Abstract: An ink tank for an ink jet printer is provided. The ink tank includes a tank body, a sponge disposed in the tank body, for absorbing and storing ink, an air flow member positioned above the sponge, for guiding air outside the ink tank to be induced into the ink tank, a nozzle coupled to one end of the air flow member, for supplying air outside the ink tank to the ink tank, and an air flow hole formed at one side of the tank body connected to the other end of the air flow member, and opened/closed by a sealing means installed on a printer frame according to the movement of the carrier and the ink tank. The air outside the ink tank is supplied only during the printing operation, thereby preventing evaporation of moisture contained in the ink stored in the ink tank. Also, the internal pressure of the ink tank is adjusted to be lower than the atmospheric pressure, thereby preventing leaking of ink.

Abstract: A bubble-jet type ink-jet printing head is provided. The ink-jet printing head includes a nozzle plate in which a plurality of nozzles, through which ink is ejected, are formed, a substrate for supporting the nozzle plate, on which a plurality of heaters having three-dimensionally concave surfaces oppose the plurality of nozzles, respectively, electrodes which are formed on the top surface of the substrate and electrically coupled to each heater so as to apply current to the heater, a plurality of ink chambers which are formed between the bottom of the nozzle plate and the surfaces of the corresponding heaters and filled with ink, and an ink feed channel, formed between the nozzle plate and the substrate so as to connect with the ink chambers, for supplying ink to the ink chambers. Each heater includes a hemispherical member and a flange disposed along the rim of the hemispherical member. The ink feed channel connects with the entire circumference of each ink chamber.

Abstract: An ink jet printer head and method for discharging ink in an ink chamber through a nozzle hole by a fluid pressure of air. The ink jet printer head having a fluid chamber defined on or in a side of a silicon plate to be charged with a fluid, such as air, and a through-hole which communicates with an ink chamber. The ink jet printer head opens the through-hole by operating a piezo-actuator, pressures ink in the ink chamber, and pushes a tail of the ink during ink discharge. Accordingly, uniform shapes of ink droplets can be obtained resulting in a high resolution print.

Abstract: A bubble-jet type ink-jet printhead is provided. The printhead has an ink channel having a simple structure, thereby significantly suppressing clogging of nozzles by particles or solidified ink. The printhead is easy to design and manufacture due to its simple structure, thereby significantly reducing the manufacturing cost. In particular, its simple structure permits flexibility in selecting a wide range of alternative designs and thus patterns in which the nozzles are arranged. Furthermore, the printhead can be manufactured by a fabrication process for a typical semiconductor device, thereby facilitating high volume production.

Abstract: There is provided an inkjet print head including: a substrate; a nozzle plate which forms a space where ink is to be filled between the substrate and the nozzle plate and on which plural orifices for ejecting ink are formed; and heaters which form bubbles to push ink droplets out through the orifices, wherein the heaters are installed on elevation parts elevated from the substrate and inserted into the orifices. According to such a structure, since the orifices for ejecting ink droplets, themselves, act as partition members against adjacent heaters, the structure can be greatly simplified. It becomes possible to control the ejection of ink droplets precisely because there is little possibility that reverse flow occurs when bubbles are expanded.

Abstract: An ink flow path of improved structure in an ink jet printer head includes a first ink channel formed at a right angle to an ink supply path in parallel relation with an ink chamber, a second ink channel formed at a right angle to the first ink channel in parallel relation with the ink supply path across the ink chamber, and a third ink channel connecting the second ink channel to a rear side of the ink chamber of which front side faces the ink supply path. Accordingly, a backflow of ink is prevented during the ink discharge through a nozzle hole, thus print quality is improved.

Abstract: A bubble-jet type ink-jet printhead is provided. When forming a doughnut-shaped bubble, the printhead allows bubbles to be first grown around the heater that surrounds the central axis of the nozzle at regular angles followed by the formation of another bubble between the earlier formed bubbles, thereby forming a larger doughnut-shaped bubble. Accordingly, this can prevent the formation of an unbalanced doughnut-shaped bubble due to variations in local resistance of the heater, which may be caused by a process error. Furthermore, the printhead allows the center of the doughnut-shaped bubble to be set on the central axis of the nozzle thus causing a droplet formed within the doughnut-shaped bubble to be ejected in a normal manner, that is, in a direction vertical to the nozzle plate.

Abstract: A bubble-jet type ink-jet printhead is provided. The bubble-jet type ink-jet printhead includes a substrate, a plurality of chamber walls arranged parallel to one another on the substrate for dividing a chamber into a plurality unit chambers having a predetermined height, which are ink flow areas, a bubble generating means, provided for each unit chamber, which includes two unit heaters spaced apart by a predetermined distance on the substrate, and a nozzle plate, combined above the substrate, in which a plurality of nozzles are formed, each nozzle corresponding to a region between the two unit heaters of each bubble generating means. In this case, ink is supplied from both sides of the unit chamber. The ink-jet printhead is constructed such that a unit chamber is provided for each nozzle and bubbles are generated chamber on both sides of a nozzle within the unit chamber, thereby effectively preventing a back flow of ink while facilitating adjustment of the size of ink droplet ejected through the nozzle.

Abstract: A heater of a bubble-jet type ink jet printhead enabling gray scale and manufacturing method thereof are provided. The heater includes two or more heating elements arranged concentrically around a nozzle. Each of the heating elements is formed in polygonal or annular shape and spaced apart by a different distance from the center of the nozzle. Each heating element is coupled to an electrode for applying heater drive power independently. Thus, the heater drive power is applied to each electrode selectively or in combination, thereby forming bubbles having different volumes.

