The present disclosure relates to a technique regarding a cartridge and a connector.
A conventionally known cartridge is detachably mounted to a mounting structure of a liquid consuming apparatus, such as a printer (as described in JP 2013-240924A). In the technique disclosed in JP 2013-240924A, the mounting structure includes electrical connecting elements and a liquid introducing structure. In the technique disclosed in JP 2013-240924A, the cartridge includes contact portions arranged to come into contact with the electrical connecting elements, and a liquid supply portion connected with the liquid introducing structure to supply a liquid to the liquid introducing structure.
A conventionally known liquid container is detachably mounted to a mounting structure of a liquid consuming apparatus (as described in, for example, JP 2006-15644A). The prior art liquid container includes a liquid container body having a liquid pack and a liquid supply port, and a sealing case provided to cover the entire liquid container body to prevent leakage of a liquid to outside.
The prior art technique is, however, likely to cause the position of the cartridge relative to the mounting structure to be deviated from the correct position by an external force applied from the mounting structure to the cartridge in a mounting process or in a mounting state. There is accordingly a demand for suppressing position misalignment of the cartridge relative to the mounting structure.
This problem is not characteristic of the cartridge that is detachably mounted to the mounting structure but is common to any member (for example, connector) that is detachably mounted to the mounting structure.
The prior art technique covers the entire liquid container body with the sealing case to suppress leakage of the liquid to outside. In the configuration that uses the sealing case to suppress leakage of the liquid to outside, however, a gap is likely to be formed due to position misalignment between members included in the sealing case or tolerance of the sealing case. The presence of such a gap is likely to cause the liquid to be leaked from inside of the sealing case to outside. There is accordingly a demand for reducing the possibility of leakage of the liquid to outside.
This problem is not characteristic of the liquid container that is detachably mounted to the mounting structure of the liquid consuming apparatus but is common to any member (for example, connector) that is detachably mounted to the mounting structure and that includes a supply flow path arranged to supply a liquid from a liquid supply source to the mounting structure.
In order to solve at least part of the problems described above, the disclosure may be implemented by aspects or configurations described below.
(1) According to one aspect of the present disclosure, there is provided a cartridge detachably mounted to a mounting structure of a liquid consuming apparatus that is provided with a liquid introducing structure, an electrical connecting element and an engagement structure. An X axis, a Y axis and a Z axis are three spatial axes that are orthogonal to one another. An X-axis direction is a direction along the X axis, a Y-axis direction is a direction along the Y axis, and a Z-axis direction is a direction along the Z axis. In a mounting state that the cartridge is mounted to the mounting structure, direction of gravity is defined as −Z-axis direction, an opposite direction of gravity is defined as +Z-axis direction, one direction in the X-axis direction is defined as +X-axis direction, and the other direction in the X-axis direction is defined as −X-axis direction. This cartridge comprises a liquid supply portion detachably connected with the liquid introducing structure to supply a liquid to the liquid introducing structure, the liquid supply portion including a base end portion, a leading end portion that forms an opening to receive the liquid introducing structure in the liquid supply portion, and a center axis that is extended in a direction along a +Y-axis direction from the base end portion toward the leading end portion; a contact portion that is located on the +Z-axis direction side of the liquid supply portion and that is arranged to contact with the electrical connecting element in the mounting state; and a positioning structure that is located between the liquid supply portion and the contact portion in the Z-axis direction and that is engaged with the engagement structure to restrict motion of the cartridge relative to the mounting structure in the mounting state. The liquid supply portion is configured to receive a first external force in the −Y-axis direction from the liquid introducing structure when the liquid supply portion is connected with the liquid introducing structure. The contact portion is configured to receive a second external force in a direction including the −Y-axis direction component from the electrical connecting element when the contact portion contacts with the electrical connecting element.
According to this aspect, the first external force causes a first moment in a first rotating direction having a −Y-axis direction component to be generated about the positioning structure as a supporting point in the cartridge. The second external force causes a second moment in a second rotating direction having a −Y-axis direction component to be generated about the positioning structure as a supporting point in the cartridge. According to this aspect, the positioning structure is placed between the liquid supply portion and the contact portion in the Z-axis direction. This configuration causes the first moment in the first rotating direction and the second moment in the second rotating direction to be applied to the cartridge in the directions of cancelling each other. This configuration reduces the possibility of position misalignment of the cartridge relative to the mounting structure in the mounting process and in the mounting state. According to this aspect, the liquid supply portion is provided on the −Z-axis direction side that is the direction of gravity side of the contact portion. This configuration reduces the possibility that the contact portion is stained with the liquid even when the liquid is leaked out from the liquid supply portion.
(2) In the cartridge of the above aspect, a plurality of the contact portions may be provided at different positions in the X-axis direction, and the plurality of the contact portions may include a first contact portion that is located on a most +X-axis direction side and a second contact portion that is located on a most −X-axis direction side in the X-axis direction among the plurality of the contact portions. When the cartridge is viewed from the +Y-axis direction side, a center of an interval between the first contact portion and the second contact portion in the X-axis direction may be located on a virtual straight line that runs through the center axis of the liquid supply portion and is parallel to the Z-axis direction.
According to this aspect, the cartridge is rotated about the center axis relative to the mounting structure along an X-Z plane that is parallel to the X-axis direction and the Z-axis direction. Such rotation suppresses position misalignment of the contact portion relative to the electrical connecting element on the X-Z plane even when the cartridge has position misalignment relative to the mounting structure on the X-Z plane. The state that the “center of an interval between the first contact portion and the second contact portion is located on the virtual straight line” is not limited to the case where the center is located exactly on the virtual straight line but includes the case where there is a slight deviation of the center of an interval between the first contact portion and the second contact portion from the virtual straight line by taking into account the capability of suppressing position misalignment of the contact portion relative to the electrical connecting element on the X-Z plane.
(3) In the cartridge of the above aspect, the positioning structure may be engaged with the engagement structure to restrict motion of the cartridge relative to the mounting structure in the X-axis direction. When the cartridge is viewed from the +Y-axis direction side, a center of the positioning structure in the X-axis direction may be located on the virtual straight line.
According to this aspect, the configuration that the center of the positioning structure is located on the virtual straight line more effectively suppresses position misalignment of the contact portion relative to the electrical connecting element. The state that the “center of the positioning structure is located on the virtual straight line” is not limited to the case where the center is located exactly on the virtual straight line but includes the case where there is a slight deviation of the center of the positioning structure from the virtual straight line by taking into account the capability of suppressing position misalignment of the contact portion relative to the electrical connecting element.
(4) In the cartridge of the above aspect, the engagement structure may include a first engagement structure and a second engagement structure. The positioning structure may include a first engaged element that is engaged with the first engagement structure in the mounting state; and a second engaged element that is arranged to be away from the first engaged element across an interval in the X-axis direction and that is engaged with the second engagement structure in the mounting state. When the cartridge is viewed from the +Y-axis direction side, the first engaged element and the second engaged element may be located across the virtual straight line.
According to this aspect, the first engaged element and the second engaged element are located across the virtual straight line. This configuration suppresses position misalignment of the cartridge by the first external force or by the second external force and position misalignment of the contact portion about the center axis in the mounting state.
(5) In the cartridge of the above aspect, the positioning structure may include a first protruded guide element that is formed to be located on a −Y-axis direction side toward the −X-axis direction and that is configured to guide the first engagement structure to the first engaged element; and a second protruded guide element that is formed to be located on the −Y-axis direction side toward the +X-axis direction and that is configured to guide the second engagement structure to the second engaged element. The first engaged element may be connected with a −X-axis direction side end of the first protruded guide element, and the second engaged element may be connected with a +X-axis direction side end of the second protruded guide element.
According to this aspect, the first protruded guide element and the second protruded guide element respectively serve to guide the first engagement structure to the first engaged element and to guide the second engagement structure to the second engaged element in the process of mounting the cartridge to the mounting structure. This configuration ensures engagement of the first engagement structure with the first engaged element and engagement of the second engagement structure with the second engaged element with higher reliability.
(6) The cartridge of the above aspect may further comprise a liquid injection portion that is configured to inject the liquid into the cartridge and that is located at an identical position in the Z-axis direction with the positioning structure.
According to this aspect, the liquid injection portion is provided with suppressing size expansion of the cartridge in the Z-axis direction. The term “identical position” is not limited to the case where the center of the positioning structure and the liquid injection portion are located at the same position in the Z-axis direction but also includes the case where the center of the positioning structure in the Z-axis direction is located in a range where the liquid injection portion is located.
(7) The cartridge of the above aspect may further comprise a main body member that is placed inside of the mounting structure in the mounting state and that is provided with the liquid supply portion, the contact portion and the positioning structure. The main body member may include a projection that is located opposed to an inner face of the mounting structure either in the Z-axis direction or in the X-axis direction.
According to this aspect, in the mounting state and in the process of mounting the cartridge to the mounting structure, when the main body member starts rotating about the center axis, the projection hits against the inner face of the mounting structure and thereby suppresses rotation of the main body member. This configuration further reduces the possibility of position misalignment of the main body member relative to the mounting structure in the mounting state and in the mounting process.
(8) The cartridge of the above aspect may further comprise a main body-side identification member that is fit in a mounting structure-side identification member provided on the mounting structure, so as to identify a type of the liquid contained inside of the cartridge. The main body-side identification member may include at least one projection, and at least one of number of the projections, shape of the projection and position of the projection may differ according to the type of the liquid.
According to this aspect, the main body-side identification member prevents the cartridge from being mistakenly inserted into a mounting structure that is different from the correct mounting structure. The configuration that the projection of the main body-side identification member is fit in the mounting structure-side identification member further reduces the possibility of position misalignment of the cartridge relative to the mounting structure.
