FR2644641A1 - Armature in a generator - Google Patents

Abstract

Armature in a generator, in which a coil unit 8 is mounted on a specific pole A1 of a multiplicity of poles of a core body 1. A resinous surround 20 covering the coil unit 8 is moulded from resin at the same time as the coil supports formed on the other poles of the core body. A secondary core 6 is mounted in order to cooperate with two cooperation recesses 1a provided in the specific pole A1. The secondary core 16 is moulded at the same time as the coil unit 8 via the resinous surround 20 so as to constitute a unitary assembly. Furthermore, the resin of the resinous surround passes through a multiplicity of through-holes 7 provided in the specific pole A1 in order to bind together the coil unit 8 and the core body 1 so as to constitute a unitary assembly.

Description

Reinforcement in a generator
The present invention relates to generator frames and, more specifically, to an armature actually used in a magneto-generator for small two-wheeled vehicles.

Usually or normally in a generator installed on a small two-wheeled vehicle an armature which includes an ignition coil (hereinafter called "excitation coil"), in which a metallic coil wire, having a diameter of the on the order of 0.1 to 0.2 mm, is wound on the order of 5000 times and a multiplicity of load / light coils (hereinafter called "load coils"), in which the coil metal wire, having a diameter on the order of 0.8 to 1.0 mm, is wound on the order of a few hundred times.

In this way, the winding structure of the exciting coil is completely different from that of the load coils. Accordingly, various methods have been proposed to improve productivity. For example, the exciting coil, which requires complicated terminal processing and wrapping, is manufactured separately from other load coils. Next, the exciting coil is mounted on a core body, having a multiplicity of poles arranged so as to extend radially while also being spaced from each other.

As an example of an armature manufactured by these methods, mention may be made of an armature as described in the unexamined Japanese Utility Model Application No. SHO 59-117 278.

In the frame, an excitation coil wound around a coil support is surrounded with the support by a resinous casing. The resinous case is mounted around an I-shaped pole. A pole piece or a secondary core is poured into the bolier. The pole piece is magnetically connected to an axis end of the pole.

In addition, as described in the unexamined Japanese Utility Model Publication No. SHO 57-21234, there is a frame which is made as follows. An exciting coil is formed such that the wire of the coil is wound around a pole separated from a core body by a coil holder which is formed by insert molding. The separate excitation coil is fixedly mounted, so that a dovetail portion formed in the form of a projection on the pole of the exciter core is force fitted in a dovetail groove provided in the core body.

However, in the first frame, means are separately required to mount the excitation coil on the I-shaped pole. For example, a method described in the unexamined publication of Japanese Utility Model No SHO 61-81755 is used, or the like, for fixedly mounting the exciting coil by a crimping process.

As a result, there may be a rupture of the spool due to its deformation, and a creep in a surface of the spool holder, which then raises a problem which is known as "a game". In addition, due to the forced assembly at the moment when the excitation coil is engaged in the pole and is fixedly mounted therein, it is necessary to seriously control the dimensional accuracy, etc., of the coil holder, the resinous box , magnetic part, pole, etc.

On the other hand, in the last frame, when the coil is wrapped around the coil support and is fixedly mounted therein so that the coil is force-fitted in the groove in the core body, a interval between the coil holder and the core body in order to prevent the coil from being deformed during press fit. However, due to the fact that the dovetail portion of the pole of the exciting coil, which is forcibly mounted in the dovetail groove in the core body, is thin or narrow, stress is concentrated there. during vibrations, and in particular in the event of resonance.

This is what comes to be known as a game. In addition, since the spool holder and the core body are mounted one inside the other, checking dimensional accuracy, etc. becomes difficult.

It is an object of the invention to provide a frame for a generator which is capable of preventing the appearance of what is known as a game in a support of an exciting coil, and which allows '' lighten the requirements of dimensional control.

According to the invention, there is provided an armature in a generator, comprising - a core body having a multiplicity of poles, - a coil unit mounted on a first pole of the core body, - a resinous frame for covering an outer periphery of the coil unit mounted on the first pole, and - of the coil supports mounted on the other poles, in which the resinous surround is molded in resin at the same time as the coil supports in a coupled manner, where it results that the coil unit is linked to the core body so as to form a unitary assembly.

