JP4999600B2 - Container with spout - Google Patents

Description

  The present invention relates to a container with a spout provided with a spout in a pouch.

Conventionally, a container with a spout is known in which a spout (also referred to as a spout) is attached to a pouch formed of a flexible film in a bag shape. The container with a spout is used for storing general foods such as beverages and jellies, or used for storing medical fluids such as infusion solutions containing vitamins and amino acids, enteral nutrients, etc. It is used as.
Since the above-mentioned container with a spout usually closes a spout, the cap is provided with a cap part which can be detached by screw action.
Furthermore, a container with a spout having a nozzle portion for mounting a supply tube for administration to a patient is also known when used for a purpose of containing a medical fluid.

  As a container with a spout having the above-mentioned nozzle portion, it is a packaging bag for enteral enteral nutrients in which a spout member is sealed at the peripheral portion of the pouch, and has a filling port communicating with the inside of the pouch, A base that is sandwiched and sealed between films on the periphery of the pouch, and a spout for connecting the tube to the distal end is provided so as to communicate with the filling port. A packaging bag for enteral enteral nutrients having a nozzle part and a cap for sealing a spout is known (Patent Document 1).

The packaging bag described in Patent Document 1 is filled with contents from a base filling port sandwiched and sealed between films on the periphery of a pouch, and then a nozzle portion sealed with a cap is attached to the base portion. By attaching via a screw mechanism, the contents can be sealed.
The packaging bag containing the above-mentioned contents in a hermetically sealed manner can cut the gap between the cap and the nozzle part and open the spout of the nozzle part by turning the cap with respect to the nozzle part.
By attaching a supply tube to the nozzle portion where the spout is opened, a transluminal enteral nutrient can be administered from the spout through the supply tube.
JP 2006-61554 A

However, in the packaging bag for enteral enteral nutrient described in Patent Document 1, the cap may break from the nozzle portion when the nozzle portion is attached to the base via a screw mechanism.
Specifically, in the conventional packaging bag, after filling the contents from the filling port, the nozzle portion is attached to the base via a screw mechanism in order to close the filling port. That is, the nozzle portion is attached to the base portion by tightening the nozzle portion in one direction around the axis. When the nozzle portion is rotated, a rotational force may be applied to the cap by mistake, and the cap may rotate with respect to the nozzle portion, thereby causing a partial breakage between the cap and the nozzle portion. Thus, since the content leaks out from the spout of a nozzle part, the improvement is calculated | required.

  Moreover, the packaging bag after filling the contents can open the spout of the nozzle part by turning the cap and cutting it off. When the cap is turned and cut from the nozzle portion, the nozzle portion may rotate together, and the tightening of the base portion of the nozzle portion may be loosened. If the nozzle part is loosened with respect to the base part, the contents leak out from the filling port of the nozzle part. Therefore, it is necessary to devise such a situation not to occur.

Challenge of the present invention, in order to close the filling opening, when mounting the nozzle portion on the base member, can at preventing breakage between the cap portion and the nozzle portion, further, when dispensing the contents thereof, the nozzle It is to provide a container with a spout that can prevent the part from loosening.

The present invention is a pouch in which a film is formed in a bag shape, and is a base member in which a pouch having a housing portion formed therein and a filling port communicating with the housing portion of the pouch are formed. A base member attached to a part, and a nozzle part attached to the base member via a screw mechanism and capable of attaching a supply tube, the nozzle part being provided with a spout communicating with the filling port; A container with a spout that can be separated from the spout of the nozzle portion by rotating the cap portion in the other direction around the axis . The screw mechanism tightens the nozzle portion with respect to the base member by rotating the nozzle portion in one direction around the axis, and turns the nozzle portion with respect to the base member by rotating the nozzle portion in the other direction around the axis. Is configured to be fit, the cap once stop mechanism regulating and and the cap portion to be around about the axis direction of the cap portion is the nozzle portion allows the turn around the axis other direction, and the nozzle And a nozzle detent mechanism that allows the portion to rotate in one direction around the axis, which is a rotation regulating direction of the cap detent mechanism, and restricts rotation in the other direction around the axis. To do.

