JP6751678B2 - Pouring container - Google Patents

Description

The present invention relates to a dispensing container.

Conventionally, a two-agent mixing container as shown in Patent Document 1 below is known. This two-agent mixing container is provided above the first agent accommodating portion and the first agent accommodating portion for accommodating the first agent, and the second agent accommodating portion and the second agent accommodating portion for accommodating the second agent. It is provided with a bottom lid that closes the lower end of the. When this two-agent mixing container is operated, the bottom lid is removed and the second agent in the second agent accommodating portion falls toward the first agent accommodating portion, and the first agent and the second agent are mixed.

JP, 2003-292059, A

In this type of container, it is desired that one of the first agent and the second agent is simply weighed in a substantially quantitative amount, brought into contact with the other, and then dispensed. On the other hand, in the configuration disclosed in Patent Document 1, it is difficult to meet the above requirements because almost all the amounts of the first agent and the second agent are mixed at the time of use.

The present invention has been made in consideration of such circumstances, and a pouring container capable of pouring after one of the first agent and the second agent is weighed substantially quantitatively and brought into contact with the other is provided. The purpose is to provide.

In order to solve the above problems, the dispensing container of the present invention has a container body in which a liquid first agent is housed and a mounting cap mounted on the mouth of the container body while forming a pouring hole. The mounting cap is provided with a second agent accommodating portion in which an introduction hole for the first agent is formed and accommodating the second agent, and a storage disposed below the second agent accommodating portion. The second agent accommodating portion is located below the introduction hole, and the second agent accommodating portion and the second agent accommodating portion have a communication portion that communicates the inside of the storage portion and the injection hole. It is characterized in that a dropping hole that communicates with the inside of the storage portion is formed.

According to the present invention, when the pouring container is tilted, the liquid first agent in the container body flows into the second agent accommodating portion through the introduction hole. After that, when the pouring container is placed in an upright position, the portion of the first agent that has flowed into the second agent accommodating portion, which is located above the introduction hole, moves from the inside of the second agent accommodating portion to the inside of the container body through the introduction hole. leak. Therefore, a substantially fixed amount of the first agent stays in the second agent accommodating portion. The substantially fixed amount of the first agent remaining in the second agent accommodating portion in this way is changed in its properties by contacting with the second agent, and then through the dropping hole formed in the second agent accommodating portion, the inside of the storage portion. Drop in sequence. After that, by tilting the pouring container again, the first agent having changed properties in the storage part is poured out from the pouring hole through the communication part, and at the same time, the first agent in the container body is seconded through the introduction hole. It flows into the agent container again, and the above-mentioned action is repeated.
As described above, according to the dispensing container of the present invention, the first agent in contact with the second agent is dispensed, and the first agent is weighed in a substantially quantitative amount in preparation for the next injection. It can be brought into contact with the second agent.

Here, the opening area of the introduction hole may be larger than the opening area of the dropping hole.

In this case, since the opening area of the introduction hole is larger than the opening area of the dropping hole, the extra first agent that has flowed into the second agent accommodating portion from the introduction hole when the pouring container is tilted and then returned to the upright posture. Can be rapidly discharged into the main body container to stabilize the amount of the first agent remaining in the second agent accommodating portion.

Further, the inside of the storage unit and the inside of the container body may communicate with each other through the communication unit.

In this case, even if the pouring hole is closed when the pouring container is tilted, the air in the second agent accommodating portion is allowed to flow into the container main body through the dropping hole and the communication portion, and the container main body is used. The first agent in the container can be smoothly flowed into the second agent accommodating portion through the introduction hole.
Further, when the first agent in contact with the second agent is dropped from the dropping hole toward the inside of the storage portion, even if the injection hole is closed, the air in the storage portion is allowed to flow into the container body through the communication portion. Since it can be moved to, the liquid dripping from the dripping hole and the air in the storage portion are smoothly replaced. As a result, the time interval at which the liquid is dropped from the dropping hole can be made the same depending on whether the injection hole is closed or not.

