JP2008036929A - Recording apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a recording apparatus capable of keeping flatness of a recording medium on a platen even when kind of the recording medium is not known and capable of holding a recording image at a high quality. <P>SOLUTION: The recording apparatus records an image on the recording medium 3 supported by the platen 12 by a recording head 2. The recording apparatus is equipped with a sucking means 17 for sucking the recording medium on the platen, a sucking force adjusting means 18 for adjusting the sucking force for the recording medium by the sucking means, a flatness detecting means 1 for detecting the flatness of the recording medium during sucking, and a flatness storing means 9 for storing the flatness detected by the flatness detecting means. The sucking force during recording is adjusted based on the flatness stored by the flatness storing means. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a recording apparatus that records an image on a recording medium supported by a platen using a recording head. More specifically, the present invention relates to a recording apparatus that performs image recording while sucking a recording medium onto a platen by suction means.

  Generally, a recording apparatus having a function such as a printer, a copying machine, or a facsimile uses a recording head based on image information to print an image (characters, symbols, etc.) on a recording medium such as paper, cloth, plastic sheet, OHP sheet, envelope, or the like. Configured to record). There are a serial type and a line type as a scanning method in the recording apparatus. The serial type is a method in which an image is recorded while alternately repeating main scanning for moving the recording head along the recording medium and sub-scanning for feeding the recording medium at a predetermined pitch. The line type is a system in which an image is recorded only by paper feeding (sub-scan) of a recording medium while recording one line at a time. The recording apparatus can be classified into an ink jet type, a thermal transfer type, a laser beam type, a thermal type, a wire dot type, and the like depending on the recording type.

  An ink jet recording apparatus (ink jet recording apparatus) records an image by discharging ink from a recording head from a recording head based on image information. In such a recording apparatus that records an image by immersing liquid ink in a recording medium such as an ink jet recording apparatus, the fiber may expand at a portion of the recording medium that has absorbed the ink. For this reason, a phenomenon called cockling in which the surface of the recording medium becomes uneven in the image recording portion may occur. When this cockling occurs, the recording medium is lifted off the platen, and the quality of the recorded image is likely to deteriorate. Also, when the recording medium itself is warped, it becomes a factor that rises from the platen. When the recording medium is lifted for such a reason, the recording medium comes into contact with the recording head, which may cause a paper jam or damage to the recording head. Therefore, in a recording apparatus such as an ink jet recording apparatus, it has been proposed that a platen is provided with a large number of holes and a recording medium is adsorbed to the platen by suction from the holes using a fan. By discharging ink and recording or feeding the recording medium in such an adsorbed state, it becomes possible to prevent paper jamming of the recording medium and damage to the recording head.

  By the way, to prevent the recording medium from rising and to ensure the flatness of the recording surface, in particular, not only plain paper and photographic paper, but also a medium-sized or large format for business that handles various recording media including films. In a recording apparatus, it is important for maintaining the quality of a recorded image. In particular, in large-format printers that record on a recording medium having a size of 24 inches or more, roll paper wound in a roll shape is often used, and curling remains even after feeding in this roll paper, so that floating occurs. Cheap. Such a tendency becomes stronger in the case of a thick recording medium. However, a strong suction force is required to attract a thick recording medium. Under such a strong suction force, plain paper or film is excessively attracted, making smooth conveyance difficult. Will happen. In addition, when the size of the recording medium is small, there is a disadvantage that a part of the suction hole is not blocked by the recording medium and the suction force is reduced.

  To solve such problems, a plurality of grooves and ribs between the grooves are formed on the platen surface in the paper conveyance direction, and suction holes are provided at the bottom of the grooves, and air is sucked from here to avoid paper floating. A configured recording apparatus is disclosed in Patent Document 1. These grooves and ribs form irregularities on the platen for smoothly conveying the recording medium. Further, in Patent Document 1, even if the size of the recording paper is changed, both end edges thereof are located on the ribs between the grooves, so that floating and deformation at the edge portions can be prevented. ing.

