Stackable Motor

Abstract

A vehicle comprises a plurality of motors operatively connected with one another. The vehicle is powered with the plurality of motors individually and in combination with one another to primarily operate each of the plurality of motors within a predetermine efficiency range.

Description

TECHNICAL FIELD

The present invention relates, generally, to an electric motor for use with a hybrid vehicle, and more specifically, to an electric motor that can be combined with other motors to power a vehicle.

BACKGROUND

Advancements in technology and the growing concern for environmentally efficient vehicles have led to the use of alternate fuel and power sources for vehicles. Electric vehicles or hybrid electric vehicles use electro mechanical devices (motors) to power the vehicle. In order to provide the required torque and power to operate the vehicle the motor must be designed to operate over a broad operating range. When a motor is chosen to act for an all purpose function, such as driving a vehicle, the motor needs to have the capacity for all load conditions, including the capacity to meet the maximum torque and power demands of the vehicle.

However, vehicles do not require peak torque and power at all times of operation. During normal operating conditions there is excess torque and power available from the motor. Additionally, motors, like any power source, have certain efficiency ranges in which they achieve their optimal performance. Sizing the motor to provide the capacity for all load conditions results in an over-sized motor that must bear the inefficiency when not operating at the optimum range. Inefficiencies of the over-sized motor are most apparent when operating at low speed. At low operating speed the forces to overcome the mass of the rotor contributes to great inefficiencies. Another inefficiency from an oversized motor is, the centrifugal forces required to start and stop the motor requires excess power and depletes the available energy more than necessary.

Additionally, vehicles are available in a variety of sizes and weights which results in additional variety in the motor capacity required among various vehicles, Therefore, the larger vehicles must default to larger and unique motors. The cost to design, manufacture and carry inventory on the variety of motors required results in cost inefficiencies as well.

SUMMARY

A vehicle comprises a plurality of motors that are operatively connected with one another. The plurality of motors is operable to power the vehicle individually and in combination with one another. Each of the plurality of motors are generally identical to one another. Alternatively, the plurality of motors is operable to power the vehicle individually and in combination with one another such that each of the plurality of motors primarily operates in a predetermined efficiency range.

A method of powering a vehicle comprises operatively connecting a plurality of motors with one another and powering the vehicle with the plurality of motors individually and in combination with one another to (primarily operate each of the plurality of motors within a predetermined efficiency range.

The above features and advantages, and other features and advantages of the present invention will be readily apparent from the following detailed description of the preferred embodiments and best modes for carrying out the present invention when taken in connection with the accompanying drawings and appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic illustration of an electric vehicle having a first embodiment of a stackable motor of the present invention;

FIG. 2 is a schematic illustration of an electric vehicle having a second embodiment of the stackable motor of the present invention;

FIG. 3 is a schematic graph of the stackable motor output for the second embodiment of the vehicle shown in FIG. 2;

FIG. 4 is a schematic illustration of a third embodiment of the stackable motor for the vehicle of FIGS. 1; and

FIG. 5 is a schematic illustration f a fourth embodiment of the stackable motor for the vehicle of FIG. 1.

DETAILED DESCRIPTION

Referring to the Figures, wherein like reference numbers refer to the same or similar components throughout the several views, FIG. 1 schematically illustrates a vehicle 10 including at least one motor 12, and a transmission 14. The vehicle 10 may be any vehicle that utilizes an electric motor to provide the vehicle with drive, such as an electric vehicle, a hybrid electric vehicle, or a fuel cell vehicle. Therefore, in addition to the at least one motor 12 the vehicle 10 may also include an internal combustion engine 16.

In the embodiment shown there is a first motor 12A and a second motor 12B. The first motor 12A and the second motor 12B are the same size and capacity as one another. The first motor 12A and the second motor 12B are operatively connected to one another to drive the transmission 14. In the embodiment shown the first motor 12A and the second motor 12B are coupled to one another. In this manner, the first motor 12A and the second motor 12B are stackable to provide the capacity required for the vehicle 10 while primarily operating within the efficiency ranges for the first motor 12A and the second motor 12B. Therefore, one large electric motor may be replaced by multiple smaller motors 12. The first motor 12A and the second motor 12B may be any type of electromechanical device to provide power, such as an induction motor, permanent magnet machine, A/C or D/C motors, etc.

The first motor 12A and the second mo or 12B may be coupled together directly, through clutches or a solid shaft connection, or indirectly, such as a serpentine belt. Direct coupling of the first motor 12A to the second motor 12B would provide an efficient arrangement with few losses. Indirect coupling may provide a more flexible arrangement for packaging the first motor it 2A and the second motor 12B within the vehicle 10. One skilled in the art would be able to select the manner of coupling most suited for a particular vehicle 10. Any number of generally identical motors, 12 may be combined or stacked to provide the capacity required by the vehicle 10.

