JP5965590B2 - Double aerosol container and manufacturing method thereof - Google Patents

Description

  The present invention relates to a double aerosol container and a method for producing the same.

  2. Description of the Related Art Conventionally, there is known a double aerosol container including an external container, an internal container accommodated therein, and an aerosol valve that closes the external container and the internal container and connects the internal container and the atmosphere. In such a double aerosol container, the contents are filled in the inner container, and the propellant is filled between the outer container and the inner container. Since it is configured in this manner, the propellant can press the inner container and eject the contents by operating the aerosol valve to connect the atmosphere and the inner container.

As a method of filling the propellant between the outer container and the inner container of such a double aerosol container, the aerosol valve is disposed in the vicinity of the opening of the outer container with the inner container closed by the aerosol valve. Before the valve is secured to the outer container, the propellant is instantaneously filled between the aerosol valve and the outer container, and at the same time, a part of the aerosol valve is caulked to the outer container and the aerosol valve is secured to the outer container. Cup filling methods are known.
At this time, a passage for filling the propellant is formed between the aerosol valve and the external container by arranging or holding the aerosol valve slightly above the external container. At that time, as shown in Cited Documents 1 and 2, when placed on the bottom surface of the outer container, the aerosol valve is set to a predetermined height using an inner container configured such that its upper end is slightly above the upper end of the outer container. A method of holding it is disclosed.

JP-A-9-118380 JP-A-9-240760

However, when the aerosol container is fixed to the outer container, the inner container as in Patent Documents 1 and 2 is a part of the inner container and bends a part for storing the contents. May leak or the connection between the inner container and the aerosol valve may be disconnected. Even when the contents are filled from the valve to the inner container after the aerosol valve is fixed to the outer container, if the part to be filled is greatly deformed, the deformed part becomes a resistance and the contents are stored. There is a risk that it will be difficult to fill in a fixed amount, or the inner container will be locally filled with filling pressure and torn. Further, as shown in FIG. 4 of Patent Document 2, it is conceivable to provide a buffer material at the lower end of the inner container. However, in that case, the cushioning material cannot be accurately arranged in the manufacturing process. Even when the buffer material is bonded to the inner container with an adhesive or the like, the process becomes complicated.
The present invention provides a double aerosol container in which the contents and the propellant can be easily and stably filled, and a method for producing a double aerosol product in which the double aerosol container is filled with the contents and the propellant. With the goal.

The double aerosol container of the present invention is a double aerosol container comprising an outer container, an inner container accommodated in the outer container, and an aerosol valve connected to the opening of the inner container and fixed to the outer container. there, the leg the inner container, the flexible sheet is a pouch which is formed being cemented, which is molded with barrel contents are filled, the body portion integrally with the lower end of the body portion The leg portion is composed of a lower end allowance in which the lower ends of the pouch sheets are bonded to each other, and the leg portion is cut upward from the lower end so as to divide the leg portion in the width direction. When the aerosol valve is connected to the inner container and placed on the bottom surface of the outer container, the position when the aerosol valve is fixed to the outer container supported by the legs of the inner container To be higher Is configured, upon securing the aerosol valve to the outer container, it is characterized in that the legs of the inner container which is divided into a plurality by the notches are deflected. Moreover, it is preferable that the said inner container is accommodated in the outer container by folding or rounding along an incision. Moreover, it is preferable that a plurality of the cuts are provided. Moreover, it is preferable that the said pouch is formed with the broken line extended in an up-down direction along the said notch.

In such a double aerosol container, the incision is preferably triangular or arcuate.

Also, the width of the pouch of the double aerosol container of the present invention, larger than the barrel portion inner diameter of the outer container is preferred. Moreover, it is preferable that the both ends of the said leg part are cut off. Furthermore, it is preferable to provide two internal containers.

  The method of manufacturing a double aerosol product of the present invention for filling a double aerosol container with contents and a propellant is to connect the inner container and an aerosol valve and insert the inner container into the outer container in that state. Is placed on the bottom of the outer container to secure a gap between the aerosol valve and the outer container, and from the gap between the aerosol valve and the outer container to the pressure chamber between the outer container and the inner container. The aerosol valve is lowered while being bent on the leg portion, and is fixed on the outer container, and the contents are filled into the inner container.

  The double aerosol container according to the present invention includes a body part in which the inner container is filled with contents, and a leg part integrally formed with the body part at a lower end of the body part, and the aerosol valve; When the inner container is connected and placed on the bottom surface of the outer container, it is supported by the legs of the inner container and is configured to be above the position when the aerosol valve is fixed to the outer container. When the aerosol valve is fixed to the outer container, the leg portion of the inner container is bent, so that the body portion of the inner container is hardly deformed and can be incorporated into the outer container without being particularly bent. When filling the inner container with the stock solution, the inner container can surely swell and be filled with a predetermined amount, and the inner container will not be broken due to local filling pressure. Moreover, since the inner container is an integrally molded product, the process of incorporating the inner container is simple.

