JP2010247402A - Image recording apparatus and cooling control method thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image recording apparatus which achieves stable ink ejection by cooling heat generated by image recording by a fan while maintaining an image recording speed high, and suppresses ink stain within the image recording apparatus generated by influences on ink droplets of an air flow of the fan, and to provide a cooling control method. <P>SOLUTION: An ambient temperature of a recording unit 13 is measured by a unit ambient temperature measuring part 27, and an ink temperature is measured by an ink temperature measuring part 28. A unit driving rate calculating part 20 calculates a driving rate of the recording unit 13 from job information. A cooling control part 19 controls a cooling part 26 on the basis of the information. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an image recording apparatus that records an image on a recording medium while transporting a recording medium such as paper or film, and more particularly to a technique for controlling cooling of a recording unit that generates heat by image recording processing.

2. Description of the Related Art Conventionally, as an image recording apparatus that records an image (including characters) on a recording medium such as paper or film, for example, an ink jet full line type image recording apparatus is known.
In this full-line type image recording apparatus, the recording medium is formed in a direction (main scanning line direction) orthogonal to the conveying direction (sub-scanning line direction) in which the recording medium is conveyed over a length greater than the width of the recording medium. It has a line head.

  The line head includes a long nozzle row composed of a plurality of nozzles that eject ink droplets, and is arranged for each color of ink to be ejected. The line heads for the respective ink colors are arranged at a predetermined interval in the sub-scanning direction, and are arranged so that the ink ejection surface of the nozzle faces the recording medium.

  Such an image recording apparatus records characters and images by ejecting ink of each color from a plurality of nozzle rows in accordance with an ink ejection timing signal onto a recording medium that is conveyed while being opposed to the plurality of nozzle rows. I do.

  As a recording medium conveyance mechanism, conveyance by a belt stretched around two rollers rotating at a constant period is known. Further, as the ink ejection timing signal, a signal corresponding to the conveyance amount of the recording medium by the belt is generated based on the pulse signal generated in accordance with the rotation of the roller rotating at a predetermined period, and the control unit generates this signal. Thus, the recording position of the recording medium in the sub scanning line direction is recognized. The control unit generates an ink discharge timing signal based on the recognition result, and controls the landing position of the discharged ink.

  Further, it is known that each nozzle included in the nozzle row is configured by a piezoelectric element as a recording element. The piezoelectric element constituting each nozzle is constituted by a piezoelectric body sandwiched between, for example, two electrodes. This piezoelectric body vibrates when a voltage is applied to the electrodes. The nozzle array discharges ink in the recording unit toward the recording medium which is disposed so as to be opposed to the nozzle array by vibration of the piezoelectric body, and records an image on the recording medium.

  However, recent image recording apparatuses require a large number of ink ejection nozzles, that is, piezoelectric elements, as the image quality is increased and the recording speed is increased. And since many piezoelectric elements are driven at high speed, the image recording apparatus tends to increase the power consumption.

  In such high-resolution and high-speed image recording, when an image with a high printing rate is recorded in an environment where the ink temperature is low, the ink viscosity is high. Supplied over a long period of time. Therefore, more power consumption is required, and the temperature rise of the piezoelectric element, the piezoelectric element driving unit, and the surroundings becomes remarkable.

  In such a case, not only high-quality image recording cannot be maintained, but there is a possibility that the piezoelectric element driving unit does not operate normally due to heat generation, and it is necessary to lower the temperature by some method.

As a method for alleviating the heat generation of such a recording element, for example, there is a technique disclosed in Patent Document 1.
In the technique of Patent Document 1, the operation of a fan that is a cooling unit is controlled according to the temperature of the recording head, and an optimum temperature table is selected from a plurality of temperature tables stored in the storage unit according to the temperature of the recording head. The recording head is operated with the energization pulse width determined while referring to this temperature table.

As another method for reducing the heat generation of the recording head, for example, there is a technique disclosed in Patent Document 2.
In the technique of Patent Document 2, the number of dots of a character pattern to be transferred is calculated for each character, and this dot number data is stored in association with the character pattern. Then, the dot density of one line of printed characters is calculated from the dot number data stored prior to the start of printing of one line, and the air volume of the cooling fan is controlled according to the calculation result.

  By performing such control, in Patent Document 2, the cooling fan rotates only when characters are printed, and unnecessary heat generation, power consumption, and noise during standby are suppressed.

JP 10-76652 A JP-A-3-55274

  However, in the method disclosed in Patent Document 1, a specified temperature is set as the temperature of the recording head, and the cooling fan is turned on / off based on the specified temperature. It is difficult to control the cooling fan.

  Further, ink stains in the image recording apparatus caused by the fan air current are not taken into consideration. The ink ejected from the recording head passes through the air as droplets until it reaches the recording medium. At this time, some of the ink droplets are affected by the air flow and adhere to the image recording apparatus and become dirty. For this reason, the cooling fan for cooling the recording head needs to be driven so that the influence of the air flow on the ink droplets is small.

  Further, in the method disclosed in Patent Document 2, the temperature inside the image recording apparatus is not taken into consideration, and the cooling fan is controlled only by the printing rate. Therefore, even when the temperature is low and the cooling fan is not necessary, the cooling fan is not used. There is a risk of driving.

