WO2019015031A1

WO2019015031A1 - Electric vehicle, wheel, and switched reluctance motor and current control method therefor

Info

Publication number: WO2019015031A1
Application number: PCT/CN2017/100280
Authority: WO
Inventors: 李铁才; 童恩东; 漆亚梅; 黄国辉
Original assignee: 深圳市配天电机技术有限公司
Priority date: 2017-07-21
Filing date: 2017-09-01
Publication date: 2019-01-24
Also published as: WO2019015094A1; CN207652275U; CN109286350B; CN109286292A; CN207504726U; CN207652276U; CN109286252A; CN109286294A; CN109286350A; CN109286291A; CN207652142U; WO2019015032A1; WO2019015030A1; CN207652274U; WO2019015063A1; CN207652144U; CN207652277U; WO2019015065A1; CN207504745U; CN207504744U

Abstract

An electric vehicle, a wheel and a switched reluctance motor and a current control method therefor. The control method comprises: during the driving period, simultaneously controlling, by means of a controller (23), first switch tubes (V1, V3, V5) and second switch tubes (V2, V4, V6) to be intermittently on; or controlling the first switch tubes (V1, V3, V5) to be continuously on, and controlling the second switch tubes (V2, V4, V6) to be intermittently on, so as to adjust the driving current of windings (111, 112, 113); during the freewheeling period, controlling, by means of the controller (23), the first switch tubes (V1, V3, V5) to be continuously off, and controlling, by means of pulse width modulation, the second switch tubes (V2, V4, V6) to be intermittently on, so as to adjust the freewheeling current of the windings (111, 112, 113); and controlling, according to the sum of currents, the driving current and the freewheeling current, so as to keep the sum of currents to be within a preset range. The current fluctuation of the switched reluctance motor is small, and thus the fluctuation of the torque is small. As the freewheeling current of the previous phase is relatively large but the driving current of a conducting phase is relatively small, the strength of the magnetic field generated by windings of the conducting phase is weak, thus reducing noise.

Description

电动车、车轮、开关磁阻电机及其电流的控制方法Electric vehicle, wheel, switched reluctance motor and current control method thereof

【技术领域】[Technical Field]

本发明涉及电机的技术领域，涉及一种电动车、车轮、开关磁阻电机及其电流的控制方法。The invention relates to the technical field of electric machines, and relates to an electric vehicle, a wheel, a switched reluctance motor and a method for controlling the current thereof.

【背景技术】【Background technique】

发明人在实践中发现，传统开关磁阻电机在转子齿与定子齿对齐时，绕组所产生的电感不变，即电感的变化率为零，此时开关磁阻电机的力矩为零，而力矩需要从零变化到正常值，因此导致开关磁阻电机的力矩波动大。The inventor found in practice that the traditional switched reluctance motor has the same inductance when the rotor teeth are aligned with the stator teeth, that is, the inductance change rate is zero. At this time, the torque of the switched reluctance motor is zero, and the torque It is necessary to change from zero to a normal value, thus causing a large fluctuation in the torque of the switched reluctance motor.

传统开关磁阻电机在转子齿即将开始对上定子齿时，此时转子齿尖和定子齿尖相对，绕组电流较大，所产生的磁场迅速增强，其磁感应线密集拥挤在转子齿尖和定子齿尖上，使铁分子发出噪声，导致传统开关磁阻电机的噪声大。In the conventional switched reluctance motor, when the rotor tooth is about to start to the upper stator tooth, the rotor tooth tip and the stator tooth tip are opposite each other, the winding current is large, and the generated magnetic field is rapidly enhanced, and the magnetic induction line is densely crowded at the rotor tooth tip and the stator. On the tip of the tooth, the iron molecules emit noise, which causes the noise of the conventional switched reluctance motor to be large.

【发明内容】[Summary of the Invention]

为了解决现有技术中的力矩波动大和噪声大的问题，本发明提供一种开关磁阻电机的电流的控制方法，开关磁阻电机以及利用该开关磁阻电机的车轮和电动车。In order to solve the problem of large torque fluctuation and large noise in the prior art, the present invention provides a method for controlling current of a switched reluctance motor, a switched reluctance motor, and a wheel and an electric vehicle using the same.

为解决上述问题，本发明实施例提供了一种开关磁阻电机的电流的控制方法，开关磁阻电机包括定子、开关驱动电路以及电流检测电路，其中所述定子设置有至少三个定子组件，所述至少三个定子组件分别包括绕组，所述电流检测电路用于检测流经所述至少三个定子组件的所述绕组的电流总和，所述开关驱动电路包括控制器以及分别与所述至少三个定子组件对应的至少三个开关模块，每一所述开关模块包括与对应的所述定子组件的绕组串联的第一开关管和第二开关管，所述控制方法包括：In order to solve the above problems, an embodiment of the present invention provides a method for controlling a current of a switched reluctance motor. The switched reluctance motor includes a stator, a switch drive circuit, and a current detecting circuit, wherein the stator is provided with at least three stator components. The at least three stator assemblies each include a winding, the current sensing circuit for detecting a sum of currents flowing through the windings of the at least three stator assemblies, the switch drive circuit including a controller and the at least At least three switch modules corresponding to the three stator assemblies, each of the switch modules includes a first switch tube and a second switch tube connected in series with a winding of the corresponding stator assembly, the control method comprising:

在驱动时段，通过所述控制器同时控制所述第一开关管和第二开关管间歇性导通；或者控制所述第一开关管持续导通，并控制第二开关管间歇性导通，以调节所述绕组的驱动电流的大小；During the driving period, the first switch tube and the second switch tube are simultaneously controlled to be turned on by the controller; or the first switch tube is continuously turned on, and the second switch tube is controlled to be turned on intermittently. To adjust the magnitude of the drive current of the winding;

在续流时段，通过所述控制器控制所述第一开关管持续关闭，并控制第二开关管间歇性导通，以调节所述绕组的续流电流的大小；During the freewheeling period, the first switch tube is continuously turned off by the controller, and the second switch tube is controlled to be turned on intermittently to adjust the magnitude of the freewheeling current of the winding;

根据所述电流总和控制所述驱动电流和所述续流电流，以使所述电流总和保持预设范围。Controlling the drive current and the freewheeling current according to the sum of the currents to sum the currents Keep the preset range.

其中，所述控制方法进一步包括：The control method further includes:

通过所述控制器控制所述至少三个定子组件所对应的所述驱动时段的相位差为2π/N，其中所述N为所述至少三个定子组件的数量。The phase difference of the driving period corresponding to the at least three stator assemblies is controlled by the controller to be 2π/N, wherein the N is the number of the at least three stator components.

通过所述控制器控制所述定子组件的续流时段与下一被驱动的所述定子组件的驱动时段的相位至少部分重叠。The freewheeling period of the stator assembly is controlled by the controller to at least partially overlap the phase of the driving period of the next driven stator assembly.

其中，所述定子组件的续流时段与下一被驱动的所述定子组件的驱动时段的相位至少部分重叠为π/N。Wherein, the freewheeling period of the stator assembly and the phase of the driving period of the next driven stator assembly at least partially overlap to π/N.

其中，在所述驱动时段时，所述驱动时段长为2π/3；在所述续流时段时，所述续流时段长为π/3。Wherein, in the driving period, the driving period is 2π/3; and in the freewheeling period, the freewheeling period is π/3.

为解决上述技术问题，本发还提供一种开关磁阻电机，其包括定子、开关驱动电路以及电流检测电路，其中所述定子设置有至少三个定子组件，所述至少三个定子组件分别包括绕组，所述电流检测电路用于检测流经所述至少三个定子组件的所述绕组的电流总和，所述开关驱动电路包括控制器以及分别与所述至少三个定子组件对应的至少三个开关模块，每一所述开关模块包括与对应的所述定子组件的绕组串联的第一开关管和第二开关管；其中：In order to solve the above technical problem, the present invention also provides a switched reluctance motor including a stator, a switch drive circuit, and a current detecting circuit, wherein the stator is provided with at least three stator assemblies, and the at least three stator assemblies respectively include a winding, the current detecting circuit for detecting a sum of currents flowing through the windings of the at least three stator assemblies, the switch driving circuit including a controller and at least three corresponding to the at least three stator assemblies respectively a switch module, each of the switch modules including a first switch tube and a second switch tube in series with a winding of the corresponding stator assembly; wherein:

在驱动时段，所述控制器同时控制所述第一开关管和第二开关管间歇性导通；或者控制所述第一开关管持续导通，并控制所述第二开关管间歇性导通，以调节所述绕组的驱动电流的大小；During the driving period, the controller simultaneously controls the first switch tube and the second switch tube to be intermittently turned on; or controls the first switch tube to continuously conduct, and controls the second switch tube to be intermittently turned on. To adjust the magnitude of the drive current of the winding;

在续流时段，所述控制器控制所述第一开关管持续关闭，并控制第二开关管间歇性导通，以调节所述绕组的续流电流的大小；During the freewheeling period, the controller controls the first switch tube to continuously turn off, and controls the second switch tube to be intermittently turned on to adjust the magnitude of the freewheeling current of the winding;

所述开关驱动电路进一步根据所述电流总和控制所述驱动电流和所述续流电流，以使所述电流总和保持预设范围The switch drive circuit further controls the drive current and the freewheeling current according to the sum of the currents to maintain the sum of the currents in a preset range

其中，每一所述开关模块进一步包括第一续流二极管和第二续流二极管，其中所述第一开关管的第一连接端连接所述电源的正极、所述第一开关管的第二连接端连接对应的所述定子组件的所述绕组的第一端、所述第二开关管的第一连接端连接对应的所述定子组件的所述绕组的第二端，所述第二开关管的第二连接端连接所述电源的负极，所述第一续流二极管的正极连接对应的所述定子组件的所述绕组的第二端，所述第一续流二极管的负极连接所述电源的正极，所述第二续流二极管的正极连接所述电源的负极，所述第二续流二极管的负极连接对应的所述定子组件的所述绕组的第一端。Each of the switch modules further includes a first freewheeling diode and a second freewheeling diode, wherein a first connection end of the first switch tube is connected to a positive pole of the power source, and a second switch end of the first switch tube a first end of the winding of the corresponding stator assembly and a first end of the second switch tube connected to a second end of the winding of the corresponding stator assembly, the second switch a second connection end of the tube is connected to the negative pole of the power source, a positive pole of the first freewheeling diode is connected to a second end of the winding of the corresponding stator assembly, and a cathode of the first freewheeling diode is connected to the a positive pole of the power source, a positive pole of the second freewheeling diode is connected to a negative pole of the power source, and a cathode of the second freewheeling diode A first end of the winding of the corresponding stator assembly is coupled.

其中，所述控制器控制所述至少三个定子组件所对应的所述驱动时段的相位差为2π/N，其中所述N为所述至少三个定子组件的数量。The controller controls a phase difference of the driving period corresponding to the at least three stator components to be 2π/N, wherein the N is the number of the at least three stator components.

其中，所述控制器控制所述定子组件的续流时段与下一被驱动的所述定子组件的驱动时段的相位至少部分重叠。Wherein the controller controls the freewheeling period of the stator assembly to at least partially overlap with the phase of the driving period of the next driven stator assembly.

其中，所述开关磁阻电机进一步包括转子，所述至少三个定子组件沿所述定子的轴向分段设置，每一所述定子组件进一步分别包括沿所述定子的周向周期性设置且由定子槽彼此间隔的多个定子齿，所述绕组绕设于所述定子齿上，其中所述至少三个定子组件的定子齿沿所述定子的周向依次错开预设角度。Wherein the switched reluctance motor further includes a rotor, the at least three stator assemblies are disposed along an axial segment of the stator, each of the stator assemblies further including a periodic arrangement along a circumference of the stator and A plurality of stator teeth spaced apart from each other by stator slots, the windings being wound around the stator teeth, wherein stator teeth of the at least three stator assemblies are sequentially offset by a predetermined angle along a circumferential direction of the stator.

