of the rotor 10 at regular intervals around the rotor 10 extend, and the rear pole core member 15 with a variety of claw-shaped magnetic poles 15a which are claw-like along the axial direction of the rotor 10 at regular intervals around the rotor 10 extend, is provided. The front and rear pole core elements 14 . 15 are on the rotating shaft 11 arranged or fitted, the claw-shaped magnetic poles 14a . 15a the front and rear pole core elements 14 . 15 are provided such that they face each other or are directly aligned and in engagement with one another, so that the claw-shaped magnetic poles 14a . 15a the rotor winding 12 surround.

In relation to 3 are on either side of each of the claw-shaped magnetic poles 14a . 15a a pair of magnets 21 which generate the magnetic fields oriented in directions opposite to the directions of the magnetic fluxes between the adjacent claw-shaped magnetic poles 14a . 15a be formed. These magnets 21 are in magnet holding sections 22a a magnetic holding element 23 fitted which together a magnetic assembly 20 form.

The slip rings 16 through which the excitation currents to the rotor winding 12 are fed are on the rotary shaft 11 fitted. The fans are the same 17 on the rotating shaft 11 close to both of its ends on the outside of the front and rear pole core members 14 . 15 arranged or fitted. The rotor 10 is through the front bracket 1a and the rear holder 1b rotatable around the rotating shaft 11 through camp 9a and 9b mounted on the front or rear portion of the rotary shaft 11 are attached. Furthermore, a role 18 at one end of the rotating shaft 11 appropriate.

If excitation by the rotor winding 12 is made, the claw-shaped magnetic poles 14a . 15a the front and rear pole core elements 14 . 15 magnetized, the claw-shaped magnetic poles 14a of the pole core element 14 for example, generate N poles, and the claw-shaped magnetic poles 15a of the pole core element 15 for example generate S poles. The magnets 21 are located between the adjacent claw-shaped magnetic poles 14a . 15a the front and rear pole core elements 14 . 15 for generating the magnetic fields which are oriented in the directions opposite to the directions of the magnetic fluxes between the adjacent claw-shaped magnetic poles 14a . 15a are formed, which are magnetized to thereby increase the number of lines of magnetic flux along a circumferential direction of the rotor 10 are distributed. Accordingly, the magnets are 21 arranged so that the N poles of the magnets 21 the side faces of the claw-shaped magnetic poles 14a facing, which generate the N poles, and that S poles of the magnets 21 the side faces of the claw-shaped magnetic poles 15a facing which generate S poles. Because the magnets 21 which generate the magnetic fields which are oriented in directions opposite to the directions of the magnetic fluxes between the adjacent claw-shaped magnetic poles 14a . 15a are formed between the side surfaces of the claw-shaped magnetic poles 14a . 15a placed in this manner will reduce the number of ineffective magnetic flux lines that exist between the side surfaces of the adjacent claw-shaped magnetic poles 14a . 15a are formed, and the number of magnetic flux lines increasing the stator is increased 2 to cut.

The following describes how the magnets 21 on the side faces of each of the claw-shaped magnetic poles 14a . 15a are attached.

3 Fig. 3 is a perspective view of a portion having the claw-shaped magnetic poles 14a of the pole core element 14 or the claw-shaped magnetic pole 15a of the pole core 15 , in which 4 a partial perspective view of each of the claw-shaped magnetic poles 14a . 15a is when viewed from its extreme end, and where 5 a sectional view of each of the claw-shaped magnetic poles 14a . 15a along its longitudinal direction.

Each of the claw-shaped magnetic poles 14a . 15a becomes thinner towards the extreme end, thereby forming an inclined inner surface as shown in the figure. This inclined inner surface of each of the claw-shaped magnetic poles 14a . 15a which of the rotating shaft 11 facing, has a "stepped down" step, which has a shallow groove-like transverse recess 14c . 15c forms in which a middle section or middle section 22b of the magnetic attachment member 22 can be fitted, the recess 14c . 15c through a stopper section 14b . 15b is limited, which in the direction of the rotating shaft 11 along the extreme end of the magnetic pole 14a . 15a protrudes as shown in the figure. Every magnet 21 has a substantially plate-like shape with a trapezoidal cross section in side view, around the shape of the claw-shaped magnetic pole 14a . 15a to match or adapt to this.

