JP2018070238A - Discharge container - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily change discharge manners for contents.SOLUTION: A discharge container 1 comprises: a container body 4 comprising an inner container 2 which contains contents and can deform decreasing in volume and an elastically deformable outer container 3 in which the inner container is put; a discharge cap 6 which is mounted at a mouse part 10 of the container body and has a first discharge opening 5 formed to discharge the contents; a coupling cap 7 which is mounted detachably on the discharge cap; and a discharger 8 which is mounted on the coupling cap. The discharger comprises: a cylinder 51; a stem 52 arranged at the cylinder to move down in an upwardly energized state; and a push-down head 55 mounted on an upper end part of the stem and having a second discharge opening 54 formed to discharge the contents, and the coupling cap comprises a communication member 46 linking the inside of the first discharge opening to the inside of a lower-end opening part 51a of the cylinder.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a discharge container.

  Conventionally, for example, as shown in Patent Document 1 below, a container main body in which contents are accommodated, and a dispenser having a stem that is disposed in an upwardly biased state at the mouth of the container main body so as to be movable downward. Discharge containers provided are known.

JP 2000-142766 A

However, in the above-described conventional discharge container, the discharge mode of the contents is largely determined by the specifications of the discharger, so that it is difficult to switch to a different discharge mode.
For example, switching to discharge a larger amount of content than the discharge amount discharged from the discharge device by one discharge operation, or different from the discharge shape (for example, mist shape) of the content discharged from the discharge device It is difficult to switch to discharge the contents in a discharge shape (for example, a linear shape). Therefore, various usages such as switching the discharge mode according to the situation cannot be performed, and there is room for improvement.

  This invention is made | formed in view of such a situation, The objective is to provide the discharge container which can switch the discharge aspect of the content simply.

(1) A discharge container according to the present invention includes a container main body including an inner container capable of reducing volume and containing contents, and an elastically deformable outer container in which the inner container is installed, and the container main body. A discharge cap mounted on the mouth portion and formed with a first discharge port for discharging the contents; a coupling cap detachably mounted on the discharge cap; and a discharger mounted on the coupling cap. The discharger is provided with a cylinder, a stem disposed on the cylinder so as to be movable downward in an upward biased state, and a second discharge port that is attached to an upper end portion of the stem and discharges contents. A pressing head, and the coupling cap includes a communication member that communicates the inside of the first discharge port and the inside of the lower end opening of the cylinder.

According to the discharge container of the present invention, since the first discharge port and the second discharge port are provided, any one of the discharge ports can be arbitrarily selected to discharge the contents.
When the contents are discharged from the first discharge port, the connection cap on which the discharge device is mounted can be detached from the discharge cap to open the first discharge port, and is accommodated in the container body through the first discharge port. The discharged contents can be discharged to the outside. At this time, for example, the container body is tilted or inverted (upside down) so that the mouth of the container body faces downward, or the outer container is squeezed (elastically deformed) radially inward to increase the internal pressure of the inner container. Thus, the contents can be discharged.

When discharging the contents from the second discharge port, the stem is moved downward by pressing the pressing head while the connecting cap is attached to the discharging cap. Thereby, the contents in the cylinder can be discharged to the outside from the second discharge port.
When the pressing operation of the pressing head is released, the stem is restored and moved upward by the upward biasing, so that the pressure in the cylinder becomes negative. Thereby, the contents accommodated in the container main body can be sucked into the cylinder via the first discharge port and the communication tube portion, and can be prepared for the next discharge.

Thus, the contents can be discharged by arbitrarily selecting the first discharge port or the second discharge port. Particularly, since the second discharge port is formed in the pressing head of the discharger, for example, a small amount of contents can be discharged in the form of a mist. On the other hand, the first discharge port is formed in a connecting cap attached to the mouth portion of the container body, so that it is difficult to be restricted by design and discharges contents in a discharge mode different from the second discharge port. Can be made. For example, the opening area of the first discharge port can be made larger than that of the second discharge port, and a larger amount of content can be discharged in a linear (or droplet) form than the second discharge port.
Therefore, by simply selecting the first discharge port or the second discharge port, the discharge mode of the contents can be easily switched. For example, various uses such as optimal discharge suitable for the application can be performed. it can. Therefore, it is possible to provide a discharge container that is easy to use and has improved convenience.

(2) The connection cap may be connected to the discharge cap via a hinge portion and detachable from the discharge cap by rotation around the hinge portion.

  In this case, the detachment operation of the connection cap from the discharge cap and the mounting operation of the connection cap with respect to the discharge cap can be performed by a simple operation by simply rotating the connection cap around the hinge portion. It is possible to smoothly switch the discharge mode of the contents using the two discharge ports.

(3) The connection cap is detachably attached to the first connection cap and the first connection cap connected to the discharge cap via the hinge portion and the discharger. A second connection cap.

  In this case, the second connection cap can be attached to the first connection cap only when the discharger is necessary. Therefore, for example, when the discharge from the first discharge port is mainly selected and used, the second connection cap is used. The connecting cap and the dispenser can be removed. Therefore, the container height can be suppressed and the container can be made compact.

Moreover, while being able to utilize a discharger and a 2nd connection cap as a replacement unit, components other than a discharger and a 2nd connection cap can be used as an exchange unit. Therefore, after the contents have been used up, the use can be continued by attaching the replacement unit to a new replacement unit filled with the contents in the container body.
As described above, since the replacement unit can be used in common and can be continuously used by replacing only the replacement unit, the maintenance cost can be reduced and the convenience can be further improved.

(4) The connection cap may be detachably attached to the discharge cap.

In this case, for example, when mainly selecting and using the discharge from the first discharge port, the entire connecting cap and the discharge device can be removed, so that the container height is further reduced and the size is reduced. Can be achieved.
Also in this case, the entire connection cap and the discharger can be used as a replacement unit, and parts other than the connection cap and the discharger can be used as the replacement unit. In particular, since the number of parts of the replacement unit can be reduced, the maintenance cost can be further reduced.

  According to the discharge container according to the present invention, the discharge mode of the contents can be easily switched, and various uses such as optimal discharge suitable for the application can be performed.

It is a longitudinal section showing a 1st embodiment of a discharge container concerning the present invention. It is the longitudinal cross-sectional view of the discharge container which expanded the periphery of the 1st discharge port shown in FIG. It is the longitudinal cross-sectional view of the discharge container which expanded the periphery of the discharge device shown in FIG. It is a figure which shows the state which is discharging the content from the 1st discharge port after opening the 2nd cap around the hinge part from the state shown in FIG. It is a figure which shows the state which presses down a pressing head from the state shown in FIG. 1, and is discharging the content from the 2nd discharge outlet. It is a longitudinal cross-sectional view which shows 2nd Embodiment of the discharge container which concerns on this invention. It is a longitudinal cross-sectional view of the discharge container which expanded the periphery of the 1st discharge port shown in FIG. It is a figure which shows the state which opened the 2nd cap around the hinge part from the state shown in FIG. It is a longitudinal cross-sectional view which shows 3rd Embodiment of the discharge container which concerns on this invention. It is the longitudinal cross-sectional view of the discharge container which expanded the periphery of the 1st discharge port shown in FIG. FIG. 10 is a diagram illustrating a state in which the lid cap is attached to the hinge cap after the separation cap is removed from the state illustrated in FIG. 9. It is a figure which shows the modification of the discharge container which concerns on this invention, Comprising: It is an expanded sectional view of the locking piece periphery which connects a 1st cap and a 2nd cap.

