Variable cooling flow

What is claimed is: 1. A rotary vane actuator comprising: a stator having at least one vane stop projecting from an inner circumferential surface of a central chamber of the stator, and a first fluid port and a second fluid port defined in an interior wall of the stator; and a rotor having at least one vane projecting from a central rotatable longitudinal shaft, said rotor rotatably disposed in the stator, said vane including a sealing element disposed on a distal end of the vane and said sealing element adapted to contact the inner circumferential surface of the stator; wherein said vane is adapted to contact said stop of the stator, and a high pressure chamber is defined by the stator and a first side of the vane and a low pressure chamber is defined by the stator and a second side of the vane; wherein said actuator further includes at least a first aperture spaced apart from the first fluid port and the second fluid port, and said actuator further includes at least a second aperture and spaced apart from the first fluid port and the second fluid port; and wherein a fluid flow passage comprising a gap between an outer surface of the stator and a housing of the actuator connects the first aperture to the second aperture; wherein the fluid flow passage and first and second apertures connect the high pressure chamber to the low pressure chamber when said vane is proximal to contact with said stop of the stator. 2. A rotary vane actuator comprising: a stator having at least one vane stop projecting from an inner circumferential surface of a central chamber of the stator, and a first fluid port and a second fluid port defined in an interior wall of the stator; and a rotor having at least one vane projecting from a central rotatable longitudinal shaft, said rotor rotatably disposed in the stator, said vane including a sealing element disposed on a distal end of the vane and said sealing element adapted to contact the inner circumferential surface of the stator; wherein said vane is adapted to contact said stop of the stator, and a high pressure chamber is defined by the stator and a first side of the vane and a low pressure chamber is defined by the stator and a second side of the vane; wherein said actuator further includes at least a first aperture spaced apart from the first fluid port and the second fluid port, and said actuator further includes at least a second aperture and spaced apart from the first fluid port and the second fluid port; and wherein a fluid flow passage comprising a groove in an outer surface of the stator connects the first aperture to the second aperture; wherein the fluid flow passage and first and second apertures connect the high pressure chamber to the low pressure chamber when said vane is proximal to contact with said stop of the stator. 3. A rotary vane actuator comprising: a housing having a bore; a stator disposed within the bore and having at least one vane stop projecting from an inner circumferential surface of a central chamber of the stator, and a first fluid port and a second fluid port defined in an interior wall of the stator; and a rotor having at least one vane projecting from a central rotatable longitudinal shaft, said rotor rotatably disposed in the stator, said vane including a sealing element disposed on a distal end of the vane and said sealing element adapted to contact the inner circumferential surface of the stator; wherein said vane is adapted to contact said stop of the stator, and a high pressure chamber is defined by the stator and a first side of the vane and a low pressure chamber is defined by the stator and a second side of the vane; wherein said actuator further includes at least a first aperture spaced apart from the first fluid port and the second fluid port, and said actuator further includes at least a second aperture and spaced apart from the first fluid port and the second fluid port; and wherein a fluid flow passage comprising a groove in an inner surface of the housing adjacent to the stator connects the first aperture to the second aperture; wherein the fluid flow passage and first and second apertures connect the high pressure chamber to the low pressure chamber when said vane is proximal to contact with said stop of the stator. 4. A rotary vane actuator comprising: a stator having at least one vane stop projecting from an inner circumferential surface of a central chamber of the stator, and a first fluid port and a second fluid port defined in an interior wall of the stator; and a rotor having at least one vane projecting from a central rotatable longitudinal shaft, said rotor rotatably disposed in the stator, said vane including a sealing element disposed on a distal end of the vane and said sealing element adapted to contact the inner circumferential surface of the stator; wherein said vane is adapted to contact said stop of the stator, and a high pressure chamber is defined by the stator and a first side of the vane and a low pressure chamber is defined by the stator and a second side of the vane; wherein said actuator further includes at least a first aperture spaced apart from the first fluid port and the second fluid port, and said actuator further includes at least a second aperture and spaced apart from the first fluid port and the second fluid port; and wherein a fluid flow passage comprising a groove in the central rotatable longitudinal shaft adjacent to the vane connects the first aperture to the second aperture; wherein the fluid flow passage and first and second apertures connect the high pressure chamber to the low pressure chamber when said vane is proximal to contact with said stop of the stator. 5. A method of cooling fluid flow for a rotary vane actuator comprising: providing a stator having at least one stator vane projecting from an inner circumferential surface of a central chamber of the stator, and a first fluid port and a second fluid port defined in an interior wall of the stator; providing a rotor having at least one rotor vane projecting from a central rotatable longitudinal shaft, said rotor rotatably disposed in the stator, said rotor vane including a sealing element disposed on a distal end of the rotor vane; defining a first fluid chamber with the stator, the sealing element, and a first side of the rotor vane; defining a second fluid chamber with the stator, the sealing element, and a second side of the rotor vane; defining a first aperture at a first circumferential location spaced apart from the first fluid port and the second fluid port, and a second aperture, in fluid communication with the first aperture, at a second circumferential location different from the first circumferential location spaced apart from the first fluid port and the second fluid port; contacting the inner circumferential surface of the stator with the sealing element at a third circumferential location between the first circumferential location and the second circumferential location; and flowing a fluid from the first fluid port to the first aperture through the first fluid chamber, to the second aperture, and to the second fluid port through the second fluid chamber, wherein fluidic communication between the first aperture and the second aperture is provided by a fluid flow passage comprising a gap between an outer surface of the stator and a housing of the actuator. 6. A method of cooling fluid flow for a rotary vane actuator comprising: providing a stator having at least one stator vane projecting from an inner circumferential surface of a central chamber of the stator, and a first fluid port and a second fluid port defined in an interior wall of the stator; providing a rotor having at least one rotor vane projecting from a central rotatable longitudinal shaft, said rotor rotatably disposed in