JP2023112881A - Ink jet printer - Google Patents

Abstract

To provide an ink jet printer which has little burden to a user when remounting a waste liquid tank after disposing ink of the waste liquid tank.SOLUTION: An ink jet printer 10 includes: a waste liquid tank detection sensor 45 which detects whether or not a waste liquid tank 41 is mounted at a prescribed mounting position; and a computer 50. The computer 50 has a waste liquid count section 61 for counting an amount of ink discharged from an ink head 22 to a cap 31 as a waste liquid count value, a storage section 62 for storing the waste liquid count value, a determination section 63 for determining whether or not the waste liquid tank 41 is remounted at the mounting position on the basis of a change in output of the waste liquid tank detection sensor 45, and an initialization section 64 which initializes the waste liquid count value stored in the storage section 62 when determining that the waste liquid tank 41 is remounted.SELECTED DRAWING: Figure 7

Description

The present invention relates to an inkjet printer with a waste liquid tank.

2. Description of the Related Art In an inkjet printer, ink is discharged from an ink head for maintenance of nozzles of the ink head, etc., in addition to printing. The discharged ink is collected in the waste liquid tank. When the waste liquid tank becomes full, the user needs to take out the waste liquid tank, discard the ink, and remount the empty waste liquid tank.

For example, as disclosed in Japanese Unexamined Patent Application Publication No. 2002-100000, there is known an inkjet printer capable of ascertaining the amount of ink in a waste liquid tank. The inkjet printer recognizes the amount of ink in the waste liquid tank based on the waste liquid count value that indicates the amount of waste ink. The ink jet printer is equipped with a computer that manages the maintenance operation of the ink head. The computer counts the waste liquid count value based on the amount of ink discharged during maintenance operations or the like.

In the inkjet printer disclosed in Patent Document 1, when it detects that the waste liquid tank is full, it displays an image prompting replacement of the waste liquid tank on the display screen. The user who sees this image takes out the full waste liquid tank, discards the ink from the waste liquid tank, and mounts the empty waste liquid tank again. Then, the user initializes the waste liquid count value by operating the operation panel or the like.

JP 2018-161838 A

In the inkjet printer, the user must initialize the waste liquid count value by operating the operation panel or the like every time an empty waste liquid tank is installed. Such an operation has been a burden on the user.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and an object thereof is to provide an inkjet printer that reduces the burden on the user when the waste liquid tank is remounted after the ink in the waste liquid tank has been discarded.

An inkjet printer according to the present invention comprises an ink head for ejecting ink, an ink receiving member for receiving ink discharged from the ink head, a waste liquid tank for collecting ink from the ink receiving member, and a predetermined liquid tank. A waste liquid tank detection sensor for detecting whether or not the ink head is mounted at the mounting position, and a computer communicably connected to the ink head and the waste liquid tank detection sensor. The computer includes a waste liquid count unit that counts the amount of ink discharged from the ink head to the ink receiving member as a waste liquid count value, a storage unit that stores the waste liquid count value, and an output of the waste liquid tank detection sensor. a determination unit that determines whether or not the waste liquid tank has been remounted at the mounting position based on the change; and if the determination unit determines that the waste liquid tank has been remounted, the waste liquid stored in the storage unit. and an initialization unit that initializes the count value.

According to the inkjet printer described above, after the waste liquid tank filled with ink is removed from the installation position and the ink is discarded, the output of the waste liquid tank detection sensor changes when the empty waste liquid tank is installed again in the installation position. . Based on the change in the output of this waste liquid tank detection sensor, it is determined whether or not the waste liquid tank has been reattached. When it is determined that the waste liquid tank has been reattached, the initialization section of the computer initializes the waste liquid count value. Therefore, when the user reattaches the waste liquid tank, the waste liquid count value is automatically initialized. After remounting the waste liquid tank, the user does not need to operate the operation panel or the like to initialize the waste liquid count value. Therefore, according to the inkjet printer described above, the burden on the user when the waste liquid tank is remounted after the ink in the waste liquid tank has been discarded is reduced.

According to the present invention, it is possible to provide an inkjet printer that reduces the burden on the user when the waste liquid tank is remounted after the ink in the waste liquid tank has been discarded.

1 is a front view of an inkjet printer according to one embodiment; FIG. It is a figure showing the structure of a cleaning mechanism. FIG. 4 is a front view of the waste liquid mechanism when the waste liquid tank is in the mounting position; FIG. 4 is a front view of the waste liquid mechanism when the waste liquid tank is removed; It is a block diagram of a computer. It is a functional block diagram of a computer. 4 is a functional block diagram of a determination unit; FIG. 7 is a flowchart showing an example of processing related to initialization of a waste liquid count value; 9 is a flow chart showing another example of processing related to initialization of the waste liquid count value.

