CN204538925U - The hybrid excitation permanent magnet motor of biharmonic excitation - Google Patents
The hybrid excitation permanent magnet motor of biharmonic excitation Download PDFInfo
- Publication number
- CN204538925U CN204538925U CN201520069899.2U CN201520069899U CN204538925U CN 204538925 U CN204538925 U CN 204538925U CN 201520069899 U CN201520069899 U CN 201520069899U CN 204538925 U CN204538925 U CN 204538925U
- Authority
- CN
- China
- Prior art keywords
- rotor
- winding
- magnetic pole
- harmonic
- harmonic winding
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
Landscapes
- Synchronous Machinery (AREA)
Abstract
A hybrid excitation permanent magnet motor for biharmonic excitation, comprises casing, stator core, stator winding, permanent magnet, rotating shaft, rotor core, rotor windings.Stator winding is distributed in stator slot, rotor core is furnished with permanent magnetism magnetic pole and ferromagnetic magnetic pole, rotor windings is made up of harmonic winding a, harmonic winding b and excitation winding, harmonic winding a is distributed in the groove of permanent magnetism magnetic pole, harmonic winding b is distributed in the groove of ferromagnetic magnetic pole, excitation winding is enclosed within the pole body of ferromagnetic magnetic pole, and harmonic winding a is connected with excitation winding by diode rectifier circuit with harmonic winding b.During generator operation, harmonic winding induced electromotive force can realize the automatic adjustment to air-gap field.The utility model compared with prior art, without the need to brush and slip ring, AC exciter and voltage regulator, without additional air gap and axial magnetic circuit, has structure simple, and good air-gap field regulating power and compounding characteristic.
Description
Technical field
The utility model belongs to technical field of motors, relates to a kind of magneto.
Background technology
Compared with electro-magnetic motor, magneto has high efficiency, high power density and the advantage such as brushless, therefore, magneto social development every field application all widely.But the excitation field due to magneto is produced by permanent magnet, cannot by regulating the adjustment of exciting current realization to air-gap field as electro-magnetic motor.In order to overcome this shortcoming of magneto, some experts and scholar propose hybrid excitation permanent magnet motor both at home and abroad, there are two kinds of excitation magnetic kinetic potentials in this motor: permanent magnet excitation magnetomotive force and electric excitation magnetic kinetic potential, and wherein electric excitation magnetic kinetic potential is used to the air-gap field regulating motor.At present, the hybrid excitation permanent magnet motor of proposition all achieves the adjustment of magneto air-gap field, but the efficiency of some hybrid excitation permanent magnet motor is lower or there is additional air gap and axial magnetic circuit or lose the brushless advantage of magneto.In addition, existing most of hybrid excitation permanent magnet motor scheme all needs voltage regulator.
Utility model content
The purpose of this utility model is for the deficiencies in the prior art, there is provided the hybrid excitation permanent magnet motor of the employing biharmonic excitation of a kind of brushless exclterless and no-voltage adjuster, biharmonic excitation here refers to that the harmonic wave electromotive force utilizing two kinds of different mechanisms of production carries out excitation.
The technical solution of the utility model realizes like this.
The utility model comprises a casing (1), casing (1) built with the stator be made up of stator core (2), stator winding (3) with by permanent magnetism magnetic pole (4), permanent magnet (41), the rotor that ferromagnetic magnetic pole (5), rotating shaft (6), rotor core (7), rotor windings (8) form, stator winding (3) is distributed in the groove (9) that stator core (2) is along the circumferential direction offered, rotor core (7) is furnished with permanent magnetism magnetic pole (4) and ferromagnetic magnetic pole (5), permanent magnetism magnetic pole (4) and ferromagnetic magnetic pole (5) surface all have groove (14), rotor windings (8) is by rotor harmonic winding a (10), rotor harmonic winding b (11) and rotor field coil (12) composition, rotor harmonic winding a (10) is distributed in the groove (14) that permanent magnetism magnetic pole (4) is along the circumferential direction offered, rotor harmonic winding b (11) is distributed in the groove (14) that ferromagnetic magnetic pole (5) is along the circumferential direction offered, rotor field coil (12) is enclosed within the pole body of ferromagnetic magnetic pole (5), rotor harmonic winding a (10) is connected with rotor field coil (12) by diode rectifier circuit with rotor harmonic winding b (11).