A dual aerosol container of the present invention, a pouch is molded by the internal container attaching the flexible sheet, in the case of a combined lower Hadai laminated sheets lower ends of the pouch and leg The structure of the inner container is simple.
Internal Then, the lower end Hadai a dual aerosol container and leg, if the cut upward from the lower end to the leg portion is formed, since the leg portions by cuts divided into a plurality of the legs Can firmly support the container. Moreover, since the intensity | strength of the up-down direction of leg part itself can be adjusted, it is easy to bend.
Even when a horizontal fold line is formed on the leg, the vertical strength of the leg can be adjusted and the leg is easily bent.
Further, when the width of the pouch is larger than the inner diameter of the body portion of the outer container, when the pouch is inserted into the outer container, a part of the pouch comes into contact with the inner surface of the outer container. Therefore, the pouch is supported horizontally on the inner surface of the outer container by its own elastic force.

  The double aerosol product manufacturing method for filling the double aerosol container of the present invention with the contents and the propellant is to connect the inner container and the aerosol valve, and in that state, insert the inner container into the outer container, The leg is placed on the bottom of the outer container to secure a gap between the aerosol valve and the outer container, the propellant is filled into the pressure chamber between the outer container and the inner container from the gap, and the leg is bent. However, the aerosol valve is lowered to cover the outer container and fixed, and the contents are filled into the inner container, so there is no irregular deformation such as bending of the inner container and the contents are filled with a certain amount without fail. Therefore, problems such as tearing of the inner container due to the filling pressure do not occur, and a stable double aerosol product can be produced. In particular, when the notch is provided in the leg part, the aerosol valve and the inner container are supported by the divided leg parts, so that the horizontal blur of the inner container and the aerosol valve is small and the propellant is filled. Sometimes a filling seal formed between the propellant filling mechanism and the aerosol valve is likely to be obtained. Further, even when the width of the pouch is larger than the inner diameter of the barrel of the outer container, when the inner container is inserted into the outer container, a part of the pouch of the inner container comes into contact with the inner surface of the outer container, and the inner container and the aerosol valve The blur in the horizontal direction is reduced.

1a is a side sectional view showing an embodiment of an aerosol container of the present invention, FIG. 1b is a sectional view taken along line AA, FIG. 1c is an assembled view of FIG. 1a, and FIG. It is an undercup filling process figure. 2a is a front view showing the pouch of FIG. 1, FIG. 2b is a front view showing a lower portion of the pouch folded, and FIGS. 2c to 2e are front views and side views showing the connecting members of FIG. 1, respectively. 2f and g are front views showing other embodiments of cuts that can be employed in the pouch of FIG. 1, and FIG. 2h is a front view showing a lower portion of the pouch of FIG. 2f in a folded state. It is. Figure 3a is a side sectional view showing a reference example of d azole container is an assembled view of FIG. 3b Fig. 3a, Fig. 3c is a under-cup filling process diagram of Figure 3a, Figure 3d legs of Figure 3a 3e is a side view showing a state where the leg portion of FIG. 3a is bent, and FIG. 3f is a side view showing another reference example that can be adopted as the leg portion of FIG. 3a. Figure 4a is a side sectional view showing a reference example of d azole vessel, Figure 4b is an under the cup filling process diagram of Figure 4a. FIG. 5a is a side sectional view showing still another embodiment of the aerosol container of the present invention, and FIG. 5b is an under cup filling process diagram of FIG. 5a. 6a is a front view showing the inner container of FIG. 5a, FIG. 6b is a front view showing the folded state of FIG. 6a, and FIG. 6c is a bottom view of FIG. 6b. FIG. 7a is a partial side cross-sectional view showing still another embodiment of the aerosol container of the present invention, and FIG. 7b is an undercup filling process diagram of FIG. 7a. 8a and 8b are a plan view and a side sectional view showing the valve holder of FIG. 7a, respectively. 9a and 9b are respectively a front view and a side sectional view showing an inner container that can be used in the aerosol container of the present invention.

  A double aerosol container 10 in FIG. 1 a includes an outer container 11, an inner container 12 accommodated in the outer container 11, and an aerosol valve 13 connected to the opening of the inner container 12 and fixed to the outer container 11. It consists of.

As shown in FIG. 1c, the outer container 11 includes a cylindrical body portion 11a having a bottom surface, a tapered shoulder portion 11b formed at the upper end thereof, and a cylindrical neck portion 11c formed at the upper end thereof. The upper end of the neck 11c is an opening. Moreover, the recessed part 11d formed in cyclic | annular form is formed in the outer periphery of the neck part 11c. Such an external container 11 is integrally formed from a metal plate such as aluminum or tinplate by impact processing, drawing processing or the like. However, a plurality of members connected by double winding may be used. Moreover, although you may shape | mold with other materials, such as a synthetic resin and pressure | voltage resistant glass, the hard body which has pressure | voltage resistance is preferable.
The inner diameter of the body 11a of the outer container 11 is 1.2 to 3 times the inner diameter of the neck 11c,
It is 1.3 to 2.5 times.

