JP4492171B2 - Liquid ejecting apparatus and liquid ejecting apparatus cleaning method - Google Patents

Description

  The present invention relates to a liquid ejecting apparatus that ejects liquid onto a target and a cleaning method for the liquid ejecting apparatus.

2. Description of the Related Art Conventionally, ink jet recording apparatuses have an ink jet recording head for ejecting ink onto recording paper or the like. The ink jet recording head is provided with an ink cartridge containing ink in order to supply ink to the ink jet recording head. This ink cartridge is detachable.
For this reason, for example, when the ink cartridge is replaced, bubbles may be mixed into the ink.
On the other hand, the ink in the ink cartridge is introduced into the ink jet recording head, and the ink jet recording head is provided with a filter for preventing entry of foreign matters or the like mixed in the ink.
For this reason, the air bubbles mixed when the ink cartridge is replaced do not flow into the ink jet recording head by the filter.

Thus, if bubbles remain in the filter, the effective area of the filter decreases and the efficiency of the filter decreases. For this reason, as shown in Patent Document 1, an ink jet recording head is tilted to provide a recess for trapping bubbles remaining in the vicinity of the filter (for example, Patent Document 1).
JP 2000-177144 A (FIG. 2 etc.)

However, in the proposal described in Patent Document 1, it is necessary to tilt the ink jet recording head. For this reason, when the attitude of the ink jet recording apparatus changes, such a proposal cannot eliminate the influence of bubbles, and it is necessary to suck the ink from the nozzles of the ink jet recording head with a suction pump and discharge the bubbles together with the ink. is there.
At this time, although the amount of ink required for discharging differs depending on the position of the bubble in the filter, it is unclear at which position the bubble is present. Therefore, in order to reliably discharge the air bubbles, it is necessary to suck ink with a suction pump or the like, assuming that the air bubbles stay in a portion that is difficult to discharge.
In this case, there is a problem that wasteful ink is consumed and it is uneconomical. In addition, since the amount of ink sucked is large, the cleaning time is long, and there is a problem that it is difficult for the user to use.

  SUMMARY An advantage of some aspects of the invention is to provide a liquid ejecting apparatus and a cleaning method for the liquid ejecting apparatus that can efficiently operate the cleaning unit without waste.

  According to the first aspect of the present invention, there is provided, according to the first invention, a discharge opening that discharges liquid to a target, and a cleaning unit that is disposed with respect to the discharge opening and that cleans at least the discharge opening. A liquid ejecting apparatus comprising: a cleaning unit control unit that controls the operation of the cleaning unit; and a cleaning unit control unit management information storage unit that stores cleaning unit control unit management information for controlling the cleaning unit control unit. In addition, position change information acquisition means for acquiring position change information that is a change in the arrangement position of the liquid ejecting apparatus, and posture change information generation information for generating attitude change information of the liquid ejecting apparatus based on the position change information Posture change information generation information storage means for storing the cleaning means control unit management information, It is accomplished by liquid-jet apparatus characterized being generated based on the change information.

According to the configuration of the first aspect of the invention, the position change information acquisition unit that acquires position change information that is a change in the arrangement position of the liquid ejecting apparatus, and the posture change information of the liquid ejecting apparatus based on the position change information. Posture change information generation information storage means for storing posture change information generation information to be generated.
For this reason, the liquid ejecting apparatus can acquire the posture change information such as the inclination.
In addition, since the cleaning unit control unit management information of the liquid ejecting apparatus is generated based on the posture change information, the cleaning unit can be operated in accordance with the posture change of the liquid ejecting apparatus such as its inclination. The cleaning means can be operated efficiently without waste.

  Preferably, according to the second invention, in the configuration of the first invention, the position change information acquisition means is an acceleration sensor, and the posture change information is defined corresponding to a detection direction of the acceleration sensor. In addition, the liquid ejecting apparatus includes information on an angle range formed by the specified axial direction and the gravity direction.

  According to the configuration of the second invention, the posture change information includes angle range information formed by a prescribed axis direction and a gravity direction defined corresponding to the detection direction of the acceleration sensor. Simple and accurate acquisition is possible.

  Preferably, according to the third invention, in the configuration of the second invention, the specified axial direction is arranged in a normal direction of a filter surface arranged for filtering the liquid supplied to the discharge opening. This is a liquid ejecting apparatus.