An inkjet printer (hereinafter simply referred to as "printer") according to an embodiment of the present invention will be described below with reference to the drawings. As used herein, the term "inkjet printer" refers to a printing method using conventionally known inkjet technology, such as a continuous method such as a binary deflection method or a continuous deflection method, or various on-demand methods such as a thermal method or a piezoelectric element method. Refers to general printers that use

FIG. 1 is a front view of the printer 10. FIG. In the following description, left, right, top, and bottom refer to left, right, top, and bottom as seen from the user in front of the printer 10, and the direction closer to the user from the printer 10 is the front. , the farther side is the rear side. Symbols F, Rr, L, R, U, and D in the drawings represent front, rear, left, right, up, and down, respectively. Symbols X, Y, and Z in the drawings represent the front-back direction, the left-right direction, and the up-down direction, respectively. However, this is merely a direction for convenience of explanation, and does not limit the installation form of the printer 10 in any way.

The printer 10 according to the present embodiment sequentially moves the roll-shaped recording medium 5 forward, and ejects ink from each of the plurality of ink heads 22 mounted on the carriage 19 that moves in the left-right direction. 5 to print the image. The printer 10 includes a main body 11 , legs 12 supporting the main body 11 , a touch panel 13 , a platen 16 and a computer 50 .

The printer 10 includes a carriage 19 and a head moving mechanism 20 that moves the carriage 19 in the left-right direction. The head moving mechanism 20 includes, for example, a guide rail 20a extending in the left-right direction, a pulley 20b provided on the left side of the guide rail 20a, a pulley 20c provided on the right side of the guide rail 20a, an endless belt 20d, and a carriage motor 20e. Belt 20d is wound around pulley 20b and pulley 20c. Carriage 19 is fixed to belt 20d. When the carriage motor 20e is driven, the pulley 20b rotates and the belt 20d runs between the pulleys 20b and 20c. As a result, the carriage 19 moves in the left-right direction.

Printer 10 includes a media transport mechanism 25 . The medium transport mechanism 25 is a mechanism that moves the recording medium 5 placed on the platen 16 in the front-rear direction. The medium transport mechanism 25 includes a grit roller 25a, a pinch roller 25b, and a feed motor 25c. When the feed motor 25c is driven to rotate the grit roller 25a while the recording medium 5 is sandwiched between the grit roller 25a and the pinch roller 25b, the recording medium 5 is conveyed in the front-rear direction.

The touch panel 13 serves both as an input device and a display device, and is configured to receive user's operations and display various information about the printer 10 . In this embodiment, the touch panel 13 is an example of a display device. The touch panel 13 is provided on the right front surface of the main body 11 . However, the position of the touch panel 13 is not particularly limited.

The ink head 22 has a downwardly opening nozzle 22a (see FIG. 2). The ink head 22 is configured to eject ink from nozzles 22a toward the recording medium 5 during printing. The ink head 22 is electrically connected with the computer 50 . The computer 50 is communicably connected to the ink head 22 . A computer 50 controls the ejection of ink from the nozzles 22a.

The printer 10 has a cleaning mechanism 30 . The cleaning mechanism 30 is configured to remove adhering substances (for example, dust, dirt, thickened ink, hardened ink, etc.) adhering to the nozzles 22a of the ink head 22 . The cleaning mechanism 30 is arranged at a home position on the right side of the platen 16 . The home position is a position where the carriage 19 stands by when not printing. In this embodiment, the cleaning mechanism 30 includes a wiping mechanism 26 and a capping mechanism 27. As shown in FIG. The wiping mechanism 26 has a wiper 26a, a wiper moving mechanism 26b for moving the wiper 26a, and a wiper cleaning tank (not shown). When the wiper 26a moves in the front-rear direction, the wiper 26a wipes the lower surface of the ink head 22. As shown in FIG. The wiper 26a is immersed in the cleaning liquid in the wiper cleaning tank to wash off the adhering ink. The capping mechanism 27 includes a plurality of caps 31 , a cap moving mechanism 32 that moves the caps 31 , and a plurality of suction pumps 33 . The suction pump 33 is driven when the cap 31 is attached to the ink head 22 and sucks ink from the ink head 22 . Cleaning mechanism 30 is electrically connected to and controlled by computer 50 .

FIG. 2 is a schematic diagram showing a configuration of part of the cleaning mechanism 30. As shown in FIG. In FIG. 2, illustration of the wiping mechanism 26 is omitted. As described above, the cleaning mechanism 30 includes the cap 31 , which is an example of an ink receiving member, the cap moving mechanism 32 and the suction pump 33 . The cleaning mechanism 30 also includes a waste liquid path 34 .

The cap 31 has, for example, a bottomed box shape with an open top. The cap 31 is configured to cover the nozzles 22 a of the ink head 22 . A closed space is thereby formed between the nozzle 22 a and the cap 31 . The cap 31 is movable in the vertical direction Z by a cap moving mechanism 32 and is detachably attached to the lower surface of the ink head 22 .

The waste liquid path 34 is a flow path that guides the ink discharged to the cap 31 (hereinafter also referred to as waste liquid) from the cap 31 to the waste liquid mechanism 40 . A funnel 35 (see FIG. 3) is connected to the lower end of the waste liquid path 34 . The waste liquid that has passed through the waste liquid path 34 is discharged from the funnel 35 to the waste liquid tank 41 and collected in the waste liquid tank 41 . A suction pump 33 is provided in the middle of the waste liquid path 34 . A suction pump 33 is connected to the bottom surface of the cap 31 . The suction pump 33 sucks ink or the like from the nozzle 22a when the cap 31 is attached to the nozzle 22a. The suction pump 33 sends the ink or the like accumulated in the cap 31 to the waste liquid mechanism 40 . Although not particularly limited, the suction pump 33 is, for example, a vacuum pump. The suction pump 33 is electrically connected to the computer 50 and controlled by the computer 50 .