Also, when recording on the recording medium, the suction fan for adsorbing the recording medium to the platen is stopped or operated depending on the type of the recording medium, thereby preventing the recording medium from wrinkling or rubbing. An image forming apparatus is disclosed in Patent Document 2. This Patent Document 2 also discloses that when a recording medium such as a film is conveyed, the recording medium is prevented from being damaged by reversing the suction fan to lift and release the recording medium.
JP 2001-162870 A JP 2002-127515 A

However, Patent Document 1 discloses a configuration for preventing the suction force from being lowered when the size of the recording paper is changed and the suction hole is opened. However, the problem of flatness of the recording paper on the platen and the flatness are disclosed. There is no description regarding the maintenance of adjustment. Furthermore, there is no suggestion about the flatness on the uneven platen in which grooves and ribs are formed.
Further, Patent Document 2 discloses an invention for preventing wrinkles and twists when sucking a recording medium, or scratching of a film-type recording medium being conveyed. However, the invention of the cited document 2 is based on the premise that the type of the recording medium is known in advance, and cannot cope with the case where the type of the recording medium is unknown. Further, there is no suggestion regarding the adjustment and maintenance of the flatness of the recording medium on the platen. For this reason, even if a sensor is provided so that the type of the recording medium can be discriminated, it is impossible to adjust and maintain the flatness of the recording medium on the platen.

  The present invention has been made in view of such technical problems. An object of the present invention is to provide a recording apparatus capable of maintaining the flatness of a recording medium on a platen and maintaining a recorded image with high quality even when the type of the recording medium is unknown.

  The present invention relates to a recording apparatus that records an image on a recording medium supported by a platen using a recording head. The recording apparatus includes a suction unit that sucks the recording medium onto the platen, a suction force adjustment unit that adjusts the suction force of the recording medium by the suction unit, and a flatness detection unit that detects the flatness of the recording medium being sucked. Flatness storage means for storing the flatness detected by the flatness detection means. Therefore, the suction force during recording is adjusted based on the flatness stored in the flatness storage means.

  According to the present invention, there is provided a recording apparatus capable of maintaining the flatness of a recording medium on a platen and maintaining a recorded image with high quality even when the type of the recording medium is unknown.

  Embodiments of the present invention will be specifically described below with reference to the drawings. Note that the same reference numerals denote the same or corresponding parts throughout the drawings. FIG. 1 is a block diagram showing an overall schematic configuration of a recording apparatus according to an embodiment of the present invention. FIG. 2 is a plan view showing the main configuration of the recording apparatus according to the embodiment of the present invention. FIG. 3 is a longitudinal sectional view of a central portion showing a schematic configuration of a recording apparatus according to an embodiment of the present invention. 1 to 3, a distance sensor 1, a recording head 2, a relay substrate 4, and a recording medium edge detection sensor 16 are mounted (mounted) on a carriage 5A. A carriage unit 5 is constituted by a carriage 5A on which these are mounted. The carriage 5A (carriage unit 5) is guided and supported so as to be able to reciprocate in the width direction of the recording medium with a predetermined gap from the recording medium 3 supported on the platen 12.

  The distance sensor 1 detects the distance between the recording head 2 and the recording medium, and in the present embodiment, is constituted by a reflective sensor having a visible light LED and a photodiode. The recording head 2 is an ink jet recording head that records an image by ejecting ink onto a recording medium based on image information. On the ejection surface of the recording head facing the recording medium, there are provided ejection port arrays (a plurality of ejection port arrays for color recording) formed by arranging a plurality of ejection ports. On the relay substrate 4, a receiving circuit for the output signal of the distance sensor 1 is mounted. As the recording medium 3, various papers such as cloth, plastic sheets, OHP sheets, envelopes and the like can be used as long as the recording head 2 can record images (including characters and symbols) as the recording medium 3. Materials can be used.

