JP2005138373A - Liquid ejector and liquid ejecting method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid ejector and a liquid ejecting method capable of preventing degradation in image quality due to color gap. <P>SOLUTION: When the carrying speed of a recording sheet P increases during print operation, a control section 129 controls ejection timing of inks other than black to be delayed before the carrying speed of the recording sheet P is accelerated based on ejection control data dependent on the temperature detected by a temperature sensor 74 and the type of the recording sheet P prestored in a memory section 128. Color gap is prevented by impacting ink other than black at a position to be impacted with black ink. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a liquid ejecting apparatus and a liquid ejecting method in which a liquid is pressed with a pressure generated by a pressure generating element, and the pressed liquid is discharged from a discharge port as a droplet onto an object.

  As an apparatus for ejecting liquid from an ejection port, an ink jet system that records an image or characters by ejecting ink (liquid) from an ejection port of an ink ejection head having a pressure generating element onto a target recording paper There are printer devices. A printer device using this ink jet system has advantages such as low running cost, small device size, and easy colorization of printed images. In a printer apparatus using an ink jet system, for example, ink of a plurality of colors, such as yellow, magenta, cyan, and black, is supplied to an ink liquid chamber of a printer head.

  In this printer apparatus, the ink supplied to the ink liquid chamber or the like is provided corresponding to the ink liquid chamber by pressing the ink in the ink with a pressure generating element such as a heating resistor disposed in the ink liquid chamber. The ink is discharged from a small ink discharge port, so-called nozzle. More specifically, the ink in the ink chamber is heated by the heating resistor disposed in the ink liquid chamber, and bubbles are generated in the ink in the ink liquid chamber. The bubbles grow and pressurize the ink so that the ink is ejected from the nozzles, and the ejected ink is landed on a recording paper or the like as an object to print an image or characters.

  In such an ink jet printer apparatus, in order to perform high-quality printing, it is important to perform printing while keeping the distance between the nozzle and the recording paper constant. For this reason, in the printer apparatus, an appropriate load is applied to the recording paper facing the nozzle surface on which the nozzles are provided in the in-plane direction of the recording paper so that no slack occurs. The distance is kept constant (see Patent Document 1).

  Specifically, in the printer apparatus 201 shown in FIG. 16, when printing on the recording paper P facing the nozzle surface 202a of the ink ejection head 202, the recording paper P conveyed in the direction of arrow X in FIG. Increasing the rotational speed at which the paper discharge roller 204 for printing on the recording paper P and discharging the paper rotates faster than the rotational speed at which the feed roller 203 for feeding the paper rotates about the axis makes slackening. There is no tension in the transport direction.

  However, in this printer apparatus 201, as shown in FIG. 17, the rear end of the recording paper P conveyed in the direction of arrow X in FIG. 17 is the nip point of the feeding roller 203, that is, the feeding roller 203 grabs the recording paper P. 17 is applied to the recording paper P in the direction opposite to the conveyance direction by the feed roller 203 whose rotational speed is slower than that of the paper discharge roller 204, that is, the load applied to the recording paper P in the arrow Y direction in FIG. No longer. For this reason, the conveyance speed of the recording paper P is such that when the trailing end of the recording paper P deviates from the nip point of the feeding roller 203, the load in the reverse conveyance direction by the feeding roller 203 does not act on the recording paper P. The recording paper P is transported only by the paper discharge roller 204 whose rotational speed is faster than that of the paper 203, and becomes faster during printing.

  Further, since the recording paper P expands and contracts in the in-plane direction due to the temperature and humidity during printing, the conveyance speed is also affected by the temperature and humidity. Furthermore, the recording paper P has different grips with the rollers 203 and 204 depending on the type, that is, the gripping state with the rollers 203 and 204 is different, so that the conveyance speed depends on the type.

  For this reason, in the printer apparatus 201, when the trailing edge of the recording paper P deviates from the nip point of the feed roller 203, the conveyance speed of the recording paper P changes rapidly according to the temperature and humidity during printing, the type of the recording paper P, and the like. For this reason, as the transport speed increases during printing, the ink landing position shifts to the counter-transport direction side, so-called color misregistration occurs, and image quality may deteriorate.

  That is, in the printer device 201, when the temperature and humidity are high, a belt connected to a drive motor (not shown) for driving the rollers 203 and 204 becomes longer due to the influence of temperature and humidity, and the pitch of the belt becomes wider. As a result, the tension of the belt is weakened, the feed pitch per pulley tooth provided on the rollers 203 and 204 and over which the belt is engaged is reduced, the conveyance speed of the recording paper P is lowered, and the color misregistration is reduced. Specifically, since the transport speed at room temperature has increased during printing, the ink ejected from the nozzle located upstream in the transport direction of the recording paper P and the ink ejected from the nozzle located downstream If the color shift caused by the landing position shift is 300 μm, when the temperature or humidity increases, the conveyance speed of the recording paper P becomes slow, the color shift becomes, for example, 250 μm, and the color shift becomes smaller than that at normal temperature.

  On the other hand, when the temperature and humidity are low, the belt becomes short due to the influence of temperature and humidity, and the pitch of the belt becomes narrow. As a result, the belt tension is increased, the feed pitch per pulley tooth provided on the rollers 203 and 204 is increased, the conveyance speed of the recording paper P is increased, and the color shift is increased. Specifically, assuming that the color shift caused by the increase in the conveyance speed during printing at room temperature is 300 μm, when the temperature and humidity are low, the conveyance speed of the recording paper P is increased and the color shift is, for example, 350 μm. The color shift becomes larger than at normal temperature.

  Further, in the printer apparatus 201, when the recording paper P is of a type that increases the grip with respect to the rollers 203 and 204, the change in the conveyance speed during printing becomes large and the color misregistration becomes large. , 204 is small, the change in the conveyance speed during printing is small and the color misregistration is small.

JP-A-8-90858

  Therefore, the present invention has been proposed in view of such a conventional situation, and provides a liquid ejection apparatus and a liquid ejection method capable of preventing image quality deterioration due to color misregistration.

  A liquid ejection apparatus according to the present invention that achieves the above-described object has a transport unit that transports an object to which a liquid adheres in a predetermined direction, and a discharge port that discharges the liquid in a droplet state. A discharge unit that discharges droplets from the discharge port toward the object conveyed to a position opposite to the discharge port, a discharge control unit that controls the discharge unit to discharge droplets from the discharge port at a predetermined discharge timing, According to the type of the object, the environment detecting means for detecting the temperature and / or humidity environment when the droplet is discharged from the discharge port, the speed determining means for determining whether or not the conveyance speed of the object has changed, Storage means storing discharge control data for controlling the discharge timing, and stored in the storage means and the environmental data detected by the environment detection means when the speed determination means determines that the conveyance speed of the object has changed. Vomiting Based on the control data, ejection control means so as to eject a droplet from the discharge port at different ejection timings to control the discharge means and before the conveyance speed changes.

  The liquid ejection method according to the present invention includes a transport unit that transports an object to which a liquid is attached in a predetermined direction, and a discharge port that discharges the liquid in a droplet state, and transports the liquid to a position facing the discharge port. A discharge unit that discharges the droplet from the discharge port toward the target object, a discharge control unit that controls the discharge unit to discharge the droplet from the discharge port at a predetermined discharge timing, and a droplet from the discharge port. Environment detection means for detecting the temperature and / or humidity environment at the time of discharge, speed determination means for determining whether the conveyance speed of the object has changed, and discharge control for controlling the discharge timing according to the type of the object A liquid ejecting method for a liquid ejecting apparatus comprising storage means for storing data, the environment data detected by the environment detecting means and the storage means when the speed determining means determines that the conveyance speed of the object has changed Stored in Based on the ejection control data being, the droplets are discharged from the discharge port at a different ejection timings with before conveyance speed changes.

  According to the present invention, when the speed determination unit determines that the transport speed of the object has changed, the transport speed is determined based on the environmental data detected by the environment detection unit and the discharge control data stored in the storage unit. By ejecting droplets from the ejection port at a different ejection timing from before the change, the landing position where the droplets land on the subject due to changes in the transport speed of the subject depends on the type of object and the surrounding environment Shifting in the transport direction is suppressed.

  According to the present invention, since the discharge timing is adjusted based on the environmental data detected by the environment detection unit and the discharge control data stored in advance in the storage unit when the conveyance speed of the target changes, the target It is possible to suppress the landing position of the droplet on the target object from shifting in the transport direction according to temperature and humidity due to the change in the transport speed. Therefore, according to the present invention, it is possible to perform printing with excellent image quality without positional displacement, that is, color misregistration, on a droplet landed on an object.

  Further, according to the present invention, since the discharge timing can be controlled according to the type of the object by the discharge control data, it is possible to suppress the landing position of the liquid droplet from shifting in the transport direction according to the type of the object, It is possible to perform printing with excellent image quality with no color misregistration on droplets landed on different types of objects.

  Hereinafter, an example in which a liquid ejection apparatus and a liquid ejection method according to the present invention are applied to a printer apparatus will be described in detail with reference to the drawings.