(First embodiment)
Hereinafter, a first embodiment of a discharge container according to the present invention will be described with reference to the drawings. In each drawing used for the following description, the scale may be changed as appropriate in order to make each member a recognizable size.

As shown in FIG. 1, the discharge container 1 of the present embodiment includes a flexible inner container 2 that accommodates contents (not shown) and can be deformed by deformation (volume reduction deformation), and an inner container 2. A bottomed cylindrical container body 4 having an outer container 3, and a first cap (discharge cap) 6 that is attached to the mouth portion 10 of the container body 4 and has a first discharge port 5 for discharging contents. , A second cap (connection cap) 7 detachably attached to the first cap 6, and a discharger 8 attached to the second cap 7.
In addition, although it does not specifically limit as a content, For example, a cosmetic liquid, liquid foods (a seasoning liquid, soy sauce, vinegar etc.), a washing | cleaning liquid, a chemical | medical solution, etc. are mentioned.

  In the present embodiment, the central axis of the container body 4 is referred to as a container axis O1, the discharger 8 side along the container axis O1 is referred to as the upper side, and the opposite side is referred to as the lower side. Further, in a plan view viewed from the container axis O1 direction, a direction orthogonal to the container axis O1 is referred to as a radial direction, and a direction around the container axis O1 is referred to as a circumferential direction.

The container body 4 is formed by blow molding, for example, a laminated peelable container (Delami bottle) in which the inner container 2 is laminated on the inner surface of the outer container 3 in a peelable manner.
As the blow molding, for example, the container body 4 may be formed by forming a double (internal and external) laminated parison by extrusion molding or the like, and extruding and blow-molding the laminated parison. Further, a preform for the outer container and a preform for the inner container are formed by injection molding or the like, and after these are combined in double (inner and outer), the container body 4 is formed by biaxial stretch blow molding. It doesn't matter.
Furthermore, after forming the outer container preform by biaxial stretching blow molding the outer container 3, the inner container preform is placed inside, and then the inner container preform is biaxial stretching blow molding. By doing so, the container body 4 may be formed.

  The material of the inner container 2 and the outer container 3 is a resin material, and may be the same material or different materials as long as they are detachable combinations. Examples of the resin material include PET (polyethylene terephthalate), PP (polypropylene), PE (polyethylene), nylon (polyamide), EVOH (ethylene-vinyl alcohol copolymer), and the like. Out of these resin materials, the outer container 3 and the inner container 2 are formed in a combination that allows separation.

The container body 4 is formed in a bottomed cylindrical shape in which a mouth portion 10, a shoulder portion 11, a body portion 12, and a bottom portion are continuously provided from the upper side. The bottom is not shown in each drawing.
The outer container 3 can be squeezed (elastically deformed), and the inner container 2 is squeezed and deformed as the outer container 3 is squeezed. Therefore, at least a portion of the outer container 3 located in the body portion 12 can be elastically deformed toward the inside of the container.

  The mouth portion 10 of the container body 4 is configured by laminating the inner container 2 and the outer container 3. In the illustrated example, the mouth portion 10 of the container body 4 includes a lower cylinder portion 13 extending upward from the upper end portion of the shoulder portion 11, and an upper cylinder portion extending upward from the upper end portion of the lower cylinder portion 13. The upper cylinder part 14 formed in the diameter smaller than the part 13 is formed in the two-stage cylinder shape. A first screw portion 15 is formed on the outer peripheral surface of the portion of the upper cylinder portion 14 that constitutes the outer container 3.

  The discharge container 1 of the present embodiment allows air (outside air) to flow into the gap between the inner container 2 and the outer container 3, and from the gap between the inner container 2 and the outer container 3. An air introduction section (not shown) that regulates the outflow of air is provided.

  As shown in FIGS. 1 and 2, the first cap 6 includes a first peripheral wall portion 20 that surrounds the mouth portion 10 of the container body 4 from the outside in the radial direction, and a first upper portion that closes the upper end opening of the first peripheral wall portion 20. The top wall 21 is formed in a cylindrical shape with a top wall 21 and is disposed coaxially with the container axis O1.

A second screw portion 22 is formed on the inner peripheral surface of the first peripheral wall portion 20 to be screwed to the first screw portion 15 formed in the mouth portion 10 of the container body 4. Thereby, the entire first cap 6 is attached to the mouth portion 10 of the container body 4.
However, the mounting method of the 1st cap 6 is not limited to screwing, For example, you may mount | wear to the opening | mouth part 10 of the container main body 4 by the undercut fitting by a stopper.

  The first ceiling wall portion 21 is disposed on the upper end opening edge of the mouth portion 10 of the container body 4 and closes the mouth portion 10 of the container body 4. The first top wall portion 21 is formed with a seal cylinder portion 23 that protrudes downward and fits tightly inside the mouth portion 10 of the container body 4.

The first top wall portion 21 is formed with a discharge cylinder portion 24 that protrudes upward and has the inside serving as the first discharge port 5 penetrating the first top wall portion 21 in the container axis O1 direction. ing.
In the example shown in the figure, the discharge cylinder portion 24 and the first discharge port 5 are formed at positions shifted radially outward with respect to the container axis O1. However, the present invention is not limited to this case, and the discharge cylinder portion 24 and the first discharge port 5 may be formed coaxially with the container axis O1. The central axis of the first discharge port 5 is referred to as a discharge axis O2.

  In the illustrated example, the discharge cylinder portion 24 gradually increases in diameter as it goes upward. At this time, the diameter of the discharge cylinder portion 24 is not increased uniformly over the entire circumference, but the diameter is increased so that a portion located on the hinge portion 37 side described later than the discharge shaft O2 greatly expands radially outward. doing.

Inside the discharge cylinder 24, a suction cylinder 25 extending downward from the discharge cylinder 24 is disposed coaxially with the discharge axis O2.
The suction cylinder portion 25 is formed in a cylindrical shape whose outer diameter is gradually reduced from the upper side to the lower side. The upper end portion of the suction tube portion 25 and the inner peripheral surface of the discharge tube portion 24 are integrally connected in the radial direction by a plurality of connecting ribs 26 arranged at intervals around the discharge shaft O2. Thereby, the suction cylinder part 25 is integrally formed with respect to the discharge cylinder part 24 via the connection rib 26.

  A tube body 27 for sucking up contents is inserted and fitted into the inside of the suction cylinder portion 25 on the lower end side. The tube body 27 extends downward, and its lower end is located near the bottom of the container body 4.