When cleaning the nozzles 22a of the ink head 22, the suction pump 33 is driven with the cap 31 attached to the nozzles 22a. As a result, ink, deposits, and the like are sucked out from the nozzle 22 a through the cap 31 and accumulated in the cap 31 . Further, when the ink head 22 is driven with the cap 31 attached to the nozzle 22 a , ink and adhering matter are discharged into the cap 31 and accumulated in the cap 31 . The cap 31 communicates with the waste liquid mechanism 40 via the waste liquid path 34 . Ink and deposits collected in the cap 31 are sent to the waste liquid mechanism 40 through the waste liquid path 34 .

The waste liquid mechanism 40 is a mechanism for collecting waste liquid generated by cleaning operations or the like. As shown in FIG. 1 , the waste liquid mechanism 40 is arranged below the cleaning mechanism 30 . FIG. 3 is a side view of the drainage mechanism 40. FIG. The waste liquid mechanism 40 includes a waste liquid tank 41, a tray 43 on which the waste liquid tank 41 is placed, a base member 42 that displaceably supports the tray 43, a spring 44, a waste liquid tank detection sensor 45, and a first waste liquid amount detection sensor. 46 and a second waste liquid amount detection sensor 47 .

The base member 42 has a horizontal portion 42A extending in the front-rear direction and a vertical portion 42B extending vertically from the front portion of the horizontal portion 42A. The funnel 35 is fixed to the main body 11 of the printer 10 in a suspended state.

The waste liquid tank 41 is a container that collects and stores ink from the cap 31 . The waste liquid tank 41 is configured to collect ink from the cap 31 through the waste liquid path 34 . The waste liquid tank 41 is placed on the tray 43 .

The tray 43 is configured to move up and down according to the weight of the ink in the waste liquid tank 41 . In this embodiment, the tray 43 is rotatably supported by the shaft 49 with respect to the lateral portion 42A of the base member 42. As shown in FIG. As the amount of ink in the waste liquid tank 41 increases, the tray 43 rotates counterclockwise in FIG.

A first striker 48 is fixed to the tray 43 . A lower end of the spring 44 is connected to a first striker 48 . The upper end of spring 44 is connected to vertical portion 42B of base member 42 via bracket 42C. A spring 44 urges the tray 43 supporting the waste liquid tank 41 upward via a first striker 48 .

The funnel 35 is attached with a waste liquid receiver 36 for preventing dripping. The waste liquid receiver 36 is rotatably suspended from the funnel 35 by a shaft 37 . The waste liquid receiver 36 has an arm 36A rotatably supported by a shaft 37 and a plate 36B extending perpendicularly to the arm 36A (extending to the back side of the page of FIG. 3). As shown in FIG. 3, when the waste liquid tank 41 is placed on the tray 43, the waste liquid receiver 36 is pushed by the waste liquid tank 41, so that the plate 36B is removed from the position directly below the discharge hole 35a of the funnel 35. On the other hand, when the waste liquid tank 41 is not placed on the tray 43 as shown in FIG. Therefore, when the waste liquid tank 41 is not placed on the tray 43 , even if ink drips from the discharge hole 35 a of the funnel 35 , the ink is received by the plate 36 B of the waste liquid receiver 36 . Therefore, it is possible to prevent the tray 43 and the like from being stained with ink.

A second striker 38 is fixed to the waste liquid receiver 36 . The second striker 38 is rotatable around the shaft 37 together with the waste liquid receiver 36 .

The waste liquid tank detection sensor 45 is a sensor that detects whether or not the waste liquid tank 41 is mounted at a predetermined mounting position. Here, the predetermined mounting position is the position where the waste liquid tank 41 collects the ink from the cap 31 . In this embodiment, the mounting position is the position shown in FIG. position. Although the form of the waste liquid tank detection sensor 45 is not particularly limited, it consists of a light transmission type optical sensor here. Although not shown, the waste liquid tank detection sensor 45 has a light emitting element and a light receiving element. When the light receiving element receives the light from the light emitting element, the waste liquid tank detection sensor 45 is turned off. When the light receiving element does not receive the light from the light emitting element, the waste liquid tank detection sensor 45 is turned on.

As shown in FIG. 3, when the waste liquid tank 41 is at the mounting position, the light of the waste liquid tank detection sensor 45 is not blocked by the second striker 38, and the waste liquid tank detection sensor 45 is turned off. On the other hand, as shown in FIG. 4, when the waste liquid tank 41 is not at the mounting position, the light of the waste liquid tank detection sensor 45 is blocked by the second striker 38, and the waste liquid tank detection sensor 45 is turned ON. Therefore, based on ON/OFF of the waste liquid tank detection sensor 45, it is possible to detect whether or not the waste liquid tank 41 is mounted at the mounting position.

