JP2013010245A - Drying device and recording device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress color unevenness of a recording medium when a drying device is stopped.SOLUTION: The drying device includes air nozzles that are provided facing the recording medium, which is carried in and out, so that the nozzles sandwich the recording medium and blows out air for drying the recording medium. When the device stops drying operation, the device dries the recording medium located in the device, and sequentially, stops blowout of the air nozzles.

Description

  The present invention relates to a drying apparatus and a recording apparatus, and more particularly to a drying apparatus and a recording apparatus provided with air nozzles in the upper and lower directions in a recording medium conveyance path.

  Many drying apparatuses for drying a recording medium employ a method of drying ink applied on the recording medium with warm air. As one of such drying methods, the ink applied to the recording medium is dried by providing air nozzles above and below the recording medium, and the recording medium is brought into the interior of the drying device by the wind pressure applied to the front and back surfaces of the recording medium. A configuration for carrying in the air is known (for example, see Patent Document 1). In this method, air nozzles are provided above and below the recording medium inside the drying apparatus, and the vertical position (height) of the recording medium is maintained by the pressure of the air generated from these upper and lower air nozzles, thereby the entrance of the drying apparatus. It is transported at approximately the same height from the exit to the exit.

JP 2007-276309 A

  However, in the above-described technique, when the recording apparatus is stopped by the recovery process of the recording head or the like, if the upper and lower air nozzles in the drying apparatus are immediately stopped, the recording medium in the drying apparatus is slackened between the inlet and the outlet of the apparatus. The recording medium may come into contact with the lower air nozzle. At this time, among the recording images that have not been dried, there are a portion that is in contact with the lower air nozzle and a portion that is not in contact with the lower air nozzle. If there is the presence or absence of this contact in one image, there is a difference in the evaporation state of the ink due to the contact and non-contact, and this may appear as uneven color in the image after drying. is there.

  The present invention has been made in view of the above points, and is a drying device that is provided with upper and lower air nozzles for blowing warm air for drying a recording medium, and causes uneven color of the recording medium when the drying device is stopped. It aims at providing the drying apparatus which suppresses.

In order to achieve the above object, the present invention is provided with an air nozzle that is provided so as to sandwich a recording medium to be conveyed and blows out a gas for drying the recording medium,
When the drying operation is stopped, the recording medium located in the drying apparatus is dried and then the air nozzle is stopped.

  According to the above configuration, when stopping the drying device, the upper and lower air nozzles can be stopped after drying the recording medium in the drying device. Thereby, it is possible to suppress uneven color of the recording medium when the drying device is stopped.

1 is a schematic perspective view illustrating an ink jet recording apparatus according to a first embodiment. FIG. 2 is a schematic cross-sectional view showing the inside of the ink jet recording apparatus according to the first embodiment. FIG. 3 is a block diagram illustrating a control configuration in the recording apparatus according to the first embodiment. 1 is a schematic cross-sectional view illustrating a drying device according to a first embodiment. It is a figure which shows the lower air nozzle which provided the rib of 1st Embodiment. FIG. 6 is a schematic cross-sectional view seen from the direction of arrow X in FIG. 5. It is a typical perspective view which shows the inkjet recording device of 2nd Embodiment.

Embodiments of the present invention will be described below in detail with reference to the drawings.
(First embodiment)
FIG. 1 is a schematic perspective view showing the ink jet recording apparatus of the present embodiment. The recording apparatus of the present embodiment is a recording apparatus that supports roll paper for single-sided recording.

  The roll paper supply device 2 supplies the recording medium P supplied from the supply roll paper 4 made of a recording medium wound in a roll shape to the inkjet recording device 1. The recording medium P supplied from the roll paper supply device 2 is recorded by the inkjet recording device 1. After recording is performed on the recording medium P, the reversing device 30 reverses the front and back. After the recording medium P passes through the reversing device 30, it is heated in the drying device 17, and the ink used for recording is dried. After passing through the drying device 17, the roll paper take-up device 3 takes up the recorded roll paper 5.

