JP5470069B2 - Discharge container - Google Patents

Description

  The present invention relates to a discharge container for discharging contents to the outside.

2. Description of the Related Art Conventionally, in a container in which liquid contents are stored, a container provided with an open / close mechanism using a manual valve body is known in order to prevent the contents from spilling when the container falls (see Patent Document 1). ).
In this container, the discharge port (spout port) and the air hole are simultaneously sealed from the same direction by the urging force of the spring acting in the same direction, and the button using the air hole is pressed against the urging of the spring. In addition, an opening / closing mechanism is provided in which the discharge port and the air hole are simultaneously opened to discharge the contents.

Utility Model Registration No. 3078012

  However, in the case of the container having the opening / closing mechanism, it is necessary to perform a manual opening / closing operation such as pressing a button every time the contents are discharged. Therefore, an open / close structure that does not require such an operation has been desired.

  This invention is made | formed in view of such a situation, The objective is to provide the discharge container which can discharge the content easily, without performing special operation.

In order to achieve the above object, the present invention provides the following means.
(1) A discharge container according to the present invention includes a container body in which contents are stored, a top wall part that closes a mouth of the container body, and projects upward from the top wall part. A cylindrical push-up portion communicating with the inside of the container body through an opening formed in the top wall portion, and a cap body attached to the mouth portion of the container body , and a ceiling wall in which an outflow opening is formed A discharge passage mounted on the cap body so as to be movable up and down, and a peripheral wall that surrounds the push-up portion from the radially outer side. superimposed the outflow opening in the top wall portion on to cover from above, and a sealed film top wall portion outer peripheral edge portion along a circumferential direction, located radially outside the outlet opening, said push-up A notch that communicates the inside of the push-up portion with the communication path There is formed, the push-up unit, a storage position to remain within the peripheral wall with the vertical movement of the discharge head, and a push-up position for pushing up the film beyond the outlet opening, to be capable of switching, the film A non-seal part in which the seal is partially released is formed in the outer peripheral edge part, and a discharge port for discharging the contents flowing out from the outflow opening between the non-seal part and the top wall part. It is characterized by being defined.

In the discharge container according to the present invention, when discharging the contents, the container body is tilted in a state where the push-up part is located at the storage position where it remains in the peripheral wall part. Thereby, the contents flow into the outflow opening from the container through the communication path. The contents flow out from the outflow opening while pushing up the film onto the top wall. Then, the film is pressed and deformed in a direction away from the top wall by its own weight, and swells into a dome shape that protrudes upward. Thereby, the clearance gap between a ceiling wall part and a film becomes a discharge path connected with a discharge outlet. Accordingly, the contents flowing out from the outflow opening can be guided to the discharge port through this discharge path and discharged from the discharge port to the outside.
When the container body is returned to a posture in which the weight of the contents is not applied to the film after the discharge is completed, the pressing force applied to the film is released, and the film that has been deformed into a dome shape returns to the original state. In close contact with the top wall. Therefore, the outflow opening is closed again by the film and the discharge port is closed. Thereby, the sealing property of a container body is securable.

  Thus, according to the discharge container according to the present invention, since the discharge can be performed by a simple method of tilting the container body and deforming the film by the weight of the contents, the discharge operation can be easily performed without performing a special operation. It is easy to use.

Moreover, even when the remaining amount of the content is reduced, the remaining content can be discharged smoothly, and it is easy to use up without leaving the content wastefully. That is, when the remaining amount of the contents decreases, it is difficult to push up the film by its own weight even if the container body is tilted.
Therefore, the ejection head is moved up and down to shift the position of the push-up portion to the push-up position. Thereby, the push-up part pushes up the film mechanically beyond the outflow opening. Therefore, the film swells in a dome shape that protrudes upward and moves away from the top wall. Therefore, by tilting the container body in this state, the contents can flow from the outflow opening to the discharge path, and can be discharged from the discharge port to the outside through the discharge path.
As a result, even if the content becomes small, it can be discharged smoothly, and it is easy to use up without leaving the content.

(2) The discharge container according to the present invention is the discharge container according to the present invention, wherein a fitting portion into which the push-up portion is detachably fitted is formed in the peripheral wall portion, and the push-up portion includes the fitting portion. The engaging portion that shuts off the outflow opening and the container body is formed by being inserted into the container, and the storage position is the blocking position where the engaging portion of the push-up portion is inserted into the fitting portion. And a release position where the engaging portion is detached from the insertion portion, and can be switched to the blocking position, the release position, and the push-up position by the vertical movement of the discharge head, In the release position and the push-up position, the outflow opening communicates with the container body.

In the discharge container according to the present invention, when not in use, the push-up portion can be positioned at the blocking position within the peripheral wall portion by the vertical movement of the discharge head. That is, the engaging portion of the push-up portion can be fitted into the fitting portion to block between the container body and the outflow opening. Thereby, even if the container body is tilted, the contents flow from the container body into the communication path in the peripheral wall portion, but remain in the communication path. Therefore, the contents do not flow to the outflow opening side at the stage of distribution, sales display, storage, or the like.
Further, when discharging the contents, the discharge head is moved up and down from the above state, and the position of the push-up portion is positioned at the release position where the engaging portion is disengaged from the insertion portion. Thereby, the contents can be flowed to the outflow opening by tilting the container body, and the contents can be discharged. When the content becomes small, the position of the push-up portion may be shifted to the push-up position by the vertical movement of the discharge head.
In particular, by switching the position of the push-up portion, the flow of the contents to the outflow opening can be controlled, so that it is easy to prevent the contents from leaking out.