(9) The cartridge of the above aspect may further comprise a main body member that is placed inside of the mounting structure in the mounting state and that is provided with the liquid supply portion, the contact portion and the positioning structure. The main body member may include a first surface that forms a +Z-axis direction side end face; a second surface that forms a −Z-axis direction side end face; a third surface that forms a −X-axis direction side end face; a fourth surface that forms a +X-axis direction side end face; a fifth surface that forms a +Y-axis direction side end face; and a contact portion placement structure which the contact portion is placed on. The contact portion placement structure may include an upper protruded portion that is protruded from the first surface in the +Z-axis direction. In the mounting state, at least part of the upper protruded portion may be placed in a recess that is provided in the mounting structure to be recessed in the +Z-axis direction.
According to this aspect, in the mounting state, the upper protruded portion is placed in the recess of the mounting structure. Even when the cartridge starts rotating about the center axis, the upper protruded portion hits against the wall surface of the recess and thereby suppresses the rotation. This configuration further reduces the possibility of position misalignment of the cartridge relative to the mounting structure in the mounting state.
(10) In the cartridge of the above aspect, the contact portion may be located on a placement surface arranged to intersect with an X-Y plane that is parallel to the X-axis direction and the Y-axis direction and to intersect with a Y-Z plane that is parallel to the Y-axis direction and the Z-axis direction.
According to this aspect, the placement surface which the contact portion is placed on is arranged to intersect with the X-Y plane and to intersect with the Y-Z plane and is accordingly inclined to the +Y-axis direction that is the moving direction of the cartridge relative to the mounting structure. This configuration causes the electrical connecting element and the contact portion to slightly rub against each other immediately before completion of mounting of the cartridge to the mounting structure. Even when there is any extraneous substance (for example, dust) in the neighborhood of the electrical connecting element or the contact portion, this configuration exerts the effect of discharging the extraneous substance from between the electrical connecting element and the contact portion (wiping effect).
(11) In the cartridge of the above aspect, the contact portion may be located on a placement surface arranged to be parallel to an X-Z plane that is parallel to the X-axis direction and the Z-axis direction.
According to this aspect, the placement surface which the contact portion is placed on is arranged to be parallel to the X-Z plane and is thereby perpendicular to the +Y-axis direction that is the moving direction of the cartridge relative to the mounting structure. This configuration reduces the possibility of significant misalignment of the contact position of the contact portion with the electrical connecting element.
(12) The cartridge of the above aspect may further comprise a guide structure that is configured to guide the electrical connecting element to the contact portion. The guide structure may include a groove that is extended along the Y-axis direction and that is configured to receive part of the mounting structure. The groove may be formed at an identical position in the Z-axis direction with the contact portion.
According to this aspect, the guide structure serves to guide the electrical connecting element to the contact portion and thereby suppresses position misalignment of the contact portion relative to the electrical connecting element in the mounting process. The configuration that the groove is formed at the same position in the Z-axis direction with the contact portion further reduces position misalignment of the contact portion relative to the electrical connecting element. The state that the “groove is formed at the same position in the Z-axis direction with the contact portion” means that part of the contact portion is located in a range where the groove is located in the Z-axis direction.
(13) The cartridge of the above aspect may further comprise a main body member that is placed inside of the mounting structure in the mounting state and that is provided with the liquid supply portion, the contact portion and the positioning structure. An odd number of the contact portions may be arranged along the X-axis direction. A center contact portion that is located at a center among the odd number of the contact portions and the center axis may be located at a center of the main body member in the X-axis direction.
According to this aspect, the center contact portion and the center axis are located at the center of the main body member in the X-axis direction. This configuration suppresses position misalignment of the contact portion relative to the electrical connecting element even when the cartridge is rotated about the center axis in the mounting process or in the mounting state.
(14) In the cartridge of the above aspect, the liquid introducing structure may include a liquid injection needle that is connected with the liquid supply portion and that is configured to cause the liquid from the liquid supply portion to flow inside thereof, and a mounting structure-side cylindrical member that is provided to surround an outer circumference of the liquid injection needle and that is configured to place the liquid injection needle therein. The liquid supply portion may include a flow portion in a cylindrical shape that includes the base end portion and the leading end portion and that is configured to form a flow path which the liquid flows in; and a supply portion protrusion that is protruded outward from an outer surface of the flow portion that forms an outer circumference of the flow portion. The liquid supply portion may be inserted into the mounting structure-side cylindrical member in the mounting state.
According to this aspect, the cartridge has the supply portion protrusion that is protruded outward from the outer surface of the flow portion. This configuration suppresses position misalignment of the flow portion relative to the liquid injection needle in the process of mounting the cartridge to the mounting structure.
(15) In the cartridge of the above aspect, the supply portion protrusion may be formed in a ring shape around entire circumference of the outer surface of the flow portion.
The configuration of this aspect further suppresses position misalignment of the flow portion relative to the liquid injection needle in the process of mounting the cartridge to the mounting structure.
(16) In the cartridge of the above aspect, the liquid supply portion may further include a valve mechanism that is placed in the flow portion and that is configured to open and close the flow path. The valve mechanism may include a valve seat that is configured to form a valve hole; a valve element that is provided to close the valve hole and that is configured to be displaced in the −Y-axis direction by an external force input from the liquid injection needle and to be separated from the valve seat; and a pressing member that is provided to press the valve element toward the valve seat. The valve seat, the valve element and the pressing member may be arranged sequentially from a leading end side. A +Y-axis direction side end of the valve element may be located on a +Y-axis direction side of a +Y-axis direction side end of the supply portion protrusion. A distance L2 may be shorter than a distance L1, where the distance L1 denotes a distance between a −Y-axis direction side end of the mounting structure-side cylindrical member and a −Y-axis direction side end of the liquid injection needle in the Y-axis direction, and the distance L2 denotes a distance between a +Y-axis direction side end of the supply portion protrusion and a +Y-axis direction side end of the valve element in the Y-axis direction.
According to this aspect, the configuration that the distance L2 is shorter than the distance L1 causes the supply portion protrusion to be located in the mounting structure-side cylindrical member before the liquid injection needle comes into contact with the valve element, in the process of mounting the cartridge to the mounting structure. This configuration suppresses position misalignment of the flow portion relative to the liquid injection needle when the liquid injection needle presses in the valve element in the mounting process.
(17) According to another aspect of the present disclosure, there is provided a connector detachably mounted to a mounting structure of a liquid consuming apparatus that is provided with a liquid introducing structure, an electrical connecting element and an engagement structure. An X axis, a Y axis and a Z axis are three spatial axes that are orthogonal to one another. An X-axis direction is a direction along the X axis, a Y-axis direction is a direction along the Y axis, and a Z-axis direction is a direction along the Z axis. In a mounting state the connector is mounted to the mounting structure, direction of gravity is defined as −Z-axis direction, an opposite direction of gravity is defined as +Z-axis direction, one direction in the X-axis direction is defined as +X-axis direction, and the other direction in the X-axis direction is defined as −X-axis direction. The connector comprises a liquid supply portion that is detachably connected with the liquid introducing structure to supply a liquid to the liquid introducing structure; a contact portion that is located on the +Z-axis direction side of the liquid supply portion and that is arranged to contact with the electrical connecting element in the mounting state; and a positioning structure that is located between the liquid supply portion and the contact portion in the Z-axis direction and that is engaged with the engagement structure to restrict motion of the connector relative to the mounting structure in the mounting state. The liquid supply portion includes a leading end portion that forms an opening to receive the liquid introducing structure therein. The liquid supply portion is configured to receive a first external force in a direction including a −Y-axis direction component when the liquid supply portion is connected with the liquid introducing structure. The contact portion is configured to receive a second external force in a direction including the −Y-axis direction component when the contact portion contacts with the electrical connecting element.
According to this aspect, the first external force causes a first moment in a first rotating direction having a −Y-axis direction component to be generated about the positioning structure as a supporting point in the connector. The second external force causes a second moment in a second rotating direction having a −Y-axis direction component to be generated about the positioning structure as a supporting point in the connector. According to this aspect, the positioning structure is placed between the liquid supply portion and the contact portion in the Z-axis direction. This configuration causes the first moment in the first rotating direction and the second moment in the second rotating direction to be applied to the connector in the directions of cancelling each other. This configuration reduces the possibility of position misalignment of the connector relative to the mounting structure in the mounting process and in the mounting state. According to this aspect, the liquid supply portion is provided on the −Z-axis direction side that is the direction of gravity side of the contact portion. This configuration reduces the possibility that the contact portion is stained with the liquid even when the liquid is leaked out from the liquid supply portion.
(18) According to another aspect of the present disclosure, there is provided a connector that is detachably mounted to a mounting structure of a liquid consuming apparatus and that includes a supply flow path configured to supply a liquid from a liquid supply source to the mounting structure. This connector comprises a supply member that forms an upstream end of the supply flow path in a flow direction of the liquid that flows from the connector toward the mounting structure; and a connection main body member that forms a downstream end of the supply flow path in the flow direction and that is connected with the mounting structure. The supply member has a first supply opening portion that includes the upstream end, and a second supply opening portion that is located on a downstream side of the first supply opening portion in the flow direction. The connection main body member has an insertion structure that is inserted in the second supply opening portion and that forms part of the supply flow path, and a sealing main body structure that is provided to surround the insertion structure and that is configured to press the second supply opening portion toward a location where the insertion structure is located, such that an outer circumferential surface of the insertion structure and an inner circumferential surface of the second supply opening portion come into contact with each other in a circumferential direction. The connector further includes a first elastic seal member that is located on a first supply opening portion side of a contact position of the outer circumferential surface of the insertion structure with the inner circumferential surface of the second supply opening portion and that is located between the outer circumferential surface of the insertion structure and the inner circumferential surface of the second supply opening portion to seal a gap between the outer circumferential surface of the insertion structure and the inner circumferential surface of the second supply opening portion.
