CN215419801U - Synchronous motor - Google Patents

Abstract

The present invention provides a synchronous motor, comprising: a housing; the rotating shaft is connected with the machine shell and can rotate relative to the machine shell; the rotor assembly comprises a rotor core, a rotor main winding, a first rotor secondary winding and a second rotor secondary winding, wherein the rotor main winding, the first rotor secondary winding and the second rotor secondary winding are arranged in a rotor groove of the rotor core; the stator assembly comprises a stator core, a stator main winding, a first stator auxiliary winding, a second stator auxiliary winding and a third stator auxiliary winding, wherein the stator main winding, the first stator auxiliary winding, the second stator auxiliary winding and the third stator auxiliary winding are arranged in a stator slot of the stator core, and the stator core is sleeved outside the rotor core and fixedly arranged on the machine shell. According to the utility model, the no-load voltage of the motor is established through the electromagnetic coupling between the main winding and the auxiliary winding, the traditional alternating current exciter is cancelled, the manufacturing and running cost of the motor is reduced, the running reliability of the motor is improved, and the maintenance workload is reduced; meanwhile, the current of the stator secondary winding is regulated through the AVR, so that the voltage of the motor terminal is regulated.

Description

Synchronous motor

Technical Field

The utility model relates to the technical field of motors, in particular to a synchronous motor.

Background

Synchronous motors are a common type of ac motor, as are induction motors (i.e., asynchronous motors). The synchronous motor is a heart of a power system, and is an element which integrates rotation and stillness, electromagnetic change and mechanical movement and realizes conversion of electric energy and mechanical energy. Synchronous machines are divided into synchronous generators and synchronous motors. Alternators in modern power plants are based on synchronous generators.

In the prior art, the conventional synchronous motor is usually excited by an alternating-current exciter and an auxiliary exciter, so that a synchronous motor with three structural forms is formed. Or some synchronous machines eliminate the auxiliary exciter to form two structural forms of synchronous machines, such as third harmonic excitation generators. However, since both of these types of synchronous motors need to rely on an ac exciter, the reliability of the operation of the motor is reduced, the maintenance workload is increased, and the manufacturing and operating costs are increased.

SUMMERY OF THE UTILITY MODEL

Based on the above, the utility model aims to provide a synchronous motor to solve the problems of poor operation reliability, large maintenance workload and high manufacturing and operation cost of the existing synchronous motor.

According to a synchronous machine among embodiments of the present invention, the synchronous machine includes:

a housing;

the rotating shaft is connected with the machine shell and can rotate relative to the machine shell;

the rotor assembly comprises a rotor core, a rotor main winding, a first rotor auxiliary winding and a second rotor auxiliary winding, wherein the rotor core is fixedly arranged on the rotating shaft, and the rotor main winding, the first rotor auxiliary winding and the second rotor auxiliary winding are arranged in a rotor groove formed in the outer wall of the rotor core along the circumferential direction;

the stator assembly comprises a stator core, a stator main winding, a first stator auxiliary winding, a second stator auxiliary winding and a third stator auxiliary winding, wherein the stator core is sleeved outside the rotor core and is fixedly arranged on the machine shell, and the stator main winding, the first stator auxiliary winding, the second stator auxiliary winding and the third stator auxiliary winding are arranged in stator slots formed in the inner wall of the stator core along the circumferential direction;

the first rotor secondary winding and the second rotor secondary winding are electrically connected with the rotor main winding through a rotor rectifying module;

the first stator secondary winding and the second stator secondary winding are electrically connected with the third stator secondary winding through a stator rectifying module, and the stator main winding is connected with a circuit connected with the stator rectifying module and the third stator secondary winding.

Further, the rotor main winding, the first rotor secondary winding and the second rotor secondary winding form a set of rotor windings, and the rotor assembly comprises a plurality of sets of the rotor windings;

and a plurality of groups of rotor slots are formed in the outer wall of the rotor core along the circumferential direction, and each group of rotor slots is correspondingly provided with one group of rotor windings.

Further, each set of rotor slots includes two rotor slots extending in a radial direction of the rotor core;

and the first rotor secondary winding and the second rotor secondary winding are arranged in different stator slots and are positioned on one side of the rotor main winding, which is far away from the rotating shaft.

Further, the stator main winding, the first stator secondary winding, the second stator secondary winding and the third stator secondary winding form a group of stator windings, and the stator assembly comprises a plurality of groups of stator windings;

the inner wall of the stator core is circumferentially provided with a plurality of groups of stator slots, and each group of stator slots is correspondingly provided with a group of stator windings.

