TH64578B - Narrow-jet print head - Google Patents

Abstract

DC60 (02/04/45) Narrow-jet print head (100), which has the four (61) column-shaped array of the ink drop generator (40) configured for pass printing. The same time as a single color at the print resolution which has the center axis point spacing. Which is less than the interval Of the column-shaped nozzle of the ink drop generator, the ink jet print head, as well as the That is a T3 resistance in particular. The heater resistor (56) and the powerful FET drive circuit (85), which are to be framed. To compensate for variations In the parasitic resistance represented by the force trace (86a, 86b, 86c, 86d, 181), the narrow ink jet print head (100) with the four (61) column-like sequences of the dropper generator. Ink (40) that is configured for one-pass printing in one color at print resolution with a spaced axis of the medium. Which is less than the interval Of the column-shaped nozzles of the ink droplet generator, the ink jet nozzle, as well as the That is a T3 resistance in particular. The heater resistor (56) and the powerful FET drive circuit (85), which are to be framed. To compensate for variations In parasitic resistance shown by force traces (86a, 86b, 86c, 86d, 181).

Claims (2)

1. Ink jet print head Which contains the following components Print head stratters (11), including thin film layers, four (61) column-like sequences, lined up of A drip generator (40) built into the print head chopper. It and extends along the longitudinal boundary. Each column-shaped array of the generator Drip Generating droplets separated by pitch At least 100 P drop generators, the four column-shaped arrays of the machine Give birth to the accompanying drops With a sequence shaped like a pole One and the second column-shaped array, most strongly separated, 630 m, and the array-shaped array. Like the third pillar And an array shaped like the fourth column This is a maximum separation of 630 μm. Such droplet generators produce the ink droplets of a given color. Same advance And which has the volume of ink droplets which open the way Provides one-pass single-color printing at 1 / (4p) dpi along the printed axis parallel to that longitudinal region. Four pillar-shaped arrays (81) of the FET (85) thrusters built in Restrain such printheads in an array with the column-like shape following them in order. Of the droplet generators for the column-shaped excitation energy of the array The aforementioned of the drip generator 2. The print head as stated in claim 1 still includes a section. It is the first (71) and second (71) ink inlet, and where the aforementioned first column-like array of the droplet generator and the second pillar-shaped array are as follows. Of the droplet generator placed on either side of one of the ink feed slots. The third column-like sequence of the drip generator and the fourth column-like sequence of the drip generator is placed on top. Either side of the second ink feed slot 3. The printhead is indicated in claim 2, where the array with Shaped like a second pillar As such of the drip generator and The third column-like array of the drip generator is separated at a maximum of 800 μm. 4. The print head is indicated in claim 1, where P is in the range equal to 1/300. Inch to 1/600 inch 5. Print head as stated in claim 1 where the machine gives The origin of such drops will be arranged. A frame to shoot drops, which has The volume of ink droplets in the range equal to 12 to 19 picoliters 6. Print head as stated in claim 1 provided that The blob generator is configured to fire the droplet, which has The volume of ink droplets in a range equal to 37 picoliters 7. Print head as stated in claim 1 provided that Each dropper generator It will include the resistance part. The resistor of the heater (56), which has a resistance of at least 100 ohms. 8. The printhead, as stated in claim 1, remains the combined ground bus. To the part (181) which will overlap the active area of the aforementioned FET drive circuit 9. The print head as stated in claim 1, where each FET drive circuit has The resistance when active, which is less than (250,000 ohms-micrometers) / A, where A is the driving area of this type of FET is 2 micrometers 1 0. The print head is stated in claim 9 where each FET drive circuit Such have The thickness of the gate oxide (93) is a maximum of 800 angstroms. 1 1. The print head is stated in claim 9 where each FET drive circuit has The length of the gate is less than 4 μm 1 2. The print head is stated in claim 1 where each FET drive circuit has The resistance when activated has a value 14 ohms 1 3. Print head as stated in claim 1 where each FET drive circuit has The resistance when activated has a value At most 16 ohms 1 4. The printhead as stated in claim 1, which is still combined by power. (86a, 86b, 86c, 86d, 181) and where the FET propulsion circuit is configured to compensate for parasitic resistance. 1 5. The print head is indicated in claim 14 where the resistance on the corresponding FET circuit is selected to compensate for the variation. Of resistance to parasites shown 1 6. The print head is indicated in claim 15 where the size of each FET circuit is selected to set the resistance. When this is turned on, 1 7. The print head is stated in claim 15 where each FET cycle will be Including the part that is The drain electrode (87), the area of the drain (89), the exposed drain (88), the drain electrode that is electrically connected to the area Such drains; Tyrannosaurus electrodes (97); Source area (99); A touch of source (98) that the electrical connector is said to Electrical and area of Said source The calculation of the aforementioned drain will be structured to set the definition. Resistance when open These FET circuits work to compensate for the variations in parasitic resistance. Displayed by the traces of the power 1 8. Print head as stated in claim 17 where the Drain area Such will comprise With an area of long drain that includes the That is the part that does not have continuous contact. Each part which There is a length which will be chosen to set the resistance when it is turned on. The pillar-like shape of the FET propulsion circuit is enclosed in a region with a maximum width of 180 μm 2 0. The print head is stated in claim 1, where each array is placed in a maximum width of 180 μm. Pole-shaped As a result of the propulsion circuit, the FET is packaged in a region of the maximum width of 250 μm 2. 1. The print head as stated in claim 1, where the head stratters The print is LS length and WS width and where LS / WS is larger than 3.7 2. 2.Print head as stated in claim 21 where WS is approximately 2900 μm.