CN114938086A - Stator, electro-magnetic doubly-salient motor and motor control method - Google Patents

Abstract

The invention provides a stator, an electro-magnetic doubly salient motor and a motor control method, relates to the technical field of motors and solves the problem of large span of an electro-magnetic winding of the electro-magnetic doubly salient motor in the prior art, wherein the stator comprises a stator core, an armature winding and an excitation winding, the stator core is provided with a plurality of stator salient poles which are sequentially arranged at equal intervals along the circumferential direction, and a winding slot is formed between every two adjacent stator salient poles; armature windings are wound on all the stator convex poles of the stator core in the winding slots; a gap is formed in the yoke part of the stator core, and the gap communicates the inner side and the outer side of the stator core in the radial direction, so that the stator core is disconnected at the gap; the excitation winding is wound on the yoke part of the stator core and is positioned between two adjacent stator salient poles; the excitation winding and the gap are respectively arranged at two end positions on the radial direction of the stator core. Compared with the prior art, the invention can reduce the span of the electric excitation winding, reduce the cost and improve the efficiency of the motor.

Description

Stator, electro-magnetic doubly-salient motor and motor control method

Technical Field

The invention relates to the technical field of motors, in particular to a stator, an electro-magnetic doubly salient motor and a motor control method.

Background

The double-salient motor has the advantages of large low-speed torque, simple and firm structure and low cost, and common products are a Switched Reluctance Motor (SRM) and a permanent magnet double-salient motor (DSPM) and an electro-magnetic double-salient motor (DSEM) derived from the SRM.

The Switched Reluctance Motor (SRM) has excellent performance, but the armature winding has more turns, needs larger winding space, and the volume and the weight of an iron core and an enameled wire are larger. The working principle of the permanent magnet doubly salient motor (DSPM) and the electro-magnetic doubly salient motor (DSEM) is changed to a certain extent due to the addition of the excitation assembly, the number of turns of the armature winding is small, the volume and the weight of the iron core are reduced, the enameled wire consumption of the armature winding is also obviously reduced, the cost performance of the two motors is improved, the volume, the weight and the performance of the two motors are equivalent to those of a permanent magnet brushless direct current motor (BLDC) with the same power, and the cost is slightly reduced.

However, rare earth magnetic steel used in a permanent magnet doubly salient motor (DSPM) is a scarce resource, and in recent years, the price has been increased by several times, and the price is still high even though the amount of rare earth used is slightly reduced compared with that of a permanent magnet brushless direct current motor (BLDC). The cost of the electric excitation double-salient motor (DSEM) is lower than that of a permanent magnet double-salient motor (DSPM), a permanent magnet direct current brushless motor (BLDC) and a Switched Reluctance Motor (SRM), but the electric excitation double-salient motor (DSEM) has the defects that an electric excitation winding generally needs to span three stator salient poles (as shown in figure 6), grooves are formed among the stator salient poles, the whole span is large, an enameled wire used by the excitation winding is long, the internal resistance of the excitation winding is large, so that more electric energy is lost, and the efficiency is obviously reduced.

The permanent magnet direct current brushless motor (BLDC) adopts a six-step pulse mode, and the armature winding generates a magnetic field through current, and generates attractive or repulsive magnetic force with the magnetic steel on the rotor to drive the rotor to normally rotate. In the speed regulation control of a permanent magnet brushless direct current motor (BLDC), in order to improve the controllability of the motor at a high speed, mechanical or electronic weak magnetism is often used during the high-speed control to reduce the back electromotive force of an armature winding at the high speed so as to improve the controllability, so that the motor can also output power and torque at the high speed, but the mechanical weak magnetism method usually reduces the magnetic field intensity by using a permanent magnet of a magnetizer short-circuit part, and the method hardly reduces the efficiency, but has a complex structure and high cost; the electronic flux weakening method is to apply a flux weakening current in an armature winding in time to offset a part of magnetic field so that the back electromotive force of the armature winding is reduced, thereby not reducing the output power at high speed, but reducing the efficiency and leading to complex algorithm. Therefore, a permanent magnet brushless dc motor (BLDC) cannot achieve field weakening at a low cost and with high efficiency.

Disclosure of Invention

The invention aims to design a stator, an electro-magnetic doubly salient motor and a motor control method, which are used for solving the problem of large span of an electro-magnetic winding of the electro-magnetic doubly salient motor, reducing the span of the electro-magnetic winding, reducing the cost and improving the motor efficiency.