Further, each set of stator slots comprises three stator slots, the stator slots extending in a radial direction of the stator core;

and the first stator secondary winding, the second stator secondary winding and the third stator secondary winding are arranged in different stator slots and positioned on one side of the stator main winding, which is far away from the rotating shaft.

Furthermore, an automatic voltage regulator is arranged on a line connecting the stator rectifying module and the third stator secondary winding, and the stator primary winding is connected with the automatic voltage regulator.

Further, the stator main winding is a three-phase winding, a single-phase winding or a multi-phase winding, and the stator main winding is an integer slot winding or a fractional slot winding;

the first stator secondary winding and the second stator secondary winding are three-phase windings, single-phase windings or multi-phase windings, and the third stator secondary winding is a single-phase winding.

Further, the first rotor secondary winding and the second rotor secondary winding are three-phase windings, single-phase windings or multi-phase windings.

Further, the pole pair number of the stator main winding and the pole pair number of the stator auxiliary winding form odd-order multiple relation or even-order multiple relation, and the stator auxiliary winding comprises a first stator auxiliary winding, a second stator auxiliary winding and a third stator auxiliary winding;

the number of pole pairs of the rotor main winding and the number of pole pairs of the rotor auxiliary winding form odd-order multiple relation or even-order multiple relation, and the rotor auxiliary winding comprises the first rotor auxiliary winding and the second rotor auxiliary winding.

Further, the synchronous motor is in a salient pole structure or a non-salient pole structure.

Compared with the prior art: by adding the stator secondary winding and the rotor secondary winding, the no-load voltage of the motor is established through the electromagnetic coupling among the stator main winding, the stator secondary winding, the rotor main winding and the rotor secondary winding, so that the excitation is carried out without the help of an alternating current exciter, the alternating current exciter can be omitted, the manufacturing and running cost of the motor is reduced, the running reliability of the motor is improved, and the maintenance workload is reduced.

Drawings

FIG. 1 is a cross-sectional view of a synchronous machine in accordance with an embodiment of the present invention;

fig. 2 is an electrical wiring diagram of a synchronous motor according to an embodiment of the present invention.

The following detailed description will further illustrate the utility model in conjunction with the above-described figures.

Detailed Description

To facilitate an understanding of the utility model, the utility model will now be described more fully with reference to the accompanying drawings. Several embodiments of the utility model are presented in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the utility model herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Example one

Referring to fig. 1-2, a synchronous motor according to a first embodiment of the present invention is shown, which includes a housing (not shown), a rotating shaft 10 connected to the housing and capable of rotating relative to the housing, a rotor assembly fixedly connected to the rotating shaft 10 and capable of rotating synchronously with the rotating shaft 10, and a stator assembly fixed to the housing and sleeved outside the rotor assembly.

Bearings (not shown) are arranged at two ends of the casing, the rotating shaft 10 penetrates through the casing, and the two ends of the rotating shaft 10 are rotatably connected with the casing through the bearings respectively. Rotor subassembly and stator module all locate the inside of casing to the protection of being received the casing. In specific implementation, the material, shape and the like of the casing are not strictly limited, and the use requirement is met, for example, the casing can be set into a barrel shape.

The rotor assembly comprises a rotor core 6, a rotor main winding 7, a first rotor auxiliary winding 8 and a second rotor auxiliary winding 9, the rotor core 6 is fixedly arranged on a rotating shaft 10, and the rotor main winding 7, the first rotor auxiliary winding 8 and the second rotor auxiliary winding 9 are arranged in a rotor groove formed in the outer wall of the rotor core 6 along the circumferential direction.

In some cases, as shown in fig. 1, the rotor main winding 7, the first rotor secondary winding 8, and the second rotor secondary winding 9 form a set of rotor windings, the rotor assembly includes a plurality of sets of the rotor windings, a plurality of sets of rotor slots are opened on the outer wall of the rotor core 6 along the circumferential direction, and a set of the rotor windings is correspondingly arranged in each set of the rotor slots. More specifically, each set of rotor slots comprises two rotor slots extending in the radial direction of the rotor core 6, a rotor main winding 7 is arranged in each rotor slot, and the first rotor secondary winding 8 and the second rotor secondary winding 9 are arranged in different stator slots and on the side of the rotor main winding 7 away from the rotating shaft 10.