  As shown in FIG. 1, a liquid ejecting apparatus (hereinafter referred to as a printer apparatus) 1 to which the present invention is applied ejects a liquid such as ink onto a recording paper P traveling in a predetermined direction to produce images and characters. Is to be printed. That is, an inkjet printer device. In addition, the printer device 1 is a so-called line in which ink discharge ports (nozzles) are arranged in a substantially line shape in the width direction of the recording paper P, that is, in the direction of the arrow W in FIG. Type printer device. Specifically, the printer apparatus 1 shown in FIG. 1 inputs data from an information processing apparatus such as a personal computer by ejecting and landing ink on the recording paper P that is a target to be conveyed in a predetermined direction. An image, a character, or the like composed of ink dots corresponding to the character data, image data, or the like is recorded.

  The printer apparatus 1 includes a printer head cartridge (hereinafter referred to as a head cartridge) 2 that is a liquid discharge head, and a printer body 3 that is an apparatus body to which the head cartridge 2 is mounted.

  In the printer apparatus 1, the head cartridge 2 is handled as a consumable item, and the head cartridge 2 can be attached to and detached from the printer main body 3, so that the replacement can be easily performed.

  First, the head cartridge 2 that can be attached to and detached from the printer main body 3 will be described. This head cartridge 2 is a so-called line type printer head in which a plurality of nozzles 52a, which are ejection openings for ejecting ink, are arranged in a substantially straight line with a length corresponding to the width of the recording paper P in the direction of arrow W in FIG. It is.

  As shown in FIGS. 1 and 2, the head cartridge 2 includes a cartridge main body 12 to which an ink tank 11 that stores ink i is mounted. The cartridge main body 12 includes yellow, Ink tanks 11y, 11m, 11c, and 11k having four colors of cyan, magenta, and black are detachable.

  These four ink tanks 11y, 11m, 11c, and 11k are containers formed in a substantially rectangular parallelepiped shape by, for example, injection molding of a resin material or the like, and contain ink i corresponding to each color inside. Yes. In addition, these four ink tanks 11y, 11m, 11c, and 11k have an inner surface that is in contact with the ink i with a rougher surface than the outer surface so that minute foreign matters such as dust can be easily removed when the inside is cleaned. Is getting smaller. The four ink tanks 11y, 11m, 11c, and 11k have a long shape corresponding to the long side direction of the cartridge body 12 in order to accommodate as much ink as possible. The ink tanks 11y, 11m, 11c, and 11k are arranged side by side in the short side direction of the cartridge body 12. In the following description, it is assumed that the ink tanks 11y, 11m, 11c, and 11k are arranged in order in the conveyance direction of the recording paper P.

  Note that, in these four ink tanks 11y, 11m, 11c, and 11k, the black ink tank 11k that consumes the most ink has a larger capacity than the other ink tanks 11y, 11m, and 11c, and is thicker than the others. It has the same structure except having. The configuration of these ink tanks 11y, 11m, 11c, and 11k will be collectively described as the ink tank 11 below.

  As shown in FIGS. 2 and 3, the ink tank 11 that stores the ink i includes an ink storage portion 21 that is a liquid storage portion that stores the ink i, and the ink i in the ink storage portion 21 to the cartridge body 12. An ink delivery part 22 that is a liquid delivery part to be delivered, an external communication hole 23 that allows the ink storage part 21 to communicate with the outside, and an air introduction tube 24 that introduces external air into the ink storage part 21 from the external communication hole 23. And have.

  The ink storage portion 21 forms a storage space for storing the ink i, and has an inner shape substantially corresponding to the outer shape of the ink tank 11 in order to store as much ink i as possible. Further, the ink containing portion 21 is formed so that the bottom surface portion of the ink containing portion 21 is the deepest at the ink sending portion 22 located at the substantially center, and the ink i contained therein flows into the ink sending portion 22 in a concentrated manner. It is made like that.

  The ink delivery unit 22 is a nozzle that supplies ink i from the ink tank 11 communicated with the ink storage unit 21 to the cartridge body 12, and is provided so as to protrude downward from the lower surface central portion of the ink storage unit 21. Yes. The ink delivery part 22 has a tapered shape whose inner diameter is increased toward the tip so that the ink delivery part 22 can be smoothly fitted to a connecting part 35 of the cartridge body 12 described later.

  As shown in FIG. 3, the external communication hole 23 is provided at the center of the upper surface of the ink containing portion 21. Further, the external communication hole 23 is closed by a sealing member (not shown) having air permeability. Thereby, in the ink tank 11, the ink i is prevented from leaking outside from the external communication hole 23, and dust or the like is generated in the ink storage portion 21 when external air is taken in from the external communication hole 23. Preventing intrusion.

  The air introduction tube 24 extends downward from the external communication hole 23 to the inside of the ink containing portion 21. As a result, in the ink tank 11, when the ink i in the ink containing portion 21 is sent from the ink sending portion 22 to the cartridge body 12, the air corresponding to the decrease in the ink i in the ink containing portion 21. Is taken into the ink containing portion 21 from the external communication hole 23 through the air introduction tube 24.

  In addition, in the middle of the air introduction tube 24, a liquid storage unit that temporarily stores the ink i so that the ink i that has flowed back from the ink storage unit 21 does not suddenly flow out of the external communication hole 23. An ink reservoir 25 is provided. The ink storage portion 25 forms a substantially rhombus-shaped internal space in which the longer diagonal line when viewed from the front is aligned with the long side direction of the ink storage portion 21, and the upper corner portion is the air introduction tube 24. Are communicated with the external communication hole 23, and the lower corner portion is communicated with the ink containing portion 21 via the air introduction tube 24. As a result, in the ink tank 11, the ink storage unit 25 temporarily stores the ink i that has flowed back from the ink storage unit 21 through the air introduction tube 24, so that the ink i does not leak to the outside from the external communication hole 23. The ink i can be returned again to the ink container 21 side.

  Further, as shown in FIGS. 2 and 3, the ink tank 11 has an engaging step portion 26 and a locking protrusion 27 which are fixing means for fixing to a tank mounting portion 31 of the cartridge body 12 described later. doing.

  The engagement step portion 26 is a step portion formed on one end side in the long side direction of the ink tank 11, and a horizontal surface portion 26 a that is parallel to the upper surface portion and lower than the upper surface portion from the side surface portion on the one end side. And an inclined surface portion 26b inclined from the horizontal surface portion 26a toward the upper surface portion.

  The locking projection 27 is a projection formed to project from the side surface portion on the other end side in the long side direction of the ink tank 11, and is positioned below the horizontal surface portion 27a and a horizontal surface portion 27a parallel to the upper surface portion. And an inclined surface portion 27b inclined toward the side surface portion.

  On the other hand, as shown in FIGS. 2 and 3, the cartridge main body 12 has a tank mounting portion 31 in which the ink tanks 11y, 11m, 11c, and 11k corresponding to the above-described colors are mounted.

  The tank mounting portion 31 has a depth sufficient to accommodate the ink tanks 11y, 11m, 11c, and 11k from the upper surface portion of the cartridge main body 12 that is formed in a substantially rectangular parallelepiped shape corresponding to the width of the recording paper P. The bottom surface of the recess is formed by a partition wall 31a so that the ink tanks 11y, 11m, 11c, and 11k are arranged in the short side direction of the cartridge body 12. Yes.

  The black ink tank 11k is thicker than the other ink tanks 11y, 11m, and 11c. Therefore, the tank mounting portion 31 also has a partition wall 31a that partitions the mounting position of the black ink tank 11k. The interval is formed by a predetermined width wider than the interval of the partition walls 31a that partition the mounting positions of the other ink tanks 11y, 11m, and 11c.

  The tank mounting portion 31 is provided with an engaged portion 32, a latch lever 33, and a leaf spring 34 which are fixing means for fixing the ink tank 11 described above.

  The engaged portion 32 is a portion that is engaged with the horizontal surface portion 26 a of the engagement step portion 26 formed in the ink tank 11 described above, and is an open end that is located on one end side in the long side direction of the tank mounting portion 31. Projecting by a predetermined width in the long side direction.

  The latch lever 33 is an elastic displacement piece that protrudes upward from a bottom corner portion located on the other end side in the long side direction of the tank mounting portion 31, and a tip portion of the latch lever 33 with respect to a side surface portion of the tank mounting portion 31. Thus, it can be elastically displaced in the direction of approaching and separating. Further, a locking hole 33 a for locking the locking protrusion 27 of the ink tank 11 described above is formed in the leading end side of the latch lever 33. A latch lever 33 corresponding to each of the ink tanks 11y, 11m, 11c, and 11k is provided along the short side direction of the cartridge main body 12 in the tank mounting portion 31 partitioned by the partition wall 31a.

  The leaf spring 34 is a pressing member that is provided on the bottom surface of the tank mounting portion 31 and presses the ink tank 11 mounted on the tank mounting portion 31 upward. The leaf spring 34 is disposed along the long side direction of the tank mounting portion 31, has one end fixed to the bottom surface portion of the tank mounting portion 31, and an intermediate portion thereof bent upward. ing. A plate spring 34 corresponding to each of the ink tanks 11y, 11m, 11c, and 11k is provided along the short side direction of the cartridge main body 12 on the bottom surface of the tank mounting portion 31 partitioned by the partition wall 31a. Yes.