According to this aspect, the connector forming the supply flow path which the liquid from the liquid supply source flows in includes the sealing main body structure and the first elastic seal member. The sealing main body structure causes the outer circumferential surface of the insertion structure and the inner circumferential surface of the second supply opening portion to come into contact with each other in the circumferential direction. The first elastic seal member serves to seal the gap between the outer circumferential surface of the insertion structure and the inner circumferential surface of the second supply opening portion. This configuration suppresses leakage of the liquid to outside by a narrower required space, compared with a configuration that the liquid supply source and the connector are covered by a sealed case to suppress leakage of the liquid to outside. This configuration accordingly reduces the possibility of a failure to sufficiently exert the function of suppressing leakage of the liquid to outside, due to position misalignment between the members or a tolerance of the member. The connector has the double seal structure formed by the first elastic seal member and by the contact of the outer circumferential surface of the insertion structure with the inner circumferential surface of the second supply opening portion in the circumferential direction by the sealing main body structure and thereby more effectively suppresses leakage of the liquid to outside.
(19) In the connector of the above aspect, the insertion structure of the connection main body member may include an insertion structure inner circumferential surface that defines part of the supply flow path formed by the insertion structure and that is located on an opposite side to the outer circumferential surface of the insertion structure where the first elastic seal member is located, a first rib that has respective ends connected with the insertion structure inner circumferential surface, and a second rib that has two second rib ends connected with the insertion structure inner circumferential surface and that is arranged to intersect with the first rib.
According to this aspect, the insertion structure has the first rib and the second rib and accordingly suppresses deformation of the insertion structure caused by an external force applied from the first elastic seal member to the insertion structure. This configuration reduces the possibility of leakage of the liquid from the gap between the insertion structure and the supply member to outside.
(20) The connector of the above aspect may further comprise a filter that is located on a downstream side of the insertion structure in the supply flow path in the flow direction and that is configured to prevent an extraneous substance from passing through.
Even when an extraneous substance is mixed into the liquid that flows from the upstream side of the filter toward the downstream side of the filter, the configuration of this aspect reduces the possibility that the extraneous substance reaches the mounting structure
(21) In the connector of the above aspect, the connection main body member may include a first projection that is located on an outer circumference of the filter and that is configured to restrict motion of the filter in a direction that is perpendicular to the flow direction.
According to this aspect, the first projection serves to restrict the motion of the filter and thereby suppresses position misalignment of the filter. This accordingly further reduces the possibility that the extraneous substance reaches the mounting structure.
(22) In the connector of the above aspect, the connection main body member may have an intermediate member that includes the insertion structure, and a connection member that forms the downstream end in the flow direction and that is connected with the intermediate member. The connector may further comprise a second elastic seal member configured to seal a gap between the intermediate member and the connection member.
According to this aspect, the presence of the second elastic seal member further reduces the possibility of leakage of the liquid to outside.
(23) In the connector of the above aspect, the connection member may include a second projection that is located on an intermediate member side of the second elastic seal member and that is connected with the intermediate member.
According to this aspect, the second projection causes the connection member to be connected with the intermediate member.
(24) In the connector of the above aspect, the connection main body member may include an injection flow path that is arranged to cause a liquid to flow from outside toward the liquid supply source and that joins the supply flow path on an upstream side of the filter in the flow direction. The connection member may include a recess that has a bottom wall provided with a supply path opening that forms the supply flow path and an injection path opening that forms the injection flow path, and a groove that is provided to surround an outer circumference of the recess. The recess may include a partition wall in a frame-like shape that rises from the bottom wall to surround the supply path opening and that has the filter attached at an end opposite to a side where the bottom wall is located. The second elastic seal member may be placed in the groove to be pressed by the groove and the intermediate member, so as to seal a gap between the groove and the intermediate member.
According to this aspect, the groove is provided to surround the outer circumference of the recess in which the supply path opening and the injection path opening are formed. The second elastic seal member is pressed by the groove and the intermediate member to seal the gap between the groove and the intermediate member. This configuration accordingly reduces the possibility of leakage of the liquid to outside when the liquid flows in the injection flow path and when the liquid from the liquid supply source flows in the supply flow path.
(25) In the connector of the above aspect, the connection main body member may include an intermediate member that includes the insertion structure, and a connection member that forms the downstream end of the supply flow path in the flow direction and that is connected with the intermediate member. The intermediate member and the connection member may be welded to each other to surround a circumference of the supply flow path.
According to this aspect, the intermediate member and the connection member are welded to each other to surround the circumference of the supply flow path. This configuration reduces the possibility of leakage of the liquid in the supply flow path from the boundary between the intermediate member and the connection member to outside.
The present disclosure may be implemented by any of various aspects other than the cartridge and the connector described above. For example, the present disclosure may be implemented by a liquid container including the connector and a liquid supply source, a connector unit including the connector and a case, a manufacturing method of the cartridge or the connector, a liquid consumption system including the cartridge (liquid container) and a liquid consuming apparatus, a liquid consumption system including the connector and a liquid consuming apparatus, and a liquid consumption system including the connector unit and a liquid consuming apparatus.
The liquid consumption system 1 includes a liquid consuming apparatus 10, cartridges 30, a main placement rack 19 and a sub placement rack 18. The liquid consuming apparatus 10 is an inkjet textile printing machine configured to perform recording (printing) by ejecting ink as one example of a liquid onto a medium such as a fabric product. According to another embodiment, the liquid consuming apparatus 10 may be a printer configured to perform recording (printing) by ejecting ink on paper.
Eight cartridges 30 are provided. The eight cartridges 30 respectively contain different colors of liquids (inks). Reference signs 30A to 30H are used for discrimination of the eight cartridges 30. The cartridge (liquid container) 30A contains a liquid of cyan (C) color. A cartridge (liquid container) 30B contains liquid of a magenta (M) color. A cartridge (liquid container) 30C contains a liquid of yellow (Y) color. A cartridge (liquid container) 30D contains a liquid of black (K) color. A cartridge (liquid container) 30E contains a liquid of red (R) color. A cartridge (liquid container) 30F contains a liquid of blue (B) color. A cartridge (liquid container) 30G contains a liquid of orange (O) color. A cartridge (liquid container) 30H contains a liquid of gray (LK) color. According to another embodiment, the number of the cartridges 30 may be less than 8 or greater than 8.
The main placement rack 19 is provided outside of the liquid consuming apparatus 10 and is used to place the eight cartridges 30 thereon. The main placement rack 19 has a two-shelf structure. The cartridges 30A to 30D are placed on an upper shelf, and the cartridges 30E to 30H are placed on a lower shelf. Respective one ends of first tubes 98 described later are placed on the main placement rack 19.
The sub placement rack 18 is used to place eight sub-tanks 18a thereon. The eight sub-tanks 18a are provided corresponding to the eight cartridges 30A to 30H. The cartridges 30A to 30H are arranged to communicate with the corresponding sub-tanks 18a by means of flexible first tube 98. Eight first tubes 98 are provided corresponding to the cartridges 30A to 30H. The liquid contained in each of the cartridges 30A to 30H is flowed through the first tube 98 and is supplied to the corresponding sub-tank 18a by a suction mechanism (not shown) (for example, a pump (not shown) placed on the sub placement rack 18) included in the liquid consumption system 1.
The liquid consuming apparatus 10 includes an outer shell 12, a liquid consuming portion 14, a controller 16, first tubes 98, mounting structures 20 and second tubes 99. The outer shell 12 is formed in an approximately rectangular parallelepiped external shape. The outer shell 12 forms an outer surface of the liquid consuming apparatus 10.
The liquid consuming portion 14 is placed inside of the outer shell 12. The liquid consuming portion 14 is arranged to communicate with the sub-tanks 18a by flexible second tubes 99 provided for the respective sub-tanks 18a. The liquids flowed through the respective second tubes 99 are supplied to the liquid consuming portion 14. According to this embodiment, the liquids contained in the sub-tanks 18a are supplied through the second tubes 99 to the liquid consuming portion 14 by a pressurization mechanism (not shown) (for example, a pump) included in the liquid consuming apparatus 10. The liquid consuming portion 14 has an ejection head that is configured to eject the liquids onto a medium such as a fabric product. The liquid consuming portion 14 moves back and forth along the Y-axis direction by means of a drive mechanism (not shown) included in the liquid consuming apparatus 10. While the liquid consuming portion 14 moves back and forth along the Y-axis direction with ejecting the liquids, the medium is moved inside of the outer shell 12 from a +X-axis direction side toward a −X-axis direction side by means of a conveyance mechanism (not shown) of the liquid consuming apparatus 10. This configuration causes the liquid to be ejected onto the medium. After ejection of the liquids, the medium is discharged from an ejection slot 17 provided on a −X-axis direction side face (front face) of the outer shell 12 to outside of the outer shell 12. According to another embodiment, the liquid consuming portion 14 may be a line head that does not move back and forth but is fixed in position.
The controller 16 is placed inside of the outer shell 12. The controller 16 controls the operations of the liquid consuming apparatus 10. The controller 16 controls, for example, the operations of the drive mechanism and the conveyance mechanism mentioned above. The controller 16 is also electrically connected with the cartridges 30 to transmit various information to and from the cartridges 30. The various information include, for example, color information regarding the colors of the liquids contained in the respective cartridges 30 and information regarding the state of mounting or non-mounting of the respective cartridges 30 to the liquid consuming apparatus 10.
