The present invention relates to an ink jet type printing apparatus including a mechanism for wiping a nozzle surface, and more particularly to a printing apparatus that can appropriately prevent an apparatus from ink scattering when ink adhering to a wiper blade is scraped off without an increase in size and complexity of the apparatus.
In the related art, an ink jet type printer is used widely. In such a printer, a print head includes a plurality of nozzles that discharge (eject) ink onto a print medium, but ink may adhere to the vicinity of a nozzle opening portion and be solidified. In such a state, there are problems that the ink ejection direction becoming unstable, ink ejection being impossible, and the like are generated.
Therefore, in the related art, a wiper made of a rubber plate or the like is provided to clean an ink ejecting surface (nozzle surface). In addition, after cleaning, cleaning for scraping off the ink adhering to the wiper is performed.
In JP-A-2007-152940, an apparatus for removing ink adhering to a rear surface of a wiper using an ink absorbing body is proposed.
However, a method described in JP-A-2007-152940 described above has a risk that ink absorbed by the ink absorbing body thickens and causes malfunction.
In addition, as another method, there is a method that can move a rubber plate of a wiper while abutting on a cleaner (scraping member) and scrape off the adhering ink, but in that case, there is a problem that ink is scattered when the wiper passes through the cleaner. In order to protect other portions from ink scattering, a cover is provided in all directions in a movement direction of the wiper, and in a backward path of the wiper, means is taken to provide a mechanism that does not abut on the cleaner, but in either case, it is not preferable because an increase in size and complexity of the apparatus are generated.
An advantage of some aspects of the invention is to provide an ink jet type printing apparatus having a mechanism which wipes a nozzle surface, which can appropriately prevent the apparatus from ink scattering when ink adhering to a wiper blade is scraped off without an increase in size and complexity of the apparatus.
According to an aspect of the invention, there is provided a printing apparatus which performs printing by ejecting ink from a nozzle, including: a wiper blade that abuts on a nozzle surface on which an opening of the nozzle is formed, and moves in a first direction to wipe the ink adhering to the nozzle surface; and a cleaner that abuts on the moving wiper blade and scrapes off the ink adhering to the wiper blade, in which the wiper blade includes a blade member which protrudes in a second direction which is substantially orthogonal to the first direction, in which the cleaner includes a scraping member which protrudes in a third direction which is a direction opposite to the second direction, and in which shapes of a tip surface of the blade member in the second direction and a tip surface of the scraping member in the third direction are formed so that the blade member is sequentially separated from the scraping member from one end toward the other end thereof in a fourth direction which is substantially orthogonal to the first direction in the tip surface thereof when the wiper blade abuts on the cleaner and passes through the cleaner.
According to the aspect, since the blade member is sequentially separated from the scraping member in one direction, an ink scattering direction can regulate (control) when the wiper blade passes through the cleaner. Therefore, by appropriately designing the shapes of the tip surface of the blade member and the tip surface of the scraping member, a region where the ink is not desired to be scattered, such as a printing region can be reliably prevented from ink scattering. Therefore, the region where ink is not desired to be scattered can be reliably prevented from ink scattering without an increase in size and complexity of the printing apparatus.
According to another aspect of the invention, there is provided a printing apparatus which performs printing by ejecting ink from a nozzle, including: a wiper blade that abuts on a nozzle surface on which an opening of the nozzle is formed, and moves in a first direction to wipe the ink adhering to the nozzle surface; and a cleaner that abuts on the moving wiper blade and scrapes off the ink adhering to the wiper blade, in which the wiper blade includes a blade member which protrudes in a second direction which is substantially orthogonal to the first direction, in which the cleaner includes a scraping member which protrudes in a third direction which is a direction opposite to the second direction, and in which shapes of a tip surface of the blade member in the second direction and a tip surface of the scraping member in the third direction are formed so that a separation distance between the blade member and the scraping member in the first direction increases without decreasing or decreases without increasing from one end toward the other end thereof in a fourth direction which is substantially orthogonal to the first direction in the tip surface of the blade member.
