The present invention relates to a technique of discharging liquid such as ink.
A liquid discharge head that discharges liquid such as ink from nozzles has plurality of channels. For example, JP-A-2015-163440 discloses a liquid discharge head formed by laminating channel members in which a plurality of channels are formed. Some channel members have openings that allow the channels inside the channel members to communicate with the outside. Examples of such openings include, for example, nozzles. Thus, when the liquid discharge head or the channel members are transported, the openings communicating with the outside may be closed by protective films so as to suppress entry of foreign matter into the channels during transportation.
Meanwhile, the component may be transported under an environment where the atmospheric pressure or temperature largely varies such as an environment during an airlift. In such a case, depending on the material of the protective films or the method of closing the openings communicating with the outside, simply closing the openings by the protective films may result in, due to variation in atmospheric pressure or temperature in the channels, deformation of the channels or, even when the channels are not deformed, fatigue of the channel members themselves. Such fatigue of the channel members may lead to degradation of strength.
An advantage of some aspects of the invention is to, during transportation, suppress entry of foreign matter into channels and suppress deformation of the channels or fatigue of channel members due to variation in atmospheric pressure or temperature.
A channel structure according to a first aspect of the invention includes a channel member in which a channel is formed. The channel structure has a plurality of openings that allow the channel to communicate with an outside. The plurality of openings are closed by respective lid members. At least one of the lid members that closes at least one of the plurality of openings has air permeability. According to the above-described form, the plurality of openings that allow the channel to communicate with the outside are closed by the lid members. This can suppress entry of foreign matter such as dust or dirt into the channel during transportation. Furthermore, the at least one of the lid members that closes the at least one of the plurality of openings has the air permeability. Thus, during transportation, even when air in the channel or the openings expands or contracts due to variation in atmospheric pressure or pressure, the air in the channel can pass through the lid members. This can suppress deformation of the channel or reduction in strength due to fatigue of the channel member. Accordingly, with this form, during transportation, entry of foreign matter into the channel can be suppressed and deformation of the channels or fatigue of the channel members due to variation in atmospheric pressure or temperature can be suppressed.
It is preferable that all of the plurality of openings be closed by lid members having the air permeability. According to this form, all of the plurality of openings are closed by the lid members having the air permeability. Thus, the air in the channel or the openings easily passes through the lid members. This can reduce stress applied to the channel member due to the expansion or contraction of the air in the channel or the openings.
It is preferable that a diameter of at least one air hole of the at least one of the lid members having the air permeability be 1/100 to 1/10 of a minimum width of a section of the channel. According to this form, the diameter of the at least one air hole of the at least one of the lid members having the air permeability is 1/100 to 1/10 of the minimum width of the section of the channel. Thus, even when the openings are closed by the lid members, the air easily passes while foreign matter is unlikely to enter.
It is preferable that the at least one air hole include a plurality of air holes, and an average diameter of the plurality of air holes of the at least one of the lid members having the air permeability be 10 nm to 100 μm. According to the above-described form, the average diameter of the plurality of air holes of the at least one of the lid members having the air permeability is 10 nm to 100 μm. Thus, the lid member allows the air in the channel to pass therethrough and entry of small foreign matter into the channel can be suppressed.
It is preferable that the at least one of the lid members having the air permeability have a Gurley value of 0.5 to 2000 s/100 mL. According to the above-described form, the at least one of the lid members having the air permeability has a Gurley value of 0.5 to 2000 s/100 mL. Thus, the air easily passes through the lid member when the atmospheric pressure varies. This can effectively suppress deformation of the channel or reduction in strength due to fatigue of the channel members.
It is preferable that the channel structure have a nozzle that communicates with the channel, and the plurality of openings include an opening of the nozzle. According to the above-described form, the channel structure has a nozzle that communicates with the channel, and the plurality of openings include an opening of the nozzle. Thus, even when a liquid discharge head or the channel member in which the nozzle is formed is transported as a single unit, during transportation, entry of foreign matter into the channel can be suppressed and deformation of the channel or fatigue of the channel member due to variation in atmospheric pressure or temperature can be suppressed.