  When the ink tank 11 is mounted on the tank mounting portion 31, one end side of the ink tank 11 where the engagement step portion 26 is provided is inserted obliquely into the tank mounting portion 31, and the engagement step portion 26 is inserted. While the horizontal surface portion 26a of the ink tank 11 is brought into contact with the engaged portion 32 of the tank mounting portion 31, the other end side of the ink tank 11 provided with the locking projection 27 is shown in FIG. 3 is inserted into the tank mounting portion 31 while rotating in the direction of arrow A. At this time, the locking protrusion 27 of the ink tank 11 elastically displaces the latch lever 33 in a direction close to the side surface of the tank mounting portion 31 by the inclined surface portion 27 b coming into contact with the latch lever 33.

  As shown in FIG. 4, at the same time that the ink tank 11 is mounted on the tank mounting portion 31, the locking protrusion 27 is locked in the locking hole 33 a of the latch lever 33. At this time, the front end portion of the latch lever 33 presses the side surface portion of the ink tank 11 mounted on the tank mounting portion 31, and the leaf spring 34 provided on the bottom surface portion of the tank mounting portion 31 is the bottom surface portion of the ink tank 11. The horizontal surface portion 26a of the engaging step portion 26 is locked to the engaged portion 32 of the tank mounting portion 31, and the horizontal surface portion 27a of the locking protrusion 27 is latched to the latch lever 33. The locking hole 33a is locked. Thereby, the ink tank 11 can be appropriately fixed to the tank mounting portion 31 of the cartridge body 12.

  On the other hand, when removing the ink tank 11 mounted on the tank mounting portion 31, the tip end portion of the latch lever 33 is elastically displaced in a direction away from the side surface portion of the ink tank 11. Thereby, the latching state of the horizontal surface part 27a of the latching protrusion 27 mentioned above and the latching hole 33a of the latch lever 33 is cancelled | released. At this time, as shown in FIG. 3, the plate spring 34 presses the bottom surface of the ink tank 11 toward the direction of the arrow A in FIG. 3, so that the ink tank 11 can be easily removed from the tank mounting portion 31. it can.

  Further, as shown in FIGS. 4 and 5, the cartridge main body 12 to which the ink tank 11 as described above is attached includes a connecting portion 35 connected to the ink delivery portion 22 of the ink tank 11 described above, and this connecting portion. The ink supply unit 36 is a liquid supply unit that supplies the ink i from the ink tank 11 connected to the ink tank 11, and the head unit 37 discharges the ink i supplied by the ink supply unit 36. .

  The connecting portion 35 is a nozzle provided at the center of the bottom surface of the tank mounting portion 31, and the tip of the connecting portion 35 is connected to the ink sending portion 22 described above, thereby being connected to the ink sending portion 22 of the ink tank 11. . Further, when the ink delivery part 22 of the ink tank 11 is connected to the connection part 35, an opening / closing pin (not shown) provided at the tip of the connection part 35 opens the ink delivery part 22. The connecting portion 35 is provided with a seal member 38 such as an O-ring to prevent the ink i from leaking from the connected ink delivery portion 22. In addition, you may make it the front-end | tip part serve as an opening-and-closing pin. That is, a configuration in which the distal end portion of the connecting portion 35 is fitted to the ink delivery portion 22 and the ink delivery portion 22 is opened may be employed. Further, the distal end portion of the connecting portion 35 has a tapered shape whose outer diameter is reduced toward the distal end so as to be smoothly fitted to the ink delivery portion 22 described above.

  At the center of the bottom surface of the tank mounting portion 31 partitioned by the partition wall 31a, connecting portions 35 corresponding to the respective ink tanks 11y, 11m, 11c, and 11k are provided side by side in the short side direction of the cartridge main body 12. ing.

  When ink i is ejected from a nozzle 52a of the head unit 37, which will be described later, the ink supply unit 36 opens a valve (not shown) due to the negative pressure generated on the head unit 37 side, and from the ink storage unit 21 of the ink tank 11. When the ink i is supplied to the head portion 37 and the ink i is supplied from the ink containing portion 21 of the ink tank 11 to the head portion 37 and the pressure on the head portion 37 side returns to the steady state, the valve is closed to close the ink. This is a valve mechanism that stops the supply of the ink i from the ink storage portion 21 of the tank 11 to the head portion 37.

  And the ink supply part 36 repeats the supply operation | movement of the ink i, whenever the ink i is discharged from the nozzle 52a of the head part 37 mentioned later. On the other hand, in the ink tank 11, when the ink i in the ink storage unit 21 is supplied to the ink supply unit 36 side in conjunction with the supply operation of the ink i by the ink supply unit 36 described above, As the ink i decreases, air corresponding to the decreased ink i is introduced into the ink containing portion 21 from the external communication hole 23 through the air introduction tube 24. Accordingly, it is possible to appropriately supply the ink i to the ink supply unit 36 side while keeping the pressure in the ink storage unit 21 in an equilibrium state.

  In addition, an ink supply unit 36 is provided below the connecting unit 35 corresponding to each color described above.

  The head unit 37 is positioned above the discharge surface 41 on which a nozzle 52a (described later) that discharges ink i in the form of droplets is formed, and the ink i is supplied from the ink supply unit 36. An ink supply port 42, an ink flow path 43 that guides ink i supplied from the ink supply port 42 to each nozzle, and a head cap 44 that protects the ejection surface 41 are provided.

  The discharge surface 41 is provided with a plurality of nozzles 52a arranged in a substantially straight line over a length corresponding to the width of the recording paper P. The ink supply port 42 is provided at the center of the upper surface of the ink flow path 43 and communicates with the ink supply unit 36. The ink flow path 43 is provided substantially linearly over a length corresponding to the width of the recording paper P so that the ink i is supplied to each nozzle 52a.

  As shown in FIGS. 1 and 2, the head cap 44 is a cover provided to protect the ejection surface 41 and retracts from the ejection surface 41 during a printing operation. The head cap 44 includes a pair of engaging protrusions 44a provided in the opening / closing direction at both ends in the direction of the arrow W in FIG. 2, and a cleaning roller 44b provided in the longitudinal direction to absorb excess ink i attached to the ejection surface 41. have. The head cap 44 is engaged with a pair of engagement grooves 41a when the engagement protrusion 44a is provided on the discharge surface 41 in a direction substantially orthogonal to the arrow W direction in FIG. The ink tank 11 is opened and closed in a direction substantially perpendicular to the short direction of the ink tank 11, that is, the direction of the arrow W in FIG. In the head cap 44, during the opening / closing operation, the cleaning roller 44 b rotates while being in contact with the ejection surface 41, so that the excess ink i is absorbed and the ejection surface 41 is cleaned. For the cleaning roller 44b, for example, a highly hygroscopic member, specifically, a sponge, a nonwoven fabric, a woven fabric, or the like is used. Further, the head cap 44 closes the ejection surface 41 so that the ink i exposed from the nozzles 52a of the ejection surface 44 is not dried when the printing operation is not performed.

  In addition to the configuration described above, the head portion 37 having such a configuration includes a plurality of ink discharge heads 45 each having a predetermined number of nozzles 52a as a set, and the ink discharge heads 45 are arranged in a staggered manner. That is, the ink discharge heads 45 are arranged so as to be alternately arranged in the width direction of the recording paper P with the ink flow path 43 interposed therebetween.

  As shown in FIG. 6, the ink discharge head 45 is divided into a circuit board 51 as a base, a nozzle sheet 52 formed with a plurality of nozzles 52a, and a section between the circuit board 51 and the nozzle sheet 52 for each nozzle 52a. And an ink liquid chamber 54 that pressurizes the ink i supplied through the ink flow path 43, and a heating resistor 55 that heats the ink i supplied to the ink liquid chamber 54.

  The circuit board 51 forms a control circuit including a logic IC (Integrated Circuit), a driver transistor, and the like on a semiconductor wafer made of silicon or the like, and forms an upper surface portion of the ink liquid chamber 54.

  The nozzle sheet 52 is reduced in diameter toward the discharge surface 41, and a nozzle 52 a having a diameter of about 20 μm on the discharge surface 41 side is provided, and the nozzle sheet 52 is disposed to face the circuit board 51 and the film 53. The lower surface of the ink liquid chamber 54 is formed.

  The film 53 is made of, for example, an exposure curable dry film resist, and is formed so as to surround each nozzle 52a except for the portion communicating with the ink flow path 43 described above. Further, the film 53 is interposed between the circuit board 51 and the nozzle sheet 52, thereby forming a side surface portion of the ink liquid chamber 54.

  The ink liquid chamber 54 is surrounded by the circuit board 51, the nozzle sheet 52, and the film 53 described above, thereby forming a pressurizing space that pressurizes the ink i supplied from the ink flow path 43 for each nozzle 52a.