In the following description, the predetermined full state of the waste liquid tank 41 is referred to as "end state", and the state in which the waste liquid tank 41 is close to the predetermined full state is referred to as "near end state". The end state may be, for example, a state in which the amount of ink in the waste liquid tank 41 is approximately 70% by volume or more, typically 80% by volume or more, for example 90% by volume or more, of the total volume of the waste liquid tank 41 . The near-end state is a state in which a smaller amount of ink is collected in the waste liquid tank 41 than in the end state. state. Hereinafter, a state in which the amount of ink in the waste liquid tank 41 exceeds the first threshold and is equal to or less than the second threshold is referred to as a near-end state, and a state in which the amount of ink in the waste liquid tank 41 exceeds the second threshold is referred to as an end state. . Note that the first threshold and the second threshold are predetermined values, and the second threshold is greater than the first threshold.

The first waste liquid amount detection sensor 46 is a sensor that detects a near-end state. That is, the first waste liquid amount detection sensor 46 is a sensor that detects whether or not the amount of ink in the waste liquid tank 41 exceeds the first threshold value. The second waste liquid amount detection sensor 47 is a sensor that detects the end state. That is, the second waste liquid amount detection sensor 47 is a sensor that detects whether or not the amount of ink in the waste liquid tank 41 exceeds the second threshold. Although the form of the first waste liquid amount detection sensor 46 and the second waste liquid amount detection sensor 47 is not particularly limited, here, like the waste liquid tank detection sensor 45, they are made of optical transmission type sensors.

As described above, the tray 43 supports the waste liquid tank 41 and is rotatable around the shaft 49 . As the amount of ink in the waste liquid tank 41 increases, the tray 43 rotates counterclockwise in FIG. Since the first striker 48 is fixed to the tray 43, the first striker 48 is displaced downward when the amount of ink in the waste liquid tank 41 increases.

In this embodiment, when the waste liquid tank 41 is not in the near-end state and not in the end state, both the light from the first waste liquid amount detection sensor 46 and the light from the second waste liquid amount detection sensor 47 are blocked by the first striker 48. be done. Therefore, both the first waste liquid amount detection sensor 46 and the second waste liquid amount detection sensor 47 are turned ON. Therefore, it can be detected that the waste liquid tank 41 is not in the near end state and not in the end state based on the fact that the first waste liquid amount detection sensor 46 and the second waste liquid amount detection sensor 47 are ON.

When the waste liquid tank 41 is in the near-end state, the light from the first waste liquid amount detection sensor 46 is not blocked by the first striker 48 and the light from the second waste liquid amount detection sensor 47 is blocked by the first striker 48 . Therefore, the first waste liquid amount detection sensor 46 is turned off, and the second waste liquid amount detection sensor 47 is turned on. Therefore, the near-end state of the waste liquid tank 41 can be detected based on the fact that the first waste liquid amount detection sensor 46 is turned off and the second waste liquid amount detection sensor 47 is turned on.

When the waste liquid tank 41 is in the end state, neither the light from the first waste liquid amount detection sensor 46 nor the light from the second waste liquid amount detection sensor 47 is blocked by the first striker 48 . Therefore, both the first waste liquid amount detection sensor 46 and the second waste liquid amount detection sensor 47 are turned off. Therefore, the end state of the waste liquid tank 41 can be detected based on the fact that the first waste liquid amount detection sensor 46 and the second waste liquid amount detection sensor 47 are OFF.

In this embodiment, the computer 50 of the printer 10 can calculate the amount of ink in the waste liquid tank 41 based on the amount of ink ejected from the ink head 22 and the drive amount of the suction pump 33 during the cleaning operation. The amount of discharged ink can be displayed on the touch panel 13 as the amount of waste liquid. As shown in FIG. 5, a computer 50 includes an interface (I/F) 51 for receiving print data and the like from an external device, a central processing unit (CPU) 52 for executing control program instructions, and a It has a ROM 53 storing a program, a RAM 54 used as a working area for expanding the program, and another memory 55 storing other programs and various data. In this embodiment, the computer 50 has a microcomputer arranged inside the main body 11 of the printer 10 and is a dedicated computer for the printer 10 . However, the computer 50 may be a general-purpose personal computer or the like that is arranged outside the main body 11 and communicably connected to the printer 10 by wire or wirelessly. The form of the computer 50 is not particularly limited.

FIG. 6 is a functional block diagram of the computer 50. As shown in FIG. The computer 50 includes a waste liquid count section 61 , a storage section 62 , a determination section 63 , an initialization section 64 , a display section 65 and a warning section 66 . The computer 50 functions as a waste liquid counting unit 61 , a storage unit 62 , a determination unit 63 , an initialization unit 64 , a display unit 65 and a warning unit 66 by the CPU 52 executing programs.

Ink is discharged from the ink head 22 to the cap 31 during the cleaning operation. The ink discharged to the cap 31 is collected in the waste liquid tank 41 through the waste liquid path 34 . It is estimated that the amount of ink discharged to the cap 31 is equal to the amount of ink in the waste liquid tank 41 . Therefore, the amount of ink in the waste liquid tank 41 can be estimated based on the amount of ink discharged to the cap 31 . For example, if the amount of ink discharged to the cap 31 in one cleaning operation is predetermined, the amount of ink in the waste liquid tank 41 can be estimated from the number of cleaning operations. Alternatively, the amount of ink in the waste liquid tank 41 may be estimated from the number of times the suction pump is driven. The waste liquid count unit 61 counts the amount of ink discharged during the cleaning operation as a waste liquid count value. That is, the waste liquid count unit 61 counts the amount of ink discharged from the ink head 22 to the cap 31 as a waste liquid count value.

