The present invention relates to a printing apparatus.
There has been known a printing apparatus configured to use a tube to connect a print head for ejecting an ink to an ink tank containing the ink to be supplied to the print head. Japanese Patent Laid-Open No. 2015-27741 (Reference 1) discloses an on-off valve which can close a tube between a print head and an ink tank by using a pressing member that is linearly driven to press the tube.
According to the printing apparatus disclosed in Reference 1, the tube pressing member may fail to apply a pressure in parallel to each tube in a case of pressing a tube having a large diameter or in a case of integrally pressing two or more tubes. As a consequence, the tube pressing member or a tube supporting member for supporting the tube may be inclined relative to a width direction of the tube, thus causing a leakage due to a failure to fully press the tube.
A printing apparatus according to an aspect of the present invention includes: a tube configured to form a flow channel to supply a liquid to a liquid ejecting unit configured to eject the liquid; a holding unit configured to hold the tube; and a valve unit configured to move to a closed position to press and close the tube held by the holding unit with a pressing portion from an open position to open the tube held by the holding unit, and to move to the open position from the closed position. Here, the valve unit includes a pivot shaft and moves pivotally around the pivot shaft to move to the closed position and the open position, and a direction of extension of the pivot shaft is a direction intersecting with a direction of extension of the tube held by the holding unit.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Embodiments of the present invention will be described below with reference to the drawings. It is to be noted that the following embodiments do not intend to limit the scope of the present invention and that all the combinations of the features described in the embodiments are not always essential. The same constituents in the embodiments will be denoted by the same reference signs in the following description.
In the present specification, the term “printing” (which may also be referred to as “print”) is not limited to a case of forming significant information such as characters and graphics, but encompasses formation of all significant and insignificant information. This term is also assumed to broadly include formation of images, figures, patterns, and the like on a print medium as well as processing of a print medium regardless of whether or not these objects are materialized so as to be discernible to human eyes.
Meanwhile, the term “ink” (which may also be referred to as “liquid”) should also be interpreted in a broad sense as with the definition of the “printing” mentioned above. Accordingly, this term is assumed to represent a liquid which serves to form images, figures, patterns, and the like, to process a print medium, and to modify an ink (such as coagulation and insolubilization of a colorant contained in the ink to be applied to the print medium) in the case where the liquid is applied onto the print medium.
In addition, the term “print medium” not only includes paper used in general printing apparatuses but also broadly includes media that can accept the ink as typified by cloth, plastic films, metal plates, glass, ceramics, wood, leather, and the like.
Although the present embodiment describes an example of the printing apparatus, the same applies to a case of a liquid ejecting apparatus. For example, such a liquid ejecting apparatus may include a liquid container that contains a liquid, a liquid ejecting unit that ejects the liquid supplied from the liquid container through a liquid supply channel, and a liquid ejecting unit holder that holds the liquid ejecting unit. The description will be given in the present embodiment by using the printing apparatus 100 as the example of the liquid ejecting apparatus.
Each ink tank 11 may be a first ink tank 111 or a second ink tank 112. The present embodiment shows the case of providing the multiple first ink tanks 111 on the assumption of a case of using multiple types of inks. However, in the case of using a single type of the ink, a single ink tank (such as the first ink tank 111) may only be provided. Meanwhile, the second ink tank 112 having a larger capacity than that of the first ink tank 111 may be provided in the case of using a large amount of the ink. Without limitations to the foregoing, only the second ink tanks 112 may be provided or the first ink tanks 111 and the second ink tank 112 may be provided as in the present embodiment. In the case of providing two or more ink tanks 11, the ink tanks 11 may be provided on the right and the left relative to the center of the apparatus depending on the size of the printing apparatus 100, or provided only on one side. In the present embodiment, three color ink tanks 111 that can contain cyan ink, magenta ink, and yellow ink, respectively, are provided as the first ink tanks 111. Meanwhile, one black ink tank 112 that can contain black ink is provided as the second ink tank 112. Configurations of other components shown in
The printing apparatus 100 includes feeding rollers (not shown) that feed the print media, transportation rollers (not shown) that transport the print media, and discharge rollers (not shown) that discharge the print media. The print head 62 is detachably mounted on the carriage 61 and configured to eject the inks onto a surface of a print medium transported by the transportation rollers, thus printing an image thereon. Moreover, the printing apparatus 100 includes an ink suction mechanism 64 (see
The present embodiment describes an example in which the print head 62 ejects the inks in accordance with a movement associated with scanning by the carriage. However, the present invention is not limited only to this configuration. The print head may be of a so-called line type, which is provided with ink ejection ports in a region corresponding to a width of the print medium and configured to print images on the print medium without scanning by the carriage.