The utility model can be that rotor harmonic winding a (10) is connected with rotor field coil (12) by diode rectifier circuit with after rotor harmonic winding b (11) series connection, also can be that rotor harmonic winding a (10) is connected with rotor field coil (12) respectively by after diode rectifier circuit series connection with rotor harmonic winding b (11).
Permanent magnetism magnetic pole described in the utility model (4) can be arranged arbitrarily with the quantity of ferromagnetic magnetic pole (5), and both ratios can be determined according to voltage regulation limits.
Permanent magnet described in the utility model (41) can adopt radial structure, cutting orientation structure, and mixed structure.
Motor described in the utility model can be inner rotor motor or external rotor electric machine; Also can be rotary pole formula motor or revolving-armature type machine.
The hybrid excitation permanent magnet motor stator core (2) of biharmonic excitation of the present utility model is upper arranges a set of stator winding (3), for energy converting between mechanical, rotor not only there are permanent magnet (41) and rotor field coil (12), and also have rotor harmonic winding a (10) and rotor harmonic winding b (11).Permanent magnet (41) and rotor field coil (12) are for setting up the air-gap field of motor, and their pole span is all identical with stator winding (3) pole span.Rotor harmonic winding a (10) and rotor harmonic winding b (11) is for obtaining the energy of the harmonic field in air gap, for rotor field coil (12) provides exciting current, the harmonic field pole span that their pole span is corresponding with it is respectively identical.The number of pole-pairs of rotor is identical with the number of pole-pairs of stator winding (3), stator winding (3) is corresponding with permanent magnet (41) and rotor field coil (12), produce electromagnetic induction effect, be equivalent to the synchronous generator of a rotary pole.The harmonic wave induced electromotive force of rotor harmonic winding a (10) is by the fundametal compoment in rotor permanent magnet magnetomotive force, act on the harmonic field induction that stator tooth harmonic wave magnetic conductance produces to obtain, the harmonic wave induced electromotive force of rotor harmonic winding b (11) is by the harmonic component in stator armature magnetomotive force, acts on the harmonic field induction that average airgap magnetic conductance produces and obtains.During generator no-load running, the magnetomotive force that permanent magnet (41) produces and the magnetomotive force that rotor field coil (12) produces set up air-gap field jointly, and wherein the exciting current of rotor field coil (12) is provided after diode rectification by rotor harmonic winding a (10).When generator loading runs, the magnetomotive force that permanent magnet (41) produces, the magnetomotive force that rotor field coil (12) produces and the armature magnetomotive force that stator winding produces set up air-gap field jointly, the exciting current of rotor field coil (12) is provided after diode rectification jointly by rotor harmonic winding a (10) and rotor harmonic winding b (11), and the harmonic wave electromotive force that rotor harmonic winding b (11) responds to can increase along with the increase of load current, for compensating the demagnetizing effect of armature reaction, thus the automatic adjustment realized air-gap field, to ensure the voltage constant that stator winding (3) exports.
Compared with prior art, hybrid excitation permanent magnet motor of the present utility model has following features:
1, motor does not need brush and collector ring, and AC excitation motor, and structure is simple, reliability is high.
2, when no-voltage adjuster, make full use of the compounding characteristic that harmonic field is good, the constant voltage achieving generator exports.
3, close with common permanent magnetic synchronous motor structure, there is not axial magnetic circuit and additional air gap, maintain high power density and the high efficiency of magneto.
Accompanying drawing explanation
Fig. 1 is the hybrid excitation permanent magnet motor structural representation of the utility model biharmonic excitation, is also the A-A sectional view of Fig. 2.Wherein 1 is casing, and 2 is stator core, and 3 is stator winding, and 4 is permanent magnetism magnetic pole, and 5 is ferromagnetic magnetic pole, and 6 is rotating shaft, and 7 is rotor core, and 8 is rotor windings, and 13 is bearing.
Fig. 2 is the sectional view of motor shown in the utility model Fig. 1, very routine with 6.Wherein 2 is stator core, 3 is stator winding, and 4 is permanent magnetism magnetic pole, and 41 is permanent magnet, 5 is ferromagnetic magnetic pole, 6 is rotating shaft, and 7 is rotor core, and 9 is groove stator core being arranged winding, 10 is the rotor harmonic winding a that permanent magnetism magnetic pole 4 is arranged, 11 is the rotor harmonic winding b that the ferromagnetic magnetic pole 5 of rotor is arranged, 12 is rotor field coil, and 14 is groove rotor core being arranged winding.