  As shown in FIG. 2a, the inner container 12 includes a bag-like pouch 16 formed by bonding two flexible sheets 12a, and a cylindrical connecting member 17 attached to the opening 16a. (See FIGS. 2c-e).

  As shown in FIG. 2a, the pouch 16 includes a pasting allowance 18 in which the peripheral edges of two sheets 12a are pasted together, and a rectangular storage portion 19 surrounded by the pasting allowance 18. An opening 16a formed by a gap between the sheets is provided. That is, the trunk portion of the pouch is formed by left and right pasting. And the leg part 18a is comprised by the lower end sticking allowance which bonded the lower ends of the sheet | seat 12a. Two cuts 15 extending upward from the lower end are formed in the leg portion 18a at equal intervals. Further, the pouch 16 is formed with a loose broken line 15 a extending in the vertical direction along the notch 15. Here, the loose polygonal line refers to a polygonal line formed so as to have elasticity in the opening direction of the pouch 16. The pouch 16 is inserted into the outer container as shown in FIG. In FIG. 2a, the slit 18 or the rectangular cut 15 is provided in the leg portion 18a. However, as shown in FIGS. 2f and 2g, a triangular cut 15b or an arc cut 15c may be provided. Moreover, you may provide the cut of the shape of the half of the cut 15 in the both ends of a leg part. In that case, as shown in FIG. 2h, both corners of the lower end of the folded pouch 16 are cut off, which makes it easy to insert into the external container. Moreover, it can be made into the same shape in the folded state, it is easy to adjust the size of the leg part, and it is easy to adjust the holding force by the leg part. In addition, the leg part 18a does not show the rib effect of the up-down direction by a broken line.

The height of the pouch 16 is configured to be lower than the height of the body portion 11a of the outer container, that is, to be accommodated in the body portion 11a. Further, as will be described later, the connecting body 20 connecting the inner container 12 and the aerosol valve 13 is slightly above the position when the aerosol valve 13 is fixed to the outer container 11 (distance X in FIG. 1c). The pouch 16 is larger than the conventional one. However, a pouch 16 having a conventional size may be employed to enlarge the connecting member 17 or the aerosol valve 13.
The width of the pouch 16 is configured to be larger than the inner diameter of the body portion 11a of the outer container. In particular, the inner diameter is 1.2 to 3 times, preferably 1.5 to 2.5 times the inner diameter of the body 11a of the outer container. As a result, when the pouch 16 is inserted into the outer container 11, the pouch 16 expands, and a part of the pouch reliably contacts the inner surface of the outer container, and the elastic force causes the pouch 16 to move horizontally in the outer container. Supported. That is, when the pouch 16 is accommodated in the trunk portion 11a, the pouch 16 comes into contact with at least two locations on the inner surface of the outer container while the pouch 16 is lightly folded along the folding line 18a. If it is smaller than 1.2 times, the pouch 16 may come into contact with the outer container only at one place. When it becomes larger than 3 times, the pouch 16 is difficult to expand, and the capacity of the storage unit 19 is wasted. In this embodiment, the width of the pouch 16 is larger than the inner diameter of the body portion 11a of the outer container. However, the present invention may be smaller than the inner diameter of the body portion. In this case, horizontal support cannot be obtained.

  Examples of the sheet 12a used for the pouch include a single layer or a laminated sheet made of a synthetic resin, or a laminated sheet made of a metal foil layer and a synthetic resin layer. In particular, the metal foil includes a light metal such as an aluminum foil. Examples of the synthetic resin include polyethylene and polypropylene excellent in chemical resistance, polyethylene terephthalate, nylon and eval excellent in gas barrier properties, and the like may be selected according to the contents and used in combination. In addition, it is good also as a vapor deposition layer which vapor-deposits carbon, a silica, an alumina, etc. on a synthetic resin layer instead of a metal foil layer, and forms a film. Further, the sheets 12 are adhered to each other by welding or an adhesive. In particular, when a laminated sheet having a metal foil (layer) is used, the shielding effect is high, and various contents can be stably stored.