The valve units 53 include a black side valve unit and color side valve units. The black side valve unit closes the ink supply channel 51 and the atmospheric communicating channel 54 connected to the black ink tank 112, respectively. The color side valve units close the ink supply channels 51 and the atmospheric communicating channels 54 connected to the color ink tanks 111, respectively. In the meantime, an on-off valve mechanism 160 to shut off the communication of the liquid or the air is provided at a portion of each ink supply channel 51 between the valve unit 53 and the print head 62. The on-off valve mechanisms 160 include a black side on-off valve mechanism and color side on-off valve mechanisms. The black side on-off valve mechanism closes the ink supply channel 51 connected to the black ink tank 112. The color side on-off valve mechanisms close the ink supply channels 51 connected to the color ink tanks 111, respectively. Each on-off valve mechanism 160 includes various components. Here, the black side on-off valve mechanism and the color side on-off valve mechanisms may use the same components in common or use different components from each other. Details of the on-off valve mechanisms will be described later. Differences in role between the on-off valve mechanism 160 and the valve unit 53 will also be described later.
In the printing apparatus 100 of the present embodiment, a liquid-gas replacement portion 15 of the ink tank 11 is located at a position lower by an amount H in a height direction than the ink ejection ports 63 of the print head 62 in order to prevent a leakage of the ink from the ink ejection ports 63 of the print head 62. In other words, a negative pressure originating from a water head difference corresponding to the height H is applied to the ink ejection ports 63. Meanwhile, the buffer chamber 16 is provided at a lower part of the ink tank 11. The buffer chamber 16 can store the ink to be pushed out in the case of destruction of a meniscus in the liquid-gas replacement portion 15 due to expansion of the air inside the ink tank 11 caused by an atmospheric pressure variation or a change in temperature. Thus, it is possible to suppress the leakage of the ink from the ink tank 11 through the atmospheric communicating channel 54. In
Next, a configuration of an ink supply system and a flow from a point of injection of the ink to a point to enable image printing in the present embodiment will be described with reference to
As shown in
In the case where the user injects the ink into the ink tank 11, the user first turns the third cover member 41 upward and sets the third cover member 41 to the open state as shown in
The second cover member 21 is pivotally supported in such a way as to be movable between a position to fall forward (a closed lid position) and a position to be lifted up (an open lid position). The ink tanks 11 are provided with the second cover members 21, respectively. To be more precise, the black ink tank 112 is covered with a black second cover member 212 and the three color ink tanks 111 are integrally covered with a single color second cover member 211. The black second cover member 212 and the color second cover member 211 will be collectively referred to as the second cover member 21. Although the black second cover member 212 and the color second cover member 211 are formed into different shapes in present embodiment, these cover members may be formed into the same shape instead.
A first cover member 12 to close the ink tank 11 appears in the case where the user operates the second cover member 21 from the closed lid position to the open lid position (see
The first cover member 12 is provided with a seal member 13 formed from an elastic body such as rubber. By operating the first cover member 12 to the closed tap position, the seal member 13 closes the injection port 14 so as to prevent the leakage of the ink contained in the ink tank 11. In the present embodiment, the valve unit 53 acts in conjunction with the operation to lift the first cover member 12, thus closing the ink supply channel 51 and the atmospheric communicating channel 54, respectively (
The user can inject the ink into the ink tank 11 by putting a container (not shown) containing the ink into the injection port 14. After the injection of the ink is completed, the user operates the first cover member 12 to the closed tap position again. The valve unit 53 acts in conjunction with this operation, thus opening the ink supply channel 51 and the atmospheric communicating channel 54, respectively (see
As described above, the ink supply channel 51 is provided with the two types of the valves in the present embodiment, namely, the valve unit 53 and the on-off valve mechanism 160, which have the functions independent of and different from each other. Specifically, the valve unit 53 closes the ink supply channel 51 in the case of filling the ink tank 11 with the ink and opens the ink supply channel 51 in other cases. On the other hand, the on-off valve mechanism 160 closes the ink supply channel 51 in order to suppress the ink leakage or in the case of conducting efficient suctioning at the time of filling the ink. Details of the on-off valve mechanism 160 will be described later.
