JP2016068328A - Inkjet printing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inkjet printing device that allows an inkjet head to discharge stably by suppressing variation of pressure of nozzles while avoiding enlargement of the device.SOLUTION: The inkjet printing device comprises: a first pressurized tank 21a that stores ink to be supplied to a first nozzle row 19a that discharges ink; a first negative pressure tank 24a that stores ink returned from the first nozzle row 19a; a second pressurized tank 21b that stores ink to be supplied to a second nozzle row 19b that discharges ink; a second negative pressure tank 24b that stores ink returned from the second nozzle row 19b; a first ink pump 25a that feeds ink from the first negative pressure tank 24a to the second negative pressure tank 21b; and a second ink pump 25b that feeds ink from the second negative pressure tank 24b to the first pressurized tank 21a. The operation timing of the first ink pump 25a and the second ink pump 25b are synchronized with each other for feeding ink.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an ink circulation type ink jet printing apparatus.

  2. Description of the Related Art An ink circulation type inkjet printing apparatus that prints by ejecting ink from an inkjet head while circulating ink is known. As this ink circulation type ink jet printing apparatus, a pressure tank and a negative pressure tank are arranged upstream and downstream of the ink jet head, an air pump for sending air from the negative pressure tank to the pressure tank, and a negative pressure tank. Some have a pump that feeds the accumulated ink to a pressurized tank (see, for example, Patent Document 1).

  In such an ink circulation type, ink is ejected from the inkjet head while the ink is circulated by the pressure difference between the pressure tank and the negative pressure tank. More specifically, ink is supplied from an ink tank (pressurized tank) upstream of the inkjet head to the inkjet head, and ink that has not been consumed is supplied to a downstream tank (negative pressure tank) of the inkjet head. Then, the ink accumulated in the negative pressure tank is sent to the pressure tank by the ink pump and supplied to the inkjet head again. The pressure required for ink circulation is generated by an air pump and an air release valve provided in the pressurized tank and the negative pressure tank.

JP 2012-153004 A

  However, in the ink circulation system described above, when ink is fed from the negative pressure tank to the pressurized tank, the liquid level of the ink in the tank increases and decreases, the circulation pressure varies, and the nozzle pressure also varies. In some cases, the ink ejection becomes unstable.

  In contrast, methods have been developed in the past to increase the amount of air in the tank or to provide a separate air chamber in the air path connected to the tank to suppress nozzle pressure fluctuations. There has been a problem of increasing the size of the apparatus due to the increase in capacity and the addition of air chambers.

  Therefore, the present invention solves the above-described problems, and avoids an increase in the size of an ink circulation type inkjet printing apparatus that prints by ejecting ink from an inkjet head while circulating ink. However, an object of the present invention is to provide a system that can suppress fluctuations in nozzle pressure and realize stable ejection in an inkjet head.

  In order to achieve the above object, an ink jet printing apparatus according to the present invention includes a first nozzle row and a second nozzle row, an ink jet head that discharges ink from these first and second nozzle rows, and the first nozzle. A first supply tank for storing ink to be supplied to the row; a first reflux tank for storing ink returned from the first nozzle row; and a second supply for storing ink to be supplied to the second nozzle row. An ink tank, a second return tank for storing ink returned from the second nozzle row, and an ink for circulating from the first supply tank to the first return tank through the inkjet head. A first circulation path; a second circulation path for circulating ink from the second supply tank to the second reflux tank through the inkjet head; and the first reflux path. A first liquid feeding means for feeding ink from the tank to the second supply tank and a second liquid feeding means for feeding ink from the second reflux tank to the first supply tank. .

  As described above, according to the present invention, the first liquid feeding means for feeding ink from the first reflux tank to the second supply tank, and the ink from the second reflux tank to the first supply tank. By providing the second liquid feeding means for feeding the liquid and circulating the ink in synchronization with the two liquid feeding means, the liquid level of the ink increases and decreases in each tank, and the circulation pressure varies. Even when it occurs, the nozzle pressure fluctuations in the first and second nozzle rows can be offset or mutually absorbed, and stable ejection in the inkjet head can be realized.

  In addition, for example, even when the ink is used only in one of the first nozzle row and the second nozzle row, the circulation side tank on the nozzle side with the large amount of use is used from the circulation tank on the nozzle side with the small amount of use. Since liquid can be fed to the supply tank, the number of ink replenishments during printing can be reduced, nozzle pressure fluctuations due to liquid level fluctuations during replenishment can be suppressed, and ink can hardly be drained.

It is a block diagram which shows the structure of the inkjet printing apparatus which concerns on embodiment. It is a schematic block diagram of a printing part and a pressure adjustment part. It is a schematic block diagram of the head module of a printing part. (A)-(c) is a schematic block diagram of an ink pump. It is a schematic block diagram which shows the ink circulation part of a printing part. It is a block diagram which shows the structure of the control part of the inkjet printing apparatus shown in FIG. It is a graph which shows the fluctuation | variation of the liquid level height in a tank at the time of ink circulation. It is a graph which shows the fluctuation | variation of the liquid level height in a tank at the time of an ink pump drive. It is a graph which shows the fluctuation | variation of the liquid level in a tank at the time of an ink pump synchronous process, and a circulating pressure. It is a graph which shows the fluctuation | variation of the liquid level height in a tank by a prior art example, and a circulating pressure.

  Embodiments of the present invention will be described below with reference to the drawings. Throughout the drawings, the same or equivalent parts and components are denoted by the same or equivalent reference numerals. However, it should be noted that the drawings are schematic and different from the actual ones. Moreover, it is a matter of course that portions having different dimensional relationships and ratios are included between the drawings.

  Further, the embodiment described below exemplifies an apparatus or the like for embodying the technical idea of the present invention, and the technical idea of the present invention includes the material, shape, structure, The layout is not specified as follows. The technical idea of the present invention can be variously modified within the scope of the claims.