In the frame of the generator of the invention described above, the resinous surround molded in resin around the outer periphery of the coil unit and the resinous coil supports formed on the core body are linked so as to form a unitary set. Thus, the coil unit is secured to the core body without play. Consequently, it does not appear what is called a clearance in the coil holder in the coil unit, even in case vibration when the engine is running at high speed Furthermore, since the coil unit is integral with the core body without the need for force mounting or the like, the requirements of dimensional accuracy can be alleviated , etc., for press fit.

According to the invention, another armature is also carried out in a generator comprising: a core body having a multiplicity of poles; - a coil unit secured to a specific pole of the core body; - an ae-cooperation recess formed at a front end of the specific pole, the coil unit being mounted around the specific pole; - A secondary core mounted on the specific pole, so that this secondary core cooperates with the cooperation recess; and - a resinous surround to cover an external periphery of the coil unit which is mounted on this specific pole, the resinous surround being formed on the external periphery of the coil unit so as to form a unitary assembly with the body of nucleus.

In the armature of a generator of the invention described above, the resin of the resinous environment, which is molded in resin around the outer periphery of the coil unit, fills a gap between the secondary core and the coil unit or pole, the secondary core being mounted so as to join the specific pole and the coil unit at the front end of the specific pole.

Thus, the coil unit is secured without play to the core body. Consequently, it does not appear what is called a clearance in the spool holder of the spool unit, also in the case of vibrations resulting from a high speed rotation of the motor. In addition, the coil unit and the secondary core are integral with the core body without the need for force mounting or the like. It is thus possible to alleviate the requirements of dimensional precision, etc., for forced mounting.

According to the invention, there is still another armature in a generator, comprising - a core body having a multiplicity of poles; - a coil unit secured to a specific pole or core body; - one or more resinous filling sections formed in the core body at a location adjacent to the specific pole on which the coil unit is mounted; and - a resinous surround to cover an outer periphery of the coil unit mounted on this specific pole, in which the resinous surround has its resin which fills the resinous filling section (s) to respectively form one or more resinous solid sections, from which it follows that the coil unit is linked to the core body so as to form a unitary assembly.

In the frame of the generator of the invention described above, the resinous surround molded in resin around the outer periphery of the coil unit and the solid resinous section or sections respectively formed at the level of the resinous filling section or sections provided in the core body are linked to each other in a unitary manner. Thus, the coil unit is secured to the core body without play. Consequently, it does not appear what is called a clearance in the coil holder of the coil unit, also in case vibration resulting from high speed rotation of the motor Furthermore, the coil unit is secured to the core body without the need for force mounting or the like. Thus, it is possible to alleviate the requirements of dimensional accuracy, etc., for the forced mounting.

The invention will be better understood on reading the detailed description, given below by way of example only, of several preferred embodiments, in conjunction with the attached drawing in which identical references designate identical elements and in which: - Figure 1 is a side sectional view showing a frame in a magneto-generator according to an embodiment of the invention; - Figure 2 is a front elevational view of the frame shown in Figure 1; - Figure 3 is a partial top plan view of the frame shown in Figure 1; - Figure 4 is a front elevational view showing a core body of the frame illustrated in the figures
I to 3; - Figure 5 is a top plan view showing an exciter coil unit of the armature shown on
Figures 1 to 4; - Figure 6 is a front elevational view of the exciting coil unit shown in Figure 5;
- Figure 7 is a partial sectional view of the exciter coil unit shown in Figures 5 and 6; - Figure 8 is a top plan view of a secondary core shown in Figures 1 and 3; - Figure 9 is a front elevational view of the secondary core illustrated in Figure 8; - Figure 10 is a cross-sectional view taken along line XX of Figure 8; - Figure 11 is a side sectional view showing a frame in a magneto-generator according to another embodiment of the invention; - Figure 12 is a front elevational view of the frame shown in Figure 11; - Figure 13 is a partial top plan view of the frame shown in Figures ll and 12 ;; - Figure 14 is a top plan view showing a secondary core of the frame shown in Figures 11 to 13; - Figure 15 is a front elevational view of the secondary core shown in Figure 14; - Figure 16 is a cross-sectional view taken along line XV-XV of Figure 15; - Figure 17 is a side sectional view showing a frame in a magneto-generator according to another embodiment of the invention; - Figure 18 is a front elevational view of the frame shown in Figure 17; and - Figure 19 is a partial top plan view of the frame shown in Figures 17 and 18.