In addition, when the ambient temperature of the recording head is high and the dot density is low even though cooling is necessary, the recording unit driving unit may not be sufficiently cooled.
Furthermore, since the fan is driven by a timer operation for a certain period of time that is estimated to be necessary until the print head cools after the received data ends, cooling is insufficient, or conversely, excessive cooling is performed. There is a risk that it will not be cooled properly.

  In view of the above problems, the present invention realizes image recording at an optimum temperature by cooling the heat generation of the recording unit while maintaining the image recording speed at a high speed, and also in the image recording apparatus by the air current generated at the time of cooling. An object of the present invention is to provide an image recording apparatus and a cooling control method capable of suppressing contamination.

The image recording apparatus according to the present invention performs recording by ejecting ink onto a recording medium by driving a plurality of nozzles by a drive unit of a recording unit formed by a plurality of nozzles based on job information notified from a host apparatus. In the image recording apparatus, the unit ambient temperature measurement unit that measures the ambient temperature of the recording unit, the ink temperature measurement unit that measures the temperature of the ink,
A cooling unit that cools the recording unit drive unit, a cooling control unit that controls the cooling unit based on the ambient temperature measured by the unit ambient temperature measurement unit and the ink temperature measured by the ink temperature measurement unit, It is characterized by providing.

  Further, according to the cooling control method of the present invention, the drive unit of the recording unit formed by a plurality of nozzles drives the plurality of nozzles to discharge ink onto the recording medium based on job information notified from the host device. A method for controlling cooling of the recording unit by an image recording apparatus that performs recording, measuring an ambient temperature of the recording unit, measuring the temperature of the ink, and driving the recording unit based on the ambient temperature and the ink temperature. The part is cooled.

  According to the present invention, while maintaining a high image recording speed, heat generated during image recording is cooled by a fan to achieve stable ink ejection, and ink droplets are influenced by the air current generated by the fan. Ink stains in the image recording apparatus that occur can be suppressed.

  In addition, while maintaining the temperature of the recording unit at an optimal temperature, the cooling unit that cools the recording unit is operated at an optimal timing, whereby contamination in the apparatus due to ink can be suppressed.

Furthermore, it is possible to reduce noise caused by the cooling unit that cools the recording unit.
In addition, it is possible to reduce power consumption by the cooling unit by minimizing the driving of the cooling unit for cooling the recording unit.

1 is a diagram illustrating a configuration of an image recording apparatus according to an embodiment in a conceptual block configuration. It is a figure which shows arrangement | positioning of each component of the image recording apparatus in this embodiment. It is a block diagram which shows an example of a function structure of the control part of the image recording device in this embodiment. FIG. 6 is a diagram illustrating an image forming signal that is an output of an image forming unit and a unit driving signal that is an output of a unit driving unit when ink temperature information is constant. It is a figure which shows the structural example of a cooling control table. It is a flowchart which shows the operation processing of a cooling control part. It is a block diagram which shows an example of a function structure of the control part as another example.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. In the following description, the conveyance direction of the recording medium is the y direction or the sub-scanning direction, the direction orthogonal to the conveyance direction is the x direction or the main scanning direction, and is orthogonal to both the x direction and the y direction. The direction is defined as the z direction.

FIG. 1 is a diagram showing the configuration of the image recording apparatus in the present embodiment in a conceptual block configuration. FIG. 2 is a diagram showing the arrangement of each component of the image recording apparatus in the present embodiment.
First, the configuration of the image recording apparatus 1 according to the present embodiment will be described with reference to FIGS. 1 and 2.

As shown in FIGS. 1 and 2, the image recording apparatus 1 according to the present embodiment includes a feeding unit 2, a recording medium detection unit 5, a transport mechanism 6, a collection unit 9, an image recording unit 12, and a control unit 16. ing.
In the above configuration, the feeding unit 2 includes a feeding tray 3 and a feeding driving unit 4. Further, the feeding tray 3 is constituted by, for example, a paper feeding cassette or the like and accommodates a recording medium 21. The feeding drive unit 4 is composed of, for example, a feeding roller, and is in contact with the uppermost surface of the recording medium 21 accommodated in the feeding tray 3.

  The feeding unit 2 takes out the recording medium 21 stored in the feeding tray 3 one by one by the feeding driving unit 4 in synchronization with the image forming processing timing for the storage medium 21 and feeds the recording medium 21 to the transport mechanism 6. To send.

  The recording medium detection unit 5 includes, for example, any one of an optical transmission sensor, a reflection sensor, a capacitance sensor, and the like. The recording medium detection unit 5 is provided on the feeding path upstream of the conveying mechanism 6 in the conveying path of the recording medium 21 and detects, for example, the leading end of the recording medium 21 being fed in the sub-scanning direction. Further, when the recording medium detection unit 5 detects the leading end of the recording medium 21, the recording medium detection unit 5 notifies the control unit 16 of detection information indicating the detection.