  FIG. 2 is a schematic sectional view showing the inside of the ink jet recording apparatus 1 of the present embodiment, and is a view of the recording apparatus shown in FIG. 1 as viewed from the direction of the arrow Y1. The recording medium P supplied from the roll paper supply device 2 to the recording unit is conveyed in the direction of arrow A while being substantially guided by the platen 15, and is conveyed to the roll paper winding device 3. The recording medium P is conveyed in the recording unit by a conveyance roller 11 and a discharge roller 13 driven by a conveyance drive system (not shown) using a stepping motor as a conveyance motor. The conveyance pinch roller 12 and the paper discharge pinch roller 14 are freely rotatable driven rollers that press the recording medium P by a spring bias, thereby stabilizing the conveyance performance of the recording medium P and the height of the recording surface of the recording medium P. We are trying to make it.

  The recording head 16 includes a cyan recording head (hereinafter also referred to as cyan head) 7, a magenta recording head (hereinafter also referred to as magenta head) 8, and a yellow recording head (hereinafter also referred to as yellow head) 9. Become. Each recording head is fixed to a head mount 10 that can be raised and lowered in the direction of arrow B by a drive system (not shown), and is connected to an ink supply system (not shown). Each recording head has a plurality of nozzles. Each nozzle portion is a so-called line head in which ink discharge nozzles are arranged at a predetermined pitch over the entire length and have a nozzle length that can be recorded over the entire width of the recording medium P. Each line head is an ink jet system that discharges ink using thermal energy, and includes a plurality of electrothermal transducers for generating thermal energy. Specifically, thermal energy is generated by a pulse signal applied to the electrothermal transducer, and film boiling occurs inside the ink liquid by this thermal energy. Further, the ink is discharged from the ejection port using the foaming pressure of film boiling. Recording is performed by discharging. The ink ejection operation is performed at a predetermined timing in synchronization with the steps of the transport motor.

  The scanner device 40 is positioned downstream of the paper discharge roller 13 and is used to read an image quality adjustment image and an inspection image recorded on the recording medium P. The scanner device 40 reads an image with a CCD type image sensor 218 including a red (R), green (G), and blue (B) light emitting unit and a light receiving unit (not shown). The white reference plate 41 is disposed between the paper discharge roller 13 and the scanner sub roller 42 so as to face the image sensor 218 and is used for calibration of the image sensor 218.

  FIG. 3 is a block diagram showing a control configuration in the ink jet recording apparatus of the present embodiment. The engine controller 212 is a main control unit of the recording apparatus, and includes a CPU 210 in the form of a microcomputer, for example. The engine controller 212 further includes a ROM 209 that stores programs, required control tables, and other fixed data, and a RAM 211 that provides an area for developing image data, a work area, and the like. The host device 202 is connected to the outside of the recording device 204 and serves as an image supply source. The host device 202 may be a computer that creates and processes data such as images related to recording, and may be in the form of a reader unit for image reading. Image data, other commands, status signals, and the like supplied from the host device 202 can be transmitted to and received from the engine controller 212 via the interface 205. The operation unit 203 is a group of switches that accepts an input instruction from an operator, and includes a power switch (not shown), a recovery switch for instructing activation of recording head suction recovery, and the like. The sensor unit 201 is a sensor group for detecting the state of the recording apparatus. In addition to the roll paper coupling portion detection sensor 208, it includes various sensors (not shown) such as a temperature detection sensor and a paper presence / absence detection sensor installed in the conveyance path. The head controller 214 drives the electrothermal transducer of the recording head 16 according to the recording data. The head control unit 214 includes a shift register that aligns recording data corresponding to each of the plurality of electrothermal transducers, a latch circuit that latches at appropriate timing, and operates the electrothermal transducer in synchronization with the drive timing signal. Logic circuit elements are included. The head control unit 214 further includes a timing setting unit that appropriately sets the ink discharge timing in order to adjust the dot formation position on the recording medium, and a discharge amount control unit that adjusts the ink discharge amount for each color head. It is. The recording head 16 is driven and controlled by the head controller 214 based on a control command from the engine controller 212. The conveyance control unit 215 realizes a predetermined conveyance sequence by performing drive control of the conveyance motor 220. The roll paper supply control unit 216 performs drive control of the recording medium supply motor 221 in accordance with a command from the engine controller 212. The roll paper winding control unit 217 performs drive control of the roll paper winding motor 222 in accordance with a command from the engine controller 212. The scanner control unit 213 performs image reading control of the image sensor 218, and reading information is sent to the engine controller 212 to perform various arithmetic processes. The drying control unit 300 controls the heating device 23, the blower 24, and the exhaust blower 29, and controls the drying device 17. The recovery control unit 206 controls the head recovery operation such as cleaning of the head face by the head wiper and maintenance of the recording nozzle by the suction pump, and controls the recovery motor system 207.

