The present application claims priority from Japanese Patent Application No. 2016-082662 filed on Apr. 18, 2016, the disclosures of which is incorporated herein by reference in its entirety.
The present disclosure relates to an ink-jet printer that records an image on a sheet, based on a recording command.
In the past, attempts have been made to reduce FPOT (abbreviation of First Print Out Time) in an information processing apparatus and printer connected via a communication network. FPOT is a time from a print instruction being inputted to the external apparatus to a first sheet being discharged from the printer.
Reducing a time of a preparation process is conceivable as one of methods for reducing FPOT. The preparation process is a process that should be executed by the printer before recording an image on the sheet, and includes, for example, a flushing process in which a recording head is caused to discharge ink toward an ink receiver.
However, generally, an amount of ink that should be discharged in the flushing process is increased/decreased based on a state of the printer. Moreover, if the amount of ink that should be discharged in the flushing process becomes large, the preparation process takes a long time, whereby FPOT deteriorates. On the other hand, if the amount of ink discharged in the flushing process is insufficient, there is a possibility that image recording quality deteriorates.
The present disclosure was made in view of the above-described circumstances, and has an object of providing an ink-jet printer in which FPOT is reduced while image recording quality is maintained.
A first aspect of the present teaching provides an ink-jet printer including:
a conveyor configured to convey a sheet in a conveyance direction;
a carriage being movable in a main scanning direction along a sheet facing area, the main scanning direction intersecting the conveyance direction, and the sheet facing area facing the sheet conveyed by the conveyor;
a recording head mounted on the carriage to discharge ink from a nozzle;
a power supply configured to supply a drive voltage to the recording head;
an ink receiver facing the recording head in a case that the carriage is positioned in a first position which is more to an outside in the main scanning direction than the sheet facing area;
a command receiver; and
a controller configured to control the conveyor, the carriage, the recording head and the power supply to execute:
An amount of ink able to be discharged from the nozzle per unit time becomes larger the higher the drive voltage is. Accordingly, as in the above-described configuration, the drive voltage is increased/decreased based on an ink amount that should be discharged. As a result, ink required to maintain image recording quality can be reliably discharged in a flushing process. Moreover, since ink is discharged while a carriage is being moved in the flushing process, FPOT can be reduced more compared to when the flushing process is executed in a state where the carriage has been stopped.
A second aspect of the present teaching provides an ink-jet printer, the ink-jet printer comprising:
a conveyor configured to convey a sheet in a conveyance direction;
a carriage being movable in a main scanning direction along a sheet facing area, the main scanning direction intersecting the conveyance direction, and the sheet facing area facing the sheet conveyed by the conveyor;
a recording head mounted on the carriage to discharge ink from a nozzle;
a power supply configured to supply a drive voltage to the recording head;
an ink receiver facing the recording head in a case that the carriage is positioned in a first position displaced in the main scanning direction from the sheet facing area;
a command receiver; and
a controller configured to control the conveyor, the carriage, the recording head, and the power supply to execute:
Due to the present teaching, since the flushing process is executed while the carriage is being moved and the drive voltage is increased/decreased based on the ink amount that should be discharged, FPOT can be reduced while image recording quality is maintained.
An embodiment of the present teaching will be described below. Note that the embodiment described below is merely an example of the present teaching, and it goes without saying that the embodiment of the present teaching may be appropriately changed in a range that does not alter the gist of the present teaching. An up-down direction 7 is defined with reference to a state in which a multifunction peripheral 10 is usably disposed (state of
[Overall Configuration of Multifunction Peripheral 10]
As depicted in
[Printer 11]
The printer 11 discharges ink, thereby recording on a sheet 12 (refer to
[Feed Trays 20A, 20B and Discharge Tray 21]
The opening 13 (refer to
[Feed Sections 15A, 15B]
As depicted in
[Conveyance Path 65]
The conveyance path 65 indicates a space formed by guide members 18, 30 and guide members 19, 31. The guide members 18, 30 and the guide members 19, 31 face each other with a certain spacing between them on the inside of the printer 11. The conveyance path 65 is a path that extends from a rear end section of the feed trays 20A, 20B to a rear side of the printer 11. Moreover, the conveyance path 65 is a path that makes a U-turn while extending from a downward side to an upward side at the rear side of the printer 11, and that passes through the recording section 24 to reach the discharge tray 21. Note that a conveyance orientation 16 of the sheet 12 in the conveyance path 65 is indicated by a dot-chain line arrow in
[Conveyance Roller Section 54]
The conveyance roller section 54 is disposed upstream in the conveyance orientation 16 of the recording section 24. The conveyance roller section 54 includes a conveyance roller 60 and a pinch roller 61 that face each other. The conveyance roller 60 is driven by a conveyance motor 102 (refer to
[Discharge Roller Section 55]
The discharge roller section 55 is disposed downstream in the conveyance orientation 16 of the recording section 24. The discharge roller section 55 includes a discharge roller 62 and a spur wheel 63 that face each other. The discharge roller 62 is driven by the conveyance motor 102. The spur wheel 63 rotates in company with rotation of the discharge roller 62. The sheet 12 is nipped by the discharge roller 62 that forwardly rotates by a forward rotational drive force of the conveyance motor 102 being transmitted thereto, and the spur wheel 63, whereby the sheet 12 is conveyed along the conveyance orientation 16.
[Resist Sensor 120]
As depicted in
[Rotary Encoder 121]
As depicted in
[Recording Section 24]
As depicted in
As depicted in
As depicted in
The vibrating element is an example of a discharge energy generating element that generates, from a drive voltage applied by a power supply section 110, energy (that is, vibrational energy) for discharging ink from the nozzle. However, a specific example of the discharge energy generating element is not limited to a vibrating element, and may be, for example, a heater that generates thermal energy. Moreover, the heater may heat the ink by thermal energy generated from the drive voltage applied by the power supply section 110 and discharge foamed ink from the nozzle. Moreover, the recording head 39 according to the present embodiment discharges pigment ink, but it may discharge dye ink.
