The present invention relates to a technology of discharging a liquid such as an ink.
In a liquid discharging apparatus which is configured by installing a liquid discharging head, a liquid such as an ink and a gas for driving a valve body are carried between the liquid discharging head and the liquid discharging apparatus. In US-A-2008/0246823, a plurality of gas holes are provided in a coupling member of the liquid discharging apparatus side, gas holes of the liquid discharging head side are connected to the gas holes of the liquid discharging apparatus side, and the liquid discharging head is installed on the liquid discharging apparatus (refer to
However, in US-A-2008/0246823, there is a concern that a liquid will dribble into the gas hole. For example, in US-A-2008/0246823, since liquid holes are not formed in the coupling member, there is a concern that when connecting the liquid holes the dribbled liquid will enter the gas holes because it is necessary to separately connect the liquid holes. In particular, in US-A-2008/0246823, since the gas hole (vent hole) and the liquid hole (ink inlet) are at extremely close positions (refer to
An advantage of some aspects of the invention is to suppress entrance of a liquid into a gas hole.
According to an aspect of the invention, there is provided a liquid discharging head which includes an external cover portion which is connected to a liquid discharging apparatus and which discharges a liquid from a nozzle, in which the external cover portion includes a first gas hole for communicating a first gas flow path which is provided inside the external cover portion with an atmosphere, a second gas hole for carrying a gas between a second gas flow path which is provided inside the external cover portion and the liquid discharging apparatus, and a first liquid hole for carrying the liquid between a liquid flow path which is provided inside the external cover portion and the liquid discharging apparatus, and in which the first gas hole and the second gas hole are disposed separately in the external cover portion. In this configuration, since the first gas hole, the second gas hole, and the first liquid hole are provided on the external cover portion which is connected to the liquid discharging apparatus, it is possible to connect the second gas hole and the first liquid hole to the liquid discharging apparatus by connecting the external cover portion to the liquid discharging apparatus. Therefore, in comparison to a case in which the first liquid hole is connected to the liquid discharging apparatus separately from the external cover portion in which the first gas hole and the second gas hole are formed, it is possible to reduce the possibility that when connecting the first liquid hole the dribbled liquid will enter the first gas hole or the second gas hole when connecting the second gas hole. Accordingly, since the first gas hole for communicating with the atmosphere and the second gas hole for carrying the gas to and from the liquid discharging apparatus are disposed separately on the external cover portion, for example, when performing the carrying of the gas using the gas carrying mechanism, since the gas carrying mechanism is connected to the second gas hole instead of the first gas hole, it is possible to suppress the liquid which dribbled in the vicinity of the first gas hole being pushed into the first gas hole using the gas carrying mechanism. In this manner, according to the embodiment, it is possible to suppress the entrance of the liquid into the gas hole.
In the liquid discharging head, the external cover portion may include a first surface, and the second gas hole and the first liquid hole may be disposed on the first surface. In this configuration, since the second gas hole and the first liquid hole are disposed on the first surface which is connected to the liquid discharging apparatus, it is possible to connect the second gas hole and the first liquid hole to the liquid discharging apparatus at once by connecting the external cover portion to the liquid discharging apparatus. Therefore, since the second gas hole is also connected when connecting the first liquid hole, it is possible to greatly reduce the possibility that the dribbled liquid from the first liquid hole will enter the second gas hole in comparison to a case in which the first liquid hole and the second gas hole are connected separately.
In the liquid discharging head, the second gas hole and the first liquid hole may be arranged on a straight line. In this configuration, since the second gas hole and the first liquid hole are arranged on a straight line, it is easy to miniaturize in the direction which intersects the straight line.
In the liquid discharging head, a level difference may be provided between the first gas hole and the first liquid hole. In this configuration, since the level difference is provided between the first gas hole and the first liquid hole, even if the liquid dribbles from the first liquid hole, the liquid does not easily move to the first gas hole. Therefore, it is possible to suppress the entrance of the liquid into the first gas hole when the first liquid hole is connected to the liquid discharging apparatus.
In the liquid discharging head, the external cover portion may include a first surface and a second surface facing different directions from each other, and, of the first surface and the second surface, the first gas hole may be disposed on one and the first liquid hole may be disposed on the other. In this configuration, of the first surface and the second surface which face different directions from each other, since the first gas hole is disposed on one and the first liquid hole is disposed on the other, even if the liquid dribbles from the first liquid hole, the liquid does not easily move to the first gas hole. Therefore, it is possible to suppress the entrance of the liquid into the first gas hole when the first liquid hole is connected to the liquid discharging apparatus.