  The main body 6 for controlling each unit and each mechanism of the recording apparatus is mounted on the apparatus main body. A CPU 7 is mounted on the main board 6, and an AD converter (hereinafter referred to as ADC) 8 and a memory 9 are built in the CPU 7. The carriage drive device 10 receives a signal from the CPU 7 and reciprocates the carriage unit 5 in the X direction (the width direction of the recording medium). The carriage driving device also includes a set of components necessary for moving the carriage, such as a roller, a gear, a motor, a guide rail, and a timing belt for moving the carriage unit 5. In response to the signal from the CPU 7, the recording medium conveyance device 11 moves (conveys) the recording medium 3 in the feeding direction indicated by the arrow Y. The recording medium transport device 11 also includes a set of parts necessary for feeding such as a roller, a gear, a motor, and a belt for feeding the recording medium.

  The recording medium 3 in the image recording unit is supported by the platen 12. A plurality of suction holes 20 for adsorbing (sucking) the recording medium to the platen are formed on the upper surface (platen surface) of the platen 12. Each suction hole 20 communicates with the suction fan 17 via the intake duct 21. A negative pressure is generated in the suction hole 20 by operating the suction fan 17 as the suction means and sucking and discharging air in the direction of the dotted arrow in FIG. For example, a sirocco fan is used as the suction fan. The recording medium 3 is adsorbed on the platen 12 by this negative pressure suction force. The top surface of the platen 12 is provided with an uneven shape for smoothly transporting the recording medium 3. This uneven shape is formed by a plurality of grooves extending in the transport direction and ribs between the grooves, and suction holes 20 are formed on the bottom surface (bottom) of each groove.

  In the present embodiment, the suction holes 20 are formed in two rows in the width direction of the recording medium. The distance sensor 1, the recording head 2, and the recording medium edge detection sensor 16 on the carriage 5A are arranged at the center of two rows of suction holes. A recording medium front end detection sensor 13 for detecting the front end of the recording medium 3 is disposed at a position closer to the downstream side in the transport direction than the suction hole 20 on the platen 12. The sensor 13 can be constituted by a light reflection type sensor, for example. The relay board 4 on the carriage 5A and the main board 6 on the apparatus main body side are electrically connected by a flexible cable 15. Image information (head data) to the recording head 2 and output signals from the distance sensor 1 and the recording medium edge detection sensor 16 are transmitted by the flexible cable 15.

  The suction fan 17 is driven by a fan control device 18 having a drive circuit. The main board 6 of the apparatus main body is connected to the PC 19. A recording medium (roll paper) holder 14 is attached to the recording apparatus. The recording medium holder holds a recording medium (roll paper) 3 made of continuous paper wound around a paper tube in a roll shape. The roll paper 3 is conveyed onto the platen 12 (image recording unit) by a conveyance roller group 22 (FIG. 3) constituting the recording medium conveyance device 11, and the roll paper 3 on which a predetermined image is recorded has a predetermined length. After being cut, the paper is discharged onto a paper discharge tray 23 (FIG. 3). A home position sensor (HP sensor) 24 for detecting that the carriage unit is at the home position (initial position) is disposed at the home position of the carriage unit 5. The home position of the carriage is set to a predetermined position on the right side outside the recording area in FIG. 2, for example.

  FIG. 4 is a flowchart showing the overall operation flow of the recording apparatus according to the embodiment of the present invention. FIG. 5 is a flowchart showing the flow of the suction force adjustment sequence in FIG. FIG. 6 is a flowchart showing the flow of the recording sequence in FIG. FIG. 7 is a table showing the relationship between the drive setting value and the drive voltage (suction force setting method) of the sirocco fan as the suction means of the recording apparatus according to an embodiment of the present invention. Hereinafter, embodiments of the present invention will be described with reference to FIGS. However, in the embodiment described below, the following eight conditions (1) to (8) are assumed. First, these conditions (1) to (8) will be described.