Fig. 3 is the circuit theory diagrams be connected with rotor field coil 12 through diode rectifier circuit after the utility model rotor harmonic winding a connects with rotor harmonic winding b.
Fig. 4 is the circuit theory diagrams that the utility model rotor harmonic winding a is connected with rotor field coil 12 respectively with rotor harmonic winding b after diode rectifier circuit series connection.
Embodiment
Below in conjunction with the drawings and specific embodiments, the utility model is described in further detail.
From Fig. 1,2, the hybrid excitation permanent magnet motor of biharmonic excitation of the present utility model, comprises casing 1, is configured with stator core 2 in casing 1, and stator core 2 along the circumferential direction slots 9, is furnished with stator winding 3 in groove 9.Casing 1 and stator core 2 maintain static.Be configured with rotating shaft 6 in casing 1, rotating shaft 6 is connected with casing 1 by bearing 13.Rotating shaft 6 configures rotor core 7, rotor core 7 is furnished with permanent magnetism magnetic pole 4 and ferromagnetic magnetic pole 5, permanent magnetism magnetic pole 4 and ferromagnetic magnetic pole 5 surface all have groove 14, permanent magnetism magnetic pole 4 is furnished with permanent magnet 41 and rotor harmonic winding a10, ferromagnetic magnetic pole 5 is furnished with rotor harmonic winding b11, rotor field coil 12 is enclosed within the pole body of ferromagnetic magnetic pole 5, and rotor windings 8 is made up of rotor harmonic winding a10, rotor harmonic winding b11 and rotor field coil 12.Rotor windings 8 and rotor core 7 can together with rotate in stator core 2 along with rotating shaft 6.
The principle of rotor harmonic winding a10 induced harmonics electromotive force of the present utility model is:
For common alternating current machine, stator core surface all has groove, and during generator no-load running, rotor-exciting magnetomotive force acts in the harmonic wave magnetic conductance that stator teeth notching causes, and the harmonic field of generation can be expressed as
In formula: θ is rotor coordinate electrical degree; T is the time;
for stator each rank slot ripples magnetic conductance amplitude; ν
sfor the exponent number of stator tooth harmonic wave magnetic conductance, get positive integer;
for ν
fdsubharmonic excitation magnetic kinetic potential amplitude, ν
fdfor odd number; Z
1for number of stator slots; P is first-harmonic number of pole-pairs; ω is the angular rate that motor rotates.
From formula (1), the number of times of harmonic field is ν
sz
1/ p+ ν
fdsecondary and ν
sz
1/ p-ν
fd, relative rotor rotating speed is respectively-(ν
sz
1/ p) ω/(ν
sz
1/ p+ ν
fd) and-(ν
sz
1/ p) ω/(ν
sz
1/ p-ν
fd), in rotor harmonic winding a10, all respond to ν
sz
1/ p subharmonic electromotive force.
The principle of rotor harmonic winding b11 induced harmonics electromotive force of the present utility model is:
For the three phase alternating current motor of integer groove winding, when inputting the fundamental current of three-phase symmetrical in the stator winding at three-phase symmetrical, the stator three-phase synthesis armature magnetomotive force of generation can be expressed as
In formula: α is stator coordinate electrical degree; ω is the angular frequency of stator fundamental current, numerically equal with angular rate; F
a1for first-harmonic armature magnetomotive force amplitude; F
a νfor ν subharmonic armature magnetomotive force amplitude; K is positive integer.
Stator three-phase synthesis armature magnetomotive force acts on the average airgap magnetic conductance λ of unit are
0the air-gap field of upper generation can be expressed as
In formula (3), Section 1 is that first-harmonic armature magnetomotive force acts on λ
0the fundamental wave magnetic field of upper generation, this fundamental wave magnetic field rotates along+α direction relative stator with angular rate ω, and relative rotor is static, can not in rotor harmonic winding b11 induced electromotive force.
