JPS63290141A - Oscillatory type axial air-gap type motor - Google Patents

Abstract

PURPOSE:To form a small and low-priced oscillatory type axial air-gap type motor by eliminating at least one coil of a coreless flat armature so that said coreless flat armature does not form a disc. CONSTITUTION:Motor casings 6, 7 serving also as stator yokes are fitted with bearings 8, 9, by which the rotating shaft 2' of a coreless flat armature 21 constituting a rotor is supported. Said coreless flat rotor 21 lacks one of three armatures which it usually has, two air-core type armature coils 12-1 and 12-2 are arranged at a pitch of 120 deg. to form said rotor 21, and a part for one armature is wanting so that said rotor forms no disc. When a motor formed in this manner is rotated, the coreless flat armature 21 is eccentric and oscillates while revolving. Therefore, an oscillatory sound can be generated and a thickness can be thinned, even if any particular revolving plate is not provided.

Description

[Detailed Description of the Invention] [Industrial Application Field of the Invention] The present invention is a signal receiver for blind people, which has the purpose of transmitting a predetermined signal, and can apply a light vibrator to the human body, etc., and has a pine surge effect or a light It is built into a pine surge device that requires vibration, or a pager, etc., and when driven, it gives vibration to the above-mentioned keratobell, etc., and by applying the vibration to the human body, etc., the pager, etc. is activated. Regarding vibrating axial gap type (DC) motors that can generate vibrations, such as devices that can be used for the purpose of informing customers of the It is more useful for use in electric motors configured in a phase structure.

[Prior art and its problems] Various devices are known for the purpose of transmitting vibrations to the human body, such as pine surge machines and signal receivers for blind people.

The vibrating axial gap type electric motor of the present invention is useful for the above-mentioned bag π, but for example, in the case of a bokketobell, the conventional one has the following drawbacks.

In today's information society, pagers are frequently used by businessmen, and the number of units sold is increasing.

Here, pagers are loud no matter where they are: they emit a single sound and the sound disturbs the people around them, or the sound has a negative impact on the mental health of the person who owns the pager. It has come to the point where it is given.

Under these circumstances, attempts have recently been made to make it possible to notify the pager of a telephone call by causing the pager to vibrate instead of making a sound.

Although various methods can be considered as means for causing a pager to vibrate, an inexpensive small direct current motor is considered to be a promising method for imparting vibration to a small pager. In particular, DC motors are inexpensive, compact, yet highly efficient, and suitable for high-speed rotation.

Here, as a conventional axial gap type electric motor 4 used in a pager 5, etc., 1 is shown, for example, in FIGS.
As shown in the figure, a rotating shaft 2 of a flat axial gap type electric motor 1
It has a structure in which a rotating plate 3 is attached to the swivel plate 3.

In this way, a rotating plate 3 is attached to the rotating shaft 2 of the axial gap type electric motor 1.
A vibrating axial gap type electric motor 4 configured by attaching the same is built into the pager 5, and when the pager 5 is driven, the pager 5 vibrates.

FIG. 12 is a longitudinal sectional view of the axial gap type electric motor 1 used in the vibration type axial gap type electric motor 4 which is flat in the axial direction.
is a motor casing made of magnetic material, and the motor casing 6.7 also serves as a stator yoke.

A bearing 8.9 is mounted at the center of the motor casing 6.7, and the rotating shaft 2 of a coreless flat armature 10 constituting a rotor is rotatably supported by the bearings 8, 9.

The coreless flat armature 10 has, for example, three air-core armature coils 12-1, 12- as shown in FIG.
2.12-3 are integrally formed into a disk shape by molding the outer periphery with plastic 23 so as not to overlap each other at equal intervals of 120 degrees.

Armature coil 12-1. ..., 12-3 is.

The effective conductor portions 12 a + 12 a ′ in the radial direction contribute to the generated torque, and the conductor portions 12 b and 12 c in the circumferential direction do not contribute to the generated torque.