In order to address the above-described problem, a liquid discharge head according to a second aspect of the invention includes a channel member in which a channel is formed. The liquid discharge head has a plurality of openings that allow the channel to communicate with an outside. The plurality of openings include an opening of a nozzle and an opening that is other than the opening of the nozzle. The plurality of openings are closed by respective lid members. At least one of the lid members that closes at least one of the plurality of openings has air permeability. According to this form, even when the liquid discharge head is transported as a single unit, during transportation, entry of foreign matter into the channel can be suppressed and deformation of the channel or fatigue of the channel member due to variation in atmospheric pressure or temperature can be suppressed.
The invention will be described with reference to the accompanying drawings, wherein like numbers reference like elements.
The transport mechanism 14 transports the medium 11 in the Y direction (sub-scanning direction) under the control of the controller 12. The carriage 18 reciprocates in the X direction (main scanning direction) under the control of the controller 12. Along with the transportation of the medium 11 and the reciprocation of the carriage 18, the liquid discharge head 20 discharges the ink to the medium 11. Thus, a desired image is formed on the surface of the medium 11. Hereafter, a direction perpendicular to the X-Y plane (plane parallel to the surface of the medium 11) is referred to as the Z direction. A direction in which the ink is discharged by the liquid discharge head 20 (downward in the vertical direction) corresponds to the Z direction.
The carriage 18 is provided with a liquid containing unit 182 (cartridge holder) that contains a plurality of liquid containers C1 to C4 (cartridges) that separately store a plurality of types of ink, respectively. The ink is liquid containing colorants such as pigments or dyes and is the liquid (color ink) of four colors including, for example, cyan (C), magenta (M), yellow (Y), and black (K). A resin material can be contained in the ink. The liquid containers C1 to C4 according to the present embodiment respectively contain cyan (C) ink, magenta (M) ink, yellow ink (Y), and black (K) ink. The liquid discharge head 20 is mounted below the liquid containing unit 182 of the carriage 18. The structure and the number of the liquid containers C1 to C4 are not limited to those exemplified herein.
The liquid discharge head 20 includes a plurality of liquid discharge units 70 (head chips). Each of the liquid discharge units 70 is a channel structure which includes channel members in which channels are formed. According to the present embodiment, an example is illustrated in which four liquid discharge units 70 are arranged in the X direction. Each of the liquid discharge units 70 has two nozzle rows arranged therein. Each of the nozzle rows is a cluster of a plurality of nozzles N arranged along a straight line in the Y direction. The numbers and arrangement of the liquid discharge units 70 and the nozzle rows are not limited to those illustrated in the example. The liquid discharge head 20 has channels through which the ink flows and filters that filter the ink flowing through the channels.
As illustrated in
The channel forming substrate 71 is a flat plate-shaped channel member defining channels for the ink. The channel forming substrate 71 according to the present embodiment has openings 712, supply channels 714, and communication channels 716. The supply channels 714 are each formed for a corresponding one of the nozzles N, and the communication channels 716 are each formed for a corresponding one of the nozzles N. The openings 712 continues along a plurality of the nozzles N. The pressure chamber forming substrate 72 is a flat plate-shaped channel member having a plurality of openings 722 corresponding to the different nozzles N. The channel forming substrate 71 and the pressure chamber forming substrate 72 are each formed of, for example, a single-crystal silicon substrate.
The compliance portions 75 illustrated in
The vibrating plates 73 are disposed on the surface of the pressure chamber forming substrate 72 on the opposite side to the channel forming substrate 71 illustrated in
A plurality of piezoelectric elements 732 corresponding to the different nozzles N are formed in the surface of the vibrating plates 73 on the opposite side to the pressure chamber forming substrate 72. Each of the piezoelectric elements 732 is a laminate in which electrodes face each other with a piezoelectric body interposed therebetween. When the piezoelectric elements 732 vibrate together with the vibrating plates 73 due to drive signals supplied thereto, the pressures in the pressure chambers C are varied, thereby the ink in the pressure chambers C is discharged from the nozzles N. Thus, the piezoelectric elements 732 function as drive elements that generate drive forces to discharge the ink from the nozzles N. The piezoelectric elements 732 are sealed and protected by protective plates 76 secured to the vibrating plates 73.