  The heating resistor 55 is disposed on the circuit board 51 facing the ink liquid chamber 54 and is electrically connected to a control circuit or the like provided on the circuit board 51. The heating resistor 55 generates heat by being controlled by a control circuit or the like, and heats the ink i in the ink liquid chamber 54.

  In the ink discharge head 45, the control circuit of the circuit board 51 drives and controls the heating resistor 55, and supplies a pulse current to the selected heating resistor 55 for about 1 to 3 microseconds, for example. To do. Thereby, in the ink discharge head 45, the heating resistor 55 is rapidly heated. Then, in the ink discharge head 45, as shown in FIG. 7A, bubbles b are generated in the ink i in the ink liquid chamber 54 in contact with the heating resistor 55. In the ink discharge head 45, as shown in FIG. 7B, in the ink liquid chamber 54, the ink i is pressurized while the bubble b expands, and the pushed ink i is in a droplet state. And discharged from the nozzle 52a. In the ink discharge head 45, after the ink i droplet is discharged, the ink i is supplied to the ink liquid chamber 54 through the ink flow path 43, thereby returning to the state before the discharge again.

  In the ink discharge head 45 described above, the film 53 is formed over the entire main surface of the circuit board 51, and the film 53 is formed into a shape corresponding to the ink liquid chamber 54 using a photolithography technique. It is formed by laminating a nozzle sheet 52 thereon.

  The ink discharge head 45 described above employs an electrothermal conversion method in which the ink i is discharged while being heated by the heating resistor 55. However, the present invention is not limited to this method. For example, an electric machine such as a piezoelectric element is used. An electromechanical conversion system in which droplets of ink i are electromechanically ejected by a conversion element may be employed.

  A head unit 37 is provided below the ink supply unit 36 corresponding to each color described above. The bottom surface of the cartridge main body 12 is provided with discharge surfaces 41 of the head portions 37 corresponding to the ink tanks 11y, 11m, 11c, and 11k, respectively, along the short side direction of the cartridge main body 12. These form a continuous discharge surface 41.

  In addition to the configuration described above, the head cartridge 2 configured as described above includes a remaining amount detection unit (not shown) that detects the remaining amount of ink i in the ink storage unit 12 and ink tanks 11y, 11m, 11c, and 11k. An ink tank identifying unit (not shown) for identifying is provided.

  Next, the printer main body 3 to which the head cartridge 2 configured as described above is mounted will be described.

  As shown in FIG. 1, the printer body 3 has a structure assembled inside an outer casing 61 composed of an upper casing 61a and a lower casing 61b in order to prevent dust and the like from entering the inside. doing.

  Further, in the printer main body 3, as shown in FIGS. 8 and 9, the front side of the outer casing 61 is a pair of supports provided on both side surfaces of the upper casing 61a on a frame (not shown) in the lower casing 61b. By supporting the shaft 62, the upper housing 61a can be opened and closed with respect to the lower housing 61b.

  Further, as shown in FIG. 1, a paper supply / discharge port 63 through which the recording paper P is supplied / discharged is provided on the front surface of the outer casing 61. The storage tray 64 for storing the recording paper P is attached to the paper supply / discharge port 63, so that paper can be fed. The recording paper P passes through the paper supply / discharge port 63 and is out of the open end of the storage tray 64. The paper is discharged onto the lid tray 65 that closes the front side.

  The upper housing 61a is provided with a head mounting portion 66 to which the above-described head cartridge 2 is mounted. When the head cartridge 2 is mounted on the head mounting portion 66, the ejection surface 41 of the head cartridge 2 faces a printing position in the lower housing 61b described later. As shown in FIG. 2, a handle portion 67 is attached to the head cartridge 2. Thereby, the head cartridge 2 can be easily attached to and detached from the head mounting portion 66 at the time of replacement.

  Further, as shown in FIG. 1, a lid 61c for closing the head mounting portion 66 is attached to the upper casing 61a so as to be opened and closed. The lid 61c forms an upper surface continuous with the upper housing 61a when the head mounting portion 66 is closed. Further, the lid 61c can be closed even when the head cartridge 2 is mounted on the head mounting portion 66.

  Further, on the upper surface portion of the upper housing 61a, the operation button 68 for performing various operations, the printing state, and the like are displayed on the front side where the recording paper P to be described later is supplied and discharged. A display panel 69 is provided.

  Furthermore, a head cartridge holding mechanism 70 that detachably holds the head cartridge 2 with respect to the head mounting portion 66 when the head cartridge 2 is mounted on the head mounting portion 66 is provided on the upper surface portion of the upper housing 61a. ing. Specifically, the head cartridge holding mechanism 70 includes a biasing member such as a spring (not shown) in a locking hole 70b provided around the head mounting portion 66 of the upper housing 61a. The reference surface 3a provided around the head mounting portion 66 in the printer main body 3 and the outer peripheral surface 2a facing the reference surface 3a of the head cartridge 2 are pressure-bonded to each other. The head cartridge 2 is positioned relative to 61a so that it can be held and fixed. Thereby, the ejection surface 41 of the cartridge main body 12 and the main surface of the recording paper P conveyed to the printing position by a paper supply / discharge mechanism 72 described later can be arranged opposite to each other at a predetermined interval.

  8 and 9, when the head cartridge 2 is mounted on the head mounting portion 66, the head cap 44 attached to the ejection surface 41 of the head cartridge 2 is opened and closed. A head cap opening / closing mechanism 71 that performs recording, a paper feeding / discharging mechanism 72 that transports the recording paper P in a predetermined direction and feeds / discharges the recording paper P to / from the head unit 37, and whether the recording paper P transport speed has changed A speed determining unit 73 for determining whether or not and a temperature sensor 74 for detecting an environmental temperature in the vicinity of the head unit 37 when ink i is ejected are provided.

  The head cap opening / closing mechanism 71 has a drive unit that opens and closes the head cap 44 of the head cartridge 2. When performing printing, the head cap opening / closing mechanism 71 is exposed from the ejection surface 41 so that the ink ejection head 45 is exposed to the recording paper P. When the printing is completed, the head cap 44 is opened and closed with respect to the ejection surface 41 so that the ejection surface 41 is closed with the head cap 44 in order to protect the ink ejection head 45 and prevent the ink i from drying. .

  As shown in FIGS. 8 and 9, the paper supply / discharge mechanism 72 supplies the recording paper P to the head cartridge 2 and discharges the recording paper P printed by the head cartridge 2 to the outside. Is a sheet conveying means for conveying the sheet in a predetermined direction. Specifically, the paper feed / discharge mechanism 72 feeds the recording paper P into the printer body 3 and transports the recording paper P fed by the paper feed unit 81 to the printing position. And a paper discharge unit 83 that discharges the recording paper P conveyed by the conveyance unit 82.

  The paper feed unit 81 serves as a paper feed unit for feeding the recording paper P from the storage tray 64 to the transport unit 82. A paper feed roller 91 that feeds the recording paper P in the storage tray 64 to the transport unit 82; A pair of separation rollers 92a and 92b for sending the recording paper P sent out by the paper feed roller 91 to the transport unit 82 one by one are provided, and these are driving units provided in the lower casing 61b. While being interlocked with each other by a mechanism (not shown), they are rotationally driven in the directions of arrows B1, B2, and B3 in FIG.

  The paper feed roller 91 is disposed above the recording paper P facing the opening end on the back side of the storage tray 64, and the outer peripheral surface thereof is a paper push-up mechanism (not shown) provided in the storage tray 64. ) Can be brought into contact with the recording paper P pushed up.

  The pair of separation rollers 92a and 92b are positioned in the vicinity of the back side of the paper feed roller 91, and are rotationally driven in the same direction while sandwiching the recording paper P fed by the paper feed roller 91 between the rollers. . Thereby, even when the paper feed roller 91 mistakenly feeds two sheets of recording paper P at the same time, one separation roller 92a sends out one sheet of recording paper P in contact with the outer peripheral surface to the transport unit 82 side, The other separation roller 92b sends another sheet of recording paper P in contact with the outer peripheral surface thereof back to the front side storage tray 64, whereby only one sheet can be sent to the back side.

  The conveying unit 82 is reversed by the reversing roller 93 as a conveying unit for conveying the recording paper P from the paper feeding unit 81 to the paper discharging unit 83 and a reversing roller 93 that reverses the feeding direction of the recording paper P. It has a feed roller 94 that conveys the recording paper P to the printing position.

  The reversing roller 93 is disposed on the back side in the printer main body 3 and is rotationally driven in the direction of arrow C in FIG. 9 by a driving mechanism (not shown) provided in the lower housing 61b. Further, on the back side of the reversing roller 93, a plurality of pressing rollers 95 a, 95 b, 95 c that press the recording paper P reversed along the outer peripheral surface of the reversing roller 93 and the outer peripheral surface of the reversing roller 93 are opposed. A curved first regulating plate 96 that regulates the movement of the recording paper P is provided.

