Vacuum powered lifting mechanism

We claim: 1. A vacuum powered system for moving a movable component movable in opposing first and second directions between first and second positions relative to a fixed structure, comprising: a movable component; a vacuum actuator having a first end and a second end, the first end mounted to the fixed structure, and the second end connected to the movable component, the vacuum actuator configured to move the movable component between a first position and a second position relative to the fixed structure, the vacuum actuator including one or more intake ports configured to connect in fluid communication with a source of vacuum for moving the movable component in a first direction to the first position, and the vacuum actuator including one or more bleed valve ports configured to vent the vacuum actuator to allow the movable component to move in a second direction to the second position. 2. The vacuum powered system of claim 1 , wherein the vacuum actuator comprises an air bellows having a lower end and an upper end, wherein the lower end of the air bellows is attached to a top portion of the movable component, and wherein the upper end of the air bellows is mounted to the fixed structure. 3. The vacuum powered system of claim 2 , wherein the fixed structure includes an air manifold that is connected in fluid communication with the upper end of the air bellows, the air manifold configured to provide a source of vacuum and venting to the air bellows. 4. The vacuum powered system of claim 3 , wherein the air manifold comprises: one or more intake ports for providing vacuum to the air bellows to move the movable component in the first direction to the first position; and one or more bleed valve ports for venting the air bellows to move the movable component in the second direction to the second position. 5. The vacuum powered system of claim 1 , wherein the vacuum actuator comprises a single acting linear vacuum actuator comprising: a cylinder having a first cylinder end and a second cylinder end, the second cylinder end having a seal; a piston disposed in the cylinder for sliding reciprocating movement of the piston within the cylinder; an actuator rod connected to the piston, wherein the actuator rod extends through the seal at the second cylinder end and connects with the movable component; a vacuum connection connected to the first cylinder end for providing vacuum to the single acting linear vacuum actuator to move the movable component in the first direction to the first position; and a bleed valve connected to the first cylinder end for venting the single acting linear vacuum actuator to allow the movable component to move in the second direction to the second position. 6. The vacuum powered system of claim 1 , wherein the vacuum actuator comprises a dual acting linear vacuum actuator comprising: a cylinder having a first cylinder end and a second cylinder end, the second cylinder end having a seal; a piston disposed in the cylinder for sliding reciprocating movement of the piston within the cylinder; an actuator rod connected to the piston, wherein the actuator rod extends through the seal at the second cylinder end and connects with the movable component; a first vacuum connection connected to the first cylinder end for providing vacuum to the dual acting linear vacuum actuator to move the movable component in the first direction to the first position; a second vacuum connection connected to the second cylinder end for providing vacuum to the dual acting linear vacuum actuator to move the movable component in the second direction to the second position; a first bleed valve connected to the first cylinder end for venting the dual acting linear vacuum actuator to allow the movable component to move in the second direction to the second position; and a second bleed valve connected to the second cylinder end for venting the dual acting linear vacuum actuator to allow the movable component to move in the first direction to the first position. 7. The vacuum powered system of claim 1 , wherein the movable component comprises a stowage container. 8. The vacuum powered system of claim 7 , wherein the fixed structure comprises a stationary stowage container housing that houses the vacuum actuator. 9. The vacuum powered system of claim 8 , wherein the stationary stowage container housing comprises an above ceiling closet box. 10. The vacuum powered system of claim 8 , further comprising: one or more elongated tracks in the stationary stowage container housing; and one or more corresponding guide elements on the movable component, the corresponding guide elements movably engaged with the one or more elongated tracks for moving the movable component between the first position and the second position. 11. The vacuum powered system of claim 10 , wherein the one or more elongated tracks comprise a first set of linear tracks that are positioned on opposing inner side walls of the stationary stowage container housing, wherein the one or more corresponding guide elements comprise a second set of linear tracks that are positioned on opposing outer side walls of the stowage container, and wherein the second set of linear tracks are slidably connected to the first set of linear tracks for guiding movement of the stowage container between the first position and the second position. 12. The vacuum powered system of claim 1 , wherein the first position is a stowed position whereby the movable component is stowed, and wherein the second position is a deployed position whereby the movable component is deployed. 13. A method for moving a movable component movable in opposing first and second directions between first and second positions relative to a fixed structure, comprising the steps of: connecting a movable component to a vacuum actuator; applying a source of vacuum to the vacuum actuator through one or more intake ports that are in fluid communication with the vacuum actuator to move the movable component in a first direction to a first position; and venting the vacuum actuator through one or more bleed valve ports that are in fluid communication with the vacuum actuator to move the movable component in a second direction to a second position, the second direction opposite the first direction. 14. The method of claim 13 , further comprising: latching the movable component in the first position after applying the source of vacuum to the vacuum actuator; and latching the movable component in the second position after venting the vacuum actuator. 15. A vacuum powered lifting system for providing lift to a movable component relative to a fixed structure, comprising: a movable component; a vacuum actuator having a first end and a second end, the first end mounted to the fixed structure, and the second end connected to the movable component, the vacuum actuator configured to move the movable component between a raised position and a lowered position relative to the fixed structure, the vacuum actuator including one or more intake ports configured to connect in fluid communication with a source of vacuum for moving the movable component in a first direction to the raised position, and the vacuum actuator including one or more bleed valve ports configured to vent the vacuum actuator to allow the movable component to move in a second direction to the lowered position. 16. The vacuum powered lifting system of claim 15 , wherein the vacuum actuator comprises an air bellows having a lower end and an upper end, wherein the lower end of the air bellows is attached to a top portion of the movable com