The present invention relates to a double container pouring cap that is attached to a container body including an inner layer body for accommodating the content liquid and an outer layer body for accommodating the inner layer body and pours out the content liquid when pressed against the outer layer body, and a double container with this pouring cap attached to the container body.
In recent years, in a container having a pouring cap is attached to a container body for accommodating a content liquid, a double container (also called a delamination container or a laminated peeling container) using a container body including an inner layer body and an outer layer body, for example, as shown in Patent Literature 1 is used. This type of outer layer body is flexible and is configured to allow air to be taken into the internal space formed between the inner layer body and the outer layer body through the through hole (vent) that penetrates the front and back. The pouring cap is provided with an air valve that prevents air from leaking from the internal space to the outside world, while allowing air to be introduced from the outside world into the internal space when the internal space is decompressed.
According to the double container having such a structure, the internal space is pressurized by pressing the outer layer body, and the pressure in the filling space is increased and the content liquid can be poured out. In addition, when the pressure on the outer layer body is released, the internal space is decompressed as the outer layer body is restored, in a manner that air is introduced from the vent to the inner space and only the inner layer body can be reduced in volume and deformed. That is, there is an advantage that the self-standability of the container is maintained even if the amount of the content liquid is reduced. In addition, since the content liquid can be poured out without being replaced with the outside air, there is an advantage that the quality of the accommodated content liquid is unlikely to deteriorate. For this reason, this type of container is being widely used as a suitable container for accommodating seasonings such as soy sauce, sauce, mirin, and cooking liquor, and cosmetics such as shampoo, conditioner, liquid soap, and lotion.
As shown in Patent Literature 1, the above-mentioned pouring cap includes an air valve inside the cap body attached to the outer layer body. The cap body includes an outside air inlet leading to the vent of the outer layer body. The air valve normally abuts on the back surface of the cap body and blocks air flow between the vent and the outside air inlet. On the other hand, when the internal space is decompressed, the air valve is elastically deformed to separate from the back surface of the cap body, and air can flow between the vent and the outside air inlet.
By the way, when the air valve and the portion where the air valve abuts deviate from the intended positions, the contact state between the two changes, in a manner that, for example, when the outer layer body is pressed, the air in the internal space leaks to the outside world and the content liquid may not be discharged as intended. In addition, there is a concern that the outside air cannot be taken in smoothly when the outer layer body is restored, and it takes time to restore the outer layer body. Further, there is a possibility that the air valve separated from the back surface of the cap body vibrates and makes a noise.
An object of the present invention is to solve such a problem and to provide a double container pouring cap that can abut an air valve in an intended state and stably exhibit performance related to the air valve, and a double container.
The present invention is a double container pouring cap attached to a container body including an inner layer body having a filling space that accommodates content liquid and an outer layer body partitioning an inner space between the inner layer body and the outer layer body and including a vent that leads to the internal space, and pours out the content liquid in the filling space by pressing the outer layer body from a pouring outlet, the double container pouring cap including: a cap body covering the vent and attached to the outer layer body, and including the pouring outlet and an outside air inlet that leads to the vent; an air valve that can abut on and separate from a back surface of the cap body, and blocks air flow from the vent to the outside air inlet, while allowing air flow from the outside air inlet to the vent; and an inner plug provided to face the back surface of the cap body with the air valve interposed between, and including a regulation part that abuts on a part of the air valve and limits separation of the air valve from the back surface of the cap body, in which a first abutting surface of the air valve where the regulation part abuts is a flat surface.
The air valve preferably includes a tubular base part, a donut plate-shaped and elastically deformable air valve body part having an inner edge fixedly supported by the base part, and an air valve outer edge part provided on an outer edge side of the air valve body part and having the first abutting surface on a side that faces the regulation part and a second abutting surface that abuts on the back surface of the cap body on a side that faces the back surface of the cap body.
The air valve body part is preferably thinner than the air valve outer edge part.
The regulation part may be a protrusion having a root part connected to the inner plug and a tip part abutting on the first abutting surface.