  FIG. 1 is a block diagram showing a configuration of an ink jet printing apparatus according to an embodiment of the present invention. FIG. 2 is a schematic configuration diagram of a printing unit and a pressure adjustment unit of the inkjet printing apparatus, and FIG. 3 is a schematic configuration diagram of a head module of the printing unit. In the following description, the vertical direction is the vertical direction.

  As shown in FIG. 1, the ink jet printing apparatus 1 according to the present embodiment includes four printing units 2, a pressure adjustment unit 3, a transport unit 4, and a control unit 5.

  The printing unit 2 prints an image by ejecting ink onto the paper conveyed by the conveyance unit 4 while circulating the ink. The four printing units 2 eject inks of different colors (for example, black (K), cyan (C), magenta (M), and yellow (Y)). The four printing units 2 have the same configuration except that the colors of the ejected ink are different.

  As shown in FIG. 2, the printing unit 2 includes an inkjet head 11, an ink circulation unit (corresponding to a circulation path in claims) 12, and an ink supply unit 13.

  The ink jet head 11 ejects ink supplied by the ink circulation unit 12. Each inkjet head 11 includes a plurality of head modules 16. FIG. 3 is a view of the head module 16 as viewed from below, including a partially enlarged view. As shown in FIG. 3, each color head module 16 has two ink chambers 17a and 17b. The ink chambers 17a and 17b store ink. Ink is supplied to the ink chambers 17a and 17b via an ink path (not shown). Piezo elements (not shown) are arranged in the ink chambers 17a and 17b. By driving the piezo element, ink is ejected from a nozzle 18 described later.

  The same color ink is supplied to the ink chambers 17 a and 17 b of the head module 16. A plurality of nozzles 18 for ejecting ink are formed in the ink chambers 17a and 17b, respectively, and a first nozzle row 19a (corresponding to a first nozzle row in claims) and a second nozzle row 19b (second nozzles in claim). Column). In each nozzle row 19a, 19b, the plurality of nozzles 18 are arranged at regular intervals with a predetermined pitch P in the main scanning direction (front-rear direction), and each nozzle 18 in the first nozzle row 19a and the second nozzle row 19b. Ink is discharged from the nozzle.

  The upstream nozzle row 19a and the downstream nozzle row 19b are arranged in parallel in the paper transport direction (sub-scanning direction). The nozzles 18 of the first nozzle row 19a and the nozzles 18 of the second nozzle row 19b are arranged so as to be shifted by a half pitch (P / 2) in the main scanning direction.

  Thus, the head module 16 has two nozzle rows that can eject the same color ink, and the nozzle positions of the two nozzle rows in the main scanning direction are only half the nozzle pitch (half pitch). The printing resolution can be increased.

  The ink circulation unit 12 supplies ink to the inkjet head 11 while circulating the ink. The ink circulation unit 12 includes a first pressure tank (corresponding to the first supply tank in the claims) 21a, a first negative pressure tank (corresponding to the first reflux tank in the claims) 24a, and a second pressure. A tank (corresponding to the second supply tank in the claims) 21b, a second negative pressure tank (corresponding to the second reflux tank in the claims) 24b, the distributors 22a and 22b, the collectors 23a and 23b, A first ink pump (corresponding to the first liquid feeding means in the claims) 25a, a second ink pump (corresponding to the second liquid feeding means in the claims) 25b, an ink temperature adjusting unit 40, and an ink temperature sensor 45; And pipes 26-30.

  The first pressure tank 21a stores ink to be supplied to the first nozzle row 19a. The ink in the first pressurized tank 21a is supplied to the ink chamber 17a of the head module 16 via the pipe 28 and the distributor 22a. In the first pressurized tank 21a, an air chamber portion is formed in which air is filled on the ink surface. The first pressurized tank 21a communicates with a pressurized common air chamber 51 described later via a piping 60a described later. The first pressurizing tank 21 a is disposed at a position (downward) lower than the inkjet head 11.

  The first pressurized tank 21a has a capacity to receive the ink even if the meniscus of the nozzle of the inkjet head 11 is broken by the vibration and the ink inside the distributor 22a and the pipe 28 flows down to the first pressurized tank 21a. Have. However, if the first pressurized tank 21a is too large, the size of the apparatus is increased. For this reason, the first pressurized tank 21a has a capacity that is filled when all the ink in the distributor 22a and the pipe 28 flows down to the first pressurized tank 21a.

  The second pressurized tank 21b stores ink to be supplied to the second nozzle row 19b. The ink in the second pressurized tank 21b is supplied to the ink chamber 17b of the head module 16 through the pipe 26 (26a, 26b) and the distributor 22b. In the second pressurization tank 21b, an air chamber portion in which air is filled on the ink surface is formed. The second pressurization tank 21b is communicated with a pressurization common air chamber 51 described later via a pipe 60b described later. The second pressurizing tank 21 b is disposed at a position (downward) lower than the inkjet head 11.

  Even if the meniscus of the nozzle of the inkjet head 11 is destroyed by the vibration and the ink inside the distributor 22b and the pipe 26 flows down to the second pressurized tank 21b, the second pressurized tank 21b has a capacity sufficient to receive it. Have. However, if the second pressure tank 21b is too large, the size of the apparatus is increased. For this reason, the second pressurized tank 21b has a capacity that is filled when all the ink inside the distributor 22b and the pipe 26 flows down to the second pressurized tank 21b.

  The first pressurized tank 21a and the second pressurized tank 21b are provided with a float member 31, a pressurized tank liquid level sensor 32, and an ink filter 33, respectively. In addition, since each member is the same member, it attaches | subjects and demonstrates here the same code | symbol.

  The float member 31 is rotated in accordance with the liquid level height until the liquid level of the ink in the first pressure tank 21a or the second pressure tank 21b reaches the reference height. One end side is pivotally supported by a support shaft (not shown) in the pressure tank 21a or the second pressure tank 21b. A magnet (not shown) is provided at the other end of the float member 31.