  The transport mechanism 6 includes a drive roller 22 and a driven roller 23 that are separated in the sub-scanning direction, a transport drive unit 7 that is connected to the rotation shaft of the drive roller 22, a transport information generation unit 8 that is connected to the rotation shaft of the driven roller 23, An endless transport belt 24 stretched between the driving roller 22 and the driven roller 23 and at least one suction fan (not shown) are provided. The suction fan generates a negative pressure under the control of the control unit 16 and sucks the recording medium 21 onto the conveyance belt 24. The transport mechanism 6 transports the recording medium 21 fed from the feeding unit 2 to the downstream side while adsorbing the recording medium 21 to the transport surface of the transport belt 24. The conveyance belt 24 has a conveyance surface of the recording medium 21 opposed to an ink ejection port of at least one of the recording units 13-1 to 13-n (where n is an integer of 2 or more) shown in FIG. 21 is conveyed. On the one hand, the conveyor belt 24 is driven to rotate by a drive roller 22 driven by the conveyor drive unit 7, and on the other hand, the driven roller 23 is driven to rotate.

  The conveyance information generation unit 8 connected to the rotation shaft of the driven roller 23 is configured to include, for example, a rotary encoder. The conveyance information generation unit 8 generates a pulse signal as conveyance information of the recording medium 21 every time the conveyance belt 24 rotates by a predetermined amount, and outputs the pulse signal to the control unit 16. This pulse signal indicates the transport distance of the recording medium 21, and the control unit 16 recognizes the position of the storage medium 21 being transported from this pulse signal.

  The collection unit 9 includes a storage tray 10 and a discharge drive unit 11, for example. The discharge drive unit 11 includes, for example, a pair of discharge rollers, and discharges the recording medium 21 on which the image has been recorded conveyed by the conveyance mechanism 6 to the storage tray 10. The storage tray 10 stores the discharged recording medium 21.

  The image recording unit 12 includes at least one or more recording units 13-1 to 13-n. Each of the recording units 13-1 to 13-n includes nozzle rows 15-1-1-1 to 15-nm (where n and m are integers of 1 or more) and unit driving units 14-1 to 14-n. And is supported by the support member 25.

  In the nozzle rows 15-1-1 to 15-nm, a plurality of nozzles that eject ink are formed in a straight line. The nozzle rows 15-1-1 to 15 -nm are arranged in the main scanning direction over a length exceeding the maximum width recording medium 21 based on the design of the image recording apparatus 1.

  The unit drive units 14-1 to 14-n send drive signals for driving the nozzles to the nozzle rows 15-1-1-1 to 15-n- according to the control signal sent from the control unit 16 based on the print data information. output to m.

  The nozzle rows 15-1-1 to 15-nm discharge ink droplets from a plurality of nozzles selected by the drive signals according to the drive signals from the unit drive units 14-1 to 14-n, respectively, 24, an image is recorded on the recording medium 21 conveyed at a constant speed.

  Here, the image recording unit 12 will be further described. The recording units 13-1 to 13-n are configured to arrange a plurality of nozzle rows 15-1-1-1 to 15-nm as shown in FIG. In FIG. 2, for example, recording units 13-1 to 13-4 are arranged corresponding to four color inks of K (black), C (cyan), M (magenta), and Y (yellow). It shows the case of setting.

  Note that n represents the total number of ink colors. In FIG. Further, m represents the number of nozzle rows set for each ink color. Note that the image recording apparatus 1 according to the present embodiment is not limited to one that handles four colors of ink, and forms a color image using five or more colors of ink even if printing is performed with a single color. May be. In the case of these configurations, the number of recording units 13-1 to 13-n also differs depending on the number of ink colors handled.

  The recording units 13-1 to 13-n for the respective colors are spaced apart from each other along the sub-scanning direction, and the nozzle row 15-1- is at a timing corresponding to the positions disposed before and after the transport path. The recording process to the recording medium 21 is performed by driving 1 to 15-nm.

  The distance traveled to each of the nozzle arrays 15-1-1 to 15 -n-m after the recording medium 21 is detected by the recording medium detection unit 5 is generated as conveyance information by the conveyance information generation unit 8. This conveyance information is the number of pulse signals corresponding to the conveyance distance of the recording medium 21 generated by, for example, a rotary encoder in the conveyance information generation unit 8.

  Therefore, whether or not the recording medium 21 has reached the nozzle rows 15-1-1 to 15-nm is counted by conveying information that is a pulse signal, for example, a recording stored in the recording unit 17 in advance. The determination is made by comparing with a count value corresponding to the distance from the medium detection unit 5 to each of the nozzle arrays 15-1-1 to 15-nm.

  The unit driving units 14-1 to 14-n select the nozzles based on the image forming signal 18a from the image forming unit 18 and select at a timing determined by the timing signal generated based on the conveyance information generating unit 8. The ejected nozzle is driven to eject ink.

  The unit ambient temperature measurement unit 27 is disposed, for example, in the vicinity of the image recording unit 12 and measures the ambient temperature of the image recording unit 12 or the recording unit 13. The unit ambient temperature measurement unit 27 generates ambient temperature information 27 a indicating the ambient temperature of the image recording unit 12 or the recording unit 13 and outputs the signal to the control unit 16.