  Further, a first guide plate 97 for guiding the recording paper P is provided between the reversing roller 93 and the pair of separation rollers 92a and 92b so as to be positioned on the lower housing 61b side. Further, between the reversing roller 93 and the feed roller 94, a second guide plate 98 that guides the recording paper P, and a plane that faces the second guide plate 98 and restricts the movement of the recording paper P. A second restriction plate 99 is provided on the upper housing 61a side.

  The feed roller 94 is arranged on the upstream side in the transport direction of the recording paper P with respect to the head unit 37, that is, on the reverse roller 93 side, and on the lower housing 61b side with respect to the transported recording paper P. The recording paper P is conveyed by contacting the main surface opposite to the main surface to be printed while rotating about the axis.

  On the upper housing 61 a side of the feed roller 94, a pressing roller 100 is provided to face the feed roller 94 and press the recording paper P against the feed roller 94. As a result, the recording paper P comes into contact with the feed roller 94 by the pressing roller 100 and is properly gripped by the feed roller 94, that is, properly gripped by the outer peripheral surface of the feed roller 94, so It will be transported as appropriate. Note that the pressing roller 100 is rotatable about the axis, and rotates as the recording paper P is conveyed.

  As shown in FIGS. 8 and 9, the paper discharge unit 83 faces the paper discharge roller 101 that conveys the recording paper P printed by the head unit 37 to the paper supply / discharge port 63 side, and the paper discharge roller 101. And a spur 102.

  The paper discharge roller 101 is disposed on the downstream side in the transport direction of the recording paper P with respect to the head unit 37, that is, on the paper supply / discharge port 63 side, and on the lower housing 61b side with respect to the transported recording paper P. The recording paper P is conveyed by being brought into contact with the main surface opposite to the main surface on which the recording paper P is printed while rotating about the axis.

  The spur 102 faces the paper discharge roller 101 on the upper housing 61 side, contacts the printing surface of the recording paper P at a point so that the printed ink is not transferred as much as possible, and from between the paper discharge roller 101. The recording paper P is sent out onto the lid tray 65 on the paper supply / discharge port 63 side. The spur 102 is rotatable about the axis, and rotates as the recording paper P is conveyed.

  In the paper supply / discharge mechanism 72 having such a configuration, as shown in FIG. 10, the feed roller 94 and the paper discharge roller 101 have pulse motors 103a and 103b serving as driving sources, for example, belt pulleys (not shown) such as endless drive belts. And the power is transmitted from each of the pulse motors 103a and 103b. Then, the feed roller 94 and the paper discharge roller 101 are driven to rotate about the axis in the direction of arrow D in FIG. 10 so that the recording paper P conveyed from the reverse roller 93 side is conveyed to the paper supply / discharge port 63 side.

  These rollers 94 and 101 rotate at different rotational speeds, that is, rotate at different rotational speeds, respectively, and the rotational speeds are controlled by the frequency of the pulse current supplied to the pulse motors 103a and 103b. Specifically, the rotation of the discharge roller 101 that prints and discharges the recording paper P at the rotational speed of the feed roller 94 that feeds the recording paper P conveyed in the direction of arrow E in FIG. 10 to the printing position. The speed has been increased.

  As a result, in the paper supply / discharge mechanism 72, when printing is performed on the recording paper P facing the ejection surface 41 of the head unit 37, the recording paper P can be made to be in a tensioned state in the conveyance direction without being slackened. become. Therefore, in the paper supply / discharge mechanism 72, the recording paper P is prevented from being slackened and bent at the printing position, so that the distance between the ejection surface 41 of the head portion 73 and the main surface of the recording paper P is constantly kept constant. Can keep. Note that the frequency of the pulse current supplied to the pulse motors 103a and 103b is controlled by a control unit 129 or the like which will be described later.

  A platen plate 104 is provided between the feed roller 94 and the paper discharge roller 101 so that the recording paper P conveyed to the printing position faces the ejection surface 41 of the head unit 37. The platen plate 104 also functions as a guide plate that guides the leading edge of the recording paper P from the feed roller 94 to the paper discharge roller 101. The platen plate 104 is disposed in parallel with the ejection surface 41 of the head unit 37 described above at a printing position of the recording paper P with a predetermined distance.

  Further, the lower housing 61b is located between a transport position where the transport operation is performed at the time of printing shown in FIG. 9 and a retracted position which is located below the transport position and is retracted when not driven as shown in FIG. A lifting mechanism (not shown) that lifts and lowers the feed roller 94, the discharge roller 101, the platen plate 104, and the like described above is provided.

  In the paper supply / discharge mechanism 72 having the above-described configuration, as shown in FIG. 10, the recording paper P at the printing position is in a state of being tensioned in the conveyance direction, and is thus conveyed in the direction of arrow E in FIG. When the trailing edge of the recording paper P deviates from the nip point of the feeding roller 94, that is, the point where the recording paper P is gripped by the feeding roller 94, the recording paper P is applied to the recording paper P by the feeding roller 94 whose rotational speed is slower than the paper discharge roller 101. The load in the reverse conveyance direction, that is, the direction of the reverse arrow E in FIG. 10 ceases to act, and the conveyance speed is high while the recording paper P is being conveyed and printed only by the paper discharge roller 101 whose rotational speed is faster than the feed roller 94. Become.

  In the printer body 3, as described above, when the conveyance speed of the recording paper P is changed in the paper supply / discharge mechanism 72, it is detected that the conveyance speed of the recording paper P has changed. A speed determining unit 73 is provided as means for determining whether or not the speed is increased.

  As shown in FIG. 10, the speed discriminating unit 73, a rear end detection sensor 111 that detects the rear end of the recording paper P conveyed in the direction of arrow E in FIG. 10, an encoder 112 that detects the rotation state of the feed roller 94, The control unit 129 includes, for example, a CPU (Central Processing Unit) described later.

  The trailing edge detection sensor 111 is disposed upstream of the transport direction with respect to the feed roller 94, specifically, between the second regulating plate 99 and the feed roller 94 and is transported to the printing position. The rear end before entering between the feed roller 94 and the pressing roller 100 in P is detected, and the detected rear end detection data is output to the control unit 129 described later.

  The encoder 112 detects the rotation state of the feed roller 94 and outputs rotation detection data corresponding to the rotation speed of the feed roller 94 to the control unit 129 described later.

  In such a speed discriminating unit 73, the recording paper P is based on the distance between the trailing edge detection sensor 111 and the feeding roller 94 and the feed amount per unit time when the recording paper P is conveyed by the feeding roller 94. When the feed roller 100 rotates after the trailing edge of the trailing edge is detected by the trailing edge detection sensor 111, the trailing edge of the recording paper P reaches the nip point, and immediately after that, the trailing edge of the recording paper P moves away from the nip point. The speed determination data, such as whether or not changes, is stored in advance in the memory unit 128 or the like to be described later. Therefore, in the speed discriminating unit 73, the trailing edge detection sensor 111 detects the trailing edge of the recording paper P, and outputs the detected trailing edge detection data to the control unit 128. Based on the rotation detection data and the speed determination data stored in advance, the control unit 129 can determine that the recording paper P is out of the nip point of the feed roller 94 and the conveyance speed is increased.

  In the above description, the speed determination unit 73 determines whether or not the conveyance speed has been changed by the trailing edge detection sensor 111 and the encoder 112. However, the present invention is not limited to such a configuration. Alternatively, the load applied to the feed roller 94 or the paper discharge roller 101 when the paper is being transported may be directly detected, and it may be determined that the transport speed has changed when the load changes. Further, for example, a load applied to the recording paper P in a tensioned state by the feed roller 94 and the paper discharge roller 101 is detected directly or indirectly, and it is determined that the conveyance speed has changed when the load changes. It may be configured.

  The temperature sensor 74 detects the environmental temperature in the vicinity of the head unit 37 when ejecting the ink i, digitizes it into an information signal, and outputs it as an environmental data to the control unit 129 described later. As shown in FIGS. 8 and 9, the temperature sensor 74 is disposed in the vicinity of the ejection surface 41 so as to be downstream in the transport direction with respect to the head unit 37, specifically along the side surface of the head unit 37. Yes.

  In the control unit 129 to be described later, conveyance speed data relating to the feed amount per time of the recording paper P that varies depending on the temperature is stored in advance in the memory unit 128 to be described later. Based on the environmental data output to the unit 129, how long the recording paper P is conveyed per time, that is, the conveyance speed for each temperature is obtained. Note that the memory unit 128 described later corresponds to the type of the recording paper P because the gripping force with the feeding roller 94 and the paper discharge roller 101 differs depending on the type and thickness of the recording paper P, and the conveyance speed is also different. A plurality of conveyance speed data is stored.

  Here, the case where the temperature sensor 74 determines the conveyance speed of the recording paper P based on the environmental data obtained by detecting the ambient temperature of the head unit 37 has been described as an example, but the present invention is not limited thereto. However, for example, an environment obtained by storing conveyance speed data or the like relating to a conveyance speed that varies depending on the humidity of the recording paper P in the memory unit 128 described later, and detecting the humidity around the head unit 37 with a humidity sensor or the like. The conveyance speed of the recording paper P may be obtained by data. In addition, for example, conveyance speed data relating to a conveyance speed that varies depending on the temperature and / or humidity of the recording paper P is stored in a memory unit to be described later, and the humidity and humidity around the head unit 37 are detected by a temperature / humidity sensor or the like. The conveyance speed of the recording paper P may be obtained from the obtained environmental data.