The mounting structure 20 includes release elements 292 provided on respective sides in the X-axis direction (only one release element is shown in
The mounting structure 20 (shown in
In the mounting state that the cartridge 30 is mounted to the mounting structure 20, the mounting structure first surface 211 forms an upper face, and the mounting structure second surface 212 forms a bottom face. The mounting structure third surface 213 forms one side face, and the mounting structure fourth surface 214 forms the other side face. The mounting structure fifth surface 215 forms a bottom of the recess. The opening 216 is opposed to the mounting structure fifth surface 215 and defines an opening which part of the cartridge 30 (more specifically, a cartridge main body described later) passes through in the mounting process. The mounting structure first surface 211 and the mounting structure second surface 212 are opposed to each other in the Z-axis direction. The mounting structure third surface 213 and the mounting structure fourth surface 214 are opposed to each other in the X-axis direction. The mounting structure fifth surface 215 and the opening 216 are opposed to each other in the Y-axis direction. The mounting structure first surface 211 to the mounting structure fifth surface 215 define a housing space 21A to place the cartridge main body therein as described above.
The mounting structure 20 (shown in
The liquid introducing structure 22 includes a liquid injection needle 223 and a mounting structure-side cylindrical member 221. The liquid injection needle 223 has a center axis 22CT that is extended along the Y-axis direction. The liquid injection needle 223 is hollow inside and has a flow path that is formed inside thereof to allow the liquid to flow in. In the mounting state, the liquid injection needle 223 is connected with a liquid supply portion of the cartridge 30 described later and causes the liquid supplied from the liquid supply portion to flow inside of the liquid injection needle 223. A base end (+Y-axis direction side end) of the liquid injection needle 223 is arranged to communicate with the first tube 98.
The mounting structure-side cylindrical member 221 is arranged to surround the outer circumference of the liquid injection needle 223 about the center axis 22CT. The mounting structure-side cylindrical member 221 is also arranged to place the liquid injection needle 223 inside thereof. The mounting structure-side cylindrical member 221 has a −Y-axis direction side end that is open. The center axis of the mounting structure-side cylindrical member 221 is identical with the center axis 22CT of the liquid injection needle 223.
The apparatus-side electrical mechanism 24 includes electrical connecting elements 242 as terminals, a placement base 241 which the electrical connecting elements 242 are placed on, and mounting structure-side projections 245. In the mounting state, the apparatus-side electrical mechanism 24 is located on an opposite direction of gravity side (+Z-axis direction side) of the liquid introducing structure 22.
The electrical connecting element 242 is a metal plate-like member that is elastically deformable. Part of the electrical connecting element 242 is exposed on a surface 241fa of the placement base 241. The surface 241fa is a plane parallel to the X-axis direction and the Z-axis direction in the mounting state. The electrical connecting element 242 is elastically deformed about a bend formed inside of the placement base 241 as a supporting point, so that the exposed part on the surface 241fa is displaced in a direction including a Y-axis direction component. Seven electrical connecting elements 242 are provided (as shown in
The placement base 241 (shown in
The mounting structure-side projections 245 (shown in
Two engagement structures 26 (shown in
Out of the two engagement structures 26, the engagement structure 26 located on a −X-axis direction side (mounting structure third surface 213—side) of the electrical connecting elements 242 and the liquid introducing structure 22 is called “first engagement structure 26A”. Out of the two engagement structures 26, the engagement structure 26 located on a +X-axis direction side (mounting structure fourth surface 214—side) of the electrical connecting elements 242 and the liquid introducing structure 22 is called “second engagement structure 26B”. In the mounting state, with regard to the Z-axis direction, the engagement structures 26 are located between the electrical connecting elements 242 and the liquid introducing structure 22. The engagement structure 26 is a columnar member that is extended from the mounting structure fifth surface 215 toward the opening 216—side (−Y-axis direction side). The engagement structure 26 has an engagement claw 262 on its −Y-axis direction side end. The engagement claw 262 is formed to be bent inward in the housing space 21A. When two engagement claws 262 are to be distinguished from each other, the two engagement claws 262 are respectively expressed by reference signs “262A” and “262B”.
The engagement claw 262B of the second engagement structure 26B (shown in
The mounting structure-side identification member 28 (shown in
The liquid container case 31 is formed in an approximately rectangular parallelepiped external shape. According to this embodiment, the liquid container case 31 is made of cardboard. According to another embodiment, the liquid container case 31 may be made of another material (for example, a synthetic resin such as polypropylene or polyethylene). The liquid container case 31 includes a case first surface (case first wall) 311, a case second surface (case second wall) 312, a case third surface (case third wall) 313, a case fourth surface (case fourth wall) 314, a case fifth surface (case fifth wall) 315, and a case sixth surface (case sixth wall) 316.
In the mounting state of the cartridge 30, the case first surface 311 forms an upper face, the case second surface 312 forms a bottom face. The case third surface 313 forms one side face, and the case fourth surface 314 forms the other side face. The case fifth surface 315 forms a front face that is opposed to the mounting structure 20, and the case sixth surface 316 form a rear face. The case first surface 311 and the case second surface 312 are opposed to each other in the Z-axis direction. The case third surface 313 and the case fourth surface 314 are opposed to each other in the X-axis direction. The case fifth surface 315 and the case sixth surface 316 are opposed to each other in the Y-axis direction. An opening 318 is formed in the case fifth surface 315 to place the connector 40 inserted therein. In use of the cartridge 30 to supply the liquid contained in the liquid container body 32 to the mounting structure 20, part of the connector 40 is exposed outside of the liquid container case 31. In non-use of the cartridge 30, for example, during transportation of the cartridge 30, on the other hand, the entire connector 40 may be placed inside of the liquid container case 31. For example, the connector 40 may be placed inside of the liquid container case 31 by opening an openable lid 319a provided by a cut line 319 formed in the case fifth surface 315. According to another embodiment, the cartridge 30 may not be provided with the liquid container case 31.
The liquid container body 32 is configured to contain the liquid (ink) that is to be supplied to the mounting structure 20. The liquid container body 32 is a bag body that is filled with the liquid. The liquid container body 32 is arranged to communicate with a liquid supply portion of the connector 40 described later. When the liquid contained in the liquid container body 32 is consumed and used up to no remaining amount or little remaining amount, the liquid container body 32 and the connector 40 are replaced with new ones.
The connector 40 is electrically connected with the electrical connecting elements 242 of the mounting structure 20 and is connected with the liquid injection needle 223 of the mounting structure 20. This configuration enables the cartridge 30 to transmit electrical signals to and from the controller 16 (shown in
The connector 40 (shown in
The supply member 49 is a tubular member. One end 49A-side of the supply member 49 is mounted to the liquid container body 32 by thermal welding or the like. The other end 49B-side of the supply member 49 fit in the intermediate member 48 via an O-ring (not shown). The supply member 49 forms a flow path 492 which the liquid contained in the liquid container body 32 flows in. The supply member 49 is made of, for example, a synthetic resin such as polyethylene.
The intermediate member 48 is a member located between the main body member 41 and the supply member 49. The intermediate member 48 forms a flow path 482 which the liquid flowing through the flow path 492 of the supply member 49 flows in. The intermediate member 48 is made of, for example, a synthetic resin such as polypropylene. An opposite side portion of the intermediate member 48 that is opposite to the side where the supply member 49 is located is fit in the main body member 41 via an O-ring (not shown).
The main body member 41 is placed in the housing space 21A (shown in
The main body member 41 (shown in
In the mounting state, the first surface 411 forms a +Z-axis direction side end face (upper face). In the mounting state, the second surface 412 forms a −Z-axis direction side end face (bottom face). In the mounting state, the third surface 413 forms a −X-axis direction side end face (one side face). In the mounting state, the fourth surface 414 forms a +X-axis direction side end face (the other side face). In the mounting state, the fifth surface 415 forms a +Y-axis direction side end face (front face). In the mounting state, the sixth surface 416 forms an opening which the intermediate member 48 is fit in. The first surface 411 and the second surface 412 are portions opposed in the Z-axis direction to inner faces of the housing space 21A of the mounting structure 20. The third surface 413 and the fourth surface 414 are portions opposed in the X-axis direction to inner faces of the housing space 21A of the mounting structure 20.
The main body member 41 (shown in
The projections (first projections) 401 (shown in
With regard to the Z-axis direction or the X-axis direction described above, the numbers of the projections 401 to 404 provided on the portions (first surface 411 to fourth surface 414) opposed to the inner faces of the mounting structure 20 are not limited to those of the above embodiment. For example, the number of each of the projections 401 to 404 may be only one or may be three or more. In another example, some of the projections 401 to 404 may be omitted. In any of such configurations, at least one of the projections 401 to 404 serves to suppress rotation of the main body member 41 about the center axis 42CT in the process of mounting the cartridge 30 to the mounting structure 20 and in the mounting state.
The main body member 41 (shown in
The liquid supply portion 42 is detachably connected with the liquid introducing structure 22 (more specifically, the liquid injection needle 223) of the mounting structure 20 to supply the liquid to the liquid introducing structure 22 (more specifically, the liquid injection needle 223). The liquid supply portion 42 is inserted in the mounting structure-side cylindrical member 221 of the liquid introducing structure 22 in the mounting process and in the mounting state of the cartridge 30.