  Thus, since the suction cylinder part 25 is arrange | positioned inside the discharge cylinder part 24, the content passes the 1st discharge port 5 through the clearance gap formed between the connection ribs 26 adjacent to the circumferential direction. It is possible to pass through and the first discharge port 5 can be passed through the inside of the tube body 27 and the suction cylinder part 25.

  As shown in FIGS. 1 to 3, the second cap 7 includes a second peripheral wall portion 30 disposed above the first peripheral wall portion 20, and a support cylinder portion disposed on the radially inner side of the second peripheral wall portion 30. The first cap is formed in a double cylinder shape mainly including an annular flange wall 32 that integrally connects the upper end portion of the second peripheral wall portion 30 and the upper end portion of the support cylinder portion 31 in the radial direction. 6 is disposed coaxially with the container axis O1.

The second peripheral wall portion 30 surrounds the discharge cylinder portion 24 from the outer side in the radial direction and is formed to have a lower peripheral wall portion 35 formed substantially the same diameter as the first peripheral wall portion 20 and an upper end portion of the lower peripheral wall portion 35 upward. And an upper peripheral wall portion 36 extending.
In the illustrated example, the upper peripheral wall portion 36 is formed so as to gradually reduce in diameter as it goes upward from the connection portion with the lower peripheral wall portion 35. However, the shape of the upper peripheral wall portion 36 is not limited to this case, and may be formed in a cylindrical shape having the same diameter over the entire length in the container axis O1 direction.

The lower peripheral wall portion 35 is integrally connected to the first peripheral wall portion 20 via a hinge portion 37 and is detachably fitted to the upper end portion of the first peripheral wall portion 20. Thus, the entire second cap 7 can be rotated around the hinge portion 37, and can be detached from the first cap 6 by this rotation.
At the lower end portion of the lower peripheral wall portion 35, an operation projection piece 38 is formed so as to protrude radially outward from a portion located on the opposite side of the hinge portion 37 across the container shaft O1. Thereby, it is possible to easily perform the rotation operation of the second cap 7 using the operation protrusion 38.

The support tube portion 31 includes a first support tube portion 40 extending downward from the inner peripheral edge of the flange wall 32 and a second support tube portion further extending downward from the lower end portion of the first support tube portion 40. 41, and is disposed coaxially with the container axis O1 above the discharge cylinder portion 24. The support cylinder portion 31 supports the cylinder 51 in a state in which a lower end portion of a cylinder 51 described later of the discharger 8 is accommodated therein.
The second support cylinder part 41 is formed in a cylindrical shape whose diameter is smaller than the inner diameter of the discharge cylinder part 24 and the inner diameter of the annular flange wall 32, and its lower end part slightly enters the discharge cylinder part 24 from above. Yes. The first support cylinder portion 40 is formed in a tapered cross section that gradually decreases in diameter as it goes downward from the inner peripheral edge of the flange wall 32.

  A closing plate 42 that closes the lower end opening of the second support cylinder 41 is integrally formed at the lower end of the second support cylinder 41. A first communicating cylinder portion 43 and a second communicating cylinder portion 44 are formed on the closing plate 42 so as to extend downward.

The first communication cylinder portion 43 is disposed coaxially with the discharge shaft O2 and is inserted into the discharge cylinder portion 24 from above, and a lower end portion thereof is detachably closely fitted inside the discharge cylinder portion 24. Has been.
The second communication tube portion 44 is disposed on the inner side of the first communication tube portion 43 coaxially with the discharge shaft O2, and is inserted into the suction tube portion 25 from above, and its lower end portion is the suction tube portion. It is closely fitted inside 25 so as to be detachable. The inner side of the second communication cylinder part 44 communicates with the inner side of the support cylinder part 31 through a communication hole 45 penetrating the closing plate 42 in the container axis O1 direction.

Thereby, the inside of the 1st discharge port 5 and the inside of the lower end opening part 51a of the cylinder 51 accommodated inside the support cylinder part 31 can be connected through the 2nd communication cylinder part 44, and the tube body 27 and suction The contents passing through the first discharge port 5 through the inside of the cylinder portion 25 can be introduced into the lower end opening 51 a of the cylinder 51.
In addition, the 1st communication cylinder part 43 and the 2nd communication cylinder part 44 detach | leave from the inside of the discharge cylinder part 24 and the inside of the suction cylinder part 25, respectively, with the detachment | leave of the 2nd cap 7 with respect to the 1st cap 6. FIG. Accordingly, the first discharge port 5 can be opened, and the contents can be discharged to the outside through the first discharge port 5.

  Accordingly, the first communication cylinder portion 43 and the second communication cylinder portion 44 communicate with the inside of the first discharge port 5 and the lower end opening 51a of the cylinder 51, and are detachably fitted into the first discharge port 5. The communicating member 46 is configured.

On the inner peripheral edge portion of the flange wall 32, a mounting cylinder portion 47 protruding upward is formed. A third screw portion 48 is formed on the outer peripheral surface of the mounting cylinder portion 47. The discharger 8 is attached to the second cap 7 via the attachment cylinder portion 47.
On the outer peripheral edge portion of the flange wall 32, a finger-hanging piece 49 protruding outward in the radial direction is formed. In the illustrated example, the finger-hanging piece 49 is formed to extend in an arc shape along the circumferential direction. However, it is not limited to this case, and the finger-hanging piece 49 may be formed in an annular shape over the entire circumference of the flange wall 32 or may be formed at intervals in the circumferential direction.

  As shown in FIG. 3, the discharger 8 includes a mounting cap 50 that is mounted on the mounting cylinder portion 47 of the second cap 7, a cylinder 51 and a stem that is disposed in the cylinder 51 so as to be movable downward in an upward biased state. The pump main body 53 which has 52, and the pressing head 55 with which the 2nd discharge port 54 with which the upper end part of the stem 52 was discharged | emitted and formed the discharge was formed was mainly provided.

  The mounting cap 50 includes a surrounding tube portion 60 that surrounds the mounting tube portion 47 from the radially outer side, an outer tube portion 61 that protrudes further upward from the upper end portion of the surrounding tube portion 60, and an upper end portion of the surrounding tube portion 60. An annular flange-shaped outer flange plate 62 extending inward in the radial direction, a holding cylinder portion 63 extending upward from the inner peripheral edge of the outer flange plate 62, and a radial direction from the upper end of the holding cylinder portion 63 An annular plate-like inner flange plate 64 projecting inward and a guide tube portion 65 extending downward from the inner peripheral edge of the inner flange plate 64 are disposed coaxially with the container shaft O1. .

A fourth screw portion 66 that is screwed onto the third screw portion 48 is formed on the inner peripheral surface of the surrounding tube portion 60. As a result, the mounting cap 50 is mounted on the mounting cylinder portion 47.
However, the mounting method of the mounting cap 50 is not limited to screwing. For example, the mounting cap 50 may be mounted on the mounting cylinder portion 47 by undercut fitting. The outer flange plate 62 is disposed on the upper end opening edge of the mounting cylinder portion 47 via an annular packing.