  Next, the control circuit 121 shown in FIG. 11 for controlling printing by the printer apparatus 1 configured as described above will be described with reference to the drawings.

  The control circuit 121 includes a printer controller 122 that controls driving of the head cap opening / closing mechanism 71 and the paper supply / discharge mechanism 72 of the printer main body 3 described above, currents supplied to the ink discharge heads 45 corresponding to the inks i of the respective colors, and the like. A discharge control unit 123 that controls the remaining amount of ink i of each color, a warning unit 124 that warns the remaining amount of ink i of each color, an input / output terminal 125 that inputs / outputs signals to / from an external device, and a ROM (Read Only) in which a control program is recorded Memory) 126, the read control program and the like are temporarily stored, and a RAM (Random Access Memory) 127 that is read out as necessary, and when the ink i is ejected from the nozzle 52a according to the type of the recording paper P It has a memory unit 128 that stores ejection control data for controlling ejection timing, and a control unit 129 that controls each unit.

  The printer drive unit 122 drives a drive motor (not shown) constituting the head cap opening / closing mechanism 71 based on a control signal from the control unit 129 so as to open / close the head cap 44. 71 is controlled. Further, the printer drive unit 122 drives a drive motor (not shown) constituting the paper supply / discharge mechanism 72 and pulse motors 103 a and 103 b based on a control signal from the control unit 129 to store the printer main body 3. The paper supply / discharge mechanism 72 is controlled so that the recording paper P is fed from the tray 64 and the recording paper P is discharged onto the lid tray 65 from the paper supply / discharge port 63 after printing.

  The ejection control unit 123 is a switching element that turns on / off an electrical connection with an external power source that supplies a pulse current to the heating resistor 55 provided in the ink ejection head 45, and a pulse current value that is supplied to the heating resistor 55. It is an electric circuit which has a control circuit part etc. which control switching of ON / OFF of a resistor which adjusts, a switching element, etc. The ejection control unit 123 adjusts the pulse current supplied to the heating resistor 55 provided in the ink ejection head 45 based on the control signal from the control unit 129, and supplies the ink i from the nozzle 52 a of the ink ejection head 45. The discharge timing when discharging is controlled.

  The warning unit 124 is a display unit such as an LCD (Liquid Crystal Display), for example, and displays information such as a printing condition, a printing state, and an ink remaining amount. The warning unit 124 may be a voice output unit such as a speaker. In this case, the warning unit 124 outputs information such as a printing condition, a printing state, and a remaining amount of ink by voice. The warning unit 124 may be configured to have both a display unit and an audio output unit. In addition, this warning may be given by a monitor or a speaker of the information processing apparatus 130.

  The input / output terminal 125 transmits information such as the above-described printing condition, printing state, ink remaining amount, and the like to the external information processing apparatus 130 and the like via the interface. The input / output terminal 125 receives a control signal for outputting information such as the printing conditions, the printing state, and the remaining ink amount, print data, and the like from the external information processing apparatus 130 or the like. Here, the information processing apparatus 130 described above is an electronic device such as a personal computer or a PDA (Personal Digital Assistant).

  The input / output terminal 125 connected to the information processing apparatus 130 or the like can use, for example, a serial interface or a parallel interface as an interface, and specifically, USB (Universal Serial Bus), RS (Recommended Standard) 232C, IEEE (Institute). of Electrical and Electronic Engineers) 1394. Further, the input / output terminal 125 may perform data communication with the information processing apparatus 130 in any form of wired communication or wireless communication. Note that the wireless communication standards include IEEE 802.11a, 802.11b, 802.11g, and the like.

  A network such as the Internet may be interposed between the input / output terminal 125 and the information processing apparatus 130. In this case, the input / output terminal 125 is, for example, a LAN (Local Area Network) or ISDN (Integrated Services Digital). Network, xDSL (Digital Subscriber Line), FTHP (Fiber To The Home), CATV (Community Antenna TeleVision), BS (Broadcasting Satellite), etc., and data communication is performed by TCP / IP (Transmission Control Protocol / It is performed by various protocols such as Internet Protocol.

  The ROM 126 is a memory such as an EP-ROM (Erasable Programmable Read-Only Memory), for example, and stores a program for each process performed by the control unit 129. The stored program is loaded into the RAM 127 by the control unit 129.

  The RAM 127 is a program read from the ROM 126 by the control unit 129, the rear end detection data or the rotation detection data output from the rear end detection sensor 111 and the encoder 112 to the control unit 129, and the temperature sensor 74. The environmental data output from the control unit 129 to the control unit 129 is stored.

  The memory unit 128 is, for example, a ROM, an EP-ROM, a RAM, or the like, and stores the above-described speed determination data, transport speed data for each type of recording paper P, and the like. In addition to these data, the memory unit 128 also stores ejection control data for each type of recording paper P described above.

  The ejection control data here means color misregistration in which the landing position of the ink i deviates to the anti-conveyance direction when the conveyance speed of the recording paper P becomes faster during printing as in the prior art. This is program data for controlling the ink discharge head 45 by the discharge control unit 123 so as to adjust the discharge timing so as to correct the above.

  Specifically, a description will be given with reference to FIGS. In FIGS. 12A to 12C, each color ink i that has landed on the recording paper P is indicated by y for yellow, m for magenta, c for cyan, and k for black. ing.

  When printing on the recording paper P, as shown in FIG. 12A, the ink tanks 11y, 11m, 11c, and 11c are arranged in order in the conveyance direction of the recording paper P, that is, in the direction of arrow E in FIG. When the ink i of each color is ejected from the nozzles 52a provided on the ejection surface 41 corresponding to 11k onto the recording paper P transported, the ink i of each color is applied to the recording paper P in the order of yellow, magenta, cyan, and black. Are sequentially landed at a predetermined landing position M1. Then, when the conveyance speed of the recording paper P changes during printing, for example, when the trailing edge of the recording paper P is removed from the nip point of the feeding roller 94, as shown in FIG. Since the ink i is sequentially discharged from the nozzles 52a at a predetermined discharge timing, the ink i of each color is landed with a deviation toward the upstream side in the conveyance direction of the recording paper P with respect to the predetermined landing position M1. That is, color misregistration occurs. For such color misregistration, the ejection control data stored in the memory unit 128 controls the ejection control unit 123 to correct the color misregistration and correct the ejection timing of the ink i ejected from each nozzle 52a. As shown in FIG. 12C, the non-black ink i is landed at substantially the same position as the landing position M2 where the black ink i is landed by being shifted to the upstream side in the conveyance direction of the recording paper P. As described above, the ejection timing of the ink i ejected from the nozzles 52a other than the nozzle 52a from which the black ink i is ejected is controlled. Specifically, control is performed so that the ejection timing of the non-black ink i ejected before the black ink i is ejected is delayed from that before the conveyance speed of the recording paper P increases, and the ink i is ejected. The ink i other than black is landed on the landing position M2 where the black ink i is landed.

  Here, how much color misregistration occurs with respect to the landing position M1 of the ink i of each color that occurs at each distance from the leading edge of the recording paper P when the conveyance speed increases during printing, that is, FIG. 13 shows the result of measuring how much the landing position M1 deviates from the landing position M1 to land on the landing position M2. In FIG. 13, y represents the amount of deviation in yellow ink i, m represents the amount of deviation in magenta ink i, c represents the amount of deviation in cyan ink i, and k represents the amount of deviation in black ink i. Is shown.

  From the measurement results shown in FIG. 13, when printing progresses about 250 mm from the leading edge of the recording paper P, the conveyance speed changes and color misregistration begins to occur, and ejection is performed from the nozzle 52 a on the most downstream side in the conveyance direction of the recording paper P. It can be seen that the color shift of the black ink i is the largest. The above-described ejection control data causes the non-black ink i to be ejected at a later ejection timing than before the transport speed is increased, and the black ink i deviation amount shown in FIG. Color misregistration is suppressed so as to be substantially the same.

  In addition, after the color misregistration caused by the change in the conveyance speed is corrected, since the color misregistration occurs on the contrary when the ejection timing of the ink i other than black is delayed, the ejection control data is conveyed again. The ejection control unit 123 is controlled so that each color ink i is sequentially ejected from each nozzle 52a at the ejection timing before the speed changes.

  Generally, in the printer apparatus 1, when the temperature and humidity are high, the endless driving belt that connects the feed roller 94 and the discharge roller 101 and the pulse motors 103a and 103b becomes longer due to the influence of the temperature and humidity. The pitch of the drive belt is widened. As a result, the tension of the endless driving belt is weakened, the feed pitch per pulley tooth provided on the roller 94, the paper discharge roller 101, etc. and the endless driving belt is multiplied is decreased, and the conveyance speed of the recording paper P is decreased. Color shift is reduced. That is, the landing position deviation of the ink i of a different color is smaller when the temperature and humidity are higher than the color deviation caused by the change in the conveyance speed at normal temperature.