In the container with a spout, after filling the contents from the filling port of the base member attached to the pouch, the nozzle portion with the cap portion is attached to the base member via a screw mechanism in order to close the filling port. Install. That is, the nozzle portion can be tightened with respect to the base member by rotating the nozzle portion in one direction around its axis by the screw mechanism.
Since the container with a spout is provided with a cap turning prevention mechanism that restricts the cap portion from rotating in one direction around the axis of the nozzle portion, the cap portion may be accidentally turned when the nozzle portion is rotated in one direction around the axis. Even if a rotational force in one direction around the axis is applied, the cap portion can be prevented from rotating. Therefore, when mounting the nozzle portion, it is possible to prevent partial breakage between the cap portion and the nozzle portion.

The said container with a spout can open | release the spout of a nozzle part by separating a cap part from a nozzle part, and can pour the content from there.
Superscript Kichu outlet container, the cap once stop mechanism the nozzle unit to allow the nozzle once stop mechanism for restricting the orbiting about the axis other direction, that the cap portion turns around the axis other direction of the nozzle portion, but Since it is provided, it is possible to prevent the nozzle portion from rotating together with the cap portion when the cap portion is rotated in the other direction around the axis. Therefore, twisting occurs at the boundary between the cap part and the nozzle part, and the cap part can be reliably separated from the nozzle part and the spout can be opened. In addition, as described above, since the nozzle portion does not rotate when the cap portion is rotated, the nozzle portion does not loosen with respect to the base member.

  In a preferable container with a spout according to the present invention, the nozzle part and the cap part are formed of an integrally molded product of synthetic resin.

The container with a spout according to the present invention can prevent breakage between the cap part and the nozzle part when the nozzle part is attached to the base member in order to close the filling port after filling the contents.
Furthermore, the container with a spout of the present invention can reliably separate the cap portion from the nozzle portion when the contents are poured out, and can prevent the nozzle portion from loosening with respect to the base member.

Hereinafter, the present invention will be specifically described with reference to the drawings.
However, the axis refers to a direction passing through the center of the horizontal cross section (the cross section shown in FIG. 5) of the nozzle portion and perpendicular to the horizontal cross section. One direction around the axis refers to either the clockwise or counterclockwise direction around the axis, and the other direction around the axis refers to a direction opposite to the one direction around the axis.
1 to 4, reference numeral 1 denotes a flexible pouch 2, a base member 3 attached to a part of the pouch 2, a nozzle portion 5 attached to the base member 3 via a screw mechanism, and a nozzle The container with a spout which has the cap part 7 which obstruct | occludes the spout 59 of the part 5 is shown.

The pouch 2 is made of a flexible film. By forming the film into a bag shape, the pouch 2 in which the accommodating portion 23 is formed is configured.
Specifically, the pouch 2 has a predetermined shape (for example, a rectangular shape) of a surface film 21 and a back film 22, and the inner surfaces of the front and back films 21 and 22 are adhered to each other at the three sides. In one side, the base member 3 is bonded between the front and back films 21 and 22. In addition, in order to illustrate the bonded portion in an easy-to-understand manner, the bonded portion is shown in light ink painting in FIG.

As a method for adhering the front and back films 21 and 22 and between the front and back films 21 and 22 and the base member 3, typically, heat sealing is used, but adhesion using a solvent, adhesion using an adhesive, or the like may be used. .
The pouch 2 has a housing portion 23 for filling the contents in a hermetically sealed manner by adhering the peripheral portions of the front and back films 21 and 22. The base member 3 is sandwiched and bonded to one side of the front and back films 21 and 22, and a filling port 39 formed in the base member 3 is opened to the outside. The filling port 39 communicates with the accommodating portion 23 of the pouch 2 through the conduction path 33 of the base member 3.
A hole 24 for suspension is formed on the other side facing the one side of the front and back films 21 and 22. The hole 24 for suspension is formed at a point-symmetrical position with respect to the base member 3 with respect to the center of gravity of the surface film 21. In the present embodiment, since the base member 3 is attached to the substantially central portion of one side of the front and back films 21 and 22 by adhesion, the hanging hole 24 is substantially the central portion of the other side portion. Is formed.