As shown in FIGS. 2c to 2e, the connecting member 17 is provided with a cylindrical sticking portion 21 fixed to the opening of the pouch 16, and an aerosol valve which is provided coaxially above the sticking portion 21 and will be described later. 13 includes a cylindrical valve connecting portion 22 connected to the lower end of 13, and a cylindrical intermediate portion 23 provided coaxially between the sticking portion 21 and the valve connecting portion 22. The center hole of the sticking part 21, the intermediate | middle part 23, and the valve | bulb connection part 22 is connecting. The connecting member 17 is an integrally molded product.
The sticking part 21 is a substantially rhombus-shaped thing, and the horizontal rib 21a extended in a horizontal direction is formed in the side surface. A sheet 12 a of the pouch 16 is attached to the outer peripheral surface of the attaching part 21. Moreover, the flange part 21b is formed in the upper end. This flange part 21b specifies the sticking position of the pouch 16, and the pouch 16 can be reliably stuck to the sticking part 21 by this.
The valve connection part 22 is a cylindrical thing, and the flange part 22a is formed in the lower end.
The intermediate part 23 has a rectangular parallelepiped shape. Since the intermediate portion 23 has a rectangular parallelepiped shape, it is easy to grip with a finger or the like, and the internal container 13 is easy to handle. The intermediate portion 23 may not be provided. Either the flange portion 21b of the sticking portion 21 or the flange portion 22a of the valve connecting portion 22 is omitted. Any of these may be omitted.
Examples of the connecting member 17 include stainless steel coated with an adhesive resin such as polyester, polyurethane, and polyolefin, or synthetic resin such as polyacetal and nylon.

Referring back to FIG. 1b, the aerosol valve 13 includes a cylindrical housing 13a, a stem 13b accommodated in the housing so as to be movable up and down, a spring 13c that constantly biases the stem upward, and a stem hole in the stem. And a cup-shaped valve cap 13f that is fixed to the opening of the outer container 11 as a whole. The aerosol valve 13 closes the outer container 11 via a gasket 14 provided at the upper edge of the outer container 11 (see FIG. 1a).
At the lower end of the housing 13a, a cylindrical communication portion 26a that protrudes downward and connects the inside and the outside of the housing is formed. By inserting this communication portion 26 a into the valve connecting portion 22 of the connecting member 17, the aerosol valve 13 and the inner container 12 are connected.
Further, a stepped portion 26b that engages with the inner surface of the recess 11d of the outer container 11 is formed in an annular shape on the side surface of the housing 13a. The aerosol valve 13 is supported by the recess 11d of the outer container.

The filling process of the contents and the propellant into the double aerosol container 10 configured as described above will be described below. First, the connecting body 20 is assembled by connecting the inner container 12 and the aerosol valve 13. Next, the pouch 16 of the inner container 12 is folded or rolled along the fold line 18a. At this time, it may be lightly held in a folded state with a tape or the like. Thereby, an insertion process can be simplified. With the inner container 12 folded, the inner container 12 is inserted into the outer container 11 (see FIG. 1c).
As shown in FIG. 1d, the inserted connecting body 20 is placed on the bottom surface of the trunk portion 11a of the outer container 11, and is slightly above the position when the aerosol valve 13 is fixed to the outer container 11 (distance X). Placed in. In particular, since the pouch 16 has a width larger than the inner diameter of the outer container 11, the pouch 16 stands in the outer container 11 in a slightly bent state even if the pouch 16 is not fixed in a folded state with a tape or the like. Therefore, even if the pouch 16 is made of the flexible sheet 12a, the aerosol valve 13 is sufficiently supported. Further, since the leg portion 18a is divided into a plurality of parts by cutting, the aerosol valve 13 is stably supported. Furthermore, since the pouch 16 is supported on the inner side surface of the outer container, the radial direction of the outer container is also supported, and the aerosol valve 13 is less likely to shake. When the inner container 12 is inserted in a folded state with a tape or the like, there is no such support.

Thus, since the aerosol valve 13 is disposed with a gap from the outer container 11, the propellant B is filled between the outer container 11 and the inner container 12 (under-cup filling) (in the direction of the arrow in FIG. 1d). At this time, it is not necessary to lift the aerosol valve 13.
After filling the propellant with the propellant filling mechanism, the aerosol valve 13 is pressed toward the outer container 11 (downward) so that the lower end of the cap 13f of the aerosol valve 13 is brought into contact with the recess 11d of the outer container 11. By caulking, the aerosol valve 13 is fixed to the outer container 11. At this time, the leg portion 18a of the inner container bends by absorbing at least a part of the downward pressing force. In particular, the pouch 16 is in the outer container in a lightly folded or rolled state, and its gentle fold line exerts a rib-like action on the force in the vertical direction. Since the cut 15 is formed, the leg portion 18a is more easily bent than the trunk portion. Thus, by suppressing the bending of the body part (storage part) of the internal container, the body part (storage part) of the internal container can be prevented from being bent, and the change in volume can be reduced.
Finally, the contents are filled into the inner container 12 from the stem 13 b of the aerosol valve 13. At this time, the inner container swells and its volume increases, but there is little deformation of the body of the inner container when caulking the aerosol valve, and there is no particular bending, so the inner container can swell smoothly, ensuring the contents A predetermined amount can be filled. This method is preferable when compressed gas is used as the propellant, and the volume of the storage unit 19 is increased by filling the propellant (compressed gas) at 0.2 MPa to 0.4 MPa and then filling the contents. In addition, the space between the outer container 11 and the inner container 12 is reduced, and the product pressure can be increased to 0.5 to 1.0 MPa. However, the contents may be filled before filling with the propellant.
Further, when the inner container 12 is inserted, if it is held in a folded state with a tape or the like, the folded state with the tape or the like is released by filling the contents.