The liquid discharging head may further include a second liquid hole for returning the liquid from the liquid discharging head to the liquid discharging apparatus, in which the first liquid hole and the second liquid hole may be arranged on a straight line, and in which the second liquid hole may be disposed at an end portion on the straight line. In this configuration, since the first liquid hole and the second liquid hole are arranged on the straight line and the second liquid hole is disposed at an end portion on the straight line, it is possible to simplify the routing of the flow path to which the second liquid hole is connected.
The liquid discharging head may further include a second liquid hole for returning the liquid from the liquid discharging head to the liquid discharging apparatus, in which the external cover portion may include a first surface and a second surface facing different directions from each other, and in which, of the first surface and the second surface, the first liquid hole may be disposed on one and the second liquid hole is disposed on the other. In this configuration, of the first surface and the second surface which face different directions from each other, since the first liquid hole is disposed on one and the second liquid hole is disposed on the other, it is possible to simplify the routing of the flow path to which the second liquid hole is connected.
In the liquid discharging head, a plurality of the second gas holes may be provided, the external cover portion may include a first surface, and the plurality of second gas holes may be disposed on the first surface. In this configuration, since a plurality of the second gas holes are disposed on the external cover portion, it is possible to carry the gas thereto. For example, it is possible to carry the gas at different timings for each of the second gas holes, and it is possible to selectively carry the gas from the plurality of second gas holes.
In the liquid discharging head, a plurality of the first liquid holes may be provided, and the plurality of first liquid holes and the plurality of second gas holes may be disposed on the first surface. In this configuration, since the plurality of second gas holes and the plurality of first liquid holes are disposed on the first surface of the external cover portion, it is possible to connect the plurality of second gas holes and the plurality of first liquid holes to the liquid discharging apparatus at once. Therefore, since the second gas holes are also connected when connecting the first liquid holes, it is possible to greatly reduce the possibility that the dribbled liquid from any of the plurality of first liquid holes will enter any of the plurality of second gas holes in comparison to a case in which the plurality of first liquid holes and the plurality of second gas holes are connected separately.
The liquid discharging head may further include a plurality of liquid discharge units which discharge the liquid, in which the first surface may include a plurality of regions corresponding to the plurality of liquid discharge units, in which the first liquid hole and the second gas hole may be disposed in each of the plurality of regions, and in which an interval between the first liquid hole and the second gas hole in a direction of the straight line in a predetermined region of the plurality of regions may be equal to an interval between the first liquid hole and the second gas hole in the direction of the straight line in the other regions. In this configuration, the interval between the first liquid hole and the second gas hole in a direction of the straight line in a predetermined region of the plurality of regions corresponding to the plurality of liquid discharge units is equal to the interval between the first liquid hole and the second gas hole in the direction of the straight line in the other regions. Therefore, it is possible to connect the liquid discharging head to any position on the liquid discharging apparatus side by providing a plurality of groups of holes on the liquid discharging apparatus which are connected to the first liquid holes and the second gas holes.
The liquid discharging head may further include a check valve which communicates with the first liquid hole. In this configuration, since the liquid discharging head further includes the check valve which communicates with the first liquid hole, it is possible to suppress the liquid inside the liquid discharging head flowing out from the first liquid hole.
According to another aspect of the invention, there is provided a liquid discharging apparatus which includes an apparatus main body to which the liquid discharging head is connected, in which the apparatus main body includes a main body-side second gas hole which is connected to the second gas hole, and a main body-side first liquid hole which connects to the first liquid hole, and in which the first gas flow path communicates with an atmosphere. In this configuration, it is possible to connect the liquid discharging head to the apparatus main body by connecting the second gas hole of the liquid discharging head to the main body-side second gas hole and connecting the first liquid hole of the liquid discharging head to the main body-side first liquid hole. It is possible to communicate the first gas flow path with the atmosphere on the apparatus main body side.