The first motor 12A acts as the primary motor and operates to drive the transmission 14 while the vehicle 10 is operating at steady speeds. The second motor 12B acts as an additional power source and engages to drive the transmission 14 when additional operating loads are placed on the motors 12, such as during accelerations of the vehicle 10. The second motor 12B would engage any time the operating loads exceed the capacity of the first motor 12A. Alternatively, the second motor 12B may be engaged prior to the capacity of the first motor 12A and at any time when the first motor 12A begins to operate outside of the desired efficiency range. In this manner the first motor 12A and the second motor 12B may both operate within their efficiency range for greater periods of time and the overall vehicle 10 efficiency will be increased.

In the above embodiment, the first motor 12A is the primary motor for the vehicle 10 and the second motor 12B is used to provide additional power and torque when required by the vehicle 10. Alternatively, the second motor 12B may be the primary motor and the first motor 12A may be used to provide additional power and torque. Additionally, the first motor 12A and the second motor 12B may alternately be the primary motor and the other would provide the additional power and torque. In this manner, even overall wear on both the first motor 12A and the second motor 12B may be maintained.

Further, the primary motor 12A or 12B and the additional motor 129 or 12A may be engaged or disengaged to maintain operation within the efficiency ranges. The primary motor 12A or 12B and the additional motor 12B or 12A may also engage or disengage in cooperation with the shift strategy of the transmission 14 to maintain maximum efficiency of the vehicle 10. In this manner, nontraditional shift strategies of the transmission 14 may be utilized in combination with the motors 12 to increase the efficiency of the vehicle 10.

Additionally, the first motor 12A or the second motor 12B may act as the primary motor in case of mechanical trouble of the other motor 12A-B. In this instance the primary motor 12A-B would not be able to meet the full capacity of the vehicle 10. However, the vehicle 10 would operate in a restricted or limp-home mode but would allow the vehicle 10 operator to reach their destination.

FIGS. 2-3 illustrate a second embodiment of the vehicle 110 including at least one motor 112, and a transmission 114. The vehicle 110 may be an electric vehicle or a hybrid electric vehicle 110. Therefore, in addition to the at least one motor 112 the vehicle 110 may also include an internal combustion engine 116.

In the embodiment shown, there are four motors, 112A, 112B, 112C, 112D to drive the vehicle 110. As explained above any number of motors, 112 may be combined to provide the capacity required by the vehicle 110. In this manner one large electric motor may be replaced by multiple smaller motors 112.

The first through fourth motors 112A-D are operatively connected to one another and may be coupled together by directly, through clutches, or indirectly, such as by a serpentine belt. Direct coupling of the first through fourth motors 112A-D would provide an efficient arrangement with few losses. Indirect coupling may provide a more flexible arrangement for packaging the first through fourth motors 112A-D within the vehicle 10. One skilled in the art would be able to select the manner of coupling most suited for a particular vehicle 110.

One of the motors 112 may be designated as the primary motor 112A and the other motors 112B-D may provide additional power and torque as required by the vehicle 110. When the capacity of the first motor 112A is exceeded or when the first motor 112A begins to operate outside the efficiency range, the additional motors 112B-D may be engaged. The additional motors 112B-D may each provide the same amount of additional power and torque. Alternatively, the additional motors 112B-D may be engaged in an incremental manner. For example, the second motor 112B may be engaged to assist the first motor 112A when the capacity of the first motor 112A is exceeded or when the first motor 112A begins to operate outside the efficiency range. When the capacity of the first motor 112A and the second motor 112B are exceeded or when the first motor 112A and the second motor 112B begin to operate outside the efficiency ranges, then the third motor 112C may be engaged. Likewise, the fourth motor 112D would engage when the capacity/efficiency of the first through third motors 112A-C are exceeded. Similar to the embodiment explained above, the motor 112A-D which acts as the primary power source for the vehicle 10 may alternate among the first through fourth motors 112A-D to maintain even overall wear on the first through fourth motors 112A-D.

Additionally, any one of the first through fourth motors 112A-D may act as the primary motor in case of mechanical trouble of one of the other motors 112A-D. For example, if the first motor 112A is acting as the primary motor and incurs mechanical trouble the second motor 112B may then be used as the primary motor and the first motor may be disengaged until the mechanical trouble can be corrected. In the instance of trouble for any of the motors 112A-D then the motor 112A-D chosen to be the primary motor and the additional operating motors 112A-D would not be able to meet the full capacity of the vehicle 110. However, the vehicle 110 would operate in a restricted or limp-home mode but would allow the vehicle 110 operator to reach their destination.