The storage unit 62 stores the waste liquid count value. When the waste liquid tank 41 is considered empty, the waste liquid count value is initialized. That is, the waste liquid count value is returned to zero. As the amount of ink discharged during the cleaning operation increases, the waste liquid count value is added by the waste liquid counting unit 61 , and the added waste liquid count value is stored in the storage unit 62 .

The determination unit 63 determines whether or not the waste liquid tank 41 has been reattached to the attachment position based on the change in the output of the waste liquid tank detection sensor 45 . Details of the determination made by the determination unit 63 will be described later.

The initialization unit 64 initializes the waste liquid count value stored in the storage unit 62 when the determination unit 63 determines that the waste liquid tank 41 has been remounted at the mounting position.

The display unit 65 causes the touch panel 13 to display the waste liquid amount based on the waste liquid count value stored in the storage unit 62 . The waste liquid count value has a correlation with the amount of ink in the waste liquid tank 41, and is an indicator of the amount of ink. The information displayed on the touch panel 13 by the display unit 65 is not particularly limited as long as it has a unique correlation with the amount of ink in the waste liquid tank 41 . The display unit 65 may display, for example, the waste liquid count value itself, the amount of ink (waste liquid amount) in the waste liquid tank 41, or the ratio of the volume of ink to the volume of the waste liquid tank 41. may

In addition, when the near-end state is reached, the display unit 65 causes the touch panel 13 to display a notification prompting disposal of the ink in the waste liquid tank 41 . Specifically, when the first waste liquid amount detection sensor 46 detects that the amount of ink in the waste liquid tank 41 exceeds the first threshold value, the display unit 65 displays a notification prompting disposal of the ink in the waste liquid tank 41 on the touch panel. 13.

When the end state is reached, the warning unit 66 prohibits the cleaning operation in order to prevent the ink from overflowing from the waste liquid tank 41, and also displays a warning on the touch panel 13 notifying that the ink in the waste liquid tank 41 needs to be discarded. Let Specifically, when the second waste liquid amount detection sensor 47 detects that the amount of ink in the waste liquid tank 41 exceeds the second threshold value, the warning unit 66 prohibits the cleaning operation and issues a warning to the touch panel 13 . display.

Next, a determination method performed by the determination unit 63 will be described. When the user sees a notice prompting to discard the ink in the waste liquid tank 41 or a warning that the ink needs to be discarded, the user removes the waste liquid tank 41 from the tray 43 and discards the ink in the waste liquid tank 41 . Then, the empty waste liquid tank 41 is placed on the tray 43 again. That is, the user removes the waste liquid tank 41 from the mounting position, discharges the ink from the waste liquid tank 41, and then remounts the empty waste liquid tank 41 to the mounting position.

When the user removes the waste liquid tank 41 from the mounting position, the waste liquid tank detection sensor 45 is switched from OFF to ON. Further, when the user reattaches the waste liquid tank 41 to the attachment position, the waste liquid tank detection sensor 45 is switched from ON to OFF. Therefore, the determination unit 63 can determine whether or not the waste liquid tank 41 has been reattached based on the fact that the waste liquid tank detection sensor 45 has been switched from OFF to ON or from ON to OFF. . That is, the determination unit 63 can determine whether or not the waste liquid tank 41 has been reattached based on the change in the output of the waste liquid tank detection sensor 45 . When the determination unit 63 determines that the waste liquid tank 41 has been reattached, the initialization unit 64 initializes the waste liquid count value stored in the storage unit 62 .

When the ink in the waste liquid tank 41 is discarded and an empty waste liquid tank 41 is remounted, the waste liquid tank detection sensor 45 is switched from OFF to ON and then from ON to OFF. Determination based on the change from OFF to ON of the waste liquid tank detection sensor 45 and the subsequent change from ON to OFF is particularly preferable because reattachment of the waste liquid tank 41 can be determined with high accuracy. . Therefore, in this embodiment, as shown in FIG. 7, the determination section 63 has a first state transition determination section 63A and a second state transition determination section 63B. Based on a change in the output of the waste liquid tank detection sensor 45, the first state transition determination section 63A determines whether or not there is a first state transition in which the waste liquid tank 41 is in the mounted position to not in the mounted position. The second state transition determination section 63B determines whether or not there is a second state transition in which the waste liquid tank 41 changes from the state in which the waste liquid tank 41 is not in the mounting position to the state in which it is in the mounting position, based on the change in the output of the waste liquid tank detection sensor 45 . After the first state transition determination unit 63A determines that the first state transition has occurred, the determination unit 63 determines that the waste liquid tank 41 is discharged when the second state transition determination unit 63B determines that the second state transition has occurred. It is configured to determine that it has been remounted.