(3) In the discharge container of the present invention, the discharge container according to the present invention moves to the push-up position by lowering the discharge head with respect to the blocking position, and the release by lifting the discharge head. It is characterized by shifting to a position.

  In the discharge container according to the present invention, the push-up portion moves to the push-up position by lowering the discharge head with respect to the shut-off position, and the push-up portion moves to the release position by raising the discharge head relative to the shut-off position. . That is, when the push-up portion is moved from the blocking position to the release position or the push-up position, it is necessary to move the ejection head in the reverse direction. Therefore, when the position of the push-up portion is shifted from the blocking position to the release position or the push-up position, the switching operation can be clearly distinguished, and the place to be the release position may be mistakenly moved to the push-up position. It is difficult to switch the reverse.

(4) The discharge container according to the present invention is the discharge container according to the present invention, wherein the movement of the discharge head is restricted between the cap body and the discharge head, and the position of the push-up portion is set to the storage position. The position restricting member to be positioned is connected to be breakable, and the ejection head is allowed to move so that the push-up portion reaches the push-up position after the position restricting member is broken.

In the discharge container according to the present invention, since the movement of the vertical movement of the discharge head is restricted by the position restriction member, the position of the push-up portion can be set only at the storage position unless the position restriction member is removed. Therefore, when the content remains sufficiently, the position of the push-up portion is not accidentally placed at the push-up position. Therefore, the film is not pushed up, and the contents are hardly discharged excessively.
When the remaining amount of the contents becomes small, the position regulating member is broken and removed from between the cap body and the ejection head. Thereby, the position of the push-up part can be positioned at the push-up position. Therefore, the remaining small amount of contents can be discharged and used up.

(5) The discharge container according to the present invention is characterized in that, in the discharge container of the present invention, the container body is a laminated peelable container in which an inner layer is peeled from an outer layer.

  In the discharge container according to the present invention, when the contents are discharged, the inner layer of the container body gradually peels off from the outer layer and starts volume-reducing deformation. Therefore, intrusion of outside air into the inside of the container body is suppressed, quality deterioration of the contents can be prevented, and the contents can be discharged smoothly.

  According to the discharge container of the present invention, the contents can be easily discharged without performing a special operation, and it is easy to use. Moreover, even if the content becomes small, it can be discharged smoothly, and it is easy to use up without leaving the content unnecessarily.

It is a figure which shows embodiment of the discharge container which concerns on this invention, Comprising: It is sectional drawing of a discharge container centering on the discharge cap of the state which closed the cover body and covered the discharge head. It is the figure which looked at the discharge container shown in FIG. 1 from the upper part (however, the cover body permeate | transmitted). It is sectional drawing along the AA line shown in FIG. It is sectional drawing along the BB line shown in FIG. It is sectional drawing which shows the state which moved the discharge head upward from the state shown in FIG. 1, and made the top wall part (engagement part) of the plug body detach | leave from the insertion part. FIG. 2 is a cross-sectional view illustrating a state in which, after removing the regulating plate from the state illustrated in FIG. 1, the ejection head is moved downward and the film is pushed up by the stopper. FIG. 4 is a cross-sectional view taken along the line CC shown in FIG. 3. It is sectional drawing which shows the state which inclines the container body from the state shown in FIG. 5, and is discharging the contents.

Hereinafter, embodiments of a discharge container according to the present invention will be described with reference to FIGS. 1 to 8.
As shown in FIGS. 1 to 3, the discharge container 1 according to the present embodiment is mounted on a container body 2 in which a liquid content W (see FIG. 8) is accommodated and a mouth portion 2 a of the container body 2. A discharge cap 3 and a lid 4 that covers the discharge head 20 constituting the discharge cap 3 are provided.

FIG. 1 is a cross-sectional view of the discharge container 1 centering on the discharge cap 3 in a state where the lid 4 is closed and the discharge head 20 is covered. FIG. 2 is a view of the discharge container 1 shown in FIG. 1 as viewed from above. However, the lid 4 is shown in a transparent state. 3 is a cross-sectional view taken along line AA shown in FIG.
Moreover, in this embodiment, let the direction orthogonal to the container axis O of the container body 2 be a radial direction, and let the direction which circulates around the container axis O be the circumferential direction. A direction from the container body 2 toward the discharge cap 3 along the container axis O is an upper side, and a direction toward the bottom side of the container body 2 (not shown) is a lower side.

The container body 2 of this embodiment is a delamination bottle (laminated peelable container) in which the inner layer 5b is detachably laminated with respect to the outer layer 5a, and an annular engagement protrusion 2b is formed on the outer peripheral surface of the mouth portion 2a. ing.
The discharge cap 3 includes a cap body 10 attached to the mouth 2a of the container body 2 and a discharge head 20 attached to the cap body 10 so as to be movable up and down.

  The cap main body 10 is disposed along the inner peripheral surface of the mouth portion 2a and the outer cylinder portion 11 surrounding the mouth portion 2a of the container body 2 from the radially outer side, and the inner cylinder portion fitted into the mouth portion 2a. 12, the upper end of the outer cylinder part 11 and the upper end of the inner cylinder part 12, and a top wall part 13 that closes the opening end of the mouth part 2a, and a guide projecting upward from the top wall part 13 The cylinder 14 and the top cylinder-shaped plug body (push-up part) 15 that are disposed radially inward of the guide cylinder 14 and project upward from the top wall 13 are configured.