According to the structure of 3rd invention, it arrange | positions in the normal line direction of the filter surface arrange | positioned in order to filter the said liquid supplied to the said discharge opening part. For this reason, since the posture change information such as the inclination of the filter surface can be acquired, it is possible to predict whether bubbles or the like staying on the filter surface are present at a position where they are easily discharged by the cleaning means.
And the most efficient cleaning which can discharge | emit the bubble etc. which exist in the estimated position can be performed.

  Preferably, according to the fourth invention, in any one of the configurations of the first to third inventions, the movement disposed in the liquid communication part that communicates the liquid storage part that stores the liquid and the discharge opening. The cleaning means has a negative pressure generating valve, and the cleaning means includes a capping portion arranged to cover the discharge opening, and a suction means for sucking the liquid from the discharge opening, and the cleaning means control part management The information is recovery operation information for selectively operating the dynamic negative pressure generating valve and / or the suction means.

According to the configuration of the fourth aspect of the invention, the liquid ejecting apparatus has the dynamic negative pressure generating valve and the suction means. Therefore, by using the dynamic negative pressure generating valve, it is possible to select, as the recovery operation information, choke cleaning or the like that vigorously discharges the liquid from the discharge opening, and at the same time, the dynamic negative pressure By not using the generating valve, normal cleaning or the like can also be selected.
That is, it is possible to select the optimal recovery operation information of the cleaning means in accordance with the change in the attitude of the liquid ejecting apparatus.

  Preferably, according to a fifth aspect of the invention, in the configuration of the fourth aspect of the invention, the recovery operation information includes the liquid suction amount information by the suction means.

  According to the configuration of the fifth aspect of the invention, since the recovery operation information includes information on the amount of liquid sucked by the suction means, the strength of cleaning by the suction means can be controlled by the magnitude of the suction amount. For this reason, it is possible to control the operation of the cleaning means more accurately and efficiently.

  Preferably, according to the sixth invention, in any one of the first to fifth inventions, the cleaning means control unit management information includes posture change notification information of the liquid ejecting apparatus. The liquid ejecting apparatus is characterized.

According to the configuration of the sixth aspect of the invention, the cleaning means control unit management information includes posture change notification information of the liquid ejecting apparatus. For this reason, when it is necessary to change the posture of the liquid ejecting apparatus in order to effectively operate the cleaning means, it is possible to notify the user or the like to that effect.
Therefore, it is possible to prevent unnecessary execution of the operation of the cleaning means.

  According to a seventh aspect of the present invention, the position change information acquisition means acquires a position change information that is a change in the arrangement position of the liquid ejecting apparatus, and the position change information acquisition step is based on the position change information. An attitude change information generating step for generating attitude change information of the liquid ejecting apparatus; and a cleaning means control step in which the cleaning means control section controls the cleaning means based on the cleaning means control section management information. The cleaning means control unit management information in the control process is generated based on the posture change information, and is achieved by a liquid ejecting apparatus cleaning method.

  According to the configuration of the seventh invention, as in the first invention, since the cleaning unit control unit management information of the liquid ejecting apparatus is generated based on the posture change information, the inclination of the liquid ejecting apparatus, etc. Since the cleaning means can be operated in accordance with the posture change, the cleaning means can be operated efficiently without waste.

Preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
The embodiments described below are preferred specific examples of the present invention, and thus various technically preferable limitations are given. However, the scope of the present invention is particularly limited in the following description. Unless otherwise stated, the present invention is not limited to these embodiments.

FIG. 1 is a schematic perspective view showing an ink jet recording apparatus (hereinafter referred to as “recording apparatus 10”) 10 according to an embodiment of a liquid ejecting apparatus of the invention.
(About the general configuration of the recording apparatus 10)
As shown in FIG. 1, the recording apparatus 10 has a main body 11. The main body 11 is placed on the mounting base B, for example.
The main body 11 has a box shape as shown in FIG. 1 and can be arranged so that the main body bottom surface 11A, which is the bottom side in the figure of the main body 11, comes into contact with the mounting base B. The main body part back surface 11 </ b> B, which is the back side of the main body part 11, can be arranged so as to contact the mounting base B.
In addition, the recording apparatus 10 includes, for example, ink cartridges 2 to 5 that are liquid storage units that store ink, for example, and are ink jet recording heads that eject ink onto a target such as paper 29. 30 (hereinafter referred to as “recording head 30”). The ink cartridge 2 and the recording head 30 are mounted on the carriage 14.