The inner plug may be provided to face the back surface of the cap body with the air valve interposed between, and may include a partition wall having a content liquid communication port that allows the filling space to communicate with the pouring outlet, an annular wall standing up from the partition wall, an air communication port penetrating at least one of the partition wall and the annular wall and allows the outside air inlet to communicate with the vent, and a plate-shaped part connected to the annular wall and separated from a lower surface of the air valve to extend along the outer edge part of the air valve,
The plate-shaped part is preferably thinner than the abutting part.
The air communication port preferably penetrates at least the annular wall, and a lower surface of the plate-shaped part is preferably at a position aligned with a lower surface of the annular wall that partitions the air communication port.
The first abutting surface and a regulation part abutting surface where the regulation part abuts on the first abutting surface are preferably both flat surfaces.
The present invention is also a double container including the container body and the double container pouring cap according to any one of the above.
In the double container pouring cap of the present invention, the inner plug is provided with a regulation part that abuts on a part of the air valve and limits the separation of the air valve from the back surface of the cap body, and the air valve is provided with a first abutting surface where the regulation part abuts. That is, when the regulation part abuts on the air valve, the air valve can be stably brought into contact with the back surface of the cap body. Further, since the vibration of the air valve is suppressed by the abutting regulation part, it is possible to suppress the noise. Furthermore, since the first abutting surface is a flat surface, the contact condition between the back surface of the cap body and the air valve does not change even if the relative positional relationship between the air valve and the regulation part changes slightly. Therefore, the performance provided by the air valve can be exhibited more stably. In the present specification and the like, the term abut includes not only a state in which the two members are in contact with each other but also a state in which the two members are slightly separated from each other.
Hereinafter, a first embodiment of the double container according to the present invention will be described with reference to
The double container of the present embodiment includes a container body 1 (including an inner layer body 2 and an outer layer body 3), a pouring cap 4 (including an inner plug 5, a check valve 6, a mobile valve 7, and a cap body 8), and a lid body 9.
The inner layer body 2 includes a filling space S inside that can accommodate the content liquid. The inner layer body 2 of the present embodiment is made of thin synthetic resin and can be reduced in volume and deformed.
The outer layer body 3 includes a tubular mouth part 3a extending along a central axis O. In the mouth part 3a of the present embodiment, a lower portion 3c is formed to have a larger diameter than an upper portion 3b having an open upper end. In addition, a male screw part 3d is provided on the outer peripheral surface of the upper portion 3b. Further, the upper portion 3b is provided with a vent 3e extending in the radial direction and penetrating the upper portion 3b, and the outer peripheral surface where the vent 3e opens is provided with a notch 3f extending in the vertical direction and divides the male screw part 3d. Although not illustrated, a tubular body part and a bottom part that closes the lower end of the body part are provided below the mouth part 3a, and the outer layer body 3 has a bottle-like shape. In addition, the outer layer body 3 of the present embodiment is made of synthetic resin, and the body part has flexibility.
In addition, an internal space N leading to the vent 3e is formed between the inner layer body 2 and the outer layer body 3.
The inner layer body 2 and the outer layer body 3 in the present embodiment are made by laminating synthetic resins having low compatibility with each other to be peelable. As synthetic resin forming the inner layer body 2, for example, nylon resin (PA), ethylene vinyl alcohol copolymer resin (EVOH), modified polyolefin resin (for example, “ADMER” (registered trademark) manufactured by Mitsui Chemicals Inc.), polyethylene terephthalate resin (PET), polyethylene resin (PE), and polypropylene resin (PP) can be used. As synthetic resin forming the outer layer body 3, for example, polyethylene resin (PE) such as low density polyethylene (LDPE) and high density polyethylene resin (HDPE), as well as polypropylene resin (PP) and polyethylene terephthalate resin (PET) can be used. The inner layer body 2 and the outer layer body 3 may be formed by a single synthetic resin to have a single layer structure, or may be formed by superimposing a plurality of synthetic resins to form a laminated structure. Such an inner layer body 2 and an outer layer body 3 can be obtained by blow molding a parison in which a synthetic resin material forming the inner layer body 2 and a synthetic resin material forming the outer layer body 3 are laminated. In addition, a test tubular preform in which the synthetic resin material of the inner layer body 2 and the synthetic resin material of the outer layer body 3 are laminated can be prepared, and this preform can be formed by biaxial stretch blow molding. It is also possible to form the inner layer body and the outer layer body individually, and then arrange the inner layer body is inside the outer layer body. Further, although not illustrated, one or a plurality of adhesive bands extending vertically to partially join the inner layer body 2 and the outer layer body 3 may be provided between the inner layer body 2 and the outer layer body 3.
