Field of the Invention
The present invention relates to a liquid ejection apparatus capable of containing liquid and including a detection unit configured to detect a remaining amount of the liquid, and to a liquid container.
Description of the Related Art
A liquid ejection apparatus includes a supply system that supplies liquid such as ink to a liquid ejection head. In the upstream of the supply system, a liquid container that holds the liquid is detachably attached. Some liquid ejection apparatus includes a detection unit configured to detect a remaining amount of liquid in the liquid container. In the case where the remaining amount of the liquid in the liquid container mounted in the liquid ejection apparatus is small, the fact is detected and the liquid container is exchanged to a new one, thereby allowing continuous use of the liquid ejection apparatus.
Japanese Patent Laid-Open No. 2012-000861 discloses a liquid container that includes a rocking member (rocking body) that rocks around a support shaft depending on a remaining amount of liquid in the liquid container and detects the remaining amount of the liquid, based on a position of the rocking body.
The present invention is a liquid ejection apparatus that ejects liquid contained in a liquid container and can mount the liquid container capable of containing liquid and having a rocking body rotatable around a support shaft depending on an amount of contained liquid, wherein the rocking body is assembled to the liquid container by melting of a part of the support shaft.
Further features of the present invention will become apparent from the following description of exemplary embodiments (with reference to the attached drawings).
In order to reliably catch the change in liquid surface in a liquid container and detect the change in remaining amount of the liquid, it is necessary to support a rocking body without disturbing the motion of the rocking body. With a configuration disclosed in Japanese Patent Laid-Open No. 2012-000861, after a support shaft is passed through a shaft hole of the rocking body, a cap member is fit onto the support shaft, thereby suppressing the drop of the rocking body without disturbing the operation of the rocking body.
However, with the configuration disclosed in Japanese Patent Laid-Open No. 2012-000861, the cap member is required to suppress the drop of the rocking body and there is a problem of an increase in costs due to an increase in the number of parts.
Therefore, according to the present invention, there are provided a liquid ejection apparatus with low costs, a liquid container, and a manufacturing method thereof.
Hereinbelow, a description will be given of a first embodiment of the present invention with reference to the drawings.
The ejection head 40 is connected to the liquid container 1 with a soft tubular member. The ejection head 40 ejects liquid supplied from the liquid container 1 based on information from the control unit 50. The sensor 52 includes a light reception unit 53 and a light emission unit 54. The light reception unit 53 receives light emitted by the light emission unit 54 and sends a signal to the liquid remaining-amount detection unit 51.
In the liquid container 1, a part of a portion storing liquid is formed of a flexible film. The main body frame 7 includes a side surface 9 that is widened in a depth direction and a height direction. Another side surface facing the side surface 9 is covered with a film, thereby forming a liquid storage chamber 4 that can store (contain) the liquid inside the main body frame 7. Further, the liquid container 1 includes a remaining-amount detection chamber 3 that is formed by communication with the liquid storage chamber 4 and by projection of the main body frame 7 and a supply port 2 that can supply the liquid in the liquid storage chamber 4 to the outside of the liquid container 1.
The liquid container 1 includes a support shaft 5 and a support post 8 that are vertically provided with respect to the side surface 9, and further includes a rocking body 11 that rotates (rotatable) around the support shaft 5. The rocking body 11 includes a float unit 12 and a detection unit 13. In the case of rotating the rocking body 11, the movement of the float unit 12 is regulated (limited) with the support post 8. Further, it is so configured that by rotation of the rocking body 11, the detection unit 13 moves in the remaining-amount detection chamber 3, corresponding to the position of the float unit 12. In the case where there is sufficient liquid in the liquid storage chamber 4, the float unit 12 rises with buoyant force of the liquid and is located above in the height direction (arrow z direction).
In this case, the detection unit 13 is configured to be located at the lowest position of the remaining-amount detection chamber 3, between the light reception unit 53 and the light emission unit 54 of the sensor 52. That is, in the case where there is sufficient liquid in the liquid storage chamber 4, light of the sensor 52 is blocked with the detection unit 13, and the liquid remaining-amount detection unit 51 does not receive a signal from the sensor 52. In the case of consuming the liquid in the liquid storage chamber 4, the liquid surface of the liquid in the liquid storage chamber 4 gradually lowers, and the position of the float unit 12 thus gradually lowers, and the position of the detection unit 13 gradually rises.