The carriage 14 is configured to be movable along the head scanning axis 17. A platen 12 for supporting the paper 29 is also arranged.
Furthermore, the recording apparatus 10 includes an acceleration sensor 8 that detects a change in posture of the recording apparatus 10. That is, the acceleration sensor 8 is an example of a position change information acquisition unit that acquires position change information that is a change in the arrangement position of the recording apparatus 10. The position change information is acceleration data, for example, as will be described later.
In addition, the acceleration sensor 8 is configured to detect a change in position such as a tilt when the main body 11 of FIG. 1 is held by a user and the main body 11 is tilted.

As shown in FIG. 1, the recording apparatus 10 may be provided with a position switch 18 together with or instead of the acceleration sensor 8. This position switch 18 is arranged on the grounding surface of the main body 11, in FIG. 1, the main body bottom 11 A, the main body rear 11 B, the main body right side 11 C, and the main body left side 11 D. And when the said surface is arrange | positioned on the mounting base B, a switch will be turned on and the attitude | position of the recording device 10 will become clear. That is, the position switch 18 is an example of a position change information acquisition unit.
The main body 11 is provided with a switch 99 for operating the ink suction device 20 of the recording apparatus 10.

(Relationship between recording head 30 and ink cartridge 2)
FIG. 2 is a schematic cross-sectional view showing a main arrangement state of the recording head 30 and the ink cartridges 2 to 5 shown in FIG.
The recording apparatus 10 stores inks of different colors in the ink cartridges 2 to 5 shown in FIG. 2, particularly when used as a color printer. An ink path 50 for connecting to each of the ink cartridges 2 to 5 is formed in the recording head 30.
The ink guided into the recording head 30 is guided to the nozzle plate 62 through the ink path 50 after the bubbles of the ink are removed by the filter 340.

FIG. 3 is a schematic diagram illustrating a main internal configuration of the recording head 30. As shown in FIG. 3, the ink guided by the ink path 50 of the recording head 30 is accommodated in the pressure chamber 51.
When a voltage is applied to the piezoelectric vibrator 39 disposed in the upper portion of the pressure chamber 51 in FIG. 3 to expand and contract, and pressure is applied to the pressure chamber 51, the ink in the pressure chamber 51 is transferred to the nozzle plate 62. It is configured to discharge from the nozzle opening 55A or the like which is the discharge opening formed in the.

FIG. 4A is a schematic enlarged view of a portion indicated by an arrow Z in FIG. As shown in FIG. 4A, the ink cartridge 3 and the filter chamber 340 of the recording head 30 are connected by a joint portion 70.
The ink cartridge 3 is provided with a pressure adjustment valve 700. The pressure regulating valve 700 is a static negative pressure generating unit for maintaining the static negative pressure (back pressure) at the nozzle opening 55A and the like in FIG. 3 within an appropriate range. That is, by adjusting the pressure adjustment valve 700, the static negative pressure in the nozzle opening 55A and the like is in an appropriate range, and a normal meniscus can be generated in the ink in the nozzle opening 55A and the like.
For this reason, the accuracy of the ink droplets to be ejected is increased by the expansion and contraction of the piezoelectric vibrator 39 in FIG. 3, thereby preventing the occurrence of ejection failure.

On the other hand, on the recording head 30 side of the joint portion 70, for example, a choke valve 80 which is a dynamic negative pressure generating valve is provided. Details of the choke valve 80 will be described later.
Further, a filter chamber 340 is formed on the ink path 50 side of the choke valve 70, and the filter 70 is disposed therein.
The filter 70 is arranged to remove bubbles and the like that are mixed when the ink cartridge 3 is replaced, etc., and to guide ink that does not contain bubbles to the ink path 50, so to speak, it functions to filter the ink.

FIG. 4B is a schematic explanatory diagram showing the state of bubbles in the filter chamber 340 of FIG. As shown in FIG. 4B, the bubble K1 stays on the surface of the filter 340a by the filter 340a. If bubbles remain on the surface of the filter 340a, the effective area of the filter 340a decreases accordingly, so that it is preferably removed as much as possible.
When the attitude of the recording apparatus 10 is tilted, the bubbles are moved to the position of K2, for example, under the influence of the direction of gravity.

