JP3461162B2 - Flat brushless vibration motor with built-in drive circuit - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flat type brushless vibration motor suitable for use as a silent notification means of a mobile communication device and having a built-in drive circuit.

[0002]

2. Description of the Related Art Conventionally, the applicant of the present invention has proposed a flat small brushless vibration motor, which was previously disclosed in Japanese Utility Model Laid-Open No. 4-137463 (Utility Model Registration No. 2549357) and Japanese Patent Laid-Open No. 10-248.
No. 203 is proposed. Further, as a similar one, the one shown in JP-A-2000-166173 has been proposed.

[0003]

The brushless motor is
A drive circuit that replaces the brush and commutator is an indispensable requirement. However, in the above-mentioned conventional structures, no drive circuit is built in, and external terminals require 4 or more lead terminals. There was a problem that it could not be handled like a type DC motor. Moreover, in a normal brushless motor, the stator has a plurality of armature coils evenly arranged around the entire circumference, and the drive circuit component cannot be built in because it requires an IC and other electronic components.

In view of the above, the present invention focuses on the fact that the vibration motor operates in a state of almost no load, so that the efficiency can be sacrificed to some extent. An object of the present invention is to provide a flat type brushless vibration motor that can be handled in the same manner as a two-terminal type DC motor.

[0005]

In order to solve the above-mentioned problems, as shown in claim 1 , a cylindrical magnet (6, 6) having a plurality of magnetic poles equally divided inside a rotor case (5).
66) is arranged and the outside of this magnet is
An eccentric rotor (R to R5) provided with a semi-cylindrical eccentric weight (5b) in a rotor case, a shaft (2) supporting the eccentric rotor, and a stator base (1a) having a shaft supporting portion (1a) supporting the shaft. ), And armature coils (3a to 33a) wound around a plurality of salient poles (4a to 44a) of the stator core (4) for driving the rotor. A cored type stator (S) that is lined, and the stator base is a flat surface.
It is formed into a disc shape when viewed from above, and the substrate (1b) is placed on the upper surface of the substrate (1b).
In addition, there is a portion where the armature coil is arranged on this substrate , and a space (K to) for leaving at least one of the armature coils, and a drive circuit member in this space. (1c) is distributed, and the stay is further provided on the outer periphery.
The dummy core (1d) is placed at an angle equal to the salient pole of the tacoa.
Raised, the so as to cover the stator base
That the rotor cover (C) is attached to the outer periphery of the base.
This can be achieved by incorporating the characteristic drive circuit. Specifically, as described in claims 2 and 3, the stator is one in which an armature coil is wound around at least two salient poles, and the magnets are alternately magnetized NS via radial air gaps. Combined with a magnet that has a magnetic pole that is an integer multiple of 2,
A drive circuit member (1) arranged in the space (K1 to K3)
c) is a sensorless type, or the stator core (44) in which the stator is arranged at an opening angle that is an integral multiple of the width of the magnetic poles.
At least two salient poles (44a-) have armature coils (3
3a-) is wound, and the drive circuit member (1) has at least one sensor in the void (K4, K5).
1c) is preferably provided. Another specific solutions of the stator as shown in claim 4, eccentric Low
The rotor case (111) and this rotor
It is glued to the ceiling of the case and evenly divides multiple magnetic poles.
Flat ring-shaped axial void magnet (66
And 6) were further this B Takesu eccentric weights other portion which is arcuate type with a portion is secured has to be placed directly on the outer periphery of the magnet (55b), fixed to the central shaft (22) is provided, the stator (S6 to) for driving the eccentric rotor is a bearing portion (111a) that supports the shaft of the eccentric rotor, and the base end of the shaft is disposed on the bearing portion (111a). Thrust bearing (11
1b), a stator base (11
1) and a substrate (1b) arranged on this stator base,
This air bag is arranged on this substrate, and is composed of a plurality of air-core armature coils (333a to) for driving the rotor, and the stator base is a portion in which the air-core armature coils are arranged in plan view, It has a space (K6 ~) that is designed to leave at least one armature coil, and the drive circuit members (1c, 11c) are installed in this space, and
A rotor cover (C) may be attached to the outer peripheral portion of the stator base so as to cover them. Here, more specifically, as the stator, the shaft supporting portion is a bearing (111a).
Is directly attached to the stator base,
It has a thrust bearing (111b) and the stator (S
6) is composed of at least two air-core armature coils having an arrangement opening angle of 60 °, and the rotors to be combined through an axial gap have NS magnetic poles of eight poles magnetized alternately, Is the member a sensorless type,
The shaft support uses a bearing (111a) on the stator base.
It is installed directly, and the thrust bearing (111
b), the stator (S8) has two air-core armature coils arranged at an opening angle that is an integer multiple of the width of the magnetic poles of the magnet, and has at least one sensor. It is preferable that the driving circuit member (11c) is provided.