  In addition, the form of the pouch 2 is not restricted to the bag formed from the front and back films 21 and 22 as described above, and the pouch 2 can adopt a conventionally known form. The pouch 2 of the present invention may be a self-supporting bag formed from, for example, a front and back film and both side gusset films sandwiched between both side portions of the front and back film (not shown).

It does not specifically limit as a film which comprises the pouch 2, A conventionally well-known flexible film can be used. The film constituting the pouch 2 is preferably a film having gas barrier properties (including water vapor barrier properties) and / or light barrier properties. In general, the material of the film is mainly composed of synthetic resin.
Examples of the film having gas barrier properties include a transparent vapor-deposited film obtained by vapor-depositing silica or alumina. Examples of the film having a light barrier property include a printed film obtained by printing a light-shielding ink or the like in a solid shape, and a colored film formed by mixing a pigment or the like with a resin composition. Examples of the film having gas barrier properties and light barrier properties include a film in which a metal foil is laminated, and a vapor deposition film in which a metal or the like is vapor-deposited.
Further, the film constituting the pouch 2 is preferably a film having a sealant layer on the inner surface. By using a film having a sealant layer, the pouch 2 can be formed by heat sealing. Examples of the sealant layer include polyethylene (PE), polypropylene (PP), ethylene-vinyl alcohol copolymer, and the like.

The film constituting the pouch 2 is preferably a laminated film in which a sealant layer is laminated on the above-described film having gas barrier properties and / or light barrier properties. Further, a base film may be laminated on the laminated film in order to increase the rigidity of the film. Examples of the base film include ester resin films such as polyethylene terephthalate, amide resin films such as nylon, and olefin resin films. The base film may be either a single layer of these one type of film or a laminate of these two or more types of films.
Most preferably, the film constituting the pouch 2 is a laminated film in which the sealant layer, the gas barrier property and / or the light barrier property, and the base film are laminated in order from the inner surface.
It should be noted that a desired display such as a product name and usage instructions is printed on the film constituting the pouch 2 as necessary.

Next, the base member 3 includes a bonded portion 31 that is bonded to the front and back films 21 and 22, and a cylindrical portion 32 that protrudes outward from the bonded portion 31.
The adherend 31 is formed in, for example, a top view boat shape. As shown in FIG. 4, a conduction path 33 that leads to the housing portion 23 of the pouch 2 is penetrated inside the adherend portion 31. The adherend portion 31 is sandwiched between one side portions of the front and back films 21 and 22, and the inner surfaces of the front and back films 21 and 22 are bonded to the outer surface of the adherend portion 31. The base member 3 is attached to the pouch 2 by bonding the adherend portion 31 to the front and back films 21 and 22. The adherend portion 31 is preferably formed of a material that can be heat sealed to the inner surfaces of the front and back films 21 and 22 (for example, a polyolefin resin such as polyethylene).

In the base member 3 attached to the pouch 2 through the adherend portion 31, the cylindrical portion 32 protrudes to the outside of the pouch 2.
A conductive path communicating with the conductive path 33 of the bonded portion 31 is formed inside the cylindrical portion 32. A filling port 39 is formed at the upper end of the cylindrical portion 32, and the filling port 39 communicates with the housing portion 23 of the pouch 2 through a conduction path 33. Although not particularly illustrated, a conducting tube extending into the accommodating portion 23 of the pouch 2 may be extended to the bonded portion 31 of the base member 3.

A male screw portion 34 is formed on the outer peripheral surface of the cylindrical portion 32 of the base member 3. The male screw portion 34 can be screwed into the female screw portion 54 of the nozzle portion 5.
Furthermore, an engaging portion 4 that engages with the engaged portion 6 of the nozzle portion 5 is provided on the outer peripheral surface of the cylindrical portion 32 at a position lower than the male screw portion 34. Hereinafter, the engaged portion 6 of the nozzle portion 5 is referred to as a “nozzle engaged portion”, and the engaging portion 4 of the base member 3 is referred to as a “base member engaging portion”.
As shown in FIG. 5, the base member engaging portion 4 has a vertical surface 41 and an inclined surface 42 protruding from the outer peripheral surface of the cylindrical portion 32, and the vertical surface 41 and the inclined surface 42 are opposed to each other. A plurality of substantially triangular protrusions are provided around the axis O at a predetermined interval. The vertical surface 41 is a surface projecting perpendicular to the tangential direction of the outer peripheral surface of the cylindrical portion 32. The inclined surface 42 is a surface inclined in the other direction L around the axis from the top of the vertical surface 41.
In addition, the inclination angle of the inclined surface 42 with respect to the vertical surface 41 is preferably about 60 ° to 80 °. Hereinafter, the inclined surface 82 of the nozzle engaging portion 8 and the inclined surface 92 of the cap engaged portion 9 are preferably at the same inclination angle with respect to the corresponding vertical surfaces 81 and 91, respectively.