Moreover, each armature coil 12-1. . . , 12-3 is the effective conductor portion 1 in order to form the electric motor 1 with good efficiency.
The opening angle between 2a and 12a° is formed into a fan frame shape with a width equal to the width of the - magnetic pole of the field magnet 14 (41F+) shown in Fig. 15, that is, 90 degrees. are doing.

On the lower surface of the coreless flat armature 10, a commutator piece 11-1 is arranged concentrically with the one-rotation shaft 2. . . , a commutator 11 consisting of 11-6 groups is provided. The commutator 11 will be described later.

As shown in FIG. 14, a printed distribution board 13 is disposed concentrically with the commutator 11 on the lower surface of the coreless flat armature 10, and is connected to the armature coils 12-1°..., 12-3 for commutation. The terminals 11 are electrically connected via a printed circuit board 13 as shown in FIGS. 17 to 20. In the case of Figures 17 and 18, the Y-type connection is used, and the
In the case of FIG. 20 and FIG. 20, the connection is Δ.

On the surface of the motor housing 7 that faces the coreless flat armature 10 through the axial gap 37, there is a flat circle having N poles and S poles alternately at an opening angle of 90 degrees, as shown in FIG. An annular field magnet (field magnet) 14 is fixed.

Two brushes 16 and 17 supported by an annular brush holder 15 made of plastic are in sliding contact with the inner surface of the field magnet 14 at an opening angle of 90 degrees, as shown in FIG.

The coreless flat armature 10 is shown in FIGS. 13, 14, and 1.
As is clear from FIGS. 7 to 20, three armature coils 12-1. . . , 12-3 are arranged at a pitch of 120 degrees, and a field magnet 14 having a flat annular shape of four magnets as shown in FIG. 15 and an axial gap 37 as shown in FIG. They are facing each other through. The field magnet 14 is.

As is clear from Fig. 15, with an opening angle width of 90 degrees, the N pole,
The magnetic poles of the S pole are alternately magnetized into four poles.

FIG. 17 shows the coreless armature coil 12-1 in the case of Y-type connection with the field magnet 14. ..., 12
-3, and Figure 18 shows the three armature coils 1.
2-1. ..., 12-3 group and 6 commutator pieces 11
-1. . . , is a wiring diagram when the commutator 11 consisting of the 11-6 group is connected in a Y type, and FIG. 19 shows the coreless flat armature 1 when connected with the field magnet 14 in a delta connection
0 and FIG. 20 shows three armature coils 1.
2-1,..., 12-3 and six commutator pieces 11-1,
. . , shows a connection diagram when the commutator 11 consisting of 11-6 is connected in a Δ configuration.

With reference to FIGS. 17 and 18, armature coil 12-
1. . . . , 12-3 connects the terminals of each one of the effective conductor portions 12a to the commutator pieces 11-1.11-3.11.
-5, the other terminals are connected in common, commutator pieces 11-1 and 11-4, 11-2 and 11-5 are connected to 1
1-3 and 11-6 are electrically connected.

Referring to FIG. 17, brushes 16 and 17 and armature coil 12-1. ..., 12-3 is the commutator piece 11-
1. . . , 11-6 are formed at equal intervals with a pitch of 60 degrees, so that the armature coils 12-1.・
..., the two brushes 16 and 17 are connected to 12-3 so that current can be passed in the forward and reverse directions by 180 electrical degrees.
are shifted by 180 electrical degrees (90 mechanical degrees) and brought into sliding contact.

The brushes 16 and 17 are connected to the positive power terminals 18 and 17 of a drive circuit (not shown), respectively. It is connected to the negative side power supply terminal 19.

19 and 20 show the Δ connection, and the armature coils 12-1. . . , the terminals of one of the effective conductor portions 12b of 12-3 are connected to the commutator pieces 11-1.11, respectively.
-3.11-5, and the other terminal is connected to commutator pieces 11-2.11-4.11-6, respectively.