According to still another aspect of the invention, there is provided a liquid discharging apparatus which includes an apparatus main body to which a first liquid discharging head and a second liquid discharging head which are different from each other are connected, in which the first liquid discharging head and the second liquid discharging head each include a gas hole for carrying a gas to and from the apparatus main body using a gas carrying mechanism, and a liquid hole for carrying the liquid to and from the apparatus main body using a liquid carrying mechanism, and in which the apparatus main body of the liquid discharging apparatus includes a main body-side gas hole which connects to the gas hole, and a main body-side liquid hole which connects to the liquid hole. In this configuration, since the gas holes and the liquid holes between the first liquid discharging head and the second liquid discharging head are provided on the external cover portion which can be connected to the apparatus main body, it is possible to connect the gas hole and the liquid hole of each of the liquid discharging heads to the liquid discharging apparatus by connecting the external cover portion of each of the liquid discharging heads to the liquid discharging apparatus. Therefore, in comparison to a case in which the liquid holes are connected to the liquid discharging apparatus separately from the external cover portion in which the first gas holes are formed, it is possible to reduce the possibility that when connecting the liquid holes the dribbled liquid will enter the gas holes. In this configuration, since it is possible to connect the gas holes and the liquid holes of the plurality of liquid discharging heads to the main body-side gas holes and the main body-side liquid holes, as long as the gas holes and the liquid holes are provided, it is possible to connect not only the same liquid discharging heads but also different liquid discharging heads to the apparatus main body while suppressing the entrance of the liquid to the gas holes.
In the liquid discharging apparatus, the number of the gas holes of a predetermined liquid discharging head of the plurality of liquid discharging heads may be different from the number of gas holes of another liquid discharging head. In this configuration, even if liquid discharging heads having different numbers of gas holes are used, it is possible to connect the liquid discharging heads to the apparatus main body.
In the liquid discharging apparatus, a position on the apparatus main body of a predetermined liquid discharging head of the plurality of liquid discharging heads may be different from a position on the apparatus main body of another liquid discharging head. In this configuration, even if liquid discharging heads having different positions with respect to the apparatus main body are used, it is possible to connect the liquid discharging heads to the apparatus main body.
According to still another aspect of the invention, there is provided a manufacturing method of a liquid discharging apparatus which includes an apparatus main body to which a first liquid discharging head and a second liquid discharging head are connected, in which the first liquid discharging head and the second liquid discharging head are different from each other, in which the first liquid discharging head and the second liquid discharging head each include a gas hole for carrying a gas to and from the apparatus main body using a gas carrying mechanism, and a liquid hole for carrying the liquid to and from the apparatus main body using a liquid carrying mechanism, in which the apparatus main body of the liquid discharging apparatus includes a main body-side gas hole which connects to the gas hole, and a main body-side liquid hole which connects to the liquid hole, in which the manufacturing method includes removing one head of the first liquid discharging head and the second liquid discharging head which are installed in the apparatus main body and exchanging the removed head for another head, and in which in the exchanging, the liquid hole is connected to the main body-side liquid hole while the gas hole of the other head is connected to the main body-side gas hole. In this configuration, it is possible to easily manufacture the liquid discharging apparatus which is provided with the head which has a different overall configuration while suppressing the entrance of the liquid into the gas holes by exchanging one of the heads of the first liquid discharging head and the second liquid discharging head which are different from each other with the other head.
The invention will be described with reference to the accompanying drawings, wherein like numbers reference like elements.
The liquid container 14 is an ink tank type of liquid container which is formed from a box-shaped container which is attachable and detachable with respect to the main body of the liquid discharging apparatus 10. The liquid container 14 is not limited to being a box-shaped container and may be an ink pack type liquid container which is formed from a bag-shaped container. The ink is stored in the liquid container 14. The ink may be a black ink and may be a color ink. The ink which is stored in the liquid container 14 is pumped to the liquid discharging heads 20.
The control device 12 performs overall control of the elements of the liquid discharging apparatus 10. The transport mechanism 15 transports the medium 11 in a Y direction under the control of the control device 12. However, the configuration of the transport mechanism 15 is not limited to the examples given above. The liquid discharging heads 20 of the line head 21 discharge the ink which is supplied from the liquid container 14 onto the medium 11 under the control of the control device 12. The line head 21 of
The liquid discharging head 20 is configured such that two structural portions 21A and 21B, each having a box shape that is long in the X direction, deviate in the X direction and overlap each other. The two liquid discharge units 44 of the first row are provided in the structural portion 21A and the two liquid discharge units 44 of the second row are provided in the structural portion 21B. As illustrated in
The liquid discharge unit 44 is a structural body in which a pressure chamber substrate 482, a diaphragm 483, a piezoelectric element 484, a housing portion 485, and a sealing body 486 are disposed on one side of a flow path substrate 481, and a nozzle plate 487 and a compliance portion 45 are disposed on the other side. The flow path substrate 481, the pressure chamber substrate 482, and the nozzle plate 487 are formed by a silicon flat plate material, for example, and the housing portion 485 is formed by the extrusion molding of a resin material, for example. A plurality of nozzles N are formed in the nozzle plate 487. A surface of the nozzle plate 487 on an opposite side from the flow path substrate 481 corresponds to the discharge surface (a surface of the liquid discharge unit 44 facing the medium 11).