The invention is realized by the following technical scheme:

the invention provides a stator, which comprises a stator core, an armature winding and an excitation winding, wherein the stator core is provided with a plurality of stator salient poles which are sequentially arranged at equal intervals along the circumferential direction, and a winding slot is formed between every two adjacent stator salient poles; the armature winding is wound on all the stator salient poles of the stator core in the winding slot; a gap is formed in the yoke part of the stator core, and the gap communicates the inner side and the outer side of the stator core in the radial direction, so that the stator core is disconnected at the gap; the excitation winding is wound on the yoke part of the stator core and is positioned between two adjacent stator salient poles; the excitation winding and the gap are respectively arranged at two end positions of the stator core in the radial direction.

When the structure is adopted, the excitation winding is directly wound at the position between two adjacent stator salient poles on the yoke part of the stator iron core, and the plurality of stator salient poles do not need to be spanned, so that the span of the excitation winding is reduced. Therefore, the length of the enameled wire in the excitation winding can be reduced, the cost is reduced, and meanwhile, the electric energy loss of the excitation winding is reduced, so that the efficiency of the motor can be improved, and the cost is reduced.

The yoke part of the stator core is provided with a gap so that an unsealed magnetic circuit gap can be formed at the gap, the arrangement positions of the gap and the excitation winding are respectively arranged at two radial end positions of the stator core, and all stator salient poles on the stator core can be equally divided into two groups. When direct current is introduced into the exciting windings, the same magnetic poles are formed on the stator salient poles of each group, the stator salient poles of different groups form paired magnetic poles, and fixed magnetic fields are formed at two ends of the exciting windings and the gaps. The arrangement can change the magnetic field intensity in the stator core simply by controlling the current value of the exciting winding, and obtain larger motor output power and output torque in a very economical mode in a wide rotating speed range.

In order to further better implement the invention, the following arrangement structure is particularly adopted: the armature windings are connected into a three-phase winding by adopting a star connection structure.

In order to further better implement the invention, the following arrangement structure is particularly adopted: and the notches are provided with connecting pieces with non-magnetic conductivity, and the connecting pieces are respectively connected with the two ends of the yoke part of the stator core at the notches to plug the notches.

When the structure is adopted, the connecting pieces made of the non-magnetic materials are arranged at the notches to connect the yoke parts of the stator cores at two ends of the notches for filling, so that the mechanical structure strength of the stator cores at the notches can be improved, and the whole stator structure is firm.

In order to further better implement the invention, the following arrangement structure is particularly adopted: stator framework is installed to stator core, armature winding twine in on the stator framework, excitation winding twines in on the stator framework.

In order to further better implement the invention, the following arrangement structure is particularly adopted: the stator salient poles are directed to an inner side or an outer side of the stator core.

The invention also provides an electro-magnetic doubly salient motor which comprises a rotor and the stator, wherein the rotor and the stator are concentrically arranged and can relatively rotate; the stator salient poles of the stator are directed radially toward the rotor, and the rotor salient poles of the rotor are directed radially toward the stator.

In order to further better implement the invention, the following arrangement structure is particularly adopted: the rotor is inserted into a stator iron core of the stator.

In order to further better implement the invention, the following arrangement structure is particularly adopted: and a stator iron core of the stator is inserted into the rotor.

In order to further better implement the invention, the following arrangement structure is adopted in particular: the stator is fixed in the shell, and the rotor is arranged in the shell and is arranged on the shell through a motor rotating shaft.

The invention also provides a motor control method, aiming at the electric excitation doubly salient motor, the electric excitation doubly salient motor is used as a motor or a generator;

when used as a motor, the motor control method includes: when a rotor of the electrically excited doubly salient motor normally rotates, adjusting motor output power and output torque by changing magnetic field intensity in a stator core by adjusting a current value of an excitation winding of a stator of the electrically excited doubly salient motor;

when used as a generator, the motor control method includes: when the rotor of the electrically excited doubly salient motor rotates normally, the current value of the exciting winding of the stator of the electrically excited doubly salient motor is adjusted to change the magnetic field intensity in the stator core of the stator of the electrically excited doubly salient motor, so that the voltage and the current output by the armature winding of the stator of the electrically excited doubly salient motor are adjusted.

