JP6942501B2 - Inkjet recording device - Google Patents

Description

The present invention relates to an inkjet recording apparatus including a platen that supports a recording medium.

Patent Document 1 discloses an inkjet recording apparatus capable of recording an image on an end portion of a recording medium by using a suction platen that attracts and supports a recording medium by sucking air from a suction hole.

Japanese Unexamined Patent Publication No. 2006-021475

The platen disclosed in Patent Document 1 is provided with a suction hole on the downstream side in the transport direction of the recording medium, but is not provided on the upstream side. Therefore, when recording is performed on the rear end of the recording medium, the rear end is adsorbed on the suction portion of the platen, but when recording is performed on the front end of the recording medium, the tip does not reach the suction portion and is not adsorbed. As a result, when recording with respect to the tip of the recording medium, it is not possible to suppress the floating of the recording medium.

In view of the above problems, it is an object of the present invention to provide an inkjet recording apparatus capable of suitably performing a recording operation on the front end and the rear end of a recording medium.

In order to achieve the above object, the present invention is provided with a recording head that ejects ink to a recording medium to perform a recording operation, and a recording head that conveys the recording medium in a first direction and is provided upstream of the recording head in the first direction. The first transport means, the second transport means that transports the recording medium in the first direction and is provided downstream of the recording head in the first direction, and the recording that is provided so as to face the recording head. An ink receiving portion that receives ink ejected from the head is provided between the ink receiving portion and the first conveying means in the first direction, and while sucking air from a suction hole, the recording medium is sucked. An upstream support portion that supports and a downstream support portion that is provided between the ink receiving portion and the second transport means in the first direction and supports while sucking a recording medium by sucking air from a suction hole. The upstream support portion and the downstream support portion include a recess provided with a suction hole and not supporting the recording medium, and a platen capable of supporting the recording medium. a rib that supports the possess, the the recording head when the recording operation is performed by discharging ink to the outside from the front end of the recording medium, the recording start position where the recording operation is started the leading end of the recording medium conveyance The distance from the tip to the first transport means in the state of being inked is changed according to the size of the recording medium .

According to the present invention, there is provided an inkjet recording apparatus capable of suitably performing a recording operation on the front end and the rear end of a recording medium.

It is a perspective view which shows the inside of the main body of the inkjet recording apparatus which concerns on 1st Embodiment. It is sectional drawing which shows the inside of the main body of the inkjet recording apparatus which concerns on 1st Embodiment. It is a perspective view which shows the platen which concerns on 1st Embodiment and its periphery. It is an enlarged perspective view which enlarged the platen which concerns on 1st Embodiment. It is sectional drawing which shows the platen which concerns on 1st Embodiment and its periphery. It is a top view which shows the positional relationship of the recording medium which concerns on 1st Embodiment, an upstream support part and a downstream support part. It is sectional drawing which shows the recording head and the platen which concerns on 1st Embodiment. It is a block diagram of the control circuit of the inkjet recording apparatus which concerns on 1st Embodiment. It is a flowchart which shows the edgeless recording of the inkjet recording apparatus which concerns on 1st Embodiment. It is sectional drawing which shows the positional relationship of a recording medium and a platen in edgeless recording of the inkjet recording apparatus which concerns on 1st Embodiment. It is a table which shows the parameter stored in the ROM which concerns on 1st Embodiment. It is a perspective view which shows the platen which concerns on 2nd Embodiment. It is sectional drawing which shows the recording head and the platen which concerns on 2nd Embodiment. It is a top view which shows the positional relationship of the line head and the platen which concerns on 3rd Embodiment. It is a flowchart which shows the recording operation which concerns on 3rd Embodiment.

An embodiment of the inkjet recording apparatus according to the present invention will be described. However, the components described in the embodiments are merely examples, and are not intended to limit the scope of the present invention. In the present specification, "ink" is used as a general term for liquids such as recording liquids. In the present specification, the "recording medium" is a medium that discharges a liquid, and is used as a general term for recording media such as paper, cloth, plastic film, metal plate, glass, ceramics, wood, and leather. Further, the recording medium is not limited to cut paper, but also includes roll-shaped continuous paper. The inkjet recording device can be applied not only to a PC printer but also to a multifunction printer having a copy function, a facsimile function, and the like.

[First Embodiment]
FIG. 1 is a perspective view showing the inside of the main body of the inkjet recording device (hereinafter, recording device) 1 of the present embodiment. Further, FIG. 2 is a cross-sectional view showing a cross section of the main body of the recording device 1. The recording device 1 includes a feeding device 2 for feeding the recording medium P into the device. The feeding device 2 is composed of a feeding tray 3 and a feeding roller 4, and the recording media loaded on the feeding tray 3 are separately fed one by one by the rotation of the feeding roller 4.

