JP6862736B2 - Power selection circuits, circuits, head modules, and printing equipment - Google Patents

Description

The present invention relates to a power supply selection circuit, a circuit, a head module, and a printing device that selects one of a plurality of power supplies connected to a driving element that discharges a liquid.

Conventionally, a recording element control circuit has been proposed that stores voltage information for each of a plurality of recording element groups and selects one of the recording element groups from the plurality of recording element groups. The recording element control circuit refers to the voltage information about the selected recording element group, generates an appropriate voltage corresponding to the printing characteristics of the recording element group based on the voltage information, and supplies the voltage to the recording element group (patented). Reference 1).

Further, an inkjet head having a driving element for discharging a liquid has been conventionally proposed. If a plurality of power supplies having different voltages and a plurality of switching elements connected to each power supply are provided in the inkjet head, the plurality of switching elements are connected to the driving element and one of the switching elements is selected. Thereby, any power source having an appropriate voltage corresponding to the discharge characteristic of the drive element can be connected to the drive element.

Special Publication No. 64-7591

However, when noise, for example, noise in which the voltage rises momentarily or noise in which the voltage drops momentarily, is added to the signal for selecting the switching element, a plurality of switching elements may be driven. When a plurality of switching elements are driven, the electric charge accumulated in the driving elements may move toward the power supply, that is, the current may flow back. If the current flows backward, the switching element may be destroyed.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a power supply selection circuit, a circuit, a head module, and a printing apparatus capable of suppressing driving of a plurality of switching elements.

The power supply selection circuit according to the present invention includes a plurality of first switching elements connected to a driving element that applies energy to the liquid and discharges the liquid, and each connected to a plurality of power supplies having different voltages, and a single power supply selection circuit. A selection signal for selecting the power supply is input, and the selection circuit includes a selection circuit for selecting one of the plurality of power supplies corresponding to the input selection signal. The driving element and the selected power supply are made conductive via the first switching element.

The circuit according to the present invention includes a plurality of power supplies connected to a driving element that applies energy to the liquid and discharges the liquid, and a plurality of first switching elements connected to the plurality of power supplies. A control circuit that controls the drive of the first switching element and a selection signal for selecting a single power supply from the control circuit are input, and the input selection signal among the plurality of power supplies is input. The selection circuit includes a selection circuit for selecting any one of the power supplies corresponding to the above, and the selection circuit makes the drive element and the selected power supply conductive via the first switching element.

The head module according to the present invention includes a drive element that applies energy to a liquid to discharge the liquid, a plurality of power supplies that are connected to the drive element and have different voltages, and a plurality of power supplies that are connected to the plurality of power supplies. A first switching element, a control circuit for controlling the drive of the first switching element, and a selection signal for selecting a single power supply from the control circuit are input, and among the plurality of power supplies, A selection circuit for selecting any one of the power sources corresponding to the input selection signal is provided, and the selection circuit conducts the drive element and the selected power source via the first switching element.

The printing apparatus according to the present invention includes a driving element that applies energy to a liquid to discharge the liquid, a plurality of power supplies that are connected to the driving element and have different voltages, and a plurality of power supplies that are connected to the plurality of power supplies. A first switching element, a control circuit for controlling the drive of the first switching element, and a selection signal for selecting a single power supply from the control circuit are input, and among the plurality of power supplies, A selection circuit for selecting any one of the power sources corresponding to the input selection signal is provided, and the selection circuit conducts the drive element and the selected power source via the first switching element.

In the power supply selection circuit, circuit, head module, and printing apparatus according to the present invention, a selection signal for selecting a single power supply is input to the selection circuit. Even if noise is added to the selection signal, the selection signal is still unique information for selecting a single power supply and does not indicate a plurality of power supplies. Further, the selection circuit selects any one power supply corresponding to the input selection signal, and drives a single first switching element connected to the selected single power supply. Therefore, it is possible to suppress driving of a plurality of first switching elements.

It is a top view which shows schematic the printing apparatus 1 which concerns on Embodiment 1. FIG. It is a schematic cross-sectional view which made the line II-II shown in FIG. 1 a cutting line. It is a bottom view of the inkjet head 4. It is a block diagram which shows the connection of the control device 7 and the head unit 11. It is a block diagram which shows the structure of the 2nd control board 72 near the power supply circuit 121-127. It is a circuit diagram which shows the power source selection circuit 20. It is a graph which shows the relationship between the nozzle address which identifies each nozzle 11a, and the liquid suitable (ink) speed which is ejected from each nozzle 11a corresponding to the nozzle address when a constant voltage is applied to the piezoelectric bodies 11b1 and 11b2. .. It is a conceptual diagram which shows an example of the 1st table which shows the correspondence relation of a nozzle address, a rank and a drive voltage. It is a conceptual diagram which shows an example of the table stored in the selection circuit 21. It is a circuit diagram which shows the power source selection circuit 20A which concerns on Embodiment 2. FIG. It is a circuit diagram which shows the power source selection circuit 20B which concerns on Embodiment 3. It is a circuit diagram which shows the power source selection circuit 20C which concerns on Embodiment 4. FIG.

(Embodiment 1)
Hereinafter, the printing apparatus according to the first embodiment will be described with reference to the drawings.

In FIG. 1, the downstream side in the transport direction of the recording paper 100 is defined as the front side of the printing device 1, and the upstream side in the transport direction is defined as the rear side of the printing device 1. Further, the paper width direction parallel to the surface on which the recording paper 100 is conveyed (the surface parallel to the paper surface in FIG. 1) and orthogonal to the conveying direction is defined as the left-right direction of the printing apparatus 1. The left side of FIG. 1 is the left side of the printing device 1, and the right side of FIG. 1 is the right side of the printing device 1. Further, the direction orthogonal to the transport surface of the recording paper 100 (the direction orthogonal to the paper surface of FIG. 1) is defined as the vertical direction of the printing apparatus 1. In FIG. 1, the front side is the upper side and the back side is the lower side. In the following, the front, back, left, right, top and bottom will be described as appropriate.