In formula (3), Section 2 is that harmonic wave armature magnetomotive force acts on λ
0the harmonic field of upper generation, the number of times of harmonic field is ν=6k ± 1.For the harmonic field of ν=6k-1 time, it rotates along-α direction relative stator with angular rate ω/(6k-1), relative rotor rotates with angular rate 6k ω/(6k-1), can respond to 6k subharmonic electromotive force in rotor harmonic winding b11.For the harmonic field of ν=6k+1 time, it rotates along+α direction relative stator with angular rate ω/(6k+1), relative rotor rotates with angular rate 6k ω/(6k+1), can respond to the harmonic wave electromotive force of 6k time in rotor harmonic winding b11.
Operation principle of the present utility model is: during generator no-load running, rotating shaft 6 rotates with synchronous speed, permanent-magnet magnetic kinetic potential acts on the harmonic field that stator tooth harmonic wave magnetic conductance produces can at rotor harmonic winding a10 induced harmonics electromotive force, this harmonic wave electromotive force is supplied to rotor field coil 12 after diode rectification, as shown in Figure 3, during unloaded steady operation, the magnetomotive force that permanent magnet 41 and rotor field coil 12 produce sets up air-gap field jointly, in stator winding 3, respond to the electromotive force of synchronizing frequency, this electromotive force keeps constant in rotating speed one timing.When on generator band during inductive load, the magnetomotive force that permanent magnet 41 and rotor field coil 12 produce and the armature magnetomotive force that stator winding produces set up air-gap field jointly, and due to the demagnetizing effect of armature reaction, its terminal voltage can decline, meanwhile, harmonic wave armature magnetomotive force acts on λ
0the harmonic field of upper generation can rotor harmonic winding b11 induced harmonics electromotive force on ferromagnetic magnetic pole 5, this harmonic wave electromotive force is supplied to rotor field coil 12 after diode rectification, as shown in Figure 3, the demagnetizing effect of armature reaction can be made up, and the size of harmonic wave electromotive force can change automatically along with the change of load current, thus when brushless without AC exciter and no-voltage adjuster, the automatic adjustment to air-gap field can be realized, still keep constant to make the terminal voltage of generator.
When the utility model is used as generator, stator winding 3 is connected with load, and during as motor, stator winding 3 is connected with driving power.
The utility model can be connected with rotor field coil 12 by diode rectifier circuit after rotor harmonic winding a10 connects with rotor harmonic winding b11, also can be that rotor harmonic winding a10 is connected with rotor field coil 12 respectively by after diode rectifier circuit series connection with rotor harmonic winding b11, as shown in Figure 3, Figure 4.
Diode rectifier circuit of the present utility model can adopt bridge full-wave rectifier, also can be halfwave rectifier.
Claims (5)
1. the hybrid excitation permanent magnet motor of biharmonic excitation, comprise a casing (1), it is characterized in that: casing (1) is built with by stator core (2), the stator that stator winding (3) forms and by permanent magnetism magnetic pole (4), permanent magnet (41), ferromagnetic magnetic pole (5), rotating shaft (6), rotor core (7), the rotor that rotor windings (8) forms, stator winding (3) is distributed in the groove (9) that stator core (2) is along the circumferential direction offered, rotor core (7) is furnished with permanent magnetism magnetic pole (4) and ferromagnetic magnetic pole (5), permanent magnetism magnetic pole (4) and ferromagnetic magnetic pole (5) surface all have groove (14), rotor windings (8) is by rotor harmonic winding a (10), rotor harmonic winding b (11) and rotor field coil (12) composition, rotor harmonic winding a (10) is distributed in the groove (14) that permanent magnetism magnetic pole (4) is along the circumferential direction offered, rotor harmonic winding b (11) is distributed in the groove (14) that ferromagnetic magnetic pole (5) is along the circumferential direction offered, rotor field coil (12) is enclosed within the pole body of ferromagnetic magnetic pole (5), rotor harmonic winding a (10) is connected with rotor field coil (12) by diode rectifier circuit with rotor harmonic winding b (11).
2. motor according to claim 1, it is characterized in that: described rotor harmonic winding a (10) is connected with rotor field coil (12) by diode rectifier circuit with after rotor harmonic winding b (11) series connection, or be that rotor harmonic winding a (10) is connected with rotor field coil (12) respectively by after diode rectifier circuit series connection with rotor harmonic winding b (11).
3. motor according to claim 1, is characterized in that: described permanent magnetism magnetic pole (4) is arranged arbitrarily with the quantity of ferromagnetic magnetic pole (5), and both ratios are determined according to voltage regulation limits.
