This application claims priority to Japanese Patent Application No. 2018-205392, filed on Oct. 31, 2018, the entire contents of which are incorporated herein by reference.
The present disclosure relates to a dispensing container capable of changing the ratio between the amounts of two kinds of contents to be dispensed.
As a type of container that contains cosmetic lotions, hair dyes, or the like, a dispensing container that contains two kinds of contents separately and that, when used, mixes the contents before dispensing them has been proposed (refer to, for example, Patent Literature [PTL] 1).
PTL 1: JP 3651773 B2
The problem with the dispensing container described in PTL 1, however, is that although it is possible to select whether to dispense equal amounts of the two kinds of contents at the same time or to dispense only one of the contents, it is not possible to dispense the two kinds of contents by changing the ratio between the amounts of the contents to be dispensed. The dispensing container can hardly be used to finely adjust the ratio between the amounts of the two contents to be dispensed in accordance with skin and hair conditions of the user, and there is room for improvement in this respect.
It would be helpful to provide a dispensing container that is capable of changing the ratio between the amounts of two kinds of contents to be dispensed.
A dispensing container according to an embodiment of the present disclosure includes:
two container bodies configured to respectively contain two kinds of contents;
two pumps respectively including two protruding stems configured to be depressed in an upwardly urged state, the two pumps being configured to respectively pump the two kinds of contents in the two container bodies upward in response to the two stems being depressed;
an adjusting member configured to directly or indirectly press the two stems and configured to be rotatable about an axis extending in a substantially vertical direction that is located between the two container bodies in a plan view; and
a pressing head configured to, in response to a depressing operation, rotate about an axis extending in a substantially horizontal direction that is parallel to a direction in which the two container bodies are arranged, to thereby depress the two stems via the adjusting member, wherein
the adjusting member includes a plurality of pressing portions against which the two stems are directly or indirectly pressed, and when the adjusting member is rotated about the axis extending in the substantially vertical direction, one of the plurality of pressing portions on a side of one of the two stems approaches the axis extending in the substantially horizontal direction in the plan view, whereby a depressing stroke of the one of the plurality of pressing portions on the side of the one of the two stems in response to a depressing operation of the pressing head becomes shorter, and another one of the plurality of pressing portions on a side of another one of the two stems moves away from the axis extending in the substantially horizontal direction, whereby a depressing stroke of the other one of the plurality of pressing portions on the side of the other one of the two stems in response to the depressing operation of the pressing head becomes longer.
In a preferred embodiment of the present dispensing container configured as above, the plurality of pressing portions of the adjusting member is configured to protrude downward from both end portions of an arm portion extending substantially in the horizontal direction, and the adjusting member is configured to be mounted to the pressing head so as to be rotatable about the axis extending in the substantially vertical direction.
In still another preferred embodiment of the present dispensing container configured as above, the adjusting member includes an operation lever that is orthogonal to a longitudinal direction of the arm portion and that protrudes to a side opposite to the axis extending in the substantially horizontal direction in the plan view, and the operation lever is configured to protrude in the substantially horizontal direction through a through hole provided in the pressing head.
In still another preferred embodiment of the present dispensing container configured as above, the adjusting member is configured to be coupled to a tab provided on an upper surface of the pressing head, so that rotation of the adjusting member is adjustable by rotating the tab.
In still another preferred embodiment of the present dispensing container configured as above, two nozzle portions are respectively mounted to the two stems, the two nozzle portions being configured to respectively guide the two kinds of contents pumped from the two pumps to two dispensing ports, and the adjusting member is configured to press the two stems via the nozzle portions.
In still another preferred embodiment of the present dispensing container configured as above, each of the two the nozzle portions is configured to be provided, in an upper end portion thereof on a side adjacent to the axis extending in the substantially horizontal direction in the plan view, with a recess that is recessed downward.
In still another preferred embodiment of the present dispensing container configured as above, each of the two nozzle portions is configured to be coupled to the corresponding dispensing port via a flexible tube.
According to the present disclosure, a dispensing container that is capable of changing the ratio between the amounts of two kinds of contents to be dispensed can be provided.
In the accompanying drawings:
Hereinafter, a first embodiment of the present disclosure will be described by illustration in more detail with reference to the drawings.
As illustrated in
In the present specification and in the claims, an up/down direction shall mean the up/down direction in a state in which the dispensing container 100 is in an upright position where a pressing head 63 is located on the upper side with respect to the container bodies 10 as illustrated in
The container bodies 10 are also referred to as laminated peelable containers (delamination containers) or double containers. Each container body 10 has a double structure including an outer layer body 18 and an inner layer body 17 accommodated on the inner side of the outer layer body 18, and in response to dispensing of the corresponding content (content liquid), the inner layer body 17 undergoes volume reduction and deformation independently from the outer layer body 18. Further, the container body 10 is provided, in the mouth 11 thereof, with a containing tubular portion 16 as a separate member. The containing tubular portion 16 covers the corresponding pump 30, which will be described later, from the outer side in the radial direction and includes an inner plug member 19.
