JP7186577B6 - discharge container - Google Patents

Description

The present invention relates to a dispensing container with a pressure regulating device.

Patent Literature 1 discloses a discharge container provided with a pressure regulating device that keeps the inside of the container at a predetermined pressure. In the mechanism of pressure regulation in Patent Document 1, a sealed chamber is formed by slidably inserting a piston into a cylindrical cylinder with a bottom, which is housed in a container. The pressurizing agent is replenished into the container by utilizing the sliding of the piston caused by the pressure difference.

With such a mechanism, when the pressure in the container and the pressure in the sealed chamber are balanced, the piston does not slide and the pressurizing agent is not replenished, and the undiluted solution in the container is discharged and the pressure in the container is discharged. When the pressure drops, the piston slides and the pressurizing agent is replenished, so the inside of the container can be kept at a predetermined pressure. The pressurizing agent is replenished from a gas container housed in the container. Specifically, the gas container is provided with an aerosol valve, and the stem of the aerosol valve is pushed in by sliding of the piston, so that the pressurizing agent is released from the gas container into the container.

International Publication 2017/061538

11 and 12 of Patent Document 1, the gas container is arranged above the piston (valve assembly side) in the cylinder so that the gas container can be easily removed from the container. ing. Such an arrangement allows access to the gas container without removing the piston from the cylinder.

However, since the sealed chamber is positioned below the cylinder, foreign matter may enter the sealed chamber. For example, the side surface of the cylinder is provided with a communication hole that communicates the inside of the cylinder with the inside of the container in order to supply the pressurizing agent released from the gas container into the container. The undiluted solution may enter the cylinder through this communication hole, and at this time, if the piston is positioned above the communication hole due to replacement of the gas container, etc., and the sealed state of the sealed chamber is released, the cylinder may The undiluted solution accumulates at the bottom, and the capacity of the sealed chamber changes (decreases), which may interfere with pressure regulation.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a discharge container that allows easy access to the gas container and allows the pressure regulator to function normally.

The discharge container of the present invention includes a container body 10 having an opening 10a, a valve assembly 20 attached to the opening 10a of the container body 10 and having a valve mechanism 21, and a pressurizing agent P contained in the container body 10. and a pressure regulating device 40 attached to the gas container 30 that maintains the pressure in the container body 10 by releasing the pressurizing agent P in the gas container 30 into the container body 10. , a discharge container in which the gas container 30 can be replaced by removing the valve assembly 20, wherein the pressure adjusting device 40 is suspended from the opening 10a of the container body 10 and accommodates the gas container 30; A sealed chamber R is formed between a holder 41 that communicates with the inside of the holder 41 and a bottomed cylinder 42 that communicates with the inside of the holder 41 and continues to the lower end of the holder 41 and a bottom portion 42 a of the cylinder 42 . A piston 43 that slides in the cylinder 42 due to the internal pressure difference to open and close the gas container 30 by sliding, and an escape prevention means that prevents the piston 43 from slipping out of the cylinder 42 and maintains the sealed state of the sealed chamber R. It is characterized by comprising E.

Moreover, it is preferable that the retaining means E is formed of a retaining stepped portion S formed in the holder 41 or the cylinder 42 . Moreover, it is preferable that the coming-off prevention means E includes a guide portion (the guide tube portion 44a and the connection tube 41A2) that guides the sliding movement of the piston 43. As shown in FIG. Further, the cylinder 42A may be fitted to the lower end of the holder 41A (connection tube 41A2), and the lower end of the holder 41 may be formed with a drop-off preventing means E. In addition, it is preferable that the piston 43 has a shaft portion 43b that protrudes toward the holder 41 beyond the removal prevention means E. As shown in FIG.