The liquid supply portion 42 (shown in
The liquid supply portion 42 also has the center axis 42CT that is extended in a direction (Y-axis direction) along the +Y-axis direction from the base end 42A toward the leading end 42B. The center axis 42CT is a center axis of a flow portion 423 in a cylindrical shape (described later) of the liquid supply portion 42. As shown in
The liquid supply portion 42 (shown in
The supply portion protrusion 421 is protruded outward from an outer surface of the flow portion 423 that forms the outer circumference of the flow portion 423 about the center axis 42CT. The supply portion protrusion 421 is formed in a ring shape around the whole circumference of the outer surface of the flow portion 423. The supply portion protrusion 421 works in cooperation with the mounting structure-side cylindrical member 221 to restrict the motion of the flow portion 423 in the process of mounting the cartridge 30 to the mounting structure 20 and in the mounting state of the cartridge 30. More specifically, the supply portion protrusion 421 is inserted in the mounting structure-side cylindrical member 221 across a small clearance from the inner face of the mounting structure-side cylindrical member 221. When the flow portion 423 moves relative to the mounting structure 20 in a radial direction (i.e., a direction that is perpendicular to the center axis 42CT and is along an X-Z plane that is parallel to the X-axis direction and the Z-axis direction), the supply portion protrusion 421 hits against the inner face of the mounting structure-side cylindrical member 221, so as to restrict the motion of the flow portion 421 in the direction perpendicular to the center axis 42CT. This configuration accordingly suppresses position misalignment of the flow portion 423 relative to the liquid injection needle 223 in the mounting process and in the mounting state. Suppressing the position misalignment of the flow portion 423 relative to the liquid injection needle 223 reduces the possibility that the liquid is leaked from the flow portion 423 to outside in the mounting process and in the mounting state.
The liquid supply portion 42 (shown in
The valve seat 427 is a member in an approximately annular shape. The valve seat 427 is formed by an elastic body of, for example, a rubber or an elastomer. The valve seat 427 is press fit in the flow portion 423. The valve seat 427 forms a valve hole 42711 which the liquid flows in.
The valve element 428 is a member in an approximately cylindrical shape. The valve element 428 comes into contact with the valve seat 427 to close the valve hole 42711 in the state prior to mounting the cartridge 30 to the mounting structure 20. The valve element 428 is, for example, displaced in the −Y-axis direction by a force (external force) input from the liquid injection needle 223 to be separated from the valve seat 427.
The pressing member 429 is a compression coil spring. The pressing member 429 serves to press the valve element 428 toward the valve seat 427. In the mounting state of the cartridge 30, the liquid injection needle 223 (shown in
The main body-side electrical mechanism 44 (shown in
The circuit board 443 (shown in
Seven main body-side terminals 442 are provided. When the seven main body-side terminals 442 are to be distinguished from one another, the seven main body-side terminals are expressed by reference signs “442A”, “442B”, “442C”, “442D”, “442E”, “442F” and “442G”. The seven main body-side terminals 442A to 442G denote seven terminals including a power supply terminal, a grounding terminal, a data terminal, a clock terminal, a reset terminal, a first mounting detection terminal and a second mounting detection terminal. Which of the seven terminals (for example, power supply terminal) is to be allocated to each of the main body-side terminals 442A to 442G is determined arbitrarily. The reset terminal receives supply of a reset signal to the storage device. The clock terminal receives supply of a clock signal to the storage device. The power supply terminal receives a power supply voltage VDD (for example, rated voltage of 3.3 V) to the storage device. The grounding terminal receives supply of a grounding voltage VSS (0 V) to the storage device. The data terminal receives supply of a data signal SDA to the storage device. The first mounting detection terminal and the second mounting detection terminal are used to check the quality (good or bad) of electrical contact with the corresponding electrical connecting element 242 and thereby causes the liquid consuming apparatus 10 to detect whether the cartridge 30 is mounted to the mounting structure 20. The number of the main body-side terminals 442 and the functions of the respective terminals may be changed appropriately.
The storage device of the circuit board 443 stores information regarding the cartridge 30 (for example, color information regarding the color of the liquid and information regarding the remaining amount of the liquid) and the like.
Each of the seven main body-side terminals 442A to 442G is formed in an approximately rectangular shape. The seven main body-side terminals 442A to 442G are arranged to form two lines Ln1 and Ln2 at different positions in the Z-axis direction. The lines Ln1 and Ln2 are parallel to the X-axis direction.
Each of the main body-side terminals 442A to 442G has a contact portion CP that is formed in its center and that is configured to come into contact with a corresponding electrical connecting element 242 in the mounting state. In the mounting state, the respective contact portions CP are located on a +Z-axis direction side of the liquid supply portion 42. The cartridge 30 has the liquid supply portion 42 on a −Z-axis direction side or gravity direction side of the contact portions CP. This configuration reduces the possibility that the contact portion CP is stained with the liquid even when the liquid is leaked out from the liquid supply portion 42. This reduces the possibility of a short circuit between a plurality of contact portions CP caused by the liquid adhering to the contact portion CP.
The above lines Ln1 and Ln2 may be regarded as lines formed by a plurality of the contact portions CP. In the mounting state, the contact portions CP are in contact with and are thereby electrically connected with the electrical connecting elements 242. This configuration enables, for example, data signals to be transmitted between the storage device of the circuit board 443 and the controller 16 of the liquid consuming apparatus 10.
The seven contact portions CP are placed at different positions in the X-axis direction. According to this embodiment, the seven contact portions CP are arranged in zigzag in the X-axis direction. Among the seven contact portions CP, a contact portion located on a most +X-axis direction side in the X-axis direction is called first contact portion CP1, and a contact portion located on a most −X-axis direction side in the X-axis direction is called second contact portion CP2. According to this embodiment, the first contact portion CP1 and the second contact portion CP2 are located on the line Ln1 along the X-axis direction. As shown in
Among the seven contact portions CP, an odd number of (more specifically, three) contact portions CP along the X-axis direction form the line Ln2. A contact portion located on the center (in the middle) of this odd number of contact portions CP is called “center contact portion CPC”. The center contact portion CPC is located at the same position as that of the center 44CP in the X-axis direction. As shown in
The guide structure 43 (shown in
The guide structure 43 is formed in a concave shape that is open on its +Y-axis direction side and +Z-axis direction side. The guide structure 43 includes a first side face (first side wall) 433 (shown in
The guide structure 43 also includes a groove 45A formed in the first side face 433 (shown in
The grooves 45A and 45B are extended along the Y-axis direction. The groove 45A is provided to receive the mounting structure-side projection 245 on the −X-axis direction side (shown in
The grooves 45A and 45B (shown in
In the mounting state, the positioning structure 46 (shown in
The positioning structure 46 is protruded in the +Y-axis direction from the fifth surface 415. The positioning structure 46 includes positioning projections 463. As shown in
Two positioning projections 463 (shown in
The first positioning projection 463A includes a first engaged element 462A and a first protruded guide element 465A. The first engaged element 462A engages with the engagement claw 262A of the first engagement structure 26A (shown in
The first protruded guide element 465A is formed by a +Y-axis direction side end of the positioning structure 46. The first protruded guide element 465A is formed to be located on the −Y-axis direction side toward the −X-axis direction. The first engaged element 462A is connected with a −X-axis direction side end of the first protruded guide element 465A. The first protruded guide element 465A serves to guide the engagement claw 262A of the first engagement structure 26A to the first engaged element 462A in the mounting process.
A second protruded guide element 465B (shown in
As shown in
As shown in
As shown in
The liquid injection portion 461 (shown in
The main body-side identification member 408 (shown in
As shown in
In the mounting state, the electrical connecting elements 242 come into contact with the contact portions CP in the state that electrical connecting elements 242 are pressed in and displaced from the surface 241fa by the circuit board 443. In the mounting process, at a stage immediately before the mounting state, the electrical connecting elements 242 are similarly pressed in from the surface 241fa by the circuit board 443. In the state that the electrical connecting elements 242 are pressed in from the surface 241fa, the electrical connecting elements 242 apply a second external force F2 of a −Y-axis direction component to the contact portions CP. In other words, the contact portions CP are configured to receive the second external force F2 in the −Y-axis direction from the electrical connecting elements 242 when the contact portions CP come into contact with the electrical connecting elements 242.
As shown in
In the mounting process, the first external force F1 causes the first moment M1 in the first rotating direction having the −Y-axis direction component to be generated about the abutting position of the positioning structure 46 and the engagement structure 26 as a supporting point in the connector 40 of the cartridge 30. In the mounting process, the second external force F2 causes the second moment M2 in the second rotating direction having the −Y-axis direction component to be generated about the abutting position of the positioning structure 46 and the engagement structure 26 as a supporting point in the connector 40 of the cartridge 30. The first rotating direction and the second rotating direction are opposite rotating directions, so that the first moment M1 in the first rotating direction and the second moment M2 in the second rotating direction are applied to the connector 40 in the directions of cancelling each other. In the mounting process, this configuration suppresses rotation of the connector 40 about the X axis and thereby reduces the possibility of position misalignment of the cartridge 30 (more specifically, the connector 40) relative to the mounting structure 20.
It is assumed that the cartridge 30 starts rotating about the center axis 42CT relative to the mounting structure 20 on and along the X-Z plane that is parallel to the X-axis direction and the Z-axis direction as shown in
It is, on the other hand, assumed that the cartridge 30 is rotated about the center axis 42CT relative to the mounting structure 20 by the angle θa along the X-Z plane in the case where the center 44CP and the center contact portion CPC are located at positions deviated from the virtual straight line Ls as shown in
The value D2 is smaller than the value D1. The configuration that the center 44CP is located on the virtual straight line Ls suppresses position misalignment of the plurality of contact portions CP relative to the electrical connecting elements 242 on the X-Z plane even when the cartridge 30 is rotated about the center axis 42CT relative to the mounting structure 20 along the X-Z plane that is parallel to the X-axis direction and the Z-axis direction and has position misalignment relative to the mounting structure 20 on the X-Z plane. The state that “the center 44CP is located on the virtual straight line Ls” herein is not limited to the case where the center 44CP is located exactly on the virtual straight line Ls but includes the case where there is a slight deviation of the center 44CP from the virtual straight line Ls by taking into account the capability of suppressing position misalignment of the contact portions CP relative to the electrical connecting elements 242 on the X-Z plane.