其中，所述至少三个定子组件的定子齿的数量和宽度相同，所述预定角度为T1/N，其中所述T1为所述定子齿的角度周期，所述N为所述至少三个定子组件的数量。Wherein the number and width of the stator teeth of the at least three stator assemblies are the same, the predetermined angle is T1/N, wherein the T1 is an angular period of the stator teeth, and the N is the at least three stators The number of components.

其中，所述电流检测电路包括具有一开口的环形铁芯以及磁场传感器，所述至少三个定子组件的所述绕组进一步分别绕设于所述环形铁芯上，所述磁场传感器设置于所述环形铁芯的开口处。The current detecting circuit includes a toroidal core having an opening, and the magnetic field sensor, wherein the windings of the at least three stator assemblies are further respectively disposed on the toroidal core, and the magnetic field sensor is disposed on the The opening of the toroidal core.

其中，各所述定子组件的所述绕组在所述环形铁芯上绕设的匝数相同。Wherein, the windings of each of the stator assemblies are wound on the toroidal core with the same number of turns.

其中，所述磁场传感器为线性霍尔电流传感器。Wherein, the magnetic field sensor is a linear Hall current sensor.

为解决上述技术问题，本发还提供一种车轮，车轮采用轮毂电机驱动，所述轮毂电机采用上述实施例中任一项所述开关磁阻电机结构。In order to solve the above technical problem, the present invention also provides a wheel, the wheel is driven by a hub motor, and the hub motor adopts the switched reluctance motor structure according to any one of the above embodiments.

为解决上述技术问题，本发还提供一种电动车，所述电动车为纯电动或混合动力车，所述电动车采用上述实施例中任一项所述开关磁阻电机结构。In order to solve the above technical problem, the present invention further provides an electric vehicle, which is a pure electric or hybrid vehicle, and the electric vehicle adopts the switched reluctance motor structure according to any one of the above embodiments.

与现有技术相比，在驱动时段，通过控制器同时控制第一开关管和第二开关管间歇性导通；或者控制第一开关管持续导通，并控制第二开关管间歇性导通，以调节绕组的驱动电流的大小；在续流时段，通过控制器控制第一开关管持续关闭，并以脉宽调制方式控制第二开关管间歇性导通，以调节绕组的续流电流的大小；根据电流总和控制驱动电流和续流电流，以使电流总和保持预设范围；由于前一相在续流时段，导通相在驱动时段，续流电流和驱动电流之和保持恒定，因此开关磁阻电机的电流波动小，进而力矩的波动小；由于前一相的续流电流较大，而导通相的驱动电流较小，因此导通相的绕组所产生的磁场强度弱，进而减小噪声。Compared with the prior art, during the driving period, the first switch tube and the second switch tube are simultaneously controlled to be turned on by the controller; or the first switch tube is continuously turned on, and the second switch tube is controlled to be intermittently turned on. To adjust the driving current of the winding; during the freewheeling period, the first switching tube is continuously turned off by the controller, and the second switching tube is intermittently turned on in a pulse width modulation manner to adjust the freewheeling current of the winding. Size; control the drive current and freewheeling current according to the sum of the currents, so that the sum of the currents maintains the preset range; since the previous phase is in the freewheeling period, the conduction phase is in the driving period, the sum of the freewheeling current and the driving current Keeping constant, the current fluctuation of the switched reluctance motor is small, and the fluctuation of the torque is small; since the freewheeling current of the previous phase is large and the driving current of the conducting phase is small, the magnetic field generated by the winding of the conducting phase The intensity is weak, which in turn reduces noise.

【附图说明】[Description of the Drawings]

为了更清楚地说明本发明实施例中的技术方案，下面将对实施例描述中所需要采用的附图作简单地介绍，显而易见地，下面描述中的附图仅仅是本发明的一些实施例，对于本领域普通技术人员来讲，在不付出创造性劳动的前提下，还可以根据这些附图获得其他的附图，也属于本发明保护范畴。其中：In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings which are required to be used in the description of the embodiments will be briefly described. It is obvious that the drawings in the following description are only some embodiments of the present invention. It will be apparent to those skilled in the art that other drawings can be obtained from these drawings without departing from the scope of the invention. among them:

图1是本发明第一实施例的开关磁阻电机的立体示意图；1 is a perspective view of a switched reluctance motor according to a first embodiment of the present invention;

图2是图1中开关磁阻电机的分解示意图；Figure 2 is an exploded perspective view of the switched reluctance motor of Figure 1;

图3是外定子内转子的三相开关磁阻电机的立体示意图；3 is a perspective view of a three-phase switched reluctance motor of an outer stator inner rotor;

图4是图1中A相绕组绕设在第一定子齿的结构示意图；4 is a schematic structural view of the A-phase winding of FIG. 1 wound around the first stator teeth;

图5是图1中第一定子齿、第二定子齿和第三定子齿的结构示意图；Figure 5 is a schematic structural view of the first stator tooth, the second stator tooth and the third stator tooth of Figure 1;

图6是图1中转子齿的中心与第一定子齿的中心重合的磁力线示意图；Figure 6 is a magnetic line diagram of the center of the rotor teeth of Figure 1 coincident with the center of the first stator teeth;

图7是图1中第一定子齿与转子槽对齐的结构示意图；Figure 7 is a schematic view showing the structure of the first stator teeth aligned with the rotor slots of Figure 1;

图8是图1中转子齿与第一定子齿位置错开的磁力线示意图；Figure 8 is a schematic view showing the magnetic lines of the rotor teeth of Figure 1 offset from the position of the first stator teeth;

图9是图1中开关磁阻电机正常工作的电感曲线的示意图；9 is a schematic diagram of an inductance curve of the normal operation of the switched reluctance motor of FIG. 1;

图10是开关磁阻电机的转子齿设有削角的结构示意图；10 is a schematic structural view showing a chamfering of a rotor tooth of a switched reluctance motor;

图11是开关驱动电路的电路图；Figure 11 is a circuit diagram of a switch driving circuit;

图12是开关磁阻电机的工作原理的时序图；Figure 12 is a timing chart of the working principle of the switched reluctance motor;

图13是电流检测电路的结构示意图；Figure 13 is a schematic structural view of a current detecting circuit;

图14是本发明第五实施例的开关磁阻电机的工作原理的时序图；Figure 14 is a timing chart showing the operation principle of the switched reluctance motor of the fifth embodiment of the present invention;

图15是位置传感器的结构示意图；Figure 15 is a schematic structural view of a position sensor;

图16是本发明第一实施例的开关磁阻电机的电流的控制方法的流程图。Fig. 16 is a flow chart showing a method of controlling the current of the switched reluctance motor of the first embodiment of the present invention.

【具体实施方式】【Detailed ways】

下面结合附图和实施例，对本发明作进一步的详细描述。特别指出的是，以下实施例仅用于说明本发明，但不对本发明的范围进行限定。同样的，以下实施例仅为本发明的部分实施例而非全部实施例，本领域普通技术人员在没有作出创造性劳动前提下所获得的所有其它实施例，都属于本发明保护的范围。 The present invention will be further described in detail below with reference to the accompanying drawings and embodiments. In particular, the following examples are merely illustrative of the invention, but are not intended to limit the scope of the invention. Also, the following embodiments are only some of the embodiments of the present invention, and not all of the embodiments, and all other embodiments obtained by those skilled in the art without creative efforts are within the scope of the present invention.

本发明的说明书和权利要求书及上述附图中的术语“第一”、“第二”、“第三”“第四”等(如果存在)是用于区别类似的对象，而不必用于描述特定的顺序或先后次序。应该理解这样使用的数据在适当情况下可以互换，以便这里描述的本发明的实施例例如能够以除了在这里图示或描述的那些以外的顺序实施。此外，术语“包括”和“具有”以及他们的任何变形，意图在于覆盖不排他的包含，例如，包含了一系列步骤或单元的过程、方法、***、产品或设备不必限于清楚地列出的那些步骤或单元，而是可包括没有清楚地列出的或对于这些过程、方法、产品或设备固有的其它步骤或单元。The terms "first", "second", "third", "fourth", etc. (if present) in the specification and claims of the present invention and the above figures are used to distinguish similar objects without being used for Describe a specific order or order. It is to be understood that the data so used may be interchanged as appropriate, such that the embodiments of the invention described herein can be implemented, for example, in a sequence other than those illustrated or described herein. In addition, the terms "comprises" and "comprises" and "the" and "the" are intended to cover a non-exclusive inclusion, for example, a process, method, system, product, or device that comprises a series of steps or units is not necessarily limited to Those steps or units may include other steps or units not explicitly listed or inherent to such processes, methods, products or devices.

如图1-2所示，本发明提供第一实施例的开关磁阻电机，该开关磁阻电机10包括定子11和转子12，其中定子11沿轴向分段设置有至少三个定子组件，每一定子组件包括沿定子11的周向周期性设置且由定子槽彼此间隔的多个定子齿以及绕设在定子齿上的绕组，即多个定子齿沿着定子11的周向周期性设置，并且与多个定子槽彼此间隔。As shown in FIG. 1-2, the present invention provides a switched reluctance motor of a first embodiment, the switched reluctance motor 10 comprising a stator 11 and a rotor 12, wherein the stator 11 is provided with at least three stator assemblies in an axial section. Each of the stator assemblies includes a plurality of stator teeth periodically disposed in the circumferential direction of the stator 11 and spaced apart from each other by the stator slots, and windings wound around the stator teeth, that is, a plurality of stator teeth are periodically arranged along the circumference of the stator 11. And spaced apart from each other by a plurality of stator slots.

举例来说，本实施例的开关磁阻电机具体可为三相开关磁阻电机，该三相开关磁阻电机可为外转子内定子的三相开关磁阻电机。如图2所示，定子11沿轴向分段设置有三个定子组件，分别为A相定子组件111、B相定子组件112和C相定子组件113。在其他实施例中，开关磁阻电机可为外定子内转子的三相开关磁阻电机30，如图3所示。For example, the switched reluctance motor of the embodiment may be a three-phase switched reluctance motor, and the three-phase switched reluctance motor may be a three-phase switched reluctance motor of an outer rotor inner stator. As shown in FIG. 2, the stator 11 is provided with three stator assemblies in the axial direction, which are an A-phase stator assembly 111, a B-phase stator assembly 112, and a C-phase stator assembly 113, respectively. In other embodiments, the switched reluctance machine can be a three-phase switched reluctance motor 30 of the outer stator inner rotor, as shown in FIG.

如图2所示，A相定子组件111包括多个第一定子齿131，多个第一定子齿131与多个第一定子槽134彼此间隔。如图4所示，A相定子组件111进一步包括绕设在第一定子齿131上的A相绕组137，在A相绕组137施加驱动电流时，A相绕组137会产生磁极，进而形成磁场。As shown in FIG. 2, the A-phase stator assembly 111 includes a plurality of first stator teeth 131, and the plurality of first stator teeth 131 and the plurality of first stator slots 134 are spaced apart from each other. As shown in FIG. 4, the A-phase stator assembly 111 further includes an A-phase winding 137 wound around the first stator tooth 131. When the A-phase winding 137 applies a driving current, the A-phase winding 137 generates a magnetic pole to form a magnetic field. .