The piston 43 has a sliding portion 43a that slides in the cylinder 42 while maintaining the sealed state of the sealed chamber R, and a stem insertion portion 43c into which the stem 32a of the gas container 30 is inserted. , the frictional force between the sliding portion 43a and the cylinder 42 may be made larger than the fitting force between the stem insertion portion 43c and the stem 32a. In this case, the sliding portion 43a includes a base portion 43a1 which is slightly smaller than the inner diameter of the cylinder 42, and a sliding seal member 43a2 which is compressed between the inner surface of the cylinder 42 and the base portion 43a1 to form a seal. What is provided is preferable. Alternatively, the piston 43 has a sliding portion 43a that slides in the cylinder 42 while maintaining the sealed state of the sealed chamber R, and a stem insertion portion 43c into which the stem 32a of the gas container 30 is inserted. E may be constituted by a slit 43c2 (release path) that weakens the fitting force when the stem 32a of the gas container 30 is inserted into the stem insertion portion 43c.

Since the discharge container of the present invention is provided with a removal prevention means for preventing the piston from coming off the cylinder and maintaining the closed state of the sealed chamber, the cylinder should be provided below the holder that communicates with the inside of the container body. In spite of this, it is possible to prevent foreign matter (such as undiluted solution) from entering the closed chamber. Further, since the holder for housing the gas container is provided on the cylinder for housing the piston, the gas container can be accessed without removing the piston.

If the slip-off preventing means is a stepped portion formed inside the holder or inside the cylinder, it is possible to reliably prevent the piston from slipping out of the cylinder. If the disengagement prevention means has a guide portion that guides the sliding of the piston, the sliding of the piston is stabilized and the pressure regulator can function normally. If the cylinder is externally fitted to the lower end of the holder and the lower end of the holder is formed with the anti-disengagement means, the manufacture is easy. Further, even if the opening of the container body and the size of the gas container are different, the cylinder can be used in common. If the piston has a shaft portion that projects toward the holder side beyond the removal prevention means, the gas container housed in the holder can be maintained even if the movement of the piston upward (toward the holder side) is restricted by the removal prevention means. can be pushed upward by the shank, facilitating access to the gas container.

The piston has a sliding portion that slides in the cylinder while maintaining the closed state of the sealed chamber, and a stem insertion portion into which the stem of the gas container is inserted. When the frictional force is made larger than the fitting force between the stem insertion portion and the stem, it is easy to prevent the piston from coming off when the gas container is removed.
Also, if the sliding portion has a base portion slightly smaller than the inner diameter of the cylinder and a sliding seal material that is compressed between the inner surface of the cylinder and the base portion to form a seal, The frictional force between the moving part and the cylinder is increased, and it is easy to prevent the piston from coming off when the gas container is removed.
The piston has a sliding portion that slides in the cylinder while maintaining the closed state of the sealed chamber, and a stem insertion portion that inserts the stem of the gas container. When the piston is formed of a slit that weakens the fitting force when the gas container is inserted into the gas container, it is easy to prevent the piston from coming off when the gas container is removed.

1 is a cross-sectional view showing one embodiment of a discharge container of the present invention; FIG. 4 is an exploded cross-sectional view of the valve assembly; FIG. FIG. 4 is an exploded cross-sectional view of the pressure regulating device; Fig. 4A is a cross-sectional view of a piston with two discharge passages; Fig. 4B is a piston with three discharge passages; 5A is a cross-sectional view showing a state in which the valve assembly is removed from the container body, and FIG. 5B is a cross-sectional view showing a state in which the gas container is removed from the container body. FIG. 4 is a cross-sectional view showing another discharge container of the present invention; FIG. 4 is a cross-sectional view showing another discharge container of the present invention;

Next, one embodiment of the discharge container of the present invention will be described in detail based on the drawings. The discharge container 1 of the present invention, as shown in FIG. and a gas container 30 filled with a pressurizing agent P, attached to the gas container 30, and releasing the pressurizing agent P in the gas container 30 into the container main body 10 to reduce the pressure in the container main body 10 and a constant pressure regulator 40 . Further, the discharge container 1 is designed so that the gas container 30 can be replaced by removing the valve assembly 20 .