Referring first to Figures 1 to 3, we see a frame in a magneto-generator according to one embodiment of the invention. The armature comprises a core body 1 having a multiplicity, eight in the present embodiment, of poles A1 to AS arranged so as to extend radially, being spaced apart from each other by the same distance, and an exciting coil 2 mounted on a predetermined pole, namely the pole Al. Load coils (not shown) are wound respectively around the other poles A2 to A8.

The core body 1 is formed so that a multiplicity of laminated plates 3, each having the planar shape shown in Figure 4 and being made of a magnetizable material such as iron or the like, are applied against each other. 'other. The core body 1 has at its center a bore 4. The laminated plates 3 of the core body 1 are fixed together by a multiplicity of rivets 6, which pass respectively through through holes 5 formed on either side of the bore 4 being at substantially the same distance therefrom. Therefore, the laminated plates 3 are secured to each other.

Several pole pieces are formed respectively on the poles A2 to A8. However, no pole piece is formed at the front end of the pole Al of the excitation coil 2. In other words, the front end of the pole
Al has an open structure. Several through holes 7, each serving as a resinous filling section, are arranged side by side, adjacent to the base end of the pole Al of the core body 1 of the excitation coil 2. The through holes 7 are formed through the body of core 1 in the direction of its thickness, that is to say in its axial direction.

An exciter coil unit 8, produced as shown in FIGS. 5 to 7, is mounted around the pole Al. Referring also to FIG. 3, a secondary core or pole piece 16 is mounted on the front end of the pole
A1. The exciter coil unit 8 comprises a coil support 9 which is formed in one piece of resin. As seen in Figures 1 and 5 to 7, the coil holder 9 has a coil winding section 9a, which has a tubular shape of rectangular cross section and which can be mounted around the pole Al. Two cheeks 9b and 9c of the coil holder 9 have a rectangular planar shape larger than the winding section 9a. The outer cheek 9b of the coil holder 9 has an outer surface in which a cooperation groove 10 is formed with the secondary core, as seen in FIGS. 3 and 5. The cooperation groove 10 has a constant width and a depth constant and extends axially relative to the core body 1. A boss 11 projects from the surface of the bottom of the cooperation groove 10. As can be seen in FIGS. 2 and 6, two terminal tongues 12.1? are arranged on both sides of the coil support 9 and are introduced longitudinally into the inner cheek 9c of the coil support 9.

As seen in Figures 1 and 7, a double-sided adhesive tape 13a is wound around the winding section 9a of the coil holder 9 and, then, a thin metal wire 14 of excitation coil is wound a large number of times around the double-sided adhesive tape 13a. Next, a glass cloth tape 15 is wrapped around the outer periphery of the wound wire 14 via a double-sided adhesive tape 13b. The coil wire 14 has two ends 14a and 14b which are electrically connected respectively to the two terminal tabs 12, 12r by soldering, as seen in FIG. 6.

As seen in Figures 8 to 10, the secondary core 16 has the shape of a thin plate or a laminated plate, practically rectangular and slightly curved. Three cooperation parts 17 are provided on each of the long sides of the secondary core 16. The three cooperation parts 17 are respectively arranged in the center and at the two ends of each large side and are projected towards the outside. A single cooperation piece 18 is also provided on each of the two short sides of the secondary core 16. This cooperation piece 18 is arranged in the center of each short side and projects outwards. An insertion hole 19 is formed in the center of the secondary core 16 and passes through the thickness of the latter. The insertion hole 19 has a rectangular shape, which is practically the same as that of the hollow portion of the winding section 9a of the coil holder 9.

