Vapor deposition and recovery systems for ink-based digital printing

What is claimed is: 1. A dampening fluid delivery system useful for printing with an ink-based digital image forming apparatus having an imaging member with a reimageable surface, the system comprising: a dampening fluid supply chamber having a dampening fluid supply chamber interior, the dampening fluid supply chamber including an inlet tube in contact with a dampening fluid source and a tube portion extending to a closed distal end thereof with the dampening fluid source configured to provide dampening fluid in a vapor state to the reimageable surface, the dampening fluid supply chamber interior defined by the inlet tube and the tube portion, the tube portion having a first split tube portion and a second split tube portion extending to the closed distal end of the split tube, with the first and second split tube portions joining at the closed distal end, the first split tube portion defining a first split tube portion interior, the second split tube portion defining a second split tube portion interior, the first split tube portion interior being in fluid communication with the second split tube portion interior at both the inlet tube and the distal end; a dampening fluid supply channel defining a dampening fluid supply channel interior in communication with the dampening fluid supply chamber interior, the dampening fluid supply channel descending towards the imaging member, the dampening fluid supply channel being configured to deliver fluid vapor from the dampening fluid supply chamber interior onto the reimageable surface of the imaging member; a dampening fluid supply channel outlet configured to enable the dampening fluid supply chamber interior to communicate with the reimageable surface of the imaging member; and a vapor flow restriction border configured to confine dampening fluid vapor provided from the dampening fluid supply channel outlet to a condensation region to support forming the layer of dampening fluid on the reimageable surface via condensation of the dampening fluid vapor over the reimageable surface. 2. The system of claim 1 , further comprising a dampening fluid recovery subsystem configured to remove excess dampening fluid vapor that does not condense over the reimageable surface within the condensation region, the dampening fluid recovery subsystem including: a seal unit having a front seal portion, the front seal portion having an upper wall facing the reimageable surface, the upper wall being configured to define an air flow channel with the reimageable surface; a vapor extraction channel defining a vapor extraction channel interior in communication with the air flow channel, the vapor extraction channel ascending away from the imaging member to deliver the excess dampening fluid vapor from the air flow channel; and a vapor extraction manifold including a vapor extraction chamber defining a vapor extraction chamber interior in communication with the vapor extraction channel interior to collect the excess dampening fluid vapor from the vapor extraction channel, the vapor extraction manifold further including a vapor condensation device configured to cool the excess dampening fluid vapor into a fluid state, the vapor extraction manifold including a dampening fluid output conduit configured to deliver the cooled dampening fluid to the dampening fluid source. 3. The system of claim 1 , the dampening fluid supply channel being configured to deliver fluid vapor from both the first split tube portion and the second split tube portion onto the reimageable surface of the imaging member. 4. The system of claim 3 , the second split tube portion including a first section proximate the inlet tube, a second section proximate the closed distal end, and an interior wall between the first and second sections, the interior wall extending across the second split tube portion interior, the interior wall configured to block dampening fluid communication within the second split tube portion interior between the first section and the second section. 5. The system of claim 1 , the reimageable surface of the imaging member having a printing area having a width parallel to the dampening fluid supply channel, the dampening fluid supply channel outlet configured to enable the dampening fluid supply chamber interior to communicate with the reimageable surface of the imaging member along the width of the printing area. 6. The system of claim 5 , wherein the width is at least 355 mm. 7. The system of claim 2 , further comprising a vacuum source attached to the vapor extraction manifold, the vacuum source configured to move the excess dampening fluid vapor from the air flow channel to the vapor condensation device. 8. The system of claim 7 , the vapor extraction manifold including a vacuum tube between the vapor condensation device and the vacuum source, the vacuum tube being different than the dampening fluid output conduit. 9. The system of claim 2 , the vapor condensation device including a coolant conduit with an input and an output, the coolant conduit housing coolant flowing from the inlet to the outlet thereof. 10. The system of claim 9 , the vapor condensation device further including a copper core, wherein the coolant conduit is a coil wrapped around the copper core. 11. The system of claim 2 , further comprising a dampening fluid distribution manifold attached between the dampening fluid source and the dampening fluid supply chamber, wherein the dampening fluid supply chamber, the dampening fluid supply channel, the dampening fluid supply channel outlet, the vapor flow restriction border, the seal unit and the vapor extraction channel form a first print station configured to print a first image onto a print substrate moving in a process direction, the dampening fluid delivery system further comprising a second print station configured to print a second image related to the first image onto the print substrate downstream the first print station, the second print station including: a second dampening fluid supply chamber having a dampening fluid supply chamber interior, the second dampening fluid supply chamber including a second inlet tube in contact with the dampening fluid source and a second tube portion extending to a closed second distal end thereof, the dampening fluid supply chamber interior defined by the second inlet tube and the second tube portion, a second dampening fluid supply channel defining a second dampening fluid supply channel interior in communication with the second dampening fluid supply chamber interior, the second dampening fluid supply channel descending towards a second imaging member, the second dampening fluid supply channel being configured to deliver fluid vapor from the second dampening fluid supply chamber interior onto a second reimageable surface of the second imaging member, a second dampening fluid supply channel outlet configured to enable the second dampening fluid supply chamber interior to communicate with the second reimageable surface, a second vapor flow restriction border configured to confine dampening fluid vapor provided from the second dampening fluid supply channel outlet to a second condensation region to support forming the layer of dampening fluid on the second reimageable surface via condensation of the dampening fluid vapor over the second reimageable surface, a second seal unit having a second front seal portion, the second front seal portion having a second upper wall facing the second reimageable surface, the upper wall being configured to define a second air flow channel with the second reimageable imaging surface, and a second vapor extraction channel defining a second vapor extraction channel interior in communication with the second a