The container body 10 is a bottomed cylindrical synthetic resin bottle having a cylindrical body portion 10b, a tapered shoulder portion 10c, and a cylindrical neck portion 10d. is provided. A thread 10e is formed on the outer periphery of the neck portion 10d to be screwed with a cap 23 of the valve assembly 20, which will be described later. The container main body 10 is filled with the undiluted liquid C. As shown in FIG.

The valve assembly 20 covers a valve mechanism 21 for communicating/blocking communication between the container body 10 and the outside air, a valve holder 22 housing the valve mechanism 21, and the valve mechanism 21 and the valve holder 22. and a cap 23 for fixing to the container body 10 .

As shown in FIG. 2, the valve mechanism 21 is an aerosol valve composed of a cylindrical stem 21a, a stem rubber 21c for closing a stem hole 21b of the stem 21a, and a spring 21d for constantly urging the stem 21a upward. By pushing the stem 21a against the urging force of the spring 21d, the blockage of the stem hole 21b by the stem rubber 21c is released, and the inside of the valve holder 22 (the inside of a housing 22a, which will be described later) communicates with the outside air. It has become.

The valve holder 22 includes a housing 22a that accommodates the stem 21a, the stem rubber 21c, and the spring 21d, and a flange portion 22b that extends outward from the side surface of the housing 22a.

The housing 22a is a cylinder with an open upper end and a bottom at its lower end. A rubber support portion 22a1 for supporting the stem rubber 21c of the valve mechanism 21 is formed at the upper end of the housing 22a. A side surface of the housing 22a is formed with a communication passage 22a2 for communication between the inside and outside of the housing 22a. An engagement groove 22a3 that engages with the cap 23 is formed on the side surface of the housing 22a above the communication path 22a2. The lower end of the housing 22a serves as a push-in portion 22a4 for pushing the gas container 30 downward (toward the cylinder 42).

The flange portion 22b extends horizontally from below the communicating passage 22a2. A passage groove 22b1 that communicates the communication passage 22a2 with the inside of the container body 10 is formed on the upper surface of the flange portion 22b. An annular first seal member (gasket) 50 having a rectangular cross section is arranged on the lower surface of the flange portion 22b. The first seal member 50 abuts on a seal projection 41a1 of the holder 41, which will be described later, and separates the inside of the holder 41 from the outside air (see FIG. 1).

The cap 23 fixes the valve mechanism 21 to the housing 22 a of the valve holder 22 and detachably fixes the valve holder 22 to the container body 10 so as to cover the valve holder 22 . Specifically, a disk-shaped upper surface portion 23a that closes the opening of the housing 22a of the valve holder 22, an upper cylindrical portion 23b that extends downward from the outer end of the upper surface portion 23a and is disposed on the outer periphery of the housing 22a, and an upper cylindrical portion 23b. It has an annular enlarged diameter portion 23c extending radially outward from the lower end of the portion 23b, and a lower cylindrical portion 23d extending downward from the outer end of the enlarged diameter portion 23c.

The upper surface portion 23a prevents the stem rubber 21c from protruding upward. A center hole 23a1 through which the stem 21a is passed is formed in the center of the upper surface portion 23a.

The upper cylindrical portion 23b is a portion that holds the housing 22a of the valve holder 22. As shown in FIG. An engaging projection 23b1 that engages with the engaging groove 22a3 of the housing 22a is formed on the inner surface of the upper tubular portion 23b. When the engagement protrusion 23b1 is engaged with the engagement groove 22a3, the valve holder 22 is restricted from coming off the cap 23. As shown in FIG. That is, the cap 23 and the bulb holder 22 are integrated.

The enlarged diameter portion 23 c is a portion for pressing the first seal member 50 against the seal protrusion 41 a 1 of the holder 41 . Although the lower surface of the enlarged diameter portion 23c and the upper surface of the flange portion 22b are in contact with each other, the communication between the inside of the housing 22a and the inside of the container body 10 is maintained because the passage groove 22b1 is formed in the upper surface of the flange portion 22b. be.