(1) Driver software for recording apparatus control is installed in a PC (personal computer) 19, and a suction force adjustment sequence and a recording start command are performed from the PC 19 via the driver software.
(2) In order to reliably control the recording position, the distance sensor 1, the recording head 2, the recording paper edge detection sensor 16, and the carriage 5A are assembled with sufficient accuracy. The assembly accuracy is higher than the detection accuracy by an encoder sensor (not shown) and an encoder scale (not shown) for detecting the position of the carriage.
(3) The fan control device 18 is provided with a variable DC-DC converter circuit for receiving a control signal having a resolution of 8 bits from the CPU 7 and variably controlling the maximum 24V fan drive voltage up to 12v.

(4) One or more ink tanks (not shown) for supplying ink to the recording head 2 are mounted on the carriage unit 5 at a higher position than the recording head 2. Of course, the ink tank may be installed at a position other than a moving body such as a carriage unit, and the ink tank and the recording head may be connected by a tube.
(5) The initial position of the carriage unit 5 is determined by the HP sensor 24, and the moving distance from the home position is accurately detected by the encoder sensor and encoder scale described above.
(6) The recording medium 3 is fed from the sheet feeding mechanism in the case of a cut sheet, and is fed from the recording medium holder 14 in the case of roll paper. Prior to recording, the recording medium holder 14 is set at a position where it can be fed by the recording apparatus itself manually by the user.

(7) The drive setting value of the fan control device 18 and the rotational speed and suction force of the suction fan 17 are in a proportional relationship. In this case, the relationship between the drive setting value of the suction fan 17 and the drive voltage is as shown in FIG.
(8) Whether or not the recording medium holder 14 is mounted is detected by a dedicated sensor.
The eight conditions are as described above.
In the case where the present invention is applied to an ink jet recording apparatus, the description of the initial operation around the recording head that is normally performed after the power is turned on in the ink jet recording apparatus will be omitted. This initial operation includes, for example, a recovery operation in which ink is discharged by sucking or pressurizing the ink in the ejection port and the ink in the ejection port is refreshed, or a wiping operation in which foreign matter such as ink adhering to the ejection surface is wiped off and so on.

  Therefore, embodiments of the present invention will be specifically described below. In FIG. 4, after the initial operation of the recording apparatus is completed, it is detected that the recording medium 3 is set in a state where it can be fed to the recording unit (step S11). Next, in step S12, the suction fan (sirocco fan) 17 is driven so as to generate the maximum suction force, and in step S13, the CPU 7 checks the paper width of the recording medium and puts out the leading edge (tip alignment) of the recording medium. In the operations of step S12 and step S13, first, the CPU 7 issues a command for feeding the recording medium to the recording medium transport device 11. Based on this, the recording medium is fed in the arrow Y direction until the recording medium leading edge detection sensor 13 detects the leading edge of the recording medium 3 and is turned on. Subsequently, a command to drive the suction fan 17 at the maximum voltage is issued to the fan control device 18.

  In steps S12 and S13, the suction fan 17 sucks the recording medium 3 with the maximum suction force. Thereafter, the carriage unit 5 is moved from the HP (home position) toward the recording area by the carriage driving device 10 and the sheet width is checked by reading the recording medium edge detection sensor 16. Here, the width of the recording medium 3 can be checked by reading it as the difference of the scale count from the HP of the encoder sensor for detecting the position of the carriage. After the paper width check, the carriage unit 5 is returned to HP.

  Subsequently, in step S14, the CPU 7 displays a message asking whether to start the suction force adjustment sequence. This display is executed, for example, by displaying as a pop-up message on the PC monitor via the driver software in the PC 19. Alternatively, in addition to the display on the monitor, it may be displayed on an operation panel (not shown) in the recording apparatus main body. Next, in step S15, the user selects execution / non-execution of the suction force adjustment sequence from the driver software. This suction force adjustment sequence is executed by the operations in steps S21 to S27 in FIG.

