JP2003039705A - Ink jet recorder - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ink jet recorder in which both high speed and compaction can be satisfied, consumable quantity of ink in an ink tank does not decrease even in case of a recording head having a large number of nozzles, and troubles of print quality or printing due to variation in the manufacture of a recording head can be prevented. SOLUTION: In an ink jet recorder where recording is performed by ejecting droplets of ink from the ejection openings of a recording head onto a recording material, means 40 for monitoring consumption of ink in an ink tank is provided and the recording head is subjected to drive control based on information from the ink consumption monitoring means 40.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ink jet recording apparatus for recording by ejecting recording liquid (hereinafter referred to as ink) as flying droplets from an ink ejection port and adhering it to a recording material. Is.

[0002]

2. Description of the Related Art In recent years, printers are required to record photographic image quality due to the birth and spread of digital cameras and the improvement in performance of personal computers. In order to achieve this photographic quality, high density of 1200 dpi or more,
There is a demand for an inkjet recording apparatus using a dark and light ink system that also uses a light ink of 1/3 to 1/6 density with an extremely small ink droplet of 4 pl or less. The recording head has a discharge port with a diameter of 20 μm or less, which is extremely small. Furthermore,
1p, which is the ejection volume of which the dots cannot be distinguished by the naked eye.
Development of a recording head capable of recording 1 has been started.

Further, it is desired to realize general printing (printing on plain paper) and printing of photographic quality with a faster and more compact printer. In order to increase the speed, it is necessary to increase the driving frequency fop. However, in order to achieve a significant speed increase, it is necessary to increase the number of nozzles. For a compact printer, reduce the size of the ink tank and recording head.

Conventionally, the size of the recording head on which the dark and light ink system is mounted is almost determined by the size of the ink tank.
The recording head unit is considerably smaller than the ink tank.
In the case of 6 colors of BK, Y, M, C, light M, and light C, the color pitch in the scanning direction of the recording head is 1 in the integrated ink tank.
The minimum is about 0 mm and about 12 mm in the independent ink tank. This is largely due to the moldability of the ink tank.

The drive frequency fop is determined from the refill frequency fr of the recording head, but it is not always the same as fop and fr.
Never match. In some cases, there is no problem even if fop is higher than fr. fr changes from the following states.

Nozzle size of the recording head (nozzle height, nozzle width, common liquid chamber distance to the heater, etc.) Temperature (change in ink viscosity, etc.) Number of ejection nozzles (pressure from ink tank to nozzle of recording head due to change in ink flow rate) Loss changes) Ink amount in ink tank (static negative pressure rise in ink tank due to ink consumption) FIG. 5 is a diagram showing ink consumption and negative pressure characteristics.

The ink tank is of a type using a sponge as an ink absorber. In FIG. 5, (1) shows a change in static negative pressure in the ink tank. Ink consumption is a
After passing the point, the static negative pressure in the ink tank rapidly increases,
When a certain negative pressure (about 300 mmH ₂ O, which is slightly different depending on the characteristics of the recording head) is reached, the ink in the recording head drops at point b and the ink tank needs to be replaced. (2) shows the total negative pressure from the ink tank to the print head at the time of full discharge, where total negative pressure = ink flow path resistance (dynamic negative pressure) R + static negative pressure in the ink tank. The ink flow path resistance (dynamic negative pressure) R changes depending on the number of nozzles ejected.

(3) shows the total negative pressure when the number of nozzles is twice that of the recording head of (2). As can be seen from this graph, when only (2) and the number of nozzles were changed, there was a problem that the usable ink amount in the ink tank decreased.

Conventionally, when the number of nozzles is increased (for example, doubled) in order to increase the speed, the ink tank is widened and a filter (SUS mesh, SUS sintering) provided at the joint portion between the ink tank and the recording head is used. ) Was increased to reduce the ink flow path resistance R. Therefore, compactness is sacrificed when speeding up. Further, in the past, since the recording head was driven with the worst value of the manufacturing variations of the recording head, the apparatus had a slow printing speed.

[0010]

The discharge port diameter for realizing photographic image quality is remarkably small of 20 .mu.m or less, and the number of nozzles is large for high speed printing (for example, 256 nozzles / color to 512 nozzles / color to 1024 nozzles). The following problems have been encountered in an inkjet recording apparatus using a bubble jet (registered trademark) type recording head.

1) Both high speed and compact size. 2) Even if the recording head has a large number of nozzles, the usable ink amount in the ink tank does not decrease. 3) The print quality and printing troubles are prevented from occurring due to manufacturing variations of the recording head.

The present invention has been made to solve the above-mentioned problems, and its object is to achieve both high speed and compact size, and even in a recording head with a large number of nozzles, the usable amount of ink in the ink tank. It is an object of the present invention to provide an ink jet recording apparatus capable of preventing the occurrence of print quality and print troubles due to manufacturing variations of recording heads without decreasing.