In the state filled with the ink as described above, as the ink is ejected from the ink ejection ports 63 in the case of printing an image on the print medium, for example, the ink is supplied from the ink tank 11 to the print head 62 in an amount equivalent to an amount of the ink discharged from the print head 62. The ink is continuously supplied from the ink tank 11 to the print head 62 until the ink in the ink tank 11 falls below a predetermined amount.
The above-described example has explained the case where the user conducts the opening and closing operations by operating the first cover member 12, the second cover member 21, and the third cover member 41. Instead, the opening and closing operations may be carried out automatically by means of control inside the printing apparatus 100.
The MPU 601 controls operations of the respective units, data processing, and the like. The ROM 602 stores programs and data to be executed by the MPU 601. The RAM 603 temporarily stores processing data to be executed by the MPU 601 and data received from a host computer 600. The print head 62 is controlled by the print head driver 607. The carriage 61 is driven by the carriage motor 604. The carriage motor 604 is controlled by the carriage motor driver 608. The feeding rollers, the transportation rollers, and the discharge rollers are driven by the transportation motor 605. The transportation motor 605 is controlled by the transportation motor driver 609. The host computer 600 includes a printer driver 610 for processing print information such as a printed image and image quality and for communicating with the printing apparatus 100 in the case where the user issues a command to execute a printing operation. The MPU 601 exchanges printed images and the like with the host computer 600 through the I/F unit 613.
Next, a description will be given of a configuration and operations of the on-off valve mechanism 160 according to the present embodiment.
As described above, the on-off valve mechanism 160 is the valve for closing and opening (establishing communication of) the ink supply channel 51 formed from the supply tube 17. As shown in
The on-off valve mechanism 160 according to the present embodiment enables opening and closing operations manually and automatically by coupling a driving unit thereto. Here, the driving unit can be electrically driven by an external power supply. In other words, the operating unit 161 can switch between the open state and closed state by driving the external driving unit in addition to the manual operation of the user. As shown in
As shown in
As shown in
As shown in
The receiving member 163 is a member for receiving the displacement member 164 that is displaceable in the direction to interfere with the supply tubes 17, and includes contact portions 163a, 163b, 163c, and 163d, and second pivot shafts 163e and 163h. The second pivot shafts 163e and 163h are fitted into a bearing portion provided to the holding member 169, and the receiving member 163 is pivotally movable about the second pivot shafts 163e and 163h. The receiving member 163 is provided on an opposite side to a portion provided with the displacement member 164 in such a way as to correspond to each supply tube 17. The receiving member 163 is biased by the biasing member 170 in a direction to come close to the displacement member 164. The receiving member 163 is biased by the biasing member 170 toward a rotation stopper 169a of the holding member 169, thereby controlling an amount of pivotal movement toward a portion holding the supply tube 17. The receiving members 163 are provided for the respective tubes, and each receiving member 163 is biased by the biasing member 170 toward the rotation stopper 169a of the holding member 169. Meanwhile, each receiving member 163 includes a pivot shaft. In the present embodiment, the pivot shafts of the receiving members 163 corresponding to the contact portions 163a, 163b, and 163c are the second pivot shafts 163e. Although
The present embodiment provides the pressing portion 164a of the displacement member 164 which acts on the first tubes, and the contact portions 163a, 163b, and 163c of the receiving members 163 corresponding thereto (see
The description will be continued with reference to
As shown in
As shown in
Next, a description will be given of an operation by the on-off valve mechanism 160 according to the present embodiment to close each supply tube 17 with reference to
As mentioned earlier,
Here, the first pivot shaft 164c is preferably provided at substantially the same height as the contact portion 163a in terms of the height in z direction at the time of the closed state shown in
Next, an operation to close the supply tube 17 will be described with reference to
Meanwhile, the tube thickness of the supply tubes 17a, 17b, and 17c is also different from that of the supply tube 17d at the time of closing the tubes in the present embodiment. Accordingly, if a distance between the pressing portion 164b and the contact portion 163d is set to such a distance that can close the supply tube 17d having the larger thickness, the supply tubes 17a, 17b, and 17c having the smaller thickness are closed incompletely. On the other hand, if the distance between the pressing portion 164a and the contact portions 163a, 163b, and 163c is set to such a distance that can close the supply tubes 17a, 17b, and 17c, the reactive force of the supply tube 17d is significantly increased in the case where the supply tube 17d is closed. Given the situation, the receiving members 163 and the biasing members 170 to bias the receiving members 163 are configured to individually come into contact with and support the supply tubes 17a, 17b, 17c, and 17d, respectively. In this way, it is possible to provide the biasing forces required for the closure appropriately depending on the respective thicknesses of the tubes. Thus, a driving load of the cam 165 can be reduced in the case of closing the tubes without unnecessarily increasing the biasing forces.