Further, the mounting cap may be provided with a replenishment hole communicating with the inside of the second agent accommodating portion, and the replenishment cap may be detachably fitted in the replenishment hole.

In this case, by repeatedly using the injection container, for example, the effect of changing the properties of the first agent by the second agent is reduced, or the second agent is eluted into the first agent and the remaining amount is reduced. At that time, the replenishment hole can be opened by removing the replenishment cap, and the second agent in the second agent accommodating portion can be replaced through the replenishment hole, or the second agent can be replenished through the replenishment hole.

According to the present invention, it is possible to provide a pouring container capable of measuring one of the first agent and the second agent in a substantially quantitative manner, bringing it into contact with the other, and then pouring it out.

It is a longitudinal cross-sectional view of the dispensing container according to the first embodiment. It is a figure explaining the use method of the pouring container of FIG. It is a longitudinal cross-sectional view of the pouring container which concerns on 2nd Embodiment.

(First Embodiment)
Hereinafter, the configuration of the pouring container according to the present embodiment will be described with reference to FIGS. 1 and 2. In each of the drawings used in the following description, the scale is appropriately changed in order to make each member recognizable.
The pouring container 10 includes a bottomed tubular container body 1 in which the liquid first agent P is housed, and a mounting cap 2 mounted on the mouth portion 1a of the container body 1. As the first agent P, for example, a lotion containing water or a liquid detergent is used.

Here, in the present embodiment, the direction along the central axis O of the container body 1 is referred to as a vertical direction, the bottom side of the container body 1 in the vertical direction is referred to as a downward direction, and the mouth portion 1a side is referred to as an upward direction. Further, in a plan view seen from the vertical direction, the direction orthogonal to the central axis O is called the radial direction, and the direction orbiting around the central axis O is called the circumferential direction. Further, in a plan view, the direction from the hinge portion 23 to the operation portion 21c, which will be described later, is referred to as the front-rear direction, the operation portion 21c side in the front-rear direction is referred to as the front, and the hinge portion 23 side is referred to as the rear.

The mounting cap 2 has a cap body 20 screwed to the mouth portion 1a of the container body 1, a measuring cylinder member 30 attached to the cap body 20, and a bottomed tubular shape attached to the lower end of the measuring cylinder member 30. The storage member 40 (storage unit) of the above is provided. In the illustrated example, the cap body 20, the measuring cylinder member 30, and the storage member 40 are formed separately, but these may be integrally formed. Further, the container body 1, the cap body 20, the measuring cylinder member 30, and the storage member 40 may be made of, for example, a transparent resin material so that the inside can be visually recognized.

(Cap body)
The cap body 20 includes a ridged tubular fixing portion 22 fixed to the mouth portion 1a of the container body 1 and a climaxed tubular opening / closing lid 21 connected to the fixing portion 22 via a hinge portion 23. I have. The central axis of the fixing portion 22 and the opening / closing lid 21 is located coaxially with the central axis O of the container body 1. The opening / closing lid 21 is provided above the fixing portion 22, and is rotatable around the hinge portion 23 with respect to the fixing portion 22 and the container body 1.

The fixed portion 22 includes an injection hole 22a that penetrates the top wall in the vertical direction, an injection cylinder 22c that extends upward from the top wall, and a small cylinder portion 22b that extends downward from the top wall. The large cylinder portion 22d and the like are formed. The injection hole 22a, the injection cylinder 22c, the small cylinder portion 22b, and the large cylinder portion 22d are located inside the mouth portion 1a of the container body 1 in the radial direction. The pouring hole 22a and the pouring cylinder 22c are located in front of the central axis O (on the operation unit 21c side), and the inner surfaces of the pouring hole 22a and the pouring cylinder 22c are connected to each other. The injection hole 22a is located inside the large cylinder portion 22d in the radial direction. The upper end of the dispensing cylinder 22c gradually increases in diameter toward the upper side.

