Electrohydrodynamic printer with fluidic extractor

The invention claimed is: 1 . An electrohydrodynamic printer having a fluidic extractor, wherein the extractor is a stream of liquid at a different electrical potential than a printing fluid provided at an extraction opening such that the stream of liquid extracts the printing fluid from the extraction opening when the stream of liquid passes by the extraction opening. 2 . The printer of claim 1 , wherein the extractor is a stream of carrier fluid that merges with extracted printing fluid and carries the printing fluid toward a printing surface. 3 . The printer of claim 1 , wherein the stream of liquid is a continuous stream. 4 . The printer of claim 1 , wherein the stream of liquid is a uniform stream of droplets. 5 . The printer of claim 4 , wherein each of a first portion of the droplets extracts a droplet of the printing fluid and each of a second portion of the droplets does not extract a droplet of the printing fluid. 6 . The printer of claim 5 , wherein the first portion of the droplets carries extracted printing fluid and is directed to a printing surface, and the second portion of the droplets is not directed to the printing surface. 7 . The printer of claim 1 , wherein the stream of liquid is a non-uniform stream of droplets. 8 . A printer, comprising: a first nozzle configured to direct a stream of carrier fluid toward a printing surface; and a second nozzle configured to provide a printing fluid at an extraction opening, wherein the stream of carrier fluid passes by the extraction opening when flowing toward the printing surface, and wherein a difference in electrical potential between the carrier fluid and the printing fluid causes the printing fluid to be extracted from the second nozzle. 9 . The printer of claim 8 , wherein extracted printing fluid merges with the stream of carrier fluid to be carried toward the printing surface. 10 . The printer of claim 8 , wherein the carrier fluid is uniformly pressurized in the first nozzle so that the stream of carrier fluid is a continuous stream. 11 . The printer of claim 8 , wherein a pressure of the carrier fluid in the first nozzle varies at a constant frequency so that the stream of carrier fluid is a uniform stream of droplets. 12 . The printer of claim 11 , further comprising a piezoelectric element configured to deform at said constant frequency to vary the pressure of the carrier fluid in the first nozzle. 13 . The printer of claim 8 , further comprising an electrode located external to the first nozzle, wherein the stream of carrier fluid is charged by the electrode to provide at least a portion of said difference in electrical potential. 14 . The printer of claim 8 , further comprising an electrode configured to charge only a portion of the stream of carrier fluid so that the stream of carrier fluid extracts printing fluid when said portion of the stream of carrier fluid passes by the extraction opening and does not extract printing fluid when an uncharged portion of the stream of carrier fluid passes by the extraction opening. 15 . The printer of claim 8 , wherein a portion of the stream of carrier fluid passes by the extraction opening without extracting printing fluid, said portion of the stream of carrier fluid being collected and returned to a carrier fluid source that supplies the first nozzle with the carrier fluid. 16 . The printer of claim 8 , wherein the printer is a drop-on-demand printer, the stream of carrier fluid being a stream of droplets, each droplet of carrier fluid extracting a droplet of printing fluid from the extraction opening and carrying the respective droplets of printing fluid to the printing surface. 17 . The printer of claim 8 , wherein the carrier fluid has a viscosity that is less than 10 centipoise and the printing fluid has a viscosity that is greater than 30 centipoise. 18 . The printer of claim 8 , wherein said difference in electrical potential is at least 500V and the stream of carrier fluid has a velocity sufficiently high to maintain a gap between the stream of carrier fluid and the extraction opening of the second nozzle. 19 . The printer of claim 8 , wherein the printing fluid is soluble in the carrier fluid and the difference in electrical potential attracts the stream of carrier fluid onto the first nozzle in a cleaning mode of the printer. 20 . The printer of claim 8 , wherein the carrier fluid is liquid.