Further, the other effective conductor portion 12b of the armature coil 12-1 and one effective conductor portion 12a of the armature coil 12-3 are electrically connected, and the one effective conductor portion 12a of the armature coil 12-2 and The other effective conductor portion 1 of the armature coil 12-3
2b, and one effective conductor portion 12a of the armature coil 12-1 and the other effective conductor portion 12b of the armature coil 12-2 are electrically connected.

Therefore, armature coil 12-1. . . , 12-3, when the commutator 11 rotates while sliding in contact with the brushes 16, 17, the armature coils 12-2, . A current can be passed in the direction of the arrow through 12-3, and a rotational torque of the magnitude of symbol f can be obtained.
In the direction of arrow F, armature coil 12-1. ..., 12
- The coreless flat armature 10 consisting of three groups is rotated.

Therefore, if you are wearing a pager 5 having such a vibrating axial gap type electric motor 4.

The pager 5 vibrates, and from the vibration of the pager 5, it is possible to know that there is a telephone call.

The axial gap type electric motor 1 used in the pager 5 is certainly useful, but if you simply attach the rotating plate 3 and use it for the pager 5, it will be difficult to use it.
Since the rotating plate 3 must be attached to the rotating shaft 2, it is not suitable for mass production and has the drawback of making the pager 5 expensive.In addition, since the rotating plate 3 is provided, the electric motor 1 becomes longer in the axial direction. This poses an obstacle to further miniaturization and cost reduction of the pager 5.

[Problems to be solved by the invention] The present invention has been made in order to eliminate the drawbacks of the conventional art, and is a vibrating axial gap type electric motor suitable for vibrating pagers, etc., which is inexpensive and axially directionless, without attaching a rotating plate to the rotating shaft. This was done with the aim of making it thinner, smaller, and lighter.

[Means for achieving the object of the invention] The object of the invention is to provide a flat field magnet having a plurality of alternating N and S magnetic poles as a stator, and to face the field magnet through an axial gap. In an axial gap type electric motor equipped with a coreless flat armature formed in a disk shape having rotatably supported coreless armature coil groups at equal intervals, when the coreless flat armature rotates, Deforming the coreless flat armature so that it does not form a disk shape in a plane by deleting one or more armature coils at a predetermined location of the coreless flat armature so that the coreless flat armature rotates eccentrically and vibrating. This can be achieved by forming a vibrating axial gap type motor at a predetermined location of the coreless flat armature within the frame cavity of the armature coil.

Other purposes will be made clear in the explanation below.

[First Embodiment of the Invention] A vibrating axial gap type electric motor as a first embodiment of the present invention will be described with reference to FIGS. 1 to 6.

Figure 1 shows a vibration type axial gap type electric motor 2 that is flat in the axial direction.
0, the same members as in FIG. 12 are designated by the same reference numerals, and their explanations will be omitted. FIG. 2 is an exploded perspective view of a vibrating axial gap electric motor 20 that embodies the one shown in FIG. The main difference between the vibrating axial gap type electric motor 4 of FIGS.
This is because the electric motor 20 having this structure does not require the rotation plate 3.

Since the rotating shaft 2' does not need to protrude above the motor 20, it is possible to form a vibrating axial gap type (DC) motor 20 that is shorter in the axial direction, and the armature coil 12-
3 and the plastic molded part of the armature coil 12-3 is also deleted, and the coreless flat armature 21 itself is deformed and formed into an eccentric shape so that it does not form a disk shape in a plane. Coreless flat armature 2
1 is lighter and a permanent magnet 24 is provided on the coreless flat armature 21, and there is a difference in the appearance of the field magnet 14 and attraction. Others will be explained in detail below.