The fed recording medium P is placed on the platen 8 at a position facing the recording head 5 along the Y direction by a first transport roller pair (first transport means) composed of a transport roller 6 and a pinch roller 7. Will be transported to. The recording head 5 is mounted on the carriage 51 and ejects ink droplets while reciprocating in the X direction intersecting the Y direction to perform a recording operation of recording an image for one band on the recording medium P. In this embodiment, the X direction and the Y direction are orthogonal to each other. The recording head 5 has a discharge port row 27 (see FIG. 7) in which a plurality of discharge ports are arranged, and ink droplets are discharged from each discharge port. The platen 8 supports the back surface of the recording medium P during the recording operation by the recording head 5. When an image for one band is recorded on the recording medium P, the recording medium P is conveyed in the Y direction by a predetermined amount by the first transfer roller pair (intermittent transfer operation). By repeating the recording operation for one band and the intermittent transfer operation, an image is recorded on the entire recording medium P. The recording medium P for which recording has been completed is discharged onto the discharge tray 10 by a second transport roller pair (second transport means) composed of a discharge roller 9 and a spur (not shown) arranged downstream of the platen 8 in the Y direction. Will be done.

In the following, since the X direction is the main scanning direction of the carriage 51, it is also referred to as the main scanning direction. Further, since the Y direction is the direction in which the recording medium P is conveyed, it is also referred to as a transfer direction.

Next, the structure of the platen 8 will be described in detail. FIG. 3 is a perspective cross-sectional view showing the platen 8 and its periphery. A first transport roller pair is arranged upstream in the transport direction of the platen 8, and a second transport roller pair is arranged downstream in the transport direction. An ink receiving portion 11 is provided on the surface of the platen 8 facing the recording head 5. The ink receiving unit 11 receives ink droplets ejected to the outside of the recording medium P when recording without margins on the recording medium P (hereinafter, borderless recording). Further, the ink receiving unit 11 may be configured to receive the ink droplets ejected by the preliminary ejection operation performed immediately before or during the recording operation by the recording head 5 in order to stabilize the ink ejection state.

Further, the platen 8 is provided with an upstream support portion 12 on the upstream side of the ink receiving portion 11 in the transport direction. The upstream support portion 12 supports the recording medium P conveyed by the transfer roller 6. Further, a downstream support portion 13 is arranged on the downstream side of the ink receiving portion 11 in the transport direction. The downstream support portion 13 supports the recording medium P on which the image is recorded by the recording head 5.

FIG. 4 is a perspective view of the platen 8 in which a part of FIG. 3 is enlarged. The upstream support portion 12 has an upstream outer peripheral rib 14 and an upstream recess 15. The upstream outer peripheral rib 14 is a rib having a flat surface that abuts on the back surface of the recording medium P, and has a rectangular shape along the outer circumference of the upstream support portion 12. The upstream concave portion 15 is configured inside the upstream outer peripheral rib 14 to be lower than the upstream outer peripheral rib 14. Therefore, when the upstream support portion 12 supports the recording medium P, the recording medium P comes into contact with the upstream outer peripheral rib 14 and does not come into contact with the upstream recess 15. In the present embodiment, the upstream recess 15 is surrounded by the upstream outer peripheral rib 14, but the present invention is not limited to this, and there may be a part that is not surrounded.

The upstream support portion 12 is further provided with a plurality of upstream division ribs 19. The upstream split rib 19 has the same height as the upstream outer peripheral rib 14, extends in the Y direction, and both ends are connected to the upstream outer rib 14. The upstream dividing rib 19 divides the region of the upstream recess 15 surrounded by the upstream outer peripheral rib 14 into a plurality of regions. When the recording medium P is supported by the upstream support portion 12, a closed space is formed by the recording medium P, the upstream recess 15, the upstream outer peripheral rib 14, and the upstream split rib 19.

Further, the upstream support portion 12 is provided with a plurality of upstream auxiliary ribs 20, and the upstream auxiliary ribs 20 include a first upstream auxiliary rib 20a and a second upstream auxiliary rib 20b. The first upstream auxiliary rib 20a has the same height as the upstream outer peripheral rib 14, extends in the Y direction, one end is connected to the first upstream outer rib 14a, and the other end is separated from the second upstream outer rib 14b. .. The second upstream auxiliary rib 20b has the same height as the upstream outer peripheral rib 14, extends in the Y direction, one end is connected to the second upstream outer rib 14b, and the other end is separated from the first upstream outer rib 14a. ..

When a plurality of upstream auxiliary ribs 20 are provided between the two upstream split ribs 19, the first upstream outer peripheral ribs 14a and the second upstream outer peripheral ribs 14b are arranged so as to alternate in the main scanning direction. The upstream auxiliary rib 20 can support the recording medium P, and when the upstream support portion 12 supports the recording medium P, it is possible to suppress the drop into the upstream recess 15.