As shown in FIG. 1, the printing device 1 includes a housing 2, a platen 3, four inkjet heads 4, two transfer rollers 5, and 6, and a control device 7.

The platen 3 is placed flat in the housing 2. Recording paper 100 is provided on the upper surface of the platen 3. The four inkjet heads 4 are arranged side by side in the front-rear direction above the platen 3. The two transfer rollers 5 and 6 are arranged on the rear side and the front side of the platen 3, respectively. The two transfer rollers 5 and 6 are each driven by a motor (not shown) to transfer the recording paper 100 on the platen 3 forward.

The control device 7 includes a plurality of FPGAs (Field Programmable Gate Arrays), ROMs (Read Only Memory), RAMs (Random Access Memory), and non-volatile memories (for example, EEPROM (Electrically Erasable Programmable Read-Only Memory)). The FPGA, ROM, RAM, and non-volatile memory are not shown. Further, the control device 7 is connected to an external device 9 such as a PC so as to be capable of data communication, and controls each part of the printing device 1 based on the print data transmitted from the external device 9.

For example, the control device 7 controls the motor that drives the transport rollers 5 and 6 to transport the recording paper 100 to the transport rollers 5 and 6 in the transport direction, and controls the inkjet head 4 toward the recording paper 100. A liquid (ink in this embodiment) is ejected. As a result, the image is printed on the recording paper 100.

A plurality of head holding portions 8 are attached to the housing 2. The plurality of head holding portions 8 are arranged side by side in the front-rear direction above the platen 3 and at a position between the two transport rollers 5 and 6. Each of the inkjet heads 4 is held by the head holding portion 8.

The four inkjet heads 4 eject four colors of ink, cyan (C), magenta (M), yellow (Y), and black (K), respectively. Ink of the corresponding color is supplied to each inkjet head 4 from an ink tank (not shown).

As shown in FIGS. 2 and 3, each inkjet head 4 includes a rectangular plate-shaped holder 10 that is long in the paper width direction, and a plurality of head units 11 attached to the holder 10. The plurality of head units 11 are arranged side by side in the left-right direction, and are arranged in two rows in the front-rear direction.

A plurality of nozzles 11a for ejecting ink are formed on the lower surface of each head unit 11. The head unit 11 includes a driving element 11b, and the driving element 11b has two piezoelectric bodies 11b1 and 11b2 (see FIG. 6). A plurality of nozzles 11a of each head unit 11 are arranged side by side along the left-right direction.

The piezoelectric bodies 11b1 and 11b2 form a part of the wall of a storage chamber (not shown) for storing ink, and a nozzle 11a is provided on the bottom surface of the storage chamber. The liquid is discharged from the nozzle 11a by driving the piezoelectric bodies 11b1 and 11b2. The head unit 11 and the control device 7 are connected via a flexible substrate (not shown).

As shown in FIGS. 1 and 2, a plurality of reservoirs 12 are provided above each of the plurality of head units 11. Note that in FIG. 3, the reservoir 12 is not shown.

The reservoir 12 is connected to an ink tank (not shown) via a tube 16, and ink supplied from the ink tank is temporarily stored. The lower portion of the reservoir 12 is connected to a plurality of head units 11, and ink is supplied from the reservoir 12 to each head unit 11. The head unit 11 may be configured as a serial head and moved in the paper width direction.

As shown in FIG. 4, the control device 7 includes a first control board 71 and a plurality of second control boards 72. The FPGA 71a is provided on the first control board 71. One FPGA 72a is provided on one second control board 72. The FPGA 71a is connected to each of the plurality of FPGAs 72a and controls the driving of the plurality of FPGAs 72a. The plurality of second control boards 72, that is, the plurality of FPGAs 72a correspond to the plurality of head units 11, respectively, and the number of FPGAs 72a is the same as that of the head units 11. The plurality of FPGA 72a and the plurality of head units 11 are connected to each other. The FPGA 71a and the FPGA 72a are connected to a ROM (not shown) that stores bitstream information and a RAM (not shown) as a memory. The second control board 72 and the head unit 11 constitute the head module 110.

The head unit 11 includes a substrate 11c, on which a detachable connector 11d, a non-volatile memory 11e, and a driver IC 11f are mounted. The head unit 11 is removably connected to the second control board 72 via the connector 11d. The driver IC 11f includes a switching circuit 27 described later.

As shown in FIG. 5, the second control board 72 is provided with a D / A (Digital / Analog) converter 120. Further, the second control board 72 is provided with a plurality of power supply circuits, for example, first power supply circuits 121 to 7th power supply circuits 127. The power supply circuit corresponds to the power supply. The first power supply circuit 121 to the seventh power supply circuit 127 has FETs, resistors, and the like, and can change the output voltage. As these first power supply circuits 121 to 7th power supply circuits 127, for example, a switching type DC / DC converter may be used. The FPGA 72a outputs a signal for setting the output voltage to the first power supply circuit 121 to the seventh power supply circuit 127 via the D / A converter 120.

The first power supply circuit 121 to the seventh power supply circuit 127 are connected to the drive element 11b via the switching circuit 27. The switching circuit 27 connects each of the plurality of drive elements 11b to any of the first power supply circuits 121 to the seventh power supply circuit 127. The first power supply circuit 121 to the fifth power supply circuit 125 are normal power supply circuits that are normally used. The sixth power supply circuit 126 may be a normal power supply circuit or a standby power supply circuit, and the seventh power supply circuit 127 is a specially designed power supply circuit. The seventh power supply circuit 127 is used, for example, for the highest drive voltage rank, is used in combination as the VCOM power supply voltage of the drive element, or is used for the drive element 11b which is difficult to eject ink. Alternatively, it is used as H VDD (high side back gate voltage) of the epitaxial transistor 31.