As described above, it is possible to reduce the inclinations of the displacement member 164 and the receiving members 163 in the width direction of the tubes irrespective of the tube thicknesses or the dimensions of the components even in the case of integrally pressing the tubes, thereby suppressing the occurrence of an incompletely closed state of any of the tubes.
The description has been given of the example of the printing apparatus 100 of the resent embodiment which includes a plurality of the supply tubes 17. However, the present invention is also applicable to a printing apparatus that uses a single supply tube 17. Even in a case of using a tube having a large diameter, the configuration described in the present embodiment can suppress the occurrence of a leakage.
Next, a description will be given of configurations the cover member 162 and the holding member 169. In general, it is ideal for the on-off valve mechanism to be configured to press the tubes in the direction orthogonal to the direction of extension of the tubes. However, even in such a pressing structure, a force may be generated in the direction of extension of the tubes due to tolerances of the components and other factors, whereby the tube may move in the direction of extension thereof. The occurrence of the movement of the tubes may consume extra lengths of the tubes and the taut tubes may be disconnected from joint portions. On the other hand, the occurrence of the movement of the tube may increase the extra lengths of the tubes and the redundant tubes that are not properly housed in a designed space may cause buckling.
Meanwhile, in the on-off valve mechanism 160 described in the present embodiment, the displacement member 164 and the receiving member 163 are configured to be pivotally movable. A displacement of the pressing portion 164a or the contact portion 163b due to tolerances of the components may generate a force to be applied in the direction of extension of the tubes. Given the situation, the cover member 162 and the holding member 169 of the present embodiment are provided with a tube arrangement structure for suppressing the movement of the supply tubes 17 even in the case of generation of the force to be applied in the direction of extension of the supply tubes 17.
A description will be given below with reference to
The tube supporting portion 169d of the holding member 169 has such a shape that its tip end projects above the contact portion 163a in the case where the supply tube 17a is closed by the on-off valve mechanism 160. The tube supporting portion 169d supports the supply tube 17a in the vicinity of the pressing position P. A contact surface of the tube supporting portion 169d with the tube is provided within the width in y direction of the tube supporting portion 169d. In other words, the tube supporting portion 169d includes a substantially U-shaped groove portion and the supply tube 17a is arranged in the groove portion. As shown in
The first tube regulating portion 169b has such a shape that its tip end projects from the side supporting the supply tube 17a with the receiving member 163 to a position below the tube supporting portion 169d.
The second tube regulating portion 162a is provided at a position more distant from the pressing position P than the first tube regulating portion 169b is in terms of the direction of extension of the tube from the pressing position P. The second tube regulating portion 162a has such a shape that projects in an opposite direction (−z direction) to the direction of projection (+z direction) of the first tube regulating portion 169b. The second tube regulating portion 162a has such a shape that its tip end projects to a position below the tip end of the first tube regulating portion 169b. In other words, the first tube regulating portion 169b and the second tube regulating portion 162a have such shapes that their tip end portions project to a position where the tip end portions overlap each other in the direction of a projection axis (the vertical direction). The first tube regulating portion 169b and the second tube regulating portion 162a form a first clearance W1 that serves as the route for the supply tube 17a. The first tube regulating portion 169b and the second tube regulating portion 162a project from mutually opposite directions in a substantially orthogonal direction (z direction) to the direction of extension (x direction) at the pressing position P of the supply tube 17a, thus forming the arrangement route for bending the supply tube 17a into an S-shape. Meanwhile, the tip end of the second tube regulating portion 162a and the opposed portion 169c of the holding member 169 opposed to this tip end portion form a second clearance W2 that serves as the route for the supply tube 17a. The supply tube 17a passing through the second clearance W2 is arranged in an opposite direction (upward) from the near side to the opposed portion 169c, and is arranged not to fall off the cover member 162 by using the third tube regulating portion 162d. By regulating the supply tube 17a in x direction by using the third tube regulating portion 162d, the supply tube 17a is kept from spreading outside of the cover member 162 by the reactive force of the tube in the case the extra length of the tube is increased due to the tolerance and the like.