The invention has the following advantages and beneficial effects:

in the invention, the excitation winding is directly wound at the position between two adjacent stator salient poles on the yoke part of the stator core, and a plurality of stator salient poles do not need to be spanned, thereby reducing the span of the excitation winding. Therefore, the length of the enameled wire in the excitation winding can be reduced, the cost is reduced, and meanwhile, the electric energy loss of the excitation winding is reduced, so that the efficiency of the motor can be improved, and the cost is reduced.

In the invention, the yoke part of the stator core is provided with the gap so that a non-closed magnetic circuit gap can be formed at the gap, the arrangement positions of the gap and the excitation winding are respectively arranged at the two radial end positions of the stator core, and all stator salient poles on the stator core can be equally divided into two groups. When direct current is introduced into the exciting windings, the same magnetic poles are formed on the stator salient poles of each group, the stator salient poles of different groups form paired magnetic poles, and fixed magnetic fields are formed at two ends of the exciting windings and the gaps. The arrangement can change the magnetic field intensity in the stator core simply by controlling the current value of the exciting winding, and obtain larger motor output power and output torque in a very economical mode in a wide rotating speed range.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic view of a stator structure without a connector;

FIG. 2 is a schematic structural view of a stator with a connector;

fig. 3 is a schematic structural view of an inner rotor type electrically excited doubly salient motor;

fig. 4 is a schematic structural view of an outer rotor type electro-magnetic doubly salient motor;

fig. 5 shows a connection structure of the armature winding;

fig. 6 shows a wound form of an excitation winding of a conventional permanent magnet doubly salient motor (a thick solid line in the drawing indicates the excitation winding);

labeled as:

1. a stator core; 11. stator salient poles; 12. a notch; 13. a connecting member;

2. an armature winding;

3. an excitation winding;

4. a stator frame;

5. a rotor;

6. a housing;

7. a motor shaft.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be described in detail below. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. All other embodiments, which can be derived by a person skilled in the art from the examples given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be noted that, unless otherwise specified, "a plurality" means two or more; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood as appropriate to those of ordinary skill in the art.

Example 1:

a stator capable of reducing the span of an electrically excited winding, reducing the cost, and improving the motor efficiency, as shown in FIG. 1, FIG. 2, FIG. 3, FIG. 4, and FIG. 5, is particularly configured as follows:

the stator includes a stator core 1, an armature winding 2, and a field winding 3.

The stator core 1 is provided with a plurality of stator salient poles 11 which are sequentially arranged at equal intervals along the circumferential direction, the stator salient poles 11 are connected through a yoke part, and a winding slot for winding the armature winding 2 is formed between two adjacent stator salient poles 11.

The present embodiment will be described further by taking as an example a case where six stator salient poles 11 are provided. Of course, twelve, eighteen, etc. may be provided in addition to the six stator salient poles 11.

The armature windings 2 are disposed in the winding slots and wound on all the stator salient poles 11 of the stator core 1. The armature windings 2 are connected into a three-phase winding by adopting a star connection structure. The two groups of armature windings 2 are connected in a star shape and then output A, B, C three phases in parallel, the wire ends of each group are connected together as a midpoint through common ends and are not led out, and the wire tails are led out as phase wires.

The yoke part of the stator core 1 is provided with a notch 12 extending along the circumferential direction, the notch 12 penetrates through the yoke part of the stator core 1 in the axial direction, and meanwhile, the notch 12 communicates the inner side and the outer side of the stator core 1 in the radial direction, so that the stator core 1 is disconnected at the notch 12 to form a roughly C-shaped opening structure.

The excitation winding 3 is wound around the inner side and the outer side of the yoke part of the stator core 1 to be wound on the yoke part of the stator core 1, and the winding position of the excitation winding 3 is located between two adjacent stator salient poles 11. The portion of the field winding 3 located inside the stator core 1 is located in the winding slots of the adjacent two stator salient poles 11.

The field winding 3 and the gap 12 are arranged at both end positions in the radial direction of the stator core 1, and therefore, the gap 12 is also located between the other two adjacent stator salient poles 11.

The stator salient poles 11 may be directed to the inner side of the stator core 1 to form an inner rotor motor as shown in fig. 3 with the adapted rotor, or may be directed to the outer side of the stator core 1 to form an outer rotor motor as shown in fig. 4 with the adapted rotor.