The inner plug 5 is made of synthetic resin such as polypropylene (PP). The inner plug 5 of the present embodiment includes a partition wall 5a located above the mouth part 3a and closing the filling space S. The partition wall 5a is provided with an opening (a content liquid communication port 5b) penetrating the partition wall 5a, and a tubular wall 5c having a cylindrical shape as a whole and having the diameter of the lower part reduced with respect to the upper part.
In addition, an annular recess part 5e having an open upper portion is provided on the radial outer side of the content liquid communication port 5b and the tubular wall 5c, and an annular seal wall 5d that abuts on the inner layer body 2 in a liquid-tight way is provided on the lower surface of the partition wall 5a on the radial outer side of the annular recess part 5e. Further, the outer edge part of the partition wall 5a is provided with an outer edge wall 5f extending upward. A communication opening 5g is provided at the connecting part between the partition wall 5a and the outer edge wall 5f.
Further, the inner plug 5 includes a protrusion (regulation part) 5h provided on the upper surface of the partition wall 5a on the radial inner side of the outer edge wall 5f. As illustrated in
The check valve 6 includes an air valve 6a for regulating the flow of air and a pouring valve 6b for regulating the flow of the content liquid. The check valve 6 of the present embodiment is made of a soft material such as rubber, elastomer, or soft polyethylene (low density polyethylene).
The air valve 6a includes a base part 6c that is cylindrical with the central axis O as the center and has a lower end part supported by the annular recess part 5e. In addition, the radial outer side of the base part 6c is provided with an air valve body part 6d that is a thin donut plate shape with the central axis O as the center, and has an inner edge part integrally connected to the base part 6c and fixedly supported by the base part 6c and extends downward in a curved shape from there toward the radial outer side (extends in an arc shape) as illustrated in
By the way, the shape of the air valve outer edge part 6e can be changed in various ways, for example, as an upper part 6f′ in which the upper part 6f and the outer end part 6h are integrally formed, as illustrated in
As illustrated in
The mobile valve 7 has a spherical shape in the present embodiment, is arranged in the tubular wall 5c, and moves along the inner peripheral surface of the tubular wall 5c in response to a change in the posture of the container body 1 or the internal pressure of the filling space S. As illustrated in
In the present embodiment, the cap body 8 is made of synthetic resin, and includes a ceiling wall 8a located above the check valve 6 and an outer peripheral wall 8b integrally connected to the outer edge of the ceiling wall 8a and surrounding the mouth part 3a. On the inner peripheral surface of the outer peripheral wall 8b, a female screw part 8c suitable for the male screw part 3d is provided.