  Further, an ink temperature measuring unit 28 not shown in FIGS. 1 and 2 is disposed in, for example, the image recording unit 12 and is used for the ink ejected by the nozzle rows 15-1-1 to 15-nm. It measures temperature. The ink temperature measurement unit 28 generates ink temperature information 28 a corresponding to the ink temperature, and outputs the ink temperature information to the control unit 16.

  The cooling unit 26 is installed, for example, in the vicinity of the image recording unit 12, and cools the heat generated by driving the nozzle rows 15-1-1 to 15-nm by the air flow generated by driving the fan. It is a cooling fan. The cooling unit 26 is configured using, for example, a DC motor as a drive source, and the number of revolutions can be controlled by, for example, the magnitude of a voltage applied to the DC motor.

  The host device 29 is, for example, a computer operated by a user who causes the image recording device 1 in the present embodiment to perform recording processing. The host device 29 issues job information for instructing image formation to the image recording apparatus 1 based on a user instruction, and the control unit 16 performs image forming processing based on the job information. The host device 29 is connected to the image recording device 1 as an external device of the image recording device 1 via, for example, a local area network (LAN).

  The control unit 16 includes a processing circuit (not shown) including, for example, an MPU (Microprocessor Unit) in an arithmetic processing device having a control function and an arithmetic function, a storage unit 17, an image forming unit 18, a cooling control unit 19, and a unit drive rate calculation unit 20. At least. The storage unit 17 stores a ROM (read only memory) that stores a control program executed by the MPU, a RAM (Random Access Memory) that serves as a work memory of the MPU, and a non-volatile storage that stores recording processing designation information including recording data. A memory. Further, the RAM temporarily stores setting values related to the control of the image recording apparatus 1 and image recording information.

FIG. 3 is a block diagram illustrating an example of a functional configuration of the control unit 16 of the image recording apparatus 1 according to the present embodiment.
As shown in FIG. 3, the cooling control unit 19 includes a cooling control table 30. The cooling control table 30 drives the cooling unit 26 in association with the ink temperature information 28a, the unit ambient temperature information 27a, and the unit drive rate information 20a output from the unit drive rate calculation unit 20 described below. The setting value is saved. The cooling control unit 19 drives the cooling unit 26 based on the set value in the cooling control table 30. The cooling control unit 19 reads the control information with reference to the cooling control table 30 based on the unit drive rate information 20a, the unit ambient temperature 27a, and the ink temperature 28a. The cooling control unit 19 generates a cooling fan control signal 19a based on the control information read from the control table 30, and outputs the generated cooling fan control signal 19a to the cooling units 26-1 to 26-2.

  The control unit 16 executes the control program read from the storage unit 17 by the MPU, whereby each component of the image recording apparatus 1, that is, the feeding unit 2, the transport mechanism 6, the collection unit 9, the image recording unit 12, The cooling unit 26 and the like are respectively controlled.

  Further, the control unit 16 controls the ink discharge amount of each nozzle included in the nozzle rows 15-1-1 to 15 -nm based on the job information from the host device 29 by the function as the image forming unit 18. Then, the above-described recording process of characters and images (hereinafter simply referred to as images) on the recording medium 21 is performed, and control for determining the recording position in the sub-scanning direction when the recording process is performed on the recording medium 21 is performed.

  The unit drive rate calculation unit 20 uses, for example, nozzles per page of the recording medium 21 based on a signal for controlling the image recording unit 12 based on job information from the host device 29 output by the image forming unit 18. A unit driving rate that is a ratio of the non-driving time and the driving time in columns 15-1-1 to 15-nm is calculated. The unit drive rate calculation unit 20 generates unit drive rate information 20a indicating the unit drive rate and outputs the unit drive rate information 20a to the cooling control unit 19.

The unit driving rate may be defined by a ratio between the non-driving time and the driving time in a predetermined time.
The cooling control unit 19 reads the setting value for driving the cooling unit 26 with reference to the cooling control table 30 using the information of the unit drive rate information 20a, the unit ambient temperature 27a, and the ink temperature 28a. Then, the cooling control unit 19 outputs a cooling control signal 19a based on this set value to the cooling unit 26, and controls the rotation speed of the cooling unit 26. In the present embodiment, the cooling control signal 19a is an ON / OFF signal for instructing driving / stopping to each of the cooling unit 26-1 and the cooling unit 26-2.

Next, the conveyance operation and recording process of the recording medium 21 by the image recording apparatus 1 of the present embodiment having the above-described configuration and functions will be described in detail.
The host apparatus 29 notifies the image recording apparatus 1 of job information related to the recording process. This job information includes image recording information when recording processing is performed on the recording medium 21, and designation information on the number of recording media 21 on which recording processing is performed. The image recording information is expressed as color information for each pixel, for example, and includes density information for each color of black, blue, red, and yellow, for example. That is, the image recording information includes the resolution, density, color information, and the like of the recorded image.

  When the control unit 16 of the image recording apparatus 1 receives the job information 29a from the host apparatus 29, the control unit 16 stores the job information in the storage unit 17 as recording processing (image recording) designation information. When receiving an instruction to start the recording process from the host device 29, the control unit 16 controls the transport driving unit 7 of the transport mechanism 6 to start the rotation of the transport belt 24.