  In addition, between the to-be-adhered part 31 and the cylindrical part 32 of the base member 3, the latching | locking part 35 for hanging on the guide rail of a filling apparatus is formed. The latching portion 35 is formed by extending the plate portion 36 to the outside of the tubular portion 32 below the tubular portion 32.

Next, the nozzle part 5 includes an attachment part 51 that is detachably attached to the base member 3, and a tube attachment part 52 provided on the attachment part 51.
The mounting portion 51 is formed in a cylindrical shape that can be fitted onto the cylindrical portion 32 of the base member 3, and is screwed onto the male thread portion 34 of the cylindrical portion 32 on the inner peripheral surface of the mounting portion 51. A mating female thread portion 54 is formed. The attachment part 51 of the nozzle part 5 can be attached to and detached from the cylindrical part 32 of the base member 3 by a screw mechanism of the male screw part 34 and the female screw part 54. Specifically, the mounting portion 51 of the nozzle portion 5 is externally fitted to the cylindrical portion 32 of the base member 3, and the nozzle portion 5 is in one direction R around the axis (for example, clockwise when viewed from the upper end side of the nozzle portion). The nozzle portion 5 is tightened with respect to the cylindrical portion 32 of the base member 3 by turning the nozzle member 5 to the base member 3. On the other hand, by rotating the nozzle part 5 in the other direction L around the axis (in the direction opposite to the one direction R around the axis, for example, counterclockwise when viewed from the upper end side of the nozzle part), the nozzle part 5 The cylindrical portion 32 of the member 3 is loosened.

A nozzle engaged portion 6 that engages with the base member engaging portion 4 is provided on the inner peripheral surface of the mounting portion 51 of the nozzle portion 5. The nozzle engaged portion 6 is provided at a position below the female screw portion 54. As shown in FIG. 5, the nozzle engaged portion 8 has a plate-like piece 61 that protrudes in an inclined manner from the inner peripheral surface of the mounting portion 51. The plate-like piece 61 is a so-called leaf spring whose tip is a free end. The plate-like piece 61 is provided with a plurality of predetermined intervals around the axis O of the inner peripheral surface of the attachment portion 51. The number and the formation interval of the plate-like pieces 61 are preferably the same as the formation number and the formation interval of the vertical surfaces 41. The plate-like piece 61 extends substantially parallel to the inclined surface 42 of the base member engaging portion 4 and projects in an inclined manner.
Therefore, when a rotational force in one direction R around the axis is applied to the nozzle portion 5, the free end portion of the plate-like piece 61 (nozzle engaged portion 6) is in contact with the inclined surface 42 of the base member engaging portion 4. Since the plate-like piece 61 swings in the radial direction, the nozzle portion 5 can be easily rotated in one direction R around the axis.
On the other hand, when a rotational force in the other direction L around the axis is applied to the nozzle portion 5, the free end portion of the plate-like piece 61 hits the vertical surface 41 of the base member engaging portion 4, and the plate-like piece 61 extends. Since the direction and the vertical surface 41 are substantially perpendicular, the plate-like piece 61 is stretched and the nozzle portion 5 cannot be rotated in the other direction L around the axis.
The nozzle engaged portion 6 and the base member engaging portion 4 correspond to a nozzle detent mechanism that allows the nozzle portion 5 to rotate in one direction R around the axis and restricts rotation in the other direction L around the axis. .