According to the aspect, since the blade member is sequentially separated from the scraping member in one direction, an ink scattering direction can regulate (control) when the wiper blade passes through the cleaner. Therefore, by appropriately designing the shapes of the tip surface of the blade member and the tip surface of the scraping member, a region where the ink is not desired to be scattered, such as a printing region can be reliably prevented for ink scattering. Therefore, the region where ink is not desired to be scattered can be reliably prevented for ink scattering without an increase in size and complexity of the printing apparatus.
Further, in an embodiment of the invention, the tip surface of the blade member may include two inclined portions which are positioned at both ends thereof in the fourth direction and a horizontal portion which connects the inclined portions to each other and extends substantially along the fourth direction, the tip surface of the scraping member may include one inclined portion which is positioned from one end in the fourth direction and a horizontal portion which connects the inclined portion and the other end in the fourth direction to each other and extends substantially along the fourth direction, and one of the inclined portions of the blade member and the inclined portion of the scraping member may be disposed at substantially the same position in the first direction, and inclination angles of the two inclined portions of the blade member with respect to the fourth direction may be less than an inclination angle of the inclined portion of the scraping member with respect to the fourth direction.
According to still another aspect of the invention, there is provided a printing apparatus which performs printing by ejecting ink from a nozzle, including: a wiper blade that abuts on a nozzle surface on which an opening of the nozzle is formed, and moves in a first direction, and wipes the ink adhering to the nozzle surface; and a cleaner that abuts on the moving wiper blade and scrapes off the ink adhering to the wiper blade, in which the cleaner includes a scraping member which protrudes in a direction which is substantially orthogonal to the first direction, and in which inclination angles of a front and rear surfaces of the scraping member in the first direction with respect to a surface substantially orthogonal to a direction in which the scraping member protrudes are different from each other.
According to the aspect, by appropriately designing the inclination angle of the scraping member, an ink scattering amount in a forward path and a backward path of the wiper blade can be controlled. Specifically, ink scattering to the printing region can be prevented. Also, in the aspect, the region where ink is not desired to be scattered can be reliably prevented from ink scattering without an increase in size and complexity of the printing apparatus.
Further, in a preferred embodiment of the invention, the inclination angle in the first direction which is the inclination angle of the front surface of the scraping member may be larger than the inclination angle in the first direction which is the inclination angle of the rear surface of the scraping member.
According to the embodiment, the ink scattering amount can increase when the wiper blade passes through the cleaner in the first direction.
According to still another aspect of the invention, there is provided a printing apparatus which performs printing by ejecting ink from a nozzle, including: a wiper blade that abuts on a nozzle surface on which an opening of the nozzle is formed, and moves in a first direction to wipe the ink adhering to the nozzle surface; and a cleaner that abuts on the moving wiper blade and scrapes off the ink adhering to the wiper blade, in which the wiper blade includes a blade member which protrudes in a second direction which is substantially orthogonal to the first direction, in which the cleaner includes a scraping member which protrudes in a third direction which is a direction opposite to the second direction, and in which a front and rear surfaces of the scraping member in the first direction is formed so that the positions thereof in the third direction at which the blade member is separated from the scraping member are different from each other with respect to a passing direction when the wiper blade abuts on the cleaner and passes through the cleaner.
According to the aspect, by appropriately designing the shape of the scraping member, the ink scattering amount in the forward path and the backward path of the wiper blade can be controlled. Specifically, ink scattering to the printing region can be prevented. Also, in the aspect, the region where ink is not desired to be scattered can be reliably prevented from ink scattering without an increase in size and complexity of the printing apparatus.
According to still another aspect of the invention, there is provided a method for controlling a printing apparatus that performs printing by ejecting ink from a nozzle, the printing apparatus including a carriage that mounts a print head having the nozzle and moves, a wiper blade that abuts on a nozzle surface on which an opening of the nozzle is formed, and wipes the ink on the nozzle surface, and a cleaner that abuts on the wiper blade and removes the ink on the wiper blade when the wiper blade passes therethrough, the method comprising: moving the carriage to a predetermined position which covers the wiper blade when the wiper blade passes through the cleaner.
Further objects and features of the invention will become apparent from the embodiments of the invention to be described below.
The invention will be described with reference to the accompanying drawings, wherein like numbers reference like elements.
Hereinafter, embodiments of the invention will be described with reference to the drawings. However, such an embodiment does not limit the technical scope of the invention. In the drawings, the same or similar elements are described by being denoted the same reference numerals or reference symbols.