  Subsequently, the control unit 16 controls the feeding drive unit 4 of the feeding unit 2 to take out the recording media 21 stacked on the feeding tray 3 one by one and feed them to the transport mechanism 6. At this time, for example, the leading end of the recording medium 21 fed on the transport path is detected by the recording medium detection unit 5.

  When the recording medium detection unit 5 detects the leading end of the recording medium 21, it outputs a leading edge signal indicating that the leading end has been detected to the control unit 16. The control unit 16 uses the leading edge signal as a trigger signal for generating recording processing timing.

Thereafter, the recording medium 21 that has passed through the recording medium detection unit 5 is further transported to the downstream side of the transport path, and is eventually attracted onto the transport belt 24 of the transport mechanism 6 and transported.
By the way, the pulse signal of the rotary encoder in the conveyance information generated by the conveyance information generation unit 8 is also used as a synchronization signal when the recording process is performed by the nozzle rows 15-1-1 to 15-nm. Therefore, the control unit 16 uses the nozzle rows 15-1-1 to 15-15 from the detection position of the transport medium detection unit 5 as timing information for starting ink ejection by the nozzle rows 15-1-1 to 15-nm. A count value of the number of pulse signals corresponding to the distance to −n−m is stored in the storage unit 17 in advance.

  The image forming unit 18 of the control unit 16 synchronizes the number of pulse signals with the number of pulse signals of the rotary encoder generated by the conveyance information generation unit 8, and unit drive units 14-1 to 14-of the image recording unit 12. n is controlled. By this control, ink is ejected from the nozzle arrays 15-1-1 to 15-nm to the recording medium 21 adsorbed on the conveying belt 24, and recording processing on the recording medium 21 is performed.

  When the host apparatus 29 outputs the job information 29a to the image forming unit 18 of the image recording apparatus 1, the image forming unit 18 selects a nozzle to be driven based on the job information 29a to select color information, resolution, and density information. Is generated and output to the unit driving units 14-1 to 14-n.

  Further, the image forming unit 18 selects a corresponding nozzle row from the nozzle rows 15-1-1 to 15-nm based on the color information included in the job information 29a and records the selected nozzle row on the recording medium 21. Determine the color of the image. At the same time, the image forming unit 18 records on the recording medium 21 by selecting and driving the nozzles included in the nozzle arrays 15-1-1 to 15-nm based on the resolution information included in the job information 29a. Determine the resolution of the resulting image. Further, the image forming unit 18 controls the amount of ink ejected by the nozzle rows 15-1-1 to 15-nm based on the density information included in the job information 29a.

  The unit driving unit 14 includes unit driving units 14-1 to 14-n corresponding to the respective ink colors. The unit driving unit 14 receives the image forming information 18a from the image forming unit 18 and generates a unit driving signal 14a for driving the nozzle arrays 15-1-1 to 15-nm. The unit drive signal 14a is a signal including the number of pulses corresponding to the amount of ink to be ejected, for example, and is a signal that determines the gradation per dot based on the number of times the piezoelectric body vibrates. The unit driving unit 14 controls the voltage applied to the nozzle rows 15-1-1-1 to 15-nm according to the viscosity of the ink.

The nozzle row 15 is composed of nozzle rows 15-1-1 to 15-nm for each color, and is driven based on the unit drive signal 14a to eject ink droplets.
The cooling unit 26 receives the cooling fan drive information 19a from the cooling control unit 19, and air-flows the heat generated when the nozzle rows 15-1-1 to 15-nm are driven according to the cooling fan drive information 19a. Cool by. The nozzle arrays 15-1-1 to 15-nm are cooled to a certain temperature or lower by the cooling unit 26, so that ink can be stably ejected.

  In this way, the recording medium 21 after the recording process is delivered to the collecting unit 9 provided on the downstream side of the transport mechanism 6. Then, the recording medium 21 is sandwiched by the discharge driving unit 11 and further conveyed to the downstream side of the conveyance path, and is eventually stored in the storage tray 10.

Next, details of the operation of the image recording unit 12 will be described.
The image recording unit 12 includes at least one or more recording units 13-1 to 13-n. Each of the recording units 13-1 to 13-n includes nozzle arrays 15-1-1-1 to 15-nm (where n and m are integers of 2 or more), unit driving units 14-1 to 14-n, And is supported by the support member 25.

  The nozzle rows 15-1-1 to 15-nm (where n and m are integers of 2 or more) are constituted by a plurality of nozzles. This nozzle is formed by, for example, forming an ink chamber by a combination of piezoelectric bodies sandwiched between two electrodes, and changes the volume of the ink chamber by vibration of the piezoelectric body generated by applying a voltage between the electrodes. Thus, ink is discharged.

  The image recording unit 12 applies the unit drive signal 14a corresponding to each nozzle between the electrodes of the nozzles included in the nozzle arrays 15-1-1-1 to 15-nm, thereby corresponding to the unit drive signal 14a. An amount of ink is ejected.