The upstream recess 15 is provided with two types of upstream suction holes 16 of a first upstream suction hole 16a and a second upstream suction hole 16b so as to penetrate the platen 8. The first upstream suction hole 16a is provided in the region between the first upstream auxiliary rib 20a and the second upstream outer peripheral rib 14b. The second upstream suction hole 16b is provided in the region between the second upstream auxiliary rib 20b and the first upstream outer peripheral rib 14a.

Like the upstream support portion 12, the downstream support portion 13 also has a downstream outer peripheral rib 21 and a downstream recess 23. A plurality of downstream split ribs 52 are provided in the downstream recess 23, and when the downstream support portion 13 supports the recording medium P, a closed space is formed by the downstream outer peripheral rib 21, the downstream recess 23, and the downstream split rib 52. Further, a plurality of downstream auxiliary ribs 53 and downstream suction holes 54 are arranged in the downstream recess 23 in the same manner as the upstream support portion 12.

FIG. 5 is a cross-sectional view showing the structure around the platen 8. The upstream suction hole 16 communicates with the upstream negative pressure chamber 17 below the platen 8 in the vertical (Z) direction. By driving the upstream suction fan 18 provided in the upstream negative pressure chamber 17, the upstream negative pressure chamber 17 is put into a negative pressure state. Further, by driving the upstream suction fan 18, air is sucked from the upstream suction hole 16, and the closed space formed by the upstream support portion 12 and the recording medium P becomes a negative pressure space. As a result, the recording medium P is attracted to the upstream outer peripheral rib 14, the upstream split rib 19, and the upstream auxiliary rib 20.

Similarly, the downstream suction hole 54 communicates with the downstream negative pressure chamber 22 below the platen 8 in the vertical direction. By driving the downstream suction fan 24 provided in the downstream negative pressure chamber 22, the downstream negative pressure chamber 22 is put into a negative pressure state. Further, by driving the downstream suction fan 24, air is sucked from the downstream suction hole 54, and the closed space formed by the downstream support portion 13 and the recording medium P becomes a negative pressure space. As a result, the recording medium P is attracted to the downstream outer peripheral rib 21, the downstream split rib 52, and the downstream auxiliary rib 53.

FIG. 6 shows the positional relationship between the recording medium P and the upstream support portion 12 and the downstream support portion 13. In the present embodiment, the so-called center-based feeding is adopted in which the reference of the recording position is set at the center of the recording medium P in the width direction (X direction shown in FIG. 6). In the center-based feeding, the recording medium P is fed so that the centers in the X direction coincide with each other in the recording media P having various widths. In the present embodiment, the recording medium P is fed so that the center of the recording medium P is located on the P-c line. The upstream dividing rib 19 and the downstream dividing rib 52 are arranged so as to correspond to the widths of various recording media P conveyed based on the center. In FIG. 6, the end portion (side end portion) of the A4 size, A3 size, and A2 size recording medium P in the width direction is shown by a solid line.

The upstream dividing rib 19 and the downstream dividing rib 52 are arranged symmetrically with respect to the X direction with respect to the P-c line. Further, the upstream dividing rib 19 and the downstream dividing rib 52 are arranged near the side end portions of the various recording media P to be conveyed, and are arranged on the center side (P-c line side) in the width direction from the side end portions. NS. That is, the upstream dividing rib 19 and the downstream dividing rib 52 are arranged in the region through which the recording medium P passes and in the vicinity of the side end portion. For example, an upstream split rib 19 and a downstream split rib 52 having a width of 3 mm in the X direction are arranged at distances of 100 mm, 143 mm, and 205 mm from the P-c line. These are the positions corresponding to the A4, A3, and A2 size recording media P, respectively. As a result, the recording operation can be performed while attracting the vicinity of the side end portion of the recording medium P, which tends to float with respect to the platen 8, to the upstream support portion 12 and the downstream support portion 13.

The feeding of the recording medium P is not limited to the center reference, and may be a one-sided reference in which the recording medium P is fed at the reference position of either the left or right side. In that case, the upstream split rib 19 and the downstream split rib 52 may be provided according to the one-sided reference. Further, in the present embodiment, separate negative pressure chambers are provided for the upstream support portion 12 and the downstream support portion 13, but the present invention is not limited to this, and a common negative pressure chamber and an on-off valve are provided to carry the recording medium P. The negative pressure supply may be switched on / off according to the position in the transport direction.