The plurality of nozzles N are divided into a first nozzle row L1 and a second nozzle row L2. Each of the first nozzle row L1 and the second nozzle row L2 is a collection of a plurality of nozzles N which are arranged along the Y direction. The first nozzle row L1 and the second nozzle row L2 are lined up with mutual intervals in the X direction. In the embodiment, the first nozzle row L1 and the second nozzle row L2 are disposed in a zigzag arrangement or a staggered arrangement such that the positions of the nozzles N of the first nozzle row L1 and the nozzles N of the second nozzle row L2 are different in the X direction.
In the liquid discharge unit 44 of
A liquid storage chamber SR which serves as a shared liquid chamber (a reservoir) which communicates with the opening portion 481A of the flow path substrate 481 is formed in the housing portion 485. The liquid storage chamber SR of the left side of
An opening portion 482A is formed for every nozzle N in the pressure chamber substrate 482. The diaphragm 483 is a flat plate material capable of elastic deformation which is installed on the surface of the pressure chamber substrate 482 on the opposite side from the flow path substrate 481. The space which is interposed between the diaphragm 483 and the flow path substrate 481 on the inside of each of the opening portions 482A of the pressure chamber substrate 482 functions as a pressure chamber (a cavity) SC which is filled with the ink which is supplied from the liquid storage chamber SR via the branched flow path 481B. Each of the pressure chambers SC communicates with a nozzle N via the communicating flow path 481C of the flow path substrate 481.
The piezoelectric element 484 is formed for every nozzle N on the surface of the diaphragm 483 on the opposite side from the pressure chamber substrate 482. Each of the piezoelectric elements 484 is a drive element in which a piezoelectric body is sandwiched between electrodes facing each other. When the diaphragm 483 vibrates due to the piezoelectric element 484 deforming according to the supply of a drive signal, the pressure inside the pressure chamber SC fluctuates and the ink inside the pressure chamber SC is discharged from the nozzle N. The sealing body 486 protects the plurality of piezoelectric elements 484. The piezoelectric elements 484 are connected to the control device 12 via a flexible printed circuit (FPC), a chip on film (COF), or the like which is not illustrated.
The compliance portion 45 of
The compliance portion 45 is fixed to a fixing plate 488. The fixing plate 488 is molded into a predetermined shape using a high rigidity material such as stainless steel, for example. A plurality of opening portions 489 corresponding to the nozzle plates 487 are formed in the fixing plate 488. The support plate 454 of the compliance portion 45 is fixed to the fixing plate 488 such that the nozzle plate 487 is exposed from the opening portion 489. The space on the inside of the opening portion 489 (specifically, the gap between the inner circumferential surface of the opening portion 489 and the outer circumferential surface of the nozzle plate 487) is filled with a filler material which is formed of a resin material, for example. The positive side of the Z direction of the opening portion 489 is closed by the fixing plate 488 and a space which is sandwiched between the compliance substrate 452 and the fixing plate 488 on the inside of the opening portion 489 forms the damper chamber SG. When the pumped ink is introduced into the liquid storage chamber SR, even if pressure fluctuation arises in the liquid storage chamber SR, it is possible to absorb the pressure fluctuation due to the compliance substrate 452 deforming.
Together with the external cover portion 41, the flow path unit 42 functions as a flow path structural body which is provided with the liquid flow path D and the gas flow path A. The liquid flow path D is a flow path which communicates to the nozzle N. The gas flow path A communicates with a bag-shaped body 73 of a pressurizing chamber RC which performs the control of the open-close valve 70 of the liquid flow path D and a decompression degassing chamber Q which performs the degassing (an operation of removing bubbles from the ink) of the liquid flow path D via gas-permeable membranes MA, MB, and MC.
First, a description will be given of the open-close valve 70 and the pressurizing chamber RC. An upstream side flow path R1 and a downstream side flow path R2 which configure a portion of the liquid flow path D, and the pressurizing chamber RC in which the bag-shaped body 73 which communicates with the gas flow path A is installed are formed in the inner portion of the external cover portion 41. The upstream side flow path R1 is connected to a liquid carrying mechanism 16 via a head-side connecting portion 412 and the main body side connecting portion 102. The liquid carrying mechanism 16 is a pump (a second pump) which carries (pumps) the ink which is stored in the liquid container 14 to the liquid discharging head 20 in a pressurized state. The open-close valve 70 is installed between the upstream side flow path R1 and the downstream side flow path R2 and a flexible film 71 is sandwiched between the downstream side flow path R2 and the pressurizing chamber RC.