  By the way, the ink ejected from the nozzle has a viscosity. Generally, the viscosity is low when the temperature is high, and the viscosity is high when the temperature is low. In order to eject ink with high viscosity, it is necessary to apply a high voltage between the electrodes of the nozzle to vibrate the piezoelectric body strongly. When the viscosity of the ink is high, there is a case where a normal amount of ink cannot be ejected for each pulse of the voltage signal applied between the electrodes of the nozzle.

At this time, in the unit driving unit 14, the power consumption increases as the applied voltage increases. For this reason, the temperature of the image recording unit 12 generates heat as the temperature of the ink is lower.
In addition, when the viscosity of the ink is high, an unexpectedly small amount of ink may be ejected from the nozzle when the ink is ejected. The minute ink is affected by the air current generated by the fan and may adhere to the image recording apparatus and become dirty.

  When an image with a high unit drive rate is recorded, the number of nozzles driven by the nozzle rows 15-1-1 to 15-nm increases and the number of times of driving increases. For this reason, the unit driving unit 14 generates heat as the unit driving rate increases.

  FIG. 4 shows an image forming signal 18a which is an output of the image forming unit 28 and a unit driving signal 14a which is an output of the unit driving unit 14 when the ink temperature information 28a is constant.

  The job information notified from the host device 29 to the control unit 16 includes resolution, density, and color information. The control unit 16 and the unit driving unit 14 use the nozzle row 15-1-1 based on the job information. Unit drive signal 14a for driving ˜15-nm is generated to drive the nozzle rows 15-1-1-1 to 15-nm.

  By performing the waveform processing as shown in FIG. 4, the image recording apparatus 1 drives the nozzle arrays 15-1-1 to 15 -n-m from the job information sent from the host apparatus 29. The unit drive signal 14a is generated.

  In FIG. 4, the unit driving unit 14 converts the image forming signal 18a output from the image forming unit 18 in which the ink amount is represented by a 3-bit binary number into a unit driving signal 14a in which the ink amount is represented by a pulse number. And output to the nozzle row 15. The nozzle row 15 ejects the number of ink droplets corresponding to the number of pulses in the unit drive signal 14a from the corresponding nozzle to the recording medium 21. In the case of FIG. 4, the ink is ejected as 0 dorp, 7 drop, 1 drop,.

  The unit drive signal 14a is output from the unit drive unit 14 to the nozzle row 15 by the number of nozzles included in the nozzle rows 15-1-1-1 to 15-nm, and the resolution of an image recorded by the image recording apparatus 1 is determined. Determine density, color.

Next, the cooling control table 30 provided in the cooling control unit 19 will be described.
FIG. 5 is a diagram illustrating a configuration example of the cooling control table 30.
The cooling control table 30 shown in FIG. 5 includes three tables corresponding to the ink temperature range. The cooling control table 30a corresponds to a table when the ink temperature is lower than 30 ° C., the cooling control table 30b corresponds to a table corresponding to an ink temperature of 30 ° C. or higher and lower than 60 ° C., and the cooling control table 30b corresponds to the ink temperature. Is a table corresponding to when the temperature is 60 ° C. or higher.

  Each of the cooling control tables 30a, 30b and 30c shown in FIG. 5 is associated with information indicating the unit drive rate and the ambient temperature of the image recording unit 12 or the recording unit 13 indicating the number of the cooling units 26 to be driven at that time. Is remembered.

  As shown in FIG. 5, the number of cooling units 26 to be driven increases as the unit drive rate increases and as the ambient temperature increases. Further, the lower the ink temperature, the higher the viscosity of the ink, so that the voltage applied to the recording unit 13 increases. Therefore, the lower the ink temperature, the greater the number of cooling units 26 that are driven.

  In the image recording apparatus 1 of the present embodiment, the cooling unit 26 includes two fans of the cooling units 26-1 and 26-2, and is driven based on the cooling control signal 19a. The cooling units 26-1 and 26-2 make one air flow through the duct and cool the unit driving unit 14. In this example, the two cooling units 26 are provided. However, the image recording apparatus 1 according to the present embodiment is not limited to such a configuration, and may include three or more cooling units 26. In addition, the degree of cooling may be adjusted by controlling the rotation speed of one cooling unit 26. The cooling unit 26 may employ another cooling method such as using a Peltier element instead of the cooling fan.

  When the cooling control table 30 is configured as shown in FIG. 5, neither of the two cooling units 26-1 and 26-2 is driven in the cooling control table 30 ('0'). The information for controlling the three states of the state in which one of the cooling units 26 is driven ('1') and the state in which both the cooling units 26 are driven ('2') is unit ambient temperature information and ink temperature information. , And a set value corresponding to the unit driving rate.

  When the image forming process is performed on the storage medium 21, the cooling fan control unit 6 includes unit ambient temperature information 27 a from the unit ambient temperature measurement unit 27, ink temperature information 28 a from the ink temperature measurement unit 28, and unit drive rate. Using the unit drive rate information 20a from the calculation unit 20, the cooling control table 30 is referred to, and a setting value for controlling the cooling unit 26 is read out. And the cooling control part 19 produces | generates the cooling control signal 19a based on the setting value read from the cooling control table 30, and outputs it to each cooling part 26-1-26-2, and controls these.