B相定子组件112包括多个第二定子齿132和绕设在第二定子齿132上的B相绕组，多个第二定子齿132与多个第二定子槽135彼此间隔；C相定子组件113包括多个第三定子齿133和绕设在第三定子齿133上的C相绕组，多个第三定子齿133与多个第三定子槽136彼此间隔。其中，B相绕组绕设在第二定子齿132上和C相绕组绕设在第三定子齿133上与A相绕组137绕设在第一定子齿131上的结构相同，不再赘述。The B-phase stator assembly 112 includes a plurality of second stator teeth 132 and a B-phase winding wound around the second stator teeth 132. The plurality of second stator teeth 132 and the plurality of second stator slots 135 are spaced apart from each other; the C-phase stator assembly 113 includes a plurality of third stator teeth 133 and a C-phase winding wound around the third stator teeth 133, the plurality of third stator teeth 133 being spaced apart from the plurality of third stator slots 136. The B-phase winding is wound around the second stator tooth 132, and the C-phase winding is wound around the third stator tooth 133 and the A-phase winding 137 is wound around the first stator tooth 131, and details are not described herein.

至少三个定子组件的定子齿沿着定子11的周向依次错开预设角度，以使得转子12能够在依次施加于至少三个定子组件的绕组上驱动电流所产生的磁场的作用下连续转动，即在至少三个定子组件的绕组上依次施加驱动电流，转子12 在绕组所产生的磁场的作用下连续转动。具体地，第二定子齿132和第一定子齿131沿着定子的周向依次错开预设角度，第三定子齿133和第二定子齿132沿着定子的周向依次错开预设角度；当A相定子组件111、B相定子组件112和C相定子组件113依次施加驱动电流，在A相绕组137产生的磁场、B相绕组产生的磁场和C相绕组产生的磁场的作用下，转子12连续转动。The stator teeth of the at least three stator assemblies are sequentially shifted by a predetermined angle along the circumferential direction of the stator 11 to enable the rotor 12 to continuously rotate under the action of a magnetic field generated by driving currents on the windings of the at least three stator assemblies. That is, driving current is sequentially applied to the windings of at least three stator components, and the rotor 12 Continuous rotation under the action of the magnetic field generated by the winding. Specifically, the second stator teeth 132 and the first stator teeth 131 are sequentially shifted by a predetermined angle along the circumferential direction of the stator, and the third stator teeth 133 and the second stator teeth 132 are sequentially shifted by a predetermined angle along the circumferential direction of the stator; When the A-phase stator assembly 111, the B-phase stator assembly 112, and the C-phase stator assembly 113 sequentially apply a drive current, the magnetic field generated by the A-phase winding 137, the magnetic field generated by the B-phase winding, and the magnetic field generated by the C-phase winding are used to rotate the rotor. 12 continuous rotation.

本实施例的A相定子组件111包括绕设在第一定子齿131上的A相绕组137，B相定子组件112包括绕设在第二定子齿132上的B相绕组，C相定子组件113包括绕设在第三定子齿133上的C相绕组，因此每个定子组件均设置同一相绕组，相对于传统的开关磁阻电机的定子设置多相绕组，由于同一相绕组的匝数比多相绕组的匝数少，因此能够减少A相绕组、B相绕组和C相绕组的匝数，进而降低开关磁阻电机10的铜耗，降低成本。The A-phase stator assembly 111 of the present embodiment includes an A-phase winding 137 wound around a first stator tooth 131, and the B-phase stator assembly 112 includes a B-phase winding wound around a second stator tooth 132, a C-phase stator assembly 113 includes a C-phase winding wound around the third stator tooth 133, so that each stator assembly is provided with the same phase winding, and a multi-phase winding is provided with respect to the stator of the conventional switched reluctance motor, due to the turns ratio of the same phase winding Since the number of turns of the multi-phase winding is small, the number of turns of the A-phase winding, the B-phase winding, and the C-phase winding can be reduced, thereby reducing the copper loss of the switched reluctance motor 10 and reducing the cost.

其中，至少三个定子组件的定子齿的数量和宽度相同，具体地，多个第一定子齿131的数量、多个第二定子齿132的数量和多个第三定子齿133的数量相同，并且第一定子齿131的宽度、第二定子齿132的宽度和第三定子齿133的宽度相同。因此，A相定子组件111、B相定子组件112和C相定子组件113的加工工艺相同。Wherein the number and width of the stator teeth of the at least three stator assemblies are the same, in particular, the number of the plurality of first stator teeth 131, the number of the plurality of second stator teeth 132, and the number of the plurality of third stator teeth 133 are the same And the width of the first stator tooth 131, the width of the second stator tooth 132, and the width of the third stator tooth 133 are the same. Therefore, the machining processes of the A-phase stator assembly 111, the B-phase stator assembly 112, and the C-phase stator assembly 113 are the same.

预设角度可为T1/N，其中T1为定子齿的电角度周期，N为至少三个定子组件的数量。该定子齿的电角度周期为2π/M，其中M为定子齿的数量，即该至少三个定子组件的定子齿沿着定子11的周向依次错开的角度为机械角度。The preset angle may be T1/N, where T1 is the electrical angular period of the stator teeth and N is the number of at least three stator assemblies. The electrical angle period of the stator teeth is 2π/M, where M is the number of stator teeth, that is, the angle at which the stator teeth of the at least three stator assemblies are sequentially displaced along the circumferential direction of the stator 11 is a mechanical angle.

如图5所示，第二定子齿132和第一定子齿131错开的预设角度为T1/N，其中第一定子齿131的角度周期T1为2π/M，N为3，因此第二定子齿132和第一定子齿131错开的角度为2π/3M。例如，第一定子齿131的数量M为6，则第二定子齿132和第一定子齿131错开的预设角度为2π/3M＝20°。由于相邻的两个第一定子齿131之间为一个角度周期，因此第二定子齿132和第一定子齿131错开1/3齿距，相当于第二定子齿132和第一定子齿131错开的电角度为120°，该齿距可为相邻两个第一定子齿131的距离。As shown in FIG. 5, the predetermined angle at which the second stator teeth 132 and the first stator teeth 131 are offset is T1/N, wherein the angular period T1 of the first stator teeth 131 is 2π/M, and N is 3, so The angle between the two stator teeth 132 and the first stator teeth 131 is 2π/3M. For example, the number M of the first stator teeth 131 is 6, and the predetermined angle at which the second stator teeth 132 and the first stator teeth 131 are staggered is 2π/3M=20°. Since the two adjacent first stator teeth 131 are in an angular period, the second stator teeth 132 and the first stator teeth 131 are offset by 1/3 pitch, which is equivalent to the second stator teeth 132 and the first stator. The sub-tooth 131 is offset by an electrical angle of 120°, which may be the distance between two adjacent first stator teeth 131.

此外，第三定子齿133和第二定子齿132错开的预设角度为2π/3M，即第三定子齿133和第二定子齿132错开1/3齿距。第一定子齿131和第三定子齿133错开的预设角度为2π/3M，即第一定子齿131和第三定子齿133错开1/3齿距。In addition, the predetermined angle at which the third stator teeth 133 and the second stator teeth 132 are staggered is 2π/3M, that is, the third stator teeth 133 and the second stator teeth 132 are offset by 1/3 pitch. The predetermined angle at which the first stator tooth 131 and the third stator tooth 133 are staggered is 2π/3M, that is, the first stator tooth 131 and the third stator tooth 133 are offset by 1/3 pitch.

如图2所示，转子12包括沿转子12的周向周期性设置且由转子槽122彼此间隔的多个转子齿121，即多个转子齿121沿着转子12的周向周期性设置，并且与多个转子槽122彼此间隔。转子齿121的数量与定子齿的数量相同，并且转子齿121的宽度小于定子槽的宽度。As shown in FIG. 2, the rotor 12 includes a periodic arrangement along the circumference of the rotor 12 and is provided by the rotor slot 122. The plurality of rotor teeth 121 of this interval, that is, the plurality of rotor teeth 121 are periodically disposed along the circumferential direction of the rotor 12, and are spaced apart from each other by the plurality of rotor slots 122. The number of rotor teeth 121 is the same as the number of stator teeth, and the width of the rotor teeth 121 is smaller than the width of the stator slots.

本实施的转子12可采用一体设置，转子12沿着轴向的长度大于或者等于定子11沿着轴向的长度，该定子11沿着轴向的长度可为A相定子组件111沿着轴向的长度、B相定子组件112沿着轴向的长度以及C相定子组件113沿着轴向的长度之和，以使转子12能够覆盖A相定子组件111、B相定子组件112和C相定子组件113。The rotor 12 of the present embodiment may be integrally provided. The length of the rotor 12 along the axial direction is greater than or equal to the length of the stator 11 along the axial direction. The length of the stator 11 along the axial direction may be the axial direction of the A-phase stator assembly 111. The length, the length of the B-phase stator assembly 112 along the axial direction, and the length of the C-phase stator assembly 113 along the axial direction to enable the rotor 12 to cover the A-phase stator assembly 111, the B-phase stator assembly 112, and the C-phase stator Component 113.

在其他实施例中，转子12可以采用分段设置，例如转子与A相定子组件、B相定子组件和C相定子组件对应设置为三段，三段转子的转子齿沿轴向对齐。In other embodiments, the rotor 12 may be arranged in segments, for example, the rotor is arranged in three segments corresponding to the A-phase stator assembly, the B-phase stator assembly, and the C-phase stator assembly, and the rotor teeth of the three-stage rotor are axially aligned.

其中，转子齿121的数量分别与第一定子齿131的数量、第二定子齿132的数量和第三定子齿133的数量均相同，在转子齿121的中心与第一定子齿131的中心重合时，如图6所示。Wherein, the number of the rotor teeth 121 is the same as the number of the first stator teeth 131, the number of the second stator teeth 132, and the number of the third stator teeth 133, respectively, at the center of the rotor teeth 121 and the first stator teeth 131. When the centers coincide, as shown in Figure 6.

图6是在开关磁阻电机的16个第一定子齿131和16个转子齿121对齐时测量开关磁阻电机的磁力线，该开关磁阻电机的磁场通过磁力线T来表示。由于定子11分段设置A相定子组件111、B相定子组件112和C相定子组件113，因此A相绕组137产生的磁力线T、B相绕组产生的磁力线和C相绕组产生的磁力线互不干扰，即A相绕组137、B相绕组和C相绕组的互感为零。此外，A相绕组137产生的磁力线T不会纠缠交叉，因此A相绕组137的每磁极产生的磁力线T闭合回路位于该磁极的极距内，即A相绕组的每磁极产生的磁力线T不会跨越相邻磁极的中线，传统磁阻电机三相绕组存在互感，通电相的电流会产生互相影响，电枢反应的非线性非常严重，并且产生难以克服的原理性转矩波动，而本发明提供的开关磁阻电机由于每个定子组件是独立的，每个定子组件的绕组都是同一相绕组，所以不存在互感，因此从原理上克服了因互感造成的转矩波动。请参考图6，相对于传统的三相开关磁阻电机的定子组件设置三相绕组，每磁极产生的磁力线必须跨越3个极距，即传统三相开关磁阻电机的任何磁极产生的磁力线回路的长度都是本实施例的每磁极产生的磁力线回路的长度的3倍，磁阻较大，绕组产生的最大电感较小，但本实施例的每磁极产生的磁力线T被约束在该磁极的极距之内，磁阻小，进而A相绕组137产生的电感大。B相绕组和C相绕组在施加驱动电流时所产生的磁力线回路与A相绕组在施加驱动电流时所产生的磁力线T回路相同，不再赘述。 6 is a view showing the magnetic lines of force of the switched reluctance motor when the 16 first stator teeth 131 and the 16 rotor teeth 121 of the switched reluctance motor are aligned, and the magnetic field of the switched reluctance motor is represented by a magnetic line of force T. Since the stator 11 is provided with the A-phase stator assembly 111, the B-phase stator assembly 112, and the C-phase stator assembly 113 in sections, the magnetic lines of the T-phase windings generated by the A-phase windings 137 and the magnetic lines generated by the C-phase windings do not interfere with each other. That is, the mutual inductance of the A-phase winding 137, the B-phase winding, and the C-phase winding is zero. In addition, the magnetic field lines T generated by the A-phase windings 137 are not entangled, so that the magnetic lines of force T generated by each magnetic pole of the A-phase windings 137 are located within the pole pitch of the magnetic poles, that is, the magnetic lines of force T generated by each magnetic pole of the A-phase windings are not Crossing the center line of adjacent magnetic poles, the three-phase windings of the conventional reluctance motor have mutual inductance, the currents of the energized phases may interact with each other, the nonlinearity of the armature reaction is very serious, and the principle torque ripple that is difficult to overcome is generated, and the present invention provides Since the switched reluctance motor is independent of each stator assembly, the windings of each stator assembly are the same phase winding, so there is no mutual inductance, so the torque fluctuation caused by the mutual inductance is overcome in principle. Referring to FIG. 6, a three-phase winding is disposed relative to a stator component of a conventional three-phase switched reluctance motor, and a magnetic line generated by each magnetic pole must span three pole pitches, that is, a magnetic line loop generated by any magnetic pole of a conventional three-phase switched reluctance motor. The length of the magnetic flux loop generated by each magnetic pole of the embodiment is three times, the magnetic resistance is large, and the maximum inductance generated by the winding is small, but the magnetic flux T generated by each magnetic pole of the embodiment is constrained to the magnetic pole. Within the pole pitch, the magnetic resistance is small, and the inductance generated by the A-phase winding 137 is large. The magnetic line circuit generated when the B-phase winding and the C-phase winding are applied with the driving current is the same as the magnetic line T circuit generated when the A-phase winding is applied with the driving current, and will not be described again.