4. motor according to claim 1, is characterized in that: described permanent magnet (41) adopts radial structure, cutting orientation structure or mixed structure.
5. motor according to claim 1, is characterized in that: described motor is inner rotor motor, external rotor electric machine, rotary magnetic pole type motor or revolving-armature type machine.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201520069899.2U CN204538925U (en) | 2015-02-02 | 2015-02-02 | The hybrid excitation permanent magnet motor of biharmonic excitation |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201520069899.2U CN204538925U (en) | 2015-02-02 | 2015-02-02 | The hybrid excitation permanent magnet motor of biharmonic excitation |
Publications (1)
Publication Number | Publication Date |
---|---|
CN204538925U true CN204538925U (en) | 2015-08-05 |
Family
ID=53752883
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201520069899.2U Expired - Fee Related CN204538925U (en) | 2015-02-02 | 2015-02-02 | The hybrid excitation permanent magnet motor of biharmonic excitation |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN204538925U (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104682648A (en) * | 2015-02-02 | 2015-06-03 | 南昌大学 | Biharmonic excitation mixed excitation permanent magnet motor |
CN106026591A (en) * | 2016-05-16 | 2016-10-12 | 南昌大学 | Hybrid excitation permanent magnet motor with double excitation windings |
-
2015
- 2015-02-02 CN CN201520069899.2U patent/CN204538925U/en not_active Expired - Fee Related
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104682648A (en) * | 2015-02-02 | 2015-06-03 | 南昌大学 | Biharmonic excitation mixed excitation permanent magnet motor |
CN104682648B (en) * | 2015-02-02 | 2017-07-11 | 南昌大学 | The hybrid excitation permanent magnet motor of biharmonic excitation |
CN106026591A (en) * | 2016-05-16 | 2016-10-12 | 南昌大学 | Hybrid excitation permanent magnet motor with double excitation windings |
CN106026591B (en) * | 2016-05-16 | 2018-07-17 | 南昌大学 | Hybrid excitation permanent magnet motor with double Exciting Windings for Transverse Differential Protection |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN103208893B (en) | Induced excitation formula composite excitation brushless synchronous motor | |
CN101651394B (en) | Mixed excitation magnetoelectric machine adopting harmonic excitation | |
CN104682648B (en) | The hybrid excitation permanent magnet motor of biharmonic excitation | |
CN102185448B (en) | Hybrid excitation permanent magnet motor for wireless transmission and tooth harmonic excitation | |
CN101039057B (en) | A. C. brushless double-fed motor | |
CN103199662B (en) | The composite excitation permanent magnet synchronous motor of third harmonic excitation | |
CN103887908B (en) | A kind of brushless harmonic exitation synchronous motor | |
CN103683775A (en) | Third-harmonic excitation synchronous motor | |
CN101969257B (en) | Hybrid excitation permanent magnet motor with tooth harmonic excitation | |
CN108988598A (en) | Flux modulation formula permanent magnetism vernier motor built in a kind of stator | |
Fu et al. | A unified theory of flux-modulated electric machines | |
CN204538925U (en) | The hybrid excitation permanent magnet motor of biharmonic excitation | |
CN102005875A (en) | Brushless parallel-structure hybrid excitation synchronous generator without additional air gap | |
CN103618392B (en) | Stator and rotor dual-permanent-magnet excitation harmonic motor | |
CN110957822B (en) | Birotor magnetic flux switches aerogenerator and power generation system | |
CN103904856B (en) | A kind of brushless Harmonic Wave Excited Generator with initial self-excitation ability | |
CN202889138U (en) | Parallel type composite excitation brushless direct-current motor | |
CN103904855A (en) | Brushless harmonic excitation motor with initial self-starting capacity | |
CN101976923B (en) | Hybrid excitation permanent magnet motor with secondary harmonic excitation | |
CN111262411A (en) | Double-harmonic winding brushless excitation direct-current generator with wide voltage regulation range | |
CN101771314A (en) | Double-rotor (stator) generator | |
CN210669671U (en) | External rotor single-phase alternating-current generator | |
CN106787564A (en) | A kind of brushless hybrid excitation magneto based on harmonic exitation | |
CN201956856U (en) | Mixed excitation permanent-magnet motor with quintuple harmonic excitation | |
CN102013779B (en) | Hybrid excitation permanent magnet motor of quintuple harmonic excitation |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20150805 Termination date: 20160202 |