  As described above, in the image recording apparatus 1 according to the present embodiment, the cooling control of the recording unit 13 is performed based on the three elements of the ambient temperature of the image recording unit 12 or the recording unit 13, the ink temperature, and the driving rate of the recording unit 13. Is called. In addition, this cooling control is performed based on two temperature information of the ambient temperature of the image recording unit 12 or the recording unit 13 and the ink temperature. These two pieces of temperature information need to be controlled to increase the degree of cooling of the recording unit 13 when the ambient temperature increases, and to decrease the degree of cooling of the recording unit 13 when the ink temperature increases.

  Although the ambient temperature and the ink temperature of the image recording unit 12 or the recording unit 13 need to be controlled to be opposite to each other, the image recording apparatus 1 of the present embodiment performs recording in consideration of both the ambient temperature and the ink temperature. Cooling control of the unit 13 can be performed.

FIG. 6 is a flowchart showing an operation process of the cooling control unit 19.
The cooling control unit 19 receives the ink temperature information 28a from the ink temperature measurement unit 28 in step S1.

  Next, in step S <b> 2, the cooling control unit 19 determines which of the plurality of cooling control tables 30 is to be used from the ink temperature indicated by the ink temperature information 28 a. When the cooling control table 30 has the configuration as shown in FIG. 5, when the ink temperature is lower than 30 ° C. (step S2, 30 ° C.), the process moves to step S3 and the cooling control table 30a is read. If the ink temperature is not lower than 30 ° C. and lower than 60 ° C. (step S2, 30 ° C. to 60 ° C.), the process proceeds to step S4 and the cooling control table 30b is read. Furthermore, when the ink temperature is 60 ° C. or higher (step S2, 60 ° C. <), the process proceeds to step S5, and the cooling control table 30c is read.

  Next, the cooling control unit 19 reads the unit ambient temperature information 27a from the unit ambient temperature measurement unit 27 in step S6. In step S <b> 7, the cooling control unit 19 reads unit drive rate information 20 a from the unit drive rate calculation unit 20.

  In step S8, the cooling control unit 19 refers to the table read in steps S3 to S5 using the head ambient temperature and the unit drive rate, and reads a set value used for driving the cooling unit 26. Then, in step S9, the cooling control unit 19 generates a cooling control signal 19a based on the set value read from the cooling control table 30 in step S8, and outputs this to the cooling unit 26 for drive control.

  As described above, in the image recording apparatus 1 of the present embodiment, the setting value is read from the cooling control table 30 based on the ambient temperature of the recording unit, the ink temperature, and the unit drive rate, and the cooling fan is based on this setting value. The air flow rate is controlled by switching ON / OFF of each 28.

  Therefore, in the image recording apparatus 1 of the present embodiment, the cooling unit 13 performs cooling control based on the temperature around the image recording unit 1 or the recording unit 13 and the temperature change of the image recording unit due to the unit drive rate and the ink temperature. Temperature control. Thereby, stable ink discharge from the recording unit 13 can be realized.

  In the case of the configuration in which cooling is performed by the cooling units 26-1 to 26-2, it is possible to minimize the influence of the air flow on the ink droplets by driving the cooling units 26-1 to 26-2 at the optimal timing. And contamination in the image recording apparatus 1 can be reduced.

Further, when the temperature of the image recording unit 12 is sufficiently lowered, the power consumption and noise of the image recording apparatus 1 can be reduced by stopping the cooling units 26-1 to 26-2.
Next, another example of the functional configuration of the cooling control unit 19 provided in the image recording apparatus 1 of the present embodiment will be described.

FIG. 7 is a block diagram illustrating an example of a functional configuration of the control unit 16 as another example.
When the configuration of FIG. 7 is compared with the configuration of FIG. 3, the cooling control unit 19 is connected to the cooling unit 26 via the pulse width modulation unit 31.

  The cooling control unit 19 in FIG. 7 reads the setting value for controlling the cooling fan with reference to the cooling control table 30 based on the information of the unit ambient temperature information 27a, the ink temperature information 28a, and the unit drive rate information 20a. Then, the cooling control unit 19 generates a cooling control signal 19 a from this set value and outputs it to the pulse width modulation unit 31.

  The set value for controlling the cooling fan in the present embodiment is a value indicating the rotational speed of the cooling unit 26, and the cooling control signal 19a is a control signal 31a indicating the rotational speed of the cooling unit 26 by, for example, a duty ratio.

  The pulse width modulation unit 31 generates a cooling fan drive signal 31a to be applied to the cooling unit 26 based on the cooling control signal 19a. The cooling fan drive signal 31a is a signal having a voltage value corresponding to the blowing amount (rotational speed) of the cooling unit 26. Note that the pulse width modulation unit 31 may be configured to convert the cooling control signal 19a into a signal having a pulse width corresponding to the air flow rate (rotational speed) of the cooling unit 26, and to perform PWM control of the cooling unit 26.

  The pulse width modulation unit 31 receives the cooling fan control unit output 19 a, generates a cooling fan drive signal 30 a, and outputs it to the cooling unit 26. The cooling fan drive signal 30a is generated by, for example, smoothing the cooling fan control unit signal 19a. The cooling unit 26 changes the rotational speed based on the cooling control signal 19 a and changes the air volume for cooling the recording unit 13.