其中，开关磁阻电机的绕组系数的计算公式为：Among them, the calculation formula of the winding coefficient of the switched reluctance motor is:

其中，传统的三相开关磁阻电机可以采用的定子齿数Zd和转子齿数Zz满足：Zz/Zd可以为4/6或8/6；以及整数倍8/12、6/12、12/18、24/18、16/24和32/24等等，根据上述公式可得绕组系数均为0.866。也即由于传统的三相开关磁阻电机的三相沿圆周120°分布，导致绕组系数为0.866。而本实施例的开关磁阻电机10的定子齿数Zd和转子齿数Zz相等，根据上述公式可得绕组系数为1。Among them, the conventional three-phase switched reluctance motor can adopt the stator tooth number Zd and the rotor tooth number Zz to satisfy: Zz/Zd can be 4/6 or 8/6; and integer multiples 8/12, 6/12, 12/18, 24/18, 16/24, 32/24, etc., according to the above formula, the winding coefficient is 0.866. That is, since the three phases of the conventional three-phase switched reluctance motor are distributed along the circumference by 120°, the winding coefficient is 0.866. On the other hand, the number of stator teeth Zd and the number of teeth Zz of the switched reluctance motor 10 of the present embodiment are equal, and the winding coefficient is 1 according to the above formula.

因此，本实施例的开关磁阻电机10属于极距为180°电角度的整距和整数槽电机，该开关磁阻电机10的绕组***为1，相对于传统的三相开关磁阻电机的绕组系数为0.866，本实施例的绕组的利用率提高了1.155倍，实现绕组利用率最大化，进而提高开关磁阻电机10的效率和输出的力矩。Therefore, the switched reluctance motor 10 of the present embodiment belongs to a full-range and integer-slot motor having a pole angle of 180°, and the winding system of the switched reluctance motor 10 is 1, compared with the conventional three-phase switched reluctance motor. The winding coefficient is 0.866, and the utilization ratio of the winding of the present embodiment is increased by 1.155 times, thereby maximizing the utilization of the winding, thereby improving the efficiency of the switched reluctance motor 10 and the torque of the output.

本发明提供第二实施例的开关磁阻电机，用于设置开关磁阻电机的齿槽参数，其在第一实施例的开关磁阻电机基础上进行描述。如图7所示，本实施例定子槽的宽度与定子齿的宽度比为1∶0.95-0.85，定子齿的宽度与转子齿的宽度比为1∶1.05-0.95。The present invention provides a switched reluctance motor of a second embodiment for setting a cogging parameter of a switched reluctance motor, which is described on the basis of the switched reluctance motor of the first embodiment. As shown in Fig. 7, the ratio of the width of the stator slot to the width of the stator teeth in this embodiment is 1:0.95-0.85, and the ratio of the width of the stator teeth to the width of the rotor teeth is 1:1.05-0.95.

以第一定子齿131和转子齿121为例进行说明，如图7所示，第一定子槽134的宽度与第一定子齿131的宽度比可为1∶0.95-0.85，即第一定子齿131的宽度小于第一定子槽134的宽度，进而保证第一定子槽134拥有足够的空间设置A相绕组137。例如：第一定子槽134的宽度与第一定子齿131的宽度比可为1∶0.85；第一定子槽134的宽度与第一定子齿131的宽度比可为1∶0.9；第一定子槽134的宽度与第一定子齿131的宽度比可为1∶0.95。相应地，第二定子槽135的宽度与第二定子齿132的比可为1∶0.95-0.85，第三定子槽136的宽度与第三定子齿133的比可为1∶0.95-0.85。Taking the first stator teeth 131 and the rotor teeth 121 as an example, as shown in FIG. 7, the width ratio of the width of the first stator slot 134 to the width of the first stator teeth 131 may be 1:0.95-0.85, that is, the first The width of the stator teeth 131 is smaller than the width of the first stator slot 134, thereby ensuring that the first stator slot 134 has sufficient space to provide the A-phase winding 137. For example, the ratio of the width of the first stator slot 134 to the width of the first stator teeth 131 may be 1:0.85; the ratio of the width of the first stator slot 134 to the width of the first stator teeth 131 may be 1:0.9; The ratio of the width of the first stator slot 134 to the width of the first stator teeth 131 may be 1:0.95. Correspondingly, the ratio of the width of the second stator slot 135 to the second stator teeth 132 may be 1:0.95-0.85, and the ratio of the width of the third stator slot 136 to the third stator teeth 133 may be 1:0.95-0.85.

第一定子齿131的宽度与转子齿121的宽度比为1∶1.05-0.95。其中，第一定子齿131的宽度与转子齿121的宽度比可为1∶1，即转子齿121的宽度与第一定子齿131的宽度相同，定子齿的宽度与转子齿121的宽度相同。第一定子齿131的宽度与转子齿121的宽度比可为1∶0.95，即转子齿121的宽度小于第一定子齿131的宽度；第一定子齿131的宽度与转子齿121的宽度比可为1∶1.05，即转子齿121的宽度大于第一定子齿131的宽度，并且转子齿121的宽度小于第一定子槽134的宽度。相应地，第二定子齿132的宽度与转子齿121的宽度比为1∶1.05-0.95，第三定子齿的宽度与转子齿121的宽度比为1∶1.05-0.95。The ratio of the width of the first stator teeth 131 to the width of the rotor teeth 121 is 1:1.05-0.95. The ratio of the width of the first stator teeth 131 to the width of the rotor teeth 121 may be 1:1, that is, the width of the rotor teeth 121 is the same as the width of the first stator teeth 131, and the width of the stator teeth and the width of the rotor teeth 121. the same. The ratio of the width of the first stator teeth 131 to the width of the rotor teeth 121 may be 1:0.95, that is, the width of the rotor teeth 121 is smaller than the width of the first stator teeth 131; the width of the first stator teeth 131 and the width of the rotor teeth 121 The width ratio may be 1:1.05, that is, the width of the rotor teeth 121 is larger than the width of the first stator teeth 131, and the width of the rotor teeth 121 is smaller than The width of the first stator slot 134. Correspondingly, the ratio of the width of the second stator teeth 132 to the width of the rotor teeth 121 is 1:1.05-0.95, and the ratio of the width of the third stator teeth to the width of the rotor teeth 121 is 1:1.05-0.95.

本实施例通过设置定子槽的宽度与定子齿的宽度比为1∶0.95-0.85，定子齿的宽度与转子齿的宽度比为1∶1.05-0.95，能够使得开关磁阻电机的电感曲线随着转子齿的位置呈三角波形变化，如图9所示，并且电感曲线的变化率大。In this embodiment, by setting the ratio of the width of the stator slot to the width of the stator teeth of 1:0.95-0.85, the ratio of the width of the stator teeth to the width of the rotor teeth is 1:1.05-0.95, which can make the inductance curve of the switched reluctance motor The position of the rotor teeth changes in a triangular shape as shown in Fig. 9, and the rate of change of the inductance curve is large.

其中，转子12与定子11之间的气隙可为0.1mm～3mm，定子槽的宽度与转子齿121的宽度的差值为气隙的8-12倍，其中定子槽的宽度为定子槽的槽口宽度，转子齿121的宽度为转子齿121顶部的宽度。即第一定子槽134的宽度与转子齿121的宽度的差值为气隙的8-12倍，第二定子槽135的宽度与转子齿121的宽度的差值为气隙的8-12倍，第三定子槽134的宽度与转子齿121的宽度的差值为气隙的8-12倍。Wherein, the air gap between the rotor 12 and the stator 11 may be 0.1 mm to 3 mm, and the difference between the width of the stator slot and the width of the rotor teeth 121 is 8-12 times that of the air gap, wherein the width of the stator slot is the stator slot The slot width, the width of the rotor teeth 121 is the width of the top of the rotor teeth 121. That is, the difference between the width of the first stator slot 134 and the width of the rotor teeth 121 is 8-12 times the air gap, and the difference between the width of the second stator slot 135 and the width of the rotor teeth 121 is 8-12 of the air gap. The difference between the width of the third stator slot 134 and the width of the rotor teeth 121 is 8-12 times the air gap.

更进一步，转子12和定子11之间的气隙为0.15mm～2mm，定子槽的宽度与转子齿121的宽度的差值可为气隙的10倍，即定子槽的宽度比转子齿121的宽度大1.5mm-20mm。其中，第一定子槽134的宽度、第二定子槽135的宽度和第三定子槽134的宽度均比转子齿121的宽度大1.5mm-20mm。Further, the air gap between the rotor 12 and the stator 11 is 0.15 mm to 2 mm, and the difference between the width of the stator slot and the width of the rotor teeth 121 may be 10 times that of the air gap, that is, the width of the stator slot is larger than that of the rotor teeth 121. The width is 1.5mm-20mm. The width of the first stator slot 134, the width of the second stator slot 135, and the width of the third stator slot 134 are both greater than the width of the rotor teeth 121 by 1.5 mm to 20 mm.

本实施所揭示的气隙可以为1mm，此时定子槽的宽度比转子齿121的宽度大10mm。The air gap disclosed in the present embodiment may be 1 mm, in which case the width of the stator slot is 10 mm larger than the width of the rotor tooth 121.

请进一步参见图8，图8是在开关磁阻电机的16个第一定子齿131和16个转子齿121位置错开时测量开关磁阻电机的磁力线，此时第一定子槽134尚未与转子齿121完全对齐，由于第一定子槽134和转子齿121之间的间隙较大，例如第一定子槽134的宽度比转子齿121的宽度大10mm。由于磁力线T不会纠缠交叉，并且在受到相邻的磁力线的挤压作用，该磁力线T只能通过当前第一定子槽134和转子齿121之间的间隙形成闭合回路，而该间隙非常大，因此磁阻大，导致A相绕组137产生的电感小。在第一定子槽134与转子齿121完全对齐时，无法检测到磁力线T。Please refer to FIG. 8 again. FIG. 8 is a measurement of the magnetic lines of force of the switched reluctance motor when the positions of the 16 first stator teeth 131 and the 16 rotor teeth 121 of the switched reluctance motor are staggered. At this time, the first stator slot 134 has not been The rotor teeth 121 are perfectly aligned, and since the gap between the first stator slots 134 and the rotor teeth 121 is large, for example, the width of the first stator slots 134 is 10 mm larger than the width of the rotor teeth 121. Since the magnetic force lines T do not entangle and cross, and are subjected to the pressing action of the adjacent magnetic lines of force, the magnetic lines of force T can only form a closed loop through the gap between the current first stator slot 134 and the rotor teeth 121, and the gap is very large. Therefore, the magnetic resistance is large, resulting in a small inductance generated by the A-phase winding 137. When the first stator slot 134 is completely aligned with the rotor teeth 121, the magnetic field lines T cannot be detected.