According to the above embodiment, the center contact portion CPC and the center axis 42CT are located at the center 41CT of the main body member 41 (as shown in
According to the above embodiment, in the mounting process and in the mounting state, the projections 409 of the main body-side identification member 408 are fit in the mounting structure-side identification member 28. This configuration causes the main body-side identification member 408 to hit against the mounting structure-side identification member 28 when the cartridge 30 starts rotating about the center axis 42CT relative to the mounting structure 20. This configuration further reduces the possibility of position misalignment of the cartridge 30 relative to the mounting structure 20.
According to the above embodiment, when the cartridge 30 is viewed from the +Y-axis direction side, the center 46CP of the positioning structure 46 in the X-axis direction is located on the virtual straight line (as shown in
According to the above embodiment, the first engaged element 462A and the second engaged element 462B are located across the virtual straight line Ls (as shown in
According to the above embodiment, the cartridge 30 is provided with the first protruded guide element 465A and the second protruded guide element 465B. This configuration causes the first engagement structure 26A and the second engagement structure 26B to be respectively guided to the first engaged element 462A and to the second engaged element 462B in the process of mounting the cartridge 30 to the mounting structure 20. This configuration accordingly ensures engagement of the first engagement structure 26A with the first engaged element 462A and engagement of the second engagement structure 26B with the second engaged element 462B with higher reliability.
According to the above embodiment, in the mounting process and in the mounting state, placing the upper protruded portion 445 (shown in
According to the above embodiment, the contact portions CP are located on the placement surface 443fa parallel to the X-Z plane that is parallel to the X-axis direction and the Z-axis direction (as shown in
The main body-side electrical mechanism 44a includes a circuit board 443a. The circuit board 443a is placed on a bottom face 432a of a guide structure 43a. Like the first embodiment, the guide structure 43a is formed in a concave shape that is open on its +Y-axis direction side and +Z-axis direction side. The bottom face 432a is arranged to intersect with an X-Y plane that is parallel to the X-axis direction and the Y-axis direction and with a Y-Z plane that is parallel to the Y-axis direction and the Z-axis direction. According to this embodiment, the direction of a normal vector of the bottom face 432a is a direction including a +Z-axis direction component and a +Y-axis direction component. Nine main body-side terminals 442 are placed on a placement surface 443faa that is a surface of the circuit board 443a. The placement surface 443faa is arranged to intersect with the X-Y plane that is parallel to the X-axis direction and the Y-axis direction and with the Y-Z plane that is parallel to the Y-axis direction and the Z-axis direction. According to this embodiment, the direction of a normal vector of the placement surface 443faa is a direction including a +Z-axis direction component and a +Y-axis direction component.
The nine main body-side terminals 442 include seven main body-side terminals having the same functions as those of the seven main body-side terminals 442A to 442G (shown in
The mounting structure which the cartridge 30a of the second embodiment is mounted to has a different configuration from that of the mounting structure 20 of the first embodiment, corresponding to the configuration of the main body-side electrical mechanism 44a of the cartridge 30a. More specifically, the difference from the mounting structure 20 of the first embodiment (shown in
The cartridge 30a of the second embodiment described above receives an external force from the mounting structure of the liquid consuming apparatus 10 as described below. More specifically, the liquid supply portion 42 receives a first external force in the −Y-axis direction from the liquid introducing structure 22 when the liquid supply portion 42 is connected with the liquid introducing structure 22. The contact portions CP receive a second external force in a direction including a −Y-axis direction component from the electrical connecting elements 242 when the contact portions CP come into contact with the electrical connecting elements 242.
The second embodiment described above has the similar configuration to the configuration of the first embodiment and accordingly has similar advantageous effects to those of the first embodiment. A first moment in a first rotating direction generated by the first external force and a second moment in a second rotating direction generated by the second external force are applied to the cartridge 30a in the directions of cancelling each other. This configuration reduces the possibility of position misalignment of the cartridge 30a relative to the mounting structure in the mounting process and in the mounting state. The liquid supply portion 42 is provided on a −Z-axis direction side or gravity direction side of the contact portions CP. This configuration reduces the risk that the contact portion CP is stained with the liquid even when the liquid is leaked out from the liquid supply portion 42.
According to the above second embodiment, the contact portions CP are located on the placement surface 443faa arranged to intersect with the X-Y plane that is parallel to the X-axis direction and the Y-axis direction and with the Y-Z plane that is parallel to the Y-axis direction and the Z-axis direction. The contact surface 443faa with the contact portions CP placed thereon is arranged to intersect with the X-Y plane and with the Y-Z plane and is accordingly inclined to the +Y-axis direction that is the moving direction of the cartridge 30a relative to the mounting structure. This configuration causes the electrical connecting elements 242 and the contact portions CP to slightly rub against each other immediately before completion of mounting of the cartridge 30a to the mounting structure. Even when there is any extraneous substance (for example, dust) in the neighborhood of the electrical connecting elements 242 or the contact portions CP, this configuration exerts the effect of discharging the extraneous substance from between the electrical connecting elements 242 and the contact portions CP (wiping effect).
A preferable first relationship between the liquid introducing structure 22 and the liquid supply portion 42 in each of the above embodiments is described with reference to
As shown in
As shown in
It is preferable that the distance L2 is shorter than the distance L1. This configuration causes the supply portion protrusion 421 to be located in the mounting structure-side cylindrical member 221 before the liquid injection needle 223 comes into contact with the valve element 428 in the process of mounting the cartridge 30 or 30a to the mounting structure 20. This configuration suppresses position misalignment of the flow portion 423 relative to the liquid injection needle 223 when the liquid injection needle 223 presses in the valve element 428 in the mounting process. This configuration accordingly reduces the possibility of leakage of the liquid from the flow portion 423 to outside in the mounting process.
A preferable second relationship between the liquid introducing structure 22 and the liquid supply portion 42 in each of the above embodiments is described with reference to
As shown in
As shown in
It is preferable that the distance L4 is longer than the distance L3. This configuration causes the supply portion protrusion 421 to be located in the mounting structure-side cylindrical member 221 before the liquid injection needle 223 comes into contact with the valve element 428 in the process of mounting the cartridge 30 or 30a to the mounting structure 20. This configuration suppresses position misalignment of the flow portion 423 relative to the liquid injection needle 223 when the liquid injection needle 223 presses in the valve element 428 in the mounting process. This configuration accordingly reduces the possibility of leakage of the liquid from the flow portion 423 to outside in the mounting process.
The cartridge 30 of the first embodiment or the cartridge 30a of the second embodiment described above may be provided with a mechanism of refilling the liquid container body 32 with the liquid or replacing the liquid container body 32. The following describes concrete examples of this mechanism.
The adapter 32d is configured to contain the liquid that is to be supplied to the liquid consuming apparatus 10. The adapter 32d is placed in the liquid container case 31d in a demountable manner. For example, the adapter 32d is inserted through an upper opening 311d of the liquid container case 31d to be placed in the liquid container case 31d.
The adapter 32d is configured to include a connection opening 68 and a fill port 60d. The connection opening 68 is arranged to communicate with inside of the adapter 32d and causes the liquid contained in the adapter 32d to be flowed to outside. A liquid retaining member is placed in the connection opening 68 to suppress leakage of the liquid to outside. The liquid retaining member may be, for example, a sponge that is a porous member. The liquid retaining member may be replaced with a valve mechanism. The connection opening 68 is connectable with a supply member 49 of the connector 40. The user connects the connection opening 68 with the supply member 49 when the adapter 32d is placed into the liquid container case 31d. This enables the liquid contained in the adapter 32d to be flowed through the connection opening 68 to the connector 40—side.
The fill port 60d is provided on an upper face of the adapter 32d. The fill port 60d is formed to pass through the wall of the adapter 32d and communicate with the adapter 32d. When a liquid level in the adapter 32d is lowered to decrease the remaining amount of the liquid, the user is allowed to refill the adapter 32d with the liquid through the fill port 60d.
According to the third concrete example, the connector 40 is provided on the liquid container case 31d-side. There is accordingly no need to provide the connector 40 in the adapter 32d that is consumable and that is configured to contain the liquid inside thereof. The cartridge 30d can thus be manufactured at a low cost.
Each of electrical connecting elements 242T is a metal plate-like member that is elastically deformable. Part of the electrical connecting element 242T is exposed on a surface 241Tfa of a placement base 241T. The direction of a normal vector of the surface 241Tfa includes a −Z-axis direction component and a −Y-axis direction component. Nine electrical connecting elements 242T are provided. The electrical connecting elements 242T are electrically connected with the controller 16 (shown in
Two engagement structures 26 are provided. In the mounting state of the liquid container 30T, each of the engagement structures 26 includes an engagement claw 262 on its −Y-axis direction side end. The engagement structures 26 engage with part of the liquid container 30, so as to restrict the motion of the liquid container 30T relative to the mounting structure 20T in at least the Y-axis direction.