The center of the ceiling wall 8a is provided with a pouring cylinder 8e that extends upward from the edge part of the hole penetrating the ceiling wall 8a and of which the upper part opening is a pouring outlet 8d of the content liquid. On the lower surface of the ceiling wall 8a, an annular wall 8f that abuts on the inner peripheral surface of the base part 6c in a liquid-tight way is provided. On the radial outer side of the annular wall 8f, an outside air inlet 8g that penetrates the ceiling wall 8a in the vertical direction is provided. The radial outer side of the outside air inlet 8g is provided with an annular step part 8h that protrudes downward from the ceiling wall 8a and has a flat lower surface. The step part 8h of the present embodiment is a portion where the air valve outer edge part 6e of the air valve 6a abuts. More specifically, as illustrated in
As will be described later, when the internal space N is in a decompressed state, regarding the air valve body part 6d of the air valve 6a, the periphery of a portion where the regulation part abutting surface 5j of the protrusion 5h abuts on the first abutting surface 6j almost does not move, and in this portion, the second abutting surface 6g abuts on the step part 8h. However, in a portion where the protrusion 5h does not abut, the air valve body part 6d bends downward. Therefore, a gap is formed between the second abutting surface 6g and the step part 8h. In this state, a passage (communication passage) through which air flows, communicating from the outside air inlet 8g to the vent 3e is formed inside the cap body 8. The communication passage of the present embodiment is a passage that passes through the outside air inlet 8g, passes through the gap between the separated second abutting surface 6g and the step part 8h, and leads to the vent 3e via the communication opening 5g and further a spiral gap formed between the male screw part 3d and the female screw part 8c (a gap due to the notch 3f). Since the air valve body part 6d of the present embodiment is thinner than the air valve outer edge part 6e and is easily bent. Therefore, when the internal space N is in a decompressed state, the second abutting surface 6g can surely be separated from the step part 8h.
The lid body 9 is made of synthetic resin in the present embodiment, and includes a top wall 9a located above the ceiling wall 8a and a lid body outer peripheral wall 9b integrally connected to the top wall 9a. The lower surface of the top wall 9a is provided with a seal tube 9c that is inserted inside the pouring cylinder 8e and abuts on the inner surface of the pouring cylinder 8e in an airtight way. The inner peripheral surface of the lid body outer peripheral wall 9b is provided with an engagement convex part 9d that engages with the claw part 8j. In addition, the outer peripheral surface of the lid body outer peripheral wall 9b is provided with a hinge part 9e that is integrally connected to the outer peripheral wall 8b of the cap body 8. Although the lid body 9 of the present embodiment is integrally connected to the cap body 8, the lid body 9 may be provided separately from the cap body 8 and detachably attached to the cap body 8 by a screw or an undercut.
In the double container having such a configuration, the internal space N is pressurized by pressing the body part of the outer layer body 3, which increases the pressure in the filling space S. Therefore, the content liquid of the filling space S raises the pouring valve main body part 6m, flows from the content liquid communication port 5b through the gap around the connecting piece 6n to the inside of the base part 6c, and is poured out through the inside of the pouring cylinder 8e from the pouring outlet 8d. Here, regarding the above-mentioned communication passage connecting the vent 3e and the outside air inlet 8g, the air valve outer edge part 6e of the air valve 6a abuts on the step part 8h over the entire circumference and is in a non-communication state. Therefore, the air in the internal space N does not leak to the outside world. The mobile valve 7 in the tubular wall 5c moves to the side of the pouring valve main body part 6m (position illustrated by the broken line in
After that, when the pressure on the outer layer body 3 is released and the body part begins to be restored, the volume of the internal space N increases, in a manner that the internal space N is in a decompressed state. As a result, regarding the air valve 6a, the air valve body part 6d bends downward at the portion where the protrusion 5h does not abut. Therefore, a gap is formed between the second abutting surface 6g and the step part 8h, and air introduced from the outside air inlet 8g is introduced through the above-mentioned communication passage to the internal space N. As a result, the outer layer body 3 can be restored while the inner layer body 2 is reduced in volume and deformed. By the way, in this state, since the regulation part abutting surface 5j of the protrusion 5h abuts on the first abutting surface 6j, the vibration of the air valve 6a can be suppressed and the noise can be suppressed. The regulation part abutting surface 5j may be a curved surface, but when both the regulation part abutting surface 5j and the first abutting surface 6j are flat surfaces as in the present embodiment, both abuts on more stably. Therefore, it is possible to more surely suppress the noise.
