The present invention relates to a recording apparatus including an inkjet head that ejects ink to a recording medium.
An inkjet recording apparatus is widely used. The inkjet recording apparatus is configured to supply ink from an ink cartridge to an inkjet recording head, and eject ink droplets from the recording head onto a recording medium to record an image, character or the like.
Such an inkjet recording head is adopted not only a small-sized recording head for use in a home, small office or the like, but also for a large-sized recording head capable of printing onto a large recording medium having a width of 1 m or wider.
The inkjet recording apparatus includes a carriage on which the recording head is mounted. The carriage is configured to reciprocate across the recording medium in a widthwise direction. The recording head ejects ink onto the recording medium on a forward path and on a backward path. A position of the carriage is detected by reading a linear scale provided along a moving direction of the carriage using a sensor mounted on the carriage. Generally, a device referred to as a linear encoder is used.
The recording head has a lot of small holes, i.e., nozzles. There are cases where the nozzle may be clogged with thickened ink, dust or the like. When the nozzle is clogged, ink is not ejected from the clogged nozzle, and therefore a stripe pattern may be formed in a recorded image.
In order to prevent non-ejection from the nozzle Japanese Laid-Open Patent Publication No. 10-138513 discloses processing performed before recording. In the processing, a test pattern is recorded using respective nozzles, the recorded test pattern is read by an optical sensor to thereby determine a non-ejection nozzle, and an ejection signal is sent to the non-ejection nozzle to forcedly eject ink.
However, in the related art, for example, when the nozzles are arranged at a density of 400 dpi, a nozzle pitch is 63 μm, and a line recorded using one dot has a width of approximately 150 to 200 μm. The sensor has a wide detection range which may include both of a recorded portion and a non-recorded portion. Therefore, when light color ink is used, a contrast between the test pattern and the recording medium is low, and therefore the test pattern may not be accurately detected, i.e., misdetection may occur. Further, the test pattern need be determined in consideration of the detection range of the sensor, a conveyance accuracy of the recording medium, and a relative movement accuracy of the recording medium and the sensor. Therefore, it is necessary to widen a line spacing of the test pattern, and therefore a recording area of the test pattern becomes large.
The present invention is intended to provide a recording apparatus capable of accurately detecting a non-ejection nozzle while reducing an area on a recording medium for detecting the non-ejection nozzle.
According to an aspect of the present invention, there is provided a recording apparatus recording an image on a recording medium. The recording apparatus includes a recording head including a plurality of nozzles ejecting ink onto the recording medium, a conveying unit that conveys the recording medium, and a carriage on which the recording head is mounted. The carriage reciprocates the recording head for scanning in a direction crossing a conveying direction of the recording medium. The recording apparatus further includes a platen provided at a position facing the recording head along a scanning direction of the recording head. The platen supports the recording medium. The recording apparatus further includes a sensor mounted on the carriage and detecting a density of an image recorded on the recording medium, and a detection controller that performs control to record test patterns on the recording medium and read densities of the test patterns using the sensor to thereby detect a non-ejection nozzle of the recording head. The test patterns are formed by recording a line including a predetermined number of dots in predetermined areas for respective nozzles every plurality of times of conveyance of the recording medium. The detection controller reads the test patterns recorded on the recording medium using the sensor, calculates a position of a non-recorded portion in the test patterns, and specifies a position of the non-ejection nozzle based on the calculated position of the non-recorded portion and positions of the nozzles that record the test patterns.
With such a configuration, it becomes possible to provide a recording apparatus capable accurately detecting non-ejection nozzle while reducing an area of a recording medium used for detection of non-ejection nozzle.
In the attached drawings:
Hereinafter, the embodiment of the present invention will be described with reference to the drawings.
First, an entire configuration of an inkjet printer 1 as a recording apparatus of this embodiment will be described with reference to
The carriage 3 is connected to an endless belt 5. The endless belt 5 is connected to a motor 6. The endless belt 5 is wound around a pulley provided at an end of the inkjet printer 1. By driving the motor 6, the endless belt 5 moves, and the carriage 3 moves together with the endless belt 5.
A linear scale 10 is provided along the rail 2. A linear encoder is mounted on the carriage 3. The linear encoder reads scales of the linear scale 10 to thereby acquire a position of the carriage 3.