Preferably, the stator core 1 is provided with a stator frame 4, and the armature winding 2 is wound on the stator frame 4 and the field winding 3 is wound on the stator frame 4.

In this embodiment, the excitation winding 3 is directly wound at a position between two adjacent stator salient poles 11 on the yoke portion of the stator core 1 without spanning a plurality of stator salient poles, thereby reducing the span of the excitation winding 3. Therefore, the length of the enameled wire in the excitation winding 3 can be reduced through the arrangement, the electric energy loss of the excitation winding 3 is reduced while the cost is reduced, and therefore the motor efficiency can be improved, and the cost is reduced.

The gap 12 is arranged at the yoke part of the stator core 1, so that an unsealed magnetic circuit gap can be formed at the gap, the arrangement positions of the gap 12 and the exciting winding 3 are respectively arranged at two radial end positions of the stator core 1, all stator salient poles 11 on the stator core 1 can be equally divided into two groups, and each group of three stator salient poles 11. When direct current is supplied to the exciting winding 3, the same magnetic poles are formed on the stator salient poles 11 of each group, the stator salient poles 11 of different groups form paired magnetic poles, and fixed magnetic fields are formed at both ends of the exciting winding 3 and the gap 12. Therefore, this arrangement makes it possible to obtain a large motor output and output torque in a wide rotational speed range in a very economical manner simply by changing the magnetic field strength in the stator core 1 by controlling the current value through the field winding 3.

Example 2:

the embodiment is further optimized on the basis of the above embodiment, and in order to further better implement the invention, the following arrangement structure is particularly adopted:

in this embodiment, as shown in fig. 2, the stator core 1 of the stator is provided with a connecting member 13 at the gap 12, the connecting member is made of a material having non-magnetic properties, and thus the connecting member 13 has non-magnetic properties. The shape of the connecting piece 13 is not limited, and it respectively connects both ends of the yoke portion of the stator core 1 at the notch 12, plugs the notch 12 and provides connection for both ends of the yoke portion of the stator core 1 at the notch 12.

In this embodiment, the connecting pieces 13 made of non-magnetic material are arranged at the notches 12 to connect the yoke parts of the stator cores 1 at the two ends of the notches 12 for filling, so that the mechanical structural strength of the stator cores 1 at the notches 12 can be improved, and the whole stator structure is firm.

Example 3:

the present embodiment further provides an electrically excited doubly salient motor based on any of the above embodiments, and particularly adopts the following arrangement structure:

the electro-magnetic doubly salient motor comprises a rotor 5 and a stator, wherein the rotor 5 and the stator are concentrically arranged and can relatively rotate.

The stator core 1 is provided with six stator salient poles 11, and the rotor core of the rotor is provided with four rotor salient poles which are sequentially arranged at equal intervals along the circumferential direction to form a unit motor with 6-4 poles, and of course, the unit motor with 12-8 poles or other pole numbers can be formed according to similar design. Wherein, the stator salient pole 11 of the stator points to the rotor 5 along the radial direction, the rotor salient pole of the rotor 5 also points to the stator along the radial direction, and an air gap is arranged between the stator salient pole 11 and the rotor salient pole.

The rotor 5 and the stator can form a structure as shown in fig. 3 according to the requirement, the rotor 5 is inserted in the stator core 1 of the stator to form an inner rotor motor, the stator is fixed in the shell 6, the rotor 5 is arranged in the shell 6 and is installed in the shell 6 through a motor rotating shaft 7. The rotor 5 and the stator can also form the structure shown in fig. 4 according to the requirement, and the stator iron core 1 of the stator is inserted in the rotor 5 to form an outer rotor motor.

The armature windings 2 are connected into a three-phase winding by adopting a star connection structure. The two groups of armature windings 2 are connected in a star shape and then output A, B, C three phases in parallel, the wire ends of each group are connected together as a midpoint through common ends and are not led out, and the wire ends are led out as phase wires.

As a preferable arrangement of the stator core 1 in the present embodiment, as shown in fig. 1, a portion of the yoke portion of the stator core 1 where the field winding 3 is wound is expanded outward in the radial direction, so that a winding slot between two adjacent stator salient poles 11 is spatially expanded, and the field winding is conveniently wound.

Example 4:

the present embodiment further provides a motor control method based on the above embodiments, and further to better implement the present invention, the following setting structure is particularly adopted:

this motor control method is directed to the electrically excited doubly salient motor in embodiment 3. The electric excitation double salient pole motor can be used as a motor or a generator.