The lower tubular portion 23 d is a portion that engages with the container body 10 . A screw 23d1 to be screwed with the screw 10e of the container body 10 is formed on the inner surface of the lower cylindrical portion 23d. Note that as long as the cap 23 can be detachably fixed to the container body 10, various fixing methods can be employed without being limited to screwing.

The gas container 30 is, as shown in FIG. 1, a so-called aerosol container composed of a pressure-resistant container 31 having an opening and an aerosol valve 32 attached to the opening of the pressure-resistant container 31 .

The pressure-resistant container 31 is made of metal, for example, and has a cylindrical shape with a bottom. However, it may be made of synthetic resin.

The aerosol valve 32 is composed of a stem 32a, a stem rubber that closes a stem hole of the stem 32a, and a spring that normally biases the stem 32a. The inside and the outside are communicated with each other. That is, it is the same mechanism as the valve mechanism 21 .

The gas container 30 configured as described above is filled with a compressed gas such as nitrogen, carbon dioxide gas, or compressed air as a pressurizing agent P. Alternatively, a liquefied gas may be filled, in which case it is preferable to provide the valve with a tube so that only the vaporized gas of the liquefied gas is released. The gas container 30 is accommodated in the holder 41 with the stem 32a facing downward.

The pressure regulating device 40 includes a holder 41 that is suspended from the opening 10 a of the container body 10 and that accommodates the gas container 30 . The holder 41 communicates with the inside of the container body 10 . A sealed chamber R is formed between a bottom cylinder 42 and a bottom portion 42a of the cylinder 42, and the pressure difference between the sealed chamber R and the container body 10 causes the cylinder 42 to slide. It has a piston 43 that opens and closes, and a retaining member 44 as a retaining member E that prevents the piston 43 from detaching from the cylinder 42 and maintains the sealed state of the sealed chamber R.

As shown in FIG. 3, the holder 41 includes a tubular body portion 41a and a flange portion 41b extending outward from the upper end of the body portion 41a.

An annular seal projection 41a1 is formed on the upper end of the main body portion 41a to abut against the first seal member 50 to form a seal. A communication hole 41a2 communicating with the inside of the container main body 10 is formed in the side surface of the main body portion 41a. Furthermore, in the vicinity of the upper end of the main body portion 41a, in order to prevent the holder 41 from being displaced when the holder 41 is accommodated in the container main body 10, the diameter is increased so as to reduce the difference from the inner diameter of the neck portion 10d of the container main body 10. It is A tube connection hole 41a4 for inserting the dip tube 70 is provided in the expanded diameter portion 41a3. The tube connection hole 41a4 opens upward through the flange portion 41b.

A communication groove 41b1 communicating with the tube connection hole 41a4 is formed in the upper surface of the flange portion 41b. The lower surface of the flange portion 41b faces the upper surface of the neck portion 10d of the container body 10. As shown in FIG. An annular second seal member (O-ring) 60 having a circular cross section is arranged below the flange portion 41b. When the cap 23 is tightened, the second seal member 60 is compressed between the lower surface of the flange portion 41b and the upper surface of the neck portion 10d of the container body 10, separating the inside of the container body 10 from the outside air (see FIG. 1). .

The cylinder 42 is in the shape of a cylinder with an open bottom and communicates with the inside of the holder 41 . This cylinder 42 is continuous with the lower end of the holder 41 . That is, it is integrated with the holder 41 . However, the cylinder 42 and the holder 41 may be provided separately. The cylinder 42 has a smaller diameter than the holder 41 . Therefore, a stepped portion 41 c is formed between the holder 41 and the cylinder 42 . The stepped portion 41c can also be referred to as a diameter-reduced portion at the lower end of the holder 41 or a flange portion at the upper end of the cylinder 42 .