(Ink suction device 20 etc.)
FIG. 5 is a schematic view showing the ink suction device 20 and the like in the main body 11 of FIG. As shown in FIG. 5, an ink suction device 20 is disposed in the main body 11.
The ink suction device 20 has a capping portion 19A disposed so as to contact the nozzle plate 62 of FIG. 3 and cover the nozzle openings 55A and the like. The capping portion 19A is configured to be able to advance and retract with respect to the nozzle plate 62.
The ink suction device 20 is a suction unit for sucking unnecessary ink or the like from the nozzle opening 55A or the like while the capping portion 19A is in contact with the nozzle plate 62 and making the inside negative pressure. 19B.
That is, the ink suction device 20 is an example of a cleaning unit that is disposed with respect to the nozzle openings 55A and the like and cleans the nozzle openings 55A and the like.

  Incidentally, the recording apparatus 100 is formed with a choke valve 80 as shown in FIG. For this reason, the choke valve 80 and the ink suction device 20 shown in FIG.

(About chalk cleaning)
With the ink suction device 20 shown in FIG. 5 in contact with the nozzle plate 62 of FIG. 3, the choke valve 80 of FIG. 4A is operated in the closing direction. Then, the atmosphere in the capping portion 19A is sucked by the suction pump 19B.
Then, the negative pressure in the capping portion 19A increases, and the negative pressure also increases at the nozzle opening 55A and the like.
Next, the choke valve 80 in FIG. 4A is operated in the opening direction. Then, the ink flows vigorously from the ink cartridge 3 side to the nozzle opening 55A and the like.
With such a flow of ink, the bubbles K1 and K2 in FIG. 4B do not stay in the filter 340a and are discharged from the nozzle openings 55A and the like.
That is, the choke valve 80 is disposed in a liquid communication portion (an ink flow path connecting the ink cartridge 3 and the ink path 50 shown in FIG. 4A) that communicates the ink cartridge 3 and the nozzle opening 55A and the like. ing.

As described above, the cleaning operation of the recording apparatus 10 includes normal cleaning performed only by the ink suction apparatus 20 and chalk cleaning that discharges ink vigorously.
The recording apparatus 10 can select a normal cleaning operation or a choke cleaning operation, and a normal cleaning operation using only the ink suction device 20 is weaker by adjusting the amount of ink sucked by the suction pump 19B. The structure can be changed from the suction state to the strong suction state for a while.

(About a block diagram showing the main configuration of the recording apparatus 10)
FIG. 6 is a schematic block diagram showing the main configuration of the recording apparatus 10 shown in FIG.
The recording apparatus 10 includes a control device 7, and the control device 7 is connected to a printer driver 41 of the host computer 40 via a local printer cable or a communication network.
The printer driver 41 is equipped with software that sends a command for executing printing, cleaning operation, or ink suction operation to each component of the recording apparatus 10.

The control device 7 is connected to the acceleration sensor 8 and the switch 99 in FIG. 1 and is connected to the suction pump 19B, the capping unit 19A, the ink cartridge 2, the recording head 30, the carriage 14, and the like, and controls their operations. It is the composition to do.
1 is also connected to the drive unit of the conveyance belt 15 that conveys the paper 29 in FIG. Further, the choke valve 80 is connected to the choke valve 80 of FIG.

  In the embodiment of FIG. 1, the plurality of ink cartridges 2 to 5 are of an on-carriage type that is directly mounted on the carriage 14, but not limited to this, the ink cartridges 2 to 5 are carriages. Of course, an off-carriage type mounted at another position may be used.

FIG. 7 is a schematic explanatory diagram describing the schematic block diagram of the recording apparatus 10 of FIG. 6 in more detail.
The acceleration sensor 8 shown in FIG. 7 is provided in the main body 11 as shown in FIG. The acceleration sensor 8 is a sensor for detecting the installation posture of the recording apparatus 10, that is, the state where the main body 11 is mounted on the mounting base B.
As shown in FIG. 7, the acceleration sensor 8 inputs, for example, acceleration data D1 that is position change information to the specified axis inclination calculation unit 600 via a CPU (Central Processing Unit) 601.
The specified axis inclination calculation unit 600 calculates g · cos θ from the inner product of the unit vector of the specified axis and the detected acceleration vector based on the acceleration data D1.