Similarly, the stator assembly comprises a stator core 1, a stator main winding 2, a first stator auxiliary winding 3, a second stator auxiliary winding 4 and a third stator auxiliary winding 5, the stator core 1 is sleeved outside the rotor core 6 and is fixedly arranged on the machine shell, and the stator main winding 2, the first stator auxiliary winding 3, the second stator auxiliary winding 4 and the third stator auxiliary winding 5 are arranged in stator slots formed in the inner wall of the stator core 1 along the circumferential direction.

In some cases of the present embodiment, as shown in fig. 1, the stator main winding 2, the first stator secondary winding 3, the second stator secondary winding 4, and the third stator secondary winding 5 form a set of stator windings, the stator assembly includes a plurality of sets of the stator windings, a plurality of sets of stator slots are opened on the inner wall of the stator core 1 along the circumferential direction, and a set of stator windings is correspondingly disposed in each set of stator slots. More specifically, each group of stator slots comprises three stator slots, each stator slot extends along the radial direction of the stator core 1, a stator main winding 2 is arranged in each stator slot, and the first stator secondary winding 3, the second stator secondary winding 4 and the third stator secondary winding 5 are arranged in different stator slots and are positioned on one side of the stator main winding 2 away from the rotating shaft 10.

In specific implementation, the stator main winding 2 is a three-phase winding, a single-phase winding or a multi-phase winding, and the stator main winding 2 is an integer slot winding or a fractional slot winding. The first stator secondary winding 3 and the second stator secondary winding 4 are three-phase windings, single-phase windings or multi-phase windings, and the third stator secondary winding 5 is a single-phase winding. The first rotor secondary winding 8 and the second rotor secondary winding 9 are three-phase windings, single-phase windings or multi-phase windings. The number of pole pairs of the stator main winding 2 and the number of pole pairs of the stator secondary winding form odd-order multiple relation or even-order multiple relation, and the stator secondary winding comprises a first stator secondary winding 3, a second stator secondary winding 4 and a third stator secondary winding 5. The pole pair number of the rotor main winding 7 and the pole pair number of the rotor secondary winding are in odd multiple relation or even multiple relation, and the rotor secondary winding comprises a first rotor secondary winding 8 and a second rotor secondary winding 9. The synchronous motor is in a salient pole structure or a non-salient pole structure.

In addition, as shown in fig. 2, the first rotor secondary winding 8 and the second rotor secondary winding 9 are electrically connected to the rotor primary winding 7 through a rotor rectifying module. In addition, the first stator secondary winding 3 and the second stator secondary winding 4 are electrically connected to the third stator secondary winding 5 through the stator rectifying module, and the stator main winding 2 is connected to a line connecting the stator rectifying module and the third stator secondary winding 5. The rotor rectifying module and the stator rectifying module can be rectifier diodes.

Further, in some optional cases of this embodiment, an Automatic Voltage Regulator (AVR) is disposed on a line connecting the stator rectification module and the third stator secondary winding 5, and the stator primary winding 2 is connected to the Automatic Voltage Regulator, so as to control an excitation current of the rotor primary winding 7, thereby achieving a purpose of regulating a terminal Voltage of the motor.

The synchronous machine in the present embodiment, when used as a generator, the stator main winding 2 is connected to a load, and when used as a motor, the stator main winding 2 is connected to an external power source. With reference to fig. 2, the specific working principle of the synchronous motor in this embodiment is as follows: when the motor runs in a no-load mode, the rotor core 6 rotates at a synchronous speed, residual magnetism in the motor induces electric potentials in the first stator secondary winding 3 and the second stator secondary winding 4, and current generated by the electric potentials is rectified by the stator rectifying module to form direct current to be supplied to the third stator secondary winding 5. The third stator secondary winding 5 provides a magnetic field to the air gap, so that the first rotor secondary winding 8 and the second rotor secondary winding 9 also induce potential, and the current generated by the induced potential is provided to the rotor main winding 7 after being rectified by the rotor rectifying module, thereby establishing the no-load voltage of the motor and further canceling the alternating current exciter;

in addition, in order to adjust the voltage of the motor terminal, the first stator secondary winding 3 and the second stator secondary winding 4 adjust the current flowing through the third stator secondary winding 5 through AVR, and further control the induced potential of the first rotor secondary winding 8 and the second rotor secondary winding 9, so that the current flowing through the rotor main winding 7 is controlled, and the purpose of adjusting the voltage of the generator terminal is achieved.