The platen 7 is a flat plate provided along the rail 2. The platen 7 has a plurality of suction holes on a surface thereof. The platen 7 holds the conveyed recording medium by suctioning the recording medium through the suction holes. A downstream guide 8 is provided downstream of the platen 7 in a conveying direction of the recording medium. The downstream guide 8 guides the conveyed recording medium. Further, an upstream guide is provided upstream of the platen 7 in the conveying direction of the recording medium. Each of the platen 7, the downstream guide 8 and the upstream guide is provided with a heater, and is heated thereby. The heating of the platen 7, the downstream guide 8 and the upstream guide causes the conveyed recording medium to be heated to an appropriate temperature, and promotes fixing of the ink.
The platen 7 is a flat plate made of aluminum. The flat plate made of aluminum has a flat surface, and the suction holes are formed on the flat surface. A groove is formed on a backside of the flat plate, and a heater wire is embedded in the groove for heating the platen 7. Each of the downstream guide 8 and the upstream guide is formed by bending a plate made of iron, and a heater wire is provided on a backside of the plate. The heater wire is covered with and fixed by an aluminum sheet.
The test patterns 21 for detection are recorded on the recording medium. A non-ejection portion 21a is a portion where no image is recorded because of non-ejection of ink for some reason. A nozzle that is to eject ink onto to the non-ejection portion 21a is determined, and is replaced with another nozzle. This suppresses negative influence on quality of a recorded image. The test patterns 21 are configured so that different recording areas are assigned to respective nozzles, and therefore recording positions of the respective nozzles can be specified. That is, based on the test pattern recorded on the recording medium, the nozzle used to record can be specified.
Then, the recording medium 23 is conveyed, and a position on which recording is to be performed moves by one line as shown in
Then, the recording medium 23 is conveyed by one line as shown in
Then, the recording medium 23 is conveyed by one line as shown in
Then, the recording medium 23 is conveyed by one line as shown in
Then, the recording medium 23 is conveyed by one line as shown in
In this example, lines are recorded so as to obtain the maximum recording resolution in the conveying direction of the recording medium 23. However, the present invention is not limited to this example. For example, it is also possible to perform recording while conveying the recording medium 23 to provide a one line interval (i.e., to leave one blank line between lines). In this case, an amount of ink of the recorded dots per unit area on the recording medium decreases. Therefore, in order to prevent a decrease in detection accuracy, it is conceivable to perform recording on a forward path and a backward path to thereby increase an amount of ejected ink and to thicken the color of the line. Further, it is also conceivable to convey the recording medium while repeatedly changing the line interval in the conveying direction in the order of 0 line, 1 line, 2 line and 1 line. In this case, when the line interval (i.e., the number of blank lines) is 1 line, it is conceivable to record the same line twice. When the line interval is 2 line, it is conceivable to record the same line thrice. Recording is performed so that an amount of ink of the recorded dots per unit area of the recording medium does not decrease. Further, by using a plurality of conveyance amounts in the conveying direction, recording can be performed even in a case where an erroneous conveyance is likely to occur. The reason is as follows. The recording medium has characteristics such as slipperiness, deformability or the like depending on a type of the recording medium, and there may be cases where the conveying rollers cannot accurately convey the recording medium if the conveyance amount is small. For example, if the conveyance amount corresponds to one line, there may be cases where the recording medium is deformed but not conveyed by the rotation of the conveying rollers. By conveying such a recording medium using a plurality of conveyance amounts, recording can be performed on the recording medium without causing a problem.
The conveying unit 103 includes the conveying rollers 9, a motor for driving the conveying rollers 9 and a drive circuit for driving the motor, and is configured to convey the recording medium. The conveying rollers 9 include a pair of a drive roller and a pinch roller, and the drive roller is rotated by the motor. The pinch roller is pressed against the drive roller, and rotates following a rotation of the drive roller. The recording medium is nipped between the drive roller and the pinch roller to be conveyed. A drive circuit of the conveying unit 103 is controlled by the controller 100, and drives the motor to rotate the conveying rollers 9 to thereby convey the recording medium.
A carriage moving unit 104 moves the carriage 3 fixed to the endless belt 5 along the rail 2. The motor 6 for rotating the endless belt 5 is driven by a drive circuit provided in the carriage moving unit 104. The drive circuit is controlled by the controller 100, and drives the motor 6 to move the carriage 3 along the rail 2 in accordance with a program of the controller 100.
A recording unit 105 includes the recording heads corresponding to ink colors. The recording heads eject ink based on a drive signal from a head drive circuit. The head drive circuit operates based on a control signal from the controller 100.
A linear encoder 106 optically detects scales of a linear scale linearly provided along a moving direction of the carriage 3. The linear encoder 106 operates based on a control signal from the controller 100, performs analog-to-digital conversion on a result of the detection, and outputs a signal obtained by conversion to the controller 100. By counting the signal, the controller 100 can specify a position of the carriage 3. That is, the controller 100 can obtain the position of the carriage 3, and perform control in accordance with the position of the carriage 3.