In the case where the remaining amount of the liquid in the liquid storage chamber 4 is extremely small, the float unit 12 is located at the lowest position and the detection unit 13 is located at the highest position and reaches a position where the light from the sensor 52 is not blocked. At this time, the liquid remaining-amount detection unit 51 receives a signal from the sensor 52, there is not the liquid in the liquid container 1 and the liquid remaining-amount detection unit 51 recognizes an exchange timing. As mentioned above, it is so configured that ON/OFF operation of the sensor 52 is performed depending on the position of the detection unit 13, and the remaining amount of the liquid in the liquid container 1 is detected (detectable).
Note that, according to the present embodiment, the description is given of the example of using an optical sensor as the sensor 52. However, the present invention is not limited to this, and may use another system (e.g., magnetic sensor). In the case of the magnetic sensor, the detection unit 13 needs to include a magnetic body.
As mentioned above, the rocking body 11 rocks in accordance with the change in the remaining amount of liquid in the liquid storage chamber 4, and it is necessary to allow rocking of the rocking body 11 and suppress the drop thereof in a state in which the support shaft 5 is passed through a support shaft through-hole of the rocking body 11. According to the present embodiment, the following method realizes a configuration in which the rocking body 11 can rock and does not drop.
As a state after the swaging, clearance is provided to some degree among the main body frame 7, the stop portion 6, and the rocking body 11, and thus the motion of the rocking body 11 is required not to be disturbed as much as possible. To this end, the swaging is performed so that a length dimension L of the support shaft 5 is longer than a thickness dimension H of the rocking body 11. As such a swaging method that the motion of the rocking body 11 is unlikely to be disturbed, there is a method for controlling a swaging amount. The control of the swaging amount includes control of reach height of a welding tool for descending a welding tool such as the metallic block 21 to a constant height from a reference position for fixing the main body frame 7 in the height direction and control of a displacement amount for detecting the tip end position of the support shaft 5 and descending the welding tool by a constant amount with a detection position as a reference. Further, such swaging control is possible that the clearance is provided among the main body frame, the swaging portion, and the rocking body by keeping a given amount of energy to be constant with the tip end position of the support shaft 5 as a reference.
As mentioned above, with melting and swaging of the support shaft, the rocking body is assembled to the liquid container, thereby suppressing the drop thereof. Thus, the liquid container can be manufactured with low costs.
Note that, it is preferable that the length of the support shaft 5 is longer and the height of the stop portion 6 after the swaging is higher than that of a frame portion of the liquid container 1 and, in the case of welding the film for sealing the liquid storage chamber 4, the end of the support shaft is simultaneously welded to the film. Thus, it is possible to suppress the flattering and the deflection of the film.
Further, in the case where the sealing member is a member harder than the film such as a resin plate, the length of the stop portion 6 is lower than the height of the frame portion, and thereby it can be configured such that the assembling of the resin plate or the like is unlikely to be disturbed.
Hereinbelow, a description is given of a second embodiment of the present invention with reference to the drawings. Note that, since the basic configuration of the present embodiment is similar to that of the first embodiment, only a characteristic configuration is described in the present embodiment hereinbelow.
In the present embodiment, in the case of swaging with a swaging tool such as a metallic block, a position where the formed stop portion 6 reaches the spacer is a reference of the end, and the swaging is possible in a state in which influence of tolerance of parts such as thickness of a main body frame, the length of the support shaft, and thickness of the rocking body is unlikely to receive. A material such as metal is used for the spacer 15 so as not to be melted with the support shaft 5 or the rocking body 11. Here, the material of the spacer is not limited to metal and resin or the like may be used which has been subjected to surface treatment so as not to be welded.
The spacer 15 can be inserted between the main body frame 7 and the rocking body 11. In the case where the side of a swaging surface of the rocking body 11 is an end reference, the rocking body 11 is also melted in swaging the support shaft 5. In this case, the materials of the support shaft 5 and the rocking body 11 are combination of materials having a melting point of the support shaft 5 lower than that of the rocking body 11, thereby suppressing the welding of the rocking body 11. For example, in the case where the material of the main body frame 7 to which the support shaft 5 is formed is a polyethylene (PE) material and the material of the rocking body 11 is polypropylene (PP) material, the melting point of the PE material is lower than that of the PP material, and therefore it is possible to melt and swage only the support shaft 5 without melting the rocking body 11.
Further, a relationship between the support shaft of the main body frame and the support shaft through-hole of the rocking body can be embodied also in a configuration in which the support shaft is provided in the rocking body and the support shaft through-hole is formed in the main body frame as shown in
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. 2015-224951 filed Nov. 17, 2015, which is hereby incorporated by reference wherein in its entirety.
Number | Date | Country | Kind |
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2015-224951 | Nov 2015 | JP | national |
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