As depicted in
Moreover, as depicted in
[Media Sensor 122]
As depicted in
[Platen 42]
As depicted in
[Maintenance Mechanism 70]
As depicted in
As depicted in
The cap 71 is configured by rubber. The cap 71 is disposed at a position that faces the recording head 39 of the carriage 23 when the carriage 23 is positioned in a second position displaced rightward in the main scanning direction from the sheet facing area. The tube 72 reaches from the cap 71 to the liquid discharge tank 74 via the pump 73. The pump 73 is, for example, a rotary type tube pump. The pump 73 is driven by the conveyance motor 102 to suck up the ink in the nozzle 40 via the cap 71 and the tube 72 and discharge it to the liquid discharge tank 74 via the tube 72.
The cap 71 is, for example, configured capable of moving between a covering position and a separated position that are separated in the up-down direction 7. The cap 71 in the covering position closely contacts the recording head 39 of the carriage 23 in the second position, thereby covering the nozzle surface. On the other hand, the cap 71 in the separated position is separated from the nozzle surface. The cap 71 moves between the covering position and the separated position by means of a cap shifter 71A driven by the feed motor 101 (see
As another example, the cap 71, instead of being moved by the cap shifter driven by the feed motor 101, may be moved by an unillustrated link mechanism that operates in conjunction with movement of the carriage 23. The link mechanism is capable of posture change between a first posture in which the cap 71 is held in the covering position and a second posture in which the cap 71 is held in the separated position. Moreover, the link mechanism, for example, undergoes posture change from the second posture to the first posture by being abutted on by the carriage 23 moving toward the second position. On the other hand, the link mechanism, for example, undergoes posture change from the first posture to the second posture by being moved away from by the carriage 23 moving toward a first position.
As another example, the multifunction peripheral 10 may include a raising-and-lowering mechanism (an example of a cap shifter) that moves the guide rails 43, 44 in the up-down direction 7, instead of the cap shifter 71A that moves the cap 71. That is, the carriage 23 in the second position is raised/lowered along with the guide rails 43, 44 that are raised/lowered by the raising-and-lowering mechanism. On the other hand, the cap 71 is fixed in a position facing the recording head 39 of the carriage 23 in the second position. Moreover, by the guide rails 43, 44 and the carriage 23 being lowered to a certain position by the raising-and-lowering mechanism, the nozzle surface of the recording head 39 is covered by the cap 71. Moreover, by the guide rails 43, 44 and the carriage 23 being raised to a certain position by the raising-and-lowering mechanism, the recording head 39 and the cap 71 separate and the carriage 23 becomes movable in the main scanning direction.
As yet another example, the multifunction peripheral 10 may include both of the cap shifter 71A that moves the cap 71 and the raising-and-lowering mechanism that moves the guide rails 43, 44. Then, by the carriage 23 and the cap 71 being moved in an orientation causing them to approach each other, the cap 71 may be caused to closely contact the nozzle surface. Furthermore, by the carriage 23 and the cap 71 being moved in an orientation causing them to separate from each other, the cap 71 may be caused to separate from the nozzle surface. That is, the previously mentioned covering position and separated position refer to relative positions of the recording head 39 and the cap 71. Moreover, all that is required is to change the relative positions of the recording head 39 and the cap 71 by moving one or both of the recording head 39 and the cap 71. In other words, all that is required is to change the relative positions of the recording head 39 and the cap 71 by moving the recording head 39 and the cap 71 relatively.
[Cap Sensor 123]
A cap sensor 123 outputs different detection signals depending on whether the cap 71 is in the covering position or not. The cap sensor 123 outputs a high level signal to the controller 130 based on the cap 71 being in the covering position. On the other hand, the cap sensor 123 outputs a low level signal to the controller 130 based on the cap 71 being in a position different from the covering position. Note that when the cap 71 has been moved from the covering position to the separated position, the detection signal outputted from the cap sensor 123 changes from the high level signal to the low level signal before the cap 71 reaches the separated position.
[Ink Receiver 75]
As depicted in
As depicted in
[Drive Force Transmitting Mechanism 80]
As depicted in
[Switching Mechanism 170]
As depicted in
The first state is a state where the drive force of the feed motor 101 is transmitted to the feed roller 25A, but is not transmitted to the feed roller 25B and the cap shifter 71A of the cap 71. The second state is a state where the drive force of the feed motor 101 is transmitted to the feed roller 25B, but is not transmitted to the feed roller 25A and the cap shifter 71A of the cap 71. The third state is a state where the drive force of the feed motor 101 is transmitted to the cap shifter 71A of the cap 71, but is not transmitted to the feed rollers 25A, 25B. Moreover, the first state and the second state are states where the drive force of the conveyance motor 102 is transmitted to the conveyance roller 60 and the discharge roller 62, but is not transmitted to the pump 73. The second state is a state where the drive force of the conveyance motor 102 is transmitted to all of the conveyance roller 60, the discharge roller 62, and the pump 73.
The slide member 171 is a roughly circular column shaped member supported by a support shaft (indicated by broken lines in
The drive gear 172 rotates by the rotational drive force of the feed motor 101 being transmitted thereto. The drive gear 172 meshes with one of the driven gears 174, 175, 176. In more detail, when the switching mechanism 170 is in the first state, the drive gear 172 meshes with the driven gear 174 as depicted in
The drive gear 173 rotates by the rotational drive force of the conveyance motor 102 being transmitted thereto. When the switching mechanism 170 is in the first state and the second state, meshing of the drive gear 173 with the driven gear 176 is released as depicted in
The driven gear 174 meshes with a gear train rotating the feed roller 25A. That is, meshing of the drive gear 172 and the driven gear 174 results in the rotational drive force of the feed motor 101 being transmitted to the feed roller 25A. Moreover, release of meshing of the drive gear 172 and the driven gear 174 results in the rotational drive force of the feed motor 101 failing to be transmitted to the feed roller 25A.