FIG. 8 is a schematic explanatory diagram illustrating a method in which the specified axis inclination calculation unit 600 detects a change in posture.
As shown in FIG. 8, the specified axis inclination calculation unit 600 can detect the inclination of the main body 11 around the specified axis L that is a reference at the time of angle detection. The prescribed axis L is a direction perpendicular to the main body bottom surface 11A of FIG. The main body bottom surface 11A is in the normal direction of the surface of the filter 340a in FIG. 4B. That is, the specified axis L is an example of a specified axis defined in correspondence with the detection direction of the acceleration sensor 8. It is.
The prescribed axis L is directed downward in the gravity direction, that is, a direction parallel to the direction in which ink is ejected from the nozzle openings of the recording head 30 is defined as a positive direction and the opposite direction is defined as a negative direction.

On the other hand, as shown in FIG. 8, the gravity direction (gravity axis) is the detection axis L1, and the angle θ formed by the detection axis L1 and the defined axis L is angle range information, which is the posture change information.
That is, the specified axis inclination calculation unit 600 calculates g · cos θ from the inner product of the unit vector of the specified axis and the detected acceleration vector based on the acceleration data D1, and the data of this calculation method is stored in the storage unit 603. Has been.
In other words, the attitude change information of the recording apparatus 10 is generated by calculating the data of this calculation method based on the acceleration data D1 (position change information). Therefore, the storage unit 603 is an example of a posture change information generation information storage unit that stores posture change information generation information.
By the way, when the specified axis L is one axis, the inner product is not necessarily required because the inner product is the detected value.

Further, as the type of the acceleration sensor 8, for example, a capacitance type or a piezoresistive type can be adopted. As the capacitance type, for example, a structure in which a weight of polycrystalline silicon is supported by a spring can be adopted, and the inclination angle θ of the main body 11 with respect to the specified axis L can be changed by changing the capacitance by the movement of the weight. Is detected. The piezoresistive type detects the tilt angle θ of the main body 11 with respect to the specified axis L by utilizing the piezoresistance effect, that is, the change in resistivity in proportion to the stress.
When the specified axis of the acceleration sensor 8 is one axis, the direction of the axis to be detected is matched with the specified axis. When there are two specified axes, the detection axis is set so that an in-plane component including the two specified axes can be detected. When there are three or more prescribed axes, the direction of the detection axis is not particularly limited if a three-axis acceleration sensor is used.

By the way, as shown in FIG. 7, the specified axis inclination calculation unit 600 supplies specified axis inclination (θ) data (attitude information) D <b> 2 to a CPU (central processing unit) 601.
On the other hand, when the user of the recording apparatus 10 desires a cleaning operation, the cleaning command D4 is input to the CPU 601 via the interface 605 by turning on the switch 99 in FIG.
Receiving the cleaning command D4, the CPU 601 acquires sequence information D5 from the storage unit 603 based on the specified axis tilt (θ) data D2. The CPU 601 is configured to control the pump drive source controller 19C of the suction pump 19B and the choke valve controller 80a of the choke valve 80 based on the sequence information D5.
That is, the pump drive source control unit 19C inputs the pump drive amount command D6 to the suction pump 19B. Then, the motor of the suction pump 19B is driven and the suction pump 19B is operated.
The choke valve control unit 80a is configured to turn on or off the choke valve 80 by inputting a choke valve ON / OFF command D7 to the choke valve 80.

The pump drive source controller 19C and the choke valve controller 80a are an example of a cleaning unit controller that controls the operation of the ink suction device 20. The sequence information D5 and the like is an example of the cleaning unit control unit management information for controlling the pump drive source control unit 19C and the like, and the storage unit 603 for storing the sequence information D5 stores the cleaning unit control unit management information. It is an example of a means.
Further, the sequence information D5 stored in the storage unit 603 is generated based on the prescribed axis inclination (θ) data D2.

Further, when the sequence information D5 is the posture change notification information of the recording apparatus 10 that is an operation other than the cleaning operation by the ink suction device 20 or the choke valve 80, the CPU 601 includes warning information D8 that is the posture change notification information. Input to the printer driver 41.
As will be described later, this posture change notification information is, for example, because the posture is too tilted. This is information for requesting a change from the user.
Incidentally, the clock generator 604 in FIG. 7 supplies a clock signal to the CPU 601.

(About information stored in the storage unit 603)
First, the storage unit 603 stores suction sequence information that is different between normal cleaning and chalk cleaning in the cleaning operation.
(About suction sequence information)
In the normal cleaning, first, ink is sucked from the nozzle openings 55A and the like in a state where the capping portion 19A of the ink suction device 20 is in contact with the nozzle plate 62. Next, the inside of the capping unit 19 </ b> A is released to the atmosphere, and empty suction for sucking ink in the capping unit 19 is performed. Finally, the suction of the nozzle opening 55A and the like is performed again.
The last suction of the nozzle opening 55A or the like is an operation for sucking bubbles or the like drawn into the nozzle opening 55A or the like.