  A metal outer cover 67 is attached to the surrounding cylinder portion 60 by, for example, caulking. The outer cover 67 surrounds the surrounding cylinder part 60 and the outer cylinder part 61 from the radially outer side, and the upper end part is folded back radially inward to further cover the outer cylinder part 61 from above. A portion of the outer cover 67 surrounding the outer cylindrical portion 61 from the radially outer side is formed with an annular engaging groove portion 68 that is recessed toward the radially inner side.

The stem 52 extends through the guide tube portion 65 of the mounting cap 50 and is disposed coaxially with the container shaft O1, and is guided in the container shaft O1 direction by the guide tube portion 65.
The cylinder 51 is formed in a multistage cylindrical shape having a diameter reduced stepwise from the upper side to the lower side, and is arranged coaxially with the container axis O1. The upper end portion of the cylinder 51 is inserted from below between the holding cylinder portion 63 and the guide cylinder portion 65 of the mounting cap 50 and is fitted inside the holding cylinder portion 63. Thereby, the cylinder 51 is combined with the mounting cap 50 integrally.

  The lower end portion side of the cylinder 51 is inserted into the support cylinder portion 31 of the second cap 7 from above and is fitted inside the second support cylinder portion 41 of the support cylinder portion 31. Thereby, the cylinder 51 is accommodated in the support cylinder part 31 in the state supported stably. Accordingly, the entire discharger 8 is stably combined with the second cap 7 with little backlash.

  The lower end of the cylinder 51 is disposed above the closing plate 42 with a gap between the lower end portion and the closing plate 42. Therefore, the lower end opening 51 a of the cylinder 51 opens downward and communicates with the second communication cylinder 44 through a communication hole 45 formed in the closing plate 42.

The pump main body 53 includes a piston 56 disposed inside the cylinder 51 so as to be vertically slidable, a biasing member 57 such as a coil spring that is disposed inside the cylinder 51 and biases the stem 52 upward, Disposed inside the cylinder 51, allows the contents to flow into the cylinder 51 through the lower end opening 51 a of the cylinder 51, and flows out of the contents from the cylinder 51 through the lower end opening 51 a of the cylinder 51. And a ball valve 58 for regulating the above.
A known pump mechanism can be adopted as the pump body 53, and further detailed description is omitted.

  The pressing head 55 includes a top wall portion 70, a fitting cylinder portion 71 that extends downward from the central portion of the top wall portion 70 and is fitted to the upper end portion of the stem 52, and an outer peripheral edge portion of the top wall portion 70. And a head cylinder part 72 that extends downward from the upper cylinder part 61 and is capable of entering from above into an annular space defined between the outer cylinder part 61 and the holding cylinder part 63 of the mounting cap 50.

  A cylindrical nozzle shaft portion 73 projects from the upper end portion of the fitting tube portion 71 toward the radially outer side. A nozzle tip 74 in which the second discharge port 54 is formed is attached to the nozzle shaft portion 73. The second discharge port 54 communicates with the inside of the stem 52 via a spin groove formed in the nozzle tip 74 and a flow passage formed between the nozzle shaft portion 73 and the nozzle tip 74.

The discharge container 1 according to the present embodiment further includes a cap cylinder 75 having a top shape that covers the outer cover 67 and the pressing head 55 of the discharger 8.
On the inner peripheral surface of the peripheral wall portion of the cap body 75, an annular engagement protrusion 76 that protrudes inward in the radial direction and removably fits in an engagement groove portion 68 formed in the outer cover 67 is formed. Has been. Thereby, the cap body 75 is detachably attached to the discharger 8.
The lower end portion of the peripheral wall portion of the cap body 75 is in contact with the flange wall 32 of the second cap 7 from above. Thereby, the cap body 75 is attached to the discharger 8 in a state of being positioned in the container axis O1 direction.

(Action of discharge container)
Next, the case where the contents are discharged using the discharge container 1 configured as described above will be described. Note that the contents of the container body 4 are sucked into the cylinder 51.

  When discharging the contents, it is possible to arbitrarily select either the first discharge port 5 or the second discharge port 54 to discharge the contents.

The case where the contents are discharged from the first discharge port 5 will be described.
In this case, from the state shown in FIG. 1, the second cap 7 to which the discharger 8 is attached is rotated around the hinge portion 37 (opening operation), and the first cap 6 is moved from the first cap 6 to the first as shown in FIG. 2 Remove the cap 7. Accordingly, the first communication cylinder portion 43 can be separated from the discharge cylinder portion 24, and the second communication cylinder portion 44 can be separated from the suction cylinder portion 25. It can be opened.

  After opening the first discharge port 5, the container body 4 is tilted so that the mouth portion 10 of the container body 4 faces downward as shown in FIG. The contents can be discharged to the outside. Specifically, the content that has passed through the gap formed between the connecting ribs 26 adjacent in the circumferential direction of the discharge shaft O2 is discharged from the first discharge port 5 to the outside as indicated by an arrow A shown in FIG. Can be made.

  Also, as indicated by an arrow B shown in FIG. 4, air is caused to flow into the container body 4 using the remaining gaps through which the contents do not pass among the gaps formed between the connecting ribs 26. Therefore, the contents can be discharged while appropriately replacing the air in the container body 4.

  Further, when the contents are discharged from the first discharge port 5, for example, the outer container 3 may be squeezed and deformed inside the container, and the inner container 2 may be deformed and deformed inside the container. In this case, the volume of the inner container 2 is reduced by the deformation of the squeezing, so that the contents can be pushed out from the container body 4 and can be easily discharged efficiently from the first discharge port 5.

Next, a case where contents are discharged from the second discharge port 54 will be described.
In this case, after removing the cap body 75 from the state shown in FIG. 1, the pressing head 55 is pressed down against the urging force of the urging member 57 as shown in FIG. Move. As a result, the contents in the cylinder 51 can be guided into the pressing head 55 through the inside of the stem 52, and the flow path formed between the nozzle shaft portion 73 and the nozzle tip 74 and the nozzle tip 74 can be It can be guided to the second ejection port 54 through the formed spin groove or the like. As a result, the contents in the cylinder 51 can be discharged from the second discharge port 54 to the outside.

  Note that when the pressing head 55 is pressed, the pressing operation can be easily performed by using the finger hanging piece 49. For example, in a state where the discharge container 1 is held with the entire palm, the pressing head 55 can be pressed with the index finger while the thumb and the middle finger are hooked on the finger-hanging piece 49 from below. Thereby, the pressing operation of the pressing head 55 can be performed stably, and the contents discharged from the second discharge port 54 can be discharged as intended.

  When the pressing of the pressing head 55 is released, the upward biasing force (elastic restoring force) by the biasing member 57 causes the piston 56, the stem 52, and the pressing head 55 to move upward and return to the original state. At this time, since the inside of the cylinder 51 becomes negative pressure, the contents in the container main body 4 are sucked into the cylinder 51 from the lower end opening 51a of the cylinder 51 through the tube body 27 and the second communication cylinder portion 44. 51 can be stored. Thereby, it can prepare for discharge of the next content.