As can be seen in FIG. 3, the secondary core 16 is mounted on the front end of the coil support 9 manufactured as described above, so that the groups of right and left cooperating parts 17,17 are housed in the cooperation grooves 10 formed in the outer cheek 9b of the coil support 9. When the secondary core 16 is fully housed in the cooperation grooves 10 of the coil support 9, the cooperation part 18 is brought into cooperation with the boss ll on the coil support 9. Thus, the secondary core 16 is mounted on the coil support 9 so that it cannot be released =
As seen in Figures 1 to 3 and 5 to 7, the coil support 9, on the front end of which is mounted the secondary core 16, is itself mounted on the pole Al for the exciting coil 2, such that the hollow portion of the winding section 9a is mounted around the pole
Al, by its open end. In this mounting state, the secondary core 16 is magnetically connected to the pole
Al.

In this state, a resinous frame 20 is molded in resin by an insert molding apparatus (not shown) around the periphery of the exciting coil unit 8 which is mounted on the pole Al for the exciting coil 2 in the core body 1. In other words, the resinous surround 20 is molded in resin around the periphery of the exciting coil unit 8 together with the resinous coil supports 22 which are formed on the other poles
A2 to A8 of the core body 1. Specifically, as seen in FIGS. 1 to 3, most of the exciter coil unit 8, except part of the secondary core 16 and parts of the tabs of terminal 12,12, is coated by the resinous environment 20. The molding of the resinous environment 20 practically ends the excitation coil 2.

On the other hand, as seen in Figures 1 to 3, the coil supports 22 molded in resin at the same time as the resinous surround 20, are formed on the other poles
A2 to A8 of the core body 1, such that the coil supports 22 extend respectively from the seven side wall surfaces of the core body 1 to the pole pieces of the respective poles A2 and A8 to cover the surfaces of the side wall and pole pieces of a layer of constant thickness. Since the resinous coil supports 22 are linked in unitary form to the resinous surrounding, the excitation coil 2 is linked to the core body 1 so as to form a unitary assembly.

In addition, the molding resin of the resinous environment 20 and the coil supports 22 is solidified so that the molding resin penetrates into the small gaps existing between the coil support 9 and the pole Al of the excitation coil 2 , between the coil holder 9 and the secondary core 16, etc. Consequently, the coil support 9, the secondary core 16 and the pole Al are linked to each other without what is commonly called a set so as to form a unitary assembly.

Furthermore, the aforementioned insert molding apparatus has a mold (not shown) which is formed such that when the resinous surround 20 is molded in resin together with the coil holders 22, part of the molding resin fills the multiplicity of through holes 7 formed adjacent to the pole Al of the core body 1. The resinous solid sections 21, which are formed by filling these through holes 7, are linked in a unitary manner to the resinous entourage 20. Thus, the excitation coil 2 is linked to the core body 1 by forming a unitary assembly.

According to the embodiment, the connection of the coil support 9 of the excitation coil unit 8 to the pole Al of the excitation coil 2 and the connection of the secondary core 16 to the coil support 9 are carried out by connection and filling of the molding resin . Thus, no force mounting operation or the like is necessary. As a result, the complicated dimensional control required for the press fit operation, etc. can be omitted. Alternatively, the severity of the dimensional control requirements can be alleviated.

In addition, since the pole A1 of the exciting coil unit 8 comprises the secondary core or pole piece 16, it is possible to increase the polar curved angle of the magnetic pole of the exciting coil 8. Thus, the ignition characteristics of the ignition device for an internal combustion engine can be improved.

Reference is now made to FIGS. 11 to 16, in which an armature is seen in a magneto-generator according to another embodiment of the invention. In this embodiment, the secondary core 16 cooperates with cooperation recesses made at the front end of the pole
A1 of the core body 1, and the exciter coil unit 8 and the core body 1 are molded of resin with the lateral core 16 forming a unitary assembly.

Specifically, as can be seen in FIGS. 14 to 16, the secondary core 16 has the shape of a thin plate or of a practically rectangular laminate. Two cooperation pieces 17,17 are provided on each of the two long sides of the secondary core 16. The cooperation pieces 17,17 are arranged respectively at the two ends of each long side and project outwards.