FIG. 7 is a schematic cross-sectional view showing the platen 8 and the recording head 5. The ink receiving portion 11 is composed of a bottom portion 25, a first side wall 26, a second side wall 55, and an ink flow path 29. The bottom portion 25 is configured to be lower than the upstream support portion 12 and the downstream support portion 13, and forms a frame in the present embodiment. The recording head 5 is provided with a plurality of ejection ports for ejecting ink on a surface facing the platen 8, and in the present embodiment, an ejection port row 27 in which a plurality of ejection ports are arranged along the transport direction is formed. The first side wall 26 connects the bottom portion 25 and the upstream support portion 12, and is provided on the upstream side of the discharge port row 27 in the transport direction. The second side wall 55 connects the bottom portion 25 and the downstream support portion 13, and is provided on the downstream side of the discharge port row 27 of the recording head 5 in the transport direction.

That is, the upstream support portion 12 is located upstream of the discharge port arranged most upstream in the transport direction in the discharge port row 27, and the downstream support portion 13 is located upstream of the discharge port arranged most downstream in the transport direction in the discharge port row 27. Is also located downstream. As a result, the ink discharged from the recording head 5 is received by the ink receiving portion 11 provided between the upstream supporting portion 12 and the downstream supporting portion 13. Therefore, even if the ink is erroneously ejected to the platen 8 while the recording medium P is not conveyed, the ink does not adhere to the upstream support portion 12 and the downstream support portion 13, and the upstream support portion 12 and the downstream support portion 12 and the downstream support are supported. The back surface of the recording medium P is not soiled by the unit 13.

The ink ejected to the outside of the recording medium P is received by the ink receiving portion 11 lower than the upstream supporting portion 12 and the downstream supporting portion 13, so that the ink is suppressed from floating in the machine body as a minute ink mist. Further, in order to suppress the rebound of the ink when the ink lands, it is preferable to provide the ink droplet landing member 28 made of urethane foam on the bottom 25. The ink flow path 29 has a slope formed so that the ink received by the bottom portion 25 and the ink droplet landing member 28 flows, and leads to a waste ink storage portion (not shown). Even when the ink landing member 28 is provided on the bottom portion 25, the top surface of the ink landing member 28 is lower than the upstream support portion 12 and the downstream support portion 13.

FIG. 8 is a block diagram of the control circuit of the recording device 1. The CPU 30 controls each mechanism in the recording device 1 via the controller 32 according to various programs stored in the ROM 31. At that time, the RAM 33 is used as a work area for temporarily storing various data and executing processing. The CPU 30 performs image processing for converting the image data received from the host device connected to the outside into a recording signal that can be recorded by the recording device 1. Then, the CPU 30 records an image on the recording medium P by driving various motors via the motor driver 34 or driving the recording head 5 via the head driver 35.

In FIG. 8, the motor 37 includes a transport motor for driving the transport roller 6, a carriage motor for driving the carriage 51, a feed motor for driving the feed roller 4, an upstream suction fan 18, and a downstream suction fan 24. The fan motors, etc. that drive the carriage are shown collectively. The motor driver 34 collectively indicates the above-mentioned motor driver.

The electrically writable EEPROM 38 stores factory setting values and updated data, and these data are used as control parameters by the controller 32 and the CPU 30. The sensor 39 collectively indicates a temperature sensor and an encoder sensor installed in various places in the apparatus.

Next, an example of the recording operation of borderless recording in the present embodiment will be described with reference to FIGS. 9 and 10. When the recording command is transmitted from the host device or the like, the recording device 1 operates according to the flowchart of FIG. First, in step S1001, the CPU 30 drives the upstream suction fan 18 to bring the upstream negative pressure chamber 17 into a predetermined negative pressure state. Here, the upstream suction fan 18 is PWM-controlled by the motor driver 34, and it is possible to control the suction negative pressure by adjusting the air volume. In order to maintain good transport performance of the recording medium P, the CPU 30 changes the air volume of the upstream suction fan 18 according to the type of the recording medium P, the state of the recording medium P, and the conditions of the atmospheric environment. For example, in the case of thick paper, paper with a large curl, environment with low humidity, etc., a strong negative pressure is preferable. The CPU 30 can also change the negative pressure generated by the upstream suction fan 18 depending on conditions such as the position of the carriage 51 and the current position of the recording medium P.

Next, in step S1002, the feeding device 2 is driven by the CPU 30, and the recording medium P is fed from the feeding device 2 to the first transport roller pair. In step S1003, the first transport roller pair transports the recording medium P to a position where the tip F (see FIG. 10A) of the recording medium P faces the ink receiving portion 11. At this time, the recording medium P is in a state of covering the upstream support portion 12, the closed space formed by the recording medium P and the upstream support portion 12 is in a negative pressure state, and the recording medium P is attracted to the upstream outer peripheral rib 14. Will be done.

When the recording medium P is conveyed to the recording start position T shown in FIG. 10A, the recording operation by the recording head 5 is started. The recording start position T indicates the position of the tip F of the recording medium P with reference to the axis of the transport roller 6, and is stored in the ROM 31 as a parameter. As shown in FIG. 11, a predetermined value of the recording start position T at the time of borderless recording is stored in the ROM 31. In this embodiment, in order to show an example of borderless recording on A4 size glossy paper, the recording start position T is a position 45 mm from the axis of the transport roller 6. The CPU 30 determines the type and size of the recording medium P based on the information included in the recording command.