Any magnetic attachment element 22 which with two magnets 21 in the magnet holding sections 22a is provided on the claw-shaped magnetic pole 14a . 15a attached to its side (inclined inner surface), which is the rotary shaft 11 facing so that the magnet 21 on side faces of the claw-shaped magnetic pole 14a . 15a are positioned. The magnet holding sections 22a of the magnetic attachment member 22 by bending the side portions of the magnetic attachment member 22 formed in such a way that the bent portions of the magnetic attachment member 22 along an outer peripheral surface of the claw-shaped magnetic pole 14a . 15a and then extend parallel to its side surface, the magnets 21 on the side surface of the claw-shaped magnetic pole 14a . 15a are positioned. Because the middle section 22b of the magnetic attachment member 22 has a flat plate-like shape which corresponds to the inclined inner surface of the claw-shaped magnetic pole 14a . 15a corresponds to that of the rotary shaft 11 faces, the magnet attachment element 22 a substantially C-shaped cross section as a whole. The magnetic attachment element 22 is made, for example, of an approximately 0.5 mm thick, non-magnetic stainless steel sheet. The magnetic attachment element 22 and the magnets 21 which in the magnet holding sections 22a are fitted, respectively on both sides of the magnetic attachment element 22 are formed, together form the aforementioned magnetic assembly 20 ,

The magnetic assembly thus constructed 20 is on the claw-shaped magnetic pole 14a . 15a by applying an adhesive to the inclined inner surface of the claw-shaped magnetic pole 14a . 15a that of the rotating shaft 11 is facing, and on an inner surface of the magnetic attachment member 22 attached, causing the magnetic assembly 20 on the claw-shaped magnetic pole 14a . 15a is attached in the way that the middle section 22b of the magnetic assembly 20 in the recess 14c . 15c is fitted or used, which in the inclined inner surface of the claw-shaped magnetic pole 14a . 15a is formed, and causing the adhesive to harden. Then the front and rear pole core elements 14 . 15 on the rotating shaft 11 fitted in the way that the claw-shaped magnetic poles 14a and 15a which differ from the pole core elements 14 and 15 extend, are engaged with each other from the front and rear sides, so that the rotor shaft 12 is surrounded.

If the magnetic assembly 20 on the claw-shaped magnetic pole 14a . 15a with an adhesive 23 is attached, which serves as a filling material between the magnets 21 and the magnetic attachment member 22 and between the magnets 21 and the side faces of the claw-shaped magnetic pole 14a . 15a is filled, there are gaps between the claw-shaped magnetic pole 14a . 15a and the magnet together construction 20 refilled. This arrangement supports that the sections of the magnetic assembly are reciprocated 20 around the magnets 21 is prevented when the rotor 10 rotates.

The magnetic attachment element 22 can on the inclined inner surface of the claw-shaped magnetic pole 14a . 15a which of the rotating shaft 11 is facing, by welding the edges of the magnetic attachment element 22 with the stopper section 14b . 15b of the claw-shaped magnetic pole 14a . 15a be attached. The magnetic assembly 20 can on the claw-shaped magnetic pole 14a . 15a be attached with high reliability, and a back and forth or fluttering of the magnetic sections of the magnetic assembly 20 , which may occur if the rotor 10 rotates, can also be prevented or suppressed in this construction.

The magnets 21 which on the side surfaces of the claw-shaped magnetic pole 14a . 15a are to be positioned using the magnetic attachment element 22 assembled or assembled to the magnetic assembly 20 form, which on the claw-shaped magnetic Po1 14a . 15a is attached in this embodiment as explained above. The stopper section is used in this construction 14b . 15b of the claw-shaped magnetic pole 14a . 15a to prevent a phenomenon, namely the magnetic assembly 20 along the inclined inner surface of the claw-shaped magnetic pole 14a . 15a which of the rotating shaft 11 is facing towards its extreme end due to a centrifugal force applied to the magnetic assembly 20 as a result of the rotation of the rotor 10 acts.