By the way, as shown in FIGS. 3 and 4, the waste liquid tank detection sensor 45 is turned ON/OFF based on whether or not the second striker 38 blocks light. swing to. When the user removes the waste liquid tank 41 from the mounting position or mounts it to the mounting position, the second striker 38 swings, and the waste liquid tank detection sensor 45 is repeatedly turned on and off in a short period of time. Sometimes. Moreover, the waste liquid tank detection sensor 45 may be repeatedly turned on and off in a short period of time due to vibration caused by movement of the carriage 19 during printing. That is, so-called chattering may occur. As a result, the determination unit 63 may erroneously determine that the second state transition occurred after the first state transition.

Therefore, in the present embodiment, after the waste liquid tank 41 transitions from the state in which the waste liquid tank 41 is in the mounting position to the state in which it is not in the mounting position, the state in which the waste liquid tank 41 is not in the mounting position is maintained for a predetermined first time. It is configured to determine that the first state transition has occurred if the state continues for a period of time. After the waste liquid tank 41 transitions from the state in which the waste liquid tank 41 is not in the mounting position to the state in which it is in the mounting position, the second state transition determination unit 63B determines whether the state in which the waste liquid tank 41 is in the mounting position continues for a predetermined second time. It is configured to determine that there has been a two-state transition. Although the first time and the second time may be different, they are set to the same time here. The first time and the second time can be set appropriately, and may be set to 2 seconds, for example.

Here, a signal output when the waste liquid tank detection sensor 45 is OFF is referred to as an OFF signal, and a signal output when the waste liquid tank detection sensor 45 is ON is referred to as an ON signal. The OFF signal is, for example, a signal with a voltage of zero or a first voltage. Strictly speaking, when the voltage is zero, the waste liquid tank detection sensor 45 does not output a signal. We will regard it as a thing. The ON signal is, for example, a signal with a second voltage higher than the first voltage. In this embodiment, the OFF signal is an example of the "first signal" and the ON signal is an example of the "second signal". The first state transition determining section 63A has a first state transition when the output received from the waste liquid tank detection sensor 45 switches from the OFF signal to the ON signal and continues to receive the ON signal for a predetermined first period of time. It is configured to determine that The second state transition determining section 63B has a second state transition when the output received from the waste liquid tank detection sensor 45 switches from the ON signal to the OFF signal and continues to receive the OFF signal for a predetermined second period of time. It is configured to determine that This makes it possible to more reliably prevent erroneous determinations of the first state transition and the second state transition.

FIG. 8 is a flow chart showing the flow of processing related to initialization of the waste liquid count value according to this embodiment. In this embodiment, when the output of the waste liquid tank detection sensor 45 switches from the OFF signal to the ON signal (step S1), it is determined whether or not the first time has elapsed since the output of the waste liquid tank detection sensor 45 became the ON signal. is determined (step S2). If the determination result in step S2 is YES, it is determined that the first state transition has occurred. After that, when the output of the waste liquid tank detection sensor 45 switches from the ON signal to the OFF signal (step S3), it is determined whether or not the second time has elapsed since the output of the waste liquid tank detection sensor 45 became the OFF signal. (Step S4). If the determination result in step S4 is YES, it is determined that the second state transition has occurred. Then, it is determined that the waste liquid tank 41 has been reattached (step S5), and the waste liquid count value is initialized (step S6).

By the way, after the near-end state or the end state, the user may remove the waste liquid tank 41 from the tray 43 and put it back on the tray 43 without discarding the waste liquid. In this case, a notice or warning prompting the disposal of the ink is displayed on the touch panel 13, so there is no particular problem, but it is not preferable to initialize the waste liquid count value.

Therefore, in the present embodiment, when the determining unit 63 determines that the waste liquid tank 41 has been reattached and the waste liquid tank 41 is neither near-end state nor end state, the initialization unit 64 It is configured to initialize the waste count value. In the present embodiment, the state that is neither the near-end state nor the end state means that the amount of ink in the waste liquid tank 41 is equal to or less than the first threshold. In the initialization unit 64, the determination unit 63 determines that the waste liquid tank 41 has been reattached, and the first waste liquid amount detection sensor 46 detects that the amount of ink in the waste liquid tank 41 is equal to or less than the first threshold value. , the waste liquid count value stored in the storage unit 62 is initialized. This can prevent the waste liquid count value from being initialized when the user reattaches the waste liquid tank 41 without discarding the waste liquid after the near-end state or the end state.

FIG. 9 is a flow chart showing the flow of the above process. In this embodiment, it is determined whether or not the amount of ink in the waste liquid tank 41 exceeds the first threshold (step S11). A notification prompting is displayed on the touch panel 13 (step S12). Next, it is determined whether or not it is determined that the waste liquid tank 41 has been reattached, and whether or not the amount of ink in the waste liquid tank 41 is equal to or less than the first threshold value (step S13). Then, when both judgment results in step S13 are YES, the waste liquid count value is initialized (step S14).

Next, various effects provided by the printer 10 according to this embodiment will be described.