When the pressure on the outer layer body 3 is released, the pressure in the filling space S returns to the original state and the pouring valve main body part 6m sits on the upper surface of the partition wall 5a. Therefore, it is possible to prevent the inflow of outside air from the content liquid communication port 5b into the filling space S. Here, when the container body 1 is displaced to the original upright posture after the pouring of the content liquid is completed, the mobile valve 7 moves downward due to its own weight or the pressure drop in the filling space S. As a result, a space corresponding to the movement of the mobile valve 7 is formed on the upper inner side of the tubular wall 5c. Therefore, the content liquid corresponding to this space can be pulled back from the pouring cylinder 8e to the inside of the tubular wall 5c (suckback function), and it is possible to effectively prevent dripping from the pouring cylinder 8e. Since the mobile valve 7 that has moved downward sits on the reduced diameter lower part of the tubular wall 5c, it is possible to prevent the inflow of outside air from the tubular wall 5c into the filling space S.
Hereinafter, a second embodiment of the double container according to the present invention will be described with reference to
The double container of the present embodiment includes the container body 1 (including the inner layer body 2 and the outer layer body 3), a pouring cap 14 (including an inner plug 15, a check valve 16, the mobile valve 7, and a cap body 18), and a lid body 19.
The inner plug 15 is made of synthetic resin such as polypropylene (PP). The inner plug 15 of the present embodiment is provided with a partition wall 15a that is located above the mouth part 3a and closes the filling space S, and the partition wall 15a includes an opening (a content liquid communication port 15b) penetrating the partition wall 15a, and a tubular wall 15c having a cylindrical shape as a whole and having the diameter of the lower part reduced with respect to the upper part.
In addition, an annular recess part 15e having an open upper portion is provided on the radial outer side of the content liquid communication port 15b and the tubular wall 15c, and an annular seal wall 15d that abuts on the inner layer body 2 in a liquid-tight way is provided on the lower surface of the partition wall 15a on the radial outer side of the annular recess part 15e. Further, the outer edge part of the partition wall 15a is provided with an annular wall 15f that stands up upward. At a portion where the partition wall 15a and the annular wall 15f are connected, the radial outer portion of the partition wall 15a and the lower portion of the annular wall 15f are integrally cut out and formed, and an air communication port 15g that penetrates both the partition wall 15a and the annular wall 15f is provided.
Further, the inner plug 15 is integrally connected to the inner peripheral surface of the annular wall 15f, and includes a plate-shaped part 15h having a relatively thin thickness. As illustrated in
The inner plug 15 of the present embodiment is formed into the above-mentioned form by curing the molten synthetic resin material in a mold. Specifically, as illustrated in
As illustrated in
By the way, the lower surface of the annular wall 15f and the lower surface of the plate-shaped part 15h are formed by the upper surface of the protrusion part D2a. Here, if the lower surface of the annular wall 15f and the lower surface of the plate-shaped part 15h are not aligned (if the lower surface of the plate-shaped part 15h is located above or below the lower surface of the annular wall 15f), the shape of the upper surface of the protrusion part D2a becomes complicated, the cost increases, and molding becomes difficult. On the other hand, by aligning the lower surface of the annular wall 15f with the lower surface of the plate-shaped part 15h as in the present embodiment, the mold cost can be suppressed and the molding can be stably performed.
As illustrated in
The air valve 16a includes a base part 16c that is cylindrical with the central axis O as the center and has a lower end part supported by the annular recess part 15e. In addition, the radial outer side of the base part 16c is provided with an air valve body part 16d that is a thin donut plate shape with the central axis O as the center, and has an inner edge part integrally connected to the base part 16c and fixedly supported by the base part 16c and extends downward in a curved shape from there toward the radial outer side (extends in an arc shape) as illustrated in
As illustrated in
As illustrated in
Like the cap body 8 described above, the cap body 18 is made of synthetic resin, and includes a ceiling wall 18a located above the check valve 16 and an outer peripheral wall 18b integrally connected to the outer edge of the ceiling wall 18a and surrounding the mouth part 3a. On the inner peripheral surface of the outer peripheral wall 18b, a female screw part 18c suitable for the male screw part 3d is provided.