The outer layer body 18 is a portion constituting an outer shell of the container body 10. As illustrated in
As illustrated in
In the present embodiment, the container body 10 has been formed into a laminated structure in which the inner layer body 17 is laminated in a peelable manner on an inner surface of the outer layer body 18, by co-extruding a synthetic resin material for the outer layer body 18 and a synthetic resin material for the inner layer body 17 that have low compatibility to thereby form a laminated parison and by blow molding the laminated parison with use of a mold. Additionally, the container body 10 may also be formed by biaxially stretch blow molding a preform having a laminated structure that has been formed in advance by injection molding or the like.
In the present embodiment, nylon is used as a material for the inner layer body 17 constituting the container body 10, and polypropylene (PP) is used as a material for the outer layer body 18. The present disclosure, however, is not limited to this embodiment, and an ethylene-vinyl alcohol copolymer resin (EVOH) may also be used as a material for the inner layer body 17, and high-density polyethylene resin (HDPE) or low-density polyethylene (LDPE) may be used as a material for the outer layer body 18. Further, in a case in which a laminated peelable container is formed by biaxial stretched blow molding, for example, polyethylene terephthalate (PET) may be used as a material for the outer layer body 18. It is to be noted that a material for the inner layer body 17 and a material for the outer layer body 18 are not limited to the above-described materials, and other resins having low compatibility with each other can be used as the materials. Further, the container body 10 does not necessarily need to be a laminated peelable container, and the outer layer body 18 and the inner layer body 17 may be formed separately and assembled together. Additionally, although not illustrated, one or more adhesive strips made of, for example, AdmerĀ® (Admer is a registered trademark in Japan, other countries, or both) may be disposed between the inner layer body 17 and the outer layer body 18 so that the adhesive strips extending in the up/down direction partially join the inner layer body 17 and the outer layer body 18.
In the present embodiment, the container body 10 is formed by blow molding and is configured so that air can be introduced into a space between the outer layer body 18 and the inner layer body 17 via a slit formed in a pinch-off portion at the bottom 15. When the content is dispensed from the dispensing port 52c, as much air as the amount of the dispensed content is taken into the space between the outer layer body 18 and the inner layer body 17 via the slit from the outside, and, while the inner layer body 17 undergoes volume reduction and deformation, the outer layer body 18 can maintain the original shape. That is, in a case in which the outer layer body 18 is made of a relatively more rigid material, such as polypropylene (PP), high-density polyethylene resin (HDPE), or polyethylene terephthalate (PET), the outer layer body 18 can continue to maintain the same shape regardless of the volume reduction and deformation undergone by the inner layer body 17. Further, in a case in which the outer layer body 18 is made of a relatively less rigid material, such as low-density polyethylene (LDPE), even when the outer layer body 18 temporarily undergoes volume reduction and deformation in conjunction with the volume reduction and deformation undergone by the inner layer body 17, air is subsequently taken into the space between the outer layer body 18 and the inner layer body 17 via the slit, whereby the outer layer body 18 can be restored to the original shape.
Because the above configuration prevents air from being taken into the inner layer body 17 from the outside, it is possible to prevent deterioration of the quality of the content due to oxidation or the like. Further, the content in the inner layer body 17 can be used up as much as possible so as to minimize the remaining amount, and moreover, even contents having high viscosities can be discharged. Besides, even in a case in which only a small amount of the content is discharged as described later, air corresponding to the dispensed amount can be taken into the space between the outer layer body 18 and the inner layer body 17 via the slit.
As illustrated in
Further, the containing tubular portion 16, which includes the inner plug member 19 (refer to
As illustrated in
The containing tubular portion 16 is positioned and fixed relative to the container body 10, with the upper end portion of the tubular-shaped portion 16a being fitted to an inner circumferential surface of the mouth 11 of the container body 10, thereby sandwiching the mouth 11 between the upper end portion of the tubular-shaped portion 16a and the upper outer wall 16c.
The inner plug member 19 is fitted and fixed to an inner surface of the first reduced-diameter portion 16e, and the inner plug member 19 includes an inner plug 19a for blocking communication between the containing space S of the container body 10 and the outside before assembly of the dispensing container 100 (refer to the inner plug 19a represented by a two-dot chain line in
Next, configurations of the dispensing caps 20 will be described with reference to
Each dispensing cap 20 is made of polypropylene, and as illustrated in
The outer circumferential wall 21 is provided, on an inner circumferential surface thereof, with a female screw portion 21a. The female screw portion 21a protrudes to the inner side in the radial direction from the inner circumferential surface of the outer circumferential wall 21 and is configured to be screw-engaged with the male screw portion 11a.
The upper circumferential wall 22 is provided, on an outer circumferential surface thereof, with vertically extending outer circumferential ribs 22b that are disposed intermittently in the circumferential direction. Each outer circumferential rib 22b fits in between adjacent inner ribs 84a formed on an inner circumferential surface of a side wall portion 84 of the later-described coupling member 80, so as to be coupled with the coupling member 80 in a manner such that the coupling member 80 is prevented from rotating in the circumferential direction.