In the choke cleaning, the choke valve 80 is closed and the suction pump 19B is driven with the capping portion 19A in contact with the nozzle plate 62 before the above-described normal cleaning, and then the choke valve 80 is opened. In this way, the operation is performed to eject ink from the nozzle openings 55A and the like.
Choke cleaning is a stronger cleaning operation than normal cleaning, and air bubbles that cannot be discharged by normal cleaning by flowing ink from the ink cartridge 3 or the like to the nozzle opening 55A or the like vigorously to the nozzle opening 55A or the like side. This is cleaning for discharging (for example, FIG. 4B, the bubble K2).
This chalk cleaning is a powerful cleaning, but has a drawback that the amount of ink discharged is large and the amount of ink consumed is large.

(Correlation diagram between the inclination of the specified axis for bubble discharge (θ) and the required suction amount)
As shown in FIG. 9, the storage unit 603 stores the amount of ink that needs to be sucked in order to discharge bubbles in the cleaning operation based on the specified axis tilt data D2 of the recording apparatus 10 (all inks in the above-described suction sequence operation). Data indicating the suction amount) is stored separately for normal cleaning and choke cleaning.
That is, FIG. 9 is data showing a correlation diagram between the inclination (θ) of the prescribed axis for discharging bubbles and the required suction amount.
Specifically, when the recording apparatus 10 of FIG. 1 is arranged on the mounting base B without being inclined, the main body 11 has the detection axis L1 and the specified axis L of FIG. ° (degrees). Since the specified axis L is also a normal line of the surface of the filter 340a in FIG. 4B, the inclination (θ) of the specified axis is also the inclination of the surface of the filter 340a.
When the inclination of the surface of the filter 340 a is 0 ° (degrees), there is a high probability that the bubbles of the filter 340 a are located in the central region of the filter 340.

In order to discharge bubbles when the inclination of the surface of the filter 340a is 0 ° (degrees), according to the data of FIG. 9, the required suction amount of ink is 20 in normal cleaning, whereas it is 25 in choke cleaning. It has become.
That is, the data in FIG. 9 determines that air bubbles located in the central region of the filter 340a can be easily discharged because they are easily discharged. Therefore, the sequence information D5 in FIG. 7 is information indicating that the suction pump 19B is driven so that the total suction amount of ink becomes 25 in the normal cleaning suction sequence.
As described above, according to the data of FIG. 9, when the inclination (θ) of the specified axis is 0 ° (degrees) to 40 ° (degrees), normal cleaning eliminates bubbles with less ink suction than chalk cleaning. I understand that I can do it.

Then, when the inclination (θ) of the specified axis is over 40 ° (degrees) to 80 ° (degrees), the choke cleaning indicates that bubbles can be discharged with a smaller ink suction amount than the normal cleaning. .
That is, according to the data of FIG. 9, it is recovery operation information for selectively operating the choke valve 80 and / or the ink suction device 20 as bubble discharge cleaning or the like.

  Further, from 80 ° (degrees) to 100 ° (degrees), bubbles can be discharged by chalk cleaning, but the ink suction amount exceeds 35 and a large amount of ink is consumed. The configuration is such that the warning information can be generated such that the posture is changed and the inclination (θ) of the prescribed axis is, for example, less than 80 degrees.

As described above, the CPU 601 in FIG. 7 performs sequence information D5 (FIG. 7) including the suction sequence (normal cleaning or chalk cleaning), the suction amount, and the like based on the inclination (θ) of the specified axis and the data in FIG. 9 in the storage unit 603. And the pump drive source controller 19C and the choke valve controller 80a are controlled according to the sequence information D5.
If the sequence information D5 is a posture change warning, the warning information D8 is supplied to the printer driver 41 via the interface 605.
Therefore, when the user of the recording apparatus 10 turns on the switch 99 in FIG. 1 and the cleaning command D4 is input, the suction sequence that is most efficient in the attitude of the recording apparatus 10 (the attitude of the filter 340a surface). Then, the ink suction amount is determined and the cleaning operation is performed. For this reason, the ink suction device 20 and the like can be operated efficiently without waste.