  The pressurized tank liquid level sensor 32 is for detecting whether or not the liquid level of the ink in the first pressurized tank 21a or the second pressurized tank 21b has reached the reference height. The reference height is at a position below the upper end of the first pressure tank 21a or the second pressure tank 21b by a predetermined distance. The pressurized tank liquid level sensor 32 is composed of a magnetic sensor, and detects the magnet of the float member 31 when the liquid level has reached the reference height. When the pressurized tank liquid level sensor 32 detects the magnet of the float member 31, that is, when the liquid level in the first pressurized tank 21a or the second pressurized tank 21b is equal to or higher than the reference height. , A signal indicating "ON" is output. When the pressurized tank liquid level sensor 32 does not detect the magnet of the float member 31, that is, when the liquid level in the first pressurized tank 21a or the second pressurized tank 21b is less than the reference height. , A signal indicating “off” is output.

  The ink filter 33 removes dust and the like in the ink.

  The distributor 22 a distributes the ink supplied from the first pressure tank 21 a via the pipe 28 to the ink chamber 17 a of the head module 16. The distributor 22 b distributes the ink supplied from the second pressurized tank 21 b via the pipe 26 to the ink chamber 17 b of the head module 16.

  The aggregator 23 a collects ink that has not been consumed in the ink chamber 17 a of the head module 16 from the head module 16. The ink collected by the collector 23a flows to the first negative pressure tank 24a via the pipe 29. The aggregator 23 b collects ink that has not been consumed in the ink chamber 17 b of the head module 16 from the head module 16. The ink collected by the collector 23b flows to the second negative pressure tank 24b via the pipe 27.

  The first negative pressure tank 24a is not consumed by the head module 16 in which the first nozzle row 19a is formed, and stores the returned ink from the collector 23a. The first negative pressure tank 24a stores ink supplied from an ink cartridge 46 of the ink supply unit 13 described later. In the first negative pressure tank 24a, there is formed an air chamber portion filled with air on the ink surface. The first negative pressure tank 24a is connected to a negative pressure common air chamber 55 described later via a pipe 61a described later. The first negative pressure tank 24a has the same height as the first pressurization tank 21a and is disposed adjacent to the first pressurization tank 21a.

  Even if the meniscus of the nozzle 18 of the ink chamber 17a is destroyed by vibration and the ink inside the head module 16, the collector 23a, and the pipe 29 flows down to the first negative pressure tank 24a, the first negative pressure tank 24a Have enough capacity to accept. However, if the first negative pressure tank 24a is too large, the apparatus becomes large. For this reason, the first negative pressure tank 24a has such a capacity that the ink in the ink chamber 17a, the collector 23a, and the pipe 29 becomes full when all the ink flows down to the first negative pressure tank 24a.

  The second negative pressure tank 24b is not consumed by the head module 16 in which the second nozzle row 19b is formed, and stores the returned ink from the collector 23b. The second negative pressure tank 24b stores ink supplied from an ink cartridge 46 of the ink supply unit 13 described later. In the second negative pressure tank 24b, an air chamber portion in which air is filled on the ink surface is formed. The second negative pressure tank 24b communicates with a negative pressure common air chamber 55 described later via a pipe 61b described later. The second negative pressure tank 24b has the same height as the second pressurization tank 21b and is disposed adjacent to the second pressurization tank 21b.

  Even if the meniscus of the nozzle 18 of the ink chamber 17b is broken by vibration and the ink inside the head module 16, the collector 23b, and the pipe 27 flows down to the second negative pressure tank 24b, the second negative pressure tank 24b Have enough capacity to accept. However, if the second negative pressure tank 24b is too large, the apparatus will be enlarged. For this reason, the second negative pressure tank 24b has such a capacity that the ink inside the head module 16, the collector 23b, and the pipe 27 is filled when all the ink flows down to the second negative pressure tank 24b.

  The first negative pressure tank 24 a and the second negative pressure tank 24 b are provided with a float member 36 and a negative pressure tank liquid level sensor 37. In addition, since each member is the same member, it attaches | subjects and demonstrates here the same code | symbol.

  The float member 36 and the negative pressure tank liquid level sensor 37 are the same as the float member 31 and the pressurized tank liquid level sensor 32 of the first pressurized tank 21a and the second pressurized tank 21b, respectively. The negative pressure tank liquid level sensor 37 detects the magnet of the float member 36, that is, the liquid level height in the first negative pressure tank 24a or the second negative pressure tank 24b is equal to or higher than the reference height. , A signal indicating "ON" is output. When the negative pressure tank liquid level sensor 37 does not detect the magnet of the float member 36, that is, when the liquid level height in the first negative pressure tank 24a or the second negative pressure tank 24b is less than the reference height. , A signal indicating “off” is output. The reference height is at a position below the upper end of the first negative pressure tank 24a or the second negative pressure tank 24b by a predetermined distance.

  The ink temperature adjustment unit 40 adjusts the ink temperature in the ink circulation unit 12. The ink temperature adjustment unit 40 is provided in the middle of the pipes 26 and 28. The ink temperature adjustment unit 40 includes a heater 41, a heater temperature sensor 42, a heat sink 43, and a cooling fan 44.

  The heater 41 heats the ink in the pipes 26 and 28. The heater temperature sensor 42 detects the temperature of the heater 41. The heat sink 43 cools the ink in the pipes 26 and 28. The cooling fan 44 sends cooling air to the heat sink 43.

  The ink temperature sensor 45 detects the temperature of the ink in the ink circulation unit 12. The ink temperature sensor 45 is provided in the middle of the pipes 26 and 28.

  The pipe 28 connects the first pressurized tank 21a and the distributor 22a. A part of the pipe 28 is branched into a part passing through the heater 41 and a part passing through the heat sink 43. In the pipe 28, ink flows from the first pressurized tank 21a toward the distributor 22a. The pipe 29 connects the collector 23a and the first negative pressure tank 24a. In the pipe 29, ink flows from the collector 23a toward the first negative pressure tank 24a. Thus, the piping 28 and the piping 29 form a first circulation path through which ink circulates from the first pressure tank 21a through the inkjet head 11 to the first negative pressure tank 24a.