On the inner peripheral surface of the outer cylinder portion 11, an annular claw portion 11a that engages with the lower side of the engaging projection 2b on the mouth portion 2a side is formed. Thereby, the cap main body 10 is attached to the mouth portion 2a of the container body 2 by undercut fitting. The claw portions 11a may not be annular, and a plurality of claw portions 11a may be formed at intervals in the circumferential direction.
Further, on the outer peripheral surface on the upper end side of the outer cylinder portion 11, a step portion 11 b is formed in which a lower end of a peripheral wall portion 50 of the lid body 4 described later is fitted. Further, on the outer peripheral surface of the outer cylinder portion 11, a hinge portion 16 for connecting the lid body 4 so as to be openable and closable is formed below the step portion 11b.

  The guide cylinder 14 is a cylinder that guides the vertical movement of the discharge head 20, and is formed at a position eccentric to the radially outer side from the container axis O, specifically, close to the hinge portion 16, and its central axis C is The container axis O is non-coaxial. Further, the opening end of the guide tube 14 is obliquely cut so that the hinge portion 16 side is specifically low and the opposite side across the central axis C is high in accordance with the inclination of the ceiling wall portion 23 described later. .

  Further, a vertically long guide groove 14 a extending along the container axis O is formed on a part of the inner peripheral surface of the guide cylinder 14. As shown in FIG. 4, three guide grooves 14a of the present embodiment are formed every 90 degrees with the central axis C as the center. However, it is not limited to this case. 4 is a cross-sectional view taken along the line BB shown in FIG.

  As shown in FIG. 1, the plug body 15 is formed so that the upper part projects upward from the guide cylinder 14, and the inner side of the plug body 15 is formed through the opening 13 a formed in the top wall part 13. It communicates with the inside. That is, the inside of the plug body 15 functions as a second communication path R <b> 2 that communicates with the inside of the container body 2 when the cap body 10 is attached.

A slit-like cutout groove 15 a is formed along a container axis O in a part of the peripheral surface of the plug body 15, and communicates the inside and the outside of the plug body 15. In the present embodiment, as shown in FIG. 4, a case where three notch grooves 15a are formed at equal intervals in the circumferential direction around the central axis C is taken as an example, but the number is limited to this number. It is not something.
As shown in FIGS. 1 and 4, the top wall portion 13 is formed with notch holes 13 b communicating with the notch grooves 15 a. Therefore, the second communication path R2 is open through the notch groove 15a and the notch hole 13b.

  As shown in FIGS. 1 to 3, the discharge head 20 includes an outer slide cylinder 21 that surrounds the guide cylinder 14 of the cap body 10 from the radially outer side, a guide cylinder 14 that surrounds the guide cylinder 14 from the radially inner side, and a cap of the cap body 10. An inner slide cylinder (peripheral wall part) 22 that surrounds the body 15 from the outside in the radial direction, and the outer slide cylinder 21 and a ceiling wall part 23 that is connected to the upper end of the inner slide cylinder 22 are provided.

  The discharge head 20 is combined with the cap body 10 so that the guide cylinder 14 of the cap body 10 is fitted between the outer slide cylinder 21 and the inner slide cylinder 22, and the guide cylinder 14 guides the discharge head 20. It is possible to move up and down. At this time, as shown in FIG. 4, three vertical ribs 22 a are formed on the outer peripheral surface of the inner slide cylinder 22 so as to be able to move up and down in guide grooves 14 a formed on the cap body 10 side. Thereby, the ejection head 20 is combined with the cap body 10 in a state in which the rotation in the circumferential direction is restricted, and moves up and down without rotating.

When the discharge head 20 is combined with the cap body 10, the plug body 15 of the cap body 10 is disposed in the inner slide cylinder 22 as shown in FIGS. 1 to 3. Further, the inside of the inner slide cylinder 22 communicates with an outflow opening 24 formed in the top wall portion 23 and functions as a first communication path (communication path) R1 communicating with the outflow opening 24.
Thus, the first communication path R1 and the second communication path R2 can communicate with each other through the notch groove 15a and the notch hole 13b.

Further, the inner slide cylinder 22 of the present embodiment is formed with a partition wall 25 in which an insertion hole (insertion portion) 25a into which an engagement portion (top wall portion) 15b of the plug body 15 is detachably inserted is formed. Yes.
That is, in the initial state in which the discharge head 20 is combined with the cap body 10 as described above, the insertion hole 25a is configured so that the engagement portion 15b of the plug body 15 blocks communication between the outflow opening 24 and the inside of the container body 2. Is inserted.

Here, the plug body 15 is switched to relatively move to three positions as the ejection head 20 moves up and down.
That is, as shown in FIGS. 1 and 3, a blocking position where the engaging portion 15 b of the plug 15 is inserted into the insertion hole 25 a and the communication between the outflow opening 24 and the inside of the container body 2 is blocked, and FIG. As shown in FIG. 6, a release position where the engaging portion 15b is detached from the insertion hole 25a to release the blocking, and as shown in FIG. 6, the plug body 15 pushes up the film 40 described later over the outflow opening 24. The position is switched to three positions.