As described above, the printer 10 according to this embodiment includes the ink head 22 that ejects ink, the cap 31 that receives the ink discharged from the ink head 22, the waste liquid tank 41 that collects the ink from the cap 31, and the waste liquid A waste liquid tank detection sensor 45 for detecting whether or not the tank 41 is mounted at a predetermined mounting position, and a computer 50 communicably connected to the ink head 22 and the waste liquid tank detection sensor 45 are provided. The computer 50 includes a waste liquid count section 61 that counts the amount of ink discharged from the ink head 22 to the cap 31 as a waste liquid count value, a storage section 62 that stores the waste liquid count value, and a change in the output of the waste liquid tank detection sensor 45. and when the determination unit 63 determines that the waste liquid tank 41 has been remounted, the waste liquid count stored in the storage unit 62. and an initialization unit 64 for initializing values.

According to the printer 10 of the present embodiment, after removing the waste liquid tank 41 filled with ink from the installation position and discarding the ink, when the empty waste liquid tank 41 is installed again at the installation position, the waste liquid tank detection sensor 45 is detected. changes, and based on the change in output, it is determined whether the waste liquid tank 41 has been reattached. Then, when it is determined that the waste liquid tank 41 has been reattached, the computer 50 initializes the waste liquid count value. Therefore, when the user reattaches the waste liquid tank 41, the waste liquid count value is automatically initialized. After remounting the waste liquid tank 41, the user does not need to operate the operation panel or the like to initialize the waste liquid count value. Therefore, according to the printer 10 of the present embodiment, it is possible to reduce the burden on the user when the waste liquid tank 41 is reattached after the ink in the waste liquid tank 41 is discarded.

Further, according to the present embodiment, the determination section 63 has a first state transition determination section 63A and a second state transition determination section 63B. Based on a change in the output of the waste liquid tank detection sensor 45, the first state transition determination section 63A determines whether or not there is a first state transition in which the waste liquid tank 41 is in the mounted position to not in the mounted position. The second state transition determination section 63B determines whether or not there is a second state transition in which the waste liquid tank 41 changes from the state in which the waste liquid tank 41 is not in the mounting position to the state in which it is in the mounting position, based on the change in the output of the waste liquid tank detection sensor 45 . After the first state transition determination unit 63A determines that the first state transition has occurred, the determination unit 63 determines that the waste liquid tank 41 is discharged when the second state transition determination unit 63B determines that the second state transition has occurred. It is configured to determine that it has been remounted.

As described above, according to the present embodiment, after it is determined that there is the first state transition in which the waste liquid tank 41 is in the mounting position to the state in which the waste liquid tank 41 is not in the mounting position, the state in which the waste liquid tank 41 is not in the mounting position is determined. It is determined that the waste liquid tank 41 has been remounted when it is determined that there has been a second state transition from the state to the mounting position. Therefore, it is possible to accurately determine that the waste liquid tank 41 has been reattached to the attachment position.

Further, according to the present embodiment, the first state transition determination section 63A continues to receive the ON signal for the predetermined first time after the output received from the waste liquid tank detection sensor 45 is switched from the OFF signal to the ON signal. is configured to determine that the first state transition has occurred when the In addition, the second state transition determination section 63B changes the output received from the waste liquid tank detection sensor 45 from the ON signal to the OFF signal, and when the OFF signal continues to be received for a predetermined second time period, the second state transition determination section 63B enters the second state. It is configured to determine that there has been a transition. Therefore, the presence/absence of the first state transition and the presence/absence of the second state transition can be determined without error.

The printer 10 according to this embodiment also includes a touch panel 13 communicably connected to the computer 50 . The computer 50 has a display section 65 for displaying the waste liquid amount based on the waste liquid count value stored in the storage section 62 on the touch panel 13 . Therefore, the user can easily grasp the amount of ink (waste liquid amount) accumulated in the waste liquid tank 41 .

The printer 10 according to this embodiment also includes a first waste liquid amount detection sensor 46 that detects whether or not the amount of ink in the waste liquid tank 41 exceeds a predetermined first threshold. When the first waste liquid amount detection sensor 46 detects that the amount of ink in the waste liquid tank 41 exceeds the first threshold value, the display unit 65 displays on the touch panel 13 a notification prompting disposal of the ink in the waste liquid tank 41 . It is configured to allow In the initialization unit 64, the determination unit 63 determines that the waste liquid tank 41 has been reattached, and the first waste liquid amount detection sensor 46 detects that the amount of ink in the waste liquid tank 41 is equal to or less than the first threshold value. , the waste liquid count value stored in the storage unit 62 is initialized. As a result, when the user once removes the waste liquid tank 41 in the near-end state or the end state from the mounting position and then mounts it again in the mounting position without discarding the ink, the waste liquid count value can be initialized. You can prevent it from slipping.

A preferred embodiment of the present invention has been described above. However, the above-described embodiments are exemplary only. The present invention can be implemented in various other forms.

Although the display device of the printer 10 is configured by the touch panel 13 in the above embodiment, the display device is not limited to the touch panel 13 . The display device may be a display panel that does not allow input operations. Also, the display device is not limited to a panel-like one. The display device may be provided in the main body 11 of the printer 10, or may be a device separated from the main body 11 (external display, etc.).

The above-described embodiment is a so-called roll-to-roll type printer 10, but the form of the ink jet printer according to the present invention is not limited at all. The inkjet printer may be, for example, a flatbed printer.