When used as a motor, the motor control method includes: when the rotor 5 of the electric excitation double salient pole motor rotates normally, the magnetic field intensity in the stator iron core 1 is changed by adjusting the current value of the excitation winding 3 of the stator of the electric excitation double salient pole motor, so that the output power and the output torque of the motor are adjusted.

When the motor control method is used as a generator, the motor control method comprises the following steps: when the rotor 5 of the electric excitation double-salient-pole motor rotates normally, the magnetic field intensity in the stator core 1 of the stator of the electric excitation double-salient-pole motor is changed by adjusting the current value of the excitation winding 3 of the stator of the electric excitation double-salient-pole motor, so that the voltage and the current output outwards by the armature winding 2 of the stator of the electric excitation double-salient-pole motor are adjusted.

The invention relates to an electric excitation double salient pole motor which is matched with a controller when in use. The controller is mainly used for controlling the current voltage of the armature winding 2 and the field winding 3. Two groups of armature windings 2 of the electric excitation doubly salient motor are connected in a star shape and then output A, B, C three phases in parallel as shown in fig. 5, the wire ends of each group are connected together as a midpoint through common ends and are not led out, and the wire tail is led out as a phase line.

The six stator salient poles 11 on the stator core 1 are divided into two groups by the gaps 12 and the exciting windings 3, and each group comprises three stator salient poles 11. When the excitation winding 3 is controlled by the controller to be electrified with direct current, current forms fixed magnetic fields at two sides of a gap 12 between the excitation winding 3 and a yoke part of the stator core 1, one of two groups of stator salient poles 11 at two sides of the gap 12 forms an N magnetic pole or an S magnetic pole, and the other group forms a matched S magnetic pole or an N magnetic pole.

An electrically excited doubly salient machine can be used as an electric motor.

When a voltage is applied to two of the terminals of the three-phase winding, current is actually passed through two of the coils, one of which is positive and one of which is negative. A positive current causes an increasing effect on the magnetic field on the corresponding stator salient pole 11, and a negative current causes a decreasing effect on the magnetic field on the corresponding stator salient pole 11. Thus, when voltage is applied according to a specific sequence, the magnetic fields of the armature winding 2 and the field winding 3 on the stator salient poles 11 are superposed, so that the magnetic field of the stator salient poles 11 in front of the rotor salient poles is enhanced along the rotation direction of the rotor, the magnetic field of the stator salient poles 11 opposite to the rotor salient poles is weakened, and magnetic field torque and reluctance torque are generated between the rotor salient poles and the stator salient poles 11, thereby driving the motor rotating shaft 7 to rotate. For example, when a voltage is applied between the C-phase terminal and the B-phase terminal, the current further increases the magnetic field of the C-phase stator salient pole 11, weakens the magnetic field of the B-phase stator salient pole 11, and the rotor rotates counterclockwise due to the magnetic field torque and the reluctance torque. When the rotor pole rotates to be close to and overlapped with the C-phase stator salient pole 11, voltage is applied between the A-phase terminal and the C-phase terminal, the current further strengthens the magnetic field of the A-phase stator salient pole 11, weakens the magnetic field of the C-phase stator salient pole 11, and the rotor continues to rotate in the counterclockwise direction due to the action of magnetic field torque and reluctance torque. When the rotor pole rotates to be close to coincide with the A-phase stator salient pole 11, voltage is applied between the B-phase terminal and the A-phase terminal, the current further strengthens the magnetic field of the B-phase stator salient pole 11, weakens the magnetic field of the A-phase stator salient pole 11, and the rotor continues to rotate in the counterclockwise direction to complete one electric cycle rotation due to the action of magnetic field torque and reluctance torque. The next electrical cycle continues to energize A, B, C phases in sequence to maintain normal, continuous counterclockwise rotation of the rotor.

Under different rotor rotating speeds, the magnetic field intensity in the stator core 1 can be changed by adopting a motor control method of adjusting the current value of the exciting winding 3 of the stator of the electrically excited doubly salient motor through the controller, and meanwhile, the current in the armature winding 2 is reasonably controlled, so that the output power and the output torque of the motor can be adjusted and obtained in a wide range. The motor control method is similar to a field weakening control method of a permanent magnet brushless direct current motor, can improve the efficiency of the motor, does not cause the increase of cost due to the complex structure as mechanical field weakening, does not cause the decrease of efficiency and the complex algorithm as electronic field weakening, and can be realized only by directly adjusting the exciting current, thereby being more economical than the permanent magnet brushless direct current motor, reducing the cost, further saving energy and reducing consumption particularly under the condition of high rotating speed, and improving the cost performance of the product.