Note that the plug body 15 remains in the inner slide cylinder 22 regardless of whether the plug body 15 is located at the blocking position or the release position. Therefore, the blocking position and the release position are included in the storage position where the plug body 15 stays in the inner slide cylinder 22.
In addition, when the plug 15 is located at the release position, the first communication path R1 and the outflow opening 24 are in direct communication. Therefore, the contents W flow from the inside of the container body 2 to the first communication path R1 via the second communication path R2 and then to the outflow opening 24. In addition, when the plug 15 is located at the push-up position, the second communication path R2 and the outflow opening 24 communicate directly. Accordingly, the content W flows from the inside of the container body 2 to the outflow opening 24 through the second communication path R2.

  Note that the plug body 15 is switched to the release position as shown in FIG. 5 by moving the discharge head 20 upward from the state in which the plug body 15 is in the blocking position (the state shown in FIGS. 1 and 3). It has become. Further, by moving the discharge head 20 downward from the state in which the plug 15 is located at the blocking position (the state shown in FIGS. 1 and 3), the plug 15 is switched to the pushed-up position as shown in FIG. It has become.

  Further, as shown in FIGS. 1, 3 and 5, the notch groove 15 a formed in the plug body 15 is connected to the first communication passage R <b> 1 and the first communication path R <b> 1 when the plug body 15 is positioned at the blocking position or the release position. As shown in FIG. 6, the two communication passages R <b> 2 are communicated with each other, and when the plug body 15 is located at the pushed-up position, the second communication path R <b> 2 and the outflow opening 24 are communicated with each other. It is formed in a vertically long shape extending up to the vicinity of the upper part.

  Meanwhile, as shown in FIGS. 1, 3, 5, and 6, an annular claw portion 21a is formed on the inner peripheral surface of the outer slide cylinder 21 so as to protrude inward. On the other hand, on the outer peripheral surface of the guide tube 14 of the cap body 10, when the plug body 15 is located at the blocking position, the release position or the push-up position, the annular grooves 14b into which the claw portions 21a are respectively fitted are divided into three stages. Is formed. As a result, the ejection head 20 can be positioned after moving up and down, and the plug 15 can be kept in the blocking position, the release position, or the push-up position.

Moreover, in this embodiment, as shown in FIG.1, FIG3 and FIG.7, on the top wall part 13 of the cap main body 10, the strip | belt-shaped control board (position control member) 30 is connected so that fracture | rupture is possible. Yes. FIG. 7 is a cross-sectional view taken along the line CC shown in FIG.
The restriction plate 30 is in a ring shape so as to surround the guide tube 14 from the outside in the radial direction, and is connected to the top wall portion 13 via a weakened portion 31 such as a thin-walled portion. A knob 30a is formed at one end of the restriction plate 30, and the restriction plate 30 can be easily broken and removed (separated) from the top wall 13 using the knob 30a. .

  The ejection head 20 described above is combined with the cap body 10 in a state where the ejection head 20 overlaps the restriction plate 30 as shown in FIGS. 1 and 3. Thereby, unless the restricting plate 30 is removed, the discharge head 20 is restricted from moving downward from the state shown in FIGS. 1 and 3 so that the position of the plug body 15 is switched only to either the blocking position or the release position. Is positioned. That is, the ejection head 20 is allowed to move downward so that the plug 15 reaches the pushed-up position as shown in FIG. 6 after the restriction plate 30 is removed.

By the way, as shown in FIGS. 1 to 3, the top wall portion 23 of the ejection head 20 is formed in a concave curved surface shape and is inclined with respect to the container axis O.
Specifically, first, the top wall portion 23 is formed so as to close the upper ends of the outer slide cylinder 21 and the inner slide cylinder 22. At this time, one side of the top wall portion 23 (the side opposite to the hinge portion 16 across the central axis C) is formed so as to protrude radially outward. Hereinafter, the protruding side is referred to as a distal end portion 23a of the top wall portion 23, and the opposite side (hinge portion 16 side) of the distal end portion 23a across the central axis C is referred to as a proximal end portion 23b.

  The top end portion 23a of the top wall portion 23 is inclined so as to be positioned above the base end portion 23b. Further, as shown in FIG. 1 and FIG. 3, the top wall portion 23 is viewed from the outside along the orthogonal direction L2 orthogonal to the inclination direction L1 connecting the distal end portion 23a and the base end portion 23b on the top wall portion 23. It is formed in a concave curved surface shape so as to become deeper gradually toward the inner side. The outflow opening 24 is formed so as to be positioned at the deepest portion of the top wall portion 23.

Further, as shown in FIGS. 1 to 3, a cut piece 35 is connected to the ejection head 20 of the present embodiment via a weakening portion 36 that can be broken with respect to the top wall portion 23.
Specifically, the cut piece 35 protrudes radially outward from the distal end portion 23a, which is a portion defining a discharge port 42 to be described later, of the top wall portion 23 through the weakening portion 36. It is connected. The weakened portion 36 is a thin-walled portion with a notch formed in the lower side, and can be easily broken by operating the cut piece 35 to be twisted upward or downward or pulled sideways. It can be done.

  Moreover, a knob 35 a is connected to the cut piece 35. Therefore, it is possible to efficiently transmit the force to the cut piece 35 using the knob 35a, and the weakened portion 36 can be smoothly broken to separate the cut piece 35 from the top wall 23. It has become.