本实施例的开关磁阻电机在正常工作时，A相定子组件的电感曲线如图9所示，该电感曲线呈三角波形变化。在转子齿121的中心与第一定子槽134的中心重合，即对应于第一电角度a1时，A相绕组产生的电感最小；在转子齿121的中心与第一定子齿131的中心重合，即对应于第二电角度a2时，A相绕组产生的电感最大，电感比可以达到21.25，而传统的三相开关磁阻电机的电感比只能达到2.5-4.5左右。由于开关磁阻电机的输出力矩

电感比高意味

大，电机的输出力矩就大，也即提高了电机的功率密度。When the switched reluctance motor of the embodiment is in normal operation, the inductance curve of the A-phase stator assembly is as shown in FIG. 9, and the inductance curve changes in a triangular waveform. When the center of the rotor tooth 121 coincides with the center of the first stator slot 134, that is, corresponding to the first electrical angle a1, the inductance generated by the A-phase winding is the smallest; at the center of the rotor tooth 121 and the center of the first stator tooth 131 Coincidence, that is, corresponding to the second electrical angle a2, the inductance of the A-phase winding is the largest, and the inductance ratio can reach 21.25, while the inductance ratio of the conventional three-phase switched reluctance motor can only reach 2.5-4.5. Due to the output torque of the switched reluctance motor

Inductance ratio is high

Large, the output torque of the motor is large, which increases the power density of the motor.

本实施例的定子齿的数量可为奇数，即第一定子齿131和第一定子槽134的总数为2N，其中N为自然数。因此第一定子齿131的数量和第一定子槽134的数量均可为奇数，能够避免齿谐波的自然谐振，例如第一定子齿131的数量为3，第一定子槽134的数量为3。相对比传统开关磁阻电机的定子齿的数量为偶数个，本实施例的开关磁阻电机能够根据不同的转速和不同力矩选择第一定子齿131的数量和第一定子槽134的数量，能够适应不同的场合，提高开关磁阻电机的实用性。The number of stator teeth of this embodiment may be an odd number, that is, the total number of first stator teeth 131 and first stator slots 134 is 2N, where N is a natural number. Therefore, the number of first stator teeth 131 and the number of first stator slots 134 can be odd, and natural resonance of the tooth harmonics can be avoided. For example, the number of first stator teeth 131 is three, and the first stator slot 134 The number is 3. Compared with the number of stator teeth of the conventional switched reluctance motor, the switched reluctance motor of the embodiment can select the number of the first stator teeth 131 and the number of the first stator slots 134 according to different rotation speeds and different moments. It can adapt to different occasions and improve the practicability of the switched reluctance motor.

本发明提供第三实施例的开关磁阻电机，其在第二实施例的开关磁阻电机的基础上进行描述。如图10所示，本实施例中的转子齿121的齿尖设置有一削角123，削角123可以为弧形削角，该削角123的深度D小于0.8mm，削角123的长度L小于转子齿121的宽度；具体地，削角123的长度L小于转子齿121的宽度的1/3，能够大幅度减小电机的噪声。在其他实施例中，转子齿121的齿尖还可以设置为倒角，其中倒角的半径小于1mm。The present invention provides a switched reluctance motor of a third embodiment, which is described on the basis of the switched reluctance motor of the second embodiment. As shown in FIG. 10, the tooth tip of the rotor tooth 121 in this embodiment is provided with a chamfer 123, and the chamfer 123 may be an arc chamfer having a depth D of less than 0.8 mm and a length L of the chamfer 123. It is smaller than the width of the rotor tooth 121; specifically, the length L of the chamfer 123 is smaller than 1/3 of the width of the rotor tooth 121, and the noise of the motor can be greatly reduced. In other embodiments, the tip of the rotor tooth 121 can also be configured as a chamfer with a radius of chamfer less than 1 mm.

本实施例的第一定子齿131、第二定子齿132和第三定子齿的齿尖结构与上述转子齿121的齿尖结构相同，不再赘述。The tip structure of the first stator tooth 131, the second stator tooth 132, and the third stator tooth of the present embodiment is the same as the tip structure of the rotor tooth 121, and will not be described again.

本发明提供第四实施例的开关磁阻电机，其在第一实施例的开关磁阻电机的基础上进行描述。如图11所示，开关磁阻电机进一步包括开关驱动电路21，开关驱动电路21连接直流电源Us和至少三个定子组件的绕组上，即开关驱动电路21连接直流电源Us、A相绕组、B相绕组和C相绕组上。The present invention provides a switched reluctance motor of a fourth embodiment, which is described on the basis of the switched reluctance motor of the first embodiment. As shown in FIG. 11, the switched reluctance motor further includes a switch drive circuit 21 connected to the DC power source Us and the windings of at least three stator components, that is, the switch drive circuit 21 is connected to the DC power source Us, the A phase winding, and B. Phase winding and phase C winding.

开关驱动电路21用于周期性依次在至少三个定子组件所对应的驱动阶段相绕组上施加驱动电流，至少三个定子组件的驱动时段的相位彼此错开，即在A相定子组件111的驱动阶段，开关驱动电路21在A相定子组件111施加驱动电流；在B相定子组件112的驱动阶段，开关驱动电路21在B相定子组件112施加驱动电流；在C相定子组件113的驱动阶段，开关驱动电路21在C相定子组件113施加驱动电流。相应地，A相定子组件111、B相定子组件112和C相定子组件113的驱动时段的相位彼此错开。The switch driving circuit 21 is configured to periodically apply driving currents to the driving phase windings corresponding to the at least three stator components, and the phases of the driving periods of the at least three stator components are shifted from each other, that is, in the driving phase of the A-phase stator assembly 111. The switch drive circuit 21 applies a drive current to the A-phase stator assembly 111; during the drive phase of the B-phase stator assembly 112, the switch drive circuit 21 applies a drive current to the B-phase stator assembly 112; during the drive phase of the C-phase stator assembly 113, the switch The drive circuit 21 applies a drive current to the C-phase stator assembly 113. Accordingly, the phases of the driving periods of the A-phase stator assembly 111, the B-phase stator assembly 112, and the C-phase stator assembly 113 are shifted from each other.

其中，开关驱动电路21进一步在至少三个定子组件对应的驱动时段后续的续流时段释放至少三个定子组件的绕组上存储的能量，以形成续流电流。即在A相定子组件111的驱动时段后续的续流时段，开关驱动电路21用于释放A相绕组上存储的能量，形成A相绕组的续流电流；在B相定子组件112的驱动时段后续的续流时段，开关驱动电路21用于释放B相绕组上存储的能量，形成B相绕组的续流电流；在C相定子组件113的驱动时段后续的续流时段，开关驱动电路21用于释放C相绕组上存储的能量，形成C相绕组的续流电流。Wherein, the switch drive circuit 21 further releases the energy stored on the windings of the at least three stator assemblies during a subsequent freewheeling period of the drive period corresponding to the at least three stator assemblies to form a freewheeling current. That is, in the freewheeling period subsequent to the driving period of the A-phase stator assembly 111, the switch driving circuit 21 is for releasing the energy stored in the A-phase winding to form a freewheeling current of the A-phase winding; during the driving period of the B-phase stator assembly 112. In the subsequent freewheeling period, the switch driving circuit 21 is configured to release the energy stored in the B-phase winding to form a freewheeling current of the B-phase winding; and in the subsequent freewheeling period of the driving period of the C-phase stator assembly 113, the switch driving circuit 21 uses The energy stored on the phase C winding is released to form a freewheeling current of the phase C winding.

开关驱动电路21包括控制器23以及分别与至少三个定子组件对应的至少三个开关模块，每一开关模块分别包括第一开关管、第二开关管、第一续流二极管和第二续流二极管，其中第一开关管的第一连接端连接电源的正极、第一开关管的第二连接端连接对应的定子组件的绕组的第一端、第二开关管的第一连接端连接对应的定子组件的绕组的第二端，第二开关管的第二连接端连接电源的负极，第一续流二极管的正极连接对应的定子组件的绕组的第二端，第一续流二极管的负极连接电源的正极，第二续流二极管的正极连接电源的负极，第二续流二极管的负极连接对应的定子组件的绕组的第一端。其中，第一开关管和第二开关管与对应的定子组件的绕组串联连接。The switch drive circuit 21 includes a controller 23 and at least three switch modules respectively corresponding to at least three stator assemblies, each switch module including a first switch tube, a second switch tube, a first freewheeling diode, and a second freewheeling a diode, wherein a first connection end of the first switch tube is connected to the positive pole of the power source, a second connection end of the first switch tube is connected to the first end of the winding of the corresponding stator assembly, and the first connection end of the second switch tube is connected to the corresponding a second end of the winding of the stator assembly, a second connection end of the second switch tube is connected to the negative pole of the power supply, a positive end of the first freewheeling diode is connected to a second end of the winding of the corresponding stator assembly, and a negative connection of the first freewheeling diode The anode of the power source, the anode of the second freewheeling diode is connected to the cathode of the power supply, and the cathode of the second freewheeling diode is connected to the first end of the winding of the corresponding stator assembly. The first switch tube and the second switch tube are connected in series with the windings of the corresponding stator assembly.

具体地，开关驱动电路21包括控制器23、与A相定子组件111对应的第一开关模块24、与B相定子组件112对应的第二开关模块25以及与C相定子组件113对应的第三开关模块26。第一开关模块24包括第一开关管V1、第二开关管V2、第一续流二极管D1和第二续流二极管D2，第二开关模块25包括第一开关管V3、第二开关管V4、第一续流二极管D3和第二续流二极管D4，第三开关模块26包括第一开关管V5、第二开关管V6、第一续流二极管D5和第二续流二极管D6。Specifically, the switch drive circuit 21 includes a controller 23, a first switch module 24 corresponding to the A-phase stator assembly 111, a second switch module 25 corresponding to the B-phase stator assembly 112, and a third corresponding to the C-phase stator assembly 113. Switch module 26. The first switch module 24 includes a first switch tube V1, a second switch tube V2, a first freewheeling diode D1, and a second freewheeling diode D2. The second switch module 25 includes a first switch tube V3 and a second switch tube V4. The first freewheeling diode D3 and the second freewheeling diode D4, the third switching module 26 includes a first switching transistor V5, a second switching transistor V6, a first freewheeling diode D5 and a second freewheeling diode D6.

其中，至少三个定子组件所对应的驱动时段的相位差为2π/N，其中N为至少三个定子组件的数量。A相定子组件111的驱动时段和B相定子组件112的驱动时段的相位差为2π/3，即电角度120°，B相定子组件112的驱动时段和C相定子组件113的驱动时段的相位差为电角度120°。Wherein, the phase difference of the driving period corresponding to the at least three stator components is 2π/N, where N is the number of at least three stator components. The phase difference between the driving period of the A-phase stator assembly 111 and the driving period of the B-phase stator assembly 112 is 2π/3, that is, the electrical angle 120°, the driving period of the B-phase stator assembly 112 and the phase of the driving period of the C-phase stator assembly 113. The difference is an electrical angle of 120°.