  Further, as the contents are sucked from the container body 4 into the cylinder 51, the inner container 2 is formed into a dent shape. Thereby, since a negative pressure is generated between the outer container 3 and the inner container 2, air can be caused to flow into the gap between the inner container 2 and the outer container 3 using the air introduction part. Therefore, only the inner container 2 can be squeezed and deformed while maintaining the shape of the outer container 3.

As described above, according to the discharge container 1 of the present embodiment, the first discharge port 5 or the second discharge port 54 can be arbitrarily selected to discharge the contents.
In particular, when the contents are discharged from the second discharge port 54 formed in the pressing head 55, a small amount of contents can be discharged in a mist form as shown in FIG. On the other hand, since the first discharge port 5 is formed in the second cap 7 attached to the mouth portion 10 of the container main body 4, the first discharge port 5 is not easily restricted by design, and as shown in FIG. The opening area is larger than that of the discharge port 54. Therefore, a larger amount of content than the second discharge port 54 can be discharged from the first discharge port 5 in a linear shape (or a droplet shape).

  Therefore, by simply selecting the first discharge port 5 or the second discharge port 54, the discharge mode (for example, discharge amount, discharge shape, etc.) of the contents can be easily switched, and the optimal discharge according to the application. Can be used in various ways. Therefore, it can be set as the discharge container 1 which was easy to use and improved in convenience.

  In addition, with a simple operation (opening / closing operation) by simply rotating the second cap 7 around the hinge portion 37, the second cap 7 can be detached from the first cap 6, and the second cap 7 can be removed from the first cap 6. Since the mounting operation can be performed, the discharge mode of the contents using the first discharge port 5 and the second discharge port 54 can be switched smoothly.

(Second Embodiment)
Next, a second embodiment of the discharge container according to the present invention will be described with reference to the drawings. In the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

As shown in FIGS. 6 and 7, the discharge container 80 of this embodiment has an intake hole 81 formed in the mouth portion 10 of the container body 4. The intake hole 81 is formed in a portion of the upper cylinder portion 14 constituting the outer container 3, and introduces air (outside air) between the outer container 3 and the inner container 2 via an air introduction hole 85 described later. Let
Furthermore, air grooves 82 extending in the direction of the container axis O1 are formed on the outer peripheral surface of the portion constituting the outer container 3 in the upper cylindrical portion 14 with a gap in the circumferential direction. The air groove 82 is formed so as to be mainly located above the intake hole 81.

  The first cap 6 of the present embodiment is disposed in the first cap 6, and is disposed between the inner cap 90 that closes the mouth portion 10 of the container body 4, and the first cap 6 and the inner plug 90. A discharge valve 110.

The first peripheral wall portion 20 in the first cap 6 extends upward from the mouth portion 10 of the container body 4. Thereby, a certain space is secured in the container axis O1 direction between the first top wall portion 21 and the mouth portion 10 of the container body 4. And the inside plug 90 and the discharge valve 110 are arrange | positioned using this space.
The first peripheral wall portion 20 is closely fitted to the lower tube portion 13 of the container body 4 at the lower end portion. Accordingly, the intake hole 81 is prevented from communicating with the outside of the discharge container 80 through the gap between the first peripheral wall portion 20 and the lower cylinder portion 13.

The first top wall portion 21 is formed in a stepped shape such that the central portion 84 is positioned above the outer peripheral portion 83 connected to the first peripheral wall portion 20.
The discharge cylinder portion 24 is formed so as to penetrate the central portion 84 of the first top wall portion 21 in the container axis O1 direction. Of the stepped portion between the outer peripheral portion 83 and the central portion 84 of the first top wall portion 21, the portion located on the opposite side of the first discharge port 5 in the radial direction across the container axis O <b> 1 is An air introduction hole 85 that communicates the inside and outside of the cap 6 is formed. In the illustrated example, the air introduction hole 85 is formed at one place, but a plurality of air introduction holes 85 may be formed at intervals in the circumferential direction, for example.
A hanging cylinder portion 86 is formed at the central portion 84 of the first top wall portion 21 so as to protrude downward from a portion located radially inward of the air introduction hole 85.

  The inner plug 90 is provided with an annular bottom wall portion 91 whose outer peripheral edge portion is disposed on the upper end opening edge of the mouth portion 10 of the container body 4, and projects downward from the bottom wall portion 91. From the seal cylinder part 92 closely fitted inside the mouth part 10, the outer cylinder part 93 standing upward from the outer peripheral edge part of the bottom wall part 91, and the inner peripheral part of the bottom wall part 91 An inner cylinder portion 94 having a top-like cylindrical shape standing upward, and is disposed coaxially with the container axis O1.

The lower end portion of the outer cylinder portion 93 is formed with an air circulation hole 95 that penetrates the outer cylinder portion 93 in the radial direction and opens downward. The air circulation hole 95 communicates with the intake hole 81 through the air groove 82 described above.
On the bottom wall portion 91, an intermediate tube portion 96 is erected upward from a portion located between the outer tube portion 93 and the inner tube portion 94. A communication hole 97 that penetrates the top wall portion 94a in the container axis O1 direction is formed in the top wall portion 94a of the inner cylinder portion 94. The communication hole 97 communicates the first discharge port 5 and the inside of the container body 4.

In the top wall portion 94a of the inner cylinder portion 94, a housing cylinder portion 100 extending downward is formed at a portion located on the opposite side of the communication hole 97 in the radial direction with respect to the container axis O1.
The housing cylinder portion 100 has a central axis extending in parallel with the container axis O1 and opening up and down. A seating cylinder part 101 that gradually decreases in diameter as it goes downward is formed at the lower end of the accommodation cylinder part 100.

A ball valve 102 that is movable in the direction of the container axis O <b> 1 on the inner peripheral surface of the accommodation cylinder portion 100 is accommodated in the accommodation cylinder portion 100. The ball valve 102 is made of a synthetic resin, is formed in a spherical shape having an outer diameter equivalent to the inner diameter of a portion of the accommodating cylinder portion 100 located above the seating cylinder portion 101, and the inner peripheral surface of the seating cylinder portion 101. It is seated so that it can be separated.
Note that a minute gap is formed between the outer peripheral surface of the ball valve 102 and the inner peripheral surface of the portion of the accommodation tube portion 100 located above the seating tube portion 101.

The ball valve 102 is restricted from being removed upward from the housing cylinder 100 by a valve body 112 described later.
However, the present invention is not limited to this case, and a restricting projection for restricting the ball valve 102 from coming off is formed on the inner peripheral surface of the upper portion of the housing cylinder portion 100 so as to protrude radially inward. It doesn't matter. Even in this case, the ball valve 102 can be prevented from coming off.

The ball valve 102 moves upward when, for example, the container body 4 is tilted or turned upside down to discharge the contents, and when the container body 4 is returned to the original upright posture, It moves to the seating cylinder part 101 side by the negative pressure generated by the restoring force.
As a result, when the contents are discharged from the first discharge port 5, the residual content existing in the first discharge port 5 can be drawn into the housing cylinder part 100, and the dripping is avoided by the so-called suck back effect. It is possible to do.