Since the strength of the curl habit differs depending on the type and size of the recording medium P, the parameters differ as shown in FIG. In general, smaller size paper tends to have a stronger curl habit than larger paper. Therefore, as the size of the paper becomes smaller, the distance between the tip F and the upstream suction hole 16 is reduced to suppress curling habits and lifting at the tip F. For example, even with the same glossy paper, the recording start position T is 40 mm in the case of 2L size, whereas the recording start position T is 45 mm in the case of A4 size.

In general, plain paper tends to have a stronger curl habit than glossy paper. Therefore, when the recording medium P is plain paper, the distance between the tip F and the upstream suction hole 16 is made smaller than that when the recording medium P is glossy paper, and control is performed so as to suppress curling habits and lifting at the tip F. As shown in FIG. 11, for example, even if the paper size is the same for A4, the recording start position T is 45 mm in the case of glossy paper, whereas the recording start position T is 35 mm in the case of plain paper. Is.

Further, the position of the tip F is calculated from the timing at which the CPU 30 detects the amount of rotation of the transport roller 6 and is detected by the front / rear end detection sensor of the recording medium P arranged at a predetermined position. The front / rear end detection sensor is provided, for example, on the upstream side of the transport roller 6 in the transport direction. A sensor that directly detects the front and rear ends of the recording medium P may be mounted.

In step S1004, the CPU 30 starts moving the carriage 51 in the main scanning direction, ejects ink from the recording head 5, and performs a recording operation on the recording medium P. At this time, the discharge port region A in which the discharge port used in the recording operation with respect to the tip end F of the recording medium P is arranged is changed according to the recording start position T. In the edgeless recording with respect to the tip F, the discharge port row located about 2 mm downstream in the transport direction from the position facing the tip F (recording start position T) is used. The ink ejected to the outside of the recording medium P is received by the ink droplet landing member 28 of the ink receiving portion 11.

In step S1005, a predetermined amount of the recording medium P is conveyed by the transfer roller 6. In this embodiment, only the transport amount C shown in FIG. 10B is transported. The transport amount C is determined by the CPU 30 before the start of feeding the recording medium P according to the size of the recording medium P and the recording start position T. The transport amount C is adjusted according to the timing at which the rear end of the recording medium P exits the first transport roller pair, the timing at which the tip of the recording medium P enters the second transport roller pair, or the transport operation before and after each. Will be done. Further, the transport amount C is also changed by the image data recorded on the recording medium P. The recording operation in step S1004 and the intermittent transfer operation in step S1005 are repeated until the tip F of the recording medium P is conveyed to a position supported by the downstream support portion 13.

In addition, even when the edgeless recording is performed on the side end portion of the recording medium P, the ink is ejected to the outside of the side end portion as well. The ink ejected to the outside of the recording medium P is received by the ink receiving unit 11.

When the tip F of the recording medium P is conveyed to a position supported by the downstream support portion 13 in step S1006, the downstream suction fan 24 is driven by the CPU 30 in step S1007. At this time, as shown in FIG. 10C, the recording medium P is in a state of covering the downstream support portion 13, and the closed space formed by the recording medium P and the downstream support portion 13 is in a negative pressure state for recording. The medium P is adsorbed on the downstream outer peripheral rib 21. That is, the recording medium P is adsorbed on both the upstream outer peripheral rib 14 and the downstream outer peripheral rib 21. As a result, curling habits and floating of the recording medium P are suppressed, and the distance between the recording medium P and the recording head 5 can be maintained appropriately.

By repeating step S1008 and step S1009, the CPU 30 continues the borderless recording on the recording medium P by the recording operation and the intermittent transfer operation. When the CPU 30 determines in step S1010 that the rear end B of the recording medium P has been transported to the downstream side in the transport direction from the upstream support portion 12, the CPU 30 stops driving the upstream suction fan 18 in step S1011.

In steps S1012 and S1013, the recording operation and the intermittent transfer operation are repeated. In step S1014, the CPU 30 determines whether or not the image data corresponds to the borderless recording of the rear end B. If the image data is for the rear end B, the rear end B is transported to the recording completion position BT by the second transport roller pair in step S1015.

The recording completion position BT is the position of the rear end B of the recording medium P with reference to the axis of the transport roller 6, and is stored in the ROM 31 as a parameter. As shown in FIG. 11, a predetermined value of the recording completion position BT at the time of borderless recording is stored in the ROM 31. In this embodiment, for borderless recording on A4 size glossy paper, the recording start position BT is 33 mm from the axis of the transport roller 6 as shown in FIG. 10 (d).