  When the non-execution of the suction force adjustment sequence is selected by the user in step S15, the process proceeds to step S17, and the recording apparatus waits until a recording command is received. If there is a recording command before a certain time has elapsed, the process proceeds to step S18 to perform a recording operation. This recording operation is executed in the sequence of steps S31 to S35 in FIG. If no recording command is received even after a predetermined time has elapsed, the suction fan 17 is stopped. If the recording medium holder 14 is inserted / removed during the standby in step S17, the CPU 7 returns to step S14 again to display a message asking execution of the suction force adjustment sequence, and repeats the subsequent operations.

  Next, the suction force adjustment sequence in step S16 in FIG. 4 will be described with reference to FIG. When the user selects to execute the suction force adjustment sequence in step S15 in FIG. 4, the suction force adjustment sequence is started in step S21 in FIG. Then, in step S22, the output of the distance sensor 1 is sequentially acquired by the CPU 7 while the carriage unit 5 is moved in the direction from the HP toward the recording area by using the carriage driving device 10, and AD conversion is performed by the ADC 8. After the carriage unit 5 is moved to the opposite end (left end in FIG. 2) of the recording medium, the CPU 7 calculates the 3σ value of the data acquired from the distance sensor 1 in step S23. This data relates to the flatness of the recording medium on the platen 12. Therefore, the distance sensor 1 constitutes a flatness detecting means for detecting the flatness of the recording medium 3 being sucked.

  Next, in step S24, the calculated 3σ value is compared with a predetermined threshold value Th1, and it is determined which is greater. This threshold value Th1 is a preset value for the flatness of the recording medium 3, and can be set to an arbitrary value. When the 3σ value is smaller than the threshold value Th1, it is determined that the flatness of the recording medium 3 on the platen 12 is ensured. In this case, the process proceeds to step S25, and the current suction fan drive set value (for example, the maximum drive voltage) is stored in the memory 9 as a record suction fan drive set value (FIG. 7). The memory 9 constitutes flatness storage means for storing the flatness detected by the flatness detection means (distance sensor 1).

  On the other hand, if 3σ is larger than the threshold Th1 in step S24, the suction force is too strong and the recording medium is sucked to the platen 12 more than necessary, and the flatness is lost due to the unevenness on the platen 12. It is judged that In this case, the process proceeds to step S26, and the suction force is reduced by lowering the suction fan drive set value of the control device 18 by a certain amount (one step). Therefore, in step S27, the recording medium 3 is conveyed (feeded) by a certain amount in the Y direction in FIG. In this case, the conveyance amount of the recording medium 3 after changing the suction force is set to be equal to or larger than the row width (for example, the distance from one end to the other end) of the suction holes 20 arranged in two rows as shown in FIG. Here, the fan control device (or fan drive device) 18 constitutes suction force adjusting means for adjusting (changing) the suction force of the recording medium 3 by the suction means 17.

  After adjusting the suction force and transporting the recording medium 3 in steps S26 and S27, the process returns to step S22, and the output of the distance sensor 1 is acquired again while moving the carriage unit 5 from the HP toward the recording area. . Next, a 3σ value is calculated from the data of the distance sensor 1 in step S24. Then, the same control operation as described above is performed until the calculated 3σ value becomes smaller than the threshold value Th1. If the 3σ value does not become smaller than Th1 even if the drive setting value of the suction fan 17 is lowered to the minimum drive voltage of 80h in FIG. 7, this 80h is stored in the memory 9 as the suction fan drive setting value for recording. To do. The suction force adjustment sequence in step S16 is thus completed, and in step S17, the carriage unit 5 is returned to HP and a recording command is awaited.