  The discharge valve 110 has a valve body cylinder 111 disposed between the bottom wall portion 91 of the inner plug 90 and the first top wall portion 21 of the first cap 6, and a top wall portion 94 a of the inner cylinder portion 94. It has a valve body 112 that closes the communication hole 97 by sitting from above, and an elastic connection piece 113 that connects the valve body 112 and the valve body cylinder 111 and elastically supports the valve body 112.

  The valve cylinder 111 has an upper end fitted inside the hanging cylinder 86 and a lower end fitted between the inner cylinder 94 and the middle cylinder 96. As a result, the inside of the valve body cylinder 111 functions as a communication passage 114 that allows communication between the first discharge port 5 and the communication hole 97.

The valve body 112 is formed in a disk shape in plan view that is disposed coaxially with the container axis O <b> 1 and is disposed inside the valve body cylinder 111 to close the communication hole 97.
The elastic connecting piece 113 extends along the circumferential direction, has an inner end connected to the outer peripheral edge of the valve body 112, and an outer end connected to the inner peripheral surface of the valve body cylinder 111.
In the illustrated example, three elastic connecting pieces 113 are formed at intervals in the circumferential direction. Thus, the discharge valve 110 is a so-called three-point valve in which the valve body 112 is elastically supported by the three elastic connecting pieces 113.

  The elastic connecting piece 113 is elastically deformed in the direction of the container axis O1 in accordance with, for example, the internal pressure fluctuation of the inner container 2 or the pressure of the discharged contents, and the valve body 112 is removed from the top wall part 94a of the inner cylinder part 94. It is elastically supported so that it can move upward. Accordingly, the valve body 112 can be elastically displaced in the container axis O1 direction with respect to the inner plug 90, and the communication hole 97 can be opened. Thereby, for example, when the internal pressure of the inner container 2 is increased, the communication hole 97 is opened, and the contents can be guided to the first discharge port 5.

  In addition, the valve body 112 does not completely close the upper end opening of the housing cylinder portion 100. Therefore, the inside of the accommodation cylinder part 100 is always opened upward. Further, the number of elastic connecting pieces 113 is not limited to three. For example, the valve body 112 may be elastically supported by one elastic connecting piece 113, or two or four or more elastic connecting pieces 113 may be used. The valve body 112 may be elastically supported.

An air introduction valve 115 is formed integrally with the discharge valve 110 configured as described above. The air introduction valve 115 includes an elastically deformable annular valve 116 that protrudes in an annular shape from the outer peripheral surface of the valve body cylinder 111 toward the radially outer side and has an outer end portion as a free end.
The outer end portion of the annular valve 116 is in contact with the lower surface of the outer peripheral portion 83 of the first top wall portion 21 so as to be able to be separated from below. Thus, the air introduction valve 115 closes the air introduction hole 85 from the inside of the first cap 6 so as to be openable.

  Therefore, the air introduction valve 115 functions as a check valve that allows the inflow of air from the outside through the air introduction hole 85 and restricts the outflow of air to the outside through the air introduction hole 85. Air that has flowed in from the outside through the air introduction hole 85 flows between the inner container 2 and the outer container 3 through the air groove 82 and the intake hole 81.

Since the upper end portion of the valve body cylinder 111 is fitted inside the drooping cylinder portion 86 and the lower end portion is fitted between the inner cylinder portion 94 and the middle cylinder portion 96, the inner plug 90, the discharge The valve 110 and the first cap 6 are combined together. Thereby, the 1st cap 6, the inside plug 90, and the discharge valve 110 can be handled as one unit.
Further, the discharge valve 110 and the air introduction valve 115 are integrally formed, but the present invention is not limited to this case, and may be a separate member.

As described above, the first cap 6 of the present embodiment does not include the suction cylinder portion 25 in the first embodiment. Therefore, the 2nd cap 7 is provided only with the 1st communication cylinder part 43, and does not have the 2nd communication cylinder part 44 in a 1st embodiment. The inner side of the first communication cylinder portion 43 communicates with the inside of the support cylinder portion 31 through the communication hole 45.
Therefore, in the present embodiment, the first communication cylinder portion 43 communicates the inside of the first discharge port 5 and the lower end opening 51a of the cylinder 51, and the communication member that is detachably fitted into the first discharge port 5. 46 is configured.

(Action of discharge container)
Next, the case where the contents are discharged using the discharge container 80 of the present embodiment configured as described above will be described. Note that the contents of the container body 4 are sucked into the cylinder 51.

  When discharging the contents from the first discharge port 5, as in the first embodiment, the second cap 7 is rotated (opened) around the hinge portion 37 from the state shown in FIG. The second cap 7 is detached from the first cap 6 as shown in FIG. Thereby, the 1st communication cylinder part 43 can be made to detach | leave from the inside of the discharge cylinder part 24, and the 1st discharge port 5 can be open | released.

  After opening the first discharge port 5, for example, the outer container 3 is squeezed into the container while the container body 4 is tilted so that the mouth portion 10 of the container body 4 faces downward. As a result, the inner container 2 and the outer container 3 are deformed and deformed inside the container to reduce the volume. Therefore, while the internal pressure of the inner container 2 rises, for example, when the valve body 112 is pressed by the contents, the elastic connecting piece 113 is elastically displaced upward. Accordingly, the valve body 112 can be separated from the inner plug 90 toward the first discharge port 5, and the communication hole 97 can be opened.

Therefore, the contents accommodated in the container body 4 can flow into the communication path 114 through the communication hole 97 and be discharged outside through the first discharge port 5.
At this time, the ball valve 102 moves to the valve body 112 side by the weight of the ball valve 102 and the pressure in the inner container 2 exerted through the seating tube portion 101 of the housing tube portion 100.

After that, when the discharge container 80 is returned to the upright posture with the mouth portion 10 facing upward, and the increase in the internal pressure of the inner container 2 is stopped or reduced by stopping or releasing the squeeze deformation of the container body 4, the valve body 112 due to the contents. The elastic connecting piece 113 is restored and displaced downward due to the elastic restoring force in combination with the weakening of the pressing force.
As a result, the valve body 112 can be seated on the inner plug 90 and the communication hole 97 can be closed. Therefore, the inner container 2 can be sealed and the discharge of the contents can be stopped.

At this time, the ball valve 102 moves downward in the housing cylinder 100 due to the weight of the ball valve 102 or a pressure drop in the inner container 2, and in the housing cylinder 100, the first discharge port 5 side of the ball valve 102. The seating cylinder portion 101 is seated while increasing the volume of the portion located at the position.
As a result, the pressure in the communication passage 114 becomes negative, and the contents remaining in the discharge cylinder portion 24 are drawn into the communication passage 114 or the accommodation cylinder portion 100 due to the suck back effect accompanying the movement of the ball valve 102. Can do. Therefore, the residual content is difficult to leak from the first discharge port 5 to the outside, and dripping can be prevented.