In step S1016, borderless recording is performed on the rear end B of the recording medium P. At this time, the discharge port area D in which the discharge port used in the recording operation for the rear end B is arranged is changed according to the recording completion position BT. In the edgeless recording with respect to the rear end B, the discharge port located about 2 mm upstream in the transport direction from the position facing the rear end B (recording completion position BT) is used. The ink ejected to the outside of the recording medium P is received by the ink droplet landing member 28 of the ink receiving portion 11.

Finally, in step S1017, the recording medium P is discharged to the outside of the recording device 1 by the second transport roller pair, and the borderless recording on the recording medium P is completed. In the present embodiment, the driving of the upstream suction fan 18 and the downstream suction fan 24 is controlled according to the transport position of the recording medium P, but the present invention is not limited to this, and both suction fans are driven at the start of the recording operation for recording. The drive of both suction fans may be stopped at the end of the operation.

As described above, the recording medium P is adsorbed by at least one of the upstream support portion 12 and the downstream support portion 13 from the start to the end of recording by the recording head 5. Therefore, suitable edgeless recording can be performed on both the front end F and the rear end B of the recording medium P by suppressing the floating of the recording medium P due to the curl habit and the like. Further, an appropriate distance can be maintained between the recording head 5 and the recording medium P, and a high-quality image can be recorded.

Further, when the upstream support portion 12 does not support the recording medium P, the drive of the upstream suction fan 18 is stopped, and when the downstream support portion 13 does not support the recording medium P, the drive of the downstream suction fan 24 is stopped. Control to do. As a result, it is possible to reduce the phenomenon that the ink droplets ejected from the recording head 5 are flown by the air flow that does not contribute to the adsorption of the recording medium P and the image appears to be stretched near the end of the recording medium P. can do.

The recording start position T is changed according to the type and size of the recording medium P, but it is desirable that the recording start position T be set so that the distance from the upstream suction hole 16 is as large as possible. In a configuration such as Platen 8 that attracts and supports the recording medium P by negative pressure, fine mist-like ink (ink mist) generated in the recording operation rides on the airflow and adheres to the back surface of the end portion of the recording medium P. There is. On the other hand, by performing the recording operation at a position where the tip F is away from the upstream suction hole 16, the influence of the air flow on the ink mist generated in the vicinity of the tip F can be reduced. Similarly, it is desirable that the recording completion position BT is also set so that the distance from the downstream suction hole 54 is large. That is, it is desirable that the recording start position T and the recording completion position BT are set to appropriate positions that can suppress both the floating of the end portion according to the type of the recording medium P and the back surface stain due to the ink mist.

Further, the recording start position T and the recording completion position BT may be parameters that can be changed by the user as needed, for example. Further, the recording start position T and the recording completion position BT are not limited to the positions based on the axis of the transport roller 6, and may be based on the positions detected by the front / rear end detection sensor. Further, it is desirable to change the recording start position T and the recording completion position BT according to the length of the discharge port row of the recording head 5.

The recording start position T, the recording completion position BT, and the discharge port area A and the like that are changed accordingly are not limited to this embodiment. Further, by changing the suction strength of each of the upstream suction fan 18 and the downstream suction fan 24 or switching ON / OFF in the recording process, the recording medium P can be sucked with the optimum suction force.

[Second Embodiment]
The present embodiment shows a configuration in which an intermediate rib 40 capable of supporting the recording medium P is added to the ink receiving portion 11. FIG. 12 is a perspective view of a platen 8 provided with an intermediate rib (intermediate support portion) 40 on the ink receiving portion 11. A plurality of intermediate ribs 40 are provided in an island shape on the ink receiving portion 11 side by side in the main scanning direction. The top surface of the intermediate rib 40 is at the same height as the upstream outer peripheral rib 14 and the downstream outer peripheral rib 21.

In order to prevent ink mist from adhering to the intermediate ribs 40 and causing stains on the back surface of the recording medium P during rimless recording with respect to the side end portion of the recording medium P, the intermediate ribs 40 are used for recording media P of each size. It is provided so as to be separated from the side end portion of the above by a predetermined value (5 mm) or more. In the transport direction, it is desirable that the upstream end of the intermediate rib 40 is provided at a distance of 10 mm or more from the upstream support portion 12, and the downstream end of the intermediate rib 40 is provided at a distance of 10 mm or more from the downstream support portion 13.