Pressing release elements 292 (only one release element is shown in
The liquid container 30T (shown in
The connector 40T (shown in
The case 31T (shown in
In the mounting state of the liquid container 30T, the case first surface 311 forms an upper face, the case second surface 312 forms a bottom face. The case third surface 313 forms one side face, and the case fourth surface 314 forms the other side face. The case fifth surface 315 forms a front face that is opposed to the mounting structure 20T, and the case sixth surface 316 form a rear face. The case first surface 311 and the case second surface 312 are opposed to each other in the Z-axis direction. The case third surface 313 and the case fourth surface 314 are opposed to each other in the X-axis direction. The case fifth surface 315 and the case sixth surface 316 are opposed to each other in the Y-axis direction. The connector 40T is inserted through the case fifth surface 315. This configuration causes part of the connector 40T to be exposed outside. In non-use of the liquid container 30T, for example, during transportation of the liquid container 30T, the entire connector 40T may be placed inside of the case 31T. For example, the connector 40T may be placed inside of the case 31T by opening an openable lid 319a provided by a cut line 319 formed in the case fifth surface 315. According to another embodiment, the liquid container 30T may not be provided with the case 31T.
The liquid supply portion 42T is detachably connected with a liquid introducing structure 22 (more specifically, the liquid injection needle 223) of the mounting structure 20T to supply the liquid to the liquid introducing structure 22 (more specifically, the liquid injection needle 223). The liquid supply portion 42T is inserted in a mounting structure-side cylindrical member 221 of the liquid introducing structure 22 in the mounting process and in the mounting state of the liquid container 30T.
The liquid supply portion 42T is a cylindrical member that is extended from the surface 415T. An opening 480TB is formed on a leading end of the liquid supply portion 42T to receive the liquid injection needle 223 therein. The opening 480TB is provided at a downstream end of the supply flow path 480T in the flow direction of the liquid that flows from the connector 40T toward the mounting structure 20T (supply flow path direction). The opening 480TB is thus also called the downstream end 480TB. In the non-use state prior to mounting the liquid container 30T to the mounting structure 20T, a film FM1 is attached to the opening 480TB to close the opening 480TB. The film FM1 is broken by the liquid injection needle 223 (shown in
The liquid supply portion 42T further includes a valve mechanism (not shown) that is placed in the flow path and that is configured to open and close the supply flow path 480T. The valve mechanism is opened when the liquid injection needle 223 is inserted into the liquid supply portion 42T.
The circuit board 443T includes main body-side terminals 442T provided on a placement surface 443Tfa and a storage device (not shown) provided on a rear face. The storage device of the circuit board 443T stores information regarding the liquid container 30T (for example, color information regarding the color of the liquid and information regarding the remaining amount of the liquid) and the like.
The direction of a normal vector of the placement surface 443Tfa includes a +Z-axis direction component and a +Y-axis direction component. Nine main body-side terminals 442T are placed on this placement surface 443Tfa. The nine main body-side terminals 442T respectively come into contact with the corresponding electrical connecting elements 242T (shown in
The engaged elements 462t are engaged with the engagement claws 262 (shown in
The liquid injection portion 461T is a cylindrical member that is extended along the Y-axis direction. The liquid injection portion 461T forms part of an injection flow path 482T that joins the supply flow path 480T. The injection flow path 482T is a flow path arranged to cause the liquid to be flowed from outside toward the liquid supply source 32. The liquid is injected from the liquid injection portion 461T through the injection flow path 482T into the liquid supply source 32. After injection of the liquid into the liquid supply source 32, the liquid injection portion 461T is closed by a film FM2, in order to prevent leakage of the liquid to outside. A valve mechanism may be provided in the liquid injection portion 461T, in order to prevent leakage of the liquid to outside.
The supply member 49T forms an upstream end 480TA of the supply flow path 480T in the flow direction of the liquid that flows from the connector 40T toward the mounting structure 20T. The supply member 49T is made of a synthetic resin. According to this embodiment, the supply member 49T is made of a material that mainly consists of polyethylene (PE) as a primary component. According to this embodiment, the primary component means a component that has a weight percent of higher than 50% by weight in the material.
The connection main body member 43T forms the downstream end 480TB of the supply flow path 480T (shown in
The connection main body member 43T includes an intermediate member 48T and a connection member 41T. The connection main body member 43T is formed by fitting the intermediate member 48T and the connection member 41T each other. Accordingly the connection member 41T is connected with the intermediate member 48T. The intermediate member 48T is located between the connection member 41T and the supply member 49T. The intermediate member 48T and the connection member 41T are respectively made of a synthetic resin. According to this embodiment, the intermediate member 48T and the connection member 41T are respectively made of a material that mainly consists of polypropylene (PP) as a primary component. In general, polypropylene has a higher hardness than polyethylene. Using polypropylene reduces the possibility of plastic deformation of the intermediate member 48T and the connection member 41T caused by a stress generated in a location where the intermediate member 48T and the connection member 41T are fit each other. Polypropylene is also generally a material of high versatility and is inexpensive. Using polypropylene accordingly reduces the manufacturing cost of the connector 40T.
The connector 40T is formed by fitting the connection member 41T and the intermediate member 48T (more specifically, one side of the intermediate member 48T) each other and fitting the intermediate member 48T (more specifically, the other side of the intermediate member 48T) and the supply member 49T each other.
The first elastic seal member 405T is provided to seal a gap between the intermediate member 48T and the supply member 49T fit each other. The first elastic seal member 405T has a ring-like shape and is placed to surround the circumference of the supply flow path 480T. The first elastic seal member 405T serves to suppress the liquid flowing in the supply flow path 480T from leaking out from the gap between the intermediate member 48T and the supply member 49T to outside. The first elastic seal member 405T is made of a material that has elasticity and that mainly consists of, for example, polybutadiene as a primary component.
The second elastic seal member 403T is provided to seal a gap between the connection member 41T and the intermediate member 48T fit each other. The second elastic seal member 403T has a frame-like shape and is placed to surround the circumference of the supply flow path 480T. The second elastic seal member 403T serves to suppress the liquid flowing in the supply flow path 480T from leaking out from the gap between the connection member 41T and the intermediate member 48T to outside. The second elastic seal member 403T is made of a material that has elasticity and that mainly consists of, for example, polybutadiene as a primary component.
The filter FT is placed in the middle of the supply flow path 480T. The filter FT is a plate-like member that is made of a metal such as stainless steel. The filter FT is attached to part of the connection member 41T. A method employable for attachment may, for example, thermally fuse part of the connection member 41T and press the fused part into part of openings of the filter FT to be cured. The filter FT has a rectangular external shape. The filter FT has a net-like structure with openings of such a size that allows the liquid flowing in the supply flow path 480T to pass through but prohibits external substances such as dust in the liquid from passing through. The filter FT serves to suppress extraneous substances in the liquid flowing in the supply flow path 480T from passing through. Even when some extraneous substance is mixed into the liquid that flows from the upstream side of the filter FT toward the downstream side of the filter FT in the flow direction, this configuration reduces the possibility that the extraneous substance reaches the mounting structure 20T. This accordingly reduces the possibility that the ejection head of the liquid consuming portion 14 (shown in
The supply member 49T (shown in
The supply member 49T includes a first supply opening portion 49TA that is one end portion and a second supply opening portion 49TB that is the other end portion. The first supply opening portion 49TA has a ring-like shape. The first supply opening portion 49TA is connected with the liquid supply source 32 by thermal welding, laser welding or the like. The first supply opening portion 49TA includes the upstream end 480TA of the supply flow path 480T (shown in
The second supply opening portion 49TB (shown in
The intermediate member 48T (shown in
The insertion structure 452T (shown in
The sealing main body structure 459T is provided to surround the outer circumference of the insertion structure 452T. The sealing main body structure 459T is an annular member. The sealing main body structure 459T (shown in
As shown in
The first insertion portion 452TA (shown in
The one end portion 46T of the intermediate member 48T (shown in
The intermediate member 48T (shown in
The connection member 41T (shown in
In the mounting state, the first surface 411T forms a +Z-axis direction side end face (upper face). In the mounting state, the second surface 412T forms a −Z-axis direction side end face (bottom face). In the mounting state, the third surface 413T forms a −X-axis direction side end face (one side face). In the mounting state, the fourth surface 414T forms a +X-axis direction side end face (the other end face). In the mounting state, the fifth surface 415T forms a +Y-axis direction side end face (front face). The first surface 411T and the second surface 412T are portions that are opposed in the Z-axis direction to the inner circumferential surface forming the housing space 21A of the mounting structure 20T. The third surface 413T and the fourth surface 414T are portions that are opposed in the X-axis direction to the inner circumferential surface forming the housing space 21A of the mounting structure 20T.
The connection member 41T includes the liquid supply portion 42T that is protruded from the fifth surface 415T. In other words, the connection member 41T forms the downstream end (opening) 480TB in the flow direction. The connection ember 41T also has the injection flow path 482T including the liquid injection portion 461T.
The connection member 41T of the connection main body member 43T includes a recess 44T and a groove 418T provided to surround the outer circumference of the recess 44T. The recess 44T and the groove 418T are formed in the sixth surface 416T.