A fitting tube 23a is formed in a middle portion of the top wall 23 of the dispensing cap 20, and a communication hole 23b, which allows for vertical communication through the top wall 23, is provided on the inner side of the fitting tube 23a. As illustrated in
Next, configurations of the pumps 30 will be described with reference to
As illustrated in
The cylinder 33 includes a tubular-shaped portion 33a that stores therein the content in a state in which the upper assembly 41 is urged upward, a flange portion 33b that is provided at the upper end portion of the tubular-shaped portion 33a and that is sandwiched between the top wall 23 of the dispensing cap 20 and the mouth 11, a fitting tube 33d that is integrally formed at a lower end portion of the tubular-shaped portion 33a via a stepped portion 33c and that is fitted to an inner circumferential surface of a later-described blocking member 36, and a draw valve seat 33e that protrudes upward from an upper end portion of the fitting tube 33d and that allows the draw valve 35c to be seated thereon for closing the valve.
The draw valve member 35 includes a draw valve 35c that is elastically supported by a support member 35d, support frames 35a in which the draw valve 35c is supported, and an upper wall 35b that closes upper ends of the support frames 35a. The support frames 35a are intermittently formed in the circumferential direction, and when the draw valve 35c is displaced upward in response to a negative pressure in the cylinder 33 so that the valve is opened, the content in the containing space S passes through the inside of the fitting tube 33d, through a space between the draw valve 35c and the draw valve seat 33e, and through spaces between adjacent intermittently formed support frames 35a, thus flowing into the tubular-shaped portion 33a of the cylinder 33.
As illustrated in
The stem 42 includes a coupling tubular portion 42a that defines a moving space for the content and that has the upper end portion to which the corresponding nozzle portion 50 is fitted, and a large-diameter portion 42c that is contiguous with a lower end portion of the coupling tubular portion 42a via a stepped portion 42b and that has a diameter greater than that of the coupling tubular portion 42a. The piston guide 44 is fitted on the inner side of the coupling tubular portion 42a, and the upper end portion of the coupling tubular portion 42a is fitted to the first locking member 46 holding the upper end portion of the urging spring 49. Further, an inner wall upper end portion 43b of the annular piston 43 is configured to be slidable on an inner circumferential surface of the large-diameter portion 42c. The annular piston 43 has an inner wall lower end portion 43c, which, together with the discharge valve seat 44d, forms a discharge valve. That is, when the inner wall lower end portion 43c is seated on the discharge valve seat 44d, the discharge valve is closed, and when the inner wall lower end portion 43c is spaced from the discharge valve seat 44d, the discharge valve is opened so that the content can pass through the discharge valve hole 44c. Additionally, the annular piston 43 has an outer wall 43a that slides on the inner surface of the tubular-shaped portion 33a of the cylinder 33.
Next, the nozzle portions 50 will be described. Each nozzle portion 50 includes a mounting member 51 that is fitted to the upper end portion of the corresponding stem 42 and that guides the content pumped from the corresponding pump 30 to the dispensing port 52c, and a dispensing port member 52 that is mounted to a tip of the mounting member 51 and that has the dispensing port 52c for the content.
The mounting member 51 includes a perpendicular tubular portion 51a that defines a flow path through which the content is guided upward and that is fitted to the upper end portion of the stem 42, a horizontal tubular portion 51d that is perpendicular to the perpendicular tubular portion 51a and that guides the content to the dispensing port 52c in a horizontal direction, a ceiling wall 51b that is contiguous with an upper end portion of the perpendicular tubular portion 51a, and a circumferential wall 51c that hangs from an outer peripheral edge of the ceiling wall 51b, and a pressure-receiving portion 51e that is provided above the perpendicular tubular portion 51a and that abuts against a pressing portion 61b of a later-described adjusting member 61. In front views illustrated in
The dispensing port member 52 includes a fitting tubular portion 52a to which an outer circumferential surface of the horizontal tubular portion 51d is fitted, and a dispensing port tubular portion 52b through which the content is guided forward after passing through the horizontal tubular portion 51d. Further, the dispensing port 52c is provided in the dispensing port tubular portion 52b. It is to be noted that a front view and a plan view for the dispensing container 100 including the dispensing port member 52 are respectively illustrated in
Next, the head portion 60 will be described. The head portion 60 includes the adjusting member 61 that depresses the respective pressure-receiving portions 51e of the two mounting members 51 at a stroke ratio desired by the user, and the pressing head 63 through which pressing force is applied to the adjusting member 61.
As illustrated in
As illustrated in
A rotation shaft 63c of the pressing head 63 is configured to be rotatable around a rotation groove (which is not illustrated) provided in the coupling member 80. Thus, when the pressing head 63 is depressed in the arrow direction illustrated in
In particular, when one of the pressing portions 61b is above the recess 51f as illustrated in
As illustrated in
The outer container 70 has an enough size to accommodate the two container bodies 10, and the outer container 70 includes a side wall portion 71 and a bottom portion 72 closing a lower end of the side wall portion 71. The bottom portion 72 is provided with two positioning walls 73 for accommodating and positioning the reduced-diameter portions 14 of the container bodies 10.