In this electric motor 20, a coreless flat armature 21 is rotatably supported by bearings 8 and 9, but this coreless flat armature 21 is different from the coreless flat armature 10 described above mainly because the coreless flat armature Delete one piece of armature coil 12-3 of child 10 as it is, and create armature coil 1.
The part where 2-3 was located is cut out (armature coil 12
-3 is made of molded plastic 23), and the rotating shaft 2° does not need to protrude above the electric motor 20, so the length is shorter than the rotating shaft 2 of 9. .

In addition, in order to increase vibration efficiency, plastic 2 with a light specific gravity is used.
Armature coils 12-1 and 1 molded by 3 etc.
2-2, a permanent magnet 24 whose surface facing the field magnet 14 is magnetized to the north pole (or may be the south pole) is provided in the cavity within the frame of the armature coil 12-1. There is.

When disposing this permanent magnet 24 in the coreless flat armature 21, it is preferable to integrate it at the same time when the armature coil 12-1, 12-2 is molded into a flat plate shape with the plastic 23.

Here, the plastic 23 is attached to the armature coils 12-1.
It is preferable to select a material having a specific gravity lighter than that of the permanent magnet 12-2, and it is necessary to select a permanent magnet 24 having an appropriate magnetic force in relation to the field magnet 14. The reason for this is that if a permanent magnet 24 with too weak magnetic force is used, it will be magnetized by the magnetic force of the field magnet 14 and a desirable result will not be obtained.

In FIG. 2, reference numerals 25 and 26 indicate the positive power terminals 18 and 26, respectively. A lead wire connected to the negative power terminal 19 is shown.

According to the vibrating axial gap type electric motor 20 having the coreless flat armature 21 formed in this manner.

Since the armature coil 12-1.12-2 is made of steel, it functions as an eccentric weight, and the permanent magnet 24 also functions as an eccentric weight, so when the electric motor 20 is driven, the coreless flat armature 21 (It rotates while centering, but in this case, the attraction between the permanent magnet 24 and the field magnet 14
Compared to the case where the permanent magnet 24 is not used to generate a repulsive force.

Since large vibrations are generated in the axial direction and rotational direction, the bogette bell 5 incorporating the electric motor 20 will vibrate greatly.

In this electric motor 20, like the electric motor 1 described above, six commutator pieces 11-1. There is a commutator 11 consisting of ..., 11-6 and two brushes 16, 17, and the brush 16
．． The arrangement of the commutator 17 is the same as in the case of the electric motor 1, but the commutator 11 is electrically connected as shown in FIGS. 3 to 6.

3 and 4 show the case of Δ connection, one effective conductor portion 12a of the armature coil 12-1.12-2 is connected to the commutator piece 11-1.11-3, respectively, The other effective conductor portion 12b includes commutator pieces 11-2, 11-, respectively.
Connected to 4.

Commutator pieces 11-3 and 11-6, 11-4 and 11-1, and 11-5 and 11-2 are electrically connected.

In this way, in the case of Δ connection, armature coil 12-3
It is sufficient to use almost the same electrical connection method as the conventional one (in the case of Figures 19 and 20) by simply omitting the , but in the case of a Y-type connection, the method shown in Figures 5 and 6 is not enough. It is necessary to devise such a method.

The Y-type connection in that case will be explained below.

5 and 6 show the case of Y-type connection.

Commutator piece 11-1. ..., the correspondence relationship between the commutator 11 consisting of the 11-6 group and the brushes 16, 1.7.

Same as the above embodiment, but armature coil 12-1.1
2-2 is electrically connected as follows.

One effective conductor portion 1 of armature coil 12-1.12-2
2a are commutator pieces 11--1, respectively.

11-3. Also, armature coil 12-1
The other effective conductor portions 12b of and 12-2 are commonly connected to each other.

Commutator pieces 11-1 and 11-4, 11-2 and 11-5, and 11-3 and 11-6 are electrically connected.

A connection point 36 between the other effective conductor portions 12b of the armature coils 11-1 and 11-2 is connected to the commutator piece 11-2 for short-circuiting.