The piston 43 includes a sliding portion 43a that slides on the inner surface of the cylinder 42, a shaft portion 43b that extends from the sliding portion 43a, and a stem insertion portion 43c into which the stem 32a of the gas container 30 is inserted. ing.

The sliding portion 43a includes a base portion 43a1 that is slightly smaller than the inner diameter of the cylinder 42, and a sliding seal material 43a2 that is compressed between the inner surface of the cylinder 42 and the base portion 43a1 to form a seal. . An annular groove 43a3 is formed in the outer periphery of the base portion 43a1 to accommodate a portion of the sliding seal member 43a2 in a state of protruding outward. The sliding seal member 43a2 is an O-ring having a circular cross section and an annular shape. By compressing the sliding seal portion 43a2 between the inner surface of the cylinder 42 and the base portion 43a1, the sliding portion 43a can slide inside the cylinder 42 while maintaining the closed state of the sealed chamber R. The frictional force between the sliding portion 43a and the cylinder 42 is increased, in particular, the fitting force between the stem insertion portion 43c (specifically, a stem insertion hole 43c1 described later) of the piston 43 and the stem 32a of the gas container 30 is increased. By doing so, the piston 43 is prevented from coming off even when the gas container 30 is removed from the holder 41 . That is, making the frictional force between the sliding portion 43a and the cylinder 42 greater than the fitting force between the stem insertion portion 43c and the stem 32a also serves as the disengagement prevention means E.

The outer diameter of the shaft portion 43b is smaller than the outer diameter of the sliding portion 43a. Moreover, it is smaller than the inner diameter of the retaining member 44 .

The stem insertion portion 43c is provided at the end of the shaft portion 43b opposite to the sliding portion 43a. The stem insertion portion 43c includes a cylindrical stem insertion hole 43c1 and a slit 43c2 formed on the outer periphery of the stem insertion hole 43c1. Two slits 43c2 are provided around the stem insertion hole 43c1 as shown in FIG. 4A, or a plurality (for example, three) are provided radially around the stem insertion hole 43c1 as shown in FIG. 4B. The slit 43c2 secures a passage for discharging the pressurizing agent P discharged from the stem 32a into the holder 41 when the stem 32a is inserted. Moreover, the slit 43c2 weakens the fitting force between the stem insertion portion 43c and the stem 32a, thereby preventing the piston 43 from coming off when the gas container 30 is removed from the holder 41. FIG. In other words, the slit 43c2 also functions as the removal preventing means E.

The retention member 44 includes a guide tube portion 44a inserted into the cylinder 42 and a flange portion 44b extending outward from the upper end of the guide tube portion 44a.

The inner diameter of the retaining member 44 (specifically, the guide tube portion 44a) is smaller than the outer diameter of the sliding portion 43a. Therefore, the sliding portion 43a is restricted from moving toward the holder 41 by the lower end of the guide tube portion 44a. That is, the lower end of the guide tube portion 44a functions as a retaining stepped portion S for retaining. Further, the inner diameter of the retaining member 44 (specifically, the guide tube portion 44a) and the outer diameter of the shaft portion 43b are substantially equal. Therefore, the inner surface of the guide tube portion 44 a functions as a guide portion that regulates the inclination of the piston 43 when the sliding portion 43 a slides inside the cylinder 42 . In addition, since the outer diameter of the shaft portion 43b is smaller than the inner diameter of the guide tube portion 44a, it can protrude toward the holder 41 side.

The pressure regulating device 40 configured as described above is assembled as follows. First, the piston 43 is inserted into the cylinder 42 . At this time, it is inserted so that the sliding portion 43a faces downward and the shaft portion 43b faces upward. By inserting the sliding portion 43a into the cylinder 42, a sealed chamber R is formed between the bottom portion 42a of the cylinder 42 and the piston 43 (sliding portion 43a).