The center of the ceiling wall 18a is provided with a pouring cylinder 18e that extends upward from the edge part of the hole penetrating the ceiling wall 18a and of which the upper part opening is a pouring outlet 18d of the content liquid. The lower surface of the ceiling wall 18a is provided with an annular recess part 18f that opens downward and supports the upper part of the base part 16c. On the radial outer side of the annular recess part 18f, an outside air inlet 18g that penetrates the ceiling wall 18a in the vertical direction is provided. The radial outer side of the outside air inlet 18g is provided with an annular step part 18h that protrudes downward from the ceiling wall 18a and has a flat lower surface. The step part 18h of the present embodiment is a portion where the air valve outer edge part 16e of the air valve 16a abuts. More specifically, as illustrated in
As will be described later, when the internal space N is in a decompressed state, the air valve body part 16d of the air valve 16a bends downward, and a gap through which air can flow is formed between the air valve outer edge part 16e and the step part 18h. In this state, a passage (communication passage) through which air flows, communicating from the outside air inlet 18g to the vent 3e is formed inside the cap body 18. The communication passage of the present embodiment is a passage that passes through the outside air inlet 18g, passes through the gap between the separated air valve outer edge part 16e and the step part 18h, and leads to the vent 3e via the air communication port 15g and further a spiral gap formed between the male screw part 3d and the female screw part 18c (a gap due to the notch 3f). Since the air valve body part 16d of the present embodiment is thinner than the air valve outer edge part 16e and is easily bent. Therefore, when the internal space N is in a decompressed state, the air valve outer edge part 16e can surely be separated from the step part 18h. Further, since the plate-shaped part 15h can be elastically deformed in the vertical direction as described above, the air valve outer edge part 16e does not significantly hinder the separation from the step part 18h.
Like the lid body 9 described above, the lid body 19 is made of synthetic resin, and includes a top wall 19a located above the ceiling wall 18a and a lid body outer peripheral wall 19b integrally connected to the top wall 19a. The lower surface of the top wall 19a is provided with a seal tube 19c that is inserted inside the pouring cylinder 18e and abuts on the inner surface of the pouring cylinder 18e in an airtight way. The inner peripheral surface of the lid body outer peripheral wall 19b is provided with an engagement convex part 19d that engages with the claw part 18j. In addition, the outer peripheral surface of the lid body outer peripheral wall 19b is provided with a hinge part 19e that is integrally connected to the outer peripheral wall 18b of the cap body 18. Although the lid body 19 of the present embodiment is integrally connected to the cap body 18, the lid body 19 may be provided separately from the cap body 18 and detachably attached to the cap body 18 by a screw or an undercut.
In such a double container of the second embodiment, the internal space N is pressurized by pressing the body part of the outer layer body 3, which increases the pressure in the filling space S. Therefore, the content liquid of the filling space S raises the pouring valve main body part 16f, flows from the content liquid communication port 15b through the gap around the connecting piece 16g to the inside of the base part 16c, and is poured out through the inside of the pouring cylinder 18e from the pouring outlet 18d. Here, regarding the above-mentioned communication passage connecting the vent 3e and the outside air inlet 18g, the air valve outer edge part 16e of the air valve 16a abuts on the step part 18h over the entire circumference and is in a non-communication state. Therefore, the air in the internal space N does not leak to the outside world. Further, in the present embodiment, the air valve outer edge part 16e is supported from below by the abutting part 15j provided at the tip of the plate-shaped part 15h, in a manner that the contact between the air valve outer edge part 16e and the step part 18h is more reliable. Therefore, it is will be possible to more surely prevent the problem that the air in the internal space N leaks to the outside world. The upper surface of the abutting part 15j (regulation part abutting surface 15j1) and the lower surface of the air valve outer edge part 16e (first abutting surface 16e1) may be a curved surface. However, when both are flat surfaces as in the present embodiment, since both abuts on with each other more stably, it is possible to more surely prevent the problem that the air in the internal space N leaks to the outside world. Then, the mobile valve 7 in the tubular wall 15c moves to the side of the pouring valve main body part 16f (position illustrated by the broken line in