As illustrated in
End portions of individual wiring substrates 78 are coupled to the vibrating plates 73. The individual wiring substrates 78 are flexible wiring substrates in each of which wiring is formed. The drive signals and a power voltage are transmitted to the piezoelectric elements 732 through the wiring of the individual wiring substrates 78. Each of the four liquid discharge units 70 is provided with a corresponding one of the individual wiring substrates 78. The individual wiring substrates 78 are connected to a circuit substrate 26, which will be described later.
As illustrated in
As illustrated in
A sealing member 25, the circuit substrate 26, and a first channel unit G1 are sequentially laminated in this order from the top in the space S2 of the lower case member 23. The plurality of liquid discharge units 70 are contained in the space S3 of the lower case member 23. The space S3 of the lower case member 23 is closed by a securing plate 29 at the bottom. A second channel unit G2 is contained in the space S1 of the upper case member 22.
The second channel unit G2 is a channel structure that includes a plurality of structural members 221, 222, 223 that are laminated. The structural members 221, 222, 223 are channel members in which channels of the ink (not illustrated) are formed. The filters having been described are provided partway along the channels in the structural member 222. The structural members 221, 222, 223 are omitted from
The circuit substrate 26 relays the drive signals, other control signals, and so forth transmitted from the controller 12. The circuit substrate 26 has terminal portions 262 electrically connected to the individual wiring substrates 78 of the liquid discharge units 70. Also, connectors 264 for connection to the controller 12, other electronic components, and so forth are mounted on the circuit substrate 26. The terminal portions 262 and the connectors 264 are electrical coupling portions. Four terminal portions 262 corresponding to the individual wiring substrates 78 of four liquid discharge units 70 are formed on an upper surface (surface on the negative side in the Z direction) of the circuit substrate 26 according to the present embodiment. Furthermore, wiring members such as flexible flat cables (FFCs) are connected to the connectors 264. Thus, the circuit substrate 26 receives the drive signals from the controller 12 through the FFCs. The connectors 264 of the circuit substrate 26 according to the present embodiment are disposed in side walls 234 of the lower case member 23 on both the positive and negative sides in the X direction so as to be exposed in openings of the side walls 234.
The first channel unit G1 is a flat plate-shaped channel structure in which the channels for the ink are formed. The first channel unit G1 may be a laminate of a plurality of channel members. The lower case member 23 has a plurality of channels 232 projecting upward. The first channel unit G1 has a plurality of channels 272 projecting upward. The channels 232 pass through through holes formed in the first channel unit G1 and the circuit substrate 26 and communicate with channels of the structural members 221, 222, 223 through through holes 252 of the sealing member 25. The channels 272 pass through through holes formed in the circuit substrate 26 and communicate with channels of the structural members 221, 222, 223 through through holes 252 of the sealing member 25. The ink is introduced into the liquid discharge units 70 through the channels 232, 272.
A surrounding fence-shaped frame body 236 defines a space that contains the liquid discharge units 70. The frame body 236 projects downward (positive side in the Z direction) from a lower end of the lower case member 23. According to the present embodiment, four liquid discharge units 70 are arranged side-by-side in the frame body 236 in the X direction (main scanning direction) perpendicular to the transport direction of the medium 11. The piezoelectric elements 732 of the liquid discharge units 70 vibrate corresponding to the drive signals supplied from the controller 12 through the circuit substrate 26 and the individual wiring substrates 78. When the pressures in the pressure chambers C vary due to vibration of the piezoelectric elements 732, the ink filled in the pressure chambers C is discharged from the nozzles N of the nozzle plate 74.
The securing plate 29 has a flat plate shape. The securing plate 29 has four openings 292 having a shape corresponding to the nozzle plate 74 (rectangular shape elongated in the Y direction) of each of the liquid discharge units 70. Each of the openings 292 is provided for a corresponding one of the liquid discharge units 70. The liquid discharge units 70 are each secured to an upper surface (surface on the negative side in the Z direction) of the securing plate 29 by, for example, an adhesive such that the nozzle plate 74 is positioned inside the opening 292. In this way, nozzles N of the nozzle rows are disposed inside the openings 292. The liquid discharge head 20 is not necessarily provided with the securing plate 29.