The driven gear 175 meshes with a gear train rotating the feed roller 25B. That is, meshing of the drive gear 172 and the driven gear 175 results in the rotational drive force of the feed motor 101 being transmitted to the feed roller 25B. Moreover, release of meshing of the drive gear 172 and the driven gear 175 results in the rotational drive force of the feed motor 101 failing to be transmitted to the feed roller 25B.
The driven gear 176 meshes with a gear train driving the cap shifter 71A of the cap 71. That is, meshing of the drive gear 172 and the driven gear 176 results in the rotational drive force of the feed motor 101 being transmitted to the cap shifter 71A of the cap 71. Moreover, release of meshing of the drive gear 172 and the driven gear 176 results in the rotational drive force of the feed motor 101 failing to be transmitted to the cap shifter 71A of the cap 71.
The driven gear 177 meshes with a gear train driving the pump 73. That is, meshing of the drive gear 173 and the driven gear 177 results in the rotational drive force of the conveyance motor 102 being transmitted to the pump 73. Moreover, release of meshing of the drive gear 173 and the driven gear 177 results in the rotational drive force of the conveyance motor 102 failing to be transmitted to the pump 73. On the other hand, the rotational drive force of the conveyance motor 102 is transmitted to the conveyance roller 60 and the discharge roller 62 without intervention of the switching mechanism 170. That is, the conveyance roller 60 and the discharge roller 62 rotate by the rotational drive force of the conveyance motor 102, regardless of the state of the switching mechanism 170.
The lever 178 is supported by the supporting shaft at a position adjacent on the right to the slide member 171. In addition, the lever 178 slides in the left-right direction 9 along the supporting shaft. Furthermore, the lever 178 projects upwardly. Moreover, a tip of the lever 178 reaches to a position where it can be abutted on by the carriage 23, via an opening 43A provided in the guide rail 43. The lever 178 slides in the left-right direction by being abutted on and moved away from by the carriage 23. Moreover, the switching mechanism 170 includes a plurality of locking sections that lock the lever 178. Moreover, the lever 178 that has been locked in the locking section can stay in its position, even after having been moved away from by the carriage 23.
The springs 179, 180 are supported by the supporting shaft. One end (a left end) of the spring 179 abuts on the frame of the printer 11, and the other end (a right end) of the spring 179 abuts on a left end surface of the slide member 171. That is, the spring 179 biases in a rightward orientation the slide member 171 and the lever 178 abutting on the slide member 171. One end (a right end) of the spring 180 abuts on the frame of the printer 11, and the other end (a left end) of the spring 180 abuts on a right end surface of the lever 178. That is, the spring 180 biases in a leftward orientation the lever 178 and the slide member 171 abutting on the lever 178. Furthermore, a biasing force of the spring 180 is larger than a biasing force of the spring 179.
When the lever 178 is locked in a first locking section, the switching mechanism 170 is in the first state. Moreover, the lever 178 pressed on by the carriage 23 moving in the rightward orientation opposes the biasing force of the spring 180 to move in the rightward orientation and be locked in a second locking section positioned rightwards of the first locking section. As a result, the slide member 171 moves in the rightward orientation following movement of the lever 178, due to the biasing force of the spring 179. As a result, the switching mechanism 170 is switched from the first state depicted in
In addition, the lever 178 pressed on by the carriage 23 moving to the second position opposes the biasing force of the spring 180 to move in the rightward orientation and be locked in a third locking section positioned even more rightwards than the second locking section. As a result, the slide member 171 moves in the rightward orientation following movement of the lever 178, due to the biasing force of the spring 179. As a result, the switching mechanism 170 is switched from the first state depicted in
Furthermore, locking in the third locking section, of the lever 178 that has been pressed on by the carriage 23 moving even more rightwards than the second position and then moved away from by the carriage 23 moving in the leftward orientation, is released. As a result, the slide member 171 and the lever 178 are moved in the leftward orientation by the biasing force of the spring 180. Then, the lever 178 is locked in the first locking section. As a result, the switching mechanism 170 is switched from the third state depicted in
That is, the state of the switching mechanism 170 is switched by abutting/separation of the carriage 23 on/from the lever 178. In other words, the transmission destinations of the drive forces of the feed motor 101 and the conveyance motor 102 are switched by the carriage 23. Note that the state of the switching mechanism 170 according to the present embodiment cannot be switched directly from the third state to the second state, and as previously mentioned, is required to be switched from the third state to the first state and further switched from the first state to the second state.
[Power Supply Section 110]
As depicted in
Moreover, the power supply section 110 is capable of switching between a drive state and a sleep state, based on a power supply signal outputted from the controller 130. In more detail, the controller 130 switches the power supply section 110 from the sleep state to the drive state by outputting a HIGH level power supply signal (for example, 5 V). Moreover, the controller 130 switches the power supply section 110 from the drive state to the sleep state by outputting a LOW level power supply signal (for example, 0 V).
The drive state is a state where drive electric power is being outputted to the motors 101-103 and the recording head 39. In other words, the drive state is a state where the motors 101-103 and the recording head 39 are operable. The sleep state is a state where drive electric power is not being outputted to the motors 101-103 and the recording head 39. In other words, the sleep state is a state where the motors 101-103 and the recording head 39 are inoperable. On the other hand, although illustration of this is omitted, the power supply section 110 outputs control electric power to a controller 30 and a communication part 50, regardless of whether the power supply section 110 is in the drive state or in the sleep state.
[Controller 130]
As depicted in
In the present embodiment, the EEPROM 134 stores time information indicating a time (hereafter, described as “FLS execution time”) when a later-mentioned flushing process was most recently executed. The controller 130 acquires the time information from a system clock (not illustrated) at an execution time of the flushing process, and stores the acquired time information in the EEPROM 134 as time information. In addition, the controller 130, based on there being time information already stored in the EEPROM 134, overwrites the time information that has already been stored with new time information.