The coupling member 80 for coupling and positioning the two dispensing caps 20 is fitted to an inner circumferential surface of an upper end portion of the outer container 70. The coupling member 80 includes the side wall portion 84 that surrounds the outer circumferential walls 21 of the dispensing caps 20, an upper wall 82 that is contiguous with an upper end portion of the side wall portion 84 and that couples the two dispensing caps 20, a circumferential wall 81 that extends upward from an outer peripheral edge of the upper wall 82, two upper tubular walls 83 that each extend upward from an upper surface of the upper wall 82 and that each surround the corresponding nozzle portion 50 from the outer side in the radial direction, a partition wall 85 that divides the dispensing caps 20, the pumps 30 and the nozzle portions 50 in the middle in the left/right direction. As illustrated in
The lid 90 includes an outer circumferential wall 91 that covers the nozzle portions 50 and the head portion 60 from the outer side in the radial direction, and an upper wall 92 that is contiguous with an upper end portion of the outer circumferential wall 91. Further, the lid 90 is fixed to the coupling member 80, by a lower end portion of the outer circumferential wall 91 being fitted to an inner circumferential surface of the circumferential wall 81. The lid 90 covers an area above the coupling member 80 except for an upper surface of the pressing head 63 from the outer side in the radial direction and from above. In the plan view, the outer circumferential wall 91 of the lid 90 is configured to be substantially aligned with the circumferential wall 81 of the coupling member 80 and with the side wall portion 71 of the outer container 70.
To dispense the contents from the dispensing container 100 with the above configuration, the user first depresses the pressing head 63 in an upright state of the dispensing container 100 illustrated in
When the stem 42 constituting the upper assembly 41 of each pump 30 is depressed in response to the pressing head 63 being depressed, the piston guide 44, which is fitted and fixed to the inner circumferential surface of the stem 42, also moves downward at the same time. At this time, the inner wall upper end portion 43b of the annular piston 43 is only slightly displaced because the inner wall upper end portion 43b slides against the inner circumferential surface of the large-diameter portion 42c. Accordingly, the discharge valve seat 44d of the piston guide 44 is separated from the inner wall lower end portion 43c of the annular piston 43, whereby the discharge valve is temporarily brought into an open state.
As a result of downward displacement of the lower end portion 44e of the piston guide 44, the content stored in the cylinder 33 is compressed, passes through the opened discharge valve, and flows into the piston guide 44 through the discharge valve hole 44c so as to be pumped upward. Although the stem 42 moves downward by a distance corresponding to a pressing stroke of the pressing portion 61b, the stem 42 stops, at farthest, at a position where the lower end portion 44e of the piston guide 44 comes into abutment against the upper wall 35b of the draw valve member 35. As is apparent from
When the user stops depressing the pressing head 63, the first locking member 46 is pushed back upward by restoring force of the urging spring 49. Accordingly, the stem 42, which is fitted to the inner circumferential surface of the first locking member 46, is also pulled upward together with the piston guide 44, thereby causing a negative pressure inside the cylinder 33. Further, because the inner wall lower end portion 43c of the annular piston 43 is not seated on the discharge valve seat 44d immediately after the stem 42 and the piston guide 44 start to be displaced upward, some of the content within a passage leading from an inner space of the piston guide 44 to the dispensing port 52c that corresponds to a change in volume inside the cylinder 33 is drawn downward by the negative pressure. This effect, which is also referred to as a suck back effect, causes the content remaining in the passage to be drawn into the cylinder 33, to thereby prevent liquid-dripping from the dispensing port 52c. As upward displacement of the piston guide 44 further continues, the discharge valve seat 44d abuts against the inner wall lower end portion 43c to be sealed, so that the discharge valve is closed. In conjunction with the closing of the discharge valve, the draw valve 35c of the draw valve member 35 is in turn lifted upward by the aforementioned negative pressure against its own weight and against elastic force of the support member 35d, so that the draw valve 35c is opened. The content in the containing space S is drawn up by the negative pressure inside the cylinder 33, passes through the draw valve 35c, and passes through spaces between adjacent support frames 35a so as to be stored in the cylinder 33.
When the stem 42 reaches the uppermost point in its movable range, the content stops from being drawn from the containing space S into the cylinder 33, and the draw valve 35c is seated on the draw valve seat 33e again. At this time, although the inner layer body 17 undergoes volume reduction and deformation in conjunction with a decrease in the content in the containing space S, since the draw valve 35c is closed, air cannot be taken into the inner layer body 17 from the outside. This prevents deterioration of the quality of the content due to oxidation or the like. Further, since air is introduced into the space between the outer layer body 18 and the inner layer body 17 via the slit formed at the bottom 15 of the container body 10, the outer layer body 18 can maintain the original shape even when the inner layer body 17 undergoes volume reduction and deformation. In particular, by changing the ratio between the amounts of the two kinds of contents to be dispensed, even in a case in which the amount of one of the contents to be dispensed is small, an amount of air corresponding to the small amount dispensed is introduced into the space between the outer layer body 18 and the inner layer body 17 via the slit at the bottom 15. Thus, the outer layer body 18 can easily maintain the original shape.