SECOND EMBODIMENT

According to a second embodiment of the invention, each is magnetic assembly 20 the first embodiment by caulking on the claw-shaped magnetic pole 14a . 15a attached. The 6A . 6B and 6C show how the caulking or caulking is carried out. 6A is a sectional view of the claw-shaped magnetic pole 14a . 15a . 6B Fig. 12 is a partial sectional view showing how the stopper section 14b . 15b of the claw-shaped magnetic pole 14a . 15a using a mortising tool 25 is caulked, such as a chisel or chisel, and 6C Fig. 12 is a partial sectional view showing a state in which the stopper section 14b . 15b has been caulked, all elements being identical or similar to those of the first embodiment with the same reference numerals.

A caulking process used in this embodiment includes the steps of fitting the midsection 22b of the magnetic attachment member 22 on every magnet assembly 20 in the recess 14c . 15c which in the claw-shaped magnetic pole 14a . 15a is trained as in 6A shown, and a caulking of the stopper portion 14b . 15b of the claw-shaped magnetic pole 14a . 15a , as in 6B shown to the middle section 22b of the magnetic attachment member 22 in the recess 14c . 15c hold back safely as in 6C shown. After connecting the magnetic assemblies 20 on the individual claw-shaped magnetic poles 14a . 15a become the front and rear pole core elements 14 . 15 on the rotating shaft 11 appropriate.

According to the caulking method according to the second embodiment described above, it is possible to assemble the magnet 20 in a simple manner and reliably on the claw-shaped magnetic poles 14a . 15a fasten securely.

THIRD EMBODIMENT

7 Fig. 12 is a sectional view illustrating how a magnetic attachment member 22 from any magnetic assembly 20 in a recess 14c . 15c which are in each claw-shaped magnetic pole 14a . 15a is configured, used or fitted according to a third embodiment of the invention, identical or similar elements of the first embodiment being designated by the same reference numerals.

In this embodiment, the opposite ends of the recess 14c . 15c in the claw-shaped magnetic pole 14a . 15a shaped in such a way that they form inclined surfaces which face inwards towards the recess 14c . 15c are inclined. The magnetic attachment element 22 from any magnetic assembly 20 is in a curved shape at its central portion 22b bent and into the recess 14c . 15c in the claw-shaped magnetic pole 14a . 15a inserted or fitted so that the magnetic attachment element 22 is securely attached in position.

The magnetic attachment element 22 from any magnetic assembly 20 is with its middle section 22b inserted or fitted, which in the recess 14c . 15c in the claw-shaped magnetic pole 14a . 15a is wrapped or wrapped. This construction makes it possible to assemble the magnets 20 in a simple way into the claw-shaped magnetic poles 14a . 15a insert or fit and securely attach to it.

FOURTH EMBODIMENT

8th Fig. 12 is a sectional view particularly illustrating how to assemble in pole core portion according to a fourth embodiment of the invention, and wherein 9A a perspective partial view of each claw-shaped magnetic pole 14a . 15a is when viewed from its extreme end, and where 9B is a perspective view showing the shape of a locking ring 31 represents, wherein identical or similar elements of the first embodiment are given the same reference numerals.

According to this embodiment, there is a locking ring 31 inside the magnet assemblies 20 used or adapted, which on the claw-shaped magnetic poles 14a . 15a the front and rear pole core elements 14 . 15 are attached.

The locking ring 31 is formed in a truncated circular conical shape, the curved outer surface being tapered to within the inclined inner surfaces of the claw-shaped magnetic poles 14a . 15a to be fitted which of the rotating shaft 11 are facing. After fitting the magnetic assemblies 20 on the claw-shaped magnetic poles 14a . 15a the locking ring thus formed 31 inside the claw-shaped magnetic poles 14a . 15a from each pole core element 14 . 15 used such that a circumferential portion with a large diameter of the locking ring 31 at the middle sections 22b of the magnetic attachment elements 22 is arranged or is located on these. Then the front and rear pole core elements 14 . 15 on the rotating shaft 11 appropriate.