  In addition, the ball valve 102 is in a state in which a small gap is formed between the outer peripheral surface of the ball valve 102 and the inner peripheral surface of the storage tube portion 100 so as to cause the above-described pull-back effect due to the suck back effect. Move through 100.

By releasing the squeeze deformation of the container body 4, the outer container 3 starts to be restored and deformed, so that a negative pressure is generated between the outer container 3 and the inner container 2. Thereby, since the gap between the outer container 3 and the inner container 2 becomes a negative pressure, the annular valve 116 of the air introduction valve 115 is elastically deformed by the negative pressure so as to be pulled downward.
Thereby, the air introduction valve 115 can be opened and the air introduction hole 85 can be opened. Therefore, the gap between the outer container 3 and the inner container 2 communicates with the outside of the container body 4 through the air groove 82, the air circulation hole 95 and the air introduction hole 85.

Therefore, air can be introduced into the gap between the outer container 3 and the inner container 2 through the air introduction valve 115. When the internal pressure in the gap between the outer container 3 and the inner container 2 increases due to the inflow of air, the annular valve 116 is elastically deformed and closes the air introduction hole 85. Thereby, the air introduction valve 115 regulates the outflow of air from the gap between the outer container 3 and the inner container 2. As a result, the outer container 3 can be restored and deformed while the volume of the inner container 2 is reduced.
It should be noted that the same operation as described above can be repeated until the contents are completely discharged.

  Next, when the contents are discharged from the second discharge port 54, the pressing head 55 is pressed against the urging force of the urging member 57 from the state shown in FIG. Let Thereby, similarly to the first embodiment, the contents in the cylinder 51 can be discharged from the second discharge port 54 to the outside.

  When the pressing of the pressing head 55 is released, the piston 56, the stem 52 and the pressing head 55 are restored and returned to the original state in the same manner as in the first embodiment. Become. Therefore, the contents of the container body 4 can be pulled upward, and the contents can be sucked into the cylinder 51 from the lower end opening 51 a of the cylinder 51 through the first communication cylinder portion 43 and can be stored in the cylinder 51. . Thereby, it can prepare for discharge of the next content.

When the contents are sucked into the cylinder 51, the contents are introduced into the first communication cylinder portion 43 through the communication hole 97 while pushing up the valve body 112 upward, for example.
Further, in the case where a gap is provided between the outer peripheral surface of the ball valve 102 and the inner peripheral surface of the accommodating tube portion 100, the accommodating tube portion 100 is pushed up while pushing the ball valve 102 upward. The contents can be introduced into the interior, and then the contents can be introduced into the first communicating cylinder portion 43 from the accommodating cylinder portion 100 through the gap between the valve body 112 and the elastic connecting piece 113.

  Further, as the contents are sucked from the container body 4 into the cylinder 51, the inner container 2 is formed into a dent shape. As a result, a negative pressure is generated between the outer container 3 and the inner container 2 in the same manner as described above, so that air flows into the gap between the inner container 2 and the outer container 3 using the air introduction valve 115. Can be made. Therefore, only the inner container 2 can be squeezed and deformed while maintaining the shape of the outer container 3.

As described above, even the discharge container 80 of the present embodiment can achieve the same effects as those of the first embodiment.
In addition, since the discharge container 80 of the present embodiment includes the discharge valve 110, when discharging the contents from the first discharge port 5, the container body 4 can be freely tilted as compared with the first embodiment. It is possible to easily improve the degree of freedom of the discharge posture. Therefore, it is easy to discharge the contents, and it becomes easier to use. Furthermore, since the discharge valve 110 is provided, the container body 4 can be sealed, and the quality of the contents can be easily maintained.

(Third embodiment)
Next, a third embodiment of the discharge container according to the present invention will be described with reference to the drawings. In the third embodiment, the same components as those in the second embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  As shown in FIGS. 9 and 10, the discharge container 120 of the present embodiment includes a hinge cap (first connection cap) 121 in which the second cap 7 is connected to the first cap 6 via the hinge portion 37, and a discharge. And a separation cap (second coupling cap) 122 detachably attached to the hinge cap 121.

  The hinge cap 121 surrounds the discharge cylinder portion 24 from the outside in the radial direction, and closes the cap peripheral wall 130 integrally connected to the first peripheral wall portion 20 via the hinge portion 37 and the upper end opening of the cap peripheral wall 130. It is formed in the shape of a top cylinder provided with a cap top wall 131, and is arranged coaxially with the container axis O1.

A lower end portion of the cap peripheral wall 130 is detachably fitted to an upper end portion of the first peripheral wall portion 20. Thereby, the whole hinge cap 121 can be rotated around the hinge portion 37 and can be detached from the first cap 6 by this rotation.
A fifth screw portion 132 is formed on the outer peripheral surface of the cap peripheral wall 130. Further, an operation projection piece 38 is formed at a lower end portion of the cap peripheral wall 130 at a portion located on the opposite side of the hinge portion 37 with the container shaft O1 interposed therebetween.

The cap top wall 131 is formed with a communication cylinder part 135 so as to extend downward and an inner connection cylinder 136 so as to extend upward.
The communication cylinder portion 135 is disposed coaxially with the discharge shaft O2 and is inserted into the discharge cylinder portion 24 from above, and a lower end portion thereof is detachably and closely fitted inside the discharge cylinder portion 24. Yes. The inner connecting cylinder 136 is disposed coaxially with the container axis O1. The lower end portion of the cylinder 51 is inserted into the inner connecting cylinder 136 from above and is detachably fitted.
And the inside of the communication cylinder part 135 and the inner side connection cylinder 136 are mutually connected in the container-axis O1 direction.

Accordingly, the inside of the first discharge port 5 and the inside of the lower end opening 51 a of the cylinder 51 can be communicated with each other through the communication cylinder portion 135 and the inner connection cylinder 136.
Therefore, the communication cylinder part 135 and the inner connection cylinder 136 communicate with each other in the first discharge port 5 and the lower end opening 51a of the cylinder 51, and are connected to the first discharge port 5 in a detachable manner. 46 is configured.

  The separation cap 122 includes a cap cylinder portion 140 that surrounds the cap peripheral wall 130 from the outside in the radial direction and is formed to have substantially the same diameter as the first peripheral wall portion 20, and an intermediate cylinder that extends upward from the upper end portion of the cap cylinder portion 140. Portion 141, a mounting cylinder portion 47 disposed above the intermediate cylinder portion 141 and having a third screw portion 48 formed on the outer peripheral surface, and an upper end portion of the intermediate cylinder portion 141 and a lower end portion of the attachment cylinder portion 47. An annular flange wall 145 that is integrally connected in the direction, and is disposed coaxially with the container axis O1.

A sixth screw portion 142 that is screwed to the fifth screw portion 132 is formed on the inner peripheral surface of the cap cylinder portion 140. Thereby, the separation cap 122 is detachably attached to the hinge cap 121.
However, the method of attaching the separation cap 122 is not limited to screwing, and may be attached to the hinge cap 121 by, for example, undercut fitting with a stopper.