The tube mounting portion 52 of the nozzle portion 5 is formed in a hollow cone shape whose diameter decreases as the outer peripheral surface of the tube mounting portion 52 moves upward. A communication passage 53 communicating with the filling port 39 of the base member 3 is formed inside the tube mounting portion 52. A spout 59 is formed at the upper end of the tube mounting portion 52, and the spout 59 communicates with the filling port 39 of the base member 3 through the communication passage 53 of the tube mounting portion 52.
Although not particularly illustrated, convex portions extending around the axis may be provided in multiple stages on the outer peripheral surface of the tube mounting portion 52 in order to prevent the supply tube from dropping off.

The nozzle portion 5 is provided with an engaging portion 8 that engages with the engaged portion 9 of the cap portion 7. Hereinafter, the engaged portion 9 of the cap portion 7 is referred to as a “cap engaged portion”, and the engaging portion 8 of the nozzle portion 5 is referred to as a “nozzle engaging portion”.
As shown in FIG. 6, the nozzle engaging portion 8 has a vertical surface 81 and an inclined surface 82 projecting from the peripheral edge of the upper surface of the mounting portion 51 of the nozzle portion 5. A plurality of substantially triangular protrusions 82 are provided around the axis O at predetermined intervals. The vertical surface 81 is a surface that protrudes perpendicularly to the upper surface of the mounting portion 51. The inclined surface 82 is a surface inclined in one direction R around the axis from the top of the vertical surface 81. In addition, although the said nozzle engaging part 8 may be formed over the perimeter of the peripheral part of the upper surface of the nozzle part 5, in this embodiment, the said nozzle engaging part 8 is the upper surface of the nozzle part 5. Are provided at two edge portions facing each other around the tube mounting portion 52 (see FIG. 1).

Next, the cap part 7 has a plug part 71 that closes the spout 59 of the nozzle part 5, and a grip part 72 that is connected to the plug part 71.
The cap part 7 and the nozzle part 5 are formed of an integrally molded product of synthetic resin. Specifically, the cap portion 7 and the nozzle portion 5 are integrally connected at the stopper portion 71 of the cap portion 7 and the upper end portion of the tube mounting portion 52 of the nozzle portion 5. A thin-walled portion 73 is formed at the boundary between the cap portion 71 of the cap portion 7 and the tube mounting portion 52 of the nozzle portion 5. By forming the thin portion 73, the cap portion 7 and the nozzle portion 5 can be easily divided by the thin portion 73 when the cap portion 7 is rotated.

The grip portion 72 of the cap portion 7 is formed integrally with the plug portion 71 and extends linearly in the radially outward direction around the plug portion 71, and the nozzle engagement from both ends of the main body portion 74. Leg portions 75 extending downward so as to face the joint portion 8. In addition, the holding part 72 and the nozzle part 5 are not connected, and both are independent.
A cap engaged portion 9 is formed on the leg portion 75.
As shown in FIG. 6, the cap engaged portion 9 has a vertical surface 91 and an inclined surface 92 projecting from below the leg portion 75, and is a substantially triangular shape composed of the vertical surface 91 and the inclined surface 92. It is constituted by a protrusion having a shape. The vertical surface 91 of the cap engaged portion 9 faces the vertical surface 81 of the nozzle engaging portion 8 with a slight gap, and the inclined surface 92 of the cap engaged portion 9 is nozzle-engaged. It faces the inclined surface 82 of the part 8 with a slight gap.
Therefore, the cap engaged portion 9 and the nozzle engaging portion 8 are engaged with each other.

When a rotational force in the other direction L around the axis is applied to the cap portion 7, the inclined surface 92 of the cap engaged portion 9 slides on the inclined surface 82 of the nozzle engaging portion 8, and the cap portion 7 can be easily rotated in the other direction L around the axis.
On the other hand, when a rotational force in one direction R around the axis is applied to the cap portion 7, the vertical surface 91 of the cap engaged portion 9 abuts on the vertical surface 81 of the nozzle engaging portion 8. Cannot turn in one direction R.
The nozzle engaging portion 8 and the cap engaged portion 9 correspond to a cap rotation stopping mechanism that restricts the cap portion 7 from rotating in one direction R around the axis and allows the cap portion 7 to rotate in the other direction L around the axis.