Abstract: An ink-jet printhead is provided. The ink-jet printhead includes: a substrate, on the rear surface of which a channel having a bottom is formed with a predetermined depth, wherein a plurality of ink feed holes are formed on the bottom of the channel; a nozzle plate which is coupled to a front surface of the substrate and on which a plurality of chamber-orifice complex holes are formed, wherein each chamber-orifice complex hole corresponds to one or more ink feed holes among the plurality of ink feed holes; and a plurality of heaters which is formed on the front surface of the substrate corresponding to the chamber-orifice complex holes, respectively. Accordingly, the ink-jet printhead can effectively increase ink ejection pressure by effectively suppressing a back flow of ink, while providing for a high resolution image by making the volume of a droplet uniform or very small.

Abstract: A bubble-jet type ink jet printhead and manufacturing method thereof are provided. In the printhead, a manifold for supplying ink and a concave ink chamber is integrated with a substrate by being recessed from the same surface of the substrate, and a nozzle palate on the substrate in which a nozzle is formed and a round-shaped heater surrounding the nozzle are integrated without a complex process such as bonding. Thus, this simplifies the manufacturing procedure and facilitates high volume production. Furthermore, the round-shaped heater forms a doughnut-shaped bubble to eject ink, thereby preventing a back flow of ink as well as formation of satellite droplets which may degrade image resolution.

Abstract: A bubble-jet type ink-jet printhead is provided. The ink-jet printhead includes: a substrate; a nozzle plate including a plurality of nozzles, which is separated a predetermined space from the substrate; walls for closing the space between the substrate and the nozzle plate and then forming a common chamber between the substrate and the nozzle plate; a plurality of resistive layers, formed on the substrate within the common chamber corresponding to the plurality of nozzles, each resistive layer encircling the central axis passing through the center of each nozzle; a plurality of pairs of wiring layers formed on the substrate, each pair of wiring layers being connecting to each resistive layer and extending to the outside of the common chamber; and a plurality of pads which are disposed at the outside of the common chamber on the substrate and electrically connected to the wiring layers.

Abstract: An inkjetting device for an inkjet printer includes a plurality of nozzle plates arranged in a parallel line, and a pair of magnets installed on respective upper and lower portions of the nozzle plates. Each nozzle plate includes a pair of parallel levers, which are connected to a bridge at one end portion and separated from each other at the other end portion, and a nozzle orifice to jet ink is formed on a front face of the bridge. Ink is stored in ink chambers respectively formed between the levers of the pairs of parallel levers. By applying an electric current to each lever in the magnetic field formed by the pair of permanent magnets, a Lorentz force affects each lever to move closer to the other one of the pair of parallel levers. Accordingly, the ink is jetted onto printing paper to execute a printing operation.

Abstract: An ink tank for an ink jet printer is provided. The ink tank includes a tank body, a sponge disposed in the tank body, for absorbing and storing ink, an air flow member positioned above the sponge, for guiding air outside the ink tank to be induced into the ink tank, a nozzle coupled to one end of the air flow member, for supplying air outside the ink tank to the ink tank, and an air flow hole formed at one side of the tank body connected to the other end of the air flow member, and opened/closed by a sealing means installed on a printer frame according to the movement of the carrier and the ink tank. The air outside the ink tank is supplied only during the printing operation, thereby preventing evaporation of moisture contained in the ink stored in the ink tank. Also, the internal pressure of the ink tank is adjusted to be lower than the atmospheric pressure, thereby preventing leaking of ink.

Abstract: An apparatus for jetting ink including a magnet, a vibrating plate for imposing a pressure upon an ink chamber and coils attached to the vibrating plate. When an electric signal is applied to the coils, the vibrating plate is deformed by a magnetic force produced between the magnet and the coils. At this time, the ink within an ink chamber is ejected to the outside via a nozzle. The quantity and the speed of the ejected ink can be easily controlled while incorporating a simplified structure and a facilitated manufacturing process. Also, printing at a high resolution can be performed at high speed.

Abstract: A jitter control apparatus is provided.

Abstract: An inkjetting device for an inkjet printer includes an ink chamber formed at a lower portion of a nozzle plate having a plurality of nozzle orifices; a barrier, having a cavity at a respectively opposite position of the nozzle orifices, formed at a bottom face of the ink chamber; and a membrane located between the ink chamber and the barrier. A ball to strike the membrane is received in the cavity and a magnetic vibrator to vibrate the ball is formed at a lower portion of the barrier.

Abstract: A fluid flow regulating valve using a thermal expansion material. The valve includes a body provided with inlet and outlet ports; a displacement control part in the body, the displacement control part containing the thermal expansion material and displaced toward the outlet port when the thermal expansion material expands, thereby regulating a degree of opening of the outlet port; and a heater for heating the thermal expansion material within the displacement control part. The displacement control part includes a container containing the thermal expansion material, the container being coupled to the body and an expansion plate for regulating the degree of opening of the outlet port by being expanded in accordance with an expansion of the thermal expansion material, the expansion plate being hermetically coupled to the container.

Abstract: A hand tremor compensating apparatus for a video camera has a bobbin for supporting and protecting a mirror section. The bobbin has a contact portion with a groove provided therein. A barrel is disposed at an outside of the bobbin. The barrel has a boss in which a post is inserted. The bobbin is slidably mounted on the boss. A rotation restraining section employs a magnetic force to restrain the movement of the bobbin. The magnetic force is an attractive force generated between magnets respectively fixed to the bobbin and the post.