[0013]

In order to achieve the above object, the present invention is an ink jet recording apparatus for ejecting a small droplet of ink from an ejection port of a recording head and adhering it onto a recording material for recording. In the above, an ink consumption monitor means for monitoring the ink consumption amount in the ink tank is provided, and drive control of the recording head is performed based on the information of the ink consumption monitor means.

[0014]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 is a block diagram showing the configuration of a control system of an ink jet recording apparatus according to the present invention.

For example, image data 10 is sent from a host device such as a computer to the CPU 20 of the ink jet recording apparatus.
Input to the print head drive control means 3
The signal is output to 0. However, the information of the ink refill storage means 32 provided in the electrical mounting portion of the recording head, the output of the ink consumption monitor means 40 for monitoring the ink consumption amount in the ink tank, and the temperature detection means 33 provided near the ejection portion. The CPU 20 calculates the output and the image data 10 to control the carriage motor 51 and the paper feed motor 52, and the recording head control that controls the recording head drive frequency, the preliminary ejection frequency, the recording mode, and the like. A signal is output to the means 30 to drive each.

The recording head drive control means 30 controls the drive frequency of the actual recording head. The first embodiment changes the serial scan speed and the driving frequency of the print head, and the driving frequency is decreased in multiple steps as the ink consumption increases. That is, when the total negative pressure increases due to the progress of ink consumption, the ink refill of the recording head becomes slow. Further, as the temperature of the recording head rises, the bubble length increases in the case of the bubble-through type inkjet recording head, so that the ink refilling becomes slower accordingly. Therefore, such information and ink refill information peculiar to the print head are calculated by the CPU 20, and if it is determined that the ink refill is not in time, the carriage speed is slowed and the drive frequency of the print head is lowered. This is performed in multiple stages depending on the amount of ink consumed.

In the second embodiment, the serial scan speed of the print head is not changed, but the print pass is changed, and the print pass is increased in multiple steps as the ink consumption increases. That is, when the total negative pressure increases due to the progress of ink consumption, the ink refill of the recording head becomes slow. Further, as the temperature of the recording head rises, the bubble length increases in the case of the bubble-through type inkjet recording head, so that the ink refilling becomes slower accordingly. Therefore, the CPU 20 calculates the information and the ink refill information specific to the print head, and when it is determined that the ink refill is not in time, the 1-pass print mode is changed to the 2-pass print mode, and the ink consumption is further reduced. Change to 3 pass mode as you proceed. This is performed in multiple stages depending on the amount of ink consumed.

In the third embodiment, dot skipping printing is performed without changing the speed of the serial scan of the recording head, and dots are complemented with another ink. That is, when the total negative pressure increases due to the progress of ink consumption, the ink refill of the recording head becomes slow. Further, as the temperature of the recording head rises, the bubble length increases in the case of a bubble-through type inkjet recording head, and the ink refilling becomes slower accordingly. Therefore, when such information and ink refill information specific to the print head are calculated by the CPU 20 and it is determined that the ink refill is not in time, for example, as shown in FIG.
Dot complement is performed in the process BK of thinning out, Y, M, and C dot overlapping printing. In FIG. 2, the dots are shown separated for clarity. Actually, in one pass, BK and process BK are driven almost at the same time, so that they are mixed and a uniform BK color is obtained.

FIG. 3 is a perspective view showing the recording head H1000.

In FIG. 3, H1100 is an ejection element for ejecting ink droplets, which is electrically connected to an electric wiring member H1300 such as a flexible circuit board or TAB. H1301 is a contact pad for exchanging electric signals with the main body of the inkjet recording apparatus.
H1302 is an EEPROM, which is mounted on the electric wiring member H1300. H1500 is a holder for connecting and holding the recording head H1000 and an ink tank (not shown).

The EEPROM: H1302 is used as an ink refill storage means. Recording head H100
For example, the ink refill rank is set from the factors that affect the ink refill due to the manufacturing variation that occurs in the manufacturing process of 0. By inputting the set value in the manufacturing process, the print head H1000 is driven with a characteristic value specific to the print head. Incidentally, the ink refill storage means may be constituted by a view ROM formed on the ejection element substrate.

FIG. 4 shows an example of factors relating to ink refill (distance between ejection port center and ink supply port).

FIG. 4A is a plan view of the nozzle H1110 of the recording head H1000 as seen from the ejection direction. The ink is supplied from the ink tank through the ink flow path of the holder H1500 to the ink supply port H11 opened in the ejection element substrate.
The nozzles H1110 are supplied to the nozzles H1110 to heat and foam the heaters and eject the ink from the ink ejection ports H1120. The nozzles H1110 are arranged in a staggered manner with 600 dpi by sandwiching the ink supply ports H1120.
Realizes dpi.