Compared with the prior art, the synchronous motor at least has the following advantages:

1. by adding the stator secondary winding and the rotor secondary winding, the no-load voltage of the motor is established through the electromagnetic coupling among the stator main winding, the stator secondary winding, the rotor main winding and the rotor secondary winding, so that the excitation is carried out without the help of an alternating current exciter, the alternating current exciter is further cancelled, a brand-new synchronous motor with a single armature core structure is formed, the manufacturing and running cost of the motor is reduced, the running reliability of the motor is improved, and the maintenance workload is reduced;

2. the current of the stator secondary winding is adjusted through the AVR, so that the voltage of the motor terminal is adjusted.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A synchronous machine, characterized in that it comprises:

a housing;

the rotating shaft is connected with the machine shell and can rotate relative to the machine shell;

the rotor assembly comprises a rotor core, a rotor main winding, a first rotor auxiliary winding and a second rotor auxiliary winding, wherein the rotor core is fixedly arranged on the rotating shaft, and the rotor main winding, the first rotor auxiliary winding and the second rotor auxiliary winding are arranged in a rotor groove formed in the outer wall of the rotor core along the circumferential direction;

the stator assembly comprises a stator core, a stator main winding, a first stator auxiliary winding, a second stator auxiliary winding and a third stator auxiliary winding, wherein the stator core is sleeved outside the rotor core and is fixedly arranged on the machine shell, and the stator main winding, the first stator auxiliary winding, the second stator auxiliary winding and the third stator auxiliary winding are arranged in stator slots formed in the inner wall of the stator core along the circumferential direction;

the first rotor secondary winding and the second rotor secondary winding are electrically connected with the rotor main winding through a rotor rectifying module;

the first stator secondary winding and the second stator secondary winding are electrically connected with the third stator secondary winding through a stator rectifying module, and the stator main winding is connected with a circuit connected with the stator rectifying module and the third stator secondary winding.

2. The synchronous machine of claim 1, wherein the rotor primary winding, the first rotor secondary winding, and the second rotor secondary winding comprise a set of rotor windings, the rotor assembly comprising a plurality of sets of the rotor windings;

and a plurality of groups of rotor slots are formed in the outer wall of the rotor core along the circumferential direction, and each group of rotor slots is correspondingly provided with one group of rotor windings.

3. The synchronous machine according to claim 2, wherein each set of rotor slots includes two rotor slots, the rotor slots extending in a radial direction of the rotor core;

and the first rotor secondary winding and the second rotor secondary winding are arranged in different stator slots and are positioned on one side of the rotor main winding, which is far away from the rotating shaft.

4. The synchronous machine of claim 1, wherein the stator main winding, the first stator secondary winding, the second stator secondary winding, and the third stator secondary winding comprise a set of stator windings, the stator assembly comprising a plurality of sets of the stator windings;

the inner wall of the stator core is circumferentially provided with a plurality of groups of stator slots, and each group of stator slots is correspondingly provided with a group of stator windings.

5. The synchronous machine of claim 4, wherein each set of stator slots comprises three stator slots, the stator slots extending in a radial direction of the stator core;

and the first stator secondary winding, the second stator secondary winding and the third stator secondary winding are arranged in different stator slots and positioned on one side of the stator main winding, which is far away from the rotating shaft.

6. The synchronous machine of any of claims 1-5, wherein an automatic voltage regulator is provided on a line connecting the stator rectifier module and the third stator secondary winding, the stator primary winding being connected to the automatic voltage regulator.

7. The synchronous machine according to any of claims 1-5, wherein the stator main winding is a three-phase winding, a single-phase winding or a multi-phase winding, the stator main winding being an integer slot winding or a fractional slot winding;

the first stator secondary winding and the second stator secondary winding are three-phase windings, single-phase windings or multi-phase windings, and the third stator secondary winding is a single-phase winding.

8. The synchronous machine of any of claims 1-5, wherein the first and second rotor secondary windings are three-phase windings, single-phase windings, or multi-phase windings.

9. The synchronous machine according to any of claims 1-5, wherein the pole pair number of the stator main winding is in odd-order multiple relation or even-order multiple relation with the pole pair number of the stator secondary winding, the stator secondary winding comprises the first stator secondary winding, the second stator secondary winding and the third stator secondary winding;

the number of pole pairs of the rotor main winding and the number of pole pairs of the rotor auxiliary winding form odd-order multiple relation or even-order multiple relation, and the rotor auxiliary winding comprises the first rotor auxiliary winding and the second rotor auxiliary winding.

10. A synchronous machine according to any of claims 1-5, characterized in that the synchronous machine is of salient-pole or non-salient-pole construction.

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