The recess 44T (shown in
The recess 44T (shown in
The connection member 41T of the connection main body member 43T (shown in
The groove 418T (shown in
The second elastic seal member 403T (shown in
The second projections 449T (shown in
The injection flow path 482T (shown in
According to the third embodiment described above, the connector 40T configured to form the supply flow path 480T which the liquid from the liquid supply source 32 flows in includes the sealing main body structure 459T and the first elastic seal member 405T (as shown in
According to the third embodiment described above, the first elastic seal member 405T is placed to apply the external force FTb inward in the radial direction to the insertion structure 452T (as shown in
According to the third embodiment described above, the connector 40T includes the groove 418T that is provided to surround the outer circumference of the recess 44T with the supply path opening 431T and the injection path opening 421T formed therein (as shown in
According to the third embodiment described above, a plurality of (seven in the embodiment) second projections 449T are provided at some intervals (as shown in
According to the third embodiment described above, the supply flow path 480T of the connector 40T is formed by the three members, i.e., the supply member 49T, the intermediate member 48T and the connection member 41T (as shown in
The intermediate member 48Ta is made of, for example, a thermoplastic resin such as polypropylene (PP). The intermediate member 48Ta (shown in
The one end portion 46Ta of the intermediate member 48Ta (shown in
The one end portion 46Ta of the intermediate member 48Ta (shown in
A plurality of projections 499T are formed on the bottom wall 491T and on the inner circumferential surface of the through hole 491TH of the intermediate member 48Ta. The plurality of projections 499T are respectively extended linearly. Providing the projections 499T increases the average wall thickness of the intermediate member 48Ta and thereby enhances the water barrier properties and the gas barrier properties. This configuration accordingly suppresses water and gas from being transmitted through the intermediate member 48Ta and leaking to outside.
The connection member 41Ta (shown in
A plurality of projections 423T are formed on the fifth surface 415T of the connection member 41Ta, on the outer circumferential surface of the liquid supply portion 42T and on the outer circumferential surface of the liquid injection portion 461T (as shown in
The first welding portion 489T of the intermediate member 48Ta and the second welding portion 451T of the connection member 41Ta are welded to each other to surround the periphery of the supply flow path 480T and the injection flow path 482T. This configuration reduces the possibility that the liquid flowing in the supply flow path 480T or in the injection flow path 482T is leaked from the boundary between the intermediate member 48Ta and the connection member 41Ta to outside. The configuration of the connector 40Ta of the fourth embodiment has the improved sealing properties and thereby further reduces the possibility of leakage of the liquid to outside, compared with a configuration that the gap between the intermediate member 48Ta and the connection member 41Ta is sealed by using a separate elastic seal member.
Any of various welding techniques may be employed as the method of welding the first welding portion 489T and the second welding portion 451T to each other. For example, any of laser welding, vibration welding, ultrasonic welding and thermal welding techniques may be employed. Employing the laser welding technique more effectively reduces vibration during welding compared with the other welding techniques and thereby reduces the possibility that the intermediate member 48Ta and the connection member 41Ta are damaged by vibration. Employing the vibration welding technique or the ultrasonic welding technique has the smaller power consumption compared with the laser welding technique and the thermal welding technique and thereby reduces the manufacturing cost of the connector 40Ta. Employing the thermal welding technique implements welding by using an apparatus of the simpler configuration, compared with the laser welding technique, the vibration welding technique and the ultrasonic welding technique.
The liquid supply system 37T includes the connector 40T, the tube 71T and the liquid supply source 32TA. The tube 71T is connected with the connector 40T and with the liquid supply source 32TA, so as to cause the supply flow path 480T and the injection flow path 482T of the connector 40T to communicate with the liquid supply source 32TA. It is preferable that the liquid supply source 32TA has a larger capacity of containing the liquid therein than the capacity of the liquid supply source 32 of the third embodiment described above. This reduces the frequency of replacement of the liquid supply source 32TA. The liquid supply source 32TA may be placed on the main placement rack 19 (shown in
The configuration of the fifth embodiment that is similar to the configuration of the third embodiment described above has the similar advantageous effects. For example, the connector 40T configured to form the supply flow path 480T which the liquid from the liquid supply source 32TA flows in includes the sealing main body structure 459T and the first elastic seal member 405T (as shown in
A connector unit 375T includes the connector 40T and the case 31Ta. The connector 40T is attached to the case 31Ta.
The liquid supply source 32Ta is configured to contain the liquid that is to be supplied to the liquid consuming apparatus 10. The liquid supply source 32Ta is placed in the case 31Ta in a demountable manner. For example, the liquid supply source 32Ta may be placed in the case 31Ta through an upper face opening 311Ta of the case 31Ta.
The liquid supply source 32Ta includes a connection opening 68T and a fill port 60Td. The connection opening 68T is arranged to communicate with inside of the liquid supply source 32Ta and causes the liquid contained in the liquid supply source 32Ta to be flowed to outside. A liquid retaining member is placed in the connection opening 68T to suppress leakage of the liquid to outside. The liquid retaining member may be, for example, a sponge that is a porous member. The liquid retaining member may be replaced with a valve mechanism. The connection opening 68T is connectable with a supply member 49T of the connector 40T. The user connects the connection opening 68T with the supply member 49T when the liquid supply source 32Ta is placed into the case 31Ta. This enables the liquid contained in the liquid supply source 32Ta to be flowed through the connection opening 68T to the connector 40T-side.
The fill port 60Td is provided on an upper face of the liquid supply source 32Ta. The fill port 60Td is formed to pass through the wall of the liquid supply source 32Ta and communicate with the liquid supply source 32Ta. When a liquid level in the liquid supply source 32Ta is lowered to decrease the remaining amount of the liquid, the user is allowed to refill the liquid supply source 32Ta with the liquid through the fill port 60Td.
The configuration of the sixth embodiment that is similar to the configuration of the third embodiment described above has the similar advantageous effects. For example, the connector 40T configured to form the supply flow path 480T which the liquid from the liquid supply source 32Ta flows in includes the sealing main body structure 459T and the first elastic seal member 405T (as shown in
The disclosure is not limited to any of the embodiments and the examples described above but may be implemented by a diversity of other aspects without departing from the scope of the disclosure. Some of possible modifications are given below.
According to the first and the second embodiments described above, the cartridge 30 or 30a includes the liquid container body 32 (as shown in
According to the first and the second embodiments described above, the supply portion protrusion 421 is formed in a ring shape around the whole circumference of the outer surface of the flow portion 423. The supply portion protrusion 421 is, however, not limited to this configuration but may have any configuration that works in cooperation with the mounting structure-side cylindrical member 221 to restrict the motion of the flow portion 423 on the X-Z plane. For example, the supply portion protrusion 421 may be formed by a plurality of projections arranged at predetermined intervals along the circumferential direction of the surface of the flow portion.
According to the first and the second embodiments described above, the contact portions CP are placed on the placement surface 443fa or 443faa that is the surface of the circuit board 443 or 443a (as shown in
In the connector 40T or 40Ta of any of the third to the sixth embodiments described above, at least one of the circuit board 443T, the injection flow path 482T including the liquid injection portion 461T, the second elastic seal member 403T, the third elastic seal member 404T, the first rib 453T, the second rib 454T, the filter FT, the first projections 447T and the second projections 449T may be omitted.
The disclosure is not limited to the textile printing machine or the cartridge (liquid container) configured to supply ink (liquid) to the textile printing machine but is also applicable to any liquid consuming apparatus and a cartridge detachably mounted to a mounting structure of the liquid consuming apparatus. For example, the disclosure may be applied to any of various liquid consuming apparatuses described below and their cartridges and connectors:
(1) image recording apparatus such as facsimile machine;
(2) color material consuming (ejecting) apparatus used for manufacturing color filters for image display apparatuses such as liquid crystal displays;
(3) electrode material consuming apparatus used for forming electrodes of, for example, organic EL (electroluminescence) displays and field emission displays (FED);
(4) liquid consuming apparatus configured to eject a bioorganic material-containing liquid used for manufacturing biochips;
(5) sample consuming apparatus used as precision pipette;
(6) consuming (ejecting) apparatus of lubricating oil;
(7) consuming (ejecting) apparatus of resin solutions;
(8) liquid consuming apparatus for pinpoint ejection of lubricating oil on precision machines such as watches and cameras;
(9) liquid consuming apparatus configured to eject transparent resin solutions, such as ultraviolet curable resin solution, onto substrates to manufacture hemispherical microlenses (optical lenses) used for, for example, optical communication elements;
(10) liquid consuming apparatus configured to eject acidic or alkaline etching solutions to etch substrates and the like; and
(11) liquid consuming apparatus equipped with a liquid ejection head configured to eject a very small volume of droplets of any other liquid.
The “droplet” herein means the state of liquid ejected from the liquid consuming apparatus and may be in a granular shape, a teardrop shape or a tapered threadlike shape. The “liquid” herein may be any material ejectable from the liquid consuming apparatus. The “liquid” may be any material in the liquid phase. For example, liquid-state materials of high viscosity or low viscosity, sols, aqueous gels and other liquid-state materials including inorganic solvents, organic solvents, solutions, liquid resins and liquid metals (metal melts) are included in the “liquid”. The “liquid” is not limited to the liquid state as one of the three states of matter but includes solutions, dispersions and mixtures of the functional solid material particles, such as pigment particles or metal particles, solved in, dispersed in or mixed with solvents. Typical examples of the liquid include ink described in the above embodiments and liquid crystal. The ink herein includes general water-based inks and oil-based inks, as well as various liquid compositions, such as gel inks and hot-melt inks.
The present disclosure is not limited to any of the embodiments, the examples and the modifications described above but may be implemented by a diversity of configurations without departing from the scope of the disclosure. For example, the technical features of any of the embodiments, the examples and the modifications corresponding to the technical features of each of the aspects described in Summary may be replaced or combined appropriately, in order to solve part or all of the problems described above or in order to achieve part or all of the advantageous effects described above. Any of the technical features may be omitted appropriately unless the technical feature is described as essential herein.
The present application claims priority from Japanese patent applications 2016-193100 and 2016-193083 filed on Sep. 30, 2016, the entireties of the disclosures of which are hereby incorporated by reference into this application.
Number | Date | Country | Kind |
---|---|---|---|
2016-193083 | Sep 2016 | JP | national |
2016-193100 | Sep 2016 | JP | national |