As the discharging mechanism, a BTJ system of a type in which foamed bubbles grow and communicate with the atmosphere is taken as an example. Here, FIG. 4B shows the relationship between the center of the ejection port, the ink supply port distance y, and the ink refill. Ink supply port H1
Due to the manufacturing tolerances of 120, for y = 50 ± 10 μm, the ink refill is slower for larger y distances. Is the total negative pressure of the ink supply system from the ink tank 150 mmH ₂
Ink refill at O is an ink refill at a total negative pressure of 250 mmH ₂ O, and is an ink refill at a total negative pressure of 300 mmH ₂ O.

If the initial driving frequency is 15 kHz,
y When the lower limit of the tolerance is 40 μm, the total negative pressure is 300 mmH
_{Even with 2} O, the ink refill is in time, so
The drive control of the recording head due to the consumption of ink in the ink tank is not necessary until the remaining amount of ink is almost exhausted. On the other hand, when the upper limit of the y tolerance is 60 μm, in the ink tank of FIG. 5, the ink consumption is c (about 80%) in the state (2) (one-pass full discharge), and drive control of the print head is required. . Further, when the upper limit of the y tolerance is 60 μm, in the state of (3) in the ink tank of FIG. Becomes

The ink consumption monitor means 40 comprises a drive pulse measuring section for measuring the number of drive pulses of the recording head and a recovery operation measuring section for measuring the number of recovery operations, and the CPU 20 calculates these pieces of information to consume the ink. Monitor the quantity. Further, the ink consumption monitor means 40 may be an ink amount sensor (optical sensor, electrode sensor, etc.) that actually measures the amount of ink in the ink tank, or may be a combination of a plurality of sensors or a combination of sensors and a measurement calculation method. . The ink consumption monitor means 40 is reset by replacing the ink tank. In the measurement calculation method, an error occurs when the ink tank is removed or attached while the ink tank is being used. As a countermeasure, ID information (RO
M, bar code label, etc.) may be added.

[0028]

As is apparent from the above description, according to the present invention, an ink jet recording apparatus for ejecting a small droplet of ink from an ejection port of a recording head and adhering it to a recording material for recording. In the above, since the ink consumption monitor means for monitoring the ink consumption amount in the ink tank is provided and the drive of the recording head is controlled based on the information of the ink consumption monitor means, it is possible to achieve both high speed and compactness. Even with a large number of recording heads, the amount of ink that can be used in the ink tank does not decrease, and it is possible to obtain the effect that it is possible to prevent the occurrence of print quality and printing troubles due to manufacturing variations of the recording heads.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of a control system of an inkjet recording apparatus according to the present invention.

FIG. 2 is a dot array diagram on a paper showing dot ejection by a recording head of an inkjet recording apparatus according to the present invention.

FIG. 3 is a perspective view of a recording head of the inkjet recording apparatus according to the present invention.

FIG. 4A is a plan view showing a nozzle array of a printhead of an inkjet printing apparatus according to the present invention, and FIG. 4B is a view showing ink refill characteristics of the printhead.

FIG. 5 is a diagram showing an ink consumption amount and a negative pressure characteristic of an ink tank.

[Explanation of symbols]

10 image data 20 CPU 30 recording head drive control means 32 ink fill storage means 40 Ink consumption monitor means 50 body control means H1000 recording head H1100 ejection element H1110 nozzle H1120 outlet H1300 Electric wiring member H1302 EEPROM

Claims (7)

[Claims] 1. An ink consumption monitor for monitoring the ink consumption in an ink tank in an ink jet recording apparatus for ejecting and ejecting small droplets of ink from an ejection port of a recording head and adhering them onto a recording material for recording. An ink jet recording apparatus comprising means for controlling drive of a recording head based on information from the ink consumption monitor means. 2. The drive control of the printhead is characterized in that the drive frequency of a printhead serial scan is changed, and the drive frequency is decreased in multiple steps due to an increase in ink consumption. 1. The inkjet recording device according to 1. 3. The drive control of the recording head is to change the number of recording passes without changing the speed of the serial scan of the recording head, and increase the number of recording passes in multiple stages by increasing the ink consumption amount. Claim 1 characterized by the above-mentioned.
The inkjet recording device described. 4. The drive control of the recording head is performed by changing the driving frequency without changing the serial scan speed of the recording head, and performing dot complementation with the ink of another color. Inkjet recording device. 5. An ink refill memory for storing information on ink refill characteristics of a recording head in an ink jet recording apparatus for ejecting a small amount of ink from an ejection port of a recording head and adhering the ejected ink onto a recording material for recording. Means, and an ink consumption monitor means for monitoring the ink consumption amount in the ink tank,
An inkjet recording apparatus, wherein drive control of a recording head is performed based on information from the ink refill storage unit and the ink consumption monitor unit. 6. The ink jet recording apparatus according to claim 5, wherein the ink refill storage means of the recording head is an EEPROM equipped with the recording head. 7. The ink jet recording apparatus according to claim 5, wherein the ink consumption monitoring unit monitors the ink consumption amount by counting the number of ejected dots and the number of suction recovery.