The H VDD terminal is a first power supply circuit 121 to 1st so that no current flows through the parasitic diode of the epitaxial transistor on the high side even when a voltage higher than that of the source terminal 31a of the epitaxial transistor 31 is applied to the drain terminal 31b. 6 It is connected to the 7th power supply circuit 127 having an output voltage higher than that of the power supply circuit 126.

As shown in FIG. 6, the control device 7 includes a power supply selection circuit 20 that selects any one of the power supply circuits 121 to 127 from a plurality of power supply circuits 121 to 127 and drives the drive element 11b with the voltage of the selected power supply circuit.

The printing device 1 includes a plurality of power supply selection circuits 20, and the plurality of power supply selection circuits 20 correspond to a plurality of drive elements 11b, respectively. Each of the plurality of drive elements 11b has a discharge characteristic. The voltages of the plurality of power supplies are set to different voltages according to the discharge characteristics of each drive element 11b in order to equalize the amount of liquid discharged by each drive of the plurality of drive elements 11b.

The rank of the nozzle 11a will be described. It should be noted that each of the nozzles 11a and each of the drive elements 11b correspond to each other. The relationship between the nozzle address that identifies each nozzle 11a and the liquid suitable (ink) speed discharged from each nozzle 11a corresponding to the nozzle address when a constant voltage is applied to the piezoelectric bodies 11b1 and 11b2 is shown in, for example, the figure. It is shown by the graph of 7. The nozzle address is, for example, 1680.

As shown in FIG. 7, for example, with respect to the liquid suitable speed, five speed ranges are set, and the speed ranges correspond to ranks A to E, respectively. Rank A corresponds to the fastest speed range, and rank E corresponds to the slowest speed range. Ranks A to E are stored in the non-volatile memory 11e corresponding to each nozzle address according to the appropriate liquid speed of each nozzle 11a. Although the droplet velocity is given here as an example, the same concept can be used for the droplet ejection amount.

In terms of the degree of ease of ink ejection, the nozzle 11a (driving element 11b) corresponding to rank A is the easiest to eject, and the nozzle 11a (driving element 11b) corresponding to rank E is the most difficult to eject. Therefore, in order to average the liquid optimum speed or the liquid suitable discharge amount in each nozzle 11a, the lowest voltage is applied to the drive element 11b corresponding to rank A, and the highest voltage is applied to the drive element 11b corresponding to rank E. Apply voltage.

The first table is stored in, for example, the non-volatile memory 11e of the head unit 11 (see FIG. 8). In FIG. 8, the nozzle address column indicates the nozzle address corresponding to each nozzle 11a (driving element 11b). The rank column indicates any of ranks A to E corresponding to the nozzle 11a, and the drive voltage column indicates the voltage for driving the drive element 11b corresponding to the rank. Specifically, the drive voltage includes VDD2-1 to VDD2-7. Each rank is assigned to each nozzle address based on the relationship shown in FIG. 7.

The piezoelectric bodies 11b1 and 11b2 of the driving element 11b are composed of, for example, a piezo element, and are driven by applying a voltage. The piezoelectric bodies 11b1 and 11b2 function as capacitors in the power supply selection circuit 20. The drive element 11b may include only a single piezoelectric body.

The power supply selection circuit 20 includes a selection circuit 21, a plurality of level shifters 22, a waveform output circuit 23, a level shifter 24, a resistor 25, a CMOS circuit 30, and the like. The FPGA 72a transmits a selection signal to the selection circuit 21. The level shifters 22 and 24 change the voltage level of the input signal to a higher voltage level, and output the signal at the changed voltage level. The CMOS circuit 30 includes a plurality of NMOS circuits, for example, first NMOS (P-type Metal-Oxide-Semiconductor) transistors 31 (1) to seventh MOSFET transistors 31 (7) and an NMOS (N-type Metal-Oxide-Semiconductor) transistor. 32 and.

Hereinafter, when it is not necessary to distinguish between them, the first MIMO transistor 31 (1) to the seventh epitaxial transistor 31 (7) are simply referred to as the MIMO transistor 31. The epitaxial transistor 31 corresponds to the first switching element, and the NMOS transistor 32 corresponds to the second switching element.

As described above, the printing apparatus 1 includes, for example, a first power supply circuit 121 to a seventh power supply circuit 127. The seventh power supply circuit 127 is, for example, a power supply for non-ejection correction used when ink is not ejected from the nozzle 11a. The first power supply circuit 121 to the seventh power supply circuit 127 and the source terminals 31a of the first epitaxial transistor 31 (1) to the seventh epitaxial transistor 31 (7) are connected to each other via the first power supply line 241 to the seventh power supply line 247, respectively. It is connected.

The voltage supplied by the first power supply line 241 to the seventh power supply line 247, that is, the voltage of the first power supply circuit 121 to the seventh power supply circuit 127 is VDD2-1 to VDD2-7, respectively. The value of each voltage is VDD2-1 <VDD2-2 << ... <VDD2-6 <VDD2-7.

The plurality of level shifters 22 correspond to the first MPa transistor 31 (1) to the seventh epitaxial transistor 31 (7), respectively. The gate terminal 31c of the epitaxial transistor 31 is connected to the level shifter 22. The gate terminal 32c of the NMOS transistor 32 is connected to the level shifter 24. The drain terminals 31b and 32b of the epitaxial transistor 31 and the NMOS transistor 32 are connected to each other and are connected to one end of the resistor 25. The resistor 25 is provided to drive the piezoelectric bodies 11b1 and 11b2, and adjusts the rising and falling portions of the waveform. Further, it is provided to prevent the FPGA 72a from being destroyed by a high voltage or current from the outside.