A printer 1 illustrated in
The printer 1 is a so-called ink jet printer, as an example, a vertical type printer which can feed paper from two directions. The vertical type means that a nozzle surface is perpendicular to a ground surface of the printing apparatus, and in the present embodiment, a nozzle plate (nozzle surface) 222 to be described below is provided substantially perpendicular to the ground surface of the printer 1.
In the
The printer 1 can insert a print medium (for example, paper such as check) from an outside portion of the apparatus in the direction of arrow B illustrated in
In addition, the printer 1 includes a printing mechanism 2. The printing mechanism 2 is a portion that performs printing on the print medium which is transported by the transport mechanism 3 and includes a print head 22, a carriage 21, and the like.
The carriage 21 is a portion that mounts the print head 22 and moves the print head 22 in a scanning direction. As illustrated in
The print head 22 includes a nozzle row 221 including a plurality of nozzles that discharge (eject) ink. In the present embodiment, as an example, two rows of nozzle rows 221 are provided. Each nozzle row 221 is provided along the Z direction. These nozzle rows 221 are formed by providing penetration holes in the nozzle plate 222. In addition, as illustrated in
Although such a print head 22 moves by the carriage 21 and performs printing on the print medium supplied to a range (printing region C) indicated by C in
The printer 1 includes the cap unit 4 and the wiper unit 5 at the position illustrated in
The wiper unit 5 is a device for cleaning unnecessary ink on the nozzle surface (nozzle plate 222). The printer 1 is characterized by the wiper unit 5, and hereinafter, a configuration and an action thereof will be specifically described.
The wiper unit 5 includes a wiper blade 51, a cleaner 52, and a driving mechanism 53.
The driving mechanism 53 is a mechanism for moving the wiper blade 51 along the nozzle plate (nozzle surface) 222 in the Z direction (direction of arrow D in
The wiper blade 51 is a portion that moves while abutting on the nozzle plate (nozzle surface) 222 and wipes off ink that is adhering (remained) on the nozzle surface 222.
As illustrated in
The blade 51B is formed of a flexible material such as rubber and is attached to the base portion 51A so as to protrude from the base portion 51A in the Y1 direction. The blade 51B has a plate shape, an end surface (upper end surface, tip surface of protrusion) of the blade in the Y1 direction (second direction) and a sectional surface taken along a flat surface which is perpendicular in Y1 direction have a V shape (accurately, V shape with a bottom portion as illustrated in aa of
The cleaner 52 is a portion for removing the ink adhering to the wiping blade 51B by the blade 51B. As illustrated in
As illustrated in
The scraping portion 52B is a member that protrudes in the Y2 direction (third direction) from the frame 52A and is a portion that comes in contact (abut) with the blade 51B when the wiper blade 51 passes the position of the cleaner 52. Therefore, as illustrated in
The wiper unit 5 of the printer 1 configured as described above is characterized by shapes of the blade 51B of the wiper blade 51 and the scraping portion 52B of the cleaner 52 and hereinafter, the point thereof will be described.
First, the end surface (tip surface of protrusion, hereinafter referred to as aa surface) of the blade 51B in the Y1 direction and the end surface (tip surface of protrusion, hereinafter referred to as bb surface) of the scraping portion 52B in the Y2 direction are characterized by the shapes thereof. Specifically, at the time of a state where the blade 51B and the scraping portion 52B are separated from each other, a distance between the aa surface and the bb surface in the Z direction (direction of arrow D in
As illustrated in
In
Next, in the present wiper unit 5, the side surface of the scraping portion 52B of the cleaner 52 (side surface viewed from X direction, hereinafter referred to as cc surface) is characterized by the shapes thereof. Specifically, angles of sides of the generally trapezoidal cc surface facing in the Z direction (movement direction of wiper blade 51) are different from each other. In other words, the inclination angles of the scraping portion 52B with respect to surfaces perpendicular to the Y direction of the front and rear surfaces in the Z direction are different from each other.
Next, an action of the shape of the wiper unit 5 described above will be described.
Accordingly, when the blade 51B moves in the forward path, first, the blade 51B passes through the scraping portion 52B from the right end (end in X1 direction) of the aa surface (aa line).
Thereafter, the blade sequentially passes through the scraping portion 52B in the X2 direction due to the change of L (X) described above.