  After the suction force adjustment sequence in step S16 is completed, in step S17, the recording medium 3 is returned to a position where it does not reach the suction hole 20 and is on standby. In this case, first, the carriage unit 5 is moved until the recording medium edge detection sensor 16 is positioned at the right end (FIG. 2) of the recording medium 3. In this state, the recording medium conveying device 11 causes the recording medium 3 to move in the direction opposite to the arrow Y direction by a certain amount from the position where the recording medium edge detection sensor 16 no longer detects the reflected light from the recording medium 3. It may be returned to (transport return direction). If a recording command is not issued from the PC 19 even after a predetermined time t1 has elapsed after entering the standby state at this position, the suction fan 17 is stopped and waits. The elapsed time t1 in this case may be appropriately determined according to the usage conditions of the recording apparatus from the viewpoint of energy saving and noise.

  When a recording command is issued from the PC 19, the recording sequence in step S18 is started. This recording sequence is executed by the operations in steps S31 to S35 in FIG. That is, when a recording command from the PC is acquired in step S31 of FIG. 6 (when a recording command is issued), an elapsed time t2 from the end of the above-described suction force adjustment sequence to acquisition of the recording command is acquired in step S32. In step S33, the elapsed time t2 is compared with the threshold Th2. When the time t2 is smaller than the threshold Th2, the process proceeds to step S35. In step S35, the suction fan drive set value for recording stored in the memory 9 is set in the fan control device 18, and the suction fan 17 is driven by the corresponding drive voltage (FIG. 7) to perform the recording operation. Start.

  Conversely, if the elapsed time t2 is greater than the threshold value Th2, the process proceeds to step S34. In step S34, after performing the suction force adjustment sequence in step S16 and FIG. 5 again, the recording operation in step S35 is started. Here, the threshold Th2 is a time during which the characteristics of the recording medium 3 are expected to change due to the influence of the surrounding environment. In the present embodiment, the threshold Th2 is set to a value sufficiently larger than the elapsed time t1 waiting for the recording command. The In the present embodiment, the suction force during image recording is adjusted based on the flatness stored in the flatness storage means (memory 9) in the above manner. In this embodiment, the suction force is adjusted in eight stages of fan drive voltages (24.000 V to 12.047 V) corresponding to the eight stages of fan drive set values “FFh” to “80 h” as illustrated in FIG. ).

  In the above embodiment, the paper width check in step S13 is performed before the suction force adjustment sequence in step S16. It is also possible to perform the suction force adjustment sequence while detecting the paper width in step S13 after setting the recording medium in step S11. By using such an operation sequence, throughput can be reduced.

  FIG. 7 illustrates a suction force setting method in the recording apparatus. Although FIG. 7 shows a case where the suction force is changed with a relatively coarse adjustment width, this may be changed with a small adjustment width using the full 8-bit accuracy. Further, the suction force on the platen 12 obtained by the suction fan (for example, sirocco fan) 17 is not only variation in the performance of the fan itself but also air leakage due to the sealing degree of the connection between the intake duct of the recording apparatus main body and the fan. Influenced by variations in quantity. For this reason, it is considered that individual differences occur between the recording devices in the suction force itself. In the present embodiment, even with respect to such a problem in adjusting the suction force, the flatness of the recording medium when it is actually sucked is determined only by the threshold value Th1 that is arbitrarily set in advance, regardless of the variation in the suction force. Can be managed based on. For this reason, the individual difference in manufacture of each component and housing | casing which comprise a recording device can be absorbed.

  In the present embodiment, the flatness threshold value Th1 of the recording medium 3 is set to an arbitrary value, but the threshold value Th1 can be changed according to use conditions. For example, in a use environment in which image quality is given priority over overall throughput, the threshold value Th1 is set small. On the other hand, the threshold value Th1 may be set to a larger value if the usage mode places more importance on the overall throughput than the image quality. In this manner, the suction force (drive) of the suction fan 17 can be set according to the assumed user usage without being limited to the fan drive setting of FIG.