As shown in FIGS. 1 to 3, a film (sheet) 40 is overlaid on the ceiling wall portion 23 configured in this manner so as to cover the outflow opening 24. The film 40 is a film formed from a material that is not easily torn and has elasticity, and covers the entire top wall portion 23. Moreover, the film 40 has a size that extends not only on the top wall 23 but also on the side of the cut piece 35 and covers the entire upper surface of the cut piece 35 before separation.
In addition, as the said film 40, although a general film (it does not have a stretching property) which is hard to tear can also be used, it is preferable to use the film which has a stretching property.

By the way, in the stage before separating the cut piece 35 from the top wall portion 23, the outer peripheral edge portion of the film 40 positioned radially outside the outflow opening 24 extends along the circumferential direction in the top wall portion 23 and the cut piece 35. Are respectively sealed (fixed) to the upper surface (hatching region S shown in FIG. 2). As a sealing method at this time, various methods such as an adhesive and heat welding (fusion, pressure bonding, etc.) may be adopted.
The film 40 separates the cut piece 35 from the top wall 23 and breaks. When attention is paid to the top wall portion 23 after separation, a part of the outer peripheral edge portion of the film 40 is a non-seal portion 41 in which the seal is partially released. The non-seal portion 41 is formed at a broken portion of the film 40.

In this embodiment, the non-seal part 41 is formed in the front-end | tip part 23a of the top wall part 23. FIG. The non-seal part 41 and the top wall part 23 define a discharge port 42 through which the contents W discharged from the outflow opening 24 are discharged.
That is, in this embodiment, before the cut piece 35 is separated from the top wall portion 23, as shown in FIG. 2, the film 40 whose outer peripheral edge portion is sealed along the circumferential direction on the cut piece 35. The discharge port 42 is sealed. Then, by separating the cut piece 35 from the top wall portion 23, the film 40 sealed on the cut piece 35 is broken along with the separation, and the discharge port 42 is formed on the top wall as shown in FIGS. It appears at the tip 23 a of the portion 23.
Further, as described above, the top wall portion 23 is inclined so that the distal end portion 23a is located above the base end portion 23b, and therefore the discharge port 42 is located above the outflow opening 24. It is supposed to be.

As shown in FIGS. 1 to 3, the lid 4 is a member that is detachably attached to the cap body 10 and covers the discharge head 20, and has a cylindrical shape with a peripheral wall portion 50 and a top wall portion 51. Is formed.
The cap body 10 and the peripheral wall portion 50 are connected to the lid body 4 via a hinge portion 16, and the lid body 4 is attached to the cap body 10 by opening and closing around the hinge portion 16. In addition, when the peripheral wall part 50 fits in the step part 11b of the cap main body 10, the cover body 4 is stably attached to the cap main body 10 without rattling or the like.

  Further, in a state where the lid 4 is attached to the cap main body 10, the peripheral wall portion 50 on the opposite side to which the hinge portion 16 is connected across the container shaft O protrudes radially outward. A portion 50a is formed, and this lid portion 50a can be used to easily open and close the lid 4 (in particular, an opening operation).

Further, a cylindrical regulating member 52 is formed on the inner side of the top wall portion 51 so as to protrude downward. For example, when the lid body 4 is attached to the cap main body 10 in a state where the plug body 15 is located at the release position (the state shown in FIG. 5), the regulating member 52 is configured so that the outflow opening 24 is in the radial direction It plays a role of pressing the film 40 against the top wall 23 so as to surround from the outside.
In particular, the lower end portion of the regulating member 52 is curved following the concave curved surface of the top wall portion 23, and is designed to contact the top wall portion 23 over the entire circumference with no gap between the film 40.

Next, the case where the contents W are discharged using the discharge container 1 configured as described above will be described.
First, at the stage of distribution or sales display, as shown in FIGS. 1 to 3, the lid 4 is attached to the cap body 10 so as to cover the discharge head 20. Thereby, the film 40 is protected and dust or the like is hardly attached to the film 40.

  Further, a cut piece 35 is connected to the distal end portion 23 a of the top wall portion 23 via a weakening portion 36, and the discharge port 42 is sealed by the cut piece 35. Moreover, the engaging portion 15b of the plug body 15 of the cap body 10 is located in a position where the engaging portion 15b is fitted into the fitting hole 25a of the discharge head 20 and the space between the outflow opening 24 and the first communication path R1 is blocked. Therefore, even if the container body 2 is tilted, the content W flows into the first communication path R1, but remains in the first communication path R1. Therefore, there is little possibility that the contents W will flow to the outflow opening 24 side.

Next, when discharging the contents W, first, the lid body 4 is rotated around the hinge portion 16 using the flange portion 50a to be in the open state, and the discharge head 20 is exposed.
Next, the weakening portion 36 is broken by pulling the knob portion 35 a, and the cut piece 35 is separated from the top wall portion 23. As a result, the discharge port 42 can be unsealed. At the same time or before and after this, as shown in FIG. 5, the discharge head 20 is moved upward to disengage the engaging portion 15b of the plug 15 from the insertion hole 25a, thereby blocking the first communication path R1. Position it at the release position to release. Thereby, the first communication path R1 and the outflow opening 24 are in direct communication with each other.