  As described above, the double aerosol container 10 has the pouch 16 of the inner container 12 larger than the inner diameter of the outer container 11, so that the inner container 12 is stored in a slightly folded state in the outer container 11. The aerosol valve 13 can be reliably supported. Therefore, the undercup filling can be performed smoothly. Further, when the aerosol valve is fixed after filling the propellant, the leg portion 18a other than the storage portion 19 (body portion) filled with the contents is bent, so that the volume of the storage portion can be made constant. In addition, the inner container 12 and the aerosol valve 13 can be reliably connected, and an aerosol product can be manufactured stably.

  The double aerosol container 30 of FIG. 3 is a blow molded body in which an inner container 31 is formed by blow molding a synthetic resin parison. The configuration of the outer container 11 and the aerosol valve 13 is substantially the same as that of the outer container 11 and the aerosol valve 13 of FIG.

As shown in FIG.3b, the inner container 31 includes a bottom 31a, a cylindrical body 31b, a tapered shoulder 31c formed at the upper end thereof, and a cylindrical neck 31d formed at the upper end thereof, It consists of a cylindrical opening 31e whose diameter is larger than that of the neck. The lower portion of the body portion 31b is tapered so as to reduce in diameter downward, and a pinch-off portion 32 protruding downward is provided on the bottom portion 31a. The pinch-off part 32 is a planar part that passes through the center of the bottom part 31a and extends parallel to the diameter of the bottom part 31a. A notch 33 extending upward from the lower end is formed in the center of the pinch-off portion 32. The lower part 33a of the pinch-off part 32 divided by the notch 33 is easily bent by receiving a force in the vertical direction. That is, the pinch-off part 32 becomes a leg part. Further, when the inner container 31 is used, it is preferable that the lower portion 33a of the pinch-off portion 32 divided by the notch 33 is bent or bent in the opposite directions as shown in FIG. 3d.
The inner container 31 is configured such that the upper end of the inner container 31 protrudes from the outer container 11 when placed on the bottom surface of the outer container 11.

The filling process of the contents and the propellant into the double aerosol container 30 configured as described above will be described below. First, the inner container 31 is inserted into the outer container 11 (see FIG. 3b). Next, as shown in FIG. 3 c, the aerosol valve 13 is placed on the opening of the inner container 31. At this time, since the opening 31 e of the inner container 31 protrudes from the upper end of the outer container 11, the aerosol valve 13 is also disposed slightly above (distance X) from the position when it is fixed to the outer container 11. Thus, since the aerosol valve 13 is arranged with a gap from the outer container 11, the aerosol valve 13 is filled when the propellant B is filled between the outer container 11 and the inner container 12 (in the direction of the arrow in FIG. 3c). There is no need to lift up. Reference numerals 30a and 30b denote a holder and a seal part of the propellant filling mechanism, respectively.
After filling the propellant with the propellant filling mechanism, the aerosol valve 13 is pressed in the direction of the outer container 11, and the lower end of the cap 13 f of the aerosol valve 13 is caulked so as to contact the concave portion 11 d of the outer container 11. The aerosol valve 13 is fixed to the outer container 11. At this time, since the notch 33 is provided in the pinch-off part 32, the lower part 33a of the pinch-off part bends preferentially over other parts of the inner container (see FIGS. 3d and 3e). Therefore, irregular deformation such as bending of the body portion of the inner container 31 can be minimized and stored in the outer container 11. In this state, the air in the inner container may be discharged from the aerosol valve, and since the inner container is not irregularly deformed, it regularly contracts as the air is discharged, and the filling of the stock solution described later is smooth. It can be carried out.
Finally, the contents are filled into the inner container 31 from the stem 13 b of the aerosol valve 13. However, the contents may be filled before the propellant is filled, or before the aerosol valve 13 is placed on the inner container 31.