如图12所示，本实施例A相定子组件111的驱动时段为电角度0°-120°，A相定子组件111的续流时段为电角度120°-180°；B相定子组件112的驱动时段为电角度120°-240°，B相定子组件112的续流时段为电角度240°-300°；C相定子组件113的驱动时段为电角度240°-360°，C相定子组件113的续流时段为电角度360°-420°。其中，各定子组件的续流时段与下一被驱动的定子组件的驱动时段的相位至少部分重叠，即A相定子组件111的续流时段与B相定子组件112的驱动时段的相位部分重叠为120°-180°，B相定子组件112的续流时段与C相定子组件113的驱动时段的相位部分重叠为240°-300°。 As shown in FIG. 12, the driving period of the phase A stator assembly 111 of the present embodiment is an electrical angle of 0°-120°, and the freewheeling period of the phase A stator assembly 111 is an electrical angle of 120°-180°; the phase B stator assembly 112 The driving period is an electrical angle of 120°-240°, the freewheeling period of the B-phase stator assembly 112 is an electrical angle of 240°-300°, and the driving period of the C-phase stator assembly 113 is an electrical angle of 240°-360°, the C-phase stator assembly. The freewheeling period of 113 is an electrical angle of 360°-420°. Wherein, the freewheeling period of each stator assembly at least partially overlaps with the phase of the driving period of the next driven stator assembly, that is, the phase of the freewheeling period of the A-phase stator assembly 111 and the driving period of the B-phase stator assembly 112 partially overlaps 120°-180°, the freewheeling period of the B-phase stator assembly 112 partially overlaps with the phase of the driving period of the C-phase stator assembly 113 by 240°-300°.

在驱动时段，控制器23以脉宽调制方式同时控制第一开关管和第二开关管间歇性导通，由此调节驱动电流的大小。该脉宽调制方式可为PWM(Pulse Width Modulation，脉冲宽度调制)信号，在A相定子组件111的驱动时段时，控制器23通过PWM信号同时控制第一开关管V1和第二开关管V2导通或者关闭。控制器23在A相绕组产生的电感最小时发送PWM信号至第一开关管V1和第二开关管V2；在第一开关管V1和第二开关管V2同时导通时，直流电源Us在A相定子组件111施加驱动电流；在第一开关管V1和第二开关管V2同时关闭时，直流电源Us停止在A相定子组件111施加驱动电流，能够避免驱动电流过大。控制器23在A相绕组产生的电感最大时停止发送PWM信号至第一开关管V1，第一开关管V1关闭，A相定子组件111进入续流时段。在其他实施例，脉宽调制方式可以采用正弦波信号。During the driving period, the controller 23 simultaneously controls the first switching transistor and the second switching transistor to be intermittently turned on in a pulse width modulation manner, thereby adjusting the magnitude of the driving current. The pulse width modulation mode may be a PWM (Pulse Width Modulation) signal. During the driving period of the A-phase stator component 111, the controller 23 simultaneously controls the first switching transistor V1 and the second switching transistor V2 through the PWM signal. Pass or close. The controller 23 sends a PWM signal to the first switching transistor V1 and the second switching transistor V2 when the inductance generated by the A-phase winding is minimum; when the first switching transistor V1 and the second switching transistor V2 are simultaneously turned on, the DC power source Us is at A The phase stator assembly 111 applies a drive current; when the first switch tube V1 and the second switch tube V2 are simultaneously turned off, the DC power source Us stops applying a drive current to the A-phase stator assembly 111, thereby avoiding excessive drive current. The controller 23 stops transmitting the PWM signal to the first switching transistor V1 when the inductance generated by the A-phase winding is maximum, the first switching transistor V1 is turned off, and the A-phase stator assembly 111 enters the freewheeling period. In other embodiments, the pulse width modulation method may employ a sine wave signal.

在续流时段，控制器23控制第一开关管持续关闭，并以脉宽调制方式控制第二开关管间歇性导通，由此调节续流电流的大小。在A相定子组件111的续流时段时，控制器23可以控制直流电源Us停止工作，A相绕组、第二开关V2和第二续流二极管D2形成回路，进而释放A相绕组上存储的能量。控制器23通过PWM信号控制第二开关管间歇性导通，以调节A相绕组的续流电流的大小。During the freewheeling period, the controller 23 controls the first switching tube to continuously turn off, and controls the second switching tube to be intermittently turned on in a pulse width modulation manner, thereby adjusting the magnitude of the freewheeling current. During the freewheeling period of the A-phase stator assembly 111, the controller 23 can control the DC power supply Us to stop working, and the A-phase winding, the second switch V2, and the second freewheeling diode D2 form a loop, thereby releasing the energy stored in the A-phase winding. . The controller 23 controls the second switching tube to be intermittently turned on by the PWM signal to adjust the magnitude of the freewheeling current of the A-phase winding.

如图13所示，开关磁阻电机进一步包括与开关驱动电路21连接的电流检测电路27，该电流检测电路27用于检测流经至少三个定子组件的绕组的电流总和，即电流检测电路27用于检测流经A相绕组、B相绕组以及C相绕组的电流总和，电流总和为i＝ia+ib+ic，ia为流经A相绕组的电流，ib为流经B相绕组的电流，ic为流经C相绕组的电流。As shown in FIG. 13, the switched reluctance motor further includes a current detecting circuit 27 connected to the switch driving circuit 21 for detecting the sum of currents flowing through the windings of at least three stator assemblies, that is, the current detecting circuit 27 Used to detect the sum of currents flowing through the A-phase winding, the B-phase winding, and the C-phase winding. The sum of the currents is i=ia+ib+ic, ia is the current flowing through the A-phase winding, and ib is the current flowing through the B-phase winding. , ic is the current flowing through the C-phase winding.

电流检测电路27包括具有一开口的环形铁芯271以及磁场传感器272，至少三个定子组件的绕组分别绕设在环形铁芯271上，磁场传感器272设置于环形铁芯271的开口处。其中，环形铁芯271可为C形铁芯，A相绕组、B相绕组以及C相绕组分别绕设在环形铁芯271上，以分别在环形铁芯271上形成线圈L1、线圈L2和线圈L3。各个定子组件的绕组在环形铁芯271上绕设的匝数相同，即线圈L1的匝数、线圈L2的匝数和线圈L3的匝数相同。其中，磁场传感器272可为线性霍尔电流传感器。本实施例的开关磁阻电机仅需要一个磁场传感器272检测流经A相绕组、B相绕组以及C相绕组的电流总和，因此减少传感器数量，降低开关磁阻电机的成本。在其他实施例中，电流检测电路27可以设置为采用磁平衡式电流传感器。The current detecting circuit 27 includes an annular core 271 having an opening and a magnetic field sensor 272, and windings of at least three stator assemblies are respectively wound around the toroidal core 271, and the magnetic field sensor 272 is disposed at the opening of the toroidal core 271. The annular core 271 may be a C-shaped iron core, and the A-phase winding, the B-phase winding, and the C-phase winding are respectively wound around the toroidal core 271 to form a coil L1, a coil L2 and a coil on the toroidal core 271, respectively. L3. The windings of the respective stator assemblies are wound on the toroidal core 271 in the same number of turns, that is, the number of turns of the coil L1, the number of turns of the coil L2, and the number of turns of the coil L3. The magnetic field sensor 272 can be a linear Hall current sensor. The switched reluctance motor of the present embodiment requires only one magnetic field sensor 272 to detect the sum of currents flowing through the A-phase winding, the B-phase winding, and the C-phase winding, thereby reducing the number of sensors and reducing the cost of the switched reluctance motor. In other embodiments, the current detecting circuit 27 can Set to use a magnetically balanced current sensor.

开关驱动电路21根据电流检测电路27所检测的电流总和i分别对各绕组的驱动电流和续流电流进行控制，以使得电流总和保持预设范围。具体地，开关驱动电路21根据电流总和i分别对A相绕组的驱动电流和续流电流、B相绕组的驱动电流和续流电流、C相绕组的驱动电流和续流电流进行控制，以使得电流总和i保持稳定。The switch drive circuit 21 controls the drive current and the freewheeling current of each winding according to the sum i of the currents detected by the current detecting circuit 27, so that the sum of the currents maintains the preset range. Specifically, the switch drive circuit 21 controls the drive current and the freewheeling current of the A-phase winding, the drive current and the freewheeling current of the B-phase winding, the drive current of the C-phase winding, and the freewheeling current according to the current sum i, respectively, so that The sum of currents i remains stable.

在A绕组的续流时段，控制器23根据电流检测电路27所检测的电流总和i通过PWM信号同时控制第一开关管V3和第二开关管V4导通或者关闭，以直流电源Us在B相定子组件112施加驱动电流，并且电流总和i保持稳定，如图12所示。During the freewheeling period of the A winding, the controller 23 simultaneously controls the first switching transistor V3 and the second switching transistor V4 to be turned on or off according to the sum of the currents detected by the current detecting circuit 27 through the PWM signal, to the DC power source Us in the B phase. The stator assembly 112 applies a drive current and the sum of currents i remains stable, as shown in FIG.

B绕组在驱动时段和续流时段的工作原理和C绕组在驱动时段和续流时段的工作原理与A绕组在驱动时段和续流时段的工作原理相同，不再赘述。The working principle of the B winding in the driving period and the freewheeling period and the working principle of the C winding in the driving period and the freewheeling period are the same as those in the driving period and the freewheeling period of the A winding, and will not be described again.

本实施例的开关驱动电路21根据电流检测电路27所检测的电流总和i分别对各绕组的驱动电流和续流电流进行控制，以使得电流总和保持预设范围，因此本实施的开关磁阻电机具有伺服电机的特性；由于开关磁阻电机的输出力矩稳定，进而降低开关磁阻电机的力矩波动和噪音。The switch drive circuit 21 of the present embodiment controls the drive current and the freewheeling current of each winding according to the sum i of the currents detected by the current detecting circuit 27, so that the sum of the currents maintains the preset range, so the switched reluctance motor of the present embodiment It has the characteristics of servo motor; because the output torque of the switched reluctance motor is stable, the torque ripple and noise of the switched reluctance motor are reduced.

本发明提供第五实施例的开关磁阻电机，其于第四实施例的开关磁阻电机的不同之处在于：如图14所示，控制器23控制第一开关持续导通，并且以脉宽调制方式控制第二开关管间歇性导通，由此调节驱动电流的大小。即在A相定子组件111的驱动时段时，控制器23控制第一开关V1持续导通，通过PWM信号控制第二开关管V2间歇性导通。The present invention provides a switched reluctance motor of a fifth embodiment, which is different from the switched reluctance motor of the fourth embodiment in that, as shown in FIG. 14, the controller 23 controls the first switch to be continuously turned on, and is pulsed. The wide modulation mode controls the intermittent conduction of the second switching transistor, thereby adjusting the magnitude of the driving current. That is, during the driving period of the A-phase stator assembly 111, the controller 23 controls the first switch V1 to be continuously turned on, and controls the second switching transistor V2 to be intermittently turned on by the PWM signal.

本发明提供第五实施例的开关磁阻电机，其于第四实施例的开关磁阻电机的基础上进行描述：如图15所示，开关磁阻电机进一步包括与开关驱动电路21连接的位置传感器28，位置传感器28用于测量开关磁阻电机10中转子12与定子11之间的相对位置，以使得开关驱动电路21根据转子12与定子11之间的相对位置改变通电状态，即开关驱动电路21根据每一定子组件的最大电感和最小电感改变通电状态，以驱动开关磁阻电机工作。其中，位置传感器28包括磁编码器或者光编码器。The present invention provides a switched reluctance motor according to a fifth embodiment, which is described on the basis of the switched reluctance motor of the fourth embodiment: as shown in FIG. 15, the switched reluctance motor further includes a position connected to the switch drive circuit 21. The sensor 28, the position sensor 28 is for measuring the relative position between the rotor 12 and the stator 11 in the switched reluctance motor 10, so that the switch drive circuit 21 changes the energization state according to the relative position between the rotor 12 and the stator 11, that is, the switch drive Circuit 21 changes the energization state based on the maximum inductance and minimum inductance of each stator assembly to drive the switched reluctance motor to operate. Among them, the position sensor 28 includes a magnetic encoder or an optical encoder.

