Pressure relief systems for generators

What is claimed is: 1. A system for relieving and/or regulating pressure from within a generator casing, comprising: a generator input shaft defining a shaft channel therein; and at least one rotating valve disposed within the shaft channel of the generator input shaft and in fluid communication with an interior of the generator casing and the atmosphere, wherein the rotating valve is configured to allow fluid within the generator casing to flow through the generator input shaft to the atmosphere in an open state and while rotating, wherein the generator shaft includes one or more oil collection apertures upstream of the rotating valve and configured to retain oil separated from air due to centrifugal force, wherein the one or more oil collection apertures are ported to the interior of the casing via a port defined in the input shaft to guide oil at least partially radially outward from the aperture, and wherein the rotating valve is configured to prevent fluid within the generator casing from flowing in a closed state, wherein the rotating valve is an axially moving check valve configured to transition from the closed state to the open state when a pressure differential between the generator casing and the atmosphere exceeds a predetermined threshold. 2. The system of claim 1 , wherein the axially moving check valve includes a spring member sized to provide closing force up to the predetermined pressure differential threshold. 3. The system of claim 1 , further comprising a separator disposed within the casing upstream of the rotating valve, the separator configured to separate oil from air. 4. The system of claim 1 , further comprising one or more relief holes defined through the generator shaft, wherein the shaft channel is in fluid communication with the atmosphere via the one or more relieve holes. 5. The system of claim 4 , wherein the one or more relief holes are disposed in the input shaft. 6. The system of claim 5 , wherein the one or more relief holes extend radially outward from the shaft channel and are angled axially toward a casing exterior. 7. A generator shaft for relieving pressure within a generator casing, comprising a shaft channel defined therein; and at least one rotating valve disposed within the shaft channel of the generator input shaft and in fluid communication with an interior of the generator casing and the atmosphere, wherein the rotating valve is configured to allow fluid within the generator casing to flow through the generator input shaft to the atmosphere in an open state and while rotating, wherein the generator shaft includes one or more oil collection apertures upstream of the rotating valve and configured to retain oil separated from air due to centrifugal force, wherein the one or more oil collection apertures are ported to the interior of the casing via a port defined in the input shaft to guide oil at least partially radially outward from the aperture, and wherein the rotating valve is configured to prevent fluid within the generator casing from flowing in a closed state, wherein the rotating valve is an axially moving check valve configured to transition from the closed state to the open state when a pressure differential between the generator casing and the atmosphere exceeds a predetermined threshold. 8. The shaft of claim 7 , wherein the axially moving check valve includes a spring member sized to provide closing force up to the predetermined pressure differential threshold. 9. The shaft of claim 7 , further comprising a separator disposed within the casing upstream of the rotating valve, the separator configured to separate oil from air. 10. The shaft of claim 7 , further comprising one or more relief holes defined through the generator input shaft, wherein the shaft channel is in fluid communication with the atmosphere via the one or more relieve holes. 11. The shaft of claim 10 , wherein the one or more relief holes are disposed in the input shaft. 12. The shaft of claim 11 , wherein the one or more relief holes extend radially outward from the shaft channel and are angled axially toward a casing exterior. 13. A generator, comprising: a casing; a generator shaft defining a shaft channel therein and disposed at least partially within the casing; and at least one rotating valve disposed within the shaft channel of the generator input shaft and in fluid communication with an interior of the generator casing and the atmosphere, wherein the rotating valve is configured to allow fluid within the generator casing to flow through the generator shaft to the atmosphere in an open state and while rotating, wherein the generator shaft includes one or more oil collection apertures upstream of the rotating valve and configured to retain oil separated from air due to centrifugal force, wherein the one or more oil collection apertures are ported to the interior of the casing via a port defined in the input shaft to guide oil at least partially radially outward from the aperture, and wherein the rotating valve is configured to prevent fluid within the generator casing from flowing in a closed state, wherein the rotating valve is an axially moving check valve configured to transition from the closed state to the open state when a pressure differential between the generator casing and the atmosphere exceeds a predetermined threshold. 14. The generator of claim 13 , wherein the axially moving check valve includes a spring member sized to provide closing force up to the predetermined pressure differential threshold. 15. The generator of claim 13 , further comprising a separator disposed within the casing upstream of the rotating valve, the separator configured to separate oil from air. 16. The generator of claim 13 , further comprising one or more relief holes defined through the generator shaft, wherein the shaft channel is in fluid communication with the atmosphere via the one or more relieve holes. 17. The generator of claim 13 , wherein the generator is a variable frequency generator.