The electro-magnetic double salient pole machine can also be used as a controllable generator.

After the doubly salient electro-magnetic machine is started, when the rotor 5 normally rotates, armature driving current is stopped to be supplied to the armature winding 2, the motor rotating shaft 7 is driven to rotate by other power sources, the armature winding 2 cuts a magnetic induction line to generate counter electromotive force, and current voltage is output outwards through the controller, the voltage and the current of the counter electromotive force can be controlled by adjusting the current value passing through the excitation winding 3, so that the magnetic field intensity in the stator core 1 of the stator of the doubly salient electro-magnetic machine is changed, and the voltage and the current output outwards by the armature winding 2 of the stator of the doubly salient electro-magnetic machine are adjusted.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and the changes or substitutions should be covered within the scope of the present invention.

Claims (10)

1. A stator comprises a stator core (1) and an armature winding (2), wherein the stator core (1) is provided with a plurality of stator salient poles (11) which are sequentially arranged at equal intervals along the circumferential direction, and a winding slot is formed between every two adjacent stator salient poles (11); the armature winding (2) is wound on all stator salient poles (11) of the stator core (1) in the winding slot; the method is characterized in that: also comprises an excitation winding (3);

a gap (12) is formed in a yoke part of the stator core (1), and the gap (12) communicates the inner side and the outer side of the stator core (1) in the radial direction, so that the stator core (1) is disconnected at the gap (12);

the excitation winding (3) is wound on the yoke part of the stator core (1) and is positioned between two adjacent stator salient poles (11);

the excitation winding (3) and the notch (12) are respectively arranged at two end positions of the stator core (1) in the radial direction.

2. A stator according to claim 1, wherein: the armature winding (2) is connected into a three-phase winding by adopting a star connection structure.

3. A stator according to claim 1, wherein: notch (12) department is provided with connecting piece (13) that have non-magnetic permeability, connecting piece (13) are connected respectively the yoke portion of stator core (1) is in both ends of notch (12) department, will notch (12) shutoff.

4. A stator according to claim 1, wherein: stator frame (4) are installed in stator core (1), armature winding (2) twine in on stator frame (4), excitation winding (3) twine in on stator frame (4).

5. A stator according to claim 1, wherein: the stator salient poles (11) are directed to the inside or the outside of the stator core (1).

6. An electro-magnetic doubly salient motor, characterized in that: comprising a rotor (5) and a stator according to any of claims 1-5, said rotor (5) and said stator being concentrically arranged and relatively rotatable; stator salient poles (11) of the stator are directed radially to the rotor (5), and rotor salient poles of the rotor (5) are directed radially to the stator.

7. An electrically excited doubly salient machine according to claim 6, wherein: the rotor (5) is inserted into the stator iron core (1) of the stator.

8. An electrically excited doubly salient machine according to claim 6, characterized in that: and a stator iron core (1) of the stator is inserted into the rotor (5).

9. An electrically excited doubly salient machine according to claim 6, characterized in that: the motor is characterized by further comprising a shell (6), the stator is fixed inside the shell (6), and the rotor (5) is arranged in the shell (6) and is installed on the shell (6) through a motor rotating shaft (7).

10. A motor control method characterized by using the electrically excited doubly salient motor as a motor or a generator for the electrically excited doubly salient motor described in any one of claims 6 to 9;

when used as a motor, the motor control method includes: when a rotor (5) of the electric excitation doubly salient motor rotates normally, the magnetic field intensity in the stator iron core (1) is changed by adjusting the current value of an excitation winding (3) of the stator of the electric excitation doubly salient motor, so that the output power and the output torque of the motor are adjusted;

when used as a generator, the motor control method includes: when a rotor (5) of the electrically excited double-salient-pole motor normally rotates, the current value of an excitation winding (3) of the stator of the electrically excited double-salient-pole motor is adjusted to change the magnetic field intensity in a stator core (1) of the stator of the electrically excited double-salient-pole motor, so that the voltage and the current output outwards by an armature winding (2) of the stator of the electrically excited double-salient-pole motor are adjusted.

Images