The feed motor 101, the conveyance motor 102, and the carriage motor 103 are connected to the ASIC 135. The ASIC 135 generates a drive signal for rotating each of the motors, and outputs the generated drive signal to each of the motors. Each of the motors is forward rotationally driven or reverse rotationally driven based on the drive signal from the ASIC 135. Moreover, the controller 130 causes ink to be discharged from the nozzle 40 by applying a drive voltage of the power supply section 110 to the vibrating element of the recording head 39.
Moreover, the communication part 50 is connected to the ASIC 135. The communication part 50 is a communication interface capable of communicating with an information processing apparatus 51. That is, the controller 130 outputs various kinds of information to the information processing apparatus 51 via the communication part 50, and receives various kinds of information from the information processing apparatus 51 via the communication part 50. The communication part 50 may transmit and receive a wireless signal by a communication protocol based on Wi-Fi (registered trademark of Wi-Fi Alliance), for example, or may be an interface to which a LAN cable or USB cable is connected. Note that in
Furthermore, the resist sensor 120, the rotary encoder 121, the carriage sensor 38, the media sensor 122, and the cap sensor 123 are connected to the ASIC 135. The controller 130 detects a position of the sheet 12, based on the detection signal outputted from the resist sensor 120 and the pulse signal outputted from the rotary encoder 121. In addition, the controller 130 detects a position of the carriage 23, based on the pulse signal outputted from the carriage sensor 38. Moreover, the controller 130 detects a position of the cap 71, based on the detection signal outputted from the cap sensor 123.
Furthermore, the controller 130 detects the sheet 12 that has been conveyed by the conveyor, based on the detection signal outputted from the media sensor 122. In more detail, the controller 130 compares an amount of change in signal level of temporally adjacent detection signals and a predetermined threshold value. Then, the controller 130, based on the amount of change in signal level having attained the threshold value or more, detects that a leading edge of the sheet 12 has reached a position facing the media sensor 122 in the up-down direction 7.
[Image Recording Process]
Next, an image recording process of the present embodiment will be described with reference to
First, although illustration of this is omitted, the information processing apparatus 51, based on, for example, having received from a user an instruction to make the multifunction peripheral 10 execute the image recording process, transmits a preceding command to the multifunction peripheral 10. The preceding command is a command that gives prior notice of transmission of a later-mentioned recording command. Next, the information processing apparatus 51, based on having transmitted the preceding command, converts to raster data image data designated by the user. Then, the information processing apparatus 51, based on having generated the raster data, transmits the recording command to the multifunction peripheral 10. The recording command is a command to record on the sheet the image indicated by the raster data.
The controller 130, based on having received the preceding command from the information processing apparatus 51 via the communication part 50 (S11: Preceding Command), executes an FLS condition determining process (S12). The FLS condition determining process is an example of a determining process for determining execution conditions of the flushing process. Details of the FLS condition determining process will be described with reference to
[FLS Condition Determining Process]
First, the controller 130 acquires time information indicating a current time, from the system clock. Then, the controller 130 calculates a difference between the FLS execution time indicated by the time information stored in the EEPROM 134 and the current time, as an elapsed time T from the flushing process being most recently executed to the preceding command being received. This process is an example of a measurement process. However, a method of measuring the elapsed time T is not limited to the previously mentioned example. Then, the controller 130 compares the elapsed time T and threshold times T1, T2, T3 (S21 to S23). The threshold times T1, T2, T3 are values pre-stored in the EEPROM 134, and for the threshold times, it holds that T1<T2<T3.
Next, the controller 130, based on the elapsed time T being less than the threshold time T1 (S21: Yes), determines an FLS shot number to be 50, determines a CR speed to be 60 ips, determines an FLS voltage to be 24V, and determines an FLS number-of-times to be one (S24 to S27). The FLS shot number is the total number of ink droplets (that is, an ink amount) discharged from each of the nozzles 40 in the flushing process. The CR speed is a movement speed of the carriage 23 in the flushing process. The FLS voltage is a drive voltage applied to the recording head in the flushing process. The FLS number-of-times is the number of times of flushing processes. The FLS shot number, the CR speed, the FLS voltage, and the FLS number-of-times are an example of execution conditions of the flushing process.
In addition, the controller 130, based on the elapsed time T being T1 or more and less than T2 (S22: Yes), determines the FLS shot number to be 300, determines the CR speed to be 4 ips, determines the FLS voltage to be 24V, and determines the FLS number-of-times to be one (S28 to S31). Moreover, the controller 130, based on the elapsed time T being T2 or more and less than T3 (S23: Yes), determines the FLS shot number to be 600, determines the CR speed to be 4 ips, determines the FLS voltage to be 26V, and determines the FLS number-of-times to be one (S32 to S35). Furthermore, the controller 130, based on the elapsed time T being T3 or more (S23: No), determines the FLS shot number to be 1800, determines the CR speed to be 4 ips, determines the FLS voltage to be 26V, and determines the FLS number-of-times to be three (S36 to S39).
That is, the controller 130 sets the FLS shot number larger, sets the CR speed slower, sets the FLS voltage higher, and sets the FLS number-of-times larger when the elapsed time T is long, compared to when the elapsed time is short. In other words, the controller 130 sets the CR speed slower, sets the FLS voltage higher, and sets the FLS number-of-times larger when the FLS shot number is large, compared to when the FLS shot number is small. An FLS shot number of between 300 and 600 (for example, 400) is an example of a first threshold value, an FLS shot number of between 50 and 300 (for example, 100) is an example of a second threshold value, and an FLS shot number of between 600 and 1800 (for example, 1000) is an example of a third threshold value. That is, in the present embodiment, the second threshold value is smaller than the first threshold value, and the first threshold value is smaller than the third threshold value. However, a magnitude relationship of the first threshold value, the second threshold value, and the third threshold is not limited to the previously mentioned example.