A relay unit 40 that relays the ink from the liquid containers C1 to C4 to channels of the upper case member 22 is provided on an upper surface of the upper case member 22 (surface on the opposite side to a discharge surface A). The relay unit 40 includes ink introduction needles 42 (relay members) and surrounding walls 44. The ink introduction needles 42 stand erect on the upper surface of the upper case member 22. The surrounding walls 44 surround the ink introduction needles 42. According to the present embodiment, a total of four ink introduction needles 42 corresponding to the liquid containers C1 to C4 of the four colors are arranged in the X direction (main scanning direction) perpendicular to the transport direction of the medium 11.
The ink introduction needles 42 are hollow needle-shaped member inserted into the liquid containers C1 to C4. The ink introduction needles 42 have respective introduction holes 43 at the tips thereof. The introduction holes 43 communicate with the channels in the structural members 221, 222, 223. The introduction holes 43 allow the ink in the liquid containers C1 to C4 to be introduced therethrough to the respective liquid discharge units 70 from the channels 232 of the lower case member 23 and the channels 272 of the first channel unit G1 through the channels of the structural members 221, 222, 223.
The ribs 45 provided inside the surrounding walls 44 divide the relay unit 40 into a total of four cartridge regions 46 arranged in the X direction. Each of the ink introduction needles 42 stands erect in a corresponding one of the cartridge regions 46. Furthermore, the liquid containers C1 to C4 are respectively mounted in the cartridge regions 46.
The sealing member 25 illustrated in
The downstream annular sealing portion 253 is pressed against the circuit substrate 26, thereby the downstream annular sealing portion 253 is brought into tight contact with the circuit substrate 26 without being firmly secured by, for example, an adhesive. A surface (surface on the negative side in the Z direction) of the upstream annular sealing portion 255 in contact with the structural member 223 is pressed against the structural member 223, thereby the upstream annular sealing portion 255 is brought into tight contact with the structural member 223 without being firmly secured by, for example, an adhesive. Thus, the openings of the introduction holes 43 of the ink introduction needles 42 and openings of the nozzles N communicate with one another in an airtight manner through the channels for the ink in the liquid discharge head 20 (channels of, for example, the first channel unit G1, the second channel unit G2, the upper case member 22, the lower case member 23, and the liquid discharge units 70). The openings of the introduction holes 43 of the ink introduction needles 42 and the openings of the nozzles N are included in openings that allow the channels in the liquid discharge head 20 to communicate with the outside.
When any of the channel structures (for example, the first channel unit G1, the second channel unit G2, the upper case member 22, the lower case member 23, the liquid discharge units 70, and so forth) or the liquid discharge head 20 including the channel members is transported as a single component, openings communicating with the outside may be closed by protective films to suppress entry of foreign matter into the channels during transportation. Meanwhile, the component may be transported under an environment where the atmospheric pressure or temperature largely varies such as an environment during an airlift. In such a case, depending on the material of the protective films or the method of closing the openings communicating with the outside, simply closing the openings by the protective films may result in, due to variation in atmospheric pressure or temperature in the channels, deformation of the channels or, even when the channels are not deformed, fatigue of the channel members themselves. Such fatigue of the channel members may lead to degradation of strength.
Here, changes in the state of the channel structures occurring due to variation in atmospheric pressure during transportation are described. For ease of understanding of the description, an example is described in which a channel structure 50 having a simple structure is transported as a single unit.
When the channel structure 50 is transported with the openings 54 closed by the non-air-permeable protective film 60′ as illustrated in
Also when the channel structure 50 is transported with the openings 54 closed by the air-permeable protective film 60 as illustrated in
It is preferable that the diameter of air holes of the air-permeable protective film 60 be 1/100 to 1/10 of a minimum width of the section of the channel 52. In some channel members included in the liquid discharge head 20 or the channel structure 50, channels having a size of several to several tens of μm are formed. For example, a width W2 and a width W1 of the channel 52 illustrated in
Furthermore, it is preferable that an average diameter of the air holes of the air-permeable protective film 60 be 10 nm to 100 μm. With such an average diameter, the protective film 60 allows the air in the channel 52 to pass therethrough and entry of small foreign matter into the channel can be suppressed. Furthermore, it is preferable that the air-permeable protective film 60 have a Gurley value of 0.5 to 2000 s/100 mL. The Gurley value, which is defined in the Japanese Industrial Standards (JIS) P8117, is a time period required to pass the air of 100 mL from one side to the other side of a film having an area of 1 inch2 with a differential pressure of 1.22 KPa. For example, when the Gurley value is t, the ISO air permeability value P is 135.3/t (μm/(s·Ps)). Such a protective film 60 allows the air to easily pass therethrough even when the air in the channel 52 or the openings 54 expands or contracts due to variation in atmospheric pressure. Accordingly, a situation in which the insides of the channel 52 and the openings 54 are subjected to pressure for a long time does not occur. This can effectively suppress deformation of the channel 52 or reduction in strength due to fatigue of the channel members.