The source terminal 32a of the NMOS transistor 32 is connected to the wiring 26. The voltage VSS2 of the wiring 26, in other words, the reference voltage is, for example, the ground potential. The voltage VSS2 is lower than the voltages VDD2-1 to VDD2-7 of any power source. One end of the piezoelectric body 11b2 is connected to the wiring 26, and the other end of the piezoelectric body 11b2 is connected to the other end of the resistor 25 and one end of the other piezoelectric body 11b1. The other end of the other piezoelectric body 11b1 is connected to the seventh power supply line 247.

From the waveform output circuit 23, a pulse signal for driving the drive element 11b is output to the selection circuit 21 and the level shifter 24, respectively. The waveform of the pulse signal determines the appropriate size or volume of the liquid discharged from the nozzle 11a. For example, the control device 7 selects one of the waveform patterns of the plurality of pulse signals stored in advance based on a command or the like from the external device 9. The plurality of waveform patterns indicate that the appropriate size or volume of the liquid is "large", "medium", and "small", respectively. The "large", "medium", and "small" waveform patterns are realized by changing the pulse width. A drive signal is output from the level shifter 24 to the NMOS transistor 32.

A selection signal for selecting any one of the plurality of power supply circuits 121 to 127 is input to the selection circuit 21. The selection signal is, for example, a digital signal composed of one or more bits. The selection circuit 21 includes a memory (not shown), and a table is stored in the memory. The table shows one-to-one correspondence between each of the plurality of pieces of information indicated by the digital signal and each of the plurality of power supplies. A logic circuit may be used instead of the memory.

As shown in FIG. 9, a table is stored in the selection circuit 21. For example, the selection signal is composed of 3 bits. In FIG. 9, "P0", "P1", and "P2" indicate the places of bit numbers 0, 1, and 2, respectively, and "1" to "7" in the "power supply circuit" column are 3-bit selections. The first power supply circuit 121 to the seventh power supply circuit 127 corresponding to the signal are shown respectively. Further, "non-selected" in the "power supply circuit" column indicates that neither power supply circuit is selected.

The seven selection signals of "001" to "111" correspond to the seven power supply circuits of the power supply circuits 121 to 127, respectively. The seven selection signals "001" to "111" correspond one-to-one with the first power supply circuit 121 to the seventh power supply circuit 127.

The selection signal "000" is a signal indicating non-selection of the power supply circuits 121 to 127 (hereinafter referred to as a non-selection signal), and the non-selection signal is not used in normal printing processing, for example, in the case of failure analysis. , Used to confirm whether the power supply circuits 121 to 127 have a cause of failure. When the non-selection signal is input to the selection circuit 21, the selection circuit 21 does not conduct the drive element 11b and all the power supply circuits 121 to 127.

Hereinafter, a case where any one of the selection signals “001” to “111” is input to the selection circuit 21 will be described. The selection circuit 21 refers to the table and outputs a drive signal to the gate terminal of any one of the PRIVATE transistors 31 corresponding to the power supply circuits 121 to 127 indicated by the input selection signal via the level shifter 22.

For example, when the selection signal "001" is input to the selection circuit 21, the selection circuit 21 outputs a drive signal to the first epitaxial transistor 31 (1). The power supply circuit corresponding to the selection signal "001" is the first power supply circuit 121. The first PRIVATE transistor 31 (1) is connected to the first power supply line 241 and the first power supply line 241 supplies the voltage VDD2-1 of the first power supply circuit 121. That is, the selection circuit 21 selects any one of the power supply circuits based on the selection signal.

When the output signal of "L" is input from the FPGA 72a to the gate terminals 31c and 32c of the epitaxial transistor 31 and the NMOS transistor 32 via the waveform output circuit 23, the epitaxial transistor 31 conducts and the piezoelectric body 11b2 is charged. 11b1 is discharged. When the output signal of "H" is input from the FPGA 72a to the gate terminals 31c and 32c of the epitaxial transistor 31 and the NMOS transistor 32, the NMOS transistor 32 conducts, the piezoelectric body 11b2 is discharged, and 11b1 is charged.

When the piezoelectric bodies 11b1 and 11b2 are charged and discharged, the piezoelectric bodies 11b1 and 11b2 are deformed and ink is discharged from the nozzle 11a. At this time, a predetermined amount is based on the waveform of the pulse signal output from the waveform output circuit 23, for example, the waveform pattern indicating that the size or volume suitable for the liquid is “large”, “medium”, and “small”, respectively. Ink is ejected.

As described above, the selection circuit 21 does not output the signal for driving the NMOS transistor 32, and the selection circuit 21 outputs the signal for driving the epitaxial transistor 31.

In other words, the selection circuit 21 is provided with a configuration for controlling the drive of the epitaxial transistor 31, but is not provided with a configuration for controlling the drive of the NMOS transistor 32. Therefore, it is possible to suppress the increase in size of the selection circuit 21, and thus the increase in size of the power supply selection circuit 20.

The voltage VDD1 is supplied to the selection circuit 21 and the waveform output circuit 23, and the voltage VDD2-7 is supplied to the level shifters 22 and 24. The voltage VDD1 is lower than the voltage VDD2-1, that is, lower than the voltage of any power source.

In the first embodiment, a selection signal for selecting a single power supply circuit is input to the selection circuit 21. Even if noise is added to the selection signal, the selection signal is still unique information for selecting a single power supply circuit and does not indicate a plurality of power supply circuits. Further, the selection circuit 21 selects any one of the power supply circuits corresponding to the input selection signal, and drives a single epitaxial transistor 31 connected to the selected single power supply circuit. Therefore, it is possible to prevent the plurality of MIMO transistors 31 from being driven.