After that, when the pressure on the outer layer body 3 is released and the body part begins to be restored, the volume of the internal space N increases, in a manner that the internal space N is in a decompressed state. As a result, the air valve body part 16d bends downward while elastically deforming the plate-shaped part 15h. Therefore, a gap is formed between the air valve outer edge part 16e and the step part 18h, and air introduced from the outside air inlet 18g is introduced through the above-mentioned communication passage to the internal space N. As a result, the outer layer body 3 can be restored while the inner layer body 2 is reduced in volume and deformed. In addition, in this state, since the upper surface of the abutting part 15j (regulation part abutting surface 15j1) abuts on the lower surface of the air valve outer edge part 16e (first abutting surface 16e1), the vibration of the air valve 16a can be suppressed and the noise can be suppressed. In particular, in the present embodiment, the upper surface of the abutting part 15j (regulation part abutting surface 15j1) and the lower surface of the air valve outer edge part 6e (first abutting surface 16e1) are both flat surfaces, and both are stably abutted. Therefore, the vibration of the air valve 16a can be suppressed more surely, in a manner that the effect of suppressing noise is further ensured.
When the pressure on the outer layer body 3 is released, the pressure in the filling space S returns to the original state and the pouring valve main body part 16f sits on the upper surface of the partition wall 15a. Therefore, it is possible to prevent the inflow of outside air from the content liquid communication port 15b into the filling space S. Here, when the container body 1 is displaced to the original upright posture after the pouring of the content liquid is completed, the mobile valve 7 moves downward due to its own weight or the pressure drop in the filling space S. As a result, a space corresponding to the movement of the mobile valve 7 is formed on the upper inner side of the tubular wall 15c. Therefore, the content liquid corresponding to this space can be pulled back from the pouring cylinder 18e to the inside of the tubular wall 15c (suckback function), and it is possible to effectively prevent dripping from the pouring cylinder 18e. Since the mobile valve 7 that has moved downward sits on the reduced diameter lower part of the tubular wall 15c, it is possible to prevent the inflow of outside air from the tubular wall 15c into the filling space S.
Although one embodiment of the present invention has been described above, the present invention is not limited to such a specific embodiment, and unless otherwise specified in the above description, various modifications and changes are possible within the range of the gist of the present invention described in the claims. Moreover, the effect of the above-described embodiment is merely an example of the effect resulting from the present invention, and does not mean that the effect of the present invention is limited to the above-mentioned effect.
For example, the protrusion 5h (regulation part) described above hardly bends when a downward force is applied to the tip part, but may bend downward when the second abutting surface 6g separates from the step part 8h by reducing the thickness or forming the protrusion 5h with a soft material (such as rubber and elastomer) by insert molding and the like. In addition, the second abutting surfaces 6g and 16e2 may abut on the lower surfaces of the ceiling walls 8a and 18a without providing the step parts 8h and 18h.
Number | Date | Country | Kind |
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2019-120735 | Jun 2019 | JP | national |
2019-140360 | Jul 2019 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2020/025388 | 6/26/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/262672 | 12/30/2020 | WO | A |
Number | Name | Date | Kind |
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6951295 | Gaus | Oct 2005 | B1 |
20210362916 | Kollia | Nov 2021 | A1 |
20220258931 | Sakamoto | Aug 2022 | A1 |
Number | Date | Country |
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2011-031932 | Feb 2011 | JP |
2014-024569 | Feb 2014 | JP |
2016-190675 | Nov 2016 | JP |
2017-132529 | Aug 2017 | JP |
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2018-052563 | Apr 2018 | JP |
2018-058594 | Apr 2018 | JP |
2018-058643 | Apr 2018 | JP |
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2018058643 | Apr 2018 | JP |
WO-2014208096 | Dec 2014 | WO |
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WO-2020262672 | Dec 2020 | WO |
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Number | Date | Country | |
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20220258931 A1 | Aug 2022 | US |