  When the ejection head 20 is moved upward, the claw portion 21a is fitted into the upper annular groove 14b, so that the ejection head 20 is positioned at this position. Therefore, there is little possibility that the ejection head 20 moves downward when not intended and the communication between the first communication path R1 and the outflow opening 24 is unexpectedly blocked.

After the removal of the cut piece 35 and the upward movement of the ejection head 20 are completed, the container body 2 is tilted so that the tip 23a of the top wall 23 is on the lower side, as shown in FIG. Then, the content W accommodated in the container body 2 flows into the outflow opening 24 after flowing into the first communication path R1 from the second communication path R2. Then, the content W flows out from the outflow opening 24 while pushing up the film 40 onto the top wall portion 23.
Then, the film 40 is pressed in a direction away from the top wall portion 23 by the dead weight of the content W that has flowed out, and reversely deformed, and swells into a dome shape that protrudes upward. As a result, a gap between the top wall portion 23 and the film 40 becomes a discharge path R3 that connects to the discharge port 42. Accordingly, the content W flowing out from the outflow opening 24 can be guided to the discharge port 42 through the discharge path R3 and discharged from the discharge port 42 to the outside.

  Further, when the container body 2 is returned to a posture where the weight of the contents W is not applied to the film 40 after the discharge is finished, the pressing force applied to the film 40 is released, and the film 40 that has been deformed into a dome shape is released. It returns to its original state due to the reverse deformation, and comes into close contact with the top wall 23. Therefore, as shown in FIG. 5, the outflow opening 24 is closed again by the film 40 and the discharge port 42 is closed. Thereby, sealing of the container body 2 is securable.

  Thereafter, when storing or the like, as shown in FIG. 1, the ejection head 20 is moved downward to return to the original state. That is, the ejection head 20 is returned to a state in which the lower end portion of the outer slide cylinder 21 is in contact with the regulation plate 30. Then, since the engaging part 15b of the plug 15 is again inserted into the insertion hole 25a, the first communication path R1 is interrupted on the way. Therefore, the communication between the first communication path R1 and the outflow opening 24 communicated earlier can be blocked. Therefore, even if the container body 2 is tilted accidentally during storage or the like, the content W is less likely to flow to the outflow opening 24 side, and leakage of the content W can be prevented.

  Similarly, when the ejection head 20 is moved downward, the claw portion 21a is fitted into the middle annular groove 14b, so that the ejection head 20 is positioned at this position. Therefore, there is little possibility that the ejection head 20 moves upward when not intended, and the first communication path R1 and the outflow opening 24 communicate unexpectedly.

  Next, the opened lid body 4 is rotated around the hinge and attached to the cap body 10 so as to cover the ejection head 20. At this time, since the peripheral wall portion 50 of the lid body 4 is fitted into the step portion 11b of the cap body 10, the lid body 4 can be attached without rattling. By attaching the lid 4, the film 40 can be protected again, and adhesion of dust and the like to the film 40 can be prevented.

As described above, according to the discharge container 1 of the present embodiment, the container body 2 is tilted, and the discharge can be performed by a simple method by reversing and deforming the film 40 due to the weight of the contents W. Therefore, a special operation is performed. The discharge operation can be easily performed without any problems and is easy to use.
By the way, when the contents W are discharged, the inner layer 5b of the container body 2 starts to be reduced and deformed so that the inner layer 5b gradually peels off from the outer layer 5a. The outer layer 5a is formed with an air hole (not shown) that communicates the inside and outside of the outer layer 5a (for example, at the mouth and bottom), so that the inner layer 5b undergoes volumetric deformation as the contents W are discharged. To do.

  Moreover, even when the remaining amount of the contents W is reduced, the remaining contents W can be discharged smoothly, and the contents W can be used up without being wasted. That is, when the remaining amount of the contents W decreases, it is difficult to push up the film 40 by its own weight even if the container body 2 is tilted.

Therefore, in this case, the restriction plate 30 is first removed from the top wall portion 13 by pulling the knob portion 30a of the restriction plate 30 connected to the top wall portion 13 of the cap body 10 while pulling. Thereby, the downward movement of the ejection head 20 is allowed.
Next, the discharge head 20 is moved downward, and the position of the plug body 15 of the cap body 10 is moved from the blocking position to the pushed-up position, or from the release position to the pushed-up position beyond the blocking position. Thereby, as shown in FIG. 6, the plug 15 mechanically pushes up the film 40 beyond the outflow opening 24 while being fitted into the fitting hole 25a. Therefore, the film 40 swells in a dome shape that is convex upward and is separated from the top wall portion 23.

  In this case, similarly, the claw portion 21a is fitted into the lower annular groove 14b, so that the ejection head 20 is positioned at this position. Therefore, there is little possibility that the ejection head 20 moves upward and the film 40 is lifted up unexpectedly.

When the container body 2 is tilted in this state, the content W flows directly into the outflow opening 24 from the second communication path R2 through the notch groove 15a. At this time, since the film 40 has already swelled in a dome shape, the contents W can be flowed to the discharge path R3 and can be discharged from the discharge port 42 to the outside through the discharge path R3.
As a result, even a small amount of contents W can be discharged smoothly, and the contents W can be used up easily without leaving them.