In addition, CR speed=60 ips is an example of a first speed, and CR speed=4 ips is an example of a second speed. That is, the second speed is slower than the first speed. Moreover, FLS voltage=24 V is an example of a first voltage, and FLS voltage=26 V is an example of a second voltage. That is, the second voltage is higher than the first voltage. Note that a drive voltage in a later-mentioned recording process is set to the first voltage. Furthermore, FLS number-of-times=1 is an example of a times, and FLS number-of-times=3 is an example of β times. That is, α<β. However, specific numerical values of CR speed, FLS voltage, and FLS number-of-times are not limited to the previously mentioned example.
Returning to
The raising process (S41) is a process in which the power supply section 110 boosts a drive voltage supplied to each of configuring elements of the printer 11, to an FLS voltage VF determined by the FLS condition determining process. The power supply section 110, for example, boosts a power supply voltage supplied from an external power supply, to the FLS voltage VF, by an unillustrated regulator circuit. Raising the power supply section 110 refers to, for example, storing a charge in an unillustrated storage element such as a condenser. Furthermore, after a charge corresponding to the FLS voltage VF has been stored in the storage element, the regulator circuit continues to apply the storage element with a voltage for maintaining the drive voltage.
However, when the drive voltage is suddenly raised, there is a possibility that the drive voltage during raising becomes unstable. Accordingly, the controller 130 boosts the drive voltage to a check voltage V1 by, for example, feedback control. Next, the controller 130, based on the drive voltage having reached the check voltage V1, boosts the drive voltage to a check voltage V2 by feedback control. In this way, raising is performed gradually by repeating a plurality of raising steps. That is, V1<V2< . . . <VF. As a result, fluctuation of the drive voltage during raising is suppressed.
Note that the closer the check voltages V1, V2, . . . come to the FLS voltage VF, the more finely they are set. As an example, when the FLS voltage VF=24 V, the check voltages are set to 20 V, 22 V, 23 V, 23.5 V, 23.75 V. As another example, when the FLS voltage VF=26 V, the check voltages are set to 20 V, 24 V, 25 V, 25.5 V, 25.75 V. Moreover, since a majority of processing time of the raising process is occupied by feedback control after the drive voltage has come close to the FLS voltage VF, no great difference occurs in execution time of the raising process, whichever of 24V, 26 V the FLS voltage VF is.
In addition, the controller 130 may execute the raising process in a state where the drive voltage has been applied to the recording head 39 by the power supply section 110. A “state where the drive voltage has been applied to the recording head 39” refers to a state where, for example, the drive voltage during raising is applied to the vibrating element of the recording head 39 by setting to a conductive state a switch element of a circuit from the power supply section 110 to the recording head 39. In other words, it may also be expressed as a state where ink is discharged from the nozzle 40 when the drive voltage during raising has reached 24 V. As a result, fluctuation of the drive voltage during raising can be further suppressed for the following reason.
First, generally, when a voltage applied to a circuit fluctuates, a rise time and a fall time of a voltage waveform become longer the larger a resistance component in said circuit is. That is, the larger the resistance component is, the smaller a change in voltage per unit time becomes. Moreover, in the circuit from the power supply section 110 to the vibrating element of the recording head 39, there exist resistance components of a transistor configuring the switch element, an output section outputting a drive signal, and so on. Accordingly, if from the power supply section 110 to the recording head 39 is configured as one circuit, then fluctuation of the drive voltage during raising can be more attenuated compared to when a break is made between the power supply section 110 and the recording head 39 to configure a single body circuit of the power supply section 110.
Moreover, a control circuit of the recording head 39 having the vibrating element can be regarded as a condenser having a certain electrostatic capacity. Moreover, this condenser repeats charging and discharging along with fluctuation of the applied drive voltage. As a result, since a high frequency component of voltage fluctuation can be removed, fluctuation of the drive voltage during raising can be further attenuated.
Furthermore, the raising process (S41) is typically executed at a timing when power supply of the multifunction peripheral 10 has been activated, or a timing when the power supply section 110 has been switched from the sleep state to the drive state. That is, when the drive voltage supplied by the power supply section 110 has already reached the FLS voltage VF, the raising process (S41) is sometimes omitted.
The uncapping process (S42) is a process in which the cap 71 is moved from the covering position to the separated position. That is, the controller 130 rotates the feed motor 101 to an extent of a predetermined rotation amount. Then, the rotational drive force of the feed motor 101 is transmitted to the cap shifter 71A via the switching mechanism 170 in the third state, whereby the cap 71 is moved from the covering position to the separated position. Moreover, the detection signal outputted from the cap sensor 123 changes from the high level signal to the low level signal before the cap 71 reaches the separated position, in other words, during execution of the uncapping process.
The second moving process (S43) includes a process in which the switching mechanism 170 is switched from the third state to the first state, and a process in which the carriage 23 that has been separated from the cap 71 is moved from the second position toward the first position. That is, the controller 130 moves the carriage 23 in the second position in the rightward orientation, and then moves it in the leftward orientation toward the first position. The controller 130, in step S43, causes the carriage 23 to reach a position leftward of the ink receiver 75, as depicted in
The jiggling process (S44, S45) is a process in which at least one of the feed motor 101 and the conveyance motor 102 is forward/reverse rotated in slight amounts, that is, a process in which forward rotation and reverse rotation are repeatedly performed in small amounts. In more detail, the controller 130 forward/reverse rotates both of the feed motor 101 and the conveyance motor 102 in small amounts when the switching mechanism 170 is in the third state (S44). As a result, surface pressure between the drive gear 172 and the driven gear 176 and surface pressure between the drive gear 173 and the driven gear 177 are released, hence meshing of each of the gears is smoothly released. In addition, the controller 130 forward/reverse rotates the feed motor 101 in small amounts when the switching mechanism 170 is switched to the first state (S45). As a result, the drive gear 172 and the driven gear 174 can be smoothly meshed. Note that the jiggling process may be only one of steps S44, S45.