This electrical short circuit is caused by the above Δ
This is different from the case of wiring.

This is because if this short circuit does not occur, there will be a point in the Y-type connection where one rotation torque will not be generated, and smooth rotation will not be possible.

[Second Embodiment of the Invention] FIG. 7 shows that in the coreless flat armature 21 shown in FIG. A coreless flat magnet 28 is embedded between the armature coils 12-1 and 12-2, and a permanent magnet 28 with the NfM magnetic pole facing the field magnet 14 side, similar to the permanent magnet 24 described above. 2 shows an exploded perspective view of two vibrating axial gap motors with armatures 30; FIG.

In the two electric motors of this embodiment, if a permanent magnet similar to the permanent magnet 24 is used as the weight instead of the weight 27, these two
The above arrangement is desirable because the two permanent magnets attract each other with the field magnet 14 and stop at that position.

[Third Embodiment of the Invention] FIG. 8 shows a coreless flat armature 3 according to a third embodiment of the present invention.
1 shows a bottom perspective view of the coreless flat armature 30 shown in FIG. A metal weight 38 for eccentricity is embedded therein.

According to this coreless flat armature 31, a result with better vibration efficiency than the coreless flat armature 21.30 is obtained.

[Fourth Embodiment of the Invention] FIG. 9 shows a coreless flat armature 32 according to a fourth embodiment of the invention.
This coreless flat armature 32 is shown in a bottom perspective view.
When molding the armature coils 12-1 and 12-2, an eccentric metal weight 40 is also molded with a plastic magnet 39 to form a flat plate, and buried in the cavity within the frame of the armature coil 12-1. integrated, armature coil 12
A plastic magnet 39 between -1 and 12-2 is magnetized with an N pole to form a permanent magnet 41 having the same function as the permanent magnet 28.

[Effects of the Invention] The present invention can effectively function for blind person signal transmission, pie break, pager, etc. by only slightly improving the conventionally known axial gap type electric motor, and moreover, Compared to the vibrating axial gap type electric motor used in pagers, this has the advantage of being thinner in the axial direction. Therefore, if adopted in the above device, there is an advantage that the device can be manufactured in a small size and at low cost.

[Brief explanation of drawings]

Fig. 1 is a vertical cross-sectional view of a vibrating axial gap type electric motor according to the first embodiment of the present invention, Fig. 2 is an exploded bottom perspective view of the same, and Figs. 3 and 4 show armature coil groups connected in a delta manner. FIG. 5 and FIG. 6 are explanatory diagrams for the case where the armature coil group is connected in a Y-shape. FIG. 7 is a bottom exploded perspective view of the second embodiment, and FIG.
The figure is a bottom perspective view of a coreless flat armature showing the third embodiment, FIG. 9 is a bottom perspective view of a coreless flat armature showing the fourth embodiment, and FIG. 10 is a conventional vibrating axial gap type. An explanatory diagram of a pager using an electric motor, Fig. 11 is an explanatory diagram of a vibrating axial gap type electric motor using a rotating plate, Fig. 12 is a vertical cross-sectional view of a coaxial gap type electric motor, and Fig. 13 is a coaxial FIG. 14 is a top perspective view of a coreless flat armature of a directional gap type electric motor, FIG. 14 is a bottom view of the same coreless flat armature, FIG. Fig. 16 is an explanatory diagram of the relationship between the commutator and brushes, Figs. 17 and 18 are explanatory diagrams when the armature coil group and commutator segment group are connected in a delta manner, and Figs. 19 and 20 are illustrations of the armature It is an explanatory view when a coil group and a commutator piece group are connected in a Y shape. [Explanation of symbols] 1... Axial gap type electric motor, 2.2''... Rotating shaft, 3... Swivel plate, 4... Vibration type axial gap type electric motor, 5... Pager 6.7...Motor casing, 8.9...Bearing, 1
0.10'...Coreless flat armature. 11... Commutator. 11-1. ..., 11-6... Commutator piece. 12-1. ..., 12-3... armature coil,
12a, 12a'...effective conductor portions. 12b, 12c...conductor portions that do not contribute to generated torque,
13... Printed distribution board, 14... Field magnet, 15... Brush holder. 16.17...Brush, 18...Positive power terminal, 1
9...Negative side power supply terminal, 20...Vibrating axial gap type motor, 21...Coreless flat armature, 23...Plastic, 24...Permanent magnet, 25.26...Lead Wire, 27... Eccentric metal weight, 28... Permanent magnet, 29... Coreless flat armature, 30... Vibration type axial gap type electric motor, 31. ..., 32... Coreless flat armature, 36... Connection point, 37... Air gap. 38... Metal weight for eccentricity, 39... Plastic magnet, 40... Metal weight for eccentricity. 41...Permanent magnet.