As described above, a dispensing container of the present embodiment includes: two container bodies 10 configured to respectively contain two kinds of contents; two pumps 30 respectively including two protruding stems 42 configured to be depressed in an upwardly urged state, the two pumps 30 being configured to respectively pump the two kinds of contents in the two container bodies 10 upward in response to the two stems 42 being depressed; an adjusting member 61 configured to directly or indirectly press the two stems 42 and configured to be rotatable about an axis OV extending in a substantially vertical direction that is located between the two container bodies 10 in a plan view; and a pressing head 63 configured to, in response to a depressing operation, rotate about an axis OH extending in a substantially horizontal direction that is parallel to a direction in which the two container bodies 10 are arranged, to thereby depress the two stems 42 via the adjusting member 61, wherein the adjusting member 61 includes a plurality of pressing portions 61b against which the two stems 42 are directly or indirectly pressed, and when the adjusting member 61 is rotated about the axis OV extending in the substantially vertical direction, one of the plurality of pressing portions 61b on a side of one of the two stems approaches the axis OH extending in the substantially horizontal direction in the plan view, whereby a depressing stroke of the one of the plurality of pressing portions 61b on the side of the one of the two stems in response to a depressing operation of the pressing head 63 becomes shorter, and another one of the plurality of pressing portions 61b on a side of another one of the two stems moves away from the axis OH extending in the substantially horizontal direction, whereby a depressing stroke of the other one of the plurality of pressing portions 61b on the side of the other one of the two stems in response to the depressing operation of the pressing head 63 becomes longer. Adopting such a configuration allows for dispensing in which the ratio between the amounts of the two kinds of contents to be dispensed can be changed by adjusting rotation of the adjusting member 61 before depressing the pressing head 63 and dispensing the contents. In particular, because in the present embodiment the ratio between the amounts to be dispensed can be adjusted by adjusting rotation of the adjusting member 61, the two kinds of contents can be dispensed while changing the ratio between the amounts of the two kinds of contents to be dispensed, without having to change relative positions of the container bodies 10 and the dispensing ports 52c.
Further, in the present embodiment, the plurality of pressing portions 61b of the adjusting member 61 is configured to protrude downward from both end portions of an arm portion 61e extending substantially in the horizontal direction, and the adjusting member 61 is configured to be mounted to the pressing head 63 so as to be rotatable about the axis OV extending in the substantially vertical direction. By adopting such a configuration, the adjusting member 61 can be configured to be compact, and moreover, the stems 42 can be reliably depressed by the pressing portions 61b protruding downward to thereby operate the pumps 30.
Further, in the present embodiment, the adjusting member 61 includes an operation lever 61f that is orthogonal to a longitudinal direction of the arm portion 61e and that protrudes to a side opposite to the axis OH extending in the substantially horizontal direction in the plan view, and the operation lever 61f is configured to protrude in the substantially horizontal direction through a through hole 63h provided in the pressing head 63. By adopting such a configuration, rotation of the adjusting member 61, which is disposed between the pressing head 63 and the stems 42, can be easily adjusted by using the operation lever 61f.
Further, in the present embodiment, two nozzle portions 50 are respectively mounted to the two stems 42, and the adjusting member 61 is configured to press the two stems 42 via the nozzle portions 50. The two nozzle portions 50 are configured to respectively guide the two kinds of contents pumped from the two pumps 30 to two dispensing ports 52c. By adopting such a configuration, the stems 42 can be pressed more easily compared with a case in which the adjusting member 61 directly presses the stems 42, and moreover, the contents can be easily guided to the dispensing ports 52c by changing directions of the contents at the nozzle portions 50.
Further, in the present embodiment, each of the two the nozzle portions 50 is configured to be provided, in an upper end portion thereof on the side adjacent to the axis OH extending in the substantially horizontal direction in the plan view, with a recess 51f that is recessed downward. By adopting such a configuration, a state in which one of the two kinds of contents cannot be dispensed may be created without difficulty.
In the following, a dispensing container 200 according to a second embodiment of the present disclosure will be described by illustration in detail with reference to the drawings.
It is to be noted that, compared with the first embodiment, the dispensing container 200 according to the second embodiment is similar to the first embodiment, except for the following points: the functions of the dispensing caps 20 and the coupling member 80 are realized by a dispensing cap 120 alone; the functions of the mounting members 51 and the dispensing port members 52 in the nozzle portions 50 are realized by mounting members 151, dispensing port members 152, and flexible tubes 153 of nozzle portions 150; the functions of the adjusting member 61 and the operation lever 61f of the head portion 60 are realized by an adjusting member 161 and a tab 165 of a head portion 160; and pipes P are fitted inside the second reduced-diameter portions 16f of the containing tubular portions 16. The description herein will therefore focus on the points different from the first embodiment.
The dispensing cap 120 of the present embodiment is made of polypropylene, and as illustrated in
Each inner circumferential wall 121 is provided, on an inner circumferential surface thereof, with a female screw portion 121a. The female screw portion 121a protrudes to the inner side in the radial direction from the inner circumferential surface of the inner circumferential wall 121, and the female screw portion 121a is configured to be screw-engaged with the male screw portion 11a.
An upper end portion of the side wall portion 71 of the outer container 70 is fitted to an inner circumferential surface of a lower end portion of the outer circumferential wall 125. The outer circumferential wall 125 has a substantially rectangular shape that is substantially aligned with the outer circumferential wall 91 of the lid 90 and the side wall portion 71 of the outer container 70 in the plan view. Thus, the dispensing container 200 has a prismatic outer shape having substantially the same sectional shape in the plan view from the lid 90 to the outer container 70.
