The disclosure relates to an electric motor having asymmetrical rotor slots.
Electric motors are used in various consumer products and industries. For instance, electric motors are used in hybrid vehicles to provide torque to propel the vehicle, charge a battery, start an internal combustion engine, etc. The electric motor may be powered by a battery or other energy storage device.
An example electric motor includes a stator and a rotor. The stator is configured to receive electrical energy and generate an electromagnetic field in accordance with the electrical energy received. The rotor is in electromagnetic communication with the stator and is configured to rotate in accordance with the electromagnetic field generated by the stator. The rotor includes a plurality of poles including a first set of poles and a second set of poles. The first set of poles defines a first slot and the second set of poles defines a second slot that has a different configuration than the first slot to reduce a torque ripple effect.
An example system includes a power source, an inverter, and an electric motor. The power source is configured to generate direct current energy. The inverter is in electrical communication with the power source and is configured to convert the direct current energy into alternating current energy. The electric motor has a stator in electrical communication with the inverter and a rotor in electrical communication with the power source and in electromagnetic communication with the stator. The stator is configured to receive the alternating current energy from the inverter and generate an electromagnetic field in accordance with the alternating current energy received. The rotor is configured to receive the direct current energy from the power source and rotate in accordance with the electromagnetic field generated by the stator. The rotor defines a first slot and a second slot that has a different configuration than the first slot to reduce a torque ripple effect.
An example rotor includes a core and a plurality of poles extending radially from the core. The plurality of poles includes a first set of poles defining a first slot and a second set of poles defining a second slot. The second slot has a different configuration than the first slot to reduce a torque ripple.
The above features and the advantages of the present disclosure are readily apparent from the following detailed description of the best modes for carrying out the invention when taken in connection with the accompanying drawings.
An electric motor includes a stator that can generate an electromagnetic field and a rotor that is configured to rotate in accordance with the electromagnetic field generated by the stator to generate a torque. The rotor includes a plurality of poles including a first set of poles and a second set of poles. The first set of poles defines a first slot and the second set of poles defines a second slot that is asymmetric relative to the first slot to reduce a torque ripple effect. That is, the first and second slots have different configurations relative to one another to reduce torque ripple.
Torque ripple may occur when the torque generated by the motor changes during the rotation of the rotor. Torque ripple may be caused by harmonics due to, e.g., physical properties of the rotor. The asymmetrical features of the first slot and the second slot, for instance, may reduce the torque ripple effect, and thus, allow the motor to output a more consistent torque during operation. The system described below may take many different forms and include multiple and/or alternate components and facilities than shown. While an example system is shown in the Figures, the components illustrated in the Figures are not intended to be limiting. Indeed, additional or alternative components and/or implementations may be used.
The power source 105 may include any device configured to generate electrical energy, such as direct current (DC) electrical energy. For example, the power source 105 may include a battery. That is, the power source 105 may include one or more electrochemical cells that are configured to convert stored chemical energy into electrical energy. In one possible approach, the power source 105 may be charged when provided with, e.g., DC energy.
The inverter 110 may include any device configured to convert DC energy into alternating current (AC) electrical energy. For instance, the inverter 110 may be in electrical communication with the power source 105 so that, e.g., the inverter 110 may convert the DC energy generated by the power source 105 into AC energy that may be output to other devices in the system 100. Accordingly, devices in the system 100 that are configured to receive AC energy may be powered by the power source 105. The inverter 110 may also include a rectifier configured to convert AC energy into DC energy. This way, AC energy generated by one or more other devices in the system 100 may be stored in the power source 105 as DC energy. In one possible implementation, the inverter 110 and rectifier may be separate devices in the system 100.
The electric motor 115 may include any device configured to convert electrical energy into rotational motion. For example, the motor 115 may be a synchronous machine configured to receive AC energy from the inverter 110 and generate rotational motion based on the electrical energy received. Moreover, the motor 115 may be configured to generate AC energy that, when converted into DC energy by the inverter 110 or rectifier, may be stored in the power source 105. As discussed in detail below with respect to
The electric motor 115 may include a stator 120 and a rotor 125. The stator 120 may be in electrical communication with the inverter 110 to, e.g., receive three-phase AC energy output by the inverter 110 and the stator 120 may be configured to generate an electromagnetic field in accordance with the AC energy received. In one example approach, the stator 120 may include an armature (not shown) that is configured to produce an electromagnetic field when provided with three-phase AC energy.
The rotor 125 may be in electrical communication with the power source 105 and in electromagnetic communication with the stator 120. In one possible approach, the rotor 125 may include field windings that receive DC energy output by the power source 105. The DC energy may magnetize portions of the rotor 125 so, e.g., the rotor 125 will rotate in accordance with the electromagnetic energy produced by the stator 120. The rotation of the rotor 125 allows the motor 115 to produce a torque. As discussed in detail below with respect to
The first pole 130, the second pole 135, and/or the third pole 140 may be a permanent magnet or may be magnetized when provided with, e.g., DC energy from the power source 105 as illustrated in
The core 145 may include any device configured to support the first pole 130, the second pole 135, the third pole 140, and any other poles used with the rotor 125. In one possible approach, the core 145 may be formed from a metal such as iron. The first pole 130, the second pole 135, and/or the third pole 140 may be integrally formed with the core 145 during, e.g., a manufacturing process.
The first slot 150 and the second slot 155 may be defined by the space between any two of the poles in the rotor 125. As illustrated, the first pole 130 and the second pole 135 may define the first slot 150, and the second pole 135 and the third pole 140 may define the second slot 155. Alternatively, the first slot 150 and the second slot 155 need not be defined by a common pole (e.g., the second pole 135 in
The poles that define the first slot 150 (e.g., the first pole 130 and the second pole 135 of
Another possible asymmetrical configuration illustrated in
As discussed above, the first pole 130, the second pole 135, and the third pole 140 may extend radially from the core 145 of the rotor 125. As such, the first pole 130 and the second pole 135 may define the first slot 150 to taper at a first pitch 190 and the second pole 135 and the third pole 140 may define the second slot 155 to taper at a second pitch 195 to reduce torque ripple. One possible asymmetrical configuration that may reduce torque ripple is that the first pitch 190 and the second pitch 195 may be different. For instance, the first pitch 190 may be based on a distance between the first pole 130 and the second pole 135 while the second pitch 195 may be based on a different distance between the second pole 135 and the third pole 140.
The first slot 150 and the second slot 155 of
The third slot 210 and the fourth slot 215 may be similar to the first slot 150 and the second slot 155 of
As illustrated in
Additionally, each slot may only include one asymmetry relative to another slot. The slots of
Furthermore, any slot may include any combination of asymmetrical features relative to any other slot to reduce torque ripple. For example, in addition to or instead of having a different size and/or a different pitch, the first slot 150 and the second slot 155 of
Moreover, groups of slots may establish a pattern that may be repeated by other groups of slots. For instance, in the context of
While the best modes for carrying out the invention have been described in detail, those familiar with the art to which this invention relates will recognize various alternative designs and embodiments for practicing the invention within the scope of the appended claims.