Airflow control via self-closing holes in movable support surface of a printing system, and related devices, systems, and methods

What is claimed is: 1. A printing system, comprising: an ink deposition assembly comprising a printhead arranged to eject a print fluid to a deposition region of the ink deposition assembly; and a media transport assembly comprising a vacuum source and a movable support surface, the movable support surface comprising valves having holes through the movable support surface, and the media transport assembly configured to hold one or more print media against the movable support surface by vacuum suction communicated from the vacuum source through valves, wherein the valves are each configured to transition between a closed state in which airflow through the hole of the respective valve is prevented and an open state in which airflow through the hole of the respective valve is allowed, wherein the valves are configured such that, for each of the valves: on condition of none of the print media covering the respective valve, the respective valve is held in the closed state; and on condition of the respective valve being covered by a print medium of the print media, the respective valve is held in the open state by force applied by the print medium to the respective valve via contact between the print medium and the respective valve with the force applied by the print medium to the respective valve being generated by a weight of the print medium and by a suction force applied to the print medium by the vacuum suction from the vacuum source. 2. The printing system of claim 1 , wherein the valves are biased toward the closed state. 3. The printing system of claim 2 , wherein each of the valves is biased toward the closed state by a biasing force comprising a combination of an internal spring force and a suction force applied to the respective valve from the vacuum suction, with both the spring force and the suction force urging the valve toward the closed state; and wherein each of the valves is configured such that, on condition of a print medium of the print media covering the respective valve, the biasing force is overcome by the force applied by the print medium to the respective valve. 4. The printing system of claim 3 , wherein each of the valves is configured such that the biasing force causes the valve to move to and/or stay in the closed state on condition of none of the print media covering the respective valve. 5. The printing system of claim 1 , wherein each of the valves comprises a flexible reed configured as a cantilever coupled to the movable support surface and moveable via bending between an open position in which the flexible reed allows airflow through the hole of the respective valve and a closed position in which the flexible reed blocks airflow through the hole of the respective valve, the open position of the flexible reed corresponding to the open state of the respective valve and the closed position of the flexible reed corresponding to the closed state of the respective valve. 6. The printing system of claim 5 , wherein each of the valves is biased toward the closed state by an internal spring force generated by the flexible reed of the respective valve and by a suction force applied to the flexible reed of the respective valve from the vacuum suction, with both the spring force and the suction force urging the flexible reed of the respective valve toward the closed position; wherein each of the valves is configured such that the vacuum suction from the vacuum source is routed through the hole of the respective valve to generate the suction force on the flexible reed. 7. The printing system of claim 6 , wherein each of the valves is configured such that, on condition of the respective valve being in the open state and none of the print media covering the respective valve, the biasing force moves the flexible reed to the closed position to transition the respective valve to the closed state. 8. The printing system of claim 6 , wherein each of the valves is configured such that, on condition of the respective valve being in the open state and covered by a print medium of the print media, the force applied by the print medium to the respective valve is sufficient to overcome the biasing force and hold the flexible reed in the open position. 9. The printing system of claim 1 , wherein the media transport assembly further comprises a roller arranged to engage the valves as the valves move past the roller, wherein engagement of the roller with one of the valves transitions the valve to the open state. 10. The printing system of claim 1 , wherein the media transport assembly comprises a vacuum platen supporting the movable support surface, the vacuum platen comprising platen holes that communicate the vacuum suction to the movable support surface; and wherein the movable support surface comprises a belt configured to move over a surface of the vacuum platen. 11. The printing system of claim 1 , wherein the media transport assembly further comprises a roller arranged to transition each of the valves to an open state by engaging each the valves as the valves move past the roller, wherein each of the valves is configured to, after being placed in the open state: on condition of the respective valve being covered by a print medium of the print media, remain in the open state due to the force applied by the print medium to the respective valve; or on condition of none of the print media covering the respective valve, transition to the closed state due to a biasing force applied to the respective valve. 12. The printing system of claim 1 , wherein for each of the valves, the respective valve is configured to, in a state of a print medium of the print media covering the respective valve, be passively actuated from the closed state to the open state by the print medium contacting and applying force to a movable portion of the respective valve. 13. A movable support surface for a printing system, comprising: a flexible belt; and a plurality of valves arranged in the flexible belt to communicate vacuum suction through the flexible belt to hold print media being transported by the movable support surface against the flexible belt, wherein the valves are configured to transition between an open state in which the vacuum suction is communicated through the respective valve and a closed state in which the vacuum suction is blocked through the respective valve, and wherein each of the valves comprises a hole and a flexible reed configured as a cantilever coupled to the flexible belt and moveable via bending between an open position in which the flexible reed allows airflow through the hole of the respective valve and a closed position in which the flexible reed blocks airflow through the hole of the respective valve, the open position of the flexible reed corresponding to the open state of the valve and the closed position of the flexible reed corresponding to the closed state of the valve. 14. The movable support surface of claim 13 , wherein each of the valves is configured to bias the flexible reed to the closed position at least in part via a spring force generated by the flexible reed. 15. The movable support surface of claim 13 , wherein the flexible reed comprises a protrusion configured to extend above a top surface of the movable support surface when the flexible reed is in the closed position. 16. The movable support surface of claim 15 , wherein for each of the valves, the flexible reed of the respective valve is configured to, in a state of a print medium of the print media covering the respective valve, be passively actuated from the closed po