Thereafter, as the movement progresses, the portion of B4 passes and the blade 51B entirely passes through the scraping portion 52B.
Accordingly, when the blade 51B passes through the scraping portion 52B, depending on a shape of the tip surfaces (aa surface and bb surface) of the blade 51B and the scraping portion 52B, the blade 51B sequentially is separated from the scraping portion 52B from the one end toward the other end thereof in the X direction (in direction of arrow I in
Next, the action by the shape of the side surface (cc surface) of the scraping portion 52B described above will be described.
The portion indicated by dd in
On the other hand, the portion indicated by ee in
If comparing behaviors of when the blade 51B is returned to the original shape thereof in both cases described above, in a case of the former (forward path), amplitude thereof is large and swing speed thereof is also fast. Therefore, in the former case, more ink is taken out from the blade 51B and is scattered. Accordingly, depending on the shape of the side surface (cc surface) of the scraping portion 52B, more specifically, depending on the angle of the side of the side surface facing in the Z direction the ink scattering amount from the blade 51B can be controlled. In a case of the present embodiment illustrated in
The shapes of the tip surfaces (aa surface and bb surface) of the blade 51B and scraping portion 52B and the shape of the side surface shape (cc surface) of the scraping portion 52B are not limited to the shapes illustrated in
In addition, with respect to the aa surface and the bb surface, the shape of the forward path and the backward path can be set according to the direction in which the ink of the apparatus is not to be scattered.
On the other hand, in a case illustrated in
In
As described above, in the printer 1, depending on the shapes of the tip surfaces (aa surface and bb surface) of the blade 51B and the scraping portion 52B of the wiper unit 5 described above, when the blade 51B passes through the scraping portion 52B, the ink scattering direction can be regulated (controlled). Therefore, by appropriately designing the shapes of the aa surface and the bb surface, the region where the ink is not desired to be scattered such as the printing region C can be reliably prevented from ink scattering. Specifically, by setting the shapes of the aa surface and the bb surface to the shapes illustrated in
Accordingly, in the printer 1, the region where ink is not desired to be scattered can be reliably prevented from ink scattering without an increase in size and complexity of the printing apparatus.
In addition, the ink scattering direction in the forward path and the backward path of the wiper blade 51 can be controlled by the shapes of the tip and the rear end in the movement direction on the tip surfaces (aa surface and bb surface) of the blade 51B and scraping portion 52B. Therefore, it can be flexibly applied according to the structure of the apparatus.
In addition, in the printer 1, by appropriately designing the side surface shape (shape of cc surface) of the scraping portion 52B, the ink scattering amount in the forward path and the backward path of the wiper blade 51 can be controlled. Specifically, by adopting the shape illustrated in
Also in this aspect, in the printer 1, the region where ink is not desired to be scattered can be reliably prevented from ink scattering without an increase in size and complexity of the printing apparatus.
Next, a wiping operation will be described.
The wiper unit 5 configured as described above performs the wiping operation when the carriage 21 is moved to a wiping position (position of wiper unit 5 in X direction). In other words, the wiping operation is performed at the time of a state illustrated in
As illustrated in
In addition, even when the wiper blade 51 at the home position is moved to the set position, the wiper blade 51 passes through the cleaner 52. At that time, similarly, ink is scraped off and scattered from the blade 51B.
When the wiper blade 51 moves from the home position to the set position, the wiper blade 51 moves from the state illustrated in
The printer 1 is characterized by control when the wiper blade 51 moves to the set position side, particularly when the wiper blade passes through the cleaner 52, and hereinafter, contents thereof will be described.
First, the control portion waits until it becomes the timing to move the wiper blade 51 to the set position (No in step S1 of
Thereafter, the control portion moves the wiper blade 51 from the home position and passes through the cleaner 52 (step S3 in
Next, the control portion retracts the carriage 21 from the wiping position (step S4 in
Thereafter, the control portion moves the wiper blade 51 to the set position (step S5 in
As described above, when the wiper blade 51 is moved to the set position and the wiper blade 51 passes through the cleaner 52, the carriage 21 is positioned at the wiping position.