  On the other hand, when the temperature and humidity are low, the endless driving belt is shortened due to the influence of temperature and humidity, and the pitch of the endless driving belt is narrowed. As a result, the tension of the endless drive belt is increased, the feed pitch per pulley tooth provided in the roller 94, the paper discharge roller 101, and the like is increased, the conveyance speed of the recording paper P is increased, and the color shift is increased. That is, the landing position shift of the ink i of a different color is greater when the temperature and humidity are lower than the color shift caused by the change in the conveyance speed at normal temperature.

  Therefore, when correcting the color misregistration by the discharge control data, the control unit 129, which will be described later, adjusts the discharge control data based on the environmental data by the temperature sensor 73, and other than black at the discharge timing controlled by the adjusted discharge control data. The ink i is ejected, and the ink i other than black is landed at the landing position M2 where the black ink i is landed.

  In the memory unit 128 storing the discharge control data for controlling the discharge control unit 123 as described above, the gripping force with the feed roller 94 and the discharge roller 101 differs depending on the type and thickness of the recording paper P. Since the degree of change in the conveyance speed is different, that is, the degree of color shift is different for each type of recording paper P, a plurality of ejection control data corresponding to the type of recording paper P is stored.

  The control unit 129 is a CPU, for example, and controls each unit based on the print data input from the input / output terminal 125, the remaining amount data of the ink i input from the head cartridge 2, and the like. The control unit 129 reads out a processing program for controlling each unit based on the input control signal and the like from the ROM 126 and stores it in the RAM 127, and controls and processes each unit based on this processing program.

  That is, the control unit 129 controls the head cap opening / closing mechanism 71 so that the head cap 44 opens and closes based on a processing program stored in the ROM 166, or feeds the recording paper P from the storage tray 64, and after printing. The paper supply / discharge mechanism 72 is controlled to send the recording paper P onto the lid tray 65 of the paper supply / discharge port 63. Further, the control unit 129 appropriately discharges the ink i at a predetermined discharge timing based on the environmental data from the temperature sensor 74 and the conveyance speed data stored in advance in the memory unit 128 before the conveyance speed is increased. When the discharge control unit 123 is controlled or the conveyance speed increases during printing, printing without color misregistration is performed on the recording paper P based on the environmental data and the discharge control data stored in the memory unit 128 in advance. The discharge control unit 123 is controlled as described above.

  In the control circuit 121 configured as described above, the processing program is stored in the ROM 126. However, the medium for storing the processing program is not limited to the ROM 126, and for example, the processing program is recorded. Various recording media such as an optical disc, a magnetic disc, a magneto-optical disc, and an IC card can be used. In this case, the control circuit 121 is configured to be connected to a drive for driving various recording media directly or via the information processing apparatus 130 so as to read a processing program from these recording media.

  Here, the memory unit 128 is configured to store speed determination data, transport speed data, a plurality of ejection control data, and the like. However, if there is a sufficient capacity in the RAM 126 and ROM 127, for example, these data are stored in the RAM 126. And / or may be stored in the ROM 127.

  Here, the printing operation of the printer apparatus 1 configured as described above will be described with reference to the flowcharts shown in FIGS. This operation is executed by arithmetic processing of a CPU (not shown) in the control unit 129 based on a processing program stored in storage means such as the ROM 126.

  First, the printer device 1 executes a printing operation to the control unit 129 by operating an operation button 68 provided on the printer main body 3 or by inputting from the external information processing device 130 via the input / output terminal 125. A command signal is input. At this time, an information signal relating to the type of recording paper P to be printed is also input, and what type of recording paper P is to be printed is set.

  Next, in step S <b> 1, the control unit 129 determines whether or not the ink tank 11 of a predetermined color is mounted on each tank mounting unit 31 and whether the head cartridge 2 is mounted on the head mounting unit 66 of the printer main body 3. Judging. The control unit 129 proceeds to step S2 when the ink tank 11 of a predetermined color is properly mounted on all the tank mounting units 31 and the head cartridge 2 is mounted on the head mounting unit 66 of the printer main body 3. When the ink tank 11 is not properly mounted on the tank mounting portion 31 and / or when the head cartridge 2 is not mounted on the head mounting portion 66 of the printer body 3, the process proceeds to step S4, and the printing operation is prohibited.

  In step S2, the control unit 129 determines whether or not the ink i in the ink tank 11 is equal to or less than a predetermined amount, that is, whether the ink is out, and if it is determined that the ink is out, the warning unit 124 A warning to that effect is issued, and the printing operation is prohibited in step S4. On the other hand, when the ink i in the ink tank 11 is equal to or larger than a predetermined amount, that is, when the ink i is filled, the control unit 129 permits a printing operation in step S3.

  In the printer apparatus 1 that is permitted to perform the printing operation, as shown in FIG. 15, in step S <b> 11, the control unit 129 drives and controls the head cap opening / closing mechanism 71 and the paper supply / discharge mechanism 72 by the printer control unit 122. The paper P is transported to a printable position. Specifically, when the printing operation is started, the control unit 129 controls the head cap opening / closing mechanism 71 to drive the head cap 44 in a state where the ejection surface 41 is closed, as shown in FIG. It moves to the retracted position on the front side of the device 1. Further, as shown in FIG. 9, the controller 129 drives and controls a lifting mechanism (not shown) to raise the feed roller 94, the paper discharge roller 101, and the platen plate 104 from the retracted position to the transport position, and the pulse motor 103a. , 103b and the like are driven to transport the recording paper P in the direction of arrow E in FIG. At this time, the temperature sensor 74 detects the temperature in the vicinity of the head unit 37 and outputs it to the control unit 129 as environmental data in step S12.

  Next, in step S13, the control unit 129 transports the recording paper P, which has been transported to the printing position by the paper supply / discharge mechanism 72, and is tensioned in the transport direction by the feed roller 94 and the paper discharge roller 101, with respect to the recording paper P. The ejection control unit 123 controls the ink ejection head 45 based on the environmental data input from the temperature sensor 74 and the conveyance speed data stored in the memory unit 128 in advance and corresponding to the type of the recording paper P set at the start of printing. The ink i is ejected and landed at an appropriate ejection timing, and a character composed of ink dots based on print data such as character data or image data input from the external information processing device 130 or the like via the input / output terminal 125 Record an image. That is, printing is performed on the recording paper P.

  Next, in step S14, the control unit 129 detects the rear end of the recording paper P being printed by the rear end detection sensor 111 of the speed determination unit 73, and inputs the rear end detection data from the speed determination unit 73 when detected. Is done. The printing in step 13 is continued until the trailing edge of the recording paper P is detected. When the trailing edge of the recording paper P is detected, the trailing edge detection data from the trailing edge detection sensor 111 and the rotation from the encoder 112 are detected. Based on the detection data and speed determination data stored in advance in the memory unit 128, it is determined that the conveyance speed of the recording paper P has been increased, and the process proceeds to step S15 to correct color misregistration.

  Next, when the speed determination unit 73 detects the trailing edge of the recording paper P in step S15 and determines that the conveyance speed has increased, the control unit 129 stores the environmental data from the temperature sensor in advance in the memory unit 128. The ejection control unit 123 controls the ink ejection head 45 on the basis of the ejection control data corresponding to the type of the recording paper P stored and set at the start of printing, and the ejection speed of the ink i other than black is increased. The ink i is ejected at a later timing and the landing position of the ink i is corrected so as not to cause color misregistration.

  In step S <b> 16, the control unit 129 controls the ejection control unit 123 to sequentially eject the inks i of each color at the ejection timing after the color misregistration correction and before the conveyance speed is changed again by the ejection control data. Print data to the end and finish printing.

  Next, in step S <b> 17, the control unit 129 controls the paper supply / discharge mechanism 72 to discharge the recording paper P, which has been printed, onto the lid tray 65 from the paper discharge roller 101, and ends the printing operation.

  In the printer apparatus 1, the ink in the ink tank 11 runs out, the recording paper P in the storage tray 64 runs out, or printing is stopped from the external information processing apparatus 130 via the operation button 68 or the input / output terminal 125. Until the command signal is input, the printing operation in steps 11 to 17 is repeated.

  In the printer apparatus 1 that performs the printing operation by the method as described above, the rear end detection sensor 111 of the speed determination unit 73 detects the rear end of the recording paper P that is being printed, and determines that the conveyance speed of the recording paper P has increased. Then, the color shift caused by the change in the conveyance speed is corrected based on the environmental data from the temperature sensor 74 and the ejection control data corresponding to the type of the recording paper P stored in the memory unit 128 in advance.

  That is, in this printer apparatus 1, when the conveyance speed of the recording paper P is increased during printing, the black discharge from the nozzle 52a on the most downstream side in the conveyance direction is performed based on the discharge control data in which environmental data is included as an element. The ejection timing of the ink i other than the ink i is controlled to be delayed from before the transport speed of the recording paper P is increased, and the transport speed is changed by landing the ink i other than the black at the landing position where the black ink i is landed. To correct the color misalignment that occurs.