As described above, the double aerosol container 30 is configured such that the inner container 31 is housed in the outer container 11 by bending the lower part 31a of the pinch-off portion, so that the degree of deformation of the body part of the inner container 31 can be reduced. Irregular bending of the part and volume change can be minimized. Therefore, it is difficult for the contents to leak at the time of filling, the inner container 31 and the aerosol valve 13 to be disconnected, or sweetened.
In the above reference example , the pinch-off portion 32 is cut, but as shown in FIG. 3f, the pinch-off portion 32 may be provided with a horizontal broken line 33b or a recessed groove so that the pinch-off portion 32 can be easily bent by a downward force. These broken lines and recessed grooves can be processed when a blow-molded pinch-off part is formed.

The double aerosol container 35 of FIG. 4a consists of an outer container 36 with a bead portion, a pouch-type inner container 37, and an aerosol valve 38 with a mounting cup that engages with the bead portion of the outer container.
As shown in FIG. 4b, the outer container 36 includes a cylindrical body portion 36a having a bottom portion and a tapered shoulder portion 36b. A bead portion 36c is formed at the upper end of the shoulder portion, and the bead portion 36c. Constitutes an opening. A cylindrical neck may be provided between the shoulder and the bead. Such an external container 36 is also formed from a metal plate such as aluminum by impact processing, drawing / ironing processing or the like.
The inner container 37 is opened without bonding the two sheets 12 at the lower portion of the pasting allowance 37b at the lower end of the pouch 37a, and the opened portion is used as a leg portion 37c. Further, the width of the pouch 37a (perpendicular to the paper surface) is larger than the inner diameter of the bead portion 36c (opening) and smaller than the inner diameter of the body portion 36a. Therefore, the inner container 37 is not supported in the horizontal direction in the outer container 36. The other structure is substantially the same as the inner container 12 of FIG. 1, and the connecting member 17 is connected to the pouch 37a. In addition, the width of the pouch 37a can be made larger than the inner diameter of the body portion 36a.
The aerosol valve 38 includes a mounting cup 38a that is crimped to the bead portion 36c of the outer container, a housing 38b that is held at the center of the mounting cup, a stem 38c that is movably moved up and down in the housing, and the housing It is provided at the upper end of 38b and comprises a stem rubber (not shown) that opens and closes the stem hole and a spring (not shown) that constantly biases the stem upward. The stem, stem rubber, and spring are substantially the same as the double aerosol container of FIG. At the lower end of the housing 38b, a cylindrical communication portion 39 that connects the housing and the outside is formed. By connecting the connecting member to the communicating portion, the aerosol valve and the pouch can be handled as a unit.
Since it is comprised in this way, it fills with the contents and propellant like FIG.

The double aerosol container 40 of FIG. 5 a includes an outer container 41 made of synthetic resin, an inner container 42, and an aerosol valve 43. The aerosol valve 43 is substantially the same as the aerosol valve 13 of FIG.
The outer container 41 includes a spherical bottom 41a, a cylindrical body 41b, a tapered shoulder 41c that closes upward, a cylindrical neck 41d, and a cylindrical mouth (opening) 41e. have. Further, a support step portion 41g is formed between the bottom portion 41a and the body portion 41b. The inner surface of the mouth portion 41e has the same diameter as the inner surface of the neck portion, and the outer surface of the mouth portion 41e is configured to be larger than the neck portion. That is, the mouth portion 41e is configured to be thicker than the neck portion 41d, and the trunk portion 41b is configured to be thinner than the shoulder portion 41c and the neck portion 41d. Such an outer container 41 is formed by molding a preform by injection molding using a synthetic resin such as polyethylene terephthalate, and further molding the preform by biaxial stretch blow molding. Further, an annular protrusion 45 is formed on the upper surface of the mouth portion 41e. Since the outer container 41 is made of synthetic resin, it may have translucency, in which case the bulging state of the inner container can be seen and the remaining amount of contents can be confirmed. A ring-shaped seal member 41h is provided on the upper surface of the mouth portion 41e.
The inner diameter of the mouth portion 41e and the neck portion 41d of the outer container is 8 to 35 mm, particularly 10 to 30 mm, and the inner diameter of the body portion 41b of the outer container is 20 to 50 mm, particularly 25 to 45 mm. And the internal diameter of the trunk | drum 41b will be 1.2 to 4 times, especially 1.5 to 3.5 times the internal diameter of the opening part 41e.

  As shown in FIG. 6a, the inner container 42 has four cuts 44b formed in the leg portions 44a of the pouch 44, and four loose broken lines 42c. The inner container 42 is folded into five and inserted into the outer container 41 as shown in FIGS. 6b and 6c. In FIG. 6b, the code | symbol 46 is a tape which hold | maintains the inner container 42 in the folded state. Other configurations are substantially the same as the inner container 11 of FIG.

  In this double aerosol container 40, since the inner container 42 is folded into five, even a small opening like the outer container 41 can be easily inserted. And since the notch is made | formed in the leg part along the broken line, the leg part is easy to bend. The contents and the propellant filling method are substantially the same as the double aerosol container 10 of FIG.