The supply tube 17a is arranged in the S-shape by using the first tube regulating portion 169b and the second tube regulating portion 162a. The tube reactive force of this supply tube 17a arranged in the S-shape is generated in a direction to bring the supply tube 17a into contact in such a way as to surround the tip end portion of the first tube regulating portion 169b or the second tube regulating portion 162a. Since this tube reactive force is constantly generated, the contact force with the first tube regulating portion 169b or the second tube regulating portion 162a is stably generated. Accordingly, even if the force is generated in the supply tube 17a in the direction of extension of the tube (x direction) from the pressing position P, a static frictional force against this force is generated so that the movement in the direction of extension of the tube can be suppressed.
To be more precise, if a force acts in a direction to drag the supply tube 17a to the pressing position P (−x direction), the contact force between a side surface portion of the first tube regulating portion 169b and the supply tube 17a is increased. Accordingly, the frictional force against the dragging force is increased so that the dragging movement of the supply tube 17a can be suppressed.
On the other hand, if a force acts in a direction to push the supply tube 17a from the pressing position P (+x direction), the contact force between a side surface portion of the second tube regulating portion 162a and the supply tube 17a is increased. Accordingly, the frictional force against the pushing force is increased so that the pushing movement of the supply tube 17a can be suppressed.
As described above, the direction of generation of the contact force with the tube regulating portion attributed to the tube reactive force is the substantially orthogonal direction to the direction of extension of the supply tube 17 from the pressing position P. Accordingly, even in case of the occurrence of the force to drag or push the supply tube 17a, the reduction in contact force of the supply tube 17a with the tube regulating member is small. Thus, it is possible to suppress the reduction in frictional force and to reduce the movement of the tube.
Meanwhile, the opposed portion 169c is provided in such a shape that blocks the direction of extension (which is z direction at this portion) of the supply tube 17a that is bent by the first tube regulating portion 169b and the second tube regulating portion 162a. In this way, even if the supply tube 17a is pushed toward the opposed portion 169c, the frictional force is increased along with the increase in contact force between the supply tube 17a and the opposed portion 169c, so that the movement of the tube can be reduced.
Moreover, the supply tube 17a is pressed against the contact portion of the tube supporting portion 169d at the time of the operation to close the tube, so that the contact force can be increased and the frictional force is increased as well. Thus, the movement of the supply tube 17a can be suppressed.
As described above, it is possible to suppress the movement of the supply tube 17a in the case where the tube is dragged to the pressing position P or in the case where the tube is pushed from the pressing position P.
In the arrangement route for the supply tube 17a, regions of the first tube regulating portion 169b, the tube supporting portion 169d, and the second tube regulating portion 162a which come into contact with and thus bend the supply tube 17a are preferably provided with arc forms. Since the supply tube 17a is bent along the arc shapes and the route is regulated accordingly, the contact area is effectively increased and an effect to suppress the movement of the tube is thus enhanced.
Meanwhile, in the present embodiment, the first clearance W1 is formed into such a width that the supply tube 17a bent into the S-shape comes into contact with the tube regulating portions with the reactive force of the tube. Here, the first clearance W1 may be set smaller than the outside diameter of the supply tube 17a to the extent that does not crush an inside diameter thereof. By pinching the supply tube 17a with the portion of the first clearance W1, it is possible to suppress the movement of the tube while reliably providing the frictional force to be applied between the supply tube 17a and the tube regulating portions 162a and 169b.
In the present embodiment, the second clearance W2 is formed into such a width that the supply tube 17a comes into contact with the opposed portion 169c with the reactive force of the tube. Here, the second clearance W2 may be set smaller than the outside diameter of the supply tube 17a to the extent that does not crush the inside diameter thereof. By pinching the supply tube 17a with the portion of the second clearance W2, it is possible to suppress the movement of the tube while reliably providing the frictional force to be applied between the supply tube 17a and the tube regulating portions 162a and 169b.
The on-off valve mechanism 160 of the present embodiment is configured to open and close the supply tubes 17 by bringing the pivotally movable displacement member 164 into contact with the receiving members 163. However, the movement of the tubes in the direction of extension thereof can be suppressed without limitations to this configuration. Specifically, an on-off valve mechanism that closes tubes by linear movement can also suppress the movement of the tubes in the direction of extension thereof by adopting the above-described configuration that uses the cover member 162 and the holding member 169.