According to the first aspect of the present invention, the drive circuit member can be easily built in, the positive and negative terminals of the power supply terminal can be made two, and the cored type stator allows the thickness of the stator to be utilized relatively. Since a high-position built-in member can be used and the rotating part is covered by the cover, there is no danger and it is convenient to handle .
Eccentricity due to the semi-cylindrical eccentric weight placed in the data case
Is emphasized, the movement of the center of gravity becomes large, and centrifugal force vibration during rotation is
The movement can be great. In the invention described in claims 2 and 3, the dummy
The cogging is improved by the core, and the stator is also vacant in the radial direction.
Since it is a gap type three-phase, a sensorless type or a single-phase one-hole sensor type can be easily adopted. According to the invention described in claim 4, the driving circuit member can be easily built in, the positive and negative terminals of the power supply terminal can be two, and the axial gap type coreless stator can be made thin. since the rotation portion is covered even by the cover, there is no danger, it is assumed that there is a convenience in handling, the rotor case and magnet
The eccentric weight placed on the
Eccentricity is emphasized because it is on the circumference, and the movement of the center of gravity is large
Therefore, centrifugal force vibration during rotation can be increased. In the inventions as claimed in claims 5 and 6, since the shaft support portion is used as a bearing, the number of parts is reduced, and the air-core armature coil is also a one-hole sensor system such as a three-phase sensorless system of axial gap type or a single-phase type. Can be easily done.

[0007]

1 shows a first embodiment of the present invention, which is a three-phase radial void type cored system.
It is a cross-sectional top view of a flat type brushless vibration motor. 2 is a vertical cross-sectional view of the motor shown in FIG. FIG. 3 is a cross sectional plan view of a first modification of the motor of FIG. FIG. 4 is a cross sectional plan view of a second modification of the motor of FIG. FIG. 5 is a cross sectional plan view of a third modification of the motor of FIG. Figure 6 shows a second embodiment of the present invention, Bian other radial gap type cored scheme
A transverse cutting plane view of the flat brushless vibration motor.
FIG. 7 is a lateral cutaway plan view of a first modification of the motor of FIG. FIG. 8 shows a third embodiment of the present invention, and is a horizontal cross-sectional plan view of a flat brushless vibration motor of an axial void type coreless system. FIG. 9 is a vertical cross-sectional view of FIG. FIG. 10 is a lateral cutaway plan view of a first modification of the motor of FIG. FIG. 11 shows the fourth embodiment of the present invention.
FIG. 10 is a lateral cross-sectional plan view of another flat type brushless vibration motor of an axial void type coreless system, showing the embodiment of FIG.