The intermediate cylinder portion 141 is gradually reduced in diameter from the lower side toward the upper side. On the inner side of the intermediate cylinder 141, the outer connection cylinder 143 that fits detachably with respect to the inner connection cylinder 136, and extends downward from the inner peripheral edge of the flange wall 145, above the outer connection cylinder 143. A drooping cylinder 146 is disposed.
The lower end portion of the outer connecting cylinder 143 is in contact with the cap top wall 131 of the hinge cap 121 from above. The upper end portion of the outer connecting tube 143 and the lower end portion of the drooping tube 146 are integrally connected in the radial direction by a plurality of connecting ribs 144 arranged around the container axis O1 with a space therebetween.
Note that a finger-hanging piece 49 is formed on the outer peripheral edge of the flange wall 145.

(Action of discharge container)
Next, a case where contents are discharged using the discharge container 120 of the present embodiment configured as described above will be described.
According to the discharge container 120 of the present embodiment, even if the contents are discharged from any one of the first discharge port 5 and the second discharge port 54, the same effect as the second embodiment described above. Can be successful.

  In addition, in the present embodiment, the separation cap 122 can be attached to the hinge cap 121 and used only when the discharger 8 is necessary. Therefore, when the discharge from the first discharge port 5 is mainly selected and used. The separation cap 122 and the discharger 8 can be removed. Therefore, the height of the container can be suppressed, and the container can be made compact.

Furthermore, since the separation cap 122 can be separated from the hinge cap 121, the discharger 8 and the separation cap 122 can be used as the replacement unit 150, and components other than the discharger 8 and the separation cap 122 can be used. An exchange unit 151 can be used.
Therefore, after the contents have been used up, the replacement unit 150 is attached to the new replacement unit 151 in which the contents of the container body 4 are filled.

  As described above, the replacement unit 150 can be used in common and can be continuously used by replacing only the replacement unit 151, so that the maintenance cost can be reduced and the convenience can be further improved.

In addition, as shown in FIG. 11, you may mount | wear with the top cap-shaped lid cap 155 with respect to the hinge cap 121 from which the separation cap 122 was removed.
A sixth screw portion 142 that is screwed onto the fifth screw portion 132 is formed on the peripheral wall of the lid cap 155. The top wall of the lid cap 155 is formed with a seal cylinder 156 that protrudes downward and fits detachably and tightly inside the inner coupling cylinder 136.

  In this way, by attaching the lid cap 155 to the hinge cap 121, it is possible to close the inner connecting cylinder 136 while maintaining the quality of the contents. For example, the contents can be discharged from the first discharge port 5. Effective when selected and used. Furthermore, this is also effective when the exchange unit 151 is distributed, stored, or the like.

  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 each embodiment, the container body 4 is a laminated peelable container in which the inner container 2 is detachably laminated on the inner surface of the outer container 3, but is not limited to this. For example, the inner container 2 and the outer container A double container in which a gap is secured between the container 3 and the container 3 may be used. However, it is preferable to use a laminate peelable container because versatility can be improved.

In the second and third embodiments, since the discharge valve 110 is provided, the ball valve 58 of the cylinder 51 can be omitted. Even in this case, the contents can be stored in a portion located above the discharge valve 110, so that the contents can be kept sucked into the cylinder 51, and the second discharge port can be maintained. The contents from 54 can be discharged.
However, even if both the discharge valve 110 and the ball valve 58 are provided, the contents can be appropriately discharged from the second discharge port 54, so that it is not necessary to omit the ball valve 58. Therefore, it is possible to use a conventional discharge device that has been used conventionally, and there is no need to design a special discharge device.

In each of the above embodiments, the entire second cap 7 may be separable from the first cap 6.
For example, the second embodiment will be described as an example. Instead of connecting the first cap 6 and the second cap 7 via the hinge portion 37, the second cap 7 is screwed to the first cap 6. You may comprise so that the 2nd cap 7 can be isolate | separated with respect to the 1st cap 6 by couple | bonding.

Further, the second cap 7 may be configured to be separable from the first cap 6 while having a hinge portion.
In this case, for example, as shown in FIG. 12, a locking groove 160 opened upward is formed on the outer peripheral surface of the first cap 6 on the upper end side of the first peripheral wall portion 20.
On the other hand, the locking piece 162 is integrally connected to the lower peripheral wall portion 35 of the second cap 7 via the main hinge portion 161. The locking piece 162 is inserted into the locking groove 160 from above and is detachably locked in the locking groove 160. Thus, the first cap 6 and the second cap 7 are integrally connected via the main hinge portion 161 and the locking piece 162.
Further, the locking piece 162 and the lower peripheral wall portion 35 of the second cap 7 are integrally connected via a sub hinge portion 163 disposed with a space in the circumferential direction with the main hinge portion 161 therebetween. Has been.

In such a configuration, the second cap 7 can be separated from the first cap 6 by detaching the locking piece 162 from the locking groove 160, and the entire second cap 7 is discharged from the discharge device 8. Can be removed.
Then, by inserting the locking piece 162 into the locking groove 160 and locking it, the second cap 7 can be mounted on the first cap 6, and the main hinge portion 161 and the sub hinge portion 163 are further mounted. The second cap 7 can be detached from the first cap 6 by rotating the second cap 7 around the two hinge portions.

  As described above, when the entire second cap 7 is configured to be separable, when the discharge from the first discharge port 5 is selected and used, the height of the entire container is further increased than in the third embodiment. You can reduce the size and make it compact.

DESCRIPTION OF SYMBOLS 1, 80, 120 ... Discharge container 2 ... Inner container 3 ... Outer container 4 ... Container main body 5 ... 1st discharge port 6 ... 1st cap (discharge cap)
7 ... Second cap (connection cap)
DESCRIPTION OF SYMBOLS 8 ... Discharge device 10 ... Mouth part 37 ... Hinge part 46 ... Communication member 51 ... Cylinder 52 ... Stem 54 ... 2nd discharge port 55 ... Pressing head 121 ... Hinge cap (1st connection cap)
122 ... Separation cap (second coupling cap)

Claims (4)

A container main body including an inner container in which the contents are contained and volume-reducing and deformable, and an outer container in which the inner container is elastically deformable;
A discharge cap attached to the mouth of the container body and having a first discharge port for discharging the contents;
A connecting cap removably attached to the discharge cap;
A dispenser attached to the connection cap,
The discharger is a cylinder, a stem that is arranged to be movable downward in an upward biased state in the cylinder, and a press that is attached to an upper end portion of the stem and has a second discharge port for discharging contents. A head, and
The connection cap includes a communication member that communicates the inside of the first discharge port and the lower end opening of the cylinder. In the discharge container according to claim 1,
The connection cap is connected to the discharge cap via a hinge portion, and can be detached from the discharge cap by rotation around the hinge portion. The discharge container according to claim 2,
The connecting cap is
A first coupling cap coupled to the discharge cap via the hinge portion;
A discharge container comprising: a second connection cap that is mounted on the discharge device and is separably mounted on the first connection cap. In the discharge container according to claim 1,
The connection cap is a discharge container that is detachably attached to the discharge cap.

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