The large cylinder portion 22d has a larger diameter than the small cylinder portion 22b and surrounds the small cylinder portion 22b. The central axis of the large cylinder portion 22d is located coaxially with the central axis O of the container body 1. The central axis of the small cylinder portion 22b is located behind the central axis O of the container body 1 (on the hinge portion 23 side). As a result, the central axis of the small cylinder portion 22b is located behind the central axis of the large cylinder portion 22d, and the width of the radial gap formed between the small cylinder portion 22b and the large cylinder portion 22d is rearward. It is getting smaller and smaller toward. A restricting plate 22f extending downward is formed at the rear end of the lower end opening edge of the small cylinder portion 22b. The regulation plate 22f prevents the second agent S housed in the second agent accommodating portion 32, which will be described later, from falling into the container body 1.

The peripheral wall of the fixed portion 22 surrounds the large cylinder portion 22d and the small cylinder portion 22b. On the inner peripheral surface of the fixing portion 22, a female screw portion that is screwed with the male screw portion formed on the outer peripheral surface of the mouth portion 1a is formed. In the vertical direction, the lower end of the peripheral wall of the fixed portion 22 is located below the lower end of the small cylinder 22b, and the lower end of the small cylinder 22b is located below the lower end of the large cylinder 22d.

The opening / closing lid 21 opens and closes the injection hole 22a by rotating around the hinge portion 23 with respect to the fixing portion 22. A seal cylinder 21a extending downward is formed on the top wall of the opening / closing lid 21. The seal cylinder 21a seals the injection hole 22a by fitting into the injection cylinder 22c. A configuration may be adopted in which the seal cylinder 21a is fitted in the injection hole 22a without providing the injection cylinder 22c. At the lower end of the peripheral wall of the opening / closing lid 21, an operating portion 21c that protrudes outward in the radial direction is formed. The operating portion 21c is arranged on the opposite side of the hinge portion 23 that sandwiches the central axis O in the radial direction. In the vertical direction, the operation unit 21c is located below the lower end portion of the seal cylinder 21a.

(Measuring cylinder member)
The measuring cylinder member 30 includes an outer cylinder portion 31 extending in the vertical direction, a tubular second agent accommodating portion 32 formed inside the outer cylinder portion 31 and extending in the vertical direction, and an outer cylinder portion 31 upward. It has a fitting cylinder portion 34 extending and an annular flange portion 35 extending radially outward from the upper end portion of the fitting cylinder portion 34. The outer cylinder portion 31, the second agent accommodating portion 32, and the fitting cylinder portion 34 are located inside the mouth portion 1a of the container body 1 in the radial direction.

The outer cylinder portion 31 has a smaller diameter than the mouth portion 1a of the container body 1, and the central axis of the outer cylinder portion 31 is located in front of the central axis O of the mouth portion 1a. Therefore, the width of the radial gap formed between the outer cylinder portion 31 and the mouth portion 1a gradually increases from the front to the rear. The lower end portion of the outer cylinder portion 31 is located below the lower end portion of the mouth portion 1a in the vertical direction. A locked portion 31b that is recessed outward in the radial direction is formed on the inner peripheral surface of the lower end portion of the outer cylinder portion 31.

The second agent S is contained in the second agent accommodating portion 32. The second agent S may be one that elutes into the first agent P, or may not elute into the first agent P. The second agent S may be granular, spherical, powdery, blocky or the like. As the second agent S, for example, a hydrogen generating agent that reacts with the water contained in the first agent P to generate hydrogen, a fragrance having a fragrance, and an fragrance that dissolves in the first agent P can be used.

The lower end portion of the second agent accommodating portion 32 is located above the lower end portion of the outer cylinder portion 31. At the lower end of the second agent accommodating portion 32, a diameter-reduced portion 32a that gradually reduces in diameter as it goes downward is formed. At the lower end of the reduced diameter portion 32a, a dropping hole 32b that penetrates the reduced diameter portion 32a in the vertical direction is formed. The second agent accommodating portion 32 has a smaller diameter than the outer cylinder portion 31, and the second agent accommodating portion 32 is located in the outer cylinder portion 31. Therefore, a gap extending in the vertical direction (hereinafter referred to as a communication portion 2b) is formed between the second agent accommodating portion 32 and the outer cylinder portion 31.