Further, the selection signal is a digital signal, and since each of the digital signal information "P0P1P2" and each of the plurality of power supply circuits 121 to 127 have a one-to-one correspondence, the digital signal is changed due to disturbance, for example, noise. However, the modified digital signal corresponds to a single power supply circuit. For example, when the 3-bit digital signal "001" corresponds to the first power supply circuit 121 and "011" corresponds to the third power supply circuit 123, noise is mixed in "001" and becomes "011". Even if it is changed, the changed "011" is the third power supply circuit 123, that is, unique information corresponding to only a single power supply circuit. Therefore, the selection circuit 21 can make only a single power supply circuit and the drive element 11b conductive. In other words, even if the selection signal is changed due to the disturbance, the continuity between the plurality of power supply circuits 121 to 127 and the single drive element 11b can be avoided.

By connecting the selection circuit 21 and the epitaxial transistor 31, a drive signal is output from the selection circuit 21 to the epitaxial transistor 31. In the selection circuit 21, a drive signal is generated based on the selection signal corresponding to any one of the power supply circuits, and is output to any one of the PRIVATE transistors 31. Therefore, the epitaxial transistor 31 can conduct any one of the power supply circuits corresponding to the selection signal and the drive element 11b.

Also, by selecting the power supply circuit before starting printing, it is possible to prevent the printing control from becoming complicated.

Further, since the power supply circuit selected before the start of printing is not changed during printing, the printing apparatus 1 including the power supply selection circuit 20 does not need to control both printing and selection at the same time. That is, it is possible to prevent the load on the printing device 1 from becoming excessive.

The power supply selection circuit 20 selects one of the power supply circuits before starting printing. Also, the power supply circuit selected before the start of printing is not changed during printing.

Each of the plurality of drive elements 11b has a discharge characteristic. The voltages VDD2-1 to VDD2-7 of the plurality of power supply circuits 121 to 127 correspond to the ejection characteristics of each driving element 11b in order to equalize the amount of ink ejected by driving each of the plurality of driving elements 11b. It is set to a different voltage. By supplying a voltage corresponding to the discharge characteristics to each drive element 11b, a desired discharge amount can be discharged from any drive element 11b.

Further, the plurality of drive elements 11b and the plurality of power supply selection circuits 20 (in other words, the plurality of selection circuits 21) correspond to each other. Each selection circuit 21 conducts any one drive element 11b corresponding to the input selection signal and any one power supply circuit corresponding to the selection signal. Therefore, even when a plurality of driving elements 11b are provided, it is possible to suppress driving of a plurality of epitaxial transistors 31.

For example, when performing failure analysis, a non-selection signal that does not select the power supply circuits 121 to 127 is input to the selection circuit 21 as a selection signal in order to check whether or not the power supply circuits 121 to 127 are the cause. When the non-selection signal is input to the selection circuit 21, the selection circuit 21 does not conduct the drive element 11b and the power supply circuits 121 to 127. The power supply selection circuit 20 can also handle the case where the power supply circuits 121 to 127 are not selected.

Basically, the upstream side of the power supply selection circuit 20 is driven by a low voltage, and the downstream side is driven by a high voltage. By arranging the selection circuit 21 on the upstream side, it can be driven at a low voltage. The drive voltage, which was a high voltage, was not simply reduced to a low voltage, but by using the basic power supply configuration and arranging the selection circuit 21 on the upstream side, the selection circuit 21 is set to the voltage VDD1, that is, the power supply circuits 121 to 121. It can be driven by a voltage lower than the voltage of 127 VDD2-1 to VDD2-7. By driving the selection circuit 21 at a low voltage, it is not necessary to use a large component that can withstand the high voltage as compared with the case where the selection circuit 21 is driven at a high voltage, and the selection circuit 21 can be miniaturized.

Further, a pulse signal for discharging the liquid, for example, a pulse signal corresponding to an appropriate size or volume of the discharged liquid is input to the NMOS transistor 32. Based on the input pulse signal, the NMOS transistor 32 repeats conduction and non-conduction between the drive element 11b and the wiring 26 of the reference voltage VSS2 at a predetermined frequency, and a desired amount of liquid is discharged.

Conventionally, a plurality of pulse generation circuits having a circuit for generating a high potential and a circuit for generating a low potential have been provided in the printing apparatus. A plurality of pulse generation circuits were provided in order to generate high potentials having different values. Since it was necessary to provide a circuit for generating a low potential for each pulse generation circuit, the number of circuits for generating a low potential increased as the number of pulse generation circuits increased, and the entire plurality of pulse generation circuits became large. It had become.
In the first embodiment, the drive element 11b connected to the plurality of power supply circuits 121 to 127 is connected to the NMOS transistor 32 connected to the terminal (ground) of the reference voltage VSS2. By driving the NMOS transistor 32, the voltage applied to the driving element 11b is switched from the power supply voltage VDD2-1 to VDD2-7 to the reference voltage VSS2, and a pulse is generated. Therefore, it is not necessary to provide a plurality of circuits for generating a low potential, and the entire circuit for generating a pulse is miniaturized.

Further, the wiring 26 is used as the ground terminal, and the reference voltage VSS2 is used as the ground. When a circuit for generating a pulse is provided and a voltage other than the ground voltage is set as the reference voltage VSS2, it is necessary to provide a circuit for generating a voltage other than the ground voltage. , There is no need to provide such a circuit.

Further, since the switching elements connected to the plurality of power supply circuits 121 to 127 are composed of the epitaxial transistor 31 and the NMOS transistor 32, the power supply selection circuit 20 can be miniaturized.

