Vibration damage repair in dynamoelectric machines

What is claimed is: 1. A dynamoelectric machine comprising: a stator core having a stator bar slot, wherein the stator bar slot includes an end-iron region, wherein the end-iron region of the stator bar slot is free of stator bar dovetails and side ripple springs therein; a stator bar installed within the stator bar slot, wherein at least a portion of the stator bar slot is within the end-iron region; a cured vibration-absorbing material, including a non-conductive room-temperature vulcanizing silicone, located within the end-iron region and in contact with each of the stator core and the stator bar; and a side ripple spring in contact with one of the stator bar or the stator core, wherein the side ripple spring is positioned between the stator bar and the stator core wholly outside the end-iron region, such that the cured vibration-absorbing material further includes a portion within the end-iron region positioned directly between the stator bar and the stator core. 2. The dynamoelectric machine of claim 1 , wherein the cured vibration-absorbing material also includes a silicone resin, and the side ripple spring includes a fiberglass material impregnated with the silicone resin. 3. The dynamoelectric machine of claim 1 , wherein side ripple spring at least partially includes the cured vibration-absorbing material therein, such that the cured vibration-absorbing material is positioned within the side-ripple spring and the end-iron region of the stator bar slot. 4. A method for reducing vibration damage in a stator, the method comprising: applying, from within a ventilation slot of a stator core, a liquid based vibration-absorbing material onto: a side ripple spring such that the liquid based vibration-absorbing material contacts and enters a trough of the side ripple spring to repair damage to the side ripple spring, the side ripple spring being in contact with a stator bar and the stator core, and an end-iron region of the ventilation slot, the end-iron region being free of stator bar dovetails and side ripple springs therein; and allowing the liquid based vibration-absorbing material to cure, wherein a first portion of the cured vibration-absorbing material remains in contact with the side ripple spring to absorb stator vibrations, and wherein a second portion of the cured vibration-absorbing material remains within the end-iron region directly between the stator bar and the stator core. 5. The method of claim 4 , wherein the cured vibration-absorbing material contacts each of the side ripple spring and the stator core. 6. The method of claim 4 , wherein the liquid based vibration-absorbing material includes a conductive room-temperature vulcanizing silicone. 7. The method of claim 4 , wherein the liquid based vibration-absorbing material includes a non-conductive room-temperature vulcanizing silicone. 8. The method of claim 4 , further comprising preventing the liquid based vibration-absorbing material from entering a stator ventilation slot. 9. The method of claim 4 , wherein the applying includes applying the liquid based vibration-absorbing material onto a vibration-induced cavity of the side ripple spring. 10. The method of claim 4 , wherein the cured vibration-absorbing material increases a lateral stiffness of the stator bar. 11. The method for reducing vibration damage in a stator of claim 4 , wherein the applying, from within the ventilation slot of the stator core, occurs between the side ripple spring and the stator core. 12. The method of claim 4 , wherein the liquid based vibration-absorbing material comprises one of epoxy, polyester, and urethane foam. 13. The method of claim 4 , wherein the cured vibration-absorbing material contacts each of the side ripple spring and an armor of the stator core. 14. The method of claim 4 , wherein the applying of the liquid based vibration-absorbing material includes injecting the liquid based vibration-absorbing material at a non-perpendicular angle relative to a sidewall of the stator bar. 15. The method of claim 14 , wherein the non-perpendicular angle is approximately forty-five degrees relative to the sidewall of the stator bar. 16. A method for repairing a side ripple spring comprising a fiberglass material and reducing vibration damage in a ventilation slot of a stator core, the method comprising: applying a liquid based vibration-absorbing material, including a silicone resin, onto each of: the side ripple spring such that the liquid based vibration-absorbing material contacts and enters a trough of the side ripple spring to repair damage to the side ripple spring, and to impregnate the fiberglass material of the side ripple spring with the silicone resin of the liquid based vibration-absorbing material, wherein the applying occurs within the ventilation slot of the stator core, and an end-iron region of the ventilation slot, the end-iron region being free of stator bar dovetails and side ripple springs therein, such that the side ripple spring is located wholly outside the end-iron region; and allowing the liquid based vibration-absorbing material to cure, wherein a first portion of the cured vibration-absorbing material remains in contact with the side ripple spring for absorbing stator core vibrations, and wherein a second portion of the cured vibration-absorbing material remains within the end-iron region directly between the stator bar and the stator core. 17. The method of claim 16 , further comprising allowing the cured vibration-absorbing material to fill a gap between the side ripple spring and a stator core. 18. The method of claim 16 , wherein the liquid based vibration-absorbing material comprises one of a conductive room-temperature vulcanizing silicone and a non-conductive room-temperature vulcanizing silicone.