本发明提供一实施例的开关磁阻电机的电流的控制方法，本实施例的控制方法在第四实施例所揭示的开关磁阻电机的基础上进行描述。如图16所示，该控制方法包括： The present invention provides a method of controlling current of a switched reluctance motor according to an embodiment. The control method of the present embodiment is described on the basis of the switched reluctance motor disclosed in the fourth embodiment. As shown in FIG. 16, the control method includes:

S161：在驱动时段，通过控制器23同时控制第一开关管和第二开关管间歇性导通；或者控制第一开关管持续导通，并控制第二开关管间歇性导通，以调节绕组的驱动电流的大小；S161: During the driving period, the first switch tube and the second switch tube are simultaneously controlled to be turned on by the controller 23; or the first switch tube is continuously turned on, and the second switch tube is controlled to be turned on intermittently to adjust the winding. The magnitude of the drive current;

S162：在续流时段，通过控制器23控制第一开关管持续关闭，并控制第二开关管间歇性导通，以调节绕组的续流电流的大小；S162: During the freewheeling period, the first switch tube is continuously turned off by the controller 23, and the second switch tube is controlled to be turned on intermittently to adjust the magnitude of the freewheeling current of the winding;

S163：根据电流总和i控制驱动电流和续流电流，以使电流总和i保持预设范围。S163: Control the driving current and the freewheeling current according to the current sum i, so that the current sum i is maintained in a preset range.

在步骤S161中，进一步通过控制器23控制至少三个定子组件所对应的驱动时段的相位差为2π/N，其中N为至少三个定子组件的数量。即A相定子组件111的驱动时段和B相定子组件112的驱动时段的相位差为2π/3，即电角度120°，B相定子组件112的驱动时段和C相定子组件113的驱动时段的相位差为电角度120°。In step S161, the phase difference of the driving period corresponding to the at least three stator components is further controlled by the controller 23 to be 2π/N, where N is the number of at least three stator components. That is, the phase difference between the driving period of the A-phase stator assembly 111 and the driving period of the B-phase stator assembly 112 is 2π/3, that is, the electrical angle is 120°, the driving period of the B-phase stator assembly 112 and the driving period of the C-phase stator assembly 113. The phase difference is an electrical angle of 120°.

通过控制器23控制定子组件的续流时段与下一被驱动的定子组件的驱动时段的相位至少部分重叠，其中定子组件的续流时段与下一被驱动的定子组件的驱动时段的相位至少部分重叠为π/N。即A相定子组件111的续流时段与B相定子组件112的驱动时段的相位部分重叠为120°-180°，B相定子组件112的续流时段与C相定子组件113的驱动时段的相位部分重叠为240°-300°，如图12所示。Controlling the freewheeling period of the stator assembly by the controller 23 to at least partially overlap with the phase of the driving period of the next driven stator assembly, wherein the phase of the freewheeling period of the stator assembly and the driving period of the next driven stator assembly are at least partially The overlap is π/N. That is, the phase of the freewheeling period of the A-phase stator assembly 111 and the phase of the driving period of the B-phase stator assembly 112 partially overlap to 120°-180°, and the phase of the freewheeling period of the B-phase stator assembly 112 and the driving period of the C-phase stator assembly 113 Partial overlap is 240°-300°, as shown in Figure 12.

其中，在A相定子组件111的驱动时段时，通过控制器23以脉宽调制方式同时控制第一开关管V1和第二开关管V2导通或者关闭。即通过控制器23在A相绕组产生的电感最小时发送PWM信号至第一开关管V1和第二开关管V2；在第一开关管V1和第二开关管V2同时导通时，直流电源Us在A相定子组件111施加驱动电流；在第一开关管V1和第二开关管V2同时关闭时，直流电源Us停止在A相定子组件111施加驱动电流，能够避免驱动电流过大。Wherein, during the driving period of the A-phase stator assembly 111, the first switching transistor V1 and the second switching transistor V2 are simultaneously turned on or off by the controller 23 in a pulse width modulation manner. That is, the controller 23 sends a PWM signal to the first switching transistor V1 and the second switching transistor V2 when the inductance generated by the A-phase winding is minimum; when the first switching transistor V1 and the second switching transistor V2 are simultaneously turned on, the DC power source Us The driving current is applied to the A-phase stator assembly 111; when the first switching transistor V1 and the second switching transistor V2 are simultaneously turned off, the DC power source Us stops applying a driving current to the A-phase stator assembly 111, and the driving current can be prevented from being excessive.

通过控制器23在A相绕组产生的电感最大时停止发送PWM信号至第一开关管V1，第一开关管V1关闭，A相定子组件111进入续流时段，进入步骤S162。When the inductance generated by the A-phase winding is maximum, the controller 23 stops transmitting the PWM signal to the first switching transistor V1, the first switching transistor V1 is turned off, and the A-phase stator assembly 111 enters the freewheeling period, and proceeds to step S162.

在步骤S162中，在A相定子组件111的续流时段时，通过控制器23控制直流电源Us停止工作，并且控制第一开关管V1持续关闭，并以脉宽调制方式控制第二开关管V2间歇性导通，以使A相绕组、第二开关V2和第二续流二极管D2形成回路，进而释放A相绕组上存储的能量，以调节A相绕组的续流电流的大小。 In step S162, during the freewheeling period of the A-phase stator assembly 111, the DC power supply Us is controlled to stop by the controller 23, and the first switching transistor V1 is controlled to be continuously turned off, and the second switching transistor V2 is controlled in a pulse width modulation manner. Intermittent conduction, so that the phase A winding, the second switch V2 and the second freewheeling diode D2 form a loop, thereby releasing the energy stored in the phase A winding to adjust the magnitude of the freewheeling current of the phase A winding.

同时，通过控制器23控制B绕组的第一开关管V3和第二开关管V4导通或者关闭，以直流电源Us在B相定子组件112施加驱动电流，其中，通过步骤S161的控制方式控制B绕组的第一开关管V3和第二开关管V4，在此不再赘述。At the same time, the first switching transistor V3 and the second switching transistor V4 of the B winding are controlled to be turned on or off by the controller 23, and the driving current is applied to the B-phase stator assembly 112 by the DC power source Us, wherein the control mode is controlled by the control mode of step S161. The first switch tube V3 and the second switch tube V4 of the winding are not described herein.

在步骤S163中，通过开关驱动电路21从电流检测电路27获取电流总和i，并且根据电流总和i控制驱动电流和续流电流，以使电流总和i保持预设范围。其中控制驱动电流的方法可采用步骤S161，控制续流电流的方法可采用步骤S162。In step S163, the current sum i is obtained from the current detecting circuit 27 through the switch drive circuit 21, and the drive current and the freewheel current are controlled in accordance with the current sum i so that the current sum i is maintained at the preset range. The method for controlling the driving current may adopt step S161, and the method for controlling the freewheeling current may adopt step S162.

本实施例的脉宽调制方式可以为方波脉宽调制或者正弦波脉宽调制。其中，上述实施例的PWM信号为方波脉宽调制。The pulse width modulation method of this embodiment may be square wave pulse width modulation or sine wave pulse width modulation. The PWM signal of the above embodiment is square wave pulse width modulation.

在本发明中，A相绕组产生的电感最小，具体可为转子齿121与第一定子槽134完全对齐时；A相绕组产生的电感最大，具体可为转子齿121与第一定子齿131完全对齐时。In the present invention, the A-phase winding generates the smallest inductance, specifically when the rotor teeth 121 are completely aligned with the first stator slot 134; the A-phase winding generates the largest inductance, specifically the rotor teeth 121 and the first stator teeth. When 131 is fully aligned.

本实施例由于前一相在续流时段，导通相在驱动时段，即A相绕组在进入续流时段时，B相绕组在进入驱动时段；A相的续流电流和B相的驱动电流之和保持恒定，因此开关磁阻电机的电流波动小，即开关磁阻电机的电流总和波动小，进而力矩的波动小。由于前一相的续流电流较大，而导通相的驱动电流较小，即A相的续流电流较大，B相的驱动电流较小；因此导通相的绕组所产生的磁场强度弱，即B相绕组所产生的磁场强度弱，进而减小噪声。In this embodiment, since the previous phase is in the freewheeling period, the conduction phase is in the driving period, that is, when the A-phase winding enters the freewheeling period, the B-phase winding enters the driving period; the free-current of the A-phase and the driving current of the B-phase The sum is kept constant, so the current fluctuation of the switched reluctance motor is small, that is, the sum of the currents of the switched reluctance motor is small, and the fluctuation of the torque is small. Since the freewheeling current of the previous phase is large, and the driving current of the conducting phase is small, that is, the freewheeling current of the phase A is large, and the driving current of the phase B is small; therefore, the magnetic field strength generated by the winding of the conducting phase is small. Weak, that is, the strength of the magnetic field generated by the B-phase winding is weak, thereby reducing noise.

本发明还提供一种车轮，该车轮采用开关磁阻电机驱动，而该开关磁阻电机为如前实施例中所述的开关磁阻电机。The present invention also provides a wheel that is driven by a switched reluctance motor that is a switched reluctance motor as described in the previous embodiment.

优选地，该车轮可以包括轮毂式开关磁阻电机，即利用轮毂式开关磁阻电机驱动，该轮毂式开关磁阻电机为外转子内定子的电机结构。Preferably, the wheel may comprise a hub-type switched reluctance motor, that is, driven by a hub-type switched reluctance motor, which is a motor structure of the stator in the outer rotor.

进一步地，本发明还提供一种电动车，该电动车可以为电动汽车、电动摩托车或者电动自行车等。该电动车为纯电动或混合动力车，该电动车的车轮采用开关磁阻电机驱动，该开关磁阻电机也为如前实施例中所述的开关磁阻电机。优选的，该电动车的驱动轮可采用上述实施例中的车轮结构，即车轮包括轮毂式开关磁阻电机，利用轮毂式开关磁阻电机驱动车轮转动。Further, the present invention also provides an electric vehicle, which may be an electric vehicle, an electric motorcycle, or an electric bicycle. The electric vehicle is a pure electric or hybrid vehicle, and the wheels of the electric vehicle are driven by a switched reluctance motor, which is also a switched reluctance motor as described in the previous embodiment. Preferably, the driving wheel of the electric vehicle can adopt the wheel structure in the above embodiment, that is, the wheel includes a hub-type switched reluctance motor, and the wheel-type switched reluctance motor drives the wheel to rotate.

需要说明的是，本发明实施例提供的开关磁阻电机的应用场景不限于电动汽车，还可以作为船舶、大型机械等驱动用电机。It should be noted that the application scenario of the switched reluctance motor provided by the embodiment of the present invention is not limited to an electric vehicle, and can also be used as a driving motor for a ship or a large machine.

需要说明的是，以上各实施例均属于同一发明构思，各实施例的描述各有侧重，在个别实施例中描述未详尽之处，可参考其他实施例中的描述。 It should be noted that the above embodiments are all in the same inventive concept, and the descriptions of the respective embodiments are different, and the details are not described in the specific embodiments, and the descriptions in other embodiments may be referred to.