The outer diameter of the snap ring 31 is determined taking into account the amount of elastic deformation that occurs when the circlip 31 against the middle sections 22b of the magnetic attachment elements 22 is pressed, which are arranged in a ring shape with a specific diameter. With this structure, it is possible to apply an outward pressing force to the center portions 22b of the magnetic attachment elements 22 by fitting the locking ring 31 to apply, the magnetic assemblies 20 on the claw-shaped magnetic poles 14a . 15a can be firmly attached.

FIFTH EMBODIMENT

10A Fig. 12 is a sectional view illustrating how a magnetic assembly 40 on each claw-shaped magnetic pole 14a . 15a is applied according to a fifth embodiment of the invention, and 10B Fig. 3 is a perspective view of a magnetic attachment member 42 of the magnetic assembly 40 , Identical or similar elements to the first embodiment having the same reference numerals.

In this embodiment, the magnetic attachment member has 42 to hold the magnets 21 on the side faces of the claw-shaped magnetic poles 14a . 15a a pair of left and right hand tabs 42c on which extends from a front portion of the magnetic attachment member 42 extend which on the magnetic pole 14a . 15a is attached, and these are bent to be on the rear side of the claw-shaped magnetic pole 14a . 15a to be held. The holding strips 42c which are on the left and right sides of the magnetic attachment member 42 are provided, clasp the claw-shaped magnetic pole 14a . 15a around its rear side in a safe manner.

The magnetic assemblies 40 are at the claw-shaped magnetic poles 14a . 15a constructed and attached to this as follows. First, every magnet assembly 40 by fitting the magnets 21 into the magnet holding sections 42a of the magnetic attachment member 42 assembled and into the recess 14c . 15c in the claw-shaped magnetic pole 14a . 15a inserted, and being the left and right tether 42c over a rear portion of the claw-shaped magnetic pole 14a . 15a be fitted. Then the blunt or joined ends of the left and right tether strips 42c , which face each other, for example connected by welding, the magnetic assembly 40 is completed.

Any magnetic assembly 40 is on the back of the claw-shaped magnetic pole 14a . 15a hung like a hook or provided with a hook. This construction is used for the magnetic assemblies 40 are held securely in fixed positions and that the magnetic assemblies are prevented 40 along the claw-shaped magnetic poles 14a . 15a towards their extreme ends due to a centrifugal force applied to each magnet assembly as a result of the rotation of the rotor 10 acts.

It can be seen that the aforementioned construction of the magnetic attachment member 42 with the holding strips 42c in this embodiment can also be applied to the constructions of the first to fourth embodiments.

Claims (7)