(Embodiment 2)
Hereinafter, the power supply selection circuit 20A according to the second embodiment will be described with reference to the drawings. Of the configurations of the power supply selection circuit 20A according to the second embodiment, the same configurations as those of the first embodiment are designated by the same reference numerals, and detailed description thereof will be omitted. In the second embodiment, unlike the first embodiment, the selection circuit 21 is driven by the voltage VDD2-7.

As shown in FIG. 10, the power supply selection circuit 20A includes a receiving circuit 37 that receives a command. The receiving circuit 37 is driven by the voltage VDD1. The selection circuit 21 is driven by the voltage VDD2-7. That is, the receiving circuit 37 is driven by a voltage lower than that of the selection circuit 21.

A plurality of level shifters 22 are provided between the receiving circuit 37 and the selection circuit 21. The receiving circuit 37 receives a command from the FPGA 72a. In the receiving circuit 37, a signal is input to each of the plurality of level shifters 22 based on the command, and is input to the selection circuit 21. The plurality of level shifters 22 correspond to the first MIMO transistor 31 (1) to the nPMOS transistor 31 (7). The selection circuit 21 receives a selection signal from the FPGA 72a.

The level shifter 22 changes the voltage level of the input signal to a higher voltage level, and outputs the signal at the changed voltage level. The selection circuit 21 outputs a drive signal to the polyclonal transistor 31 corresponding to the power supply circuits 121 to 127 indicated by the selection signal input from the FPGA 72a.

When a level shifter 22 or the like is provided between the epitaxial transistor 31 and the selection circuit 21, noise may be mixed in the level shifter 22 or the like. In the power supply selection circuit 20B according to the second embodiment, since the level shifter 22 or the like is not provided between the polyclonal transistor 31 and the selection circuit 21, noise is mixed between the epitaxial transistor 31 and the selection circuit 21. Can be suppressed.

Further, the continuity of the epitaxial transistor 31 is controlled by a voltage near the power supply voltage. When the drive voltage of the selection circuit 21 is lower than the power supply voltage, it is difficult to control the continuity of the epitaxial transistor 31 with the drive voltage of the selection circuit 21, so the level shifter 22 is placed between the epitaxial transistor 31 and the selection circuit 21. Etc. need to be provided. In the second embodiment, by setting the drive voltage of the selection circuit 21 to a high voltage, for example, the power supply voltage VDD2-7, it is not necessary to provide a level shifter 22 or the like between the epitaxial transistor 31 and the selection circuit 21. Therefore, it is possible to suppress the mixing of noise between the selection circuit 21 and the epitaxial transistor 31.

(Embodiment 3)
Hereinafter, the power supply selection circuit 20B according to the third embodiment will be described with reference to the drawings. Of the configurations of the power supply selection circuit 20B according to the third embodiment, the same configurations as those of the first or second embodiment are designated by the same reference numerals, and detailed description thereof will be omitted. The third embodiment is different from the first or second embodiment and includes a diode 28.

As shown in FIG. 11, the power supply selection circuit 20B includes a plurality of diodes 28 as current backflow prevention elements. The plurality of diodes 28 are provided between the drain terminals 31b of each of the first epitaxial transistor 31 (1) to the sixth epitaxial transistor 31 (6) and the resistor 25.

The forward direction of the diode 28 is from the epitaxial transistor 31 toward the resistor 25. A diode 28 is not provided between the drain terminal 31b of the 7th MIMO transistor 31 (7) and the resistor 25. In other words, the diode 28 is not provided between the epitaxial transistor 31 connected to the power supply circuit 127 having the maximum voltage VDD2-7 and the drive element 11b.

In the printing apparatus 1 according to the third embodiment, by providing a current backflow element, for example, a diode 28, a power source having a relatively low voltage is provided when two ProLiant transistors 31 are driven by, for example, a malfunction. It is possible to prevent the current from flowing back to the connected polyclonal transistor 31.

Even if the two NetBackup transistors 31 are driven by a malfunction, no current flows back to the epitaxial transistor 31 connected to the seventh power supply circuit 127 having the maximum voltage VDD2-7. This is because when the two ProLiant transistors 31 include the MIMO transistor 31 connected to the power supply circuit 127 having the maximum voltage VDD2-7, the power supply circuit 127 having the maximum voltage VDD2-7 to the maximum voltage VDD2-7. This is because the current flows back to the power supply circuits 121 to 126 having lower voltages VDD2-1 to VDD2-6. Therefore, the diode 28 is not provided between the 7th PRIVATE transistor 31 (7) connected to the 7th power supply circuit 127 having the maximum voltage VDD2-7 and the drive element 11b. On the other hand, a diode 28 is provided between the first epitaxial transistor 31 (1) to the sixth epitaxial transistor 31 (6) connected to the other power supply circuits 121 to 126 and the drive element 11b. As a result, the reduction of the diode 28 and the prevention of the backflow of the current can be achieved at the same time.

Further, by connecting the drain terminal of the NMOS transistor 32 to the terminal of the drive element 11b to which the epitaxial transistor 31 is connected and connecting the source terminal of the NMOS transistor 32 to the wiring 26 (terminal of the reference voltage VSS2), the power supply voltage VDD2 A pulse can be generated by switching the applied voltage of the drive element 11b from -1 to VDD2-7 to the reference voltage VSS2. That is, since the power supply voltages VDD2-1 to VDD2-7 are higher than the reference voltage VSS2, the pulse can be generated without providing a plurality of circuits for generating a low potential.

(Embodiment 4)
Hereinafter, the power supply selection circuit 20C according to the fourth embodiment will be described with reference to the drawings. Of the configurations of the power supply selection circuit 20C according to the fourth embodiment, the same configurations as those of the first to third embodiments are designated by the same reference numerals, and detailed description thereof will be omitted.