  FIG. 4 is a schematic cross-sectional view showing the drying apparatus of the present embodiment, which is shown from the direction of arrow Y2 in FIG. The drying device 17 has an inlet 18 provided on the downstream side in the transport direction and an outlet 19 provided on the upstream side in the transport direction at the same height, and the recording medium P is horizontally placed in the transport direction from the inlet 18 to the outlet 19. It is trying to become.

  The drying device 17 is provided with an air nozzle 20 that blows out air for drying ink on the recording medium toward the recording medium P on the upper side and the lower side of the conveyance path of the recording medium P, respectively. In addition, what is used for drying is not restricted to air, Gas other than air may be used. The air nozzle 20 is long in a direction perpendicular to the conveyance direction of the recording medium P, and hot air is blown in a direction perpendicular to the conveyance direction of the recording medium with one air nozzle. The nozzle portion in which a large number of air nozzles 20 are arranged is arranged so that the upper and lower nozzles are staggered across the recording medium P. When the recording medium P passes through the conveyance path of the recording medium P in a horizontal state, warm air is blown by the air nozzles 20 arranged above and below, the ink attached to the surface of the recording medium P evaporates, and the ink is dried. Done. Further, the height of the recording medium P in the vertical direction is maintained by the wind pressure of the upper and lower air nozzles. The hot air blown from the lower nozzle is set stronger than the hot air blown from the upper nozzle.

  Further, a heating device 23 for heating the air and a blower 24 for blowing the heated air (that is, hot air) onto the recording surface of the recording medium P are provided. Each air nozzle 20 is connected to a heating device 23, and the heating device 23 is connected to a blower 24. The drying device 17 is provided with an exhaust port 25 and an exhaust blower 29, and plays a role of discharging water vapor generated by drying the recording medium P to the outside. In addition, an air inlet 26 for taking outside air into the drying device 17 is provided. That is, outside air is taken in from the intake port 26, the warm air generated by the heating device 23 is sent to the air nozzle 20 by the blower 24, the warm air is blown to the recording medium P by the air nozzle 20, and water vapor evaporated by drying of the recording medium P is generated. The air flow is exhausted from the exhaust port 25. Moreover, the air nozzle 20, the heating device 23, and the blower 24 are divided into upper and lower sides with the conveyance path of the recording medium P interposed therebetween, and can be controlled independently.

  A spur 27 is attached to the lower air nozzle 22 at a wind outlet. A plurality of the spurs 27 are attached with the lower air nozzles 22 equally spaced in the direction orthogonal to the traveling direction of the recording medium. The spur 27 plays a role in avoiding contact of the recording medium P with the lower air nozzle 22 and reducing adhesion of dirt and the like. Even if the recording medium comes into contact with the spur 27, the portion where the spur 27 and the recording medium are in contact with each other is extremely small, so that the image quality of the recording medium to which ink is attached is not impaired.

  Next, the operation of the drying device 17 when starting and stopping the ink jet recording apparatus corresponding to the single-sided recording roll paper will be described. The timing to start and stop during recording by the recording apparatus is mainly when the head recovery operation such as cleaning of the head face by the head wiper and maintenance of the recording nozzle by the suction pump is performed. Therefore, the operation during maintenance of the recording nozzle will be described as an example.