In the configuration of FIG. 7 as well, a plurality of cooling units 26 may be provided.
In addition, when the cooling unit 26 is configured by a Peltier element, cooling control is performed by changing a current value applied to the Peltier element.

  As described above, the image recording apparatus 1 according to the present embodiment performs the cooling control based on the ambient temperature and ink temperature of the image recording unit 12 or the recording unit 13 and the unit drive rate. Therefore, in the image recording apparatus 1 according to the present embodiment, the cooling unit 26 is efficiently controlled based on the temperature around the image recording unit and the temperature change of the image recording unit due to the unit drive rate and the ink temperature. 12 and the recording unit 13 can be controlled to realize stable ink ejection.

  The ambient temperature and the ink temperature have opposite characteristics, and when either one is measured and controlled, appropriate cooling control cannot be realized. However, in the image recording apparatus 1 of the present embodiment, the ambient temperature and the ink temperature are not controlled. Since both are measured and cooling control based on the measurement result is performed, more accurate temperature control can be realized than the conventional image recording apparatus.

Furthermore, by driving the cooling fan at an optimal timing, it is possible to suppress the influence of airflow on the ink droplets and reduce the contamination in the image recording apparatus.
Further, when the temperature of the image recording unit is sufficiently lowered, the power consumption and the noise can be reduced by stopping the cooling unit 26.

DESCRIPTION OF SYMBOLS 1 Image recording apparatus 2 Feeding part 3 Feeding tray 4 Feeding drive part 5 Recording medium detection part 6 Conveyance mechanism 7 Conveyance drive part 8 Conveyance information generation part 9 Collection | recovery part 10 Storage tray 11 Discharge drive part 12 Image recording part 13- 1 to 13-n recording unit 14-1 to 14-n unit driving unit 14a unit driving signal 15-1-1 to 15-nm nozzle row 16 control unit 17 storage unit 18 image forming unit 18a image forming signal 19 cooling Control unit 19a Cooling control signal 20 Unit drive rate calculation unit 20a Unit drive rate information 21 Recording medium 22 Drive roller 23 Driven roller 24 Belt 25 Support member 26 Cooling unit 27 Unit ambient temperature measurement unit 27a Unit ambient temperature information 28 Ink temperature measurement unit 28a Ink temperature information 29 Host device 29a Job information 30 Cooling control table 31 Pulse width modulation section 31a cooling fan drive signals

Claims (12)

In the image recording apparatus in which the recording unit driving unit formed by a plurality of nozzles drives the plurality of nozzles to eject ink onto a recording medium based on the job information notified from the host apparatus.
A unit ambient temperature measurement unit for measuring the ambient temperature of the recording unit;
An ink temperature measurement unit for measuring the temperature of the ink;
A cooling unit for cooling the recording unit driving unit;
A cooling control unit that controls the cooling unit based on the ambient temperature measured by the unit ambient temperature measurement unit and the ink temperature measured by the ink temperature measurement unit;
An image recording apparatus comprising: A calculation unit, and a control unit including at least a storage unit that stores a control program in advance;
The image recording apparatus according to claim 1, wherein the control unit functions as the cooling control unit by causing the arithmetic processing unit to execute the control program.   The image recording apparatus according to claim 1, wherein the cooling control unit controls the cooling unit in consideration of an analysis result of the job information. A unit drive rate calculation unit for calculating a unit drive rate for driving the recording unit drive unit;
The image recording apparatus according to claim 3, wherein the analysis result of the job information includes the unit drive rate.   The cooling control unit includes an analysis result of the ambient temperature of the recording unit, the ink temperature, and the job information, and a cooling control table that associates a set value indicating a degree of cooling by the cooling unit. The image recording apparatus according to claim 3, wherein the cooling unit is controlled based on the control table.   The image recording apparatus according to claim 1, wherein the cooling unit includes a cooling fan, and the cooling control unit controls an air volume by the cooling fan.   The image recording apparatus according to claim 6, wherein the cooling unit includes a plurality of cooling fans, and the cooling control unit controls the number of cooling fans to be driven among the plurality of cooling fans.   The image recording apparatus according to claim 6, wherein the cooling control unit controls a rotation speed of the cooling fan. The recording by the image recording apparatus that performs recording by driving a plurality of nozzles and ejecting ink onto a recording medium by a driving unit of a recording unit formed by a plurality of nozzles based on job information notified from a host apparatus A method for controlling cooling of a unit, wherein the ambient temperature of the recording unit is measured,
Measuring the temperature of the ink;
The cooling control method, wherein the recording unit driving unit is cooled based on the ambient temperature and the ink temperature.   The cooling control method according to claim 9, wherein the recording unit driving unit is cooled in consideration of an analysis result of the job information in addition to the ambient temperature and the ink temperature.   The cooling control method according to claim 10, wherein the analysis of the job information includes calculating a unit driving rate for driving the recording unit driving unit from the job information.   The recording unit is obtained by referring to a cooling control table in which the ambient temperature, the ink temperature, and the analysis result of the job information are associated with a set value indicating the degree of cooling, and the recording unit is based on the degree of cooling. The cooling control method according to claim 10, wherein the cooling is performed.

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