Meanwhile, the supply tube 17a passing through the second clearance W2 is arranged in an opposite direction to the near side of the opposed portion 169c via the auxiliary contact surface 162b, so as to reduce a curvature radius of the bent portion of the supply tube 17a. Thus, it is possible to further suppress the movement of the tube by increasing the contact force between the supply tube 17a and the tube regulating portions attributed to the tube reactive force. The auxiliary contact surface 162b is formed into a curved surface portion having an arc shape with such a curvature radius that keeps a portion of the supply tube 17a around the second tube regulating portion 162a from buckling. Moreover, the supply tube 17a is arranged on an upper part of the cover member 162 with its movement in x direction being regulated by the third tube regulating portion 162d.
As described above, according to the present embodiment, the displacement member 164 configured to press the tubes can press the tubes in parallel along the widths of the tubes in the case of pressing the tube having the large diameter or in the case of integrally pressing the plurality of the tubes. In other words, the displacement member 164 is configured to be pivotally movable about the first pivot shaft 164c, and the receiving member 163 to hold the supply tube 17a is also configured to be pivotally movable about the second pivot shafts 163e and 163h. Moreover, the direction of extension of the pivot shafts are configured to extend in an intersecting direction (the width direction of the tubes) that intersects with the direction of the extension of the tubes. For this reason, even if the tubes are integrally pressed, for example, it is possible to reduce the inclinations of the displacement member 164 and the receiving members 163 in the width direction of the tubes irrespective of the tube outside diameters and the tube thicknesses as well as the dimensions of the components. As a consequence, it is possible to suppress a leakage in the case of pressing the tubes.
Meanwhile, in the present embodiment, even in the case where the supply tube 17 receives the force in the direction of extension thereof at the position to press the tube due to the opening and closing operations by the on-off valve mechanism 160, the tube route is regulated such that the frictional force is stably generated against that force. Accordingly, it is possible to suppress the movement of the supply tube 17 even if the opening and closing operations are carried out by the on-off valve mechanism 160.
The above-described embodiment has explained the example in which the displacement member 164 presses the supply tubes 17. However, the present embodiment is applicable to any other modes as long as it is a mode in which a flow channel is closed by pressing a tube with a pressing portion. For instance, the present invention is also applicable to a mode of using a pressing portion to press a tube that is connected to a pump to be used at the time of a recovery operation. In other words, the valve mechanism described in the present embodiment is applicable to tubes for various flow channels.
Meanwhile, the above-described embodiment has explained the example of the printing apparatus that performs printing by using the inks. Instead, the present invention may be applied to a flow channel opening/closing apparatus to open and close a flow channel for circulating a liquid or a gas, which includes the above-described on-off valve mechanism. Of course, the present invention is applicable to a printing apparatus that includes such a flow channel opening/closing apparatus (a flow channel opening/closing mechanism).
In the meantime, the above-described embodiment has explained the example in which the receiving member 163 is biased by the biasing member 170 in the direction to come close to the displacement member 164. However, the present invention is not limited only to this example. The same effects as those of the above-described embodiment can also be obtained from a configuration in which one of the receiving member 163 and the displacement member 164 is biased in a direction to come close to each other. In other words, the displacement member 164 does not have to be biased in the direction to come close to the receiving member 163 by the not-illustrated biasing member, and the displacement member 164 may instead be biased in a direction to come close to the receiving member 163 by another not-illustrated biasing member in a direction toward the cam 165. In this case as well, the displacement member 164 can move to the position to press and close the tube and to the position to recede from and open the tube with the cam 165 as described above. In this example, the receiving member 163 may be biased by the biasing member 170 in the direction to come close to the displacement member 164 likewise. Alternatively, the receiving member 163 may be fixed to the holding member 169.
Meanwhile, the above-described embodiment has explained the example of providing the tube arrangement route by using the holding member 169 and the cover member 162. Instead of using the separate members, the similar tube arrangement route may be provided by a single member. In the meantime, the above-described embodiment has explained the example in which the plurality of tubes are provided and the tube regulating portions project from mutually opposite directions in terms of the height direction. However, the present invention is not limited only to this configuration. In a case where the number of tubes is small, for example, the tube regulating portions may have such shapes that project from mutually opposite directions in terms of the width direction intersecting with (for example, being orthogonal to) the direction of extension of the tubes.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2021-020361, filed Feb. 12, 2021, which is hereby incorporated by reference wherein in its entirety.
Number | Date | Country | Kind |
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2021-020361 | Feb 2021 | JP | national |