1. Technical Field
Aspects of the present invention relate to a liquid discharge head for discharging liquid.
2. Description of the Related Art
Voltage is applied to a recording element (a heater) provided on a liquid discharge head to cause the heater to generate heat, causing a discharge port (a nozzle) to discharge liquid. The voltage applied to the recording element (the heater) is supplied by a power source provided on a recording apparatus, to which the liquid discharge head is attached. Such control for discharging liquid from the discharge port has been performed to this date. Japanese Patent Application Laid-Open No. 2002-292875 discusses that a recording element substrate (an element substrate) is provided with a power source regulator for feedback to keep the voltage applied to the heater constant. Japanese Patent Application Laid-Open No. 07-68761 discusses that the timing of a heat signal for driving a heater is shifted within the range of a period 1107 as illustrated in a signal 1101 in
In the recording apparatus, a distance between the surface of the element substrate 807 and a recording medium 808 is short. Furthermore, an ink flow path is formed on the back of the element substrate 807. This makes it difficult to arrange a component for reducing the parasitic impedance 902 (for example, a bypass capacitor) near the element substrate 807. For this reason, the parasitic impedance 902 cannot be removed.
Even if the configuration discussed in Japanese Patent Application Laid-Open No. 2002-292875 is adopted, the dullness of rising and falling waveforms caused by the parasitic impedance 902 outside the element substrate 807 cannot be inhibited.
Even if the configuration discussed in Japanese Patent Application Laid-Open No. 07-68761 is adopted, and if attention is focused on current flowing to one heater, periods during which much current such as current 1105 and 1106 illustrated in
According to an aspect of the present invention, a liquid discharge head includes a first unit configured to supply power, and a second unit including an input unit to which the power is input, a plurality of heaters connected to the input unit via a common power source line and configured to operate to discharge liquid, an energization unit configured to energize the plurality of heaters, and a selection unit configured to select the heaters so that a heater targeted for use for discharging liquid is energized in turn by the energization unit for a period corresponding to a time interval at which liquid is discharged, wherein the selection unit selects the heaters to energize heaters non-targeted for use for discharging liquid, different from the heater targeted for use for discharging liquid, before and after the heater targeted for use for discharging liquid is energized.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
A block selection signal 204 is a signal for selecting a heater to be energized in one group (a heater targeted for energization). The outputs of the ring shift register 209 and the latch 208 are connected to the input of the AND circuit 203. Image data are input from a DATA terminal 213 and a clock signal is input from a clock (CLK) terminal 214. The image data are input in synchronization with the clock signal. The image data input to the shift resistor 207 at the timing when the latch signal (a pulse signal) outputs are stored in the latch 208. The block selection signal 204, a group selection signal 205, a heat signal (HE), and a switching signal (BLE_SHIFT) are transferred from a control unit 813 illustrated in
The AND circuit 203 receives the block selection signal 204, the group selection signal 205, and the heat signal, and outputs the results of logical product (AND processing) to the driver 202 corresponding to the AND circuit 203. The driver 202 energizes the heater while the signal output by the AND circuit 203 is in a high level state.
The block selection signal 204 is data for bringing one of the block selection signals BLE0 to BLE3 into a signal in a high level state. The block selection signal 204 is repeated with a period of four blocks (BLK0, BLK1, BLK2, and BLK3). Driving the heater enables all of the heaters 201 to be selected.
The input of a pulse BLK0 of a latch signal (LT) starts a block period 301. In the block period 301, when a switching signal (BLE_SHIFT) is input, the ring shift register 209 switches the block selection signal 204 in a high level state. For example, the ring shift register 209 switches the block selection signal 204 in the order of BLE0, BLE1, and BLE2. The width of a high-level period of the BLE1 is determined as a time width for which ink can be discharged (a time width corresponding to the heat quantity by which ink can be discharged). The width of a high-level period of the BLE0 and the width of a high-level period of the BLE2 are determined as a time width for which ink cannot be discharged (a time width corresponding to the heat quantity by which ink cannot be discharged). The period between the two rising edges of the switching signal is a driving period for the heater of the nozzle targeted for discharging ink.
Performing the above-described operation causes first a heater current IH0 to flow into the heater 2010, secondly a heater current IH1 to flow into the heater 2011, and thirdly a heater current IH2 to flow into the heater 2012 in the block period 301. The heater 2011 energized by the heater current IH1 generates heat to discharge ink. In the block period 301, the heater 2011 is a heater targeted for use for discharging ink. The heater 2010 energized by the heater current IH0 generates heat, but no bubble is formed in the liquid. The ink is not discharged by this heat generation. The heater 2012 energized by the heater current IH2 generates heat, but no bubble is formed in the liquid. The ink is not discharged by this heat generation. In the block period 301, the heaters 2010 and 2012 are heaters non-targeted for use for discharging ink.
The block period 302 is described below. The input of a pulse BLK1 of the latch signal (LT) starts the block period 302. In the block period 302, the ring shift register 209 switches the high-level period of the block selection signal 204 in the order of BLE3, BLE0, and BLE1. In this period, the heater currents IH3, IH0, and IH1 flow in turn to each heater, and the heater 2010 energized by the heater current IH0 generates heat to discharge ink. In the block period 302, the heater 2010 is a heater targeted for use for discharging ink. The heater 2013 energized by the heater current IH3 generates heat, but no bubble is formed in the liquid. The ink is not discharged by this heat generation. The heater 2011 energized by the heater current IH1 generates heat, but no bubble is formed in the liquid. The ink is not discharged by this heat generation. In the block period 302, the heaters 2011 and 2013 are heaters non-targeted for use for discharging ink.
Similarly, in the block periods 303 and 304, the ring shift register 209 performs the similar operation. In the block period 301, the above-described operation causes the heater 2011 to discharge ink. In the block period 302, the heater 2010 operates to discharge ink. In the block period 303, the heater 2013 operates to discharge ink. In the block period 304, the heater 2012 operates to discharge ink.
In the above description, attention is focused on one group (Gr.0). Other groups (Gr.1 and Gr.2) in one block period are subjected to similar control to drive a heater targeted for use for discharging ink in each group. In the block period 301, the heaters 2011, 2015, 2019, . . . , and 2039, for example, are driven. In
In the operation timing illustrated in
Supplementarily, the rising and falling waveforms of an actual rectangular signal (a rectangular wave) are slightly dulled. This is caused by the influence of the driving capacity (a through rate) of a transistor if the switch 202 is a transistor, and the influence of a parasitic capacitance in the element substrate 807 in a moment when a heater current is switched in the element substrate 807. The parasitic capacitance in the element substrate 807 is in the order of several pico-farads (pF) to several tens of pico-farads (pF) and is smaller by about two digits than the parasitic capacitance outside the element substrate 807. For this reason, the influence of the parasitic capacitance in the element substrate 807 is smaller than that of the parasitic capacitance outside the element substrate 807.
If the heat quantity is increased by the heater non-targeted for use for discharging ink, current flowing to heaters other than heaters targeted for use for discharging ink may be divided and allocated to a plurality of heaters (a pulse is made short and allocated). The switching of the block selection signal 305 in each block period is determined so that current flowing into the element substrate 807 is kept constant before and after of energization timing of the heater targeted for use for discharging ink in each block period.
The configuration of the first exemplary embodiment may be applied to that of Japanese Patent Application Laid-Open No. 2002-292875 that the power source regulator is further provided or may be applied to control for shifting a driving timing discussed in Japanese Patent Application Laid-Open No. 07-68761.
A second exemplary embodiment is described below.
The element substrate 807 is provided with a sub-heater 501, a sub-heater driver 502, a counter 505, and a NOR circuit 509 as well as a heater 201 and a switch 202. The sub-heater 501 is a dedicated heater for heating the element substrate 807. The heater 201 is a heater used for discharging ink. The sub-heater driver 502 energizes (drives) the sub-heater 501. The sub-heater driver 502 drives the sub-heater 501 while a sub-heater drive signal (SHD) is in a high-level state. Voltage for energizing the sub-heater 501 is input from a VH terminal from which voltage for energizing the heater 201 is input.
The NOR circuit 509 is a logic operation unit for performing NOT-OR operation. The NOR circuit 509 receives the inversion signal of a sub-heat signal and the heat signal to generate the sub-heater drive signal (SHD). The NOR circuit 509 drives only any one of the heater 201 and the sub-heater 501, but does not drive the heater 201 and the sub-heater 501 at the same time.
The sub-heater driver 502 is provided with a current adjustment function. A current value is determined based on the output of an adjustment signal (ISH_C) output by the counter 505. The counter 505 receives the group election signals D0 to D7 to count the number of heaters driven at the same time for each block period. The counter 505 controls the sub-heater driver 502 to flow the current equal to the sum of heater currents in each block period. In the second exemplary embodiment, the values of the block and group selection signals are fixed in the block period. The group selection signal is updated according to image data for each block.
The time width of the sub-heat signal (SHE) in a high-level state is longer than the time width of the heat signal (HE) in a high-level state. The heat signal is input from an HE terminal 506 and the sub-heat signal is input from an SHE terminal 508 to include a high-level period of the heat signal.
A control operation for energizing the heater is described below. The latch 208 brings BLE0 to a high level in the block period 301. The latch 208 brings BLE1 to a high level in the block period 302. The latch 208 brings BLE2 to a high level in the block period 303. The latch 208 brings BLE3 to a high level in the block period 304. As described above, the AND circuit 203 outputs a signal to a corresponding driver 202 by inputting the block selection signal to each AND circuit 203. This flows the heater current IH0 to the heater 2010 in the block period 301. The heater current IH1 flows to the heater 2011 in the block period 302. The heater current IH2 flows to the heater 2012 in the block period 303. The heater current IH3 flows to the heater 2013 in the block period 304.
The above description is made with attention focused on one group (Gr.0), but the similar control is performed on other groups (Gr.1 and Gr.2) in one block period to drive the heater targeted for use for discharging ink from each group. In
The element substrate 807 is configured such that the sub heater 501 and the heater 201 are supplied with power from the same VH terminal. The current IH_SUM input to the element substrate 807 is switched (shifted) between the sub heater current (ISH) and the heater current 606 to allow suppressing the dullness of the rising and falling waveforms of the heater current 606. Although dull current is applied to the sub heater, the sub heater aims to heat the element substrate, so that influence is small.
An ink-discharge time period and the width of the rising and the falling time of the sub-heater current are previously measured. Alternatively, the values of power applied to the heater in the width of the rising and the falling time are previously obtained. The timing of operation illustrated in
A third exemplary embodiment is described below.
The dummy current drive substrate 701 is provided with circuits equivalent to the sub-heater driver 502 and the counter 505 described in the second exemplary embodiment. Adjustment is made to flow current equal in value to the current flowing to the element substrate 807. A dummy heat signal (DHE) similar to the sub-heat signal (SHE) illustrated in
Although the above exemplary embodiments are described using a serial-type inkjet recording apparatus as an example, the exemplary embodiments can be applied to a full-line-type inkjet recording apparatus provided with a line-type liquid discharge head.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2012-191429 filed Aug. 31, 2012, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2012-191429 | Aug 2012 | JP | national |
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Number | Date | Country |
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7-68761 | Mar 1995 | JP |
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Number | Date | Country | |
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20140063128 A1 | Mar 2014 | US |