Positions of the respective recording heads mounted on the carriage 3 are specified in advance, and are stored in the ROM 101. A desired image can be recorded by driving the recording heads to eject ink in accordance with the position of the carriage 3, that is, the positions of the recording heads.
Test patterns are stored in advance in the ROM 101. There are a plurality of test patterns in accordance with circumstances. The controller 100 reads necessary test patterns from the plurality of test patterns in accordance with the circumstances, and uses the read test patterns.
The R detection unit 17 includes a red LED (Light Emitting Diode) 17a (i.e., a light source) that emits red light, and an optical sensor (i.e., a sensor) that detects reflected light from the lines of cyan and light cyan. The G detection unit 18 includes a green LED 18a (i.e., a light source) that emits green light, and an optical sensor (i.e., a sensor) that detects reflected light from the lines of magenta and light magenta. The B detection unit 19 includes a blue LED 19a (i.e., a light source) that emits blue light, and an optical sensor (i.e., a sensor) that detects reflected light form the lines of black and yellow. Those detection units 17, 18 and 19 are collectively referred to as a detection unit. Those detection units 17, 18 and 19 detect densities of an image recorded on the recording medium in detection ranges of the respective detection units, and output results of the detection to the controller 100. The controller 100 performs calculations based on the results of detection, and changes ejection timing of the recording heads to enhance quality of an image to be recorded.
In step S2, recording is performed based on the recording pattern J. In step S3, the recording medium is conveyed based on the conveyance amount I.
In step S4, it is determined whether recording of the test patterns for all the nozzles is completed. If the recording of the test patterns for all the nozzles is completed, the controller 100 proceeds to step S6. If the recording of the test patterns for all the nozzles is not yet completed, the controller 100 proceeds to step S5.
In step S5, in the case where the conveyance amount I and the recording pattern J are not to be changed, the conveyance amount I and the recording pattern J are kept unchanged. In the case where the conveyance amount I and the recording pattern J are to be changed so as to change the line interval based on the recording medium, the conveyance amount I and the recording pattern J are set according to a predetermined sequence. Then, the controller 100 proceeds to step S2.
In step S6, the carriage 3 and the recording medium 23 are moved to a detection position where detection is performed by the detection units. For example, the carriage 3 and the recording medium 23 are moved to a position where the recording area of the first nozzle in the test patterns is detected by the detection units.
In step S7, the test patterns recorded on the recording medium 23 are detected by the detection units for the colors of the test patterns while the carriage 3 is moved. Detection results (i.e., detection values) is stored in the RAM 102 in association with the positions of the carriage 3.
In step S8, the carriage 3 and the recording medium 23 are moved, and it is determined whether all the test patterns are detected. If all the test patterns are detected, the controller 100 proceeds to step S10. If all the test patterns are yet detected, the controller 100 proceeds to step S9.
In step S9, since the detection of all the test patterns is not yet completed, the carriage 3 and the recording medium 23 are moved to a position where a non-detected pattern is to be detected.
In step S10, a position of the non-ejection nozzle is calculated based on the detection values stored in the RAM 102 in association with the positions of the carriage 3.
Next, in step S11, a normal nozzle (i.e., a replacement nozzle) replacing the non-ejection nozzle is set. For example, a nozzle adjacent to the non-ejection nozzle is set as the replacement nozzle, and is stored in the RAM 102. Alternatively, in the case where lines are recorded using a plurality of paths, another nozzle recording the same line as the non-ejection nozzle is set as the replacement nozzle, and is stored in the RAM 102. Upon recording an image, the controller 100 performs control to cause the replacement nozzle to eject ink.
Further, after the test patterns are recorded by all the nozzles in step S7, it is preferable to record nozzle numbers at portions upstream or downstream of the test patterns recorded by the respective nozzles in the conveying direction of the recording medium. This facilitates checking by a user.
In
Further, in
Further, detection noise can be suitably removed by recording a plurality of rows of the test patterns 21, calculating an average value of one row of the test patterns 21, using the average value as a base value, and setting a median value between the initial value and the base value as the threshold.
Comparison between the detection values of the test patterns and the initial detection value of the surface of the recording medium, and calculation to determine the non-ejection nozzle based on the position of the carriage 3 upon detection is detected are performed in a similar manner as described above.
While the preferred embodiments of the present invention have been illustrated in detail, it should be apparent that modifications and improvements may be made to the invention without departing from the spirit and scope of the invention as described in the following claims.
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