The top wall 123 of the dispensing cap 120 is provided with two communication holes 123b. As illustrated in
Next, the nozzle portions 150 will be explained. Each nozzle portion 150 includes a mounting member 151 that is fitted to an upper end portion of the corresponding stem 42 and that guides the content pumped from the corresponding pump 30 to a dispensing port 152c, a flexible tube 153 that is mounted to a horizontal tubular portion 151d of the mounting member 151 so as to flexibly couple the mounting member 151 and the dispensing port member 152, and the dispensing port member 152 that is provided with the dispensing port 152c for the content.
The mounting member 151 has a vertical tubular portion 151a that defines a flow path for guiding the content upward and that is fitted to the upper end portion of the stem 42, a horizontal tubular portion 151d that is orthogonal to the vertical tubular portion 151a and that guides the content in the horizontal direction, and a pressure-receiving portion 151e that is provided above the vertical tubular portion 151a so that a pressing portion 161b of a later-described adjusting member 161 abuts against the pressure-receiving portion 151e. The horizontal tubular portion 151d is directed in a direction perpendicular to the plane of the paper in the front view illustrated in
As illustrated in
The dispensing port member 152 includes the fitting tubular portion 152a to which an outer circumferential surface of the flexible tube 153 is fitted, and a dispensing port tubular portion 152b through which the content is guided forward. Further, the dispensing port tubular portion 152b is provided, inside thereof, with a dispensing port 152c. It is to be noted that a plan view and a front view of the dispensing container 200 including the dispensing port member 152 are illustrated in
By thus coupling the mounting member 151 and the dispensing port member 152 via the flexible tube 153, the flexible tube 153 can absorb relative height fluctuations between the mounting member 151 and the dispensing port member 152, so that the dispensing port member 152 can be maintained at the same position without tilting, even when, for example, the mounting member 151 is significantly displaced downward in response to a pressing head 163 being depressed as illustrated in
Next, the head portion 160 will be described. The head portion 160 includes the adjusting member 161 that depresses the respective pressure-receiving portions 151e of the two mounting members 151 at a stroke ratio desired by the user, and the pressing head 163 through which pressing force is applied to the adjusting member 161.
As illustrated in
As illustrated in
As can be understood from
Moreover, a distance from the hinge portion 163c (axis OH extending in the substantially horizontal direction) to a portion of the pressing portion 161b of the adjusting member 161 on the side of container A that overlaps with the pressure-receiving portion 151e of the mounting member 151 is the same as that from the hinge portion 163c to a portion of the pressing portion 161b of the adjusting member 161 on the side of container B that overlaps with the pressure-receiving portion 151e of the mounting member 151. Accordingly, when the pressing head 163 is pressed and rotated about the hinge portion 163c (axis OH extending in the substantially horizontal direction), a stroke length of the pressing head 163 pressing the mounting member 151 via the adjusting member 161 on the side of container A is 3.15 mm, and a stroke length of that on the side of container B is equally 3.15 mm, as can be understood from a comparison between
As described above, in the present embodiment, the adjusting member 161 is configured to be coupled to the tab 165, which is provided on the upper surface of the pressing head 163, so that rotation of the adjusting member 161 can be adjusted by rotating the tab 165. By adopting such a configuration, the adjusting member 161, which is disposed between the pressing head 163 and the mounting members 151, can be adjusted by a simple operation of rotating the tab 165 provided on the pressing head 163.
Further, in the present embodiment, each nozzle portion 150 is configured to be coupled to the corresponding dispensing port 152c via the corresponding flexible tube 153. By adopting such a configuration, the flexible tube 153 can absorb relative height fluctuations between the mounting member 151 and the dispensing port 152c (dispensing port member 152), so that the dispensing port 152c can be maintained at the same position without tilting, even when the nozzle portion 150 (mounting member 151) is significantly displaced downward in response to the pressing head 163 being depressed.
In the following, a dispensing container 300 according to a third embodiment of the present disclosure will be described by illustration in detail with reference to the drawings.
It is to be noted that, compared with the first embodiment, the dispensing container 300 according to the third embodiment is similar to the first embodiment, except for the following points: the functions of the dispensing caps 20 and the coupling member 80 are realized by a dispensing cap 220 alone; the functions of the adjusting member 61 and the operation lever 61f in the head portion 60 are realized by an adjusting member 261 and an operation portion 261f in a head portion 260; and the outer container 70 is not additionally provided around the container bodies 10. The description herein will therefore focus on the points different from the first embodiment.
The dispensing cap 220 of the present embodiment is made of polypropylene and has a rectangular shape with rounded corners in the plan view (refer to
Each circumferential wall 221 is provided, on an inner circumferential surface thereof, with a female screw portion 221a. The female screw portion 221a protrudes to the inner side in the radial direction from the inner circumferential surface of the circumferential wall 221, and the female screw portion 221a is configured to be screw-engaged with the male screw portion 11a.