On the other hand, a single cooperation piece 18 is provided on one of the two short sides of the secondary core 16. This cooperation piece 18 is located in the center of the short side and projects outwards. In addition, an insertion opening 19 is formed on a center line on the other short side of the secondary core 16 and extends longitudinally. One end of the insertion opening 19 is open on the other short side of the secondary core 16. The other end of the insertion opening 19 is closed adjacent to the first short side of the secondary core 16. The opening insertion 19 has a width practically equal to that of the pole Al of the excitation coil 2. The insertion opening 19 has its two interior lateral surfaces comprising two cooperation parts 19a, 19a projecting towards the interior .The two cooperation parts 19a, 19a are formed so as to be able to be accommodated respectively in two cooperation recesses la, la which are formed in the pole
A1, as seen in Figures 11 to 13.

The coil holder 9, around which the coil wire 14 is wound, is mounted on the pole Al of the core body 1 of the exciting coil 2, so that the winding section 9a of the coil holder 9a a hollow portion housed around the pole Al from its open end.

The secondary core 16 is mounted on the front end of the coil support 9 mounted on the pole Al, so that the groups of right and left cooperating parts 17,17 are respectively housed in the cooperating grooves 10 which are formed on the outer cheek 9b of the coil support 9. Simultaneously, the front end of the pole A is housed in the insertion opening 19 of the secondary core 16, and the engagement parts 19a, 19a provided in the insertion opening 19 and going beyond, are housed respectively in the cooperation recesses la, la. When the secondary core 16 is fully inserted into the cooperation grooves 10 of the coil support 9, the cooperation part 18 of the secondary core 16 comes to cooperate with the boss 11 of the coil support 9. Thus, the secondary core 16 is mounted on the coil holder 9 and on the pole Al and is prevented from leaving it. In this state, the secondary core 16 is in contact with or near the pole Al, so that the secondary core 16 is magnetically connected to the pole Al.

The resinous surround 20 is molded in resin, by an apparatus for molding inserts (not shown) around the exciter coil unit 8 of the core body 1 in which the exciter coil unit 8 is mounted on the pole. A1 of the excitation coil 2. In other words, as seen in FIGS. 11 to 13, most of the excitation coil unit 8, except a part of the secondary core 16 and parts of the terminal tongues 12, 12, is coated with the resinous environment 20. The molding of the resinous environment 20 practically ends the excitation coil 2.

When the resinous environment 20 is molded in resin, part of the resinous molding material penetrates into fine gaps existing between the coil support 9 and the pole Al of the excitation coil 2, between the coil support 9 and the secondary core 16, etc., to be solidified there. Consequently, the coil support 9, the secondary core 16 and the pole Al are linked to each other, without what is commonly called a set, forming a unitary assembly.

Furthermore, the aforementioned insert molding apparatus has a mold (not shown) which is formed such that when the resinous surround 20 is molded in resin, part of the resinous molding material fills the multiplicity of holes through 7 which are formed adjacent to the pole
A1 of the core body 1. The resinous solid sections 21, which are formed by filling the through holes 7, are linked to the resinous environment 20 in one unit. Thus, the exciting coil 2 is linked to the core body 1 so as to form a unitary assembly.

Also according to the embodiment, the connection of the coil support 9 of the excitation coil unit 8 to the pole Al of the excitation coil 2 and the connection of the secondary core 16 to the coil support 9 are all obtained by bonding and filling the resin. molding. Thus, no forced mounting operation, etc., is required. As a result, the complicated dimensional check required for forced mounting, etc. can be omitted. Alternatively, the severity of the dimensional control can be alleviated
In addition, since the pole A1 of the exciter coil unit 8 is equipped with the secondary core or pole piece 16, it is possible to increase the polar curved angle of the magnetic pole of the exciter coil unit 8. Thus, the Ignition characteristics of an ignition device for an internal combustion engine can be improved.

Referring now to Figures 17 to 19 in which cn shows a frame of a magneto-generator according to another embodiment of the invention. Unlike the previous embodiment illustrated in FIGS. 1 to 10, the resinous surround 20 is not molded in resin at the same time as the coil supports 22.