The open-close valve 70 is a valve mechanism which opens and closes the liquid flow path D which supplies the ink to the liquid discharge unit 44. The open-close valve 70 is provided with a valve body V. The valve body V is provided between the upstream side flow path R1 and the downstream side flow path R2 and communicates (an open state) or blocks (a closed state) between the upstream side flow path R1 and the downstream side flow path R2. A spring Sp which biases the valve body V in a direction in which the upstream side flow path R1 and the downstream side flow path R2 are blocked is provided in the valve body V. Therefore, when a force is not acting on the valve body V, the upstream side flow path R1 and the downstream side flow path R2 are blocked. On the other hand, the upstream side flow path R1 and the downstream side flow path R2 are caused to communicate due to a force being applied to the valve body V against the biasing force of the spring Sp and the valve body V moving to the positive side in the Z direction.
The bag-shaped body 73 which is installed in the pressurizing chamber RC is a bag-shaped member which is formed by an elastic material such as rubber. The bag-shaped body 73 is connected to the gas flow path A, expands due to the pressurization of the gas flow path A and contracts due to decompression. The gas flow path A is connected to a gas carrying mechanism 19 via the head-side connecting portion 412 and the main body side connecting portion 102. The gas carrying mechanism 19 of the embodiment is a pump which carries the gas of the gas flow path A. Specifically, the gas carrying mechanism 19 is a pump (a first pump) capable of pressurizing and decompressing the gas flow path A, and is typically configured by a pneumatic pump. The gas carrying mechanism 19 may be configured by a single pump which is used for both the pressurizing and the decompression, and may be configured divided into a pump for pressurizing and a pump for decompression. It is not necessary for the entire surface of the bag-shaped body 73 to be an elastic material, and only one surface may be an elastic material as long as expansion is possible. A gas flow path B (the first gas flow path) for opening the pressurizing chamber RC to the atmosphere communicates with the pressurizing chamber RC.
In a state in which the bag-shaped body 73 is contracted, in a case in which the pressure inside the downstream side flow path R2 is maintained within a predetermined range, the valve body V is biased by the spring Sp and is pushed upward (the negative side in the Z direction) and the upstream side flow path R1 and the downstream side flow path R2 are blocked. On the other hand, when the pressure inside the downstream side flow path R2 is reduced to a numerical value which is lower than a predetermined threshold originating in the discharging of the ink by the liquid discharge unit 44 or suction from the outside, the valve body V moved downward (the positive side in the Z direction) against the biasing force of the spring Sp and the upstream side flow path R1 and the downstream side flow path R2 are communicated.
On the other hand, when the bag-shaped body 73 expands due to the pressurization by the gas carrying mechanism 19, the flexible film 71 pushes the valve body V down against the biasing force of the spring Sp according to the pressing by the bag-shaped body 73 and moves to the positive side in the Z direction. Therefore, the valve body V moves due to the pressing by the flexible film 71 and the open-close valve 70 is opened. In other words, it is possible to forcefully open the open-close valve 70 using the pressurizing by the gas carrying mechanism 19 regardless of the level of the pressure inside the downstream side flow path R2. Forcefully rendering the flexible film 71 movable using the pressurization by the gas carrying mechanism 19 to open the open-close valve 70 is exemplified by, for example, a case in which the liquid discharging head 20 is first filled with the ink (hereinafter referred to as “initial filling”), and a case in which the ink is discharged from the nozzle N during cleaning.
Next, a description will be given of the gas-permeable membranes MA, MB, and MC and the decompression degassing chamber Q. The filter chamber RF which communicates with a vertical space RV and the decompression degassing chamber Q are formed in the flow path unit 42. The decompression degassing chamber Q is a space for decompressing a portion of the liquid flow path D to remove bubbles from the ink. The decompression degassing chamber Q functions as a degassing space in which the bubbles (the gas) which are removed from the ink are temporarily retained. The decompression degassing chamber Q is configured by being divided into two spaces of a decompression chamber and a degassing chamber which communicate with each other, and may be provided with an open-close valve or a check valve in a communicating portion between the decompression chamber and the degassing chamber.