Furthermore, according to the discharge container 1 of this embodiment, there can exist the following effects.
That is, at the stage of distribution or sales display, the cut piece 35 is connected to the top wall portion 23 and the discharge port 42 is sealed. Even if the position 15 is located at the release position, the contents W are not discharged by the inclination of the container body 2. Therefore, the leakage of the contents W can be reliably prevented at the stage before use.
Further, when the cut piece 35 is separated from the top wall portion 23, the force can be efficiently transmitted to the cut piece 35 using the knob 35a, so that the weakened portion 36 can be broken smoothly. Therefore, it becomes easy to separate the cut piece 35 along the weakened portion 36.

  In addition, since the movement of the vertical movement of the ejection head 20 is partially restricted by the restriction plate 30 during use, unless the restriction plate 30 is removed, the position of the plug body 15 is set to only the blocking position or the release position. Can not do it. Therefore, when the content W remains sufficiently, the position of the plug body 15 is not mistakenly moved to the pushed-up position. Therefore, the film 40 is not pushed up by the plug body 15, and the content W can be prevented from being excessively discharged.

Further, the top wall portion 23 of the present embodiment is inclined so that the distal end portion 23a is located above the base end portion 23b and the discharge port 42 is located above the outflow opening 24. Therefore, when the container body 2 is returned to its original state after the discharge of the contents W, the contents W remaining in the discharge path R3 naturally use the inclination of the top wall portion 23 to the outflow opening 24 side. The flow easily returns to the inside of the container body 2 through the outflow opening 24.
Moreover, the top wall portion 23 is not only inclined but also formed in a concave curved surface shape, and an outflow opening 24 is formed in the deepest portion. Therefore, also at this point, the contents W remaining in the discharge passage R3 naturally return to the outflow opening 24 side by using the curvature of the top wall portion 23, and easily flow into the container body 2 through the outflow opening 24. .

  Thus, since the content W easily returns naturally to the outflow opening 24 side, the content W hardly remains in the discharge path R3. Therefore, the film 40 that has been inverted and deformed so as to swell in a dome shape is likely to return to a state in which the film 40 is securely adhered to the top wall portion 23. Therefore, the sealing property of the container body 2 can be improved.

  The technical scope of the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.

  For example, in the above embodiment, a delamination bottle that is a delamination type is adopted as the container body 2, but is not limited to this. For example, a squeeze-deformable container body may be used, and the content W may be allowed to flow out from the outflow opening 24 by the pressure during squeeze. Moreover, a general container body (a blow bottle, a pouch etc.) may be sufficient.

  Moreover, in the said embodiment, when attaching the cap main body 10 to the opening part 2a, you may comprise so that it may mount | wear by screwing instead of undercut fitting. In this case, it is preferable to provide a mechanism for positioning the cap body 10 in the circumferential direction with respect to the mouth portion 2a so that the discharge port 42 faces in a desired direction. As the mechanism, various generally known methods for restricting rotation in the circumferential direction may be employed.

In the above embodiment, when the container body 2 is erected, the top wall portion 23 of the discharge head 20 is formed so as to be inclined. However, the ceiling body 23 extends along a horizontal plane perpendicular to the container axis O. The wall portion 23 may be formed. Moreover, in the said embodiment, although the ceiling wall part 23 was formed so that it might become a concave curved surface shape, you may form so that it may become a flat flat surface.
In either case, the same effects can be achieved. In addition, when the top wall portion 23 is formed flat, a stretchable film is adopted. However, when the concave wall shape is formed as in the above embodiment, the film 40 can be inverted and deformed. Therefore, a general film having no stretchability can also be adopted. By adopting a stretchable film, when the container body 2 is tilted, the film can be elastically deformed so as to be separated from the top wall portion 23 by the weight of the contents W, and the film is convex upward. The discharge path R3 can be reliably formed in a dome shape that swells.

  In this manner, the material of the film is appropriately changed in accordance with the shape of the top wall portion 23, and various deformations such as reverse deformation and elastic deformation are caused by the weight of the contents W, and the discharge path R3 connected to the discharge port 42 is provided. Just make sure it is defined.

Moreover, in the said embodiment, although it was set as the structure which connected the cutting piece 35 to the front-end | tip part 23a of the top wall part 23 via the weakening part 36, this cutting piece 35 is not essential and does not need to provide. .
Moreover, in the said embodiment, although it was set as the structure which connected the control board 30 on the top wall part 13 so that fracture | rupture was possible, this control board 30 is not essential and does not need to provide. However, it is preferable to provide it because the downward movement of the discharge head 20 can be restricted and the film 40 can be reliably prevented from being pushed up by the plug 15 when the content W remains sufficiently.
Although the regulation plate 30 is connected to the top wall portion 13 of the cap main body 10, it may be connected to the lower end portion of the outer slide cylinder 21 of the ejection head 20 so as to be breakable. Even in this case, unless the restricting plate 30 is removed, the position of the plug body 15 cannot be positioned in the pushed-up position, so that the same effect can be obtained.
In any case, the restriction plate 30 may be connected to the cap body 10 and the ejection head 20 so as to be ruptured. It should be noted that the restricting plate 30 may be configured separately from the cap main body 10 and the ejection head 20 so as to be detachably mounted between the cap main body 10 and the ejection head 20 instead of being connected in a breakable manner. I do not care.