Next, the retaining member 44 is inserted (fitted) into the holder 41 . At this time, the guide tube portion 44a is directed downward, and the guide tube portion 44a is inserted into the cylinder . Since the inner diameter of the guide tube portion 44a is smaller than the outer diameter of the sliding portion 43a, the piston 43 further enters the cylinder 42 while being pressed by the guide tube portion 44a. The pressure in the sealed chamber R rises due to this pushing of the piston 43 .

For example, when the assembly is performed under atmospheric pressure, the pressure in the sealed chamber R is at least equal to or higher than the atmospheric pressure. In order to increase the pressure in the sealed chamber R, assembly may be performed under high pressure, or the cylinder 42 may be filled with liquefied gas. Alternatively, an adhesive may be used to fix the retainer member 44, or the holder 41 (cylinder 42) having translucency and the retainer member 44 not having translucency may be welded by laser welding or the like. . This completes the assembly of the pressure regulator 40 .

The assembled pressure regulating device 40 is housed within the container body 10 as shown in FIG. 5B. Then, the stem 32a of the gas container 30 is fitted into the stem insertion hole 43c1 of the piston 43, and the gas container 30 is accommodated in the holder 41. Then, as shown in FIG. 5A, the valve assembly 20 is attached to the container body. Attach to 10. Then, the gas container 30 is pushed downward by the pushing portion 22a4, the piston 43 pushed by the gas container 30 is further pushed into the cylinder 42, and the pressure in the sealed chamber R further increases. This pressure then becomes the reference for pressure regulation. That is, if the pressure inside the container body 10 is balanced with the pressure inside the sealed chamber R, the piston 43 does not slide inside the cylinder 42, and the stem 32a of the gas container 30 connected to the piston 43 is not pushed. Absent. When the pressure in the container body 10 becomes smaller than the pressure in the sealed chamber R, the piston 43 slides inside the cylinder 42 so as to increase the volume of the sealed chamber R, pushes the stem 32a of the gas container 30, and releases the gas. A pressurizing agent P is supplied from the container 30 into the container body 10 . When the pressure in the container main body 10 increases due to the supply of the pressurizing agent P, the piston 43 slides in the cylinder 42 so as to reduce the volume of the sealed chamber R, and the pushing of the stem 32a by the piston 43 is released. , the supply of the pressurizing agent P is stopped.

By the way, when the valve assembly 20 is removed from the container main body 10 when replacing the gas container 30, the pressure regulating device 40 is exposed to the atmospheric pressure. Since the pressure in the sealed chamber R is normally equal to or higher than the atmospheric pressure, the piston 43 slides upward (toward the holder 41 side) by being pushed by the pressure. If the pressure regulating device 40 is assembled under atmospheric pressure, the pressure in the sealed chamber R and the atmospheric pressure are balanced when the piston 43 reaches the upper end of the cylinder 42 . Therefore, if no countermeasures are taken, there is a possibility that the piston 43 will come out of the cylinder 42 and the sealed state of the sealed chamber R will be released.

However, since the discharge container 1 of the present invention is provided with the retaining member 44, the piston 43 does not come off from the cylinder 42 as shown in FIGS. can be done. If the sealed state of the sealed chamber R can be maintained in this manner, foreign matter such as the undiluted liquid C does not enter the sealed chamber R when replacing the gas container 30, and the pressure regulator 40 can function normally. In addition, since the piston 43 is provided with the shaft portion 43b through which the material of the retaining portion 44 can be inserted, the shaft portion 43b is positioned closer to the retaining member 44 than the retaining member 44. It can be positioned upward, and the gas container 30 connected to the piston 43 can be lifted high. Therefore, a part of the gas container 30 can be protruded from the holder 41, and the replacement of the gas container 30 is facilitated. When replacing the gas container 30, it is necessary to insert the stem 32a of the new gas container 30 into the stem insertion hole 43c1. Since the piston 43 is guided by the inner surface (guide portion) of the retaining member 44, the piston 43 is less shaken and can be easily inserted.