  The pipe 26 connects the second pressurized tank 21b and the distributor 22b. In the present embodiment, a range from the second pressurized tank 21b to the ink temperature adjustment unit 40 is referred to as a pipe 26a, and a range from the ink temperature adjustment unit 40 to the distributor 22b is referred to as a pipe 26b. A part of the pipe 26 passes through the ink temperature adjustment unit 40. In FIG. 2, a portion that passes through the ink temperature adjustment unit 40 is omitted, but the pipe 26 branches into a portion that passes through the heater 41 and a portion that passes through the heat sink 43, similar to the pipe 28. Yes.

  The pipe 27 connects the collector 23b and the second negative pressure tank 24b. In the pipe 27, ink flows from the collector 23b toward the second negative pressure tank 24b. In this way, the piping 27 and the piping 26 form a second circulation path through which ink circulates from the second pressurized tank 21b through the ink chamber 17b of the head module 16 to the second negative pressure tank 24b.

  The piping 30 connects each tank. In the present embodiment, a pipe 30a and a pipe 30b are provided. The pipe 30a connects the first negative pressure tank 24a and the second pressurization tank 21b. In the pipe 30a, ink flows from the first negative pressure tank 24a toward the second pressure tank 21b. The first ink pump 25a is provided in the middle of the pipe 30a. The first ink pump 25a sends ink from the first negative pressure tank 24a to the second pressurization tank 21b.

  The pipe 30b connects the second negative pressure tank 24b and the first pressurization tank 21a. In the pipe 30b, ink flows from the second negative pressure tank 24b toward the first pressure tank 21a. The second ink pump 25b is provided in the middle of the pipe 30b. The second ink pump 25b sends ink from the second negative pressure tank 24b to the first pressure tank 21a.

  In the present embodiment, the first ink pump 25a and the second ink pump 25b are volume transfer type diaphragm pumps having a diaphragm 251 and a chamber 252 as shown in FIG. As shown in FIG. 4B, the diaphragm pump raises the diaphragm 251 to increase the volume of the chamber 252, thereby reducing the pressure and allowing the ink to flow into the chamber 252. Next, as shown in FIG. 4C, the diaphragm is lowered to increase the pressure in the chamber 252, thereby forcibly discharging the ink that has just flowed into the ejection side.

  As described above, in the printing unit 2, as shown in FIG. 5, the first pressure tank 21a and the first negative pressure tank 24a for storing ink to be supplied to the ink chamber 17a having the first nozzle row 19a, and the second It has the 2nd pressurization tank 21b and the 2nd negative pressure tank 24b which store the ink supplied to the ink chamber 17b which has the nozzle row 19b. In the printing unit 2, the first pressure tank 21a for the first nozzle row 19a and the second negative pressure tank 24b for the second nozzle row 19b are connected to each other, and the second pressure for the second nozzle row 19b is connected. The ink circulation unit 12 is formed by connecting the pressure tank 21b and the first negative pressure tank 24a for the first nozzle row 19a and driving the first ink pumps 25a and 25b.

  The ink supply unit 13 supplies ink to the ink circulation unit 12. The ink supply unit 13 includes an ink cartridge 46, pipes 47a and 47b, and ink supply valves 48a and 48b.

  The ink cartridge 46 contains ink used for printing in the printing unit 2. The ink in the ink cartridge 46 is supplied to the first negative pressure tank 24a via the pipe 47a and to the second negative pressure tank 24b via the pipe 47b.

  The pipe 47a connects the ink cartridge 46 and the first negative pressure tank 24a. Ink flows from the ink cartridge 46 toward the first negative pressure tank 24a through the pipe 47a.

  The ink supply valve 48a opens and closes the ink flow path in the pipe 47a. When supplying ink from the ink cartridge 46 to the first negative pressure tank 24a, the ink supply valve 48a is opened.

  The pipe 47b connects the ink cartridge 46 and the second negative pressure tank 24b. Ink flows from the ink cartridge 46 toward the second negative pressure tank 24b in the pipe 47b. In FIG. 2, a part of the piping 47b is omitted. The ink supply valve 48b opens and closes the ink flow path in the pipe 47b. When supplying ink from the ink cartridge 46 to the second negative pressure tank 24b, the ink supply valve 48b is opened.

  The pressure adjusting unit 3 adjusts the pressures of the first pressurizing tank 21a, the first negative pressure tank 24a, the second pressurizing tank 21b, and the second negative pressure tank 24b of each printing unit 2. The pressure adjusting unit 3 includes a pressurizing common air chamber 51, a pressurizing side pressure adjusting valve 52, a pressurizing side atmospheric release valve 53, a pressurizing side pressure sensor 54, a negative pressure common air chamber 55, and a negative pressure side pressure adjusting valve. 56, a negative pressure side air release valve 57, a negative pressure side pressure sensor 58, an air pump 59, four pipes 60a, four pipes 60b, four pipes 61a, and four pipes 61b, Pipes 62 to 67, an air filter 68, and an overflow pan 69 are provided.

  The pressurized common air chamber 51 is an air chamber for equalizing the pressure of the pressurized tank of each printing unit 2. Specifically, the pressurized common air chamber 51 communicates with the air chamber portions of the first pressurized tank 21a and the second pressurized tank 21b via the piping 60a and the piping 60b for each color. Thereby, each pressurization tank of each printing part 2 is connected via pressurization common air chamber 51 and piping 60a and 60b. The pipe 60a is connected to the first pressurized tank 21a. The pipe 60b is connected to the second pressure tank 21b.

  The pressure-side pressure adjustment valve 52 adjusts the flow of air in the pipe 63 in order to adjust the pressure of the first pressure tank 21 a and the second pressure tank 21 b of each printing unit 2 through the pressure common air chamber 51. Open and close the road. The pressure side pressure adjustment valve 52 is provided in the middle of the pipe 63.