  During recording by the ink jet recording apparatus 1, the inspection image is read by the scanner device 40, thereby performing a non-discharge or ejection failure detection operation of the recording head 16. When the non-ejection of the nozzle is detected by the scanner device 40, the recording operation is stopped and the maintenance operation is performed. Inspection images read by the scanner device 40 are recorded at regular intervals during recording on the recording medium P. No nozzle non-discharge has occurred on the downstream side of the conveyance of the recording medium P from the inspection image immediately before the position where the nozzle 40 has detected non-discharge of the nozzle. The location of the inspection image immediately before the location where the nozzle ejection failure is detected is always located in the reversing device 30. In other words, the upstream side of the inspection image in the reversing device 30 is subject to disposal because there is a possibility of nozzle non-ejection and the image quality cannot be guaranteed, and the downstream side has no possibility of nozzle non-ejection. It can be used as a product. Then, after detecting the non-ejection of the nozzle by the scanner device 40, the operation of the recording head 16 is stopped and the conveyance of the recording medium P is stopped.

However, the drying device 17 does not stop immediately after the conveyance of the recording medium P is stopped.
The operation is continued for T, and the recording medium P in the drying device 17 is dried and then stopped. Here, the predetermined time ΔT is a time required to dry the ink recorded on the recording medium P. For example, the time required to dry the ink recorded on the recording medium P is the time required to transport the recording medium P from the inlet 18 to the outlet 19.

  The reason for this drying operation will be described below. When the drying device 17 is stopped, it is difficult to apply tension to the recording medium P in the drying device 17 where a force is not applied so much as to directly apply tension to the recording medium P such as a pinch roller. Therefore, the recording medium Pha gravity, to which no pressure is applied by the wind from the drying device 17, hangs down to the lower air nozzle 22 side and comes into contact. At this time, among the recording images that are not dried, there are locations that are in contact with the lower air nozzle 22 and locations that are not in contact therewith. And when natural drying advances in the state which the drying apparatus stopped, the moisture evaporation rate difference generate | occur | produces by the presence or absence of the contact to the lower air nozzle 22. FIG. Then, a difference occurs in the ink evaporation state depending on whether the moisture content is high or low. That is, color unevenness is generated in the image depending on the presence or absence of contact with the lower air nozzle 22.

  Therefore, in order to prevent color unevenness, it is necessary to stop the drying device 17 after the recording medium P is dried. Moreover, the air nozzle 20 divided into the upper and lower sides can be controlled independently. When the drying device 17 is stopped, the hot air from the lower air nozzle 22 is stopped first, and then the hot air from the upper air nozzle 21 is stopped. In order.

  The behavior of the recording medium P at that time will be described. As described above, when the drying device 17 is stopped, it is difficult to apply tension to the recording medium P in the drying device 17, and the state becomes slack to some extent. Therefore, by first stopping the warm air of the lower air nozzle 22, the recording medium P moves to the lower air nozzle 22 side, and then the upper air nozzle 21 is stopped to loosen the recording medium and fix it to the lower method. This reduces fluttering. As a result, damage to the recording medium P can be reduced. At this time, the recording medium P comes into contact with the lower air nozzle 22, but since the spur 27 is attached to the lower air nozzle 22, the recording medium P comes into contact with the spur 27, and the lower air nozzle 22 The adhesion of dirt (for example, paper dust) can be avoided.

  In this embodiment, a spur is attached to the lower air nozzle, but the present invention is not limited to a spur. Any structure that reduces the damage to the recording medium P when the upper air nozzle is stopped may be used.

  FIG. 5 is a view showing the lower air nozzle 22 provided with the ribs 28. The rib 28 is disposed in the lower air nozzle 22, and the contact area of the recording medium P with the lower air nozzle 22 can be reduced.