The structure of the present invention will be described below based on the illustrated embodiments. 1 and 2 shows a three-phase radial air gap cored type flat brushless vibration motor, that is, a stepped shaft supporting portion 1a is burring in the center of a stator base 1 which constitutes a part of a housing H. Then, the shaft 2 is started up, and the shaft 2 is press-fitted into the shaft support 1a to fix the shaft 2. The armature coil 3a is attached to the shaft support 1a,
Salient poles 3b and 3c through a core cover (not shown)
The stator core 4 wound around a, 4b, and 4c is attached to form the stator S. However, as a feature of the present invention, three of the three-phase six-salient-pole type stators having an opening angle of 60 degrees are originally used. A pole is deleted (that is, three armature coils are vacant) to form a void K, and the void I is attached to the glass cloth epoxy substrate 1b.
The drive circuit member 1c composed of C (IC) and chip type electronic parts is stored. Therefore, normally, in order to make the armature coils facing each other equal to those connected in series, it is preferable to wind many fine wires although the power is reduced. On the other hand, the rotor R is made up of a shallow cylindrical rotor case 5 having a notch 5a in the ceiling in order to reduce the weight and increase the amount of eccentricity, and a shallow cylindrical magnet 6 fixed to the inside thereof. A semi-cylindrical weight 5b is attached to the outside by welding or the like for eccentricity emphasis, and is rotatably attached to the shaft via a bearing 5c arranged at the center. Here, the magnet 6 has eight magnetic poles magnetized alternately in NS so as to obtain a good starting. In the figure, 1d is a dummy core that is raised from the stator base 1 in order to make the magnetic attraction force received from the magnet as uniform as possible.
C is a cover attached to the stator base 1 at the opening edge, and has a function of protecting the eccentric rotor and a function of avoiding a risk at the time of turning caused by the uneven surface of the eccentric rotor. A sensorless system using a three-phase unipolar or bipolar is used as a drive system of such a configuration. Since the driving principle is well known, the description is omitted.

Hereinafter, modified examples of the above-described embodiment and other embodiments will be described. However, the same members or substantially the same members having the same function may be designated by the same reference numerals and the description thereof may be omitted. is there. In addition, in the following embodiment and each modified example, the cover C is used for clarifying the structure.
Is omitted. FIG. 3 shows the first modified example described above, in which the stator S1 is composed of two salient pole type armature coils 3a and 3b for cost reduction. Is removed, and the drive member 1c as described above is attached to the void K1 in the same manner as described above. If this drive is sensorless,
Since one pole is short-circuited, it is preferable to use a bipolar system in which each phase is energized. With this configuration, a space can be provided in the arrangement space of the drive circuit member 1c, and the drive circuit member 1c can be stored without difficulty.

FIG. 4 shows a second modification of the above, in which the stator S2 is formed of four salient poles, each having a salient pole 4d facing the salient pole 4a. That is, the stator S2 is the same as that of the first embodiment except that the armature coils 3a and 3d wound around the salient poles 4a and 4d facing each other are connected in series. It is also the same as the case where the drive circuit member 1c is provided for each piece, but it is preferable to use a bare chip type which is smaller than the sensorless IC.

FIG. 5 shows a stator S3 according to the third modification.
Is a stator core 4 having an opening angle of about 80 degrees.
Shallow cylindrical magnets that are made up of armature coils 3e, 3f, and 3g that are wound around respective salient poles 4e, 4f, and 4g, and that form a desired eccentric rotor R3 through a radial gap in this stator S3. 6 is selected to have 6 magnetic poles that are alternately magnetized in NS. In this case, of course, there is one or more armature coils in the vacant space K3, and the drive circuit member 1c is also installed here. The opening angle of the three salient poles can be designed to be about 70 to 100 degrees by changing the size of the blade.

FIG. 6 shows a radial air gap type cored type flat type brushless vibration motor using one Hall IC as a second embodiment of the present invention. That is, a stator S4 that drives an eccentric rotor R4 that includes a magnet 66 having four magnetic poles that are magnetized alternately in NS.
As a stator core 44 having two salient poles 44a and 44b arranged on the stator base 11 with an opening angle of width (90 degrees in this case), and armature coils 33a and 33b wound around the stator core 44. Therefore, two of the four armature coils are removed, and one hole I is provided as the drive circuit member 11c in this space K4.
C and other electronic components attached to it are housed.

FIG. 7 shows a stator S5 as a modification of FIG.
Shows that it consists of three salient poles. That is, a third salient pole 44c is provided on the salient poles 44a, 44b so as to face the salient pole 44a. This salient pole 44c
The armature coil 33c is wound around and is connected in series with the facing armature coil 33a. Also in this case, a vacant space K5 for one armature coil is generated, and one Hall IC as the drive circuit member 11c and other electronic components accompanying this are accommodated therein. . Also in this case, the shallow cylindrical magnet 6 that constitutes the eccentric rotor R5
6 is composed of 6 magnetic poles alternately magnetized for the time being.