  Therefore, in this printer apparatus 1, even if the conveyance speed changes during printing, color misregistration caused by the change in the conveyance speed during printing takes into account the type of recording paper P, the ambient environmental temperature, and the like. High-quality printing can be prevented.

  The above is an example in which the present invention is applied to a printer apparatus. However, the present invention is not limited to the above example, and can be widely applied to other liquid ejection apparatuses that eject liquid. . For example, a facsimile, a copying machine, a discharge device for a DNA chip in liquid (Japanese Patent Laid-Open No. 2002-34560), a liquid discharge device that discharges a liquid containing conductive particles for forming a wiring pattern of a printer wiring board, and the like It is also applicable to.

  In the above description, the ink discharge head 45 that heats and discharges the ink i by one heating resistor 55 has been described as an example. However, the present invention is not limited to such a structure, and includes a plurality of pressure generating elements. The present invention can also be applied to a liquid ejection apparatus including ejection means that can control the ejection direction by supplying different energy to each pressure generating element or energy at different timings.

  In the above description, the electrothermal conversion method is employed in which the ink i is heated from one nozzle 52a while being heated by one heating resistor 55. However, the present invention is not limited to this method. An electromechanical conversion method in which ink is electromechanically ejected from a nozzle by a mechanical conversion element or the like may be used.

  In the above, the line type printer apparatus 1 has been described as an example. However, the present invention is not limited to this. For example, a serial type liquid in which the ink head moves in a direction substantially orthogonal to the running direction of the recording paper P is described. The present invention can also be applied to a discharge device.

It is a disassembled perspective view which shows the liquid discharge apparatus to which this invention was applied. FIG. 3 is an exploded perspective view showing a printer head cartridge provided in the liquid ejecting apparatus. FIG. 4 is a cross-sectional view illustrating a state where the ink tank is mounted on the cartridge body in the printer head cartridge. It is sectional drawing which shows the structure of the printer head cartridge. FIG. 2 is a diagram schematically showing the printer head cartridge. FIG. 3 is a cross-sectional view schematically showing an ink discharge head provided in the printer head cartridge. The same ink discharge head is shown. FIG. 2A is a cross-sectional view schematically showing a state where bubbles are generated in the heating resistor, and FIG. 2B is a schematic view showing a state where ink is discharged from the nozzle. FIG. It is a see-through | perspective side view which shows the structure of the same liquid discharge apparatus. FIG. 10 is a perspective side view for explaining a printing operation of the liquid ejection apparatus. FIG. 6 is a schematic diagram for explaining a roller that holds a recording sheet in a tension state in a paper supply / discharge mechanism provided in the liquid ejection apparatus. It is a block diagram which shows typically the control circuit of the same liquid discharge apparatus. FIG. 4 is a diagram for explaining ejection control data for correcting color misregistration caused by an increase in the conveyance speed during printing in the liquid ejection apparatus, and FIG. 5A shows a state in which ink is ejected onto the recording paper being conveyed. FIG. 4B is a schematic diagram for explaining color misregistration caused by an increase in conveyance speed during printing, and FIG. 8C is a diagram for explaining a method for correcting color misregistration. It is a schematic diagram. FIG. 6 is a characteristic diagram illustrating a shift in landing position that occurs in ink of each color when the recording paper conveyance speed increases. 4 is a flowchart for explaining a print preparation operation of the liquid ejection apparatus. 6 is a flowchart illustrating a printing operation of the liquid ejection apparatus. It is a schematic diagram which shows the conventional printer apparatus. FIG. 6 is a schematic diagram for explaining that the recording paper conveyance speed changes during printing in the printer apparatus.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Liquid ejection apparatus (liquid ejection apparatus), 2 Printer head cartridge, 3 Printer main body, 11 Ink tank, 12 Cartridge main body, 37 Head part, 41 Ejection surface, 44 Cover cap, 45 Ink ejection head, 52a Nozzle, 72 Supply / discharge Paper mechanism, 73 Speed discrimination unit, 74 Temperature sensor, 94 Feed roller, 101 Paper discharge roller, 103a, 103b Pulse motor, 111 Rear end detection sensor, 112 Encoder, 128 Memory unit, 129 Control unit

Claims (10)

Transport means for transporting an object to which the liquid is adhered in a predetermined direction;
An ejection unit that ejects the liquid in a droplet state, and ejects the droplet from the ejection port toward the object conveyed to a position facing the ejection port;
A discharge control means for controlling the discharge means so as to discharge the droplets from the discharge port at a predetermined discharge timing;
Environment detecting means for detecting a temperature and / or humidity environment when discharging the droplets from the discharge port;
Speed discriminating means for discriminating whether or not the conveyance speed of the object has changed;
Storage means for storing discharge control data for controlling the discharge timing according to the type of the object,
The discharge control means is based on the environmental data detected by the environment detection means and the discharge control data stored in the storage means when the speed determination means determines that the transport speed has changed. A liquid discharge apparatus that discharges the liquid droplets from the discharge port at the discharge timing different from that before the conveyance speed changes. The discharge means includes a plurality of discharge ports arranged in parallel in the transport direction of the object, and discharges the liquid droplets sequentially toward the target from the discharge port located upstream in the transport direction of the target object. ,
The discharge control means uses the landing position of the droplet discharged from the discharge port positioned downstream in the transport direction of the object as a reference, and the discharge port positioned downstream discharges the droplet. Before the transport speed is changed so that the liquid droplets discharged from the discharge ports other than the discharge ports located on the downstream side are landed at substantially the same position as the reference landing position. The liquid discharge apparatus according to claim 1, wherein the liquid droplets are discharged from discharge ports other than the discharge port located on the downstream side at the discharge timing different from the above.   The transport means is located upstream in the transport direction of the object with respect to the discharge means, and a downstream side in the transport direction of the target with reference to the feed roller that rotates about the axis and the discharge means And a discharge roller that rotates about the axis at a rotational speed faster than the rotational speed of the feed roller, and when the object is conveyed to a position facing the discharge port, The liquid discharge apparatus according to claim 1, wherein the discharge roller and the discharge roller convey the object substantially simultaneously to place the object in a tensioned direction in the in-plane direction of the discharge surface.   The speed discriminating unit has a rear end detection sensor that is located upstream of the transport direction with respect to the discharge unit and detects a rear end of the target in the transport direction. The liquid ejecting apparatus according to claim 1, wherein it is determined that the transport speed has changed after a predetermined time has elapsed since the rear end of the object was detected.   The liquid ejection apparatus according to claim 1, wherein the ejection unit has the ejection ports arranged in a substantially line shape in a direction substantially orthogonal to a conveyance direction of the object. It has transport means for transporting the object to which the liquid adheres in a predetermined direction, and a discharge port for discharging the liquid in the form of liquid droplets. Discharge means for discharging the droplets from the discharge port, discharge control means for controlling the discharge means to discharge the droplets from the discharge port at a predetermined discharge timing, and the droplets from the discharge port. Environment detection means for detecting the temperature and / or humidity environment when discharging the liquid, speed determination means for determining whether or not the conveyance speed of the object has changed, and the discharge timing according to the type of the object. A liquid discharge method for a liquid discharge apparatus comprising storage means for storing discharge control data to be controlled,
When the speed determining means determines that the transport speed of the object has changed, the transport speed is determined based on the environmental data detected by the environment detecting means and the discharge control data stored in the storage means. A liquid discharge method, wherein the liquid droplets are discharged from the discharge port at the discharge timing different from that before the change. A plurality of the discharge ports are juxtaposed in the conveyance direction of the object, and the droplets are discharged toward the object in order from the discharge port located on the upstream side in the conveyance direction of the object,
The landing position of the droplet discharged from the discharge port located downstream in the transport direction of the object is used as a reference, and the reference before the discharge port located on the downstream side discharges the droplet. The ejection timing is different from that before the change in the transport speed so that the droplets ejected from the ejection ports other than the ejection ports located on the downstream side are landed at substantially the same position as the landing position. The liquid discharge method according to claim 6, wherein the liquid droplets are discharged from discharge ports other than the discharge port located on the downstream side. As the transport means, a feed roller that rotates about the axis upstream of the discharge means with respect to the discharge means, and the feed downstream of the discharge direction with respect to the discharge means. A discharge roller that rotates around the axis at a rotational speed faster than the rotational speed of the roller, and
When the object is conveyed to a position facing the discharge port, the feeding roller and the discharge roller convey the object almost simultaneously, thereby tensioning the object in the in-plane direction of the discharge surface. The liquid discharging method according to claim 6, wherein the liquid discharge method is performed. As the speed discriminating means, a rear end detection sensor for detecting a rear end in the transport direction of the object on the upstream side of the transport direction on the basis of the discharge means,
The liquid ejection method according to claim 6, wherein it is determined that the transport speed has changed after a predetermined time has elapsed since the rear end detection sensor detected the rear end of the object.   The liquid ejection method according to claim 6, wherein the ejection ports are arranged in a substantially line shape in a direction substantially orthogonal to a conveyance direction of the object.

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