  The double aerosol container 50 shown in FIG. 7a includes an outer container 51, two inner containers 12 accommodated therein, two aerosol valves 13 connected to the respective inner containers, and an opening of the outer container 51. And a mountain cover 53 that covers the aerosol valve 13 and the valve holder 52 and attaches the valve holder 52 to the external container 51. The inner container 12 and the aerosol valve 13 are substantially the same as the inner container 12 and the aerosol valve 13 of FIG.

The outer container 51 has a cylindrical body portion 51a, a tapered shoulder portion 51b that closes upward, a cylindrical neck portion 51c, and a cylindrical mouth portion (opening portion) 51d. The inner container 51d has an inner diameter of 20 to 45 mm, particularly 25 to 40 mm, and the outer container body 51a has an inner diameter of 25 to 50 mm, particularly 30 to 45 mm. And the internal diameter of the trunk | drum 51a is 1.2 to 2.5 times, especially 1.3 to 2 times from the internal diameter of the opening part 51d. Other configurations are substantially the same as those of the outer container 41 of FIG.
As shown in FIGS. 8a and 8b, the valve holder 52 has a columnar base portion 52a and two cylindrical holder portions 52b formed so as to vertically penetrate the base portion. The base 52 a is a part that is fixed to the upper end of the outer container 51 by the mountain cover 53. The holder 52b is for inserting and holding the aerosol valve 13.
The base portion 52a includes a columnar main body 56 and a cylindrical seal portion 57 extending downward from the lower end thereof, and a flange portion 56a protruding outward is formed at the lower portion of the main body 56. An annular recess 57 a for inserting an annular gasket 58 is formed on the outer periphery of the seal portion 57. The gasket 58 is a ring-shaped sealing material having a circular cross section. That is, by inserting the seal portion 57 into the outer container 51 with the gasket 58 fitted in the annular recess 57a, the gasket 58 comes into contact with the inner surface of the outer container 51, and the valve holder 52, the outer container 51, Seal between.

  The holder part 52b is a part that receives and holds the aerosol valve 13, and includes an upper cylinder part 59a, a lower cylinder part 59b having a diameter smaller than that of the upper cylinder part 59a, a lower end of the upper cylinder part 59a, and an upper cylinder part 59b. It consists of the annular step part 59c which continues an upper end. The holder portion 52b supports the aerosol valve 13 by an annular step portion 59c.

The filling process of the contents and the propellant into the double aerosol container 50 configured as described above will be described below. First, the pre-folded inner container 12 and the aerosol valve 13 are connected with the valve holder 52 interposed therebetween. At this time, the inner container 12 is lightly held in a folded state with a tape or the like. Next, the valve holder 52 is placed on the outer container 51 (see FIG. 7b).
In this state, the aerosol valve 13 is disposed slightly above (distance X) above the holder portion 52 b of the valve holder 52 with the leg portions 18 a of the respective inner containers 12 placed on the bottom surface of the outer container 51. In this state, the propellant is injected from the lower end of the mounting cover 53, and the outer container is filled with the propellant through the holder portion 52b of the valve holder (arrow in FIG. 7b).
After filling the propellant with the propellant filling mechanism, the aerosol valve 13 is pressed toward the outer container 51 (valve holder 52) (downward), and the lower end of the mounting cover is brought into contact with the boundary between the neck and mouth of the outer container 51. By caulking in contact with each other, the valve holder 52 and the aerosol valve 13 are fixed to the outer container 11. At this time, the leg 18a (see FIG. 2a) of the inner container absorbs and bends at least a part of the downward pressing force, so that the inner container body is not bent or irregularly deformed. The stock solution described later can be filled smoothly.
Finally, two different kinds of contents are filled into the inner container 12 from the stem 13b of each aerosol valve 13. However, the contents may be filled before filling with the propellant. When the inner container 12 is inserted and held in a folded state with a tape or the like, the folded state with the tape or the like is released by filling the contents.

FIG. 9 shows a two-pack storage type internal container that can be used in the double aerosol container of the present invention.
The pouch 61 of the inner container 60 is obtained by stacking three sheets 12a (lower sheet, middle sheet, and upper sheet) and pasting the peripheral edges of each sheet. Moreover, two cuts 61a are formed in the lower end pasting allowance, and two broken lines 61b are formed along it. Other configurations are substantially the same as the pouch 16 of FIG. Since it is configured in this manner, the storage portions 62a and 62b for the contents are formed by the lower sheet 12a and the middle sheet 12b, and the middle sheet 12b and the upper sheet 12c, respectively.
The connecting member 63 of the inner container 60 is fixed to the upper end of the inner container so as to close the upper end openings of the storage portions 62a and 62b of the pouch 61 and communicate them independently from the outside. The connecting member 63 is an integrally formed product including a columnar attaching portion 66 to which the pouch 61 is attached and a cylindrical valve connecting portion 67 that is connected to the communicating portion 26 a of the aerosol valve 13. The sticking portion 66 includes a slit 66a extending upward from the lower end, and a first passage 66b and a second passage 66c that are formed across the slit and penetrate the sticking portion 66 vertically. . That is, the sticking portion 66 can be divided into a first plug portion that closes the storage portion 62a and a second plug portion that closes the storage portion 62b with the slit 66a as a boundary, and the first plug portion and the second plug portion, respectively. A first passage 66b and a second passage 66c are formed. A central hole 67a of the valve connecting portion 67 communicates with the first passage 66b and the second passage 66c.