The central axis of the second agent accommodating portion 32 is located behind the central axis of the outer cylinder portion 31. The rear end portion of the second agent accommodating portion 32 is integrally formed with the rear end portion of the outer cylinder portion 31, and the upper end portion of the integrally formed portion has a through hole 31a penetrating this portion in the front-rear direction. Is formed. The through hole 31a is arranged at the same position in the circumferential direction as the regulation plate 22f of the cap body 20, and is partially covered by the regulation plate 22f. The opening area of the through hole 31a is larger than the surface area of the regulation plate 22f seen from the opening direction, and a gap (hereinafter referred to as an introduction hole 2a) is formed between the inner surface of the through hole 31a and the regulation plate 22f. There is. The opening area of the introduction hole 2a is larger than the opening area of the dropping hole 32b. The introduction hole 2a is located behind the injection hole 22a and the dropping hole 32b. The dropping hole 32b is located below the introduction hole 2a. The lower end opening edge of the dropping hole 32b is located below the upper end opening edge of the storage member 40 in the vertical direction, and is located inside the storage member 40 in the radial direction.

The fitting cylinder portion 34 is externally fitted to the large cylinder portion 22d of the cap body 20. The flange portion 35 is in contact with or close to the top wall of the fixing portion 22 of the cap body 20 from below. The flange portion 35 faces the upper end opening edge of the mouth portion 1a of the container body 1 in the vertical direction, and an annular packing 4 is sandwiched between the upper end opening edge and the flange portion 35. As a result, the mouth portion 1a is sealed.

A bulging portion 33 that bulges rearward from the outer cylinder portion 31 is formed in a portion of the measuring cylinder member 30 that is located between the through hole 31a and the fitting cylinder portion 34 in the vertical direction. .. In the radial direction, the radial inner surface of the bulging portion 33 is arranged at a position equivalent to the inner surface of the large cylinder portion 22d. Therefore, a gap is formed between the bulging portion 33 and the small cylinder portion 22b, and the radial width of this gap is the radial gap between the large cylinder portion 22d and the small cylinder portion 22b. It is equivalent to the width. The width of these gaps is adjusted so that air can pass through and the first agent P cannot pass through. The inside of the container body 1 and the inside of the communication portion 2b communicate with each other through the communication portion 2b, the gap between the large cylinder portion 22d and the small cylinder portion 22b, and the gap between the small cylinder portion 22b and the bulging portion 33. ..

(Storage member)
The peripheral wall 41 of the storage member 40 is fitted in the outer cylinder portion 31 of the measuring cylinder member 30. The storage member 40 is located below the fixing portion 22 of the cap body 20 in the vertical direction. An annular abutting portion 43 projecting outward in the radial direction is formed at the central portion of the peripheral wall 41 of the storage member 40 in the vertical direction. An annular locking portion 41a that protrudes outward in the radial direction is formed above the abutting portion 43 on the peripheral wall 41. The locking portion 41a is locked to the locked portion 31b of the outer cylinder portion 31. As a result, the movement of the storage member 40 with respect to the measuring cylinder member 30 in the vertical direction is restricted. The bottom wall 42 of the storage member 40 is formed in a curved surface shape that is convex downward.

Next, the operation of the dispensing container 10 configured as described above will be described.

When the opening / closing lid 21 is rotated around the hinge portion 23 by operating the operating portion 21c and the pouring container 10 is tilted as shown in FIG. 2A, the first agent P in the container body 1 is introduced into the introduction hole 2a. It flows into the second agent container 32 through. At this time, the air in the second agent accommodating portion 32 is discharged to the outside of the pouring container 10 through the dropping hole 32b, the communicating portion 2b, and the pouring hole 22a. Even when the opening / closing lid 21 is closed and the injection hole 22a is closed when the injection container 10 is tilted, the air in the second agent accommodating portion 32 is still in the dropping hole 32b and the communication portion. 2b, the air flows into the container body 1 through the gap between the large cylinder portion 22d and the small cylinder portion 22b, and the gap between the small cylinder portion 22b and the bulging portion 33. Therefore, even if the injection hole 22a is closed, the first agent P in the container body 1 can be smoothly flowed into the second agent accommodating portion 32 through the introduction hole 2a.