What is shown in FIGS. 8 and 9 is the third embodiment of the present invention.
As an embodiment of an axially opposed coreless type three-phase
Flat type brushless vibration motor, that is, stator S
As shown in FIG. 6, a bearing 111a serving as a shaft supporting portion is directly and integrally fixed to the center of the stator base 111, and three of the six components which should originally be arranged at an opening angle of 60 degrees of three phases are deleted. The remaining three air-core armature coils 333a, 333b, 333c are arranged, and the sensorless drive circuit member 1 is provided in the space K6 for the three air-core armature coils.
It is configured by arranging c. Since this one Hall sensor type driving principle is well known, its explanation is omitted here. A thrust bearing 111b made of a ball is inserted at the bottom of the bearing 111a in order to reduce the sliding area of the shaft for the purpose of reducing the strong attraction brake of the magnet 666 arranged on the rotor side.
On the other hand, in the eccentric rotor R6, a flat ring-shaped magnet 666 consisting of eight magnetic poles magnetized alternately in NS is fixed to the ceiling portion of the rotor case 55, and the shaft 22 is press-fitted into the burring portion 55a provided at the center. Other than the above, it is the same as the above-described examples detailed in FIG. The eccentric rotor R6 thus configured is rotatably mounted on the bearing 111a. Eccentric weight as unbalance means 5
5b is partially bonded directly to the outer circumference of the flat ring-shaped magnet 666, and as shown in the drawing,
The part is also adhered to the outer periphery of the rotor case 55.
The above-mentioned air core electric machine so that it can be judged from the figure
Hanging to the thickness of the child coils 333a, 333b, 333c
is doing. For this reason, eccentricity emphasis becomes great. FIG. 10 shows the first modification of FIG. 8 in which the stator S7 includes three air-core armature coils 333d and 333e having an arrangement opening angle of about 80 degrees.
And 333f, and a shallow cylindrical magnet 666 that faces the stator S7 via an axial gap.
Is selected to have 6 magnetic poles magnetized alternately in NS. In this case, of course, there is one or more armature coils in the vacant space K7, and the drive circuit member 1c is also installed here. Incidentally, the arrangement angle of the three salient poles can be designed to be 70 degrees to 100 degrees by changing the size or the like.

FIG. 11 shows a modification of the stator S shown in FIG.
In order to reduce the cost, the two air core armatures 333g are arranged at an angle of 90 degrees (opening angle of the magnetic poles). Naturally, the space K8 has two air core armature coils. The drive circuit member 11c composed of one Hall IC as described above and an attached electronic component is housed. This stator S8
The eccentric rotor, which has a magnetic field of 4 degrees, has four magnetic poles magnetized alternately at an opening angle of 90 degrees in NS, but is composed of six magnetic poles according to the opening angle of the effective conductor portion of the air-core armature coil. You can also let it. Although not shown, three air-core armature coils may be arranged at an opening angle of 90 degrees and the space may be limited to one air-core armature.

In each of the above-described embodiments and its modifications, the main body is shown with the shaft supporting portion on the side of the stator base, which is a part of the housing. The cover may be provided with a shaft support. That is, Japanese Patent Application Laid-Open No. HEI 1 disclosed by the present applicant
It may be as shown in FIG. 3 of 0-248203. Furthermore, instead of the glass cloth epoxy board 1b, a stator base may be replaced with a circuit printed iron board and the drive circuit member 1c may be additionally provided. By doing so, the heat dissipation of the drive circuit member is improved. This invention has its technical idea,
Various other embodiments can be adopted without departing from the characteristics. Therefore, the above-described embodiment is merely an example and should not be limitedly interpreted. The technical scope of the present invention is shown by the claims and is not bound by the text of the specification.