  The pressurization-side air release valve 53 is configured to seal the first pressurization tank 21a and the second pressurization tank 21b of each printing unit 2 through the pressurization common air chamber 51 (a state in which the first pressurization tank 21b is shut off from the atmosphere) and an air release state ( The air flow path in the pipe 64 is opened and closed in order to switch between the state and the air communication state. The pressurization side air release valve 53 is provided in the middle of the pipe 64.

  The pressure side pressure sensor 54 detects the pressure (pressure side pressure) in the pressure common air chamber 51. Here, the pressure in the pressurized common air chamber 51 is equal to the pressure in the first pressurized tank 21 a and the second pressurized tank 21 b of each printing unit 2. This is because the pressurized common air chamber 51 and the air chamber portions of the first pressurizing tank 21a and the second pressurizing tank 21b of each printing unit 2 are communicated with each other.

  The negative pressure common air chamber 55 is an air chamber for equalizing the pressure in the negative pressure tank of each printing unit 2. Specifically, the negative pressure common air chamber 55 is communicated with the air chamber portions of the first negative pressure tank 24a and the second negative pressure tank 24b via the pipe 61a and the pipe 61b. Thereby, the negative pressure tanks of the printing units 2 are communicated with each other via the negative pressure common air chamber 55 and the pipes 61a and 61b.

  The negative pressure side pressure adjusting valve 56 adjusts the pressure of the first negative pressure tank 24a and the second negative pressure tank 24b of each printing unit 2 via the negative pressure common air chamber 55 to allow the air flow in the pipe 65 to flow. Open and close the road. The negative pressure side pressure adjustment valve 56 is provided in the middle of the pipe 65.

  The negative pressure side atmospheric release valve 57 is configured to switch the first negative pressure tank 24a and the second negative pressure tank 24b of each printing unit 2 between the sealed state and the atmospheric release state via the negative pressure common air chamber 55. The air flow path in the pipe 66 is opened and closed. The negative pressure side air release valve 57 is provided in the middle of the pipe 66.

  The negative pressure side pressure sensor 58 detects the pressure in the negative pressure common air chamber 55 (negative pressure side pressure). Here, the pressure in the negative pressure common air chamber 55 is equal to the pressure in the first negative pressure tank 24 a and the second negative pressure tank 24 b of each printing unit 2. This is because the negative pressure common air chamber 55 communicates with the air chamber portions of the first negative pressure tank 24a and the second negative pressure tank 24b of each printing unit 2.

  The air pump 59 sends air from the negative pressure tank of each printing unit 2 to the pressurization tank via the pressurization common air chamber 51 and the negative pressure common air chamber 55. The air pump 59 is provided in the middle of the pipe 62.

  The four pipes 60 a connect the pressurized common air chamber 51 and the first pressurized tanks 21 a of the four printing units 2. One end of the pipe 60a is connected to the pressurized common air chamber 51, and the other end is connected to the air chamber portion of the first pressurized tank 21a. The four pipes 60 b connect the pressurized common air chamber 51 and the second pressurized tanks 21 b of the four printing units 2. One end of the pipe 60b is connected to the pressurized common air chamber 51, and the other end is connected to the air chamber portion of the second pressurized tank 21b.

  The four pipes 61 a connect the negative pressure common air chamber 55 and the first negative pressure tanks 24 a of the four printing units 2. One end of the pipe 61a is connected to the negative pressure common air chamber 55, and the other end is connected to the air chamber portion of the first negative pressure tank 24a. The four pipes 61b connect the negative pressure common air chamber 55 to the second negative pressure tanks 24b of the four printing units 2. One end of the pipe 61b is connected to the negative pressure common air chamber 55, and the other end is connected to the air chamber portion of the second negative pressure tank 24b.

  The pipe 62 forms a flow path for air sent from the negative pressure common air chamber 55 to the pressurized common air chamber 51 by the air pump 59. One end of the pipe 62 is connected to the negative pressure common air chamber 55, and the other end is connected to the pressurization common air chamber 51.

  Each of the pipes 63 and 64 has one end connected to the pressurized common air chamber 51 and the other end connected to the pipe 67. Each of the pipes 65 and 66 has one end connected to the negative pressure common air chamber 55 and the other end connected to the pipe 67. One end (upper end) of the pipe 67 communicates with the atmosphere via the air filter 68, and the other end is connected to the overflow pan 69.

  The air filter 68 is provided at the upper end of the pipe 67 and prevents dust or the like in the outside air from entering.

  The overflow pan 69 is used when ink overflows from the pressurized tank and the negative pressure tank due to, for example, an abnormality in the ink supply valves 48 a and 48 b, and further overflows from the pressurized common air chamber 51 and the negative pressure common air chamber 55. , Receive that ink.

  The overflow pan 69 is provided with a float member 71 and an overflow liquid level sensor 72. The float member 71 and the overflow liquid level sensor 72 are the same as the float member 31 and the pressurized tank liquid level sensor 32 of the pressurized tank, respectively.

  The overflow pan 69 is connected to a waste liquid tank (not shown), and discharges ink to the waste liquid tank when the overflow liquid level sensor 72 is turned on.

  The transport unit 4 takes out the paper from a paper feed table (not shown) and transports the paper along the transport path. The transport unit 4 includes a roller for transporting the paper, a motor for driving the roller (both not shown), and the like.

  Although not shown, the inkjet printing apparatus 1 is provided with an operation panel that displays various input screens and the like and accepts an input operation by a user. In addition, a commercial power supply is connected to the inkjet printing apparatus 1, and a main power switch that is a switch for switching on and off the main power of the inkjet printing apparatus 1, and electric power supplied via the main power switch are inkjet. A power supply unit that supplies each unit of the printing apparatus 1 is provided.

  The control unit 5 controls the operation of the entire inkjet printing apparatus 1. As shown in FIG. 4, the control unit 5 includes a main controller 81 and a mechanical controller 82.