The top wall 223 of the dispensing cap 220 is provided with two communication holes 223b. As illustrated in
Next, the head portion 260 will be explained. The head portion 260 includes an adjusting member 261 that depresses the respective pressure-receiving portions 51e of the two mounting members 51 of the two nozzle portions 50 at a stroke ratio desired by the user, and a pressing head 263 that can rotate about the axis OH extending in the substantially horizontal direction that is parallel to a direction in which the two container bodies 10 are arranged (refer to
In the present embodiment, the pressing head 263 is configured to be depressed in response to the operating portion 261f of the adjusting member 261 being pressed downward. In this way, a depressing operation of the pressing head 263 refers to a notion including a case of indirectly depressing the pressing head 263 by applying force to another member as in the present embodiment, without being limited to a case of directly depressing the pressing head 263.
As illustrated in
The pressing head 263 includes a rotation shaft 263c defining the axis OH extending in the substantially horizontal direction, positioning arms 263a that extend rearward from both end portions in the left/right direction (up/down direction in
The rotation shaft 263c of the pressing head 263 is configured to be rotatable around a sliding surface (which is not shown) provided in the lid 90. Thus, when the pressing head 263 is depressed in the direction toward the back of the plane of paper in
In the present embodiment, rotation of the adjusting member 261 about the axis OV extending in the substantially vertical direction can be adjusted by rotating the operation portion 261f illustrated in
It is to be noted that in the present embodiment an angular position of the adjusting member 261 about the axis OV extending in the substantially vertical direction with respect to the pressing head 263 is determined, by fitting the plurality of fitting protrusions 261g, which are provided on the upper portions of the pressing portions 261b, in a plurality of recesses 263d provided in the corresponding positioning arm 263a of the pressing head 263. The user can change the angular position of the adjusting member 261 about the axis OV extending in the substantially vertical direction with respect to the pressing head 263, by further rotating the operating portion 261f about the axis OV extending in the substantially vertical direction to thereby fit the fitting protrusions 261g in different recesses 263d. Thus, the ratio of the two kinds of contents to be dispensed can be changed.
With the above configuration in which the fitting protrusions 261g are fitted in the recesses 263d, the user can easily see that the adjusting member 261 has been adjusted to an intended angular position. Further, the adjusting member 261 is prevented from shifting out of the angular position contrary to the intention of the user.
While the present disclosure has been described with reference to the drawings and examples, it is to be noted that various modifications and revisions may be implemented by those skilled in the art based on the present disclosure. Therefore, such changes and modifications are to be understood as included within the scope of this disclosure. For example, functions or the like included in each component can be rearranged without logical inconsistency, and a plurality of components can be combined together or divided. These are construed as being encompassed in the scope of the present disclosure.
For example, although in the first through the third embodiment, the container bodies 10 are laminated peelable containers (double containers), the present disclosure is not limited to these embodiments, and the container bodies 10 do not necessarily need to have double container configurations. For example, as the container bodies 10, high viscosity pump dispenser (HVD) containers having bottom portions provided with middle plates may be employed in place of double containers.
Further, although in the first through the third embodiment the adjusting members 61, 161, 261 are configured to indirectly press the stems 42 via the nozzle portions 50, 150 (mounting members 51, 151), the present disclosure is not limited to these embodiments, and the adjusting members 61, 161, 261 may be configured to directly press the stems 42.
Moreover, although in the first through the third embodiment the dispensing caps 20, 120, 220 are made of polypropylene or polyethylene, the present disclosure is not limited to these embodiments, and the dispensing caps 20, 120, 220 may be made of other synthetic resin materials.
Moreover, although in the first through the third embodiment the outer layer body 18 of each container body 10 is made of polyethylene resin or polyethylene terephthalate, the present disclosure is not limited to these embodiments, and it is only necessary that the outer layer body 18 and the inner layer body 17 have low compatibility with each other, and a material for the outer layer body 18 and a material for the inner layer body 17 can be changed in various ways.
Moreover, although in the first through the third embodiment the container bodies 10 are configured to be formed by extrusion blow molding, the present disclosure is not limited to these embodiments, and the container bodies 10 may be formed by biaxial stretch blow molding.
Moreover, each nozzle portion 50 in the first embodiment is configured to be provided, in the upper end portion thereof on the side adjacent to the axis OH extending in the substantially horizontal direction in the plan view, with the recess 51f that is recessed downward. In the second and the third embodiment also, recesses may be formed in upper end portions on the side adjacent to the axis OH extending in the substantially horizontal direction in the plan views.
Further, although the pipe P are fitted inside the second reduced-diameter portions 16f of the containing tubular portions 16 only in the second embodiment, pipes P may be provided in the dispensing containers 100, 300 according to the first and the third embodiment. In a case in which the container bodies 10 are double containers or HVD containers, pipes P are not essential components and may or may not be provided. In a case in which the container bodies 10 are normal containers that are neither double containers nor HVD containers, pipes P are preferably provided, although this is not essential.
In the first and the second embodiment, the pressing heads 63, 163 are configured to cover the adjusting members 61, 161 from above, the present disclosure is not limited to these embodiments. For example, the adjusting members 61, 161 may be mounted on upper surfaces of the pressing heads 63, 163 so as to be relatively rotatable, and the pressing portions 61b, 161b of the adjusting members 61, 161 may be configured to extend downward through openings provided in the pressing heads 63, 163 so as to be capable of pressing the mounting members 51, 151 or the like.