Next, another discharge container 2 of the present invention will be described. In the discharge container 2 of FIG. 6, the retainer member 44A does not have the guide tube portion 44a and is ring-shaped. When the retainer member 44A is inserted into the position where it abuts against the upper surface of the stepped portion 41c, the outer peripheral portion thereof is fitted to the inner peripheral surface of the main body portion 41a of the holder 41 and fixed. Even with such a configuration, if the inner diameter of the retaining member 44A is smaller than the outer diameter of the sliding portion 43a, it functions as the retaining stepped portion S for retaining the piston 43 from the cylinder 42. It is possible to prevent the omission. Further, if the inner diameter of the retaining member 44A is larger than the outer diameter of the shaft portion 43b of the piston 43, the shaft portion 43b can be protruded toward the holder 41 beyond the retaining member 44. It has the same function and effect as. Since other structures are the same as those of the discharge container 1, the same reference numerals are given and detailed description thereof will be omitted.

FIG. 7 shows yet another dispensing container 3 of the invention. In this discharge container 3, the holder 41A and the cylinder 42A are separated. A reduced diameter stepped portion 41A1 and a connecting tube 41A2 extending downward from the inner end of the reduced diameter stepped portion 41A1 are provided at the lower end of the holder 41A. The cylinder 42A is fitted onto the connecting cylinder 41A2. The inner diameter of the connecting tube 41A2 is smaller than the outer diameter of the sliding portion 43a. Therefore, the lower end of the connecting tube 41A2 functions as a retaining stepped portion S for retaining. With such a configuration, there is no need to attach the retainer member 44, which is a separate member, and manufacturing can be simplified. The inner diameter of the connecting tube 41A2 is slightly larger than the outer diameter of the shaft portion 43b of the piston 43, and the inner surface of the connecting tube 41A2 functions as a guide portion that guides the piston 43 to slide. As a method for fixing the cylinder 42A to the connecting tube 41A2, in addition to interference fitting, an adhesive agent may be used, or screws may be provided on both sides and screwed together. Furthermore, the cylinder 42A having translucency and the holder 41A having no translucency may be welded by laser welding or the like.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the present invention. For example, as the slip-off prevention means E, the slip-off prevention stepped portion S, the frictional force between the piston 43 and the cylinder 42, and the slit 43c2 for weakening the fitting force between the stem 32a and the stem insertion portion 43c are mentioned. , it is not always necessary to use three, and any one or any combination of two may be used.

1, 2, 3 Discharge container 10 Container main body 10a Opening 10b Body 10c Shoulder 10d Neck 10e Screw 20 Valve assembly 21 Valve mechanism 21a Stem 21b Stem hole 21c Stem rubber 21d Spring 22 Valve holder 22a Housing 22a1 Rubber support 22a2 Continuous Passage 22a3 Engagement groove 22a4 Push-in portion 22b Flange portion 22b1 Passage groove 23 Cap 23a Upper surface portion 23a1 Center hole 23b Upper cylinder portion 23b1 Engagement projection 23c Expanded diameter portion 23d Lower cylinder portion 23d1 Screw 30 Gas container 31 Pressure container 32 Aerosol valve 32a Stem 40 Pressure adjusting device 41, 41A Holder 41a Body portion 41a1 Seal projection 41a2 Communication hole 41a3 Expanded diameter portion 41a4 Tube connection hole 41b Flange portion 41b1 Communication groove 41c Stepped portion 41A1 Diameter reduced stepped portion 41A2 Connecting cylinders 42, 42A Cylinder 42a Bottom portion 43 Piston 43a Sliding portion 43a1 Base portion 43a2 Sliding seal member 43a3 Annular groove 43b Shaft portion 43c Stem insertion portion 43c1 Stem insertion hole 43c2 Slit (release path)
44, 44A Retaining member 44a Guide cylinder 44b Flange 50 First sealing material 60 Second sealing material 70 Dip tube P Pressurizing agent C Undiluted solution R Sealed chamber S Retaining step E Retaining means