As shown in FIG. 12, in the fourth embodiment, unlike the first to third embodiments, the voltage supplied by the first power supply line 241 to the seventh power supply line 247, that is, the voltage VDD2 of the first power supply to the seventh power supply. The values of -1 to VDD2-7 are VDD2-1> VDD2-2 >> ...> VDD2-6> VDD2-7.

The reference voltage VSS2 is higher than the voltages VDD2-1 to VDD2-7 of any power source. Further, the voltage VDD1 is higher than the voltage VDD2-1, that is, lower than the voltage of any power source. The drive element 11b includes only the piezoelectric body 11b1. The drive element 11b may include a plurality of piezoelectric bodies.

In the fourth embodiment, the NMOS transistors 32 connected to the wiring 26 of the reference voltage VSS2 are connected to the drive elements 11b connected to the plurality of power supply circuits 121 to 127. By driving the NMOS transistor 32, the voltage applied to the driving element 11b is switched from the voltage VDD2-1 to VDD2-7 of the power supply circuits 121 to 127 to the reference voltage VSS2, and a pulse is generated. Therefore, it is possible to generate a pulse without providing a plurality of circuits for generating a high potential. Further, it is not necessary to provide a plurality of circuits for generating a high potential, and the entire circuit for generating a pulse is miniaturized as compared with the case where a plurality of circuits for generating a high potential are provided.

(Embodiment 5)
The printing apparatus 1 according to the fifth embodiment will be described below. Of the configurations of the printing apparatus 1 according to the fifth embodiment, the same configurations as those of the first to fourth embodiments are designated by the same reference numerals, and detailed description thereof will be omitted.

The printing device 1 can change the power supply circuit selected by the selection circuit 21. When the power supply circuit selected by the selection circuit 21 is changed, the printing apparatus 1 drives the NMOS transistor 32 for a predetermined time to conduct the NMOS transistor 32 for a predetermined time before changing the power supply circuit. Due to the conduction of the NMOS transistor 32, the electric charge accumulated in the driving element 11b is discharged to the wiring 26 of the reference voltage VSS2. After releasing the charge accumulated in the drive element 11b, the selection circuit 21 changes the power supply circuit.

Since the electric charge accumulated in the drive element 11b is released before the power supply circuit is changed, noise that the voltage rises momentarily or noise that the voltage drops momentarily is added when the power supply circuit is changed. It is possible to prevent the backflow of current, that is, the charge accumulated in the driving element 11b is moved toward the power supply circuit having a relatively low voltage by driving the two PRIVATE transistors 31 due to the malfunction.

By setting the reference voltage VSS2 to the ground potential, the electric charge accumulated in the drive element 11b is released more reliably.

The plurality of power supply circuits 121 to 127 of the present embodiment are examples of the plurality of power supplies of the present invention. The MIMO transistor 31 of the present embodiment is an example of the first switching element of the present invention. The diode 28 of the present embodiment is an example of the current backflow prevention element of the present invention. The NMOS transistor 32 of this embodiment is an example of the second switching element of the present invention. The FPGA 72a of the present embodiment is an example of the control circuit of the present invention.

The embodiments disclosed this time should be considered to be exemplary in all respects and not restrictive. The technical features described in each example can be combined with each other and the scope of the invention is intended to include all modifications within the claims and scope equivalent to the claims. Will be done.

1 Printing device 11a Nozzle 11b Drive element 11b1, 11b2 Piezoelectric body 20 Power supply selection circuit 21 Selection circuit 22 Level shifter 26 terminals 27 Reception circuit 28 Diode (current backflow prevention element)
30 CMOS circuit 31 ProLiant transistor (first switching element)
32 NMOS transistor (second switching element)

Claims (30)