By providing the intermediate rib 40 in this way, the drop of the recording medium P into the ink receiving portion 11 is suppressed, so that the recording start position T is made larger than that of the first embodiment as shown in FIG. 13 (a). Can be done. That is, the recording start position T and the upstream support portion 12 can be separated from each other as compared with the first embodiment, and the back dirt of the recording medium P due to the ink mist can be reduced. Further, as shown in FIG. 13B, the recording completion position BT can be made smaller than that of the first embodiment. That is, the recording completion position BT and the downstream support portion 13 can be made smaller than those in the first embodiment, and the back dirt of the recording medium P due to the ink mist can be reduced. Along with this, the discharge port region used for edgeless recording is the entire discharge port row 27 for both the front end and the rear end. This increases the number of discharge ports that can be used for edgeless recording at the front and rear ends, and improves throughput. Further, even in the recording operation other than the end portion, the recording medium P is supported by the intermediate rib 40, so that the waviness of the recording medium P can be suppressed and the recording quality is improved.

[Third Embodiment]
This embodiment is a configuration in which the serial type recording head 5 of the first embodiment is changed to a line head 41. FIG. 14 is a top view showing the positional relationship between the line head 41 and the platen 8, and the line head 41 schematically shows the outer shape (dotted line frame) and the discharge port row 42 on the platen 8. In the line head 41, a plurality of ejection ports are arranged along the X direction for each color of ink. In the present embodiment, there is a discharge port row 42 corresponding to four colors of K (black), Y (yellow), M (magenta), and C (cyan) from the upstream side in the transport direction. The type and number of colors are not limited to this.

The platen 8 is composed of an ink receiving portion 11, an upstream support portion 12, and a downstream support portion 13 as in the first embodiment. The first side wall 26 of the ink receiving portion 11 is located upstream of the black discharge port row 42K in the transport direction, and the second side wall 55 is located downstream of the cyan discharge port row 42C in the transport direction. The line head 41 of the present embodiment has a discharge port row 42 for each color, but the present invention is not limited to this, and short linear discharge port rows may be arranged in a staggered pattern.

Subsequently, the borderless recording of this embodiment will be described with reference to the flowchart of FIG. In step S1601, the CPU 30 starts driving the upstream suction fan 18, and in step S1602, feeding is performed by the transfer roller 6. When the recording medium P is conveyed to a position facing the discharge port row 42 in step S1603, the recording operation by the recording head 5 is started. Here, unlike the serial type, the line head 41 does not have a reciprocating scan of the carriage 51, so that the stop time of the first transport roller pair and the second transport roller pair is unnecessary. That is, the recording medium P is continuously conveyed from the start of recording in step S1603 to the completion of recording in step S1608 described later.

When the tip F of the recording medium P is conveyed to a position facing the downstream outer peripheral rib 21 in step S1604, the downstream suction fan 24 is driven in step S1605. Further, when recording is continued and the rear end B of the recording medium P is transported downstream from the upstream outer peripheral rib 14 in the transport direction in S1606, the drive of the upstream suction fan 18 is stopped in step S1607. Then, when the rear end B is conveyed downstream from the cyan discharge port row 42C, recording is completed in step S1608, and the recording medium P is discharged to the outside of the recording device 1 in step S1609.

As described above, even in the recording device 1 using the line head 41, the recording medium P can be recorded in a state of being adsorbed on both the front end F and the rear end B of the recording medium P, so that the recording medium P can be lifted. It can be suppressed.

1 Inkjet recording device 5 Recording head 6 Transfer roller (1st transfer means)
7 Pinch roller (first transport means)
8 Platen 9 Discharge roller (second transport means)
11 Ink receiving part 12 Upstream support part 13 Downstream support part 16 Upstream suction hole 54 Downstream suction hole P Recording medium

Claims (12)

