Bonded rotor shaft

1 . A rotor for an electric motor, comprising: a rotor core having a central opening; a shaft disposed within the central opening; at least three protrusions extending into the central opening from the rotor core, the at least three protrusions being fixed to the rotor core, and the at least three protrusions contacting or being within 0.001″ of the shaft without being rotationally fixed thereto; a portion of the central opening forming a circumferential gap disposed between the rotor core and the shaft and between each of the at least three protrusions; and a resin disposed within the circumferential gap. 2 . The rotor according to claim 1 , wherein the circumferential gap comprises a first width and a second width between the rotor core and the shaft, the second width being at least twice the first width, and the first width extending circumferentially around the shaft at least three times a circumferential length of the second width. 3 . The rotor according to claim 2 , wherein a portion of the second width is disposed on each side of each of the at least three protrusions, and the first width extends between each of the portions of the second width. 4 . The rotor according to claim 2 , wherein a portion of the first width is disposed on each side of each of the at least three protrusions, and the second width is centrally located between each of the at least three protrusions. 5 . The rotor according to claim 1 , wherein the rotor core comprises a first non-round portion and the shaft comprises a second non-round portion, the first and second non-round portions being interlocked with each other to rotationally fix the rotor core and shaft together, a lateral gap being disposed between the first and second non-round portions or between a separate key and the first and second non-round portions, the resin being disposed within the lateral gap. 6 . The rotor according to claim 1 , wherein the rotor core comprises a plurality of laminations, the laminations being stacked along the length of the shaft, and each lamination comprising a lamination central opening corresponding to the central opening of the rotor core. 7 . The rotor according to claim 6 , wherein the lamination central openings of a first group of the laminations comprise the at least three protrusions, and the lamination central openings of a second group of the laminations comprise a lamination circumferential gap that extends completely around the shaft without the at least three protrusions. 8 . The rotor according to claim 7 , wherein the first group comprises less than half of the laminations and the second group comprises more than half of the laminations. 9 . The rotor according to claim 1 , wherein the resin is a thermoset resin. 10 . The rotor according to claim 1 , wherein the at least three protrusions contact the shaft around less than 20% of a circumference of the shaft. 11 . The rotor according to claim 1 , wherein the rotor core comprises a first non-round portion and the shaft comprises a second non-round portion, the first and second non-round portions being interlocked with each other to rotationally fix the rotor core and shaft together, a lateral gap being disposed between the first and second non-round portions or between a separate key and the first and second non-round portions, the resin being disposed within the lateral gap, and the rotor core comprises a plurality of laminations, the laminations being stacked along the length of the shaft, and each lamination comprising a lamination central opening corresponding to the central opening of the rotor core. 12 . The rotor according to claim 11 , wherein the circumferential gap comprises a first width and a second width between the rotor core and the shaft, the second width being at least twice the first width, and the first width extending circumferentially around the shaft at least three times a circumferential length of the second width. 13 . The rotor according to claim 12 , wherein the at least three protrusions contact the shaft around less than 20% of a circumference of the shaft, and the resin is a thermoset resin. 14 . The rotor according to claim 13 , wherein the lamination central openings of a first group of the laminations comprise the at least three protrusions, the lamination central openings of a second group of the laminations comprise a lamination circumferential gap that extends completely around the shaft without the at least three protrusions, and the first group comprises less than half of the laminations and the second group comprises more than half of the laminations. 15 . The rotor according to claim 1 , wherein the rotor core comprises second openings located away from the central opening, a permanent magnet being disposed within each of the second openings, and the resin fills a space in each second opening between the rotor core and the permanent magnet, the rotor core comprises a plurality of laminations, the laminations being stacked along the length of the shaft, and each lamination comprising a lamination central opening corresponding to the central opening of the rotor core, and the resin is a thermoset resin. 16 . A method of manufacturing a rotor for an electric motor, comprising: placing a rotor assembly in a mold, the rotor assembly comprising: a rotor core having a central opening; a shaft disposed within the central opening; at least three protrusions extending into the central opening from the rotor core, the at least three protrusions being fixed to the rotor core, and the at least three protrusions contacting the shaft without being rotationally fixed thereto; and a portion of the central opening forming a circumferential gap disposed between the rotor core and the shaft and between each of the at least three protrusions; and injecting resin into the mold, wherein the resin fills the circumferential gap. 17 . The method according to claim 16 , wherein the mold fully encompasses the rotor core, wherein the resin completely fills any open spaces in the rotor core. 18 . The method according to claim 17 , wherein the rotor core comprises a second opening located away from the central opening, and the rotor assembly comprises an additional component disposed in the second opening and only partially filling the second opening, wherein the resin fills a space in the second opening between the rotor core and the additional component. 19 . The method according to claim 18 , wherein the additional component is a permanent magnet. 20 . The method according to claim 19 , wherein the resin is a thermoset resin.