  Since the inclination (θ) of the specified axis is a normal line of the surface of the filter 340a, the inclination of the filter 340a can be obtained with high accuracy, so that the bubble K1 shown in FIG. The position of K2 can be predicted with high accuracy. The bubbles K1 and K2 can be efficiently discharged with the smallest amount of ink.

  Further, when the ink consumption becomes excessive when the suction sequence is operated, posture change warning information D8 is notified, so that the user avoids unnecessary ink consumption and changes the posture of the recording apparatus 10. In addition, it is possible to operate a suction sequence that consumes less ink.

Although the recording apparatus 10 of the present embodiment is configured as described above, an example of the operation will be described below.
(Regarding the specified axis tilt (θ) 0 ° (degrees))
A description will be given of a case where the user of the recording apparatus 10 in which bubbles are mixed by exchanging the ink cartridge 3 or the like turns on the switch 99 to perform cleaning in the recording apparatus 10 arranged as shown in FIG. To do. The position of the bubble is the central portion K1 in FIG.

  First, as shown in FIG. 7, the acceleration sensor 8 detects a change in posture of the recording apparatus 10 (an example of a position change information acquisition step), and inputs the change as acceleration data D1 to the regulation axis inclination calculation unit 600.

  Next, the specified axis inclination calculation unit 600 generates specified axis inclination (θ) data D2 (an example of a posture change information generation step). Specifically, the specified axis inclination (θ) data D2 is generated based on the angle θ formed by the detection axis L1 and the specified axis L in FIG. In this example, since it is not tilted, the specified axis tilt (θ) data D2 indicating that the posture is tilted by 0 ° (degree) is generated and input to the CPU 601.

On the other hand, normal cleaning is selected as the suction sequence for the specified axis inclination (θ) from the correlation diagram data of the specified axis inclination (θ) and the required suction amount for discharging bubbles in FIG. Then, 20 is selected as the suction amount.
7 having such information is input to the CPU 601, the pump drive source control unit 19C is driven, the suction pump 19B and the like are driven (an example of a cleaning unit control step), and cleaning is performed. At this time, no drive signal is input to the choke valve control unit 80a.
With this normal cleaning operation, the bubble K1 located at the center of the filter 340a in FIG. 4B is discharged.

(For the case where the specified axis is tilted (θ) 60 ° (degrees))
The recording device 10 in which air bubbles are mixed by replacing the ink cartridge 3 will be described in the case where the switch 99 is turned on in order to perform cleaning with the user tilted by 60 degrees. It is K2 spaced apart from the center of 4 (b).
First, the prescribed axis inclination calculation unit 600 in FIG. 7 determines that the prescribed axis inclination (θ) is 60 ° (degrees). Then, the choke cleaning and the suction amount 28 are selected from the data of FIG. Then, choke cleaning is performed via the pump drive source controller 19C and the choke valve controller 80a in FIG. 7, and the bubble K2 in FIG. 4B is discharged.

  As described above, the bubble position can be grasped, and the suction sequence and the suction amount that are most efficient for the discharge can be easily and accurately executed. For this reason, even if the posture change is various as in the mobile (for carrying) type recording apparatus 10, an appropriate cleaning operation can always be performed.

  The present invention is not limited to the above embodiment as an ink jet recording apparatus, and various modifications can be made without departing from the scope of the claims. Furthermore, the above-described embodiments may be combined with each other. Further, the present invention is not limited to an ink jet recording apparatus, but a recording head used in an image recording apparatus such as a printer, a color material ejection head used in manufacturing a color filter such as a liquid crystal display, an organic EL display, and an FED (surface emitting). Electrode material ejecting heads used for electrode formation such as displays), liquid ejecting apparatuses using liquid ejecting heads for ejecting liquids such as bioorganic ejecting heads used for biochip manufacturing, sample ejecting apparatuses as precision pipettes, etc. Applicable.