A filter F is provided in the filter chamber RF. The filter F is installed in the liquid discharge unit 44 to cross the liquid flow path D and gathers bubbles and foreign matter which are mixed into the ink. Specifically, the filter F is installed to partition a space RF1 and a space RF2. The space RF1 of the upstream side communicates with the downstream side flow path R2 of the external cover portion 41 and the space RF2 of the downstream side communicates with the vertical space RV.
The vertical space RV is a space for temporarily storing the ink. An inlet Vin into which the ink which passes the filter F flows from the space RF2 and an outlet Vout from which the ink flows out to the nozzle N side are formed in the vertical space RV. Compared to the outlet Vout, the inlet Vin is positioned above (the negative side in the Z direction) the outlet Vout in the vertical direction. In this configuration, the ink inside the space RF2 flows into the vertical space RV via the inlet Vin, and the ink inside the vertical space RV flows into the liquid storage chamber SR via the outlet Vout. The ink which flows into the liquid storage chamber SR is supplied to the pressure chambers SC via the opening portion 481A and is discharged from the nozzles N.
The gas-permeable membranes MA, MB, and MC are installed to partition a plurality of locations of the decompression degassing chamber Q and the liquid flow path D. However, the arrangement positions and the number of the gas-permeable membranes are not limited to those exemplified. The gas-permeable membrane MA is sandwiched between the vertical space RV and the decompression degassing chamber Q. The gas-permeable membrane MB is sandwiched between the liquid storage chamber SR and the decompression degassing chamber Q. The gas-permeable membrane MC is sandwiched between the space RF1 and the decompression degassing chamber Q. The gas-permeable membranes MA to MC are gas-permeable membranes (gas-liquid separation membranes) in which, although gas (air) is allowed to permeate, liquids such as ink are not allowed to permeate. The bubbles which are gathered by the filter F are discharged into the decompression degassing chamber Q and removed from the ink by permeating the gas-permeable membrane MC. The bubbles which permeate the filter F also flow into the vertical space RV via the inlet Vin from the space RF1 and flow into the vertical space RV. Therefore, the bubbles which flow into the vertical space RV are discharged into the decompression degassing chamber Q by permeating the gas-permeable membrane MA.
An output port Rout is formed in the liquid storage chamber SR. The output port Rout is a flow path which is formed in a ceiling surface 49 of the liquid storage chamber SR. The ceiling surface 49 of the liquid storage chamber SR is an inclined surface (a flat surface or a curved surface) which gets higher from the inlet Rin side to the output port Rout side. Therefore, the bubbles which enter from the inlet Rin are guided to the output port Rout side and discharged into the decompression degassing chamber Q by permeating the gas-permeable membrane MB.
Since the decompression degassing chamber Q communicates with the gas flow path A, the decompression degassing chamber Q is decompressed due to the gas flow path A being decompressed by the gas carrying mechanism 19. When the decompression degassing chamber Q is decompressed, the bubbles in the liquid flow path D pass through the gas-permeable membranes MA, MB, and MC. The gas which passes through the gas-permeable membranes MA, MB, and MC and moves into the decompression degassing chamber Q passes through the gas flow path A and is discharged to the outside of the apparatus. In this manner, the bubbles are removed from the liquid flow path D.
The liquid flow path D of the embodiment includes a liquid flow path E for returning the ink of the liquid discharging head 20 to the liquid discharging apparatus 10 side. The liquid flow path E is a path which communicates with the inner portion flow path of the flow path unit 42 (specifically, a flow path for supplying the ink to the liquid discharge unit 44). Specifically, the liquid flow path E communicates the output port Rout and the vertical space RV of the liquid storage chamber SR of each of the liquid discharge units 44 with each other. The liquid flow path E is connected to a circulating mechanism 78 via the external cover portion 41 and the main body side connecting portion 102. The circulating mechanism 78 is provided with a circulation path, a pump, and the like, and has a function of causing the ink which is discharged from the liquid flow path E to circulate such that the ink returns to the liquid discharging apparatus 10 side and can be used again by the liquid discharging head 20.
As illustrated in
The head-side connecting portion 412 is provided with a gas hole Ba (an example of a first gas hole) which communicates with the gas flow path B (an example of a first gas flow path), and a gas hole Aa (an example of a second gas hole) which communicates with the gas flow path A (an example of a second gas flow path). The head-side connecting portion 412 is provided with a liquid hole Da (an example of a first liquid hole) which communicates with the liquid flow path D (an example of a first liquid flow path), and a liquid hole Ea (an example of a second liquid hole) which communicates with the liquid flow path E (an example of a second liquid flow path). On the other hand, the main body side connecting portion 102 is provided with a main body-side gas hole Ab for connecting to the gas hole Aa, a main body-side liquid hole Db for connecting to the liquid hole Da, and a main body-side liquid hole Eb for connecting to the liquid hole Ea. As illustrated in
In this configuration, due to connecting the liquid discharging head 20 to the apparatus main body 101 such that the head-side connecting portion 412 is connected to the main body side connecting portion 102, it is possible to connect the gas hole Aa which communicates with the gas flow path A to the main body-side gas hole Ab separately from the gas hole Ba which communicates with the gas flow path B.