[0017]

According to the present invention, as described in claim 1 , a circle having a plurality of magnetic poles equally divided inside the rotor case (5).
With arranging the cylindrical magnet (6, 66), this Ma
A semi-cylindrical eccentric weight is attached to the rotor case outside the gnet.
And an eccentric rotor (R to R5) provided with a wheel (5b),
A shaft (2) for supporting the eccentric rotor, a stator base (1) having a shaft supporting portion (1a) for supporting the shaft, and a stator core (4) arranged on the stator base for driving the rotor. A plurality of salient poles (4a to 4)
4a to 4) and cored type stators (S) in which armature coils (3a to 33a) are respectively wound, and the stator base is formed in a disk shape when viewed from above , and has an equivalent shape.
-Shaped circuit board (1b) is placed on the upper surface and
A portion in which the armature coil is arranged on the circuit board of ,
The armature coil has a space (K to) so as to leave at least one armature coil, and the drive circuit member (1) is provided in this space.
c) is Haigi such that the stator outer periphery radially inward, further
The outer circumference of the stator base to cover them
Those fitted with the rotor cover (C) to the part as the first basic, as shown in claim 4 rotor case (111)
A disk-shaped ring-shaped magnet having a plurality of magnetic poles evenly distributed inside
Gnet (666) is arranged and this magnet
Is fixed to the outer circumference of the
An eccentric rotor (R6 ~) having a fixed eccentric weight (55b) , a shaft (22) for supporting the eccentric rotor,
A shaft support (111a) for supporting the shaft, distribution in the shaft support
Thrust bearing (11
1b) and the disk support as a whole with the shaft support.
The data base (111) and the stator base
Substrate (1b) and a plurality of air-core armature coils (333a ) arranged on this substrate to drive the rotor.
And a stator (S6 to), the stator base has a portion where the air-core armature coil is arranged in a plan view, and a vacant space (at least one of the armature coils). K6~) have, said in this space
The driving circuit members (1c, 11c) are arranged in a range where the air-core armature coil is arranged with a circular outer circumference, and the semi-cylindrical eccentricity is provided.
The weight hangs down to the outer peripheral part of the air-core armature coil.
Further, the stator base to cover these
The one with the rotor cover (C) attached to the outer periphery of the
Since all of them are based on the standard, driving circuit parts can be built in with a simple configuration to handle the same as a normal DC motor, but with an eccentricity emphasis weight.
Therefore, it is possible to provide a flat brushless vibration motor having a large vibration amount .

[Brief description of drawings]

FIG. 1 shows a first embodiment of the present invention, in which 3
It is a cross-sectional plan view of a flat type brushless vibration motor of a radial gap type cored system of a phase.

2 is a vertical cross-sectional view of the motor of FIG.

FIG. 3 is a horizontal cutaway plan view of a first modification of the motor of FIG.

4 is a lateral cutaway plan view of a second variation of the motor of FIG.

5 is a lateral cutaway plan view of a third modification of the motor of FIG. 1. FIG.

FIG. 6 shows a second embodiment of the present invention, and is a horizontal cross-sectional plan view of another radial type air gap type cored type flat brushless vibration motor.

7 is a lateral cutaway plan view of a first variation of the motor of FIG.

FIG. 8 shows a third embodiment of the present invention, and is a horizontal cross-sectional plan view of an axial gap type coreless type flat brushless vibration motor.

9 is a vertical cross-sectional view of FIG.

10 is a lateral cutaway plan view of a first modification of the motor of FIG. 9. FIG.

FIG. 11 shows a fourth embodiment of the present invention,
It is a cross-sectional top view of another flat type brushless vibration motor of an axial gap type coreless system.

[Explanation of symbols]

H ... housing 1, 11, 111 ... Stator base 2, 22 ... Axis 3a to 3g, 33a, 33b, 33c ... Armature coil 333a to 333h ... Air-core armature coil 4,44 Stator core 4a-4g, 44a-44c ... salient poles S, S1 ... Sn ... Stator K, K1-K8 ... vacant place 1c, 11c ... Drive circuit member R, R1, R2 ... Eccentric rotor 5 Shallow cylindrical rotor case 5b ... Eccentric weight 6, 66 ... Shallow cylindrical magnet 666 ... Ring-shaped flat magnet C ... cover

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁷ identification symbol FI H02K 7/065 H02K 7/065 11/00 11/00 X (56) Reference JP 2000-262969 (JP, A) JP 59-139852 (JP, A) JP-A-11-289734 (JP, A) JP-A-11-98761 (JP, A) JP-A-8-37753 (JP, A) JP-A-7-213041 (JP , A) JP-A-5-304744 (JP, A) JP-A-4-229044 (JP, A) Actually opened 61-52483 (JP, U) Actually opened 55-117185 (JP, U) Actually opened 2-22071 (JP, U) Actual Kaihei 1-180868 (JP, U) (58) Fields surveyed (Int.Cl. ⁷ , DB name) H02K 29/00 B06B 1/04 H02K 3/04 H02K 3 / 18 H02K 3/47 H02K 7/065 H02K 11/00 H02K 21/00

