Ink reservoir with pneumatically driven integrated piston and shut-off valves

What is claimed is: 1. A pneumatic integrated structure comprising: an internal ink reservoir; a reservoir air inlet positioned to allow pressurized air to flow into the internal ink reservoir; a cylinder adjacent the internal ink reservoir; a shaft within the cylinder; an inlet seal connected to the shaft; an outlet seal connected to the shaft; and a piston connected to the shaft, wherein the piston is within the cylinder, wherein the inlet seal, the outlet seal, and the piston are connected to the shaft and move with the shaft, wherein a biasing member contacts the piston and biases the piston in a first direction, and the pressurized air in the cylinder biases the piston in a second direction, opposite the first direction, wherein the shaft is adapted to move to a first position when biased in the first direction, and to a second position when biased in the second direction, wherein positioning the shaft in the first position simultaneously locates the inlet seal to not seal an ink inlet in fluid communication with the internal ink reservoir and positions the outlet seal to seal an ink outlet, wherein positioning the shaft in the second position simultaneously locates the inlet seal to seal the ink inlet and positions the outlet seal to not seal the ink outlet, and wherein the ink inlet and the ink outlet are in fluid communication with the internal ink reservoir. 2. The pneumatic integrated structure according to claim 1 , wherein the internal ink reservoir and the cylinder are connected to the same air pressure source and receive the pressurized air simultaneously, wherein the pressurized air pressurizes ink in the internal ink reservoir. 3. The pneumatic integrated structure according to claim 1 , wherein the inlet seal, the outlet seal, and the piston are aligned relative to a centerline of the shaft. 4. The pneumatic integrated structure according to claim 1 , wherein the shaft is within a body, wherein the internal ink reservoir and the cylinder comprise separate cavities within the body, wherein the body comprises a linear shaft cavity in which the shaft is located, wherein a first end of the linear shaft cavity is in fluid communication with the ink inlet and the internal ink reservoir, wherein a second end of the linear shaft cavity is in fluid communication with the ink outlet and internal ink reservoir, and wherein the pneumatic integrated structure further comprises a shaft cavity seal between the first end of the linear shaft cavity and the second end of the linear shaft cavity preventing fluid from passing through the linear shaft cavity between the first end and the second end. 5. The pneumatic integrated structure according to claim 1 , wherein closure of the ink inlet by the inlet seal prevents pressurized ink within the ink internal reservoir from flowing out the ink inlet. 6. The pneumatic integrated structure according to claim 1 , further comprising a piston seal between the piston and the cylinder. 7. The pneumatic integrated structure according to claim 1 , further comprising a heater positioned to heat the internal ink reservoir. 8. A pressurized ink delivery apparatus comprising: an internal ink reservoir; an ink inlet positioned to allow ink to flow from an ink storage vessel into the internal ink reservoir; an ink outlet positioned to allow ink to flow from the internal ink reservoir out to inkjet printheads; a reservoir air inlet positioned to allow pressurized air to flow into the internal ink reservoir; a pneumatic integrated multi-valve structure positioned within the ink inlet and the ink outlet; a cylinder in which the pneumatic integrated multi-valve structure is positioned; a cylinder air inlet positioned to allow pressurized air to flow into a first portion of the cylinder; and a biasing member within a second portion of the cylinder, wherein the pneumatic integrated multi-valve structure comprises a shaft, an inlet seal connected to the shaft, an outlet seal connected to the shaft, and a piston connected to the shaft, wherein the inlet seal, the outlet seal, and the piston are connected to the shaft and move with the shaft, wherein the biasing member contacts the piston and biases the piston in a first direction, and pressurized air in the first portion of the cylinder biases the piston in a second direction, opposite the first direction, wherein the shaft is adapted to move to a first position when biased in the first direction, and to a second position when biased in the second direction, wherein positioning the shaft in the first position simultaneously locates the inlet seal to not seal the ink inlet and positions the outlet seal to seal the ink outlet, and wherein positioning the shaft in the second position simultaneously locates the inlet seal to seal the ink inlet and positions the outlet seal to not seal the ink outlet. 9. The pressurized ink delivery apparatus according to claim 8 , wherein the reservoir air inlet and the cylinder air inlet are connected to the same air pressure source and receive the pressurized air simultaneously, wherein the pressurized air pressurizes ink in the internal ink reservoir. 10. The pressurized ink delivery apparatus according to claim 8 , wherein the inlet seal, the outlet seal, and the piston are aligned relative to a centerline of the shaft. 11. The pressurized ink delivery apparatus according to claim 8 , further comprising a body, wherein the internal ink reservoir and the cylinder comprise separate cavities within the body, wherein the body comprises a linear shaft cavity in which the shaft is located, wherein a first end of the linear shaft cavity is in fluid communication with the ink inlet and the internal ink reservoir, wherein a second end of the linear shaft cavity is in fluid communication with the ink outlet and internal ink reservoir, and wherein the pneumatic integrated multi-valve structure further comprises a shaft cavity seal between the first end of the linear shaft cavity and the second end of the linear shaft cavity preventing fluid from passing through the linear shaft cavity between the first end and the second end. 12. The pressurized ink delivery apparatus according to claim 8 , wherein closure of the ink inlet by the inlet seal prevents pressurized ink within internal ink reservoir from flowing out the ink inlet. 13. The pressurized ink delivery apparatus according to claim 8 , further comprising a piston seal between the piston and the cylinder. 14. The pressurized ink delivery apparatus according to claim 8 , further comprising a heater positioned to heat the internal ink reservoir. 15. A pressurized ink delivery apparatus comprising: an internal ink reservoir; an ink inlet positioned to allow ink to flow from an ink storage vessel into the internal ink reservoir; an ink outlet positioned to allow ink to flow from the internal ink reservoir; a reservoir air inlet positioned to allow pressurized air to flow into the internal ink reservoir; a pneumatic integrated multi-valve structure positioned within the ink inlet and the ink outlet; a cylinder in which the pneumatic integrated multi-valve structure is positioned; and at least one biasing member within the cylinder, wherein the pneumatic integrated multi-valve structure comprises a shaft, an inlet seal connected to the shaft, and an outlet seal connected to the shaft, wherein the inlet seal and the outlet seal are connected to the shaft and move with the shaft, wherein the at least one biasing member biases the shaft between a first direction and a second direction, opposite the first directi