  By using such an inner container 60 for a two-component aerosol valve, a double aerosol container for discharging two liquids is completed. Even with such a double aerosol container, the contents and the propellant can be filled in the same manner as the double aerosol container of FIG.

B propellant X distance 10 double aerosol container 11 outer container 11a trunk 11b shoulder 11c neck 11d recess 12 inner container 12a seat 13 aerosol valve 13a housing 13b stem 13c spring 13e stem rubber 13f cap 15 notch 15a bent line 16 Part 17 Connecting member 18 Pasting allowance 18a Leg part 19 Storage part 20 Connecting body 21 Adhering part 21a Horizontal rib 21b Flange part 22 Valve connecting part 22a Flange part 23 Intermediate part 26a Communication part 26b Step part 30 Double aerosol container 30a Propellant Holder for filling mechanism 30b Sealing part 31 for propellant filling mechanism 31 Inner container 31a Bottom part 31b Body part 31c Shoulder part 31d Neck part 31e Opening part 32 Pinch-off part 33 Notch 35 Double aerosol container 36 External Container 36a Body part 36b Shoulder part 36c Bead part 37 Internal container 37a Pouch 37b Pasting 37c Leg part 38 Aerosol valve 38a Mounting cup 38b Housing 38c Stem 39 Communication part 40 Double aerosol container 41 External container 41a Bottom part 41b Body part 41c Body part 41c 41d neck part 41e mouth part 41g support group part 41h seal member 42 inner container 42c polygonal line 43 aerosol valve 44 pouch 44a leg part 44b cut 45 annular projection 46 tape 50 double aerosol container 51 outer container 51a trunk part 51b neck part 51c neck part 51c Part 52 Valve holder 52a Base part 52b Holder part 53 Mountain cover 56 Main body 56a Flange part 57 Seal part 57a Annular recess 58 Gasket 59a Upper tube part
59b Lower cylinder part 59c Annular step part 60 Inner container 61 Pouch 62a, b Storage part 63 Connection member 66 Adhering part 66a Slit 66b 1st channel | path 66c 2nd channel | path 67 Valve connection part

Claims (9)

An external container;
An inner container housed in the outer container;
A double aerosol container comprising an aerosol valve connected to the opening of the inner container and secured to the outer container;
The inner container is a flexible pouch sheet is molded been cemented, and the body which contents are filled, and a leg portion which is molded into the body portion integrally with the lower end of the body portion Has
The leg part consists of a lower end pasting allowance in which the lower end of the pouch sheet is bonded together,
The leg is formed with a notch extending upward from the lower end so as to divide the leg in the width direction .
When the aerosol valve and the inner container are connected and placed on the bottom surface of the outer container, the aerosol valve is supported by the leg of the inner container and is positioned above the position when the aerosol valve is fixed to the outer container. Configured,
When the aerosol valve is fixed to the outer container, the legs of the inner container divided into a plurality by the notch are bent,
Double aerosol container. The double aerosol container according to claim 1, wherein the inner container is accommodated in the outer container by being folded or rounded along a cut. The double aerosol container according to claim 1 or 2, wherein a plurality of the cuts are provided. The double aerosol container according to any one of claims 1 to 3, wherein the pouch is formed with a polygonal line extending in the vertical direction along the cut. The double aerosol container according to any one of claims 1 to 4, wherein the cut has a triangular shape or an arc shape. The double aerosol container according to any one of claims 1 to 5, wherein a width of the pouch is larger than a body inner diameter of the outer container. The double aerosol container according to any one of claims 1 to 6, wherein both end portions of the leg portion are cut off. The double aerosol container according to any one of claims 1 to 7, comprising two inner containers. A method for producing a double aerosol product, wherein the double aerosol container according to any one of claims 1 to 8 is filled with contents and a propellant,
Connecting the inner container and the aerosol valve;
In that state, the inner container is inserted into the outer container, and the legs are placed on the bottom of the outer container to secure a gap between the aerosol valve and the outer container,
Fill the pressurization chamber between the outer container and the inner container from the gap with a propellant,
While bending the legs, lower the aerosol valve to cover the outer container and fix it.
Filling the contents into the inner container,
Manufacturing method for double aerosol products.

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