Claims (6)

(57) [Claims] 1. A cylindrical magnet (6, 66) having a plurality of magnetic poles equally arranged inside a rotor case (5), and the rotor case is located outside the magnet.
An eccentric rotor (R to R5) provided with a semi-cylindrical eccentric weight (5b) , and a shaft (2) supporting the eccentric rotor.
And a stator base (1) having a shaft supporting portion (1a) for supporting the shaft, and a stator base (1) arranged on the stator base,
A cored type stator (S) in which armature coils (3a to 33a) are respectively wound around a plurality of salient poles (4a to 44a) of a stator core (4) for driving the rotor, The stator base is a circle when viewed from above
When it is formed in the shape of a board and the substrate (1b) is placed on the upper surface thereof,
Both have a portion where the armature coil is arranged on this substrate , and a space (K to) for leaving at least one of the armature coils, and the drive circuit member (1c). ) Is attached to the stator core, and
The dummy core (1d) stands up at an opening angle equal to the salient pole of
Of the stator base to cover them .
Features a rotor cover (C) attached to the outer periphery
Flat brushless vibration motor having a built-in driving circuit to. 2. The stator has at least two salient poles around which an armature coil is wound, and has an N-shaped radial gap.
The driving circuit member (1c) arranged in the vacant spaces (K1 to K3) in combination with a magnet having magnetic poles of S alternately magnetized by an integer multiple of 2 is of a sensorless type. Flat type brushless vibration motor with built-in drive circuit members. 3. The stator core (44) , wherein the stator is arranged at an opening angle that is an integral multiple of the width of the magnetic pole, is obtained by winding an armature coil (33a-) around at least two salient poles (44a-). The flat brushless vibration motor having a drive circuit according to claim 1, wherein the drive circuit member (11c) having at least one sensor is provided in the space (K4, K5). 4. An eccentric rotor (R6-) is a rotor case.
(111) was adhered to the ceiling of the rotor case
A flat ring-shaped axial direction that has multiple magnetic poles evenly
A void type magnet (666) and this rotor
Other part that is partly fixed to the base and has an arc shape
Eccentricity so that the magnets are directly arranged on the outer circumference of the magnet
The weight (55b) and the shaft (22) fixed to the center
Is equipped with a stay that drives this eccentric rotor.
Is a bearing portion (1) that supports the shaft of the eccentric rotor.
11a), which is arranged in this bearing part,
Thrust bearing (111b) to receive, the bearing part is integrated
Stator base (111) and this stator base
The substrate (1b) placed on top, the one placed on this substrate,
A plurality of air-core armature coils (33) for driving the rotor.
3a-), the stator base is viewed from a plane.
And a portion where the air-core armature coil is arranged,
A vacant space for at least one child coil
(K6 ~), and drive circuit members (1c, 1
1c) is distributed, and the cover is covered to cover them.
Attach the rotor cover (C) to the outer periphery of the data base
A flat type brushless vibration motor with a built-in drive circuit. 5. The shaft support includes a bearing (111a) for supporting the bearing.
It is attached directly to the data base and has thrust inside.
The bearing (111b), the stator (S6) is composed of at least two air-core armature coils with an arrangement opening angle of 60 degrees pitch, and the rotors assembled through axial air gaps are magnetized alternately in NS. The flat brushless vibration motor having a built-in drive circuit member according to claim 4, wherein the drive circuit member has eight magnetic poles and the drive circuit member is of a sensorless type. 6. The bearing comprises a bearing (111a) for the shaft support.
It is attached directly to the data base and has thrust inside.
Has a bearing (111b), said stator (S8) is the
The drive circuit according to claim 4, comprising two air-core armature coils arranged at an opening angle that is an integral multiple of the width of the magnetic pole of the magnet, and comprising the drive circuit member (11c) having at least one sensor. Flat type brushless vibration motor with built-in.