When the container 1 with a spout is in use, the container 23 of the pouch 2 is filled with the contents.
The content to be filled is not particularly limited. But the container 1 with a spout of this invention can attach a supply tube to the nozzle part 5, Therefore As a content, a medical fluid is preferable.
The filling of the contents can be performed as follows, for example.
The hook portion 35 of the base member 3 of the pouch 2 to which the base member 3 is mounted is hooked on the guide rail of the filling device. Individual pouches 2 are taken out from a plurality of pouches 2 hung on the guide rail, and the contents 23 are filled into the accommodating portion 23 of the pouch 2 from the filling port 39 of the base member 3. After the filling, the nozzle portion 5 is tubularly fitted via a screw mechanism by fitting the mounting portion 51 of the nozzle portion 5 to the tubular portion 32 of the base member 3 and turning the nozzle portion 5 in one direction R around the axis. It can be attached to the part 32. Since the spout 59 of the nozzle portion 5 is closed by the cap portion 7, the filling port 39 can be closed by attaching the nozzle portion 5 to the base member 3. Thus, the container 1 with a spout as shown in FIGS. 1-3 can be obtained. In FIGS. 1 to 3, the contents are not filled.

  As described above, in the case of filling the contents from the filling port 39 of the base member 3, high-speed filling is possible, and more contents can be filled in the accommodating portion 23.

The container 1 with a spout of the present invention allows a nozzle portion 5 between the base member 3 and the nozzle portion 5 to allow the nozzle portion 5 to rotate in one direction R around the axis and to restrict rotation in the other direction L around the axis. A stopper mechanism is provided, and a cap stopper mechanism is provided between the nozzle part 5 and the cap part 7 that restricts the cap part 7 from rotating in one direction R around the axis and allows it to rotate in the other direction L around the axis. It has been.
Therefore, when a rotational force in one direction R around the axis is applied to the nozzle portion 5 after filling, even if a rotational force in one direction R around the axis is accidentally applied to the cap portion 7, the cap portion 7 is prevented from rotating the cap. The rotation in the direction R is regulated by the mechanism. Therefore, when attaching the nozzle part 5, it can prevent that the cap part 7 rotates accidentally, and there is no possibility that the partial fracture | rupture between the cap part 7 and the nozzle part 5 will arise. Therefore, the container 1 with a spout which does not leak after filling can be provided.

On the other hand, when pouring the contents of the filled container 1 with the spout, the cap portion 7 is rotated in the other direction L around the axis. As described above, the cap rotation mechanism allows the cap portion 7 to rotate in the other direction L around the axis, and the nozzle rotation mechanism restricts the nozzle portion 5 from rotating in the other direction L around the axis. Therefore, when a rotational force in the other direction L around the axis is applied to the cap part 7, there is no possibility that the nozzle part 5 rotates in the other direction L together with the cap part 7. Accordingly, the boundary portion (thin wall portion 73) between the cap portion 7 that rotates in the other direction L and the nozzle portion 5 that does not move as described above is twisted and divided at that portion, and the cap portion 7 is separated from the nozzle portion 5. can do.
Further, since the nozzle unit 5 does not rotate when the cap unit 7 is rotated, the nozzle unit 5 is loosened with respect to the base member 3 and passes through the gap between the nozzle unit 5 and the base member 3 from the filling port 39 of the base member 3. There is no risk of the contents leaking out.

  When the cap part 7 is separated, the spout 59 of the nozzle part 5 opens. By attaching the supply tube to the tube attachment portion 52 of the nozzle portion 5, the contents poured out from the spout 59 can be supplied through the supply tube. In addition, the container 1 with a spout attached with the supply tube may be used by hanging the hole 24 formed in the pouch on a hook or the like.

  Next, a modified example of the present invention will be described. However, configurations different from those of the above embodiment will be mainly described, and descriptions of similar configurations and effects may be omitted, and terms and symbols may be used as they are.