In the embodiment shown in Figures 17 to 19, an insert molding apparatus has a mold, (not shown), which is formed such that, when the resinous surround 20 is molded in resin, part of the molding resin fills the multiplicity of through holes 7 which are formed adjacent to the pole Al of the core body 1. The resinous solid sections 21, are formed there by the filling of the through holes 7, are linked to the resinous surrounding 20 by forming a unitary whole. Thus, the exciting coil 2 and the core body 1 form only one unit.

In addition, the resin for molding the resinous environment 20 is solidified so that this resin for molding penetrates into the small gaps existing between the coil support 9 and the pole Al of the excitation coil 2, between the coil support. 9 and the secondary core 16, etc. Consequently, the coil support 9, the secondary core 16 and the pole Al are joined together so as to form a unitary assembly.

Also according to the embodiment, the connection of the coil support 9 of the excitation coil unit 8 to the pole Al of the excitation coil 2 and the connection of the secondary core 16 to the coil support 9 are made by bonding and filling the resin with molding. Thus, no forced mounting operation, etc., is necessary. As a result, the complicated dimensional check required for forced mounting, etc. can be omitted. Alternatively, the severity of the dimensional control can be alleviated.

In addition, since the pole A1 of the exciting coil unit 8 is provided with the secondary core or pole piece 16, it is possible to increase the polar curved angle of the magnetic pole of the exciting coil unit 8. Thus, the ignition characteristics of the ignition device for an internal combustion engine can be improved.

In connection with what has just been said, the invention should not be limited to the embodiments indicated, but it is needless to say that various modifications and variants can be made without departing from the scope of the invention .

For example, it is unnecessary to form on all the other poles of the core body the resinous coil supports to connect the exciter coil unit to the core body so as to form a unit. In fact, one or more other poles can be provided with the resinous coil support.

The insertion holes serving as resinous filling sections, which practically form the resinous solid sections for connecting the exciter coil unit to the core body so as to form a unit, are integrally formed together with the resinous surrounding which covers the outer periphery of the spool holder. Consequently, the number of through holes and their configuration can be appropriately fixed according to these conditions.

Furthermore, the formation of resinous filling sections is not limited to the use of through holes.

Specifically, the arrangement can be such that recesses having an optional depth in the thickness direction are formed in the core body from its two sides and the resin fills these recesses. In other words, it is unnecessary for the recesses serving as resinous filling sections to extend perfectly through the core body in the thickness direction, but the recesses may have their bottom halfway in the direction of the thickness. Also in this case, the filling of the recesses with the resin ensures the connection between the exciter coil unit and the core body.

In the embodiments described above, an example is illustrated having eight poles. However, the invention can be applied to an armature having any number of poles. In addition, one can appropriately select the configuration and structure of the core, poles and supports, and choose the thickness, number of turns, etc., of the wire from the coil, depending on the conditions required for the generator.

As described above, according to the invention, the resinous coil supports formed on the core body and the resinous surround of the coil unit mounted on the pole of the core body are linked to each other by molding of resin by forming a unitary whole. So what is known as a game does not happen. In addition, the operation of fixing the coil unit with respect to the core body is carried out at the same time as the molding of the resinous surround of the coil unit. As a result, operational performance is high. In addition1 because the mounting of the coil support in the core body is not carried out by force, it is possible to reduce the severity of the dimensional control for the mounting by force.

Claims (12)