Furthermore, when the entirety of the protective film 60 that closes the openings 54, which allow the channel 52 to communicate with the outside, is air permeable as illustrated in
Furthermore, the material of the channel members included in the channel structure 50 is not limited to PDMS and may be silicon (Si), polyphenylenesulfide (PPS) resin, or the like. Furthermore, the channel structure 50 may be a composite member formed by coupling a plurality of members formed of different materials.
As has been described, according to the present embodiment, when the liquid discharge head 20 or the channel structure is transported as a single component with the plurality of openings that allow the channels to communicate with the outside closed by the protective film 60, the protective film 60 that closes at least one of the plurality of openings has air permeability. Thus, during transportation, entry of foreign matter into the channels can be suppressed and deformation of the channels or fatigue of the channel members due to variation in atmospheric pressure or temperature can be suppressed.
Hereafter, the case where the liquid discharge unit 70 as the channel structure is transported as a single unit and the case where the liquid discharge head 20 is transported as a single unit are specifically described with examples.
In the example illustrated in
In the example illustrated in
The exemplified forms and the embodiment having been described can be varied in a variety of manners. Specific forms of variations are exemplified as follows. Two or more of the forms arbitrarily selected from among the following examples and the above-described forms can be appropriately combined as long as no conflict occurs between the selected two or more forms.
1. Although the protective films 60 are bonded to the channel structure 50 according to the above-described embodiment, members that close the openings 54 of the channel structure 50 (lid members) are not limited to the protective film 60. For example, as exemplified in
Alternatively, the openings 54 of the channel structure 50 may be closed by protective members 64 exemplified in
As can be understood from the above-described examples, according to preferred forms of the invention, the plurality of openings 54 of the channel structure 50 are closed by the lid member or lid members having the air permeability. Each of the protective films 60 illustrated in
2. Although a serial scan head in which the carriage 18 on which the liquid discharge head 20 is mounted repeatedly reciprocates in the X direction has been described as the example according to the above-described embodiment, the invention can be applied also to a line scan head in which liquid discharge heads 20 are arranged throughout the width of the medium 11.
3. Although the liquid discharge head 20 of a piezoelectric method that utilizes piezoelectric elements applying mechanical vibration to pressure chambers is described as the example according to the above-described embodiment, a liquid discharge head of a thermal method that utilizes heating elements generating bubbles in pressure chambers by heating may be used.
4. The liquid discharge apparatus 10 described as the example according to the above-described embodiment can be used for any of a variety of apparatuses such as facsimile machines and copiers other than apparatuses dedicated to printing. Furthermore, application of the liquid discharge apparatus 10 according to the invention is not limited to printing. For example, a liquid discharge apparatus that discharges a solution of colorant is used as any of manufacturing apparatuses that form color filters of liquid crystal displays, organic electroluminescent (EL) displays, field-emission displays (FEDs) and so forth. Furthermore, a liquid discharge apparatus that discharges a solution of a conductive material are used as any of manufacturing apparatuses that form wiring and electrodes of wiring substrates. Furthermore, a liquid discharge apparatus is used as any of chip manufacturing apparatuses that discharge solutions of biological organic matter as a type of liquid.
The entire disclosure of Japanese Patent Application No. 2017-220605, filed Nov. 16, 2017 and the entire disclosure of Japanese Patent Application No. 2018-079564, filed Apr. 18, 2018 are expressly incorporated by reference herein.
Number | Date | Country | Kind |
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2017-220605 | Nov 2017 | JP | national |
2018-079564 | Apr 2018 | JP | national |