  The main controller 81 controls the entire inkjet printing apparatus 1. The main controller 81 includes a CPU (Central Processing Unit) 91, a memory 92, an HDD (Hard Disk Drive) 93, an external I / F (interface) 94, a mechanical controller I / F 95, a user I / F 96, And a head I / F 97.

  CPU91 performs arithmetic processing. The memory 92 is used as a work area for the CPU 91 during temporary data storage or calculation. The HDD 93 stores various programs and the like.

  The external I / F 94 transmits / receives data to / from an external device via a network. The mechanical controller I / F 95 connects the mechanical controller 82 to the main controller 81. The user I / F 96 connects the operation panel to the main controller 81. The head I / F 97 connects the inkjet head 11 to the main controller 81.

  The mechanical controller 82 controls ink circulation and ink supply in the printing unit 2, controls pressure adjustment by the pressure adjustment unit 3, and controls paper conveyance by the conveyance unit 4. The mechanical controller 82 includes a CPU 101, a memory 102, a sensor I / F 103, a main controller I / F 104, an actuator I / F 105, a driver unit 106, and a latch circuit 107.

  The CPU 101 executes arithmetic processing. The memory 102 is used as a work area for the CPU 101 during temporary data storage or computation.

  The sensor I / F 103 connects various sensors such as a pressurized tank liquid level sensor 32 and a negative pressure tank liquid level sensor 37 to the mechanical controller 82. The main controller I / F 104 connects the mechanical controller 82 to the main controller 81. The actuator I / F 105 transmits a control signal to the driver unit 106.

  The driver unit 106 includes various drivers that drive the first ink pump 25a, the second ink pump 25b, the air pump 59, the motor of the transport unit 4, and the like.

  The latch circuit 107 holds a latch that is set when the power supply (sub power supply) is turned on for the first time after the main power supply is turned on until the main power supply is turned off.

  Such a control unit 5 executes print processing based on the print job. Specifically, when starting the printing, the control unit 5 controls the pressure adjusting unit 3 to apply pressure to the first pressurizing tank 21 a and the first negative pressure tank 24 a of each printing unit 2, 2 Negative pressure is applied to the pressurized tank 21b and the second negative pressure tank 24b. As a result, a flow of ink from the first pressure tank 21a to the first negative pressure tank 24a via the ink chamber 17a is generated, and the second negative pressure from the second pressure tank 21b via the ink chamber 17b. Ink flows toward the tank 24b and ink circulation starts. At this time, the controller 5 circulates the ink by synchronizing the first ink pump 25a and the second ink pump 25b, thereby changing the circulation pressure caused by the increase or decrease in the liquid level of the ink in the tank. Suppress.

  Next, the operation at the time of printing of the inkjet printing apparatus 1 will be described.

  When a print job is input to the inkjet printing apparatus 1, first, the control unit 5 performs ink circulation control. As the ink circulation control, first, the CPU 101 of the mechanical controller 82 starts the liquid level maintenance control of each printing unit 2. In the liquid level maintenance control, each of the pressure pumps 21a and 21b and each of the negative pressure tanks 24a and 24b is maintained in the vicinity of the reference height, and each ink pump 25a, 25b and the ink supply valves 48a and 48b.

  Here, since the first pressurized tank 21a and the second negative pressure tank 24b are connected through the pump 25b, the negative pressure between the pressurized tank liquid level sensor 32 of the first pressurized tank 21a and the second negative pressure tank 24b. Based on the detection result of the pressure tank liquid level sensor 37, the driving of the second ink pump 25b and the opening / closing of the ink supply valve 48b are controlled.

  Further, since the second pressurized tank 21b and the first negative pressure tank 24a are connected through the pump 25a, the pressurized tank liquid level sensor 32 of the second pressurized tank 21b and the negative pressure of the first negative pressure tank 24a. Based on the detection result from the tank liquid level sensor 37, the driving of the first ink pump 25a and the opening / closing of the ink supply valve 48a are controlled.

  Specifically, when both the pressurized tank liquid level sensor 32 and the negative pressure tank liquid level sensor 37 are on, the CPU 101 turns off the ink pump and closes the ink supply valve. Similarly, even when the pressurized tank liquid level sensor 32 is on and the negative pressure tank liquid level sensor 37 is off, the CPU 101 turns off the ink pump and closes the ink supply valve.

  When the pressurized tank liquid level sensor 32 is off and the negative pressure tank liquid level sensor 37 is on, the CPU 101 turns on the ink pump and closes the ink supply valve.

  When both the pressurized tank liquid level sensor 32 and the negative pressure tank liquid level sensor 37 are off, the CPU 101 turns off the ink pump and opens the ink supply valve.

  Thereafter, the CPU 101 closes the pressurization side air release valve 53 and the negative pressure side air release valve 57. As a result, the pressurizing tanks 21 a and 21 b of the printing units 2 are in a sealed state via the pressurized common air chamber 51, and the negative pressure tanks 24 a and 24 b are in a sealed state via the negative pressure common air chamber 55. .

  Next, the CPU 101 starts pressure control. The pressure control is performed by applying a predetermined positive pressure and negative pressure to the pressurizing tanks 21a and 21b and the negative pressure tanks 24a and 24b, respectively, and maintaining the air pump 59, the pressurizing pressure regulating valve 52, And control of the negative pressure side pressure regulating valve 56.

  Specifically, the CPU 101 activates the air pump 59 when the pressure control is started. As a result, air is sent from the negative pressure common air chamber 55 to the pressurized common air chamber 51, whereby the negative pressure common air chamber 55, the first negative pressure tank 24a, and the second negative pressure tank 24b are depressurized. The pressure common air chamber 51, the first pressure tank 21a, and the second pressure tank 21b are pressurized. As a result, ink flows from the pressurized tanks 21 a and 21 b toward the inkjet head 11.