In the nozzle rotation stopping mechanism of the above embodiment, the base member 3 is provided with the base member engaging portion 4 having the vertical surface 41 and the inclined surface 42, and the nozzle portion 5 has the plate-like piece 61. On the contrary, the base member 3 is provided with a plate-like piece similar to the above, and the nozzle part 5 is provided with the same vertical surface and inclined surface as described above. May be. Further, as the nozzle rotation stop mechanism, the configuration exemplified in the cap rotation stop mechanism can be adopted.
The nozzle detent mechanism of the present invention only needs to be configured to allow the nozzle portion 5 to rotate in one direction R around the axis and to restrict rotation in the other direction L around the axis. Does not matter.

In the cap rotation stopping mechanism of the above embodiment, the nozzle portion 5 is provided with the nozzle engaging portion 8 having the vertical surface 81 and the inclined surface 82, and the cap portion 7 is engaged with the nozzle engaging portion 8. Although the cap engaging portion 9 having the vertical surface 91 and the inclined surface 92 is provided, the cap rotation stopping mechanism is not limited to this and can be changed to various configurations. For example, as shown in FIG. 7, the leg portion 75 of the cap portion 7 extends to the vicinity of the upper surface of the mounting portion 51 of the nozzle portion 5, and on the surface side facing the one side R around the axis of the leg portion 75. In addition, a stopper portion 84 may protrude from the upper surface of the mounting portion 51. In the case of this configuration, when the cap portion 7 is rotated in one direction R around the axis line, the leg portion 75 of the cap portion 7 hits the stopper portion 84 of the nozzle portion 5 and the cap portion 7 rotates in the one direction R. Can be regulated.
The cap rotation stopping mechanism of the present invention may be configured so as to restrict the cap portion 7 from rotating in one direction R around the axis and to allow it to rotate in the other direction L around the axis. Does not matter.

  Moreover, although the said nozzle part 5 and the cap part 7 are formed with the synthetic resin integral molding, it is not necessarily restricted to an integral molding. For example, the nozzle part 5 and the cap part 7 are formed separately, and the plug part 71 of the separate cap part 7 is fitted to the upper end part of the nozzle part 5 so as to close the spout 59 of the nozzle part 5, You may adhere | attach this fitting part. As this bonding method, bonding using an adhesive, when the nozzle part 5 and the cap part 7 are made of a solvent-bondable material, solvent bonding, and when the nozzle part 5 and the cap part 7 are made of a heat-weldable material For example, heat welding can be exemplified.

The front view which shows the container with a spout which concerns on one Embodiment. The same side view. FIG. The partial both substantially expanded sectional view cut | disconnected by the II line. The expanded end elevation cut | disconnected by the II-II line. The enlarged view of a circle enclosure III part. The side view which shows the container with a spout which concerns on other embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Container with spout, 2 ... Pouch, 3 ... Base member, 34 ... Male screw part of base member, 39 ... Filling port, 4 ... Base member engaging part, 5 ... Nozzle part, 54 ... Female screw of nozzle part , 59 ... spout, 6 ... nozzle engaged part, 7 ... cap part, 8 ... nozzle engaging part, 9 ... cap engaged part, R ... one direction around the axis, L ... other direction around the axis

Claims (2)

A pouch in which a film is formed in a bag shape, and a base member in which a housing portion is formed and a filling port communicating with the housing portion of the pouch is formed, and is attached to a part of the pouch. A base part, a nozzle part that is attached to the base member via a screw mechanism and can be fitted with a supply tube, the nozzle part having a spout communicating with the filling port, and the nozzle part A container with a spout that can be separated from the spout of the nozzle part by rotating the cap part in the other direction around the axis ,
The screw mechanism is capable of tightening the nozzle portion with respect to the base member by rotating the nozzle portion in one direction around the axis and loosening the nozzle portion with respect to the base member by rotating the nozzle portion in the other direction around the axis. Is configured as
A cap locking mechanism that restricts the cap portion from rotating in one direction around the axis and permits the cap portion to rotate in the other direction around the axis ; and
A nozzle detent mechanism is provided that allows the nozzle portion to rotate in one direction around the axis, which is a rotation regulating direction of the cap detent mechanism, and restricts rotation in the other direction around the axis. Characteristic container with spout.   The container with a spout according to claim 1, wherein the nozzle part and the cap part are formed of an integrally molded product of synthetic resin.

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