1 is a schematic perspective view illustrating an ink jet recording apparatus according to an embodiment of a liquid ejecting apparatus of the invention. FIG. 2 is a schematic cross-sectional view illustrating a main arrangement state of a recording head and an ink cartridge illustrated in FIG. 1. FIG. 2 is a schematic diagram illustrating a main internal configuration of a recording head. (A) is a schematic enlarged view of the part shown by the arrow Z of FIG. 2, (b) is a schematic explanatory drawing which shows the state of the bubble in the filter chamber of (a). It is the schematic which shows the ink suction device etc. in the main-body part of FIG. FIG. 2 is a schematic block diagram illustrating a main configuration of the recording apparatus illustrated in FIG. 1. It is the schematic explanatory drawing which described the schematic block diagram of the recording device of FIG. 6 further in detail. It is a schematic explanatory drawing which shows the method in which a regular axis inclination calculating part detects the change of a posture. It is data which shows the correlation diagram of the inclination ((theta)) of the prescription | regulation axis | shaft for bubble discharge | emission, and required suction | attraction amount.

Explanation of symbols

  2, 3, 4, 5 ... Ink cartridge, 7 ... Control device, 10 ... Inkjet recording device, 11 ... Main unit, 11A ... Bottom of main unit, 11B ... Main unit Back surface, 14 ... carriage, 15 ... transport belt, 17 ... head scanning axis, 18 ... position switch, 19 ... pump, 19A ... capping unit, 19B ... suction pump, 19C: Pump drive source controller, 20 ... Ink suction device, 29 ... Paper, 30 ... Inkjet recording head, 40 ... Host computer, 50 ... Ink path, 55A to 55D ... nozzle opening, 62 ... nozzle plate, 70 ... joint part, 80 ... choke valve, 80a ... choke valve control part, 99 ... switch, 100 ... waste liquid tank, DESCRIPTION OF SYMBOLS 40 ... Filter room, 340a ... Filter, 600 ... Prescription axis inclination calculating part, 601 ... CPU, 603 ... Memory | storage part, 604 ... Clock generation part, 605 ... Interface, B: A mounting base.

Claims (6)

A discharge opening for discharging liquid to the target;
A liquid communication part for communicating the liquid storage part for storing the liquid and the discharge opening; and
A filter and a dynamic negative pressure generating valve for retaining bubbles in the liquid communication part;
A suction means for sucking the liquid from the discharge opening, and a cleaning means for discharging bubbles accumulated in the filter by the suction means ;
A cleaning means controller for controlling the operation of the cleaning means;
A liquid ejecting apparatus comprising: cleaning means control section management information storage means for storing cleaning means control section management information for controlling the cleaning means control section,
Position change information acquisition means for acquiring position change information which is a change in the arrangement position of the liquid ejecting apparatus;
Posture change information generation information storage means for storing posture change information generation information for generating posture change information of the liquid ejecting apparatus based on the position change information;
The cleaning means control unit management information is recovery operation information for selectively operating the dynamic negative pressure generating valve and the suction means, and is generated based on the posture change information. apparatus.   The position change information acquisition means is an acceleration sensor, and the posture change information includes angle range information formed by a prescribed axis direction defined in correspondence with a detection direction of the acceleration sensor and a gravity direction. The liquid ejecting apparatus according to claim 1.   The liquid ejecting apparatus according to claim 2, wherein the prescribed axial direction is arranged in a normal direction of a filter surface arranged for filtering the liquid supplied to the discharge opening. The liquid ejecting apparatus according to claim 1 , wherein the recovery operation information includes information on a suction amount of the liquid by the suction unit. Wherein the cleaning unit controller management information, a liquid ejecting apparatus according to any one of claims 1 to 4, characterized in that it contains the posture change notification information of the liquid ejecting apparatus. A discharge opening for discharging liquid to the target;
A liquid communication part for communicating the liquid storage part for storing the liquid and the discharge opening; and
A filter and a dynamic negative pressure generating valve for retaining bubbles in the liquid communication part;
A suction means for sucking the liquid from the discharge opening, and a cleaning means for discharging bubbles accumulated in the filter by the suction means;
A cleaning means controller for controlling the operation of the cleaning means;
Cleaning means control section management information storage means for storing cleaning means control section management information for controlling the cleaning means control section;
Position change information acquisition means,
The location change information acquiring unit, a position change information acquisition step of acquiring positional change information is the change in position of the liquid ejecting apparatus,
A posture change information generating step for generating posture change information of the liquid ejecting apparatus based on the position change information;
The cleaning unit controller has a, a cleaning means controlling process of controlling the cleaning unit based on the cleaning means control unit management information,
Characterized in that said cleaning means and said the cleaning means controller management information is dynamic negative pressure generating valve and the recovery operation information for selectively operating said suction means of the control process, are generated based on the posture change information A method for cleaning a liquid ejecting apparatus.

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