Rotary electric machines and methods of cooling rotary electric machines

What is claimed is: 1. A rotary electric machine, comprising: a stator with a stator winding; a rotor with a field winding supported for rotation about a rotation axis relative to the stator, the rotor defining a coolant channel having an inlet and an outlet; and an excitation winding fixed relative to the rotor and electrically connected to the field winding, wherein liquid coolant that enters the inlet flows outwardly through a portion of the excitation winding to conduct heat away from the excitation winding; wherein: the rotor comprises an end plate fixed in rotation relative to rotor, the end plate arranged axially between the excitation winding and the field winding; the end plate defines a radially outer segment extending between the excitation winding and the field winding; and the end plate defines, within the end plate; a coolant channel radially inner segment extending between the rotation axis and the excitation winding, a radially inner channel of the coolant channel segment fluidly terminating at the excitation winding; and a coolant channel radially outer segment extending between the excitation winding and the field winding, the excitation winding fluidly interposed between the radially outer segment and the rotation axis, wherein the coolant channel radially outer segment extends at least partially about the rotation axis with a circumferential component; and wherein an end turn pocket is defined on an axial face of the end plate, wherein an end turn of the excitation winding is fixed within the end turn pocket, the end turn pocket fluidly coupling the excitation winding end turn to the coolant channel radially inner and outer segments. 2. The rotary electric machine as recited in claim 1 , wherein the rotor comprises a shaft arranged along the rotation axis, the shaft defining the inlet. 3. The rotary electric machine as recited in claim 2 , further comprising a liquid coolant source in fluid communication with the inlet. 4. The rotary electric machine as recited in claim 2 , wherein the shaft has a wall bounding a hollow interior with a feed aperture extending radially therethrough, the inlet in fluid communication with the excitation winding through the hollow interior and the feed aperture of the shaft. 5. The rotary electric machine as recited in claim 1 , wherein the rotor comprises a rotor core supporting the excitation winding and the field winding, the coolant channel extending through the rotor core. 6. The rotary electric machine as recited in claim 5 , wherein the rotor core defines a coolant channel radially inner segment extending between the rotation axis and the excitation winding, the radially inner channel segment fluidly terminating at the excitation winding. 7. The rotary electric machine as recited in claim 5 , wherein the rotor core defines a coolant channel axial segment extending along the field winding, the axial segment fluidly coupling the excitation winding to the outlet. 8. The rotary electric machine as recited in claim 1 , further comprising a rotating rectifier arranged radially between the excitation winding and the rotation axis, wherein the coolant channel extends fluidly through the rotating rectifier. 9. A generator, comprising: a stator having a stator winding; a rotor with a field winding supported for rotation about a rotation axis relative to the stator, the rotor defining a coolant channel having an inlet and an outlet; an excitation winding with an end turn fixed relative to the rotor and electrically connected to the field winding; and a rotating rectifier arranged radially between the excitation winding and the rotation axis, wherein the coolant channel extends fluidly through the rotating rectifier, wherein liquid coolant that enters the inlet flow outwardly through the end turn of the excitation winding to conduct heat away from the excitation winding, wherein: the rotor comprises an end plate fixed in rotation relative to rotor, the end plate arranged axially between the excitation winding and the field windings; the end plate defines a radially outer segment extending between the excitation winding and the field winding; and the end plate defines, within the end plate; a coolant channel radially inner segment extending between the rotation axis and the excitation winding, a radially inner channel of the coolant channel segment fluidly terminating at the excitation winding; and a coolant channel radially outer segment extending between the excitation winding and the field winding, the excitation winding fluidly interposed between the radially outer segment and the rotation axis, wherein the coolant channel radially outer segment extends at least partially about the rotation axis with a circumferential component; and wherein an end turn pocket is defined on an axial face of the end plate, wherein an end turn of the excitation winding is fixed within the end turn pocket, the end turn pocket fluidly coupling the excitation winding end turn to the coolant channel radially inner and outer segments. 10. The generator as recited in claim 9 , wherein the rotor comprises a rotor core supporting the excitation winding and the field winding, the coolant channel extending through the rotor core; wherein the rotor core defines a coolant channel radially inner segment extending between the rotation axis and the excitation winding, the radially inner channel segment fluidly terminating at the excitation winding; wherein the rotor core defines a coolant channel radially outer segment extending between the excitation winding and the field winding, the excitation winding fluidly interposed between the radially outer segment and the rotation axis; and wherein the rotor core defines a coolant channel axial segment extending along the field winding, the axial segment fluidly coupling the excitation winding to the outlet of the coolant channel. 11. An aircraft electrical system, comprising: a generator as recited in claim 9 , wherein the rotor comprises a shaft arranged along the rotation axis, the shaft defining the inlet of the coolant channel; an electrical load connected to the stator winding; and a liquid coolant source in fluid communication with the coolant channel through the inlet of the coolant channel. 12. A method of cooling a rotary electrical machine, comprising: at a rotary electrical machine that includes: a stator with a stator winding, a rotor with a field winding supported for rotation about a rotation axis relative to the stator, the rotor defining a coolant channel having an inlet and an outlet; and an excitation winding fixed relative to the rotor and electrically connected to the field winding, wherein: the rotor comprises an end plate fixed in rotation relative to rotor, the end plate arranged axially between the excitation winding and the field windings; the end plate defines a radially outer segment extending between the excitation winding and the field winding; and the end plate defines, within the end plate; a coolant channel radially inner segment extending, between the rotation axis and the excitation winding, a radially inner channel of the coolant channel segment fluidly terminating at the excitation winding; and a coolant channel radially outer segment extending between the excitation winding and the field winding, the excitation winding fluidly interposed between the radially outer segment and the rotation axis, wherein the coolant channel radially outer segment extends at least partially about the rotation axis with a circumferential component; and wherein an end turn pocket is defined on an axial face of the end plate, wherein an end turn