Claims I.- Armature in a generator, characterized in that it comprises - a core body (1) having a multiplicity of poles (A1-A8); - a coil unit (8) mounted on a first pole (A1) of this multiplicity of poles of the core body; - a resinous frame (20) for covering an outer periphery of this coil unit mounted on the first pole; and - coil supports (22) formed on the other poles, and in that the resinous surround (20) is molded in resin at the same time as the coil supports (9,22) so as to connect them together, whereby the coil unit (8) is linked to the core body (1) so as to form a unitary assembly. 2. Armature according to claim 1, characterized in that the first pole (Al), on which is mounted the coil unit (8), has at least one resinous filling section for connecting the coil unit to the body of core so as to form a unitary whole. 3. Armature according to claim 1, characterized in that the exciter coil unit (8) is mounted around the first pole (AI), this exciter coil unit having a coil support (9) which is molded in resin. so as to constitute a unitary whole. 4. A frame according to claim 3, characterized in that it further comprises a secondary core (16) mounted on the front end of the first pole (Al), this secondary core having a substantially rectangular laminated shape and slightly curved, at least a first cooperation part (17) being provided on each long side of this secondary core so as to project outwards, and at least a second cooperation part (18) being provided on each short side of this core secondary so as to project outwards. 5. A frame according to claim 3, characterized in that the secondary core (16) has, in its center, an insertion hole (19) which extends in the direction of the thickness of the secondary core, and in that the coil holder (9) of the exciter coil unit (8) has a winding section (9a) which has a hollow portion, the insertion hole having a rectangular shape which is practically the same as that of the hollow portion of the winding section. 6.- Armature in a generator, characterized in that it comprises - a core body (1) having a multiplicity of poles (A1-A8); - a coil unit (8) secured to a specific pole (Al) of this multiplicity of poles of the core body; - At least one cooperation recess (la) formed at the front end of this specific pole, this coil unit being mounted around this specific pole; - a secondary core (16) mounted on this specific pole (Al) so as to cooperate with the cooperation recess (la); and - a resinous surround (20) to cover the outer periphery of this coil unit (8) mounted on this specific pole (Al), the resinous surround being formed on the outer periphery of the coil unit so as to constitute a unitary assembly with the core body. 7. Armature according to claim 6, characterized in that the secondary core (16) has a practically rectangular laminated shape, this secondary core having two large sides on each of which is provided at least one cooperation part (17) projecting towards outside, and in that a single second cooperation piece (18) is provided in the center of one of the two short sides of this secondary core, and projects towards the outside.  8. A frame according to claim 6, characterized in that the secondary core (16) has an insertion opening (19) which extends longitudinally in this secondary core, the insertion opening opening in the one of the two short sides of the secondary core and being closed at the other short side of the secondary core. 9. Armature according to claim 8, characterized in that the width of the insertion opening is the same as that of the specific pole (Al), in that the armature further comprises two cooperation parts (19a) which are provided respectively on two interior surfaces of the insertion opening (19) projecting inwardly, and in that these two cooperation parts are housed in the cooperation recess (la) of this specific pole so that the two cooperation parts (19a) can cooperate with the cooperation recess (la). 10.- Armature in a generator, characterized in that it comprises - a core body (1) having a multiplicity of poles (A1-A8); - a coil unit (8) secured to a specific pole (Al) of the multiplicity of poles of this core body; - a multiplicity of resinous filling sections formed in the core body at a location adjacent to this specific pole (Al) on which the coil unit (8) is mounted; and - a resinous surround (20) for covering the outer periphery of the coil unit mounted on the specific pole, and in that the resinous surround (20) has its resin filling the resinous filling sections to respectively form a multiplicity resinous solid sections (21), whereby the coil unit (8) is linked to the core body (1) so as to constitute a unitary assembly. 11. Armature according to claim 10, characterized in that the coil unit (8) has its coil support (9) which is linked to the specific pole (Al) by this resin, and in that the armature comprises furthermore a secondary core (16) which is linked to the coil support by this resin. 12.- Armature in a generator, characterized in that it comprises - a core body (1) having a multiplicity of poles (A1-A8); - a coil unit (8) mounted on a specific pole (A1) of this multiplicity of poles of the core body; - a resinous frame (20) to cover the outer periphery of the coil unit mounted on this specific pole; - coil supports (22) formed on the other poles; in that 1 t resinous frame (20) is molded in resin at the same time as the coil supports (9,22) so as to connect them together, from which it follows that the coil unit (8) is linked to the core body (1) so as to form a unitary assembly; in that at least one cooperation recess (la) is formed at the front end of this specific pole and that a secondary core (16) is mounted on this specific pole so as to cooperate with this cooperation recess; and in that at least one resinous filling section is formed in the core body at a location adjacent to this specific pole on which the coil unit is mounted, whereby the resinous environment (20) has its resin which fills the resinous filling section to form at least one resinous solid section (21), the coil unit (8) being thus linked to the core body (1) so as to constitute a unitary assembly.