FIG. 3 is a graph which illustrates how the output of the first through fourth motors 112A-D may be combined to allow the first through fourth motors 112A-D to primarily operate within their efficiency ranges while combining to provide the capacity required by the vehicle 110. Phase 0 indicates the output of the first motor 112A. Phase 1 indicates the output of the second motor 112B as operating along with the first motor 112A such that the torque output is increased. Phase 3 indicates the output of the motors when the first through third motors 112A-C are operating together and Phase four indicates the output of all the motors 112A-D operating at the same time. The efficiency range for the motors 112A-D is indicated at area 120. By adding the outputs of the motors 112A-D together each of the motors 112A-D each motor can continue to operate within the efficiency range 120 while providing an increase in the total output torque.

FIG. 4 schematically illustrates a third embodiment of a vehicle 210 having first motor 212A and a second motor 212B. The first motor 212A and the second motor 212B are coupled directly together. Direct coupling of the first motor 12A to the second motor 12B provides an efficient arrangement with few losses. The first motor 212A has a first input member 222A and a first output member 224A. Likewise, the second motor 212B has a second input member 222B and a second output member 224B. The first output member 224B is connected to the second input member 224A. In the embodiment shown, the first and second input members 222A and 222B are female input shafts and the first and second output members 224A and 224B are male output shaft. However, any arrangement of input members 222A-B and output members 224A-B that would mate together may be

The first motor 212A and the second motor 212B are identical and have the same input members 222A-B and output members 224A-B. Additional motors (not shown) may be connected to the first and second motors 212A-B and would have the same input members and output members. Therefore, any number of motors 212 may be connected in any order as required to provide the capacity of the vehicle 210.

In the embodiment shown in FIG. 4, the second motor 212B is connected to the transmission 214 and acts as the primary motor to drive the vehicle 210 while operating at steady speeds. The first motor 212A acts as an additional power source and engages to drive the vehicle 210 when additional operating toads are placed on the motors 212A-B, such as during accelerations of the vehicle 110. The first motor 212A would engage any time the operating loads exceed the capacity of the second motor 212B. Alternatively the first motor 212A may be engaged prior to reaching the capacity of the second motor 212B and at any time when the second motor 212B begins to operate outside of the desired efficiency range. In this manner, the first motor 212A and the second motor 212B may both operate within their efficiency range for greater periods of time and the overall vehicle 210 efficiency will be increased.

In the above embodiment, the second motor 212B is the primary motor for the vehicle 210 and the first motor 212A is used to provide additional power and torque when required by the vehicle 10. Alternatively, the first motor 212A may be the primary motor and the second motor 212B may be used to provide additional power and torque. Additionally, the first motor 212A and the second motor 212B may alternately be the primary motor and the other would provide the additional power and torque. In this manner, even overall wear on both the first motor 212A and the second motor 212B may be maintained. The first motor 212A has a first rotor 226A and the second motor 212B has a second motor 226B. Due to the direct connection between the first motor 212A and the second motor 212B the rotor 226A or 226B of the additional motor 212A or 212B would continue to rotate while the primary motor 212B or 212A operates even though the additional motor 212A or 212B is not operating.

Additionally, either the first motor 212A or the second motor 212B may act as the primary motor if case of mechanical trouble of the other motor 212A-B. In this instance the primary motor 212B or A would not be able to meet the full capacity of the vehicle 210. However, the vehicle 210 would operate in a restricted or limp-home mode but would allow the vehicle 210 operator to reach their destination.

FIG. 5 schematically illustrates a fourth embodiment of a vehicle 310 having a first motor 312A and a second motor 312B. The first motor 312A has a first input member 322A and a first output member 324A. Likewise, the second motor 312B has a second input member 322B and a second output member 324B.

The first motor 312A is connected to the second motor 312B through a first clutch 328A. That is, the first clutch 328A has a first clutch input member 330A and a first clutch output member 330B. The first motor output member 324A is connected to the first clutch input member 330A and the first clutch output member 332A is connected to the second motor input member 322B.

The second motor 312B is connected to a transmission 314 for the vehicle 310 through a second clutch 328B. That is, the second clutch 328B has a second clutch input member 330B and a second clutch output member 332B. The second motor output member 324B is connected to the second clutch input member 330B and the second clutch output member 332B is connected to the transmission 314.

The first motor 312A, the second motor 312B, the first clutch 328A and the second clutch 328B are generally identical and each have the same input members 322A-B, 330A-B and output members 324A-B, 332A-B as one another. Additional motors and clutches (not shown) may be connected to the first and second motors 312A-B and the first and second clutches 328A-B and would have the same input members and output members. Therefore, any number of motors 312 may be connected through the clutches 328A-B as required to provide the capacity required by the vehicle 310.