Note that as depicted in
Furthermore, the controller 130 begins the process of step S43 at a timing when the detection signal of the cap sensor 123 has changed from the high level signal to the low level signal. That is, the controller 130 begins step S43 later than a start of steps S41, S42. In more detail, the controller 130 executes the process to move the carriage 23 at low speed in the leftward orientation and the process to move the carriage 23 rightwards of the second position, of step S43, in parallel with step S42. On the other hand, the controller 130 executes the process to move the carriage 23 in the leftward orientation toward the first position, of step S43, after finish of step S42.
Typically, the raising process has the longest execution time among the plurality of processes (S41 to S45) included in the first preparation process. Accordingly, as depicted in
Next, returning to
Then, the controller 130, based on having judged that the first preparation process has finished (S14: Yes), executes a second preparation process (S15). The second preparation process is a process not included in the first preparation process, of the process for putting the printer 11 in a state enabling execution of the recording process. As depicted in
The flushing process (S51) is a process in which the recording head 39 is caused to discharge ink toward the ink receiver 75, based on the execution conditions determined in the FLS condition determining process. That is, the controller 130, in step S51, in the process of moving the carriage 23 at the CR speed, applies the vibrating element with the FLS voltage VF to execute, to an extent of the FLS number-of-times, the flushing process causing the recording head 39 to discharge ink of the FLS shot number.
First, the controller 130, as a first time flushing process, moves the carriage 23 rightwards from the position depicted in
A discharge timing of ink is predetermined such that ink impacts on target positions on the guide plates 75B, 75C. Discharge timing of each of the nozzles 40 is specified by the pulse signal outputted from the carriage sensor 38, for example. In the present embodiment, as depicted by the broken lines in
Moreover, when FLS number-of-times=1, in a single time flushing process, the FLS shot number of ink droplets are discharged from each of the nozzles 40. On the other hand, when FLS number-of-times=3, in a single time flushing process, ⅓ of the FLS shot number of ink droplets are discharged from each of the nozzles 40. In more detail, the controller 130, in a single time flushing process, causes each of the nozzles 40 to discharge (FLS shot number/FLS number-of-times) of ink. That is, the controller 130, when executing a plurality of times of the flushing processes in step S51, causes each of the nozzles 40 to discharge the FLS shot number of ink droplets dispersed in the plurality of flushing processes.
Next, when FLS number-of-times=3, the controller 130, after having caused ink to be discharged from all of the nozzles 40 in the first time flushing process, stops the carriage 23 at the position depicted in
Furthermore, the controller 130, based on the second time flushing process having finished, executes a similar process to the first time flushing process, as a third time flushing process. That is, regardless of the FLS number-of-times determined in the FLS condition determining process, the controller 130, in a final flushing process, moves the carriage 23 in an orientation approaching the sheet facing area (that is, the rightward orientation).
Note that the controller 130 may further execute a non-discharge flushing process before the first time flushing process. The non-discharge flushing process is a process in which the vibrating element is vibrated to a degree insufficient for ink to be discharged from the nozzle 40. The non-discharge flushing process may be executed at any timing after finishing the raising process. That is, the non-discharge flushing process may be started before the recording command is received. Moreover, execution time of the non-discharge flushing process may be set such that, for example, the longer the elapsed time T is, the longer the execution time is set. As a result, in the flushing process, ink becomes more easily discharged from the nozzle 40.
The first moving process (S52) is a process in which the carriage 23 is moved to a detection position. The detection position is a position that the sheet 12 of all sizes (for example, A4, B4, L-type, and so on) supportable by the feed trays 20A, 20B passes, of the sheet facing area. When the sheet 12 is supported by the feed trays 20A, 20B in a state where a center of the sheet 12 in the main scanning direction has been positioned, the detection position may be a center of the sheet facing area in the main scanning direction.
In the first time flushing process when FLS number-of-times=1 or in the third time flushing process when FLS number-of-times=3, the controller 130, based on ink having been discharged from all of the nozzles 40, causes the carriage 23 which is in motion to reach the detection position without stopping the carriage 23. As an example, the controller 130, in the case of having executed the flushing process at CR speed=60 ips, executes the first moving process without changing the speed of the carriage 23. As another example, the controller 130, in the case of having executed the flushing process at CR speed=4 ips, executes the first moving process accelerating the carriage 23 to 24 ips. CR speed=24 ips is an example of a third speed. However, a specific example of the third speed is not limited to the previously mentioned example, and, for example, may be identical to the first speed (60 ips).
The step-down process (S53) is a process in which the drive voltage is stepped down from the second voltage to the first voltage. That is, the controller 130, in the case of having raised the drive voltage to the second voltage in step S41, executes the step-down process. On the other hand, the controller 130, in the case of having raised the drive voltage to the first voltage in step S41, skips execution of the step-down process. The controller 130 causes the regulator circuit to stop application of the voltage to the storage element. As a result, the charge that has been stored in the storage element self-discharges. Then, the controller 130, based on the charge that has been stored in the storage element having attained the first voltage, causes the regulator circuit to continuously apply to the storage element a voltage for maintaining the drive voltage at the first voltage.
The feed process (S54) is a process in which the sheet 12 supported by the feed tray 20A is fed by the feed section 15A to a position where the sheet 12 reaches the conveyance roller section 54. This feed process is executed in the case that the recording command indicates the feed tray 20A as a feed source of the sheet 12. The controller 130 forwardly rotates the feed motor 101, and after the detection signal of the resist sensor 120 changes from the low level signal to the high level signal, further forwardly rotates the feed motor 101 to an extent of a predetermined rotation amount. Then, by the rotational drive force of the feed motor 101 being transmitted to the feed roller 25A via the switching mechanism 170 in the first state, the sheet supported by the feed tray 20A is fed to the conveyance path 65.