A recording head that ejects ink to a recording medium to perform recording operations,
A first transport means for transporting the recording medium in the first direction and provided upstream of the recording head in the first direction.
A second transport means that transports the recording medium in the first direction and is provided downstream of the recording head in the first direction.
An ink receiving portion that is provided so as to face the recording head and receives ink discharged from the recording head, and an ink receiving portion that is provided between the ink receiving portion and the first transport means in the first direction and is provided from a suction hole. An upstream support portion that attracts and supports a recording medium by sucking air is provided between the ink receiving portion and the second transport means in the first direction, and air is sucked from the suction holes. It is provided with a downstream support portion that supports the recording medium while adsorbing it, and a platen that has and can support the recording medium.
The downstream support portion and the upstream support portion, possess a recess wherein the suction hole is not supporting the recording medium is provided, and the ribs for supporting the enclosure recording medium the periphery of the recess, and
When the recording head ejects ink to the outside of the tip of the recording medium to perform a recording operation, the tip of the recording medium is conveyed from the tip to the recording start position where the recording operation is started. 1 An inkjet recording apparatus characterized in that the distance to a transport means is changed according to the size of a recording medium. A recording head that ejects ink to a recording medium to perform recording operations,
A first transport means for transporting the recording medium in the first direction and provided upstream of the recording head in the first direction.
A second transport means that transports the recording medium in the first direction and is provided downstream of the recording head in the first direction.
An ink receiving portion that is provided so as to face the recording head and receives ink discharged from the recording head, and an ink receiving portion that is provided between the ink receiving portion and the first transport means in the first direction and is provided from a suction hole. An upstream support portion that attracts and supports a recording medium by sucking air is provided between the ink receiving portion and the second transport means in the first direction, and air is sucked from the suction holes. It is provided with a downstream support portion that supports the recording medium while adsorbing it, and a platen that has and can support the recording medium.
The downstream support portion and the upstream support portion, possess a recess wherein the suction hole is not supporting the recording medium is provided, and the ribs for supporting the enclosure recording medium the periphery of the recess, and
When the recording head ejects ink to the outside of the tip of the recording medium to perform a recording operation, the tip of the recording medium is conveyed from the tip to the recording start position where the recording operation is started. 1 An inkjet recording apparatus characterized in that the distance to the transport means is changed according to the type of recording medium. A recording head that ejects ink to a recording medium to perform recording operations,
A first transport means for transporting the recording medium in the first direction and provided upstream of the recording head in the first direction.
A second transport means that transports the recording medium in the first direction and is provided downstream of the recording head in the first direction.
An ink receiving portion that is provided so as to face the recording head and receives ink discharged from the recording head, and an ink receiving portion that is provided between the ink receiving portion and the first transport means in the first direction and is provided from a suction hole. An upstream support portion that attracts and supports a recording medium by sucking air is provided between the ink receiving portion and the second transport means in the first direction, and air is sucked from the suction holes. It is provided with a downstream support portion that supports the recording medium while adsorbing it, and a platen that has and can support the recording medium.
The downstream support portion and the upstream support portion, possess a recess wherein the suction hole is not supporting the recording medium is provided, and the ribs for supporting the enclosure recording medium the periphery of the recess, and
When the recording head ejects ink to the outside of the rear end of the recording medium to perform a recording operation, the rear end of the recording medium is conveyed to the recording completion position where the recording operation is performed from the rear end. An inkjet recording apparatus characterized in that the distance to the first transport means is changed according to the size of a recording medium. A recording head that ejects ink to a recording medium to perform recording operations,
A first transport means for transporting the recording medium in the first direction and provided upstream of the recording head in the first direction.
A second transport means that transports the recording medium in the first direction and is provided downstream of the recording head in the first direction.
An ink receiving portion that is provided so as to face the recording head and receives ink discharged from the recording head, and an ink receiving portion that is provided between the ink receiving portion and the first transport means in the first direction and is provided from a suction hole. An upstream support portion that attracts and supports a recording medium by sucking air is provided between the ink receiving portion and the second transport means in the first direction, and air is sucked from the suction holes. It is provided with a downstream support portion that supports the recording medium while adsorbing it, and a platen that has and can support the recording medium.
The downstream support portion and the upstream support portion, possess a recess wherein the suction hole is not supporting the recording medium is provided, and the ribs for supporting the enclosure recording medium the periphery of the recess, and
When the recording head ejects ink to the outside of the rear end of the recording medium to perform a recording operation, the rear end of the recording medium is conveyed to the recording completion position where the recording operation is performed from the rear end. An inkjet recording apparatus characterized in that the distance to the first transport means is changed according to the type of recording medium. The recording head has a plurality of ejection ports for ejecting ink, the ink receiving portion is located at a position facing the plurality of ejection ports, and the upstream support portion is more than the plurality of ejection ports in the first direction. The inkjet recording apparatus according to any one of claims 1 to 4 , wherein the downstream support portion is located on the upstream side and is located on the downstream side of the plurality of ejection ports in the first direction. The downstream support portion and the upstream support portion, claim 1, characterized in that it comprises a second rib which supports the recording medium provided in the vicinity of an end of the recording medium in a second direction crossing the first direction 5. The inkjet recording apparatus according to any one of 5. One of claims 1 to 6 , wherein when the recording medium is supported by the upstream support portion but not supported by the downstream support portion, air is not sucked from the suction hole of the downstream support portion. The inkjet recording apparatus according to the above. Any one of claims 1 to 7 , wherein when the recording medium is supported by the downstream support portion but not supported by the upstream support portion, air is not sucked from the suction hole of the upstream support portion. The inkjet recording apparatus according to the above. The inkjet recording apparatus according to any one of claims 1 to 8 , wherein the ink receiving portion is provided lower than the upstream support portion and the downstream support portion. The inkjet recording apparatus according to any one of claims 1 to 9 , wherein the ink receiving portion has an intermediate support portion capable of supporting a recording medium. The inkjet recording apparatus according to claim 10 , wherein the intermediate support portion is provided so that the distance from the upstream support portion and the downstream support portion is a predetermined value or more in the first direction. The inkjet recording according to claim 10 or 11 , wherein the intermediate support portion is provided so that the distance from the side end of the recording medium in the second direction intersecting the first direction is equal to or larger than a predetermined value. Device.

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