Hypothetically, if the gas hole Ba and the gas hole Aa are the same single hole, when pressurizing the gas flow path A using the gas carrying mechanism 19, there is a concern that the dribbled ink in the vicinity of the single hole will be pushed into the inner portion of the gas flow path B by the gas carrying mechanism 19. When the ink enters the inner portion of the gas flow path B, there is a concern that the gas flow path B will be blocked by solidification of the ink. With regard to this point, in the embodiment, since the gas hole Ba for communicating with the atmosphere and the gas hole Aa which is connected to the gas carrying mechanism 19 are disposed separately in the head-side connecting portion 412, it is possible to suppress the pushing of the dribbled ink in the vicinity of the gas hole Ba into the inner portion of the gas flow path B by the gas carrying mechanism 19.
In this configuration of the embodiment, the gas hole Aa, the liquid hole Da, and the liquid hole Ea are each connected once to the main body-side gas hole Ab, the main body-side liquid hole Db, and the main body-side liquid hole Eb. Therefore, it is possible to suppress the ink dribbling from the liquid hole Da or the liquid hole Ea and entering the gas hole Aa.
Hypothetically, if the gas hole Aa, the liquid hole Da, and the liquid hole Ea are each separately connected to the main body-side gas hole Ab, the main body-side liquid hole Db, and the main body-side liquid hole Eb, there is a concern that the ink will dribble and enter the gas hole Aa when connecting the liquid hole Da and the liquid hole Ea to the main body-side liquid hole Db and the main body-side liquid hole Eb. Regarding this point, in the embodiment, since it is possible to connect each of the gas hole Aa, the liquid hole Da, and the liquid hole Ea to the main body-side gas hole Ab, the main body-side liquid hole Db, and the main body-side liquid hole Eb at once, it is possible to ensure that the ink does not easily dribble from the liquid hole Da or the liquid hole Ea, and even if the ink does dribble, since the gas hole Aa is connected to the main body-side gas hole Ab, the dribbled ink does not easily enter the gas hole Aa.
In the liquid discharging head 20 of
In
The plurality of gas holes Aa1 and Aa2 and the plurality of liquid holes Da1, Da2, Ea1, and Ea2 are all disposed on the same first surface FA. On the other hand, the main body-side gas holes Ab1 and Ab2 and the plurality of main body-side liquid holes Db1, Db2, Eb1, and Eb2 which are connected to the plurality of gas holes Aa1 and Aa2 and the plurality of liquid holes Da1, Da2, Ea1, and Ea2, respectively, are disposed on the connecting surface F1 which faces the first surface FA.
According to the configuration of
Hypothetically, in a case in which the liquid holes Da1, Da2, Ea1, and Ea2 are connected to the main body side connecting portion 102 separately from the external cover portion 41 in which the gas holes Aa1 and Aa2 are formed, there is a possibility that when the ink dribbles during connecting any of the liquid holes Da1, Da2, Ea1, and Ea2, when connecting the external cover portion 41, the dribbled ink will enter one of the gas holes Aa1 and Aa2. Regarding this point, according to the configuration of
In the configuration of
In
The gas hole Ba for opening the liquid discharging head 20 to the atmosphere of
The liquid hole Da1, the gas hole Aa1, the liquid hole Ea1, the liquid hole Da2, the gas hole Aa2, and the liquid hole Ea2 are arranged on a straight line along a virtual straight line G from the positive side to the negative side in the X direction in this order. Therefore, it is easy to reduce the size of the liquid discharging head 20 in the Y direction which intersects the X direction of the virtual straight line G. Although a case is exemplified in which the gas hole Ba for creating an opening to the atmosphere which is disposed on the second surface FB communicates with the gas flow path B for opening the pressurizing chamber RC to the atmosphere, the configuration is not limited thereto. The gas hole Ba for creating an opening to the atmosphere may be a gas hole which communicates with the gas flow path for communicating the space in which the damper chamber SG and the piezoelectric element 484 of the compliance substrate 452 are stored to the atmosphere, for example. The configuration is not limited to the case which is exemplified in
Incidentally, in the first surface FA of the head-side connecting portion 412 of
The gas holes and the liquid holes which are disposed on the head-side connecting portion 412 are not limited to the case illustrated in
According to the configuration of
In
According to the configuration of
Even in the configuration of
In the line head 21 of the liquid discharging apparatus 10 of
According to the configuration of