The positioning process (S44) is a process in which the sheet 12 that has been brought to the conveyance roller section 54 by the feed process is conveyed in the conveyance orientation 16 by the conveyor to a position where an area on which an image will first be recorded (hereafter, sometimes described as “recording area”) can face the recording head 39. An initial recording area on the sheet 12 is indicated in the recording command. The controller 130, by forwardly rotating the conveyance motor 102, detects a leading edge of the sheet 12 by the media sensor 122, and further causes the sheet 12 that has been brought to the conveyance roller section 54 to be conveyed by the conveyor until the initial recording area indicated in the recording command faces the recording head 39.
Note that each of the processes (S51 to S55) included in the second preparation process cannot be started until after at least some of the plurality of processes included in the first preparation process have finished. The flushing process cannot be started until after the raising process, the uncapping process, and the second moving process have finished, but can be started even if the jiggling processing has not finished. On the other hand, the feed process cannot be started until after the jiggling process has finished, but can be started even if the raising process and the second moving process have not finished. Moreover, the first moving process cannot be started until after the flushing process has finished. Furthermore, the positioning process cannot be started until after the feed process and the first moving process have finished.
That is, the controller 130, based on having received the recording command and on the raising process, the uncapping process, and the second moving process having finished (S11: Recording Command & S14: Yes), begins the flushing process. Then, the controller 130, based on the flushing process having finished, begins the first moving process and the step-down process. That is, the controller 130 executes the first moving process and the step-down process in parallel. Moreover, the controller 130, based on having received the recording command and on the jiggling process having finished (S11: Recording Command & S14: Yes), begins the feed process. Then, the controller 130, based on the feed process and the first moving process having finished, begins the positioning process.
Moreover, although illustration of this is omitted, in the case that the recording command indicates the feed tray 20B as a feed source of the sheet 12, the controller 130 switches the switching mechanism 170 from the first state to the second state, based on the flushing process having finished. That is, the controller 130 moves the carriage 23 which is in motion in the flushing process further in the rightward orientation, whereby the lever 178 locked in the first locking section is locked in the second locking section. Then, the controller 130, based on having switched the switching mechanism 170 to the second state, moves the carriage 23 to the detection position. Furthermore, the controller 130, based on having switched the switching mechanism 170 to the second state, begins the feed process to feed the sheet 12 supported by the feed tray 20B.
Returning again to
That is, the controller 130 moves the carriage 23 from one end to the other end of the sheet facing area and causes the recording head 39 to discharge an ink droplet at a timing indicated by the recording command (S16). Next, the controller 130, based on existence of an image that should be recorded on the next recording area (S17: No), causes the conveyor to convey the sheet 12 to a position where the next recording area is faced by the recording head 39 (S18). The controller 130 repeatedly executes the processes of steps S16 to S18 until an image is recorded on all of the recording areas (S17: No). The controller 130, based on an image having been recorded on all of the recording areas (S17: Yes), causes the discharge roller section 55 to discharge the sheet 12 to the discharge tray 21 (S19).
Moreover, although illustration of this is omitted, the controller 130, based on a certain time having elapsed after the recording process (S16 to S19) has finished, moves the carriage 23 to the second position, changes the switching mechanism 170 to the third state, and moves the cap 71 to the covering position. Furthermore, the controller 130, based on a certain time having elapsed after moving the cap 71 to the covering position, switches the power supply section 110 from the drive state to the sleep state, and executes a so-called discharge flushing process. The discharge flushing process is a process in which the regulator circuit is caused to stop application of the voltage to the storage element, and the drive voltage is applied to vibrate the vibrating element. As a result, the charge that has been stored in the storage element is instantaneously discharged. Moreover, even if ink has been discharged from the nozzle 40 due to vibration of the vibrating element, said ink impacts on the inside of the cap 71, hence contamination of the sheet facing area can be suppressed.
In order to maintain image recording quality in the recording process, it is required that when the elapsed time T from the immediately preceding flushing process has lengthened, the amount of ink that should be discharged in the next flushing process is increased more compared to when the elapsed time T is short. Accordingly, as in the above-described embodiment, when the elapsed time T has lengthened, the CR speed is slowed, the FLS voltage is raised, and the FLS number-of-times is increased. In other words, when the FLS shot number has increased, the CR speed is slowed, the FLS voltage is raised, and the FLS number-of-times is increased. As a result, the ink required to maintain the image recording quality can be reliably discharged in the flushing process. Moreover, since the ink is discharged while moving the carriage 23 in the flushing process, FPOT can be reduced more compared to when the flushing process is executed in a state where the carriage 23 has been stopped.
Now, due to the CR speed being slowed, the ink amount dischargeable from each of the nozzles 40 in a single time flushing process increases. Moreover, in the final flushing process, the carriage 23 which is in motion is moved to the detection position without being stopped. Furthermore, when the flushing process has been executed at CR speed=4 ips, the first moving process is executed increasing the speed to CR speed=24 ips. As a result, execution time of the second preparation process can be further reduced.
Moreover, due to the FLS voltage being raised, a discharge interval of ink from each of the nozzles 40 can be shortened or large ink droplets can be discharged. Furthermore, when the FLS shot number is small, the flushing process is executed at the first voltage (24 V) which is the drive voltage during the recording process, hence the step-down process can be skipped. As a result, execution time of the second preparation process can be further reduced.
Furthermore, due to the FLS number-of-times being increased, the necessary ink amount can be dispersed in a plurality of times of flushing processes. As a result, elapsed time after ink being finally discharged can be smoothed between the nozzle 40 that initially discharged ink and the nozzle 40 that finally discharged ink. As a result, deterioration of image recording quality can be further suppressed. Moreover, when a plurality of times of flushing processes are executed in step S51, the ink amounts discharged in each of the flushing process need not be equal.