  According to the embodiment described above, in the recording apparatus that sucks the recording medium onto the platen, even when there are irregularities for smooth paper feeding on the platen, the flatness of the recording medium is not lost, and high It is possible to maintain quality recording quality. It is possible to prevent excessive suction due to individual differences of suction fans and variations in the recording device, and to prevent the flatness of the recording medium from being damaged by unevenness on the platen, thereby preventing deterioration in recording quality. . Furthermore, it is possible to automatically set an optimum suction force for the set recording medium regardless of the type of the recording medium. For this reason, it is not necessary to determine the suction force for each type of recording medium in advance. Even when the recording medium is thick roll paper and the fed roll paper is curled, it can be easily and appropriately dealt with. Further, by changing the threshold value, it is possible to easily realize a recording apparatus setting that prioritizes recording quality and a recording apparatus setting that emphasizes throughput. In other words, it is possible to use the same product for different purposes.

  In the above embodiment, the case where the present invention is applied to a recording apparatus such as an inkjet recording apparatus has been described as an example. The present invention is not limited to a single recording apparatus such as a printer, a copying machine, a facsimile, or a captured image forming apparatus. The present invention can be widely applied as a recording apparatus in a composite apparatus combining these or a composite apparatus such as a computer system. In addition, the present invention can be similarly applied when applied to a recording apparatus, regardless of the number and arrangement of recording heads, and can be similarly applied to an inkjet recording apparatus regardless of the type or properties of ink. It is. For recording media, the present invention can be applied regardless of the material or form as long as it can record images (including characters and symbols) such as paper, cloth, plastic sheets, OHP sheets, and envelopes. .

1 is a block diagram illustrating an overall schematic configuration of a recording apparatus according to an embodiment of the present invention. FIG. 2 is a plan view illustrating a main configuration of a recording apparatus according to an embodiment of the invention. 1 is a longitudinal sectional view of a central portion showing a schematic configuration of a recording apparatus according to an embodiment of the present invention. 3 is a flowchart showing a flow of overall operation of the recording apparatus according to the embodiment of the present invention. It is a flowchart which shows the flow of the attraction | suction force adjustment sequence in FIG. It is a flowchart which shows the flow of the recording sequence in FIG. It is a table | surface which shows the relationship (suction force setting method) of the drive setting value and drive voltage of a sirocco fan as a suction means of the recording device which concerns on one Embodiment of this invention.

Explanation of symbols

1 Flatness detection means (distance sensor)
2 Recording head 3 Recording medium (recording paper, etc.)
5 Carriage unit 5A Carriage 9 Flatness storage means (memory)
11 Recording medium transport device 12 Platen 17 Suction means (suction fan, sirocco fan)
18 Suction force adjusting means (fan control device, fan drive device)
20 Suction hole

Claims (5)

In a recording apparatus for recording an image with a recording head on a recording medium supported by a platen,
Suction means for sucking the recording medium onto the platen, suction force adjusting means for adjusting the suction force of the recording medium by the suction means, flatness detecting means for detecting the flatness of the recording medium being sucked, and the flat surface Flatness storage means for storing the flatness detected by the degree detection means,
A recording apparatus for adjusting a suction force during recording based on the flatness stored in the flatness storage means.   2. The recording apparatus according to claim 1, wherein irregularities are formed on the platen by grooves and ribs, and suction holes are formed at the bottom of the grooves.   The recording apparatus according to claim 1, wherein the flatness detecting unit is a reflection type distance sensor attached to a carriage on which the recording head is mounted.   4. The recording according to claim 1, wherein the suction force during recording is adjusted based on flatness when the recording medium is sucked with a maximum suction force that can be set by the suction means. apparatus. If it is determined that the suction force needs to be adjusted based on the flatness when the recording medium is sucked with the maximum suction force that can be set by the suction means, the flatness of the recording medium is reduced after reducing the suction force of the suction means. The recording apparatus according to claim 1, wherein the recording device is detected again.

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