Claims (6)

a container body having an opening;
a valve assembly attached to the opening of the container body and having a valve mechanism;
a gas container housed in a container body and filled with a pressurizing agent;
a pressure regulating device attached to the gas container that maintains the pressure in the container body by releasing the pressurizing agent in the gas container into the container body;
A discharge container in which the gas container can be replaced by removing the valve assembly,
A pressure regulator
a holder that is suspended from the opening of the container body and that accommodates the gas container and communicates with the inside of the container body;
a bottomed cylinder communicating with the inside of the holder and continuing to the lower end of the holder;
a piston that forms a sealed chamber with the bottom of the cylinder, slides in the cylinder due to the pressure difference between the sealed chamber and the container body, and opens and closes the gas container by sliding;
and a removal prevention means for preventing the piston from falling out of the cylinder and maintaining the sealed state of the sealed chamber,
A discharge container , wherein a cylinder is fitted to the lower end of a holder, and a drop-off prevention means is formed at the lower end of the holder . 2. The discharge container according to claim 1 , wherein the coming-off prevention means has a guide portion for guiding sliding of the piston. 3. The discharge container according to claim 1 or 2 , wherein the piston has a shaft portion projecting toward the holder side beyond the removal prevention means. a container body having an opening;
a valve assembly attached to the opening of the container body and having a valve mechanism;
a gas container housed in a container body and filled with a pressurizing agent;
a pressure regulating device attached to the gas container that maintains the pressure in the container body by releasing the pressurizing agent in the gas container into the container body;
A discharge container in which the gas container can be replaced by removing the valve assembly,
A pressure regulator
a holder that is suspended from the opening of the container body and that accommodates the gas container and communicates with the inside of the container body;
a bottomed cylinder communicating with the inside of the holder and continuing to the lower end of the holder;
a piston that forms a sealed chamber with the bottom of the cylinder, slides in the cylinder due to the pressure difference between the sealed chamber and the container body, and opens and closes the gas container by sliding;
and a removal prevention means for preventing the piston from falling out of the cylinder and maintaining the sealed state of the sealed chamber,
The piston has a sliding part that slides in the cylinder while maintaining the closed state of the sealed chamber, and a stem insertion part that inserts the stem of the gas container,
A discharge container , wherein the disengagement prevention means is configured such that the frictional force between the sliding portion and the cylinder is greater than the fitting force between the stem insertion portion and the stem . 5. The slide of claim 4 , wherein the slide comprises a base slightly smaller than the inner diameter of the cylinder and a sliding seal material compressed between the inner surface of the cylinder and the base to form a seal. discharge container. a container body having an opening;
a valve assembly attached to the opening of the container body and having a valve mechanism;
a gas container housed in a container body and filled with a pressurizing agent;
a pressure regulating device attached to the gas container that maintains the pressure in the container body by releasing the pressurizing agent in the gas container into the container body;
A discharge container in which the gas container can be replaced by removing the valve assembly,
A pressure regulator
a holder that is suspended from the opening of the container body and that accommodates the gas container and communicates with the inside of the container body;
a bottomed cylinder communicating with the inside of the holder and continuing to the lower end of the holder;
a piston that forms a sealed chamber with the bottom of the cylinder, slides in the cylinder due to the pressure difference between the sealed chamber and the container body, and opens and closes the gas container by sliding;
and a removal prevention means for preventing the piston from falling out of the cylinder and maintaining the sealed state of the sealed chamber,
The piston has a sliding part that slides in the cylinder while maintaining the closed state of the sealed chamber, and a stem insertion part that inserts the stem of the gas container,
A discharge container , wherein the disengagement prevention means is composed of a slit that weakens the fitting force when the stem of the gas container is inserted into the stem insertion portion .

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