  When the detected value of the pressurizing side pressure sensor 54 (pressurizing side pressure) and the detected value of the negative pressure side pressure sensor 58 (negative pressure side pressure) become the specified value of the pressurizing side pressure and the specified value of the negative pressure side pressure, respectively, the air pump 59 is stopped. The prescribed values of the pressure side pressure and the negative pressure side pressure are values set in advance as values for keeping the nozzle pressure of the inkjet head 11 within an appropriate range while circulating ink. Here, the CPU 101 sets the pressure side pressure adjustment valve 52 and the pressure side pressure adjustment valve according to the detection values of the pressure side pressure sensor 54 and the pressure side pressure sensor 58 in order to set the pressure side pressure and the pressure side pressure to the specified values. 56 is controlled to adjust the pressure side pressure and the negative pressure side pressure.

  When the CPU 101 determines that the pressurizing side pressure and the negative pressure side pressure have reached the respective specified values, the CPUs 91 and 101 start executing the print job. Specifically, the CPU 91 of the main controller 81 divides the print job into image data and job data, and transmits the job data to the mechanical controller 82. The job data includes information indicating the number of printed sheets, paper type, and the like. Then, the CPU 101 of the mechanical controller 82 causes the transport unit 4 to transport the paper based on the job data. The CPU 91 of the main controller 81 causes ink to be ejected from the inkjet head 11 onto the conveyed paper based on the image data. Thereby, an image is printed on the paper.

  FIG. 7 is a graph showing the fluctuation of the liquid level in the tank during ink circulation. During execution of the print job, ink is supplied from the first pressure tank 21a to the ink chamber 17a of the inkjet head 11, and ink that has not been consumed in the ink chamber 17a is collected in the first negative pressure tank 24a. Further, ink is supplied from the second pressure tank 21b to the ink chamber 17b of the inkjet head 11, and ink that has not been consumed in the ink chamber 17b is collected in the second negative pressure tank 24b. As a result, as shown in FIG. 7, the ink liquid level in the negative pressure tank rises and the ink liquid level in the negative pressure tank falls. Then, the pressurized tank liquid level sensor 32 is turned off and the negative pressure tank liquid level sensor 37 is turned on.

  When the pressurized tank liquid level sensor 32 is turned off, the CPU 101 drives the first ink pump 25a and the second ink pump 25b by liquid level maintenance control. Specifically, the second ink pump 25b sends ink from the second negative pressure tank 24b to the first pressure tank 21a. Further, the first ink pump 25a sends ink from the first negative pressure tank 24a to the second pressure tank 21b. Thereby, as shown in FIG. 7, the liquid level in the negative pressure tank is lowered, and the liquid level in the pressurized tank is raised. Thereafter, the driving of the first ink pump 25a and the second ink pump 25b is stopped, and the ink is fed to the inkjet head 11 by the pressure difference between the pressure tank and the negative pressure tank. In this way, printing is performed while the ink is circulated.

  In this embodiment, when the first ink pump 25a and the second ink pump 25b are driven, the CPU 101 synchronizes the first ink pump 25a and the second ink pump 25b to perform ink circulation, thereby The fluctuation of the circulating pressure caused by the increase or decrease in the liquid level of the ink is suppressed. The synchronization process of the first ink pump 25a and the second ink pump 25b will be described in detail. FIG. 8 is a graph showing the fluctuation of the liquid level in the tank when the ink pump is driven. FIG. 9 is a graph showing the fluctuation of the liquid level in the tank and the circulation pressure when the ink pump is synchronously processed.

  First, driving of the ink pump and fluctuations in the liquid level in the pressure tank and the negative pressure tank connected by the ink pump will be described.

  In FIG. 8, the fluctuation | variation of the liquid level height of the 1st pressurization tank 21a and the 2nd negative pressure tank 24b connected via the 1st ink pump 25a is shown. First, as illustrated in FIG. 4B, the CPU 101 raises the diaphragm 251 of the first ink pump 25 a to increase the volume of the chamber 252, and causes ink to flow into the chamber 252 from the second negative pressure tank 24 b.

  In this case, as shown in FIG. 8, for example, at time t1, the liquid level of the second negative pressure tank 24b drops from the height h6 to the height h5. On the other hand, at this time, since the ink flowing out from the second negative pressure tank 24b is stored in the chamber 252, it does not flow into the first pressurizing tank 21a, and as shown in FIG. There is no change in the liquid level in the pressure tank 21a.

  Thereafter, as shown in FIG. 4 (c), the diaphragm 251 is lowered to forcibly discharge the ink that has just flowed into the first pressure tank 21a. Then, as shown in FIG. 8, at time t2, the liquid level height of the first pressurized tank 21a increases from the height h6 ′ to the height h5 ′ with a delay from the timing when the second negative pressure tank 24b descends. To do. Thereafter, the liquid level height of the second negative pressure tank 24b gradually decreases at the timing of time t3, time t5, time t7, and time t9 by repeatedly raising and lowering the diaphragm 251 of the first ink pump 25a. At the timing of time t4, time t6, and time t8, the liquid level of the first pressurized tank 21a increases.

  Thus, in the 1st pressurization tank 21a and the 2nd negative pressure tank 24b connected with the 1st ink pump 25a, the timing which the liquid level height in each tank changes by the drive of the 1st ink pump 25a. Different. In addition, since the fluctuation | variation of the liquid level height of the 2nd pressurization tank 21b and the 1st negative pressure tank 24a connected via the 2nd ink pump 25b is also the same, the description is abbreviate | omitted.

  Therefore, the CPU 101 synchronizes the driving of the first ink pump 25a and the second ink pump 25b so that the liquid level heights of the adjacent pressurized tank and negative pressure tank change simultaneously. Specifically, as shown in FIG. 9, the liquid level of the first pressurized tank 21a rises at the time t1, time t3, time t5, time t7, and time t9, and the first pressurized tank The ink pumps 25a and 25b are controlled so that the liquid level of the first negative pressure tank 24a adjacent to 21a is lowered.