Rotor ( 10 ) a rotating electrical device, the rotor ( 10 ) has: a rotating shaft ( 11 ); a rotor winding ( 12 ) which the rotary shaft ( 11 ) surrounds; a pair of pole core elements ( 14 . 15 ) with a large number of claw-shaped magnetic poles ( 14a . 15a ) that claw-like along an axial direction of the rotor ( 10 ) at regular intervals around the rotor ( 10 ), each of the claw-shaped magnetic poles ( 14a . 15a ) becomes thinner towards its extreme end, whereby an inclined inner surface is formed, which the rotary shaft ( 11 ) facing, and wherein the pole core elements ( 14 . 15 ) on the rotating shaft ( 11 ) are fitted, the claw-shaped magnetic poles ( 14a . 15a ) directly facing and engaging with each other from the front and rear sides so that the claw-shaped magnetic poles ( 14a . 15a ) the rotor winding ( 12 ) surround; a variety of magnets ( 21 ), which is on both sides of each claw-shaped magnetic Po1 ( 14a . 15a ) so that each of the magnets ( 21 ) generates a magnetic field which is oriented in a direction opposite to the direction of a magnetic flux which is between the adjacent claw-shaped magnetic poles ( 14a . 15a ) is trained; and a variety of magnetic attachment elements ( 22 ) to hold the magnets ( 21 ) on both side surfaces of each of the claw-shaped magnetic poles ( 14a . 15a ); each of the magnetic attachment members ( 22 ) an essentially C-shaped cross section with a plurality of magnet holding sections ( 22a ), which hold the magnets on both sides ( 21 ) on the side faces of each claw-shaped magnetic pole ( 14a . 15a ) are formed, and with a central section ( 22b ) which has a plate-like shape corresponding to the inclined inner surface of each claw-shaped magnetic pole ( 14a . 15a ), with each of the magnetic attachment members ( 22 ) and each of the magnets ( 21 ), which in the magnet holding sections ( 22a ) are used on both sides, together a magnetic assembly ( 20 ) form; each of the claw-shaped magnetic poles ( 14a . 15a ) of the pole core elements ( 14 . 15 ) a stopper section ( 14b . 15b ), which in the direction of the rotary shaft ( 11 ) from the extreme end of each claw-shaped magnetic pole ( 14a . 15a ) protrudes from the inclined inner surface; and the magnetic assembly ( 20 ) on each of the claw-shaped magnetic poles ( 14a . 15a ) is firmly attached, the middle section ( 22b ) of the magnetic holding element ( 22 ) with the stopper section ( 14b . 15b ) which is on the inclined inner surface of each of the claw-shaped magnetic poles ( 14a . 15a ) is trained. Rotor ( 10 ) of the rotating electrical device according to claim 1, wherein the magnetic assembly ( 20 ) on each of the claw-shaped magnetic poles ( 14a . 15a ) with an adhesive ( 23 ) is attached, which on the middle section ( 22b ) of the magnetic attachment element ( 22 ) is applied, and wherein the magnetic attachment element ( 22 ) on each of the claw-shaped magnetic poles ( 14a . 15a ) is attached when the adhesive ( 23 ) hardens. Rotor ( 10 ) of the rotating electrical device according to claim 1, wherein the magnetic attachment member ( 22 ) on each of the claw-shaped magnetic poles ( 14a . 15a ) by welding the magnetic attachment element ( 22 ) on the stopper section ( 14b . 15b ) of each of the claw-shaped magnetic poles ( 14a . 15a ) is attached. The rotor of the rotating electrical device according to claim 1, wherein the magnetic attachment member ( 22 ) on each of the claw-shaped magnetic poles ( 14a . 15a ) by caulking the stopper section ( 14b . 15b ) of each of the claw-shaped magnetic poles ( 14a . 15a ) is attached. Rotor ( 10 ) of the rotating electrical device according to claim 1, wherein the magnetic attachment member ( 22 ) on each of the claw-shaped magnetic poles ( 14a . 15a ) by attaching the magnetic attachment element ( 22 ) is attached, the middle section ( 22b ) is bent into a curved shape. Rotor ( 10 ) of the rotating electrical device according to one of claims 1 to 5, wherein the rotor ( 10 ) also a circlip ( 31 ) which is inside the claw-shaped magnetic poles ( 14a . 15a ) is used, with the locking ring ( 31 ) has a shortened, conically shaped outer surface, the diameter of which is such that the outer surface of the locking ring ( 31 ) in close contact with the inclined inner surface of the magnet assembly ( 20 ) which is on each of the claw-shaped magnetic poles ( 14a . 15a ) is attached. Rotor ( 10 ) of the rotating electrical device according to any one of claims 1 to 6, wherein the magnetic attachment member ( 42 ) of the magnetic assembly ( 40 ) a restraint ( 42c ), which can be seen from both sides as a basic element of the magnetic attachment element ( 42 ) extends and each of the claw-shaped magnetic poles ( 14a . 15a ) clasped around the rear side when this over each of the claw-shaped magnetic poles ( 14a . 15a ) is attached.