A mechanism for detecting the amount of ink in the waste liquid tank 41 is not limited at all. In the above embodiment, the tray 43 that supports the waste liquid tank 41 is configured to be rotatable around the shaft 49, but the tray 43 may be configured to be vertically slidable, for example.

The form of the waste liquid tank detection sensor 45 is not limited at all. In the above-described embodiment, the waste liquid tank detection sensor 45 detects whether or not the waste liquid tank 41 is at the mounting position by detecting the second striker 38, but the waste liquid tank detection sensor 45 detects the waste liquid tank 41 itself, for example. It may be configured to detect. The waste liquid tank detection sensor 45 may be configured to detect whether or not the waste liquid tank 41 is at the mounting position by detecting the weight of the waste liquid tank 41 .

In the above embodiment, the printer 10 is provided with the first waste liquid amount detection sensor 46 and the second waste liquid amount detection sensor 47 in order to detect the near-end state and the end state of the waste liquid tank 41 . However, only one waste liquid amount detection sensor may be used. For example, the printer 10 may include only the second waste liquid amount detection sensor 47 without the first waste liquid amount detection sensor 46 . In this case, by replacing the first threshold value described above with the second threshold value, the same determination or processing as described above can be executed. Also, the printer 10 may be provided with three or more waste liquid amount detection sensors.

The ink receiving member that receives ink discharged from the ink head 22 is not limited to the cap 31 . The ink receiving member may not be in close contact with the nozzle surface of the ink head 22 . The ink receiving member may be, for example, a container arranged below the ink head 22 at the home position.

10 inkjet printer 13 touch panel (display device)
22 ink head 31 cap (ink receiving member)
41 waste liquid tank 45 waste liquid tank detection sensor 46 first waste liquid amount detection sensor 47 second waste liquid amount detection sensor 50 computer 61 waste liquid count unit 62 storage unit 63 determination unit 63A first state transition determination unit 63B second state transition determination unit 64 initial display unit 65 display unit

Claims (6)

an ink head for ejecting ink;
an ink receiving member that receives ink discharged from the ink head;
a waste liquid tank for collecting ink from the ink receiving member;
a waste liquid tank detection sensor that detects whether or not the waste liquid tank is mounted at a predetermined mounting position;
a computer communicably connected to the ink head and the waste liquid tank detection sensor;
The computer is
a waste liquid count unit that counts the amount of ink discharged from the ink head to the ink receiving member as a waste liquid count value;
a storage unit that stores the waste liquid count value;
a determination unit that determines whether or not the waste liquid tank has been remounted at the mounting position based on a change in the output of the waste liquid tank detection sensor;
an initialization unit that initializes the waste liquid count value stored in the storage unit when the determination unit determines that the waste liquid tank has been reattached;
, an inkjet printer. The determination unit
a first state transition determination unit that determines whether or not there is a first state transition in which the waste liquid tank is in the mounting position to not in the mounting position based on a change in the output of the waste liquid tank detection sensor;
a second state transition determination unit that determines whether or not there is a second state transition in which the waste liquid tank is not in the mounting position and is in the mounting position based on a change in the output of the waste liquid tank detection sensor; has
After the first state transition determining unit determines that the first state transition has occurred, the waste liquid tank is remounted when the second state transition determining unit determines that the second state transition has occurred. 2. The inkjet printer of claim 1, wherein the ink jet printer is configured to determine that the The output of the waste liquid tank detection sensor when the waste liquid tank is mounted at the mounting position is defined as a first signal, and the output of the waste liquid tank detection sensor when the waste liquid tank is not mounted at the mounting position is defined as a first signal. As a second signal,
The first state transition determining section continues to receive the second signal for a predetermined first time after the output received from the waste liquid tank detection sensor is switched from the first signal to the second signal. is configured to determine that the first state transition has occurred when
and/or
The second state transition determining section continues to receive the first signal for a predetermined second time after the output received from the waste liquid tank detection sensor is switched from the second signal to the first signal. 3. The inkjet printer of claim 2, configured to determine that the second state transition has occurred when a A display device communicatively connected to the computer,
The inkjet printer according to any one of claims 1 to 3, wherein the computer has a display section for displaying the amount of waste liquid based on the waste liquid count value stored in the storage section on the display device. . a waste liquid amount detection sensor that detects whether or not the amount of ink in the waste liquid tank exceeds a predetermined threshold;
When the waste liquid amount detection sensor detects that the amount of ink in the waste liquid tank exceeds the threshold value, the display unit causes the display device to display a notification prompting disposal of the ink in the waste liquid tank. configured to
After displaying the notification on the display device, the initialization unit determines that the waste liquid tank has been reattached, and that the amount of ink in the waste liquid tank is equal to or less than the threshold value. 5. The inkjet printer according to claim 4, configured to initialize a waste liquid count value stored in said storage unit when detected by said waste liquid amount detection sensor. a waste liquid amount detection sensor that detects whether or not the amount of ink in the waste liquid tank exceeds a predetermined threshold;
When the determination unit determines that the waste liquid tank has been remounted and the waste liquid amount detection sensor detects that the amount of ink in the waste liquid tank is equal to or less than the threshold value, the initialization unit performs the 5. The inkjet printer according to claim 1, wherein the waste liquid count value stored in the storage unit is initialized.

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