A plurality of first switching elements connected to a driving element that applies energy to the liquid and discharges the liquid, and each connected to a plurality of power supplies having different voltages.
A selection signal for selecting the single power supply is input, and the selection circuit for selecting one of the plurality of power supplies corresponding to the input selection signal is provided.
The selection circuit conducts the driving element and the selected power supply via the first switching element .
A second switching element connected to the drive element and the wiring of the reference voltage is provided.
A pulse signal for discharging the liquid is input to the second switching element.
The second switching element conducts the driving element and the wiring of the reference voltage based on the input pulse signal.
The voltage of the power supply is higher than the reference voltage
A power supply selection circuit in which a signal for driving the second switching element is not output from the selection circuit, and a signal for driving the first switching element is output from the selection circuit. A plurality of first switching elements connected to a driving element that applies energy to the liquid and discharges the liquid, and each connected to a plurality of power supplies having different voltages.
A selection signal for selecting a single power supply is input, and a selection circuit for selecting one of the plurality of power supplies corresponding to the input selection signal is provided.
With
The selection circuit conducts the driving element and the selected power supply via the first switching element.
A second switching element connected to the drive element and the wiring of the reference voltage is provided.
A pulse signal for discharging the liquid is input to the second switching element.
The second switching element conducts the driving element and the wiring of the reference voltage based on the input pulse signal.
The voltage of the power supply is lower than the reference voltage,
The signal for driving the second switching element is not output from the selection circuit, and the signal for driving the first switching element is output from the selection circuit.
Power selection circuit. A plurality of first switching elements connected to a driving element that applies energy to the liquid and discharges the liquid, and each connected to a plurality of power supplies having different voltages.
A selection signal for selecting a single power supply is input, and a selection circuit for selecting one of the plurality of power supplies corresponding to the input selection signal is provided.
With
The selection circuit conducts the driving element and the selected power supply via the first switching element.
A second switching element connected to the drive element and the wiring of the reference voltage is provided.
A pulse signal for discharging the liquid is input to the second switching element.
The second switching element conducts the driving element and the wiring of the reference voltage based on the input pulse signal.
When changing the selected power supply in the selection circuit, the second switching element is driven before changing the power supply.
Power selection circuit. A plurality of first switching elements connected to a driving element that applies energy to the liquid and discharges the liquid, and each connected to a plurality of power supplies having different voltages.
A selection signal for selecting a single power supply is input, and a selection circuit for selecting one of the plurality of power supplies corresponding to the input selection signal is provided.
With
The selection circuit conducts the driving element and the selected power supply via the first switching element.
The selection circuit selects any one of the power sources before starting printing with the liquid discharged by the driving element.
The selection circuit does not change the power supply during printing
Power selection circuit. A plurality of first switching elements connected to a driving element that applies energy to the liquid and discharges the liquid, and each connected to a plurality of power supplies having different voltages.
A selection signal for selecting a single power supply is input, and a selection circuit for selecting one of the plurality of power supplies corresponding to the input selection signal is provided.
With
The selection circuit conducts the driving element and the selected power supply via the first switching element.
It has a low voltage region to which a voltage lower than the voltage of the power supply is supplied and a high voltage region to which a voltage higher than the low voltage region is supplied.
The selection circuit is arranged in the low voltage region and is driven by a voltage lower than the voltage of the power supply.
Power selection circuit. The power supply selection circuit according to any one of claims 1 to 3 and 5, wherein the selection circuit selects any one power source before starting printing with the liquid discharged by the drive element. The power supply selection circuit according to claim 6 , wherein the selection circuit does not change the power supply during printing. The power supply selection circuit according to any one of claims 1 to 4 , wherein the selection circuit is driven by a voltage lower than the voltage of the power supply. A second switching element connected to the drive element and the wiring of the reference voltage is provided.
A pulse signal for discharging the liquid is input to the second switching element.
The power supply selection circuit according to claim 4 or 5 , wherein the second switching element conducts the driving element and the wiring of the reference voltage based on the input pulse signal. The power supply selection circuit according to claim 3 or 9 , wherein the voltage of the power supply is higher than the reference voltage. The power supply selection circuit according to claim 3 or 9 , wherein the voltage of the power supply is lower than the reference voltage. The power supply selection according to claim 1, 2, 10 or 11 , wherein the signal for driving the second switching element is not output from the selection circuit, and the signal for driving the first switching element is output from the selection circuit. circuit. One terminal of the second switching element is connected to the terminal of the driving element to which the plurality of first switching elements are connected.
The power supply selection circuit according to any one of claims 1, 2, 10, 11 or 12 , wherein the other terminal of the second switching element is connected to the wiring of the reference voltage. In the selection circuit, when the selected power supply is changed, any one of claims 1, 2, 10, 11, 12 or 13 for driving the second switching element before changing the power supply. The power supply selection circuit described. The power supply selection circuit according to any one of claims 1, 2, 3, 10, 11, 12, 13 or 14 , wherein the reference voltage wiring is connected to the ground. The power supply selection circuit according to any one of claims 1, 2, 3, 10, 11, 12, 13, 14 or 15, wherein the second switching element is a MOS transistor. The selection signal is a digital signal composed of one or more bits.
In the selection circuit, a one-to-one correspondence relationship between each of the plurality of information indicated by the digital signal and each of the plurality of power supplies is set.
The power supply selection circuit according to any one of claims 1 to 16, wherein the selection circuit makes any one of the power supplies and the drive element conductive based on the correspondence. The selection circuit is connected to the first switching element, and the selection circuit is connected to the first switching element.
When the selection signal is input to the selection circuit, a drive signal for driving the first switching element is output to any one of the first switching elements connected to the power supply corresponding to the selection signal.
The power supply selection circuit according to any one of claims 1 to 17, wherein the first switching element to which the drive signal is input conducts the drive element and the power supply corresponding to the selection signal. It is equipped with a plurality of the driving elements.
The power supply according to any one of claims 1 to 18 , wherein the voltages of the plurality of power supplies are set to different voltages in order to equalize the amount of liquid discharged by driving each of the plurality of driving elements. Selection circuit. With the plurality of the driving elements
A plurality of the selection circuits corresponding to the plurality of driving elements are provided.
The selection signal corresponds to any one of the driving elements.
The power supply selection circuit according to any one of claims 1 to 19 , wherein the selection circuit conducts the driving element corresponding to the input selection signal and any one of the power supplies corresponding to the selection signal. .. The selection signal includes a signal corresponding to the non-selection of the power supply.
The power supply selection circuit according to any one of claims 1 to 20 , wherein when a signal corresponding to the non-selection of the power supply is input, the selection circuit does not conduct the drive element and the power supply. The power supply selection circuit according to any one of claims 1 to 21 , wherein a level shifter for changing a voltage level is not provided between the selection circuit and the first switching element. A receiving circuit that receives the selection signal and drives the selection circuit at a voltage lower than the drive voltage of the selection circuit is provided.
The power supply selection circuit according to claim 22 , wherein the level shifter is interposed between the reception circuit and the selection circuit. The power supply selection circuit according to any one of claims 1 to 23 , wherein a current backflow prevention element is provided between the first switching element and the driving element. The power supply selection circuit according to claim 24 , wherein the current backflow prevention element has a diode. The power source selection according to claim 24 or 25 , wherein the current backflow prevention element is provided between each first switching element connected to the power source other than the power source having the maximum voltage and the drive element, respectively. circuit. The power supply selection circuit according to any one of claims 1 to 26, wherein the first switching element is a MOS transistor. The power supply selection circuit according to any one of claims 1 to 5.
And a control circuit for controlling the driving of the first switching element,
A circuit in which the selection signal is input to the selection circuit from the control circuit. A drive element that applies energy to the liquid and discharges the liquid,
A plurality of power supplies connected to the driving element and having different voltages,
With the circuit according to claim 28
Head module comprising a. A printing apparatus comprising the head module according to claim 29.

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