In the embodiment shown, the first and second motor input members 322A and 322B are female input members and the first and second motor output members 324A and 324B are male output members. Likewise, the first and second clutch input members 330A-B are female input members and the first and second clutch output members 332A-B are mate output members. However, any arrangement of input members 322A-B, 330A-B and output members 324A-B, 332A-B may be utilized which would allow the first and second motors 312A-B to be connected through the first and second clutches 328A-B

In the embodiment shown, the second motor 312B is connected through the second clutch 328B to the transmission 314 and acts as the primary motor and to drive the vehicle 310 is operating at steady speeds. The first motor 312A acts as an additional power source and engages to drive the vehicle 310 when additional operating loads are placed on the motors 312A-B, such as during accelerations of the vehicle 110. The first motor 312A would engage any time the operating loads exceed the capacity of the second motor 312B. Alternatively, the first motor 312A may be engaged prior to reaching the capacity of the second motor 312B and at any time when the second motor 312B begins to operate outside of the desired efficiency range. In this manner, the first motor 312A and the second motor 312B may both operate within their efficiency range for greater periods of time and the overall vehicle 310 efficiency will be increased.

The first motor 312A has a first rotor 326A and the second motor 312B has a second motor 326B. The first rotor 326A does not rotate when the second motor 312B is operating and the first motor 312A is not operating. This is due to the first motor 312A and the second motor 312B being connected through the clutch 328A which can be disengaged when the first motor 312A is not operating.

Additionally, the first motor 312A or the second motor 312B may act as the primary motor if case of mechanical trouble of the other motor 312A or 312B. In this instance the primary motor 312B or 312A would not be able to meet the full capacity of the vehicle 310. However, the vehicle 310 would operate in a restricted or limp-home mode but would allow the vehicle 310 operator to reach their destination.

In the embodiment described above the motors 12, 112, 212, 312 are described as being generally identical to one another. That is, the motors 12, 112, 212, 312 have the same general size, capacity and preferably configuration of one another. Alternatively, this may mean for a particular vehicle 10, 110, 210, 310 configuration the motors 12, 112, 212, 312 of that vehicle 10 are able to be used interchangeably with one another.

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.

Claims

1. A system for powering a vehicle comprising: a primary motor and a secondary motor operatively connected with one another to drive the vehicle through an operable connection to the secondary motor,wherein the primary motor and the secondary motor are selectively engageable to operate within a predetermined efficiency range

2. The system of claim 1 wherein the primary motor and secondary motor are coupled together indirectly.

3. The system of claim 2 wherein the primary motor and secondary motor are coupled together using a serpentine belt.

4. The system of claim 1 wherein the primary motor and secondary motor are substantially the same capacity.

5. The system of claim 1 further comprising a third motor and a fourth motor.

6. The system of claim 5 wherein the secondary motor, the third motor, and fourth motor are configured to be engaged incrementally, independent of one another.

7. The system of claim 5 wherein the primary motor, the secondary motor, the third motor, and fourth motor are coupled together indirectly.

8. The system of claim 7 wherein the primary motor, the secondary motor, the third motor, and fourth motor are coupled together using a serpentine belt.

9. The system of claim 5 wherein the primary motor, the secondary motor, the third motor, and fourth motor are coupled together directly.

10. The system of claim 9 wherein the primary motor, the secondary motor, the third motor, and fourth motor are coupled together using direct shaft connections.

11. The system of claim 9 wherein the primary motor, the secondary motor, the third motor, and fourth motor are coupled together using a series of clutches.

12. A system for powering a vehicle, comprising: a first motor and a second motor that are operatively connected with one another to power the vehicle individually or in combination with one another such that each motor operates in a predetermined efficiency range;wherein the second motor is configured as a primary motor and operably couple to drive the vehicle; andwherein the first motor provides an auxiliary power source to the second motor and is configured to selectively engage the second motor when an operating load exceeding a capacity of the second motor is placed on the second motor, wherein the primary motor status alternates between the first and second motors.

13. The system of claim 12. wherein the first motor and second motor are coupled together indirectly.

14. The system of claim 12 wherein the first motor and second motor are coupled together using a serpentine belt.

15. The system of claim 12 wherein the first motor and second motor are substantially the same capacity.

16. The system of claim 12 further comprising a third motor and a fourth motor.

17. The system of claim 16 wherein the first motor, the third motor, and fourth motor are configured to be engaged incrementally, independent of one another.

18. The system of claim 16 wherein the first motor, the second motor, the third motor, and fourth motor are coupled together indirectly.

19. The system of claim 18 wherein the first motor, the second motor, the third motor, and fourth motor are coupled together using a serpentine belt.

20. The system of claim 16 wherein the first motor, the second motor, the third motor, and fourth motor are coupled together directly.