Next, when the pouring container 10 is returned to the upright posture as shown in FIG. 2B, the first agent P that has flowed into the second agent accommodating portion 32 is located above the introduction hole 2a. The portion flows out from the introduction hole 2a and returns to the inside of the container body 1. Therefore, when the pouring container 10 is returned to the upright posture, the lower end portion of the second agent accommodating portion 32 is determined from the internal volume of the portion of the second agent accommodating portion 32 located below the introduction hole 2a. The first agent P having the difference volume obtained by subtracting the volume of the second agent S accumulated in the second agent S stays in the second agent accommodating portion 32, and the first agent P in contact with the second agent S is weighed. It can be approximately quantitative.

A substantially fixed amount of the first agent P remaining in the second agent accommodating portion 32 comes into contact with the second agent S deposited at the lower end portion in the second agent accommodating portion 32, so that, for example, the second agent S When is a hydrogen-producing agent, the hydrogen produced by the reaction between the hydrogen-producing agent and the water content of the first agent P dissolves in the first agent P. Alternatively, when the second agent S is an fragrance agent, the first agent P and the second agent S come into contact with each other to add a scent to the first agent P. In this way, the first agent (hereinafter referred to as the contact liquid R) whose properties have been changed by contacting with the second agent S is sequentially dropped into the storage member 40 from the dropping hole 32b. At this time, even when the opening / closing lid 21 is closed and the injection hole 22a is closed, the air in the storage member 40 is a gap between the communication portion 2b, the large cylinder portion 22d, and the small cylinder portion 22b. , And move into the container body 1 through the gap between the small cylinder portion 22b and the bulging portion 33, so that the air and the contact liquid R are smoothly replaced in the storage member 40. When the opening / closing lid 21 is open, the air in the storage member 40 is discharged from the pouring hole 22a as the contact liquid R drops from the dropping hole 32b. Therefore, when the contact liquid R is dropped, the dropping time interval and the like are the same depending on whether the opening / closing lid 21 is open or closed.

By appropriately changing the inner diameter of the dropping hole 32b, the time interval at which the contact liquid R drops from the dropping hole 32b, the size of the droplet, and the like can be changed, and the first agent P and the first agent P can be changed in the second agent accommodating portion 32. The time of contact with the second agent S can be easily adjusted. This makes it possible to easily obtain the desired quality of the contact liquid R according to the types of the first agent P and the second agent S.

Next, when the pouring container 10 is tilted again as shown in FIG. 2C, the contact liquid R in the storage member 40 is poured out through the communication portion 2b, the pouring hole 22a, and the pouring cylinder 22c. At this time, assuming that the first agent P in the container body 1 flows into the second agent accommodating portion 32 through the introduction hole 2a and then the pouring container 10 is put into the upright posture again, the second agent accommodating portion is as described above. A substantially fixed amount of the first agent P stays in the 32, and when this comes into contact with the second agent S, a contact liquid R is obtained, and the contact liquid R is dropped through the dropping hole 32b.

As described above, according to the present embodiment, the mounting cap 2 is arranged below the second agent accommodating portion 32 in which the introduction hole 2a of the first agent P is formed and the second agent accommodating portion 32. The storage member 40 has a communication portion 2b that communicates the inside of the storage member 40 with the injection hole 22a, and the second agent accommodating portion 32 is located below the introduction hole 2a and has a second agent. A dropping hole 32b is formed which communicates the inside of the accommodating portion 32 and the inside of the storage member 40. With this configuration, the contact liquid R in the storage member 40 is poured out from the pouring hole 22a by tilting the pouring container 10, and a substantially quantitative first amount is provided in the second agent accommodating portion 32 in preparation for the next pouring. Agent P can be retained. Then, when the pouring container 10 is in the upright posture, the first agent P drops through the dropping hole 32b while in contact with the second agent S, so that the operation of tilting the pouring container 10 and then putting it in the upright posture is repeated. As a result, a substantially fixed amount of the contