1. Field of the Invention
The present invention relates to a printing element substrate, a printhead, and a printing apparatus.
2. Description of the Related Art
Japanese Patent Laid-Open No. 2009-29117 describes an inkjet printing apparatus represented by a printer or the like. The inkjet printing apparatus includes a printhead for executing printing on a printing medium. The printhead includes a printing element substrate. The printing element substrate includes a printing unit for executing printing, a processing unit for processing print data, a level shifter for performing the level shift of an active signal from the processing unit, and outputting the signal to the printing unit, and a voltage generation unit for generating a voltage to be used by the level shifter to perform a level shift. The printing unit includes a printing element and a driving transistor for driving the printing element.
A plurality of different power supply voltages are supplied to the printing element substrate. The processing unit uses a power supply voltage for a logic circuit. The printing unit uses a power supply voltage for driving the printing element. Furthermore, the voltage generation unit uses a power supply voltage for generating a voltage to be supplied to the level shifter.
When the order of supply of the plurality of power supply voltages is wrong or the printhead is not appropriately mounted, only some of the plurality of power supply voltages may be supplied. For example, not the power supply voltage for the logic circuit but other power supply voltages may be supplied. In this case, since the potential of the power supply node of the logic circuit is indefinite, this may cause, for example, an operation error of the printing unit. Furthermore, a current (for example, a through current) generated when the potential of the power supply node of the logic circuit is indefinite may increase the power consumption.
Note that Japanese Patent Laid-Open No. 2009-29117 discloses an arrangement in which when no power supply voltage for the logic circuit is supplied to the printing apparatus, the drive transistor for receiving a signal from the level shifter is rendered non-conductive by prohibiting supply of a voltage to the level shifter, thereby preventing an operation error of the printing unit. The arrangement described in Japanese Patent Laid-Open No. 2009-29117, however, does not consider the current of the voltage generation unit for generating a voltage to be supplied to the level shifter.
The present invention provides a technique advantageous in reducing the power consumption while decreasing the probability of an operation error of a printing element substrate when a power supply voltage is not appropriately supplied.
One of the aspects of the present invention provides a printing element substrate, comprising a printing unit including a printing element and a transistor configured to drive the printing element, a logic circuit unit configured to be supplied with a first power supply voltage, and receive print data, a unit configured to be supplied with a second power supply voltage, and output a signal from the logic circuit unit to a control terminal of the transistor, a voltage generation unit configured to be supplied with a third power supply voltage, and generate, using the third power supply voltage, the second power supply voltage to be supplied to the unit, and a controlling unit configured to control supply of the third power supply voltage to the voltage generation unit, wherein when the first power supply voltage is not supplied to the logic circuit unit, the controlling unit does not supply the third power supply voltage to the voltage generation unit.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
(Example of Arrangement of Printing Apparatus)
An example of the arrangement of an inkjet printing apparatus will be described with reference to
In addition to the printhead 3, for example, ink cartridges 6 are mounted on the carriage 2. Each ink cartridge 6 stores ink to be supplied to the printhead 3. The ink cartridge 6 is detachable from the carriage 2. The printing apparatus PA is capable of executing color printing. Therefore, four ink cartridges which contain magenta (M), cyan (C), yellow (Y), and black (K) inks are mounted on the carriage 2. These four ink cartridges are independently detachable.
The printhead 3 includes ink orifices (nozzles) for discharging ink, and also includes a printing element substrate having electrothermal transducers (heaters) corresponding to the nozzles. A pulse voltage corresponding to a print signal is applied to each heater, and heat energy by the heater which has been applied with the pulse voltage generates bubbles in ink, thereby discharging ink from the nozzle corresponding to the heater.
The printing apparatus PA further includes a printhead driver 1705, motor drivers 1706 and 1707, a conveyance motor 1709, and a carrier motor 1710. The printhead driver 1705 drives the printhead 1708. The motor drivers 1706 and 1707 drive the conveyance motor 1709 and carrier motor 1710, respectively. The conveyance motor 1709 conveys a printing medium. The carrier motor 1710 conveys the printhead 1708.
When a print signal is input to the interface 1700, it can be converted into print data of a predetermined format between the gate array 1704 and the MPU 1701. Each mechanism performs a desired operation in accordance with the print data, thus performing the above-described printing.
(First Embodiment)
A printing element substrate I1 according to the first embodiment will be described with reference to
The plurality of printing units PE are divided into, for example, a plurality of groups G (four groups G1 to G4 in this example), and each group G (for example, a kth group Gk) includes a plurality of printing units PEk (four printing units PEk1 to PEk4 in this example). With this arrangement, each printing unit PE executes printing by a so-called time-divisional driving method using a signal 102 for deciding a group G to be selected and a signal 103 for deciding a printing unit PE to be driven in each group G.
Note that an arrangement in which the number of groups is four and each group includes four printing units PE will be exemplified for the sake of simplicity. However, the number of groups G and that of printing units PE are not limited to them. For a general description, the numbers of the groups G, the numbers of the printing units PE of each group G, and the numbers of the heater RH and transistor DMN forming each printing unit PE can be omitted.
The printing element substrate 11 includes a plurality of first units 104 and a second unit 105. Each unit 104 mainly functions as a driving unit for driving the corresponding transistor DMN. For example, the unit 104 has an arrangement shown in
The respective power supply voltages are about, for example, VDD=3 to 5 [V], VH=24 to 32 [V], VHT=24 to 32 [V], and VHTM=12 [V]. The power supply voltages VH and VHT may be equal or different. If the power supply voltages VH and VHT are made equal to each other, it is possible to use the same power supply node or power supply line (electrically connect a power supply node NVH of the power supply voltage VH and a power supply node NVHT of the power supply voltage VHT). Since, however, the power supply node NVH supplies a heater current flowing to the heater RH, potential fluctuations may occur at the power supply node NVH. Therefore, the power supply nodes NVHT and NVH are not electrically connected here (that is, these power supply wirings are separately arranged).
The circuit unit LS can be formed using NMOS transistors MN1 and MN2 and PMOS transistors MP1 to MP4. The transistors MN1, MP1, and MP4 are arranged to form a current path between a ground node and a power supply node NVHTM to which the power supply voltage VHTM is supplied. The transistors MN2, MP2, and MP3 are arranged to form a current path between the power supply node NVHTM and the ground node.
The gates of the transistors MN1 and MP1 are connected to the output of the inverter INV1. The node between the transistors MN1 and MP1 is connected to the gate of the transistor MP3. The gates of the transistors MN2 and MP2 are connected to the output of the inverter INV2. The node between the transistors MN2 and MP2 is connected to the gate of the transistor MP4 and the input of the buffer BUF.
The inputs IN1 and IN2 of the unit 104 receive the signals 102 and 103. An output OUT of the unit 104, therefore, outputs a signal at the signal level VHTM when both the signals 102 and 103 are activated. The output OUT of the unit 104 is connected to the gate terminal of the transistor DMN. Note that the arrangement of the level shift unit 106 is not limited to the above-described one, and the level shift unit 106 may adopt another arrangement. Furthermore, if no level shift is performed, the circuit unit LS of the unit 104 may be omitted.
The unit 105 also includes a monitor unit 112 for monitoring the potential of a power supply node NVDD of the power supply voltage VDD. The monitor unit 112 is arranged between the power supply node NVHT and the ground node. The monitor unit 112 outputs a monitor result to the switch unit 110.
The switch unit 110 can function as a controlling unit for controlling supply of the power supply voltage VHT to the voltage generation unit 150 based on the monitor result of the power supply node NVDD by the monitor unit 112. More specifically, the monitor unit monitors the power supply node NVDD. When the power supply voltage VDD is appropriately supplied to the processing unit 101 (more specifically, the printing element substrate 11 itself), the switch unit 110 is rendered conductive. When the switch unit 110 is rendered conductive, the power supply voltage VHT is supplied to the voltage generation unit 150, and the output of the voltage generation unit 150 becomes about 12 [V]. As a result, the potential of the power supply node NVHTM of the power supply voltage VHTM to be supplied to each unit 104 becomes about 12 [V], and each unit 104 enters an operation state.
On the other hand, when the power supply voltage VDD is not appropriately supplied to the processing unit 101, for example, the potential of the power supply node NVDD is in a floating state, a voltage supplied for the power supply node NVDD is lower than the power supply voltage VDD, or the like, the monitor unit renders the switch unit 110 non-conductive. When the switch unit 110 is rendered non-conductive, no power supply voltage VHT is supplied to the voltage generation unit 150 and the output of the voltage generation unit 150 becomes 0 [V]. In other case, when the switch unit 110 is rendered non-conductive, a current path from a node supplied with the power supply voltage VHT to the ground node is cut off. As a result, the potential of the power supply node NVHTM of the power supply voltage VHTM to be supplied to each unit 104 becomes 0 [V], and each unit 104 enters a sleep state. When the unit 104 is in the sleep state, the output OUT of the unit 104 becomes 0 [V], and thus the transistor DMN is rendered non-conductive.
As exemplified in
In an arrangement shown in
The arrangement of the output circuit 111 is not limited to the above-described arrangements shown in
In the arrangement shown in
On the other hand, when the power supply voltage VDD is not appropriately supplied to the processing unit 101, the transistor MN3 is rendered non-conductive, and the potential of the node between the resistance elements R1 and R2 becomes equal to the potential of the power supply node NVHT. As a result, the transistor MP5 is rendered non-conductive, and no power supply voltage VHT is supplied to the voltage generation unit 150. As described above, the output of the voltage generation unit 150 becomes 0 [V], and each unit 104 enters a sleep state.
Note that whether the power supply voltage VDD is appropriately supplied to the processing unit 101 can be determined by comparing the potential of the power supply node NVDD with a predetermined reference value. With the above arrangement, for example, if the potential of the power supply node NVDD is higher than the threshold voltage of the transistor MN3, it can be determined that the power supply voltage VDD is appropriately supplied to the processing unit 101. If the potential of the power supply node NVDD is lower than the threshold voltage of the transistor MN3, it can be determined that the power supply voltage VDD is not appropriately supplied to the processing unit 101. If no power supply voltage VDD is supplied, the potential of the power supply node NVDD enters a floating state. In this case, although the potential of the power supply node NVDD can become equal to the potential of the ground node via the substrate, the power supply node NVDD may be pulled down and fixed using, for example, a resistance element having a large resistance value in order to avoid the indefinite state of the potential of the power supply node NVDD.
As exemplified in
In the arrangement shown in
On the other hand, when the power supply voltage VDD is not appropriately supplied to the processing unit 101, the transistor MN5 is rendered non-conductive, and the potential of the node between the resistance elements R3 and R4 becomes equal to the potential of the power supply node NVHT. With this operation, the transistor MP6 is rendered non-conductive, and the potential of the node between the transistor MP6 and the resistance element R5 becomes equal to the potential of the ground node. As a result, the transistor MN4 is rendered non-conductive, and no power supply voltage VHT is supplied to the voltage generation unit 150.
As exemplified in
Note that although the arrangement in which the transistor MN6 is added has been exemplified, the present invention is not limited to this, and two or more transistors may be added. Furthermore, in the arrangement shown in
In the unit 105 with the above arrangement, the monitor unit 112 monitors the potential of the power supply node NVDD, the switch unit 110 supplies the power supply voltage VHT to the voltage generation unit 150 based on the monitor result, and the voltage generation unit 150 generates the power supply voltage VHTM using the supplied power supply voltage VHT. That is, the unit 105 has two operation modes. When the power supply voltage VDD is appropriately supplied to the processing unit 101 (more specifically, the printing element substrate 11 itself), the unit 105 operates in the first mode in which the power supply voltage VHTM is supplied to each unit 104. Alternatively, when the power supply voltage VDD is not appropriately supplied to the processing unit 101, the unit 105 operates in the second mode in which no power supply voltage VHT is supplied to the voltage generation unit 150. Furthermore, when the power supply voltage VDD is not appropriately supplied to the processing unit 101 (in the second mode), the switch unit 110 is rendered non-conductive, and no power supply voltage VHT is supplied to the voltage generation unit 150. Consequently, the voltage generation unit 150 supplies no power supply voltage VHTM to each unit 104, and each unit 104 enters a sleep state, thereby preventing an operation error of the unit 104 or printing unit PE. At this time, since the switch unit 110 is non-conductive, and the transistor of the monitor unit 112, which receives the power supply voltage VDD, is also non-conductive, the current path between the power supply node NVHT and the ground node is cut off. Therefore, this embodiment is advantageous in preventing an operation error of the unit 104 or printing unit PE, and reducing the power consumption.
Note that the power supply voltage VH or VHT as a high voltage (24 to 32 [V]) is used to appropriately operate each of the aforementioned units, as described above. DMOS transistors as high-breakdown voltage transistors, therefore, can be used as the respective transistors of the unit 105 and the transistor DMN (to be described later).
(Second Embodiment)
A printing element substrate 12 according to the second embodiment will be described with reference to
The printing unit PE′ includes a heater RH, an NMOS transistor DMN for controlling the driving of the heater RH, and a PMOS transistor DMP whose gate is connected to a power supply node NVHTML of a power supply voltage VHTML. While the transistor DMN is conductive and drives the heater RH, the source potential of the transistor DMN complies with the gate potential by a source follower operation, and the potential of one terminal of the heater RH changes to the source potential. With respect to the transistor DMP, the power supply voltage VHTML is a constant voltage, the source potential of the transistor DMP complies with the gate potential by a source follower operation, and the potential of the other terminal of the heater RH changes to the source potential. In the printing unit PE′, the transistors DMN and DMP are configured so that a constant current is supplied to the heater RH even if potential fluctuations occur at a power supply node NVH and a ground node.
The unit 105′ monitors the potential of the power supply node NVH of a power supply voltage VH in addition to the potential of a power supply node NVDD of a power supply voltage VDD. A power supply voltage VHTMH corresponds to the power supply voltage VHTM in the first embodiment, and is generated by the unit 105′ and supplied to units 104. When the power supply voltage VDD and a power supply voltage VH are appropriately supplied to the printing element substrate 12, the unit 105′ supplies the power supply voltage VHTMH (=about 12 [V]) to each unit 104. When at least one of the power supply voltages VDD and VH is not appropriately supplied, the unit 105′ supplies no power supply voltage VHT to a voltage generation unit 150 (the unit 105′ outputs 0 [V]).
With the above arrangement, when the power supply voltages VDD and VH are appropriately supplied to the printing element substrate 12, a transistor MP5 of a switch unit 110 is rendered conductive, and the output of the unit 105′ becomes about 12 [V]. On the other hand, when at least one of the power supply voltages VDD and VH is not appropriately supplied to the printing element substrate 12, the transistor MP5 of the switch unit 110 is rendered non-conductive, and the output of the unit 105′ becomes 0 [V]. Note that in this case, no power supply voltage VHTMH is supplied to each unit 104. Each unit 104 enters a sleep state (an output OUT of each unit 104 becomes 0 [V]), and thus the transistor DMN is rendered non-conductive, as described above.
That is, according to this embodiment, the unit 105′ monitors the potential of the power supply node NVH of the power supply voltage VH in addition to the potential of the power supply node NVDD of the power supply voltage VDD. When the power supply voltages VDD and VH are appropriately supplied to the printing element substrate 12, the unit 105′ operates in the first mode in which the power supply voltage VHTMH (=about 12 [V]) is supplied to each unit 104. On the other hand, when at least one of the power supply voltages VDD and VH is not appropriately supplied, the unit 105′ operates in the second mode in which no power supply voltage VHT is supplied to the voltage generation unit 150. Alternatively, when neither of the power supply voltages VDD and VH is appropriately supplied to the printing element substrate 12, the switch unit 110 is rendered non-conductive, and no power supply voltage VHT is supplied to the voltage generation unit 150. In this embodiment, therefore, it is also possible to obtain the same effects as those in the first embodiment.
Note that the power supply voltage VH or VHT as a high voltage (24 to 32 [V]) is used to appropriately operate each of the aforementioned units, as described above. DMOS transistors as high-breakdown voltage transistors, therefore, can be used as the respective transistors of the unit 105′ and the transistor DMN.
(High-Breakdown Voltage Transistor)
In
The arrangement shown in
In
Although the two embodiments have been described above, the present invention is not limited to them. The embodiments can be appropriately changed or combined in accordance with the purpose, state, application, function, and other specifications, and the present invention can also be implemented by another embodiment. For example, an arrangement using a heater (electrothermal transducer) as a printing element has been exemplified in each of the above-described embodiments, but a printing method using a piezoelectric element or another known printing method may be adopted. Furthermore, for example, each parameter (a voltage value or the like) can be changed in accordance with the specification and application, and each unit can be accordingly changed so as to appropriately operate.
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. 2013-156031, filed Jul. 26, 2013, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2013-156031 | Jul 2013 | JP | national |
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Entry |
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Chinese Office Action issued in corresponding application No. 201410353850.X dated Aug. 26, 2015- 13 pages with English translation. |
Number | Date | Country | |
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20150029245 A1 | Jan 2015 | US |