In the above embodiment, the inner slide cylinder 22 is provided with the partition wall 25 in which the insertion hole 25a is formed. As the ejection head 20 moves up and down, the plug body 15 is positioned at the blocking position, the release position, or the push-up position. Although it is configured to switch to one position, it may be configured as follows.
That is, the inner slide cylinder 22 is not provided with the partition wall 25, and as the ejection head 20 moves up and down, the film 40 is pushed up beyond the storage position where the stopper 15 stays in the inner slide cylinder 22 and the outflow opening 24. You may comprise so that it may switch to two positions of a pushing-up position. That is, the plug 15 is caused to function as a push-up unit that simply pushes up the film 40.

  Even when configured in this way, when the contents W are sufficient, the contents W can be discharged by inclining the container body 2 while the stopper body 15 is positioned at the storage position. When the remaining amount of the contents W decreases, the remaining contents W can be discharged by tilting the container body 2 after the stopper body 15 is positioned in the pushed-up position.

Moreover, in the said embodiment, as an example of the pushing-up part which pushes up the film 40, the capped tubular plug 15 was mentioned as an example, but it is not limited to a capped tubular shape, and is a cylinder formed in a cylindrical shape. Alternatively, a solid bar member or the like may be used as the push-up unit.
The top wall portion of the plug body 15 is used as an engaging portion that is fitted into the fitting hole 25. However, the present invention is not limited to this case. For example, when a solid bar-like member is used as the push-up portion, it is partially A portion with an enlarged diameter may be used as an engaging portion, or a groove (concave portion) may be formed in a part of a pair of rods having the same diameter, and this groove may be used as a communication path.

Moreover, in the said embodiment, it switches to a cancellation | release position by moving the discharge head 20 upward from the state which the plug body 15 is located in the interruption | blocking position, and switches to a pushing-up position by moving the discharge head 20 downward from the interruption | blocking position. Although configured, it is not limited to this case. For example, the discharge head 20 may be switched from the blocking position to the release position, and the discharge head 20 may be further moved downward to switch to the push-up position.
In any case, as the ejection head 20 moves up and down, the position of the plug body 15 may be switched to three positions: a blocking position, a release position, and a push-up position.

  In the above embodiment, the discharge head 20 has the outer slide cylinder 21 and the inner slide cylinder 22. However, if the sealing performance can be ensured between the cap cylinder 10 and the guide cylinder 14, only one of the slide cylinders can be used. The discharge head 20 may be configured.

W ... Contents R1 ... First communication path (communication path)
R2 ... 2nd communicating path 2 ... Container body 2a ... Mouth part 4 ... Lid body 5a ... Outer layer of container body 5b ... Inner layer of container body 10 ... Cap body 15 ... Plug body (push-up part)
15b ... engaging portion 20 ... discharge head 22 ... inner slide cylinder (periphery wall portion of cap body)
23 ... Top wall part 24 ... Outflow opening 25a ... Insertion hole (insertion part)
30 ... Restriction plate (position restriction member)
35 ... Cut-off piece 36 ... Weakened part 40 ... Film 41 ... Non-seal part 42 ... Discharge port 52 ... Lid restriction member

Claims (5)

A container containing the contents;
A top wall portion that closes the mouth portion of the container body, and a cylindrical push-up that protrudes upward from the top wall portion and that communicates with the inside of the container body through an opening formed in the top wall portion. It includes a part, and a cap body attached to the mouth portion of the container body,
A ceiling wall portion in which an outflow opening is formed, and a communication passage that communicates with the outflow opening on the inside, and a peripheral wall portion that surrounds the push-up portion from the radially outer side, and is movable up and down with respect to the cap body Mounted ejection head;
A film that is overlaid on the top wall so as to cover the outflow opening from above, and an outer peripheral edge located radially outside the outflow opening is sealed to the top wall along the circumferential direction,
On the peripheral surface of the push-up portion, a notch groove that communicates the inside of the push-up portion and the communication path is formed,
The push-up portion can be switched between a storage position that stays in the peripheral wall portion as the discharge head moves up and down, and a push-up position that pushes up the film beyond the outflow opening,
A non-seal part in which the seal is partially released is formed at the outer peripheral edge of the film, and the contents discharged from the outflow opening are discharged by the non-seal part and the top wall part. A discharge container characterized by defining a discharge port. In the discharge container according to claim 1,
In the peripheral wall portion, an insertion portion into which the push-up portion is detachably inserted is formed,
The push-up portion is formed with an engagement portion that shuts off the outflow opening and the container body by being inserted into the insertion portion.
The storage position includes a blocking position where the engaging portion of the push-up portion is inserted into the insertion portion, and a release position where the engaging portion is detached from the insertion portion,
By the vertical movement of the discharge head, it is possible to switch between the blocking position, the release position, and the push-up position,
In the release position and the pushed-up position, the discharge opening and the container body communicate with each other. The discharge container according to claim 2,
A discharge container that moves to the push-up position by lowering the discharge head and moves to the release position by raising the discharge head with respect to the blocking position. In the discharge container according to any one of claims 1 to 3,
Between the cap body and the ejection head, a position regulating member that restricts the movement of the ejection head and positions the push-up portion at the storage position is connected to be breakable,
The discharge head is allowed to move so that the push-up portion reaches the push-up position after the position regulating member is broken. In the discharge container according to any one of claims 1 to 4,
The discharge container according to claim 1, wherein the container body is a delamination type container in which an inner layer is detachably laminated with respect to an outer layer.

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