Claims (10)

[Claims] (1) A coreless electric machine equipped with a flat field magnet having a plurality of alternating N and S magnetic poles as a stator, which faces the field magnet through an axial gap and is rotatably supported. In an axial gap type electric motor equipped with a coreless flat armature formed in a disc shape having child coil groups at equal intervals, when the coreless flat armature rotates, the coreless flat armature becomes eccentric and vibrates. One or more armature coils at a predetermined location of the coreless flat armature are removed so that the coreless flat armature does not form a disk shape in a plane, so that the coreless flat armature rotates with A vibrating axial gap type in which a permanent magnet magnetized to either the N pole or the S pole is disposed at a predetermined location of a coreless flat armature such as a cavity, and is opposed to the field magnet. Electric motor. (2) A flat field magnet having four N and S magnetic poles alternately is provided as a stator, and three flat field magnets are rotatably supported and face to face with the field magnet through an axial gap. In an axial gap type motor equipped with a coreless flat armature having coreless armature coil groups at equal intervals, when the coreless flat armature rotates, the coreless flat armature rotates eccentrically and vibrates. According to claim (1), the coreless flat armature is configured by two armature coils by removing one coreless armature coil at a predetermined location of the coreless flat armature. Vibration type axial gap type electric motor. (3) The above coreless armature includes a commutator having 3n (n is an integer of 1 or more) commutator pieces, and a width m of one magnetic pole of a field magnet (m is an odd number of 1 or more). ) A vibrating axial gap type electric motor according to claim (2), comprising two positive power terminals arranged at a double opening angle and a brush connected to a negative power terminal. (4) The coreless flat armature has six commutator pieces, these six commutator pieces and the two armature coils are connected in a Y-shape, and the remaining armature coils are removed. The vibration type axial direction according to claim (3), which is formed by short-circuiting the commutator piece to which the terminal of Air gap type electric motor. (5) The above-mentioned permanent magnet is formed in at least one armature coil of the plurality of armature coils, and is integrated with plastic or the like to form a coreless flat armature. The vibrating axial gap type electric motor according to any one of items (1) to (4). (6) When there are two armature coils, the vibration according to claim (5) is formed by forming the permanent magnet in only one of the armature coils. Type axial gap type electric motor. (7) When there are two armature coils, the permanent magnet is formed in only one of the armature coils, and the permanent magnet is also formed outside at least one of the armature coils. Claim No. (6)
The vibrating axial gap type electric motor described in . (8) When there are two armature coils, the permanent magnet is formed in only one of the armature coils, and a weight is disposed on the outside of at least one of the armature coils. A vibrating axial gap type electric motor according to claim (6). (9) When there are two armature coils, a weight is placed in only one of the armature coils, and the permanent magnet is formed on the outside of at least one of the armature coils. A vibrating axial gap type electric motor according to claim (6). (10) The above permanent magnet is formed by integrally molding the armature coil group with a plastic magnet, and then magnetizing either the N pole or the S pole at a predetermined location of the plastic magnet. A vibrating axial gap type electric motor according to any one of claims (1) to (9).