In
However, in this passing operation, in the printer 1, as described above, the carriage 21 is positioned at the wiping position and covers the substantially upper side (Z1 direction side) of the wiper blade 51 at a short distance. Accordingly, the ink scattered from the blade 51B (2) hits the carriage 21 as illustrated by arrow K in
In a case where ink is sucked and wiped by the printer 1, since the control portion first moves the wiper blade 51 at the home position to the set position, as described with reference to
In a case of an apparatus in which the movement of the wiper blade 51 is performed by the same driving source (motor or the like) as the suction pump or the like of the cap unit 4, in addition to when the wiper blade 51 is moved to the set position, the wiper blade 51 may need to move in a direction in which the wiper blade 51 passes through the cleaner 52. For example, in a case where the suction pump is rotated in the reverse direction, there is a case where the suction pump is initialized, or the like. Also in this case, similarly, the control portion controls the wiper blade 51 to move after the carriage 21 is moved to the wiping position.
In addition, although the carriage 21 is moved to the wiping position when the wiper blade 51 is moved so that the wiper blade 51 passes through the cleaner 52 in the above description, instead of accurately moving the wiper blade 51 to the wiping position, the carriage may be moved to an appropriate position that can cover the wiper blade 51. For example, in a case where the ink scattering direction is defined in a predetermined fixed direction by the shapes of the blade 51B, the scraping portion 52B, and the like, the carriage 21 is moved to a position for covering the direction thereof. In addition, for example, the carriage 21 is moved so as to cover a direction of a portion (for example, printing region C or the like) where ink scattering is particularly desired to be prevented.
As described above, in the printer 1, when (before) the wiper blade 51 passes the cleaner 52 in the Z1 direction (upward), the carriage 21 moves to a predetermined position (for example, wiping position) covering a periphery of the wiper blade 51. Therefore, when the wiper blade 51 passes through the cleaner 52, the blade 51B vibrates and the ink scattered from the blade 51B is received by the carriage 21 at a short distance and disordered ink scattering can be prevented. Accordingly, adhering of ink splash to the transport mechanism 3 (transport roller and the like) can be prevented so as not to contaminate printed matter or other portions in the apparatus. In addition, the operation load by thickening of the flying ink is not increased. Further, such an effect can be obtained without providing a new mechanism, and complexity of the apparatus and an increase in manufacturing cost are not generated.
In addition, the invention is suitable for a small-sized printing apparatus in which the operating path of the wiper blade 51 and the transport path of the print medium have to be disposed close to each other like the printer 1.
In addition, by setting the predetermined position for moving the carriage 21 to the wiping position, it is possible to effectively prevent the wiper blade 51 and the carriage 21 from approaching to each other to the maximum and scattering the ink to other portions and there is no need to create a new stop position of the carriage 21.
In addition, by setting the predetermined position for moving the carriage 21 to a position covering the ink scattering direction from the blade 51B, ink scattering to the other portion can be reliably prevented.
In addition, by setting the predetermined position for moving the carriage 21 to the position of the blade 51B on the printing region C side in the scanning direction (X direction), ink scattering to the printing region C can be prevented.
Further, the absorbing material 211 is attached to the wiper blade 51 side of the carriage 21 and since the absorbing material 211 absorbs the receiving ink, transfer of the ink to other portions can be prevented.
The protection scope of the invention is not limited to the above embodiment but extends to the invention described in the claims and equivalents thereof.
The entire disclosure of Japanese Patent Application No. 2016-206823, filed Oct. 21, 2016 and No. 2016-206822, filed Oct. 21, 2016 are expressly incorporated by reference herein.
Number | Date | Country | Kind |
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2016-206822 | Oct 2016 | JP | national |
2016-206823 | Oct 2016 | JP | national |
Number | Name | Date | Kind |
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9168754 | Mano | Oct 2015 | B2 |
9186899 | Ogata | Nov 2015 | B2 |
20070103505 | Takagi | May 2007 | A1 |
20080024550 | Miyazawa | Jan 2008 | A1 |
20100207994 | Hayashi | Aug 2010 | A1 |
Number | Date | Country |
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2007-152940 | Jun 2007 | JP |
5481772 | Nov 2007 | JP |
2010-188565 | Sep 2010 | JP |
2015-231721 | Dec 2015 | JP |
Number | Date | Country | |
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20180111375 A1 | Apr 2018 | US |