Electrically-powered wheel assembly for a work vehicle having stacked electric motors

The invention claimed is: 1. An electrically-powered wheel assembly for a work vehicle, the wheel assembly comprising: an axle; a wheel configured to rotate relative to the axle, the wheel positioned outward from the axle in a radial direction such that a wheel cavity is defined between the wheel and the axle in the radial direction; a first electric motor configured to rotationally drive the wheel relative to the axle, the first electric motor positioned within the wheel cavity and further configured to receive electric power from a power source, the first electric motor including a first electrical connector; and a second electric motor positioned within the wheel cavity and configured to rotationally drive the wheel relative to the axle, the second electric motor including a second electrical connector configured to engage the first electrical connector of the first electric motor such that the second electric motor is configured to receive electric power through the first electric motor via the first and second electrical connectors. 2. The wheel assembly of claim 1 , wherein the first electric motor and the second electric motor are configured to be independently controlled. 3. The wheel assembly of claim 2 , wherein the first electric motor comprises a first controller configured to control an operation of the first electric motor and the second electric motor comprises a second controller configured to control an operation of the second electric motor. 4. The wheel assembly of claim 3 , wherein the first controller is further configured to receive electric power from the power source and the second controller is further configured to receive electric power through the first electric motor via the first and second electrical connectors. 5. The wheel assembly of claim 1 , wherein the first electric motor and the second electric motor are aligned within the wheel cavity in the radial direction. 6. The wheel assembly of claim 5 , wherein the axle extends from a first end to a second end in an axial direction, the first electric motor and the second electric motor configured to engage the axle such that the first electric motor and the second electric motor are stacked along the axle such that the first electrical connector engages the second electrical connector. 7. The wheel assembly of claim 1 , wherein the first electric motor comprises a stator coupled to the axle and a rotor coupled the wheel, the second electric motor comprising a stator coupled to the axle and a rotor coupled the wheel. 8. The wheel assembly of claim 1 , wherein the wheel defines an access opening configured to provide access to the wheel cavity, the wheel assembly further comprising: an end cap removably coupled to an end of the axle to cover the access opening in a manner that prevents access to the wheel cavity. 9. The wheel assembly of claim 8 , further comprising: an electric circuit configured to supply electric power from the power source to the first electric motor, wherein, when the end cap is decoupled from the end of the axle, the electric circuit is opened such that the supply of electric power to the axle and the first electric motor is halted. 10. The wheel assembly of claim 8 , further comprising: a sensor configured to detect whether the end cap is coupled to the end of the axle; and a controller communicatively coupled to the sensor, the controller configured to: determine when the end cap is decoupled from the end of the axle based on data received from the sensor; and halt the supply of the electric power to the axle and the first electric motor when the end cap is decoupled from the end of the axle. 11. The wheel assembly of claim 8 , further comprising: a spacer configured to slidingly engage the axle such that the spacer is positioned between the second electric motor and the end cap. 12. The wheel assembly of claim 1 , wherein the first electric motor is configured to receive coolant from a coolant source and the second electric motor is configured to receive the coolant through the first electric motor. 13. The wheel assembly of claim 12 , wherein the first electric motor comprises a stator coupled to the axle and the second electric motor comprises a stator coupled to the axle, the stator of the first electric motor defining a first coolant passage configured to receive the coolant from the coolant source, the stator of the second electric motor defining a second coolant passage in fluid communication with and configured to receive the coolant from the first coolant passage. 14. The wheel assembly of claim 1 , further comprising: a rib extending inward from the wheel in the radial direction, wherein at least one of the first electric motor or the second electric motor is coupled to the rib. 15. An electrically-powered wheel assembly for a work vehicle, the wheel assembly comprising: an axle; a wheel configured to rotate relative to the axle, the wheel positioned outward from the axle in a radial direction such that a wheel cavity is defined between the wheel and the axle in the radial direction; a first electric motor configured to rotationally drive the wheel relative to the axle, the first electric motor positioned within the wheel cavity and configured to receive coolant from a coolant source, the first electric motor including a stator coupled to the axle, the stator of the first electric motor defining a first coolant passage configured to receive the coolant from the coolant source; and a second electric motor positioned within the wheel cavity and configured to rotationally drive the wheel relative to the axle, the second electric motor including a stator coupled to the axle, the stator of the second electric motor defining a second coolant passage in fluid communication with and configured to receive the coolant from the first coolant passage of the first electric motor. 16. A method for increasing the output capacity of an electric wheel motor assembly, the electric wheel motor assembly comprising an axle and a wheel configured to rotate relative to the axle, the method comprising: decoupling an end cap from an end of the axle to provide access to a wheel cavity defined between the wheel and the axle, the electric wheel assembly including a pre-existing electric motor including a first electrical connector positioned within the wheel cavity and configured to rotationally drive the wheel relative to the axle; installing an additional electric motor including a second electrical connector within the wheel cavity such that the second electrical connector engages the first electrical connector of the pre-existing electric motor, the additional electric motor configured to rotationally drive the wheel relative to the axle, the additional electric motor further configured to, when installed, receive electric power through the pre-existing electric motor via the first and second electrical connectors; and re-installing the end cap relative to the end of the axle. 17. The method of claim 16 , further comprising: removing a first spacer from the axle after decoupling the end cap, the first spacer having a first length; and installing a second spacer onto the axle after installing the second electric motor, the second spacer having a second length that is less than the first length.