The exchanging of the heads in the exchanging process may be performed by an operator and may be performed automatically by a robot arm or the like. In this case, in the liquid discharging apparatus 10, a configuration may be adopted in which information of the types and the installable positions of the exchangeable liquid discharging heads 20 is stored in a memory device and the exchanging process is performed based on the stored information. In this configuration, in the liquid discharging apparatus 10, it is possible to suppress the unintended installation of the liquid discharging head 20 of a type which cannot be exchanged and the installation at a deviated position. For example, the types of the installable heads such as the liquid discharging heads 20A and 20B illustrated in
Regarding the positions of the liquid discharging heads 20, as in the fifth modification example of the first embodiment illustrated in
Hereinabove, although a case is exemplified in which the liquid discharging heads 20 of the configurations of
A description will be given of the second embodiment of the invention. Regarding the elements of the operations and functions of the embodiments to be exemplified hereinafter that are similar to those in the first embodiment, the reference numerals which are used in the description of the first embodiment will be reused and detailed description of the elements will be omitted, as appropriate. For the liquid discharging head 20 of the first embodiment, a case is exemplified in which four of the liquid discharging units 44 are provided and the two regions Ha and Hb which correspond to every two of the liquid discharge units 44 are present on the first surface FA of the head-side connecting portion 412. For the liquid discharging head 20 of the second embodiment, a case is exemplified in which two of the liquid discharging units 44 are provided and the one region Ha which corresponds to two of the liquid discharge units 44 is present on the first surface FA of the head-side connecting portion 412.
As illustrated in
In
A description will be given of the third embodiment of the invention. In the first embodiment and the second embodiment, the line head 21 in which the liquid discharging heads 20 are arranged along the entire width of the medium 11 is exemplified. In the third embodiment, a serial head which causes a carriage 18 on which the liquid discharging head 20 is mounted to repeatedly move reciprocally along the X direction is exemplified.
As illustrated in
As illustrated in
The gas hole Ba for creating an opening to the atmosphere is also disposed on the head-side connecting portion 412. A level difference 414 is formed between the gas hole Ba for creating an opening to the atmosphere, and the liquid hole Da, the gas hole Aa, and the liquid hole Ea. Therefore, even if the ink dribbles from the liquid holes Da and Ea, since the level difference 414 gets in the way, the ink does not easily move to the gas hole Ba. Therefore, it is possible to suppress the entrance of the ink into the gas hole Ba.
The aspects and embodiments which are exemplified above may be modified in various manners. Specific modified aspects will be exemplified hereinafter. Two or more aspects selected arbitrarily from the following examples and the above-described aspects may be combined, as appropriate, insofar as there is no mutual contradiction.
(1) In the embodiments, although a piezoelectric type of the liquid discharging head 20 which uses piezoelectric elements to apply mechanical vibrations to pressure chambers is exemplified, it is also possible to adopt a heat type liquid discharging head which uses heat generating elements which generate bubbles in the inner portions of pressure chambers using heat.
(2) For the liquid discharging apparatus 10 which is exemplified in the embodiments, in addition to a device which is dedicated to printing, it is possible to adopt various devices such as a facsimile device or a copier device. Naturally, the usage of the liquid discharging apparatus 10 of the invention is not limited to printing. For example, the liquid discharging apparatus which discharges a colorant solution is used as a manufacturing apparatus which forms color filters of a liquid crystal display device, organic electroluminescence (EL) displays, field emission displays (FED), and the like. The liquid discharging apparatus which discharges a solution of a conductive material is used as a manufacturing apparatus which forms the wiring and the electrodes of a wiring substrate. The liquid discharging apparatus is also used as a chip manufacturing apparatus which discharges a solution of biological organic matter as a type of liquid.
The entire disclosure of Japanese Patent Application Nos. 2017-127125, filed Jun. 29, 2017 and 2018-13727, filed Jan. 30, 2018 are expressly incorporated by reference herein.
Number | Date | Country | Kind |
---|---|---|---|
2017-127125 | Jun 2017 | JP | national |
2018-013727 | Jan 2018 | JP | national |