以上对本发明实施例所提供的开关磁阻电机及电动车和车轮进行了详细介绍，本文中应用了具体个例对本发明的原理及实施方式进行了阐述，以上实施例的说明只是用于帮助理解本发明的方法及其核心思想；同时，对于本领域的一般技术人员，依据本发明的思想，在具体实施方式及应用范围上均会有改变之处，综上所述，本说明书内容不应理解为对本发明的限制。 The switched reluctance motor and the electric vehicle and the wheel provided by the embodiments of the present invention are described in detail. The principles and embodiments of the present invention are described in the following. The description of the above embodiments is only for helping to understand. The method of the present invention and its core idea; at the same time, for those skilled in the art, according to the idea of the present invention, there will be changes in the specific implementation manner and the scope of application. It is understood to be a limitation of the invention.

Claims

一种开关磁阻电机的电流的控制方法，其特征在于，所述开关磁阻电机包括定子、开关驱动电路以及电流检测电路，其中所述定子设置有至少三个定子组件，所述至少三个定子组件分别包括绕组，所述电流检测电路用于检测流经所述至少三个定子组件的所述绕组的电流总和，所述开关驱动电路包括控制器以及分别与所述至少三个定子组件对应的至少三个开关模块，每一所述开关模块包括与对应的所述定子组件的绕组串联的第一开关管和第二开关管，所述控制方法包括：A method for controlling a current of a switched reluctance motor, characterized in that the switched reluctance motor comprises a stator, a switch drive circuit and a current detecting circuit, wherein the stator is provided with at least three stator assemblies, the at least three The stator assemblies each include a winding, the current sensing circuit for detecting a sum of currents flowing through the windings of the at least three stator assemblies, the switch drive circuit including a controller and corresponding to the at least three stator assemblies, respectively At least three switch modules, each of the switch modules includes a first switch tube and a second switch tube in series with a winding of the corresponding stator assembly, the control method comprising:

在驱动时段，通过所述控制器同时控制所述第一开关管和第二开关管间歇性导通；或者控制所述第一开关管持续导通，并控制第二开关管间歇性导通，以调节所述绕组的驱动电流的大小；During the driving period, the first switch tube and the second switch tube are simultaneously controlled to be turned on by the controller; or the first switch tube is continuously turned on, and the second switch tube is controlled to be turned on intermittently. To adjust the magnitude of the drive current of the winding;

在续流时段，通过所述控制器控制所述第一开关管持续关闭，并以控制第二开关管间歇性导通，以调节所述绕组的续流电流的大小；During the freewheeling period, the first switch tube is continuously turned off by the controller, and the second switch tube is controlled to be turned on intermittently to adjust the magnitude of the freewheeling current of the winding;

根据所述电流总和控制所述驱动电流和所述续流电流，以使所述电流总和保持在预设范围。The drive current and the freewheeling current are controlled according to the sum of the currents to maintain the sum of the currents within a preset range.
根据权利要求1所述的控制方法，其特征在于，所述控制方法进一步包括：The control method according to claim 1, wherein the control method further comprises:

通过所述控制器控制所述至少三个定子组件所对应的所述驱动时段的相位差为2π/N，其中所述N为所述至少三个定子组件的数量。The phase difference of the driving period corresponding to the at least three stator assemblies is controlled by the controller to be 2π/N, wherein the N is the number of the at least three stator components.
根据权利要求2所述的控制方法，其特征在于，所述控制方法进一步包括：The control method according to claim 2, wherein the control method further comprises:

通过所述控制器控制所述定子组件的续流时段与下一被驱动的所述定子组件的驱动时段的相位至少部分重叠。The freewheeling period of the stator assembly is controlled by the controller to at least partially overlap the phase of the driving period of the next driven stator assembly.
根据权利要求3所述的控制方法，其特征在于，所述定子组件的续流时段与下一被驱动的所述定子组件的驱动时段的相位至少部分重叠为π/N。The control method according to claim 3, wherein a phase of the freewheeling period of the stator assembly and a phase of a driving period of the next driven stator assembly at least partially overlap by π/N.
根据权利要求4所述的控制方法，其特征在于，在所述驱动时段时，所述驱动时段长为2π/3；在所述续流时段时，所述续流时段长为π/3。The control method according to claim 4, wherein the driving period is 2π/3 in the driving period, and the freewheeling period is π/3 in the freewheeling period.
一种开关磁阻电机，其特征在于，所述开关磁阻电机包括定子、开关驱动电路以及电流检测电路，其中所述定子设置有至少三个定子组件，所述至少三个定子组件分别包括绕组，所述电流检测电路用于检测流经所述至少三个定子组件的所述绕组的电流总和，所述开关驱动电路包括控制器以及分别与所述至少三个定子组件对应的至少三个开关模块，每一所述开关模块包括与对应的所述定子组件的绕组串联的第一开关管和第二开关管；其中：A switched reluctance motor, comprising: a stator, a switch drive circuit, and a current detecting circuit, wherein the stator is provided with at least three stator assemblies, and the at least three stator assemblies respectively comprise windings The current detecting circuit is configured to detect a sum of currents flowing through the windings of the at least three stator assemblies, the switch driving circuit including a controller and respectively At least three switch modules corresponding to at least three stator modules, each of the switch modules including a first switch tube and a second switch tube in series with a winding of the corresponding stator assembly; wherein:

在驱动时段，所述控制器同时控制所述第一开关管和第二开关管间歇性导通；或者控制所述第一开关管持续导通，并控制所述第二开关管间歇性导通，以调节所述绕组的驱动电流的大小；During the driving period, the controller simultaneously controls the first switch tube and the second switch tube to be intermittently turned on; or controls the first switch tube to continuously conduct, and controls the second switch tube to be intermittently turned on. To adjust the magnitude of the drive current of the winding;

在续流时段，所述控制器控制所述第一开关管持续关闭，并控制第二开关管间歇性导通，以调节所述绕组的续流电流的大小；During the freewheeling period, the controller controls the first switch tube to continuously turn off, and controls the second switch tube to be intermittently turned on to adjust the magnitude of the freewheeling current of the winding;

所述开关驱动电路进一步根据所述电流总和控制所述驱动电流和所述续流电流，以使所述电流总和保持预设范围。The switch drive circuit further controls the drive current and the freewheeling current according to the sum of the currents to maintain the sum of the currents in a preset range.
根据权利要求6所述的开关磁阻电机，其特征在于，每一所述开关模块进一步包括第一续流二极管和第二续流二极管，其中所述第一开关管的第一连接端连接所述电源的正极、所述第一开关管的第二连接端连接对应的所述定子组件的所述绕组的第一端、所述第二开关管的第一连接端连接对应的所述定子组件的所述绕组的第二端，所述第二开关管的第二连接端连接所述电源的负极，所述第一续流二极管的正极连接对应的所述定子组件的所述绕组的第二端，所述第一续流二极管的负极连接所述电源的正极，所述第二续流二极管的正极连接所述电源的负极，所述第二续流二极管的负极连接对应的所述定子组件的所述绕组的第一端。The switched reluctance motor according to claim 6, wherein each of said switch modules further comprises a first freewheeling diode and a second freewheeling diode, wherein said first connecting end of said first switching transistor is connected a positive pole of the power source, a second connection end of the first switch tube is connected to a first end of the winding of the corresponding stator assembly, and a first end of the second switch tube is connected to the corresponding stator component a second end of the winding, a second connection end of the second switch tube is connected to a negative pole of the power source, and a positive pole of the first freewheeling diode is connected to a second part of the winding of the corresponding stator assembly End, a cathode of the first freewheeling diode is connected to a positive pole of the power source, a cathode of the second freewheeling diode is connected to a cathode of the power source, and a cathode of the second freewheeling diode is connected to a corresponding stator component. The first end of the winding.
根据权利要求6所述的开关磁阻电机，其特征在于，所述控制器控制所述至少三个定子组件所对应的所述驱动时段的相位差为2π/N，其中所述N为所述至少三个定子组件的数量。The switched reluctance motor according to claim 6, wherein said controller controls a phase difference of said driving period corresponding to said at least three stator assemblies to be 2π/N, wherein said N is said The number of at least three stator components.
根据权利要求8所述的开关磁阻电机，其特征在于，所述控制器控制所述定子组件的续流时段与下一被驱动的所述定子组件的驱动时段的相位至少部分重叠。The switched reluctance motor of claim 8 wherein said controller controls said freewheeling period of said stator assembly to at least partially overlap with a phase of a driving period of said next driven stator assembly.
根据权利要求9所述的开关磁阻电机，其特征在于，所述定子组件的续流时段与下一被驱动的所述定子组件的驱动时段的相位至少部分重叠为π/N。The switched reluctance motor according to claim 9, wherein a phase of the freewheeling period of the stator assembly and a phase of a driving period of the next driven stator assembly at least partially overlap by π/N.
根据权利要求6所述的开关磁阻电机，其特征在于，在所述驱动时段时，所述驱动时段长为2π/3；在所述续流时段时，所述续流时段长为π/3。The switched reluctance motor according to claim 6, wherein said driving period is 2π/3 in length during said driving period; and said freewheeling period is π/ in said freewheeling period 3.
根据权利要求6所述的开关磁阻电机，其特征在于，所述开关磁阻电机进一步包括转子，所述至少三个定子组件沿所述定子的轴向分段设置，每一所述定子组件进一步分别包括沿所述定子的周向周期性设置且由定子槽彼此间隔的多个定子齿，所述绕组绕设于所述定子齿上，其中所述至少三个定子组件的定子齿沿所述定子的周向依次错开预设角度。A switched reluctance motor according to claim 6, wherein said switched reluctance motor further comprises a rotor, said at least three stator assemblies being disposed along an axial section of said stator, each of said stator assemblies Further comprising periodically circumferentially along the stator and spaced apart from each other by stator slots a plurality of stator teeth, the windings being wound around the stator teeth, wherein the stator teeth of the at least three stator assemblies are sequentially offset by a predetermined angle along a circumferential direction of the stator.
根据权利要求12所述的开关磁阻电机，其特征在于，所述至少三个定子组件的定子齿的数量和宽度相同，所述预定角度为T1/N，其中所述T1为所述定子齿的角度周期，所述N为所述至少三个定子组件的数量。The switched reluctance motor according to claim 12, wherein said stator teeth of said at least three stator assemblies have the same number and width, said predetermined angle being T1/N, wherein said T1 is said stator teeth The angular period of the N is the number of the at least three stator components.
根据权利要求6所述的开关磁阻电机，其特征在于，所述电流检测电路包括具有一开口的环形铁芯以及磁场传感器，所述至少三个定子组件的所述绕组进一步分别绕设于所述环形铁芯上，所述磁场传感器设置于所述环形铁芯的开口处。A switched reluctance motor according to claim 6, wherein said current detecting circuit comprises a toroidal core having an opening and a magnetic field sensor, said windings of said at least three stator assemblies being further wound around said On the toroidal core, the magnetic field sensor is disposed at an opening of the toroidal core.
根据权利要求14所述的开关磁阻电机，其特征在于，各所述定子组件的所述绕组在所述环形铁芯上绕设的匝数相同。A switched reluctance motor according to claim 14, wherein said winding of each of said stator assemblies has the same number of turns around said toroidal core.
根据权利要求14所述的开关磁阻电机，其特征在于，所述磁场传感器为线性霍尔电流传感器。The switched reluctance motor of claim 14 wherein said magnetic field sensor is a linear Hall current sensor.
一种车轮，其特征在于，所述车轮采用轮毂电机驱动，所述轮毂电机为权利要求6-16任一项所述的开关磁阻电机。A wheel characterized in that the wheel is driven by a hub motor, which is the switched reluctance motor of any one of claims 6-16.
一种电动车，其特征在于，所述电动车为纯电动或混合动力车，所述电动车包括如权利要求6-16任一项所述的开关磁阻电机。 An electric vehicle, characterized in that the electric vehicle is a pure electric or hybrid vehicle, and the electric vehicle includes the switched reluctance motor according to any one of claims 6-16.