  Further, the CPU 101 controls the timing at which the liquid level of the second pressurized tank 21b rises and the timing at which the liquid level of the second negative pressure tank 24b adjacent to the second pressurized tank 21b falls simultaneously. To do. The CPU 101 adjusts the ink temperature by controlling the ink temperature adjustment unit 40 so that the temperature detected by the ink temperature sensor 45 is maintained within the appropriate temperature range during ink circulation.

  After starting execution of the print job, the CPU 101 determines whether or not the print job has ended. When determining that the print job has not ended, the CPU 101 repeats the printing process.

  When determining that the print job has ended, the CPU 101 ends the pressure control. Here, when the pressurization side pressure adjustment valve 52 and the negative pressure side pressure adjustment valve 56 are open, the CPU 101 closes them.

  Next, the CPU 101 opens the pressurization side air release valve 53 and the negative pressure side air release valve 57. Thereby, each pressurization tank 21a, 21b of each printing part 2 will be in an air release state via the pressurization common air chamber 51, and each negative pressure tank 24a, 24b will be an air release state via the negative pressure common air chamber 55. It becomes. Then, the CPU 101 ends the printing process.

  As described above, in the inkjet printing apparatus 1, the first ink pump 25a that feeds ink from the first negative pressure tank 24a to the second pressure tank 21b, and the first pressure tank from the second negative pressure tank 24b. 21a is provided with a second ink pump 25b for feeding ink, and the ink liquid is set in each adjacent tank by appropriately controlling the operations of the first ink pump 25a and the second ink pump 25b to be synchronized. Even when the surface height increases or decreases and the circulation pressure fluctuates, the nozzle pressure fluctuations in the first nozzle row 19a and the second nozzle row 19b can be offset or mutually absorbed. Discharging can be realized.

  More specifically, as shown in FIG. 10, in the ink jet printing apparatus 1 having only one pressure tank and one negative pressure tank as in the prior art, the liquid level in the adjacent tank is driven by the ink pump. The timing of fluctuating was different. In the example shown in FIG. 10, the liquid level of the negative pressure tank decreases at the timing of time t1, time t3, time t5, time t7, and time t9, and at the timing of time t2, time t4, time t6, and time t8. The liquid level of the pressurized tank was rising.

  For this reason, in the conventional ink jet printing apparatus 1, the circulation pressure varies. Specifically, as shown in FIG. 10, at the timing when the liquid level drops only in the negative pressure tank, only the air chamber portion in the negative pressure tank is expanded and depressurized. Lower than the circulating value. As a result, the nozzle pressure may shift and ink ejection may become unstable.

  On the other hand, in the present embodiment, the adjacent pressurized tank and negative pressure tank are configured to be driven by different first ink pumps 25a or 25b. Therefore, as shown in FIG. 9, the pressurized tank Since the liquid level rises at the same time as the liquid level rises at the negative pressure tank adjacent to the pressurized tank, the liquid level height of the ink in each tank increases or decreases. Even when the circulation pressure fluctuates, the nozzle pressure fluctuations in the first and second nozzle arrays can be offset or mutually absorbed. As a result, stable ejection in the inkjet head 11 can be realized.

  In this embodiment, ink is ejected from each of the first nozzle row 19a and the second nozzle row 19b, but for example, one of the first nozzle row 19a or the second nozzle row 19b. You can also use ink alone. In the inkjet printing apparatus 1, even for the same color, 600 dpi and 300 dpi may be properly used depending on the head gap, and ink may be consumed only in one nozzle row.

  In this case, since the liquid can be fed from the negative pressure tank on the nozzle side with a small amount of use to the pressure tank on the nozzle side with a large amount of use, the number of times of ink replenishment during printing can be reduced, The nozzle pressure fluctuation due to the fluctuation can be suppressed, and the ink is hardly withered.

  In the above embodiment, the head module 16 for each color has the ink chamber 17a and the ink chamber 17b, and the two first nozzle rows 19a and the second nozzle rows 19b are formed. The ink chamber 17a and the ink chamber 17b may be formed only for black (K). In this case, the printing resolution can be increased more than other colors.

In the above embodiment, the head module 16 is formed by a single full-line type ink jet head. However, for example, by arranging the short head modules 16 in a staggered manner, the head module 16 is pseudo-full. A line inkjet head may be formed.
The present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the components without departing from the scope of the invention in the implementation stage. Various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiments. For example, some components may be deleted from all the components shown in the embodiment.

DESCRIPTION OF SYMBOLS 1 ... Inkjet printing apparatus 2 ... Printing part 3 ... Pressure adjustment part 4 ... Conveyance part 5 ... Control part 11 ... Inkjet head 12 ... Ink circulation part 13 ... Ink supply part 16 ... Head module 17a, 17b ... Ink chamber 18 ... Nozzle 19a First nozzle row 19b Second nozzle row 21a First pressure tank 21b Second pressure tank 24a First negative pressure tank 24b Second negative pressure tank 25a First ink pump 25b Second ink Pump 51 ... Pressure common air chamber 54 ... Pressure side pressure sensor 55 ... Negative pressure common air chamber 58 ... Negative pressure side pressure sensor 59 ... Air pump 91, 101 ... CPU
251 ... Diaphragm 252 ... Chamber

Claims (1)

An inkjet head having a first nozzle row and a second nozzle row, and ejecting ink from the first and second nozzle rows;
A first supply tank for storing ink to be supplied to the first nozzle row;
A first reflux tank for storing ink returned from the first nozzle row;
A second supply tank for storing ink to be supplied to the second nozzle row;
A second reflux tank for storing ink returned from the second nozzle row;
A first circulation path for the ink to circulate from the first supply tank to the first reflux tank via the inkjet head;
A second circulation path for circulating ink from the second supply tank to the second reflux tank through the inkjet head;
First liquid feeding means for feeding ink from the first reflux tank to the second supply tank;
A second liquid feeding means for feeding ink from the second reflux tank to the first supply tank;
An ink jet printing apparatus, wherein the ink is fed in synchronization with the operation timing of the first liquid feeding means and the second liquid feeding means.

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