Further, although in the first through the third embodiment each of the adjusting members 61, 161, 261 is configured to press each stem 42 by the corresponding pressing portion 61b, 161b, 261b via the corresponding mounting member 51, 151, the present disclosure is not limited to these embodiments. The adjusting members 61, 161, 261 may be configured so that each stem 42 is pressed by a plurality of pressing portions 61b, 161b, 261b.
10 Container body
11 Mouth
11
a Male screw portion
12 Shoulder
13 Trunk
14 Reduced-diameter portion
15 Bottom
16 Containing tubular portion
16
a Tubular portion
16
b Flange portion
16
c Upper outer wall
16
d Stepped portion
16
e First reduced-diameter portion
16
f Second reduced-diameter portion
17 Inner layer body
18 Outer layer body
19 Inner plug member
19
a Inner plug
19
b Circumferential wall
20 Dispensing cap
21 Outer circumferential wall
21
a Female screw portion
22 Upper circumferential wall
22
a Stepped portion
22
b Outer circumferential rib
23 Top wall
23
a Fitting tube
23
b Communication hole
30 Pump
31 Lower assembly
33 Cylinder
33
a Tubular-shaped portion
33
b Flange portion
33
c Stepped portion
33
d Fitting tube
33
e Draw valve seat
34 Second locking member
35 Draw valve member
35
a Support frame
35
b Upper wall
35
c Draw valve
35
d Support member
41 Upper assembly
42 Stem
42
a Coupling tubular portion
42
b Stepped portion
42
c Large-diameter portion
43 Annular piston
43
a Outer wall
43
b Inner wall upper end portion
43
c Inner wall lower end portion
44 Piston guide
44
a Guide body
44
c Discharge valve hole
44
d Discharge valve seat
44
e Lower end portion
46 First locking member
49 Urging spring
50 Nozzle portion
51 Mounting member
51
a Perpendicular tubular portion
51
b Ceiling wall
51
c Circumferential wall
51
d Horizontal tubular portion
51
e Pressure-receiving portion
51
f Recess
52 Dispensing port member
52
a Fitting tubular portion
52
b Dispensing port tubular portion
52
c Dispensing port
60 Head portion
61 Adjusting member
61
b Pressing portion
61
d Rotating hole
61
e Arm portion
61
f Operation lever
61
g Abutment portion
63 Pressing head
63
a Pressing plate
63
b Rotation shaft
63
c Rotation shaft
63
h Through hole
70 Outer container
71 Side wall portion
72 Bottom portion
73 Positioning wall
80 Coupling member
82 Upper wall
83 Upper tubular wall
84 Side wall portion
84
a Inner rib
85 Partition wall
90 Lid
91 Outer circumferential wall
92 Upper wall
100, 200, 300 Dispensing container
120 Dispensing cap
121 Inner circumferential wall
121
a Female screw portion
123 Top wall
123
b Communication hole
125 Outer circumferential wall
127 Upper circumferential wall
150 Nozzle portion
151 Mounting member
151
a Vertical tubular portion
151
d Horizontal tubular portion
151
e Pressure-receiving portion
152 Dispensing port member
152
a Fitting tubular portion
152
b Dispensing port tubular portion
152
c Dispensing port
153 Flexible tube
160 Head portion
161 Adjusting member
161
b Pressing portion
161
d Rotation shaft
163 Pressing head
163
a Pressing plate
163
b Rotating hole
163
c Hinge portion
165 Tab
220 Dispensing cap
221 Circumferential wall
221
a Female screw portion
223 Top wall
223
b Communication hole
227 Upper circumferential wall
227
a Engagement protrusion
260 Head portion
261 Adjusting member
261
b Pressing portion
261
d Rotation shaft
261
e Arm portion
261
f Operation portion
261
g Fitting protrusion
263 Pressing head
263
a Positioning arm
263
b Rotating hole
263
c Rotation shaft
263
d Recess
O Axis
OH Axis extending in substantially horizontal direction
OV Axis extending in substantially vertical direction
S Containing space
Number | Date | Country | Kind |
---|---|---|---|
JP2018-205392 | Oct 2018 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2019/042867 | 10/31/2019 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/090993 | 5/7/2020 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5848732 | Brugger | Dec 1998 | A |
6464107 | Brugger | Oct 2002 | B1 |
7222752 | Ponton | May 2007 | B2 |
7240808 | Brugger | Jul 2007 | B2 |
9550199 | Burrowes | Jan 2017 | B2 |
10583450 | Brugger | Mar 2020 | B2 |
10584023 | Beyda | Mar 2020 | B2 |
20040251274 | Ponton | Dec 2004 | A1 |
Number | Date | Country |
---|---|---|
2002-522187 | Jul 2002 | JP |
2003-034374 | Feb 2003 | JP |
3651773 | May 2005 | JP |
2010-005537 | Jan 2010 | JP |
2012029272 | Mar 2012 | WO |
Entry |
---|
Dec. 3, 2019 International Search Report issued in International Patent Application No. PCT/JP2019/042867. |
May 6, 2021 Office Action issued in Taiwanese Patent Application No. 108139581. |
Number | Date | Country | |
---|---|---|---|
20210354156 A1 | Nov 2021 | US |