As an example, the controller 130 may set the ink amount discharged in the final flushing process larger than the ink amount discharged in the flushing processes prior to the final flushing process. As a result, since much ink is discharged at a timing temporally close to the recording process, the recording process can be executed in a state where there is little deteriorated ink. That is, image recording quality can be appropriately maintained.
As another example, the controller 130 may set the ink amount discharged in the final flushing process smaller than the ink amount discharged in the flushing processes prior to the final flushing process. Furthermore, the controller 130 may set the movement speed of the carriage in the final flushing process faster than the movement speed of the carriage in the flushing processes prior to the final flushing process. As a result, a process following the flushing process (that is, the first moving process) can be promptly executed, hence FPOT can be further reduced.
Moreover, a combination of FLS numbers-of-times is not limited to α=1, β=3, and may be, for example, α=2, β=4. The first time flushing process in this case may be executed on the carriage 23 which is in motion leftwards in the second moving process. That is, the controller 130 may finish the raising process and the non-discharge flushing process during execution of the second moving process and execute the first time flushing process at a timing when the carriage 23 has reached a certain position. Furthermore, in the flushing process when α≥2, the controller 130 should cause the recording head 39 to dispersedly discharge ink of the ink amount determined in the FLS condition determining process.
Moreover, the FLS number-of-times β may be variable based on the elapsed time T or the FLS shot number. For example, the controller 130, in the FLS condition determining process, determines the FLS shot number to be 1800 and determines the FLS number-of-times β to be 3 (or 4), based on the elapsed time T being T3 or more and less than T4. On the other hand, the controller 130 determines the FLS shot number to be 2400 and determines the FLS number-of-times β to be 5 (or 6), based on the elapsed time T being T4 or more. Note that T3<T4. That is, the controller 130 may set a value of β such that the longer the elapsed time T is or the larger the FLS shot number is, the larger the value of β is set.
Moreover, when raising the power supply section 110 in a state where the drive voltage has been applied to the recording head 39, fluctuation of the drive voltage during raising is suppressed. As a result, even if the number of raising steps is reduced, it can be suppressed that the drive voltage exceeds the FLS voltage VF. As a result, since execution time of the raising process is reduced, execution time of the first preparation process overall is reduced. Furthermore, since there is a lowering of possibility of the drive voltage exceeding the FLS voltage VF whereby ink is discharged from the recording head 39, mistaken discharge of ink in the sheet facing area is suppressed, even if the raising process and the second moving process are executed in parallel. Note that as another example of the raising process, the controller 130 may execute the raising process setting to a cut-off state the switch element of the circuit from the power supply section 110 to the recording head 39.
Moreover, in the step-down process according to the above-described embodiment, the drive voltage is stepped down by self-discharge of the storage element, hence even if the step-down process and the first moving process are executed in parallel, it can be suppressed that ink is mistakenly discharged onto the sheet facing area. Note that a specific example of the step-down process is not limited to the previously mentioned example, and the drive voltage may be stepped down by discharge flushing process, as when the power supply section 110 is switched from the drive state to the sleep state.
Note that the above-described embodiment described an example where together with increase in the FLS shot number, first, the CR speed, next, the FLS voltage, and finally, the FLS number-of-times, of the plurality of execution conditions of the flushing process, is changed. However, a change sequence of the execution conditions of the flushing process is not limited to the previously mentioned example. Moreover, the FLS shot number is not limited to being increased/decreased by the elapsed time T, and may be increased/decreased by another parameter. For example, image quality (for example, “fine”, “draft”) of the recording process may be designated by the user via an unillustrated operation panel. Moreover, the controller 130 may set the FLS shot number larger when high image quality “fine” has been designated than when low image quality “draft” has been designated. Moreover, head temperature may be monitored by a temperature sensor and the FLS shot number increased/decreased based on the head temperature. For example, when the head temperature is low, viscosity of ink may be judged to have risen, and the FLS shot number may be set larger. Alternatively, elapsed time after replacing the ink cartridge may be measured and the FLS shot number increased/decreased based on the elapsed time after replacing the ink cartridge. For example, it may be judged that when the elapsed time after replacing the ink cartridge has lengthened, there is a high possibility of ink having increased in viscosity, and the FLS shot number may be set larger.
Moreover, the controller 130 may change only some of the CR speed, the FLS voltage, and the FLS number-of-times, and set the remainder to a constant value. For example, the width in the main scanning direction of the ink receiver 75 may be set larger than the width in the main scanning direction of the nozzle surface. Moreover, the controller 130 may execute the flushing process in a state where the carriage 23 has been stopped at a position facing the ink receiver 75. In this case, the controller 130 may fix CR speed=0 and FLS number-of-times=1, and change only the FLS voltage based on the elapsed time T or FLS shot number.
Moreover, due to the above-described embodiment, the drive voltage is raised during movement of the cap 71 and the carriage 23, hence execution time of the first preparation process is reduced more compared to when the uncapping process, the second moving process, and the raising process are executed in turn. By executing the uncapping process, the second moving process, and the raising process included in the first preparation process at appropriate timings in this way, FPOT can be further reduced.
Moreover, due to the above-described embodiment, the first preparation process is executed adopting the preceding command as a trigger, hence FPOT can be reduced more compared to when the first preparation process is executed after receiving the recording command. Moreover, in the first preparation process, the uncapping process, the second moving process, and the jiggling process are executed in parallel with the raising process, whereby execution time of the first preparation process can be reduced more compared to when each of the processes is executed in turn.
On the other hand, due to the above-described embodiment, the flushing process is executed after the recording command has been received, hence the standby time from the flushing process finishing to the recording process being started can be shortened. That is, deterioration of image recording quality due to ink in the nozzle drying, can be suppressed. By executing the first preparation process and the second preparation process at appropriate timings in this way, FPOT can be reduced and deterioration of image recording quality can be suppressed.
Number | Date | Country | Kind |
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2016-082662 | Apr 2016 | JP | national |
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Number | Date | Country | |
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20170297341 A1 | Oct 2017 | US |