  FIG. 6 shows a schematic cross-sectional view as seen from the direction of arrow X in FIG. The ribs 28 have a height relationship that curves the recording medium P. In other words, the closer to the entrance and exit from the central portion of the transport path, the longer. By stabilizing the posture by curving the recording medium P and applying stiffness, it is possible to reduce contact with other than the ribs 28 and reduce adhesion of dirt. Then, after the drying device 17 is stopped, maintenance of the recording nozzle is executed, and the device is started again to start recording. At the time of activation, first, the drying device 17 is activated in order to stabilize the posture of the slack recording medium P in the drying device 17 with warm air. In order to suppress the fluttering of the recording medium P at the time of startup, the hot air is discharged from the lower air nozzle 22 after the hot air is discharged from the upper air nozzle 21 contrary to the stop time. After the drying device 17 is activated, the conveyance of the recording medium P is started and the operation of the recording head 16 is started. Since the image of the recording medium P in the drying device 17 is dried at the time of stoppage, image unevenness does not occur, and even when the device is stopped, it is possible to reduce waste of sheets.

(Second Embodiment)
In the first embodiment, the recording apparatus corresponding to the roll paper for single-sided recording has been described. However, the present invention is not limited to such a recording apparatus, and the recording apparatus corresponding to the roll paper for double-sided recording is described. It may be.

  FIG. 7 is a schematic perspective view showing the recording apparatus of the present embodiment. The recording apparatus of this embodiment has a front surface inkjet recording device 31 and a back surface inkjet recording device 32.

  The recording medium P drawn out from the supply roll paper 4 formed of the recording medium wound in a roll shape supplied from the roll paper supply apparatus 2 that supplies the recording medium to the ink jet recording apparatus is applied to the surface by the surface ink jet recording apparatus 31. Recording is performed. When the recording on the front surface is finished, the recording medium P is turned over by the turning device 30. After the recording medium P passes through the reversing device 30, the back surface recording is performed by the back surface inkjet recording device 32. When the recording on the back surface is completed, the recording medium P is heated in the drying device 17 and the ink on the recording medium P is dried. After passing through the drying device 17, the recording medium P is wound up as a recorded roll paper 5 by the roll paper winding device 3.

  The operation of the drying device 17 in the recording apparatus according to the present embodiment is difficult to apply tension to the recording medium P when the drying device 17 is stopped, like the drying device in the recording apparatus according to the first embodiment. It hangs down to the air nozzle 22 side and comes into contact. Therefore, after the recording medium P is dried, the order of operating the drying device 17 by ΔT and stopping the drying device 17 is required. In addition, the recording medium P existing upstream of the drying device 17 at the time of stopping is naturally dried while being nipped between the rollers and the like, and is therefore a target for discarding. The stopping method in the drying device 17 is performed in the order in which the hot air from the lower air nozzle 22 is stopped first and then the hot air from the upper air nozzle 21 is stopped. At the time of activation, as in the first embodiment, the drying device 17 is first activated, and after the warm air from the upper air nozzle 21 is released, the warm air from the lower air nozzle 22 is discharged. When the drying device 17 is activated, the conveyance of the recording medium P is started and the operation of the recording head 16 is started. Since the image of the recording medium P in the drying device 17 is dried at the time of stoppage, image unevenness does not occur, and even when the device is stopped, it is possible to reduce waste of sheets.

DESCRIPTION OF SYMBOLS 1 Inkjet recording device 2 Roll paper supply device 3 Roll paper winding device 17 Drying device 18 Drying device inlet 19 Drying device outlet 20 Air nozzle 21 Upper air nozzle 22 Lower air nozzle 23 Heating device 27 Spur

Claims (6)

An air nozzle is provided so as to face the recording medium to be conveyed, and blows out a gas for drying the recording medium.
When the drying operation is stopped, the blowing of the air nozzle is stopped after drying the recording medium located in the drying device.   When the drying device starts drying, after the gas nozzle starts to blow out air from the air nozzle provided above the recording medium, the air nozzle starts to blow gas from the air nozzle provided below the recording medium. The drying apparatus according to claim 1.   The drying apparatus according to claim 1, wherein the air nozzle provided at a lower portion of the recording medium includes a spur.   The drying apparatus according to claim 1, wherein the air nozzle provided in a lower portion of the recording medium includes a rib.   The drying apparatus according to claim 4, wherein the rib is longer from a central portion of the recording medium toward an inlet and an outlet of the drying apparatus.   6. A recording apparatus comprising: a recording unit that records an image on a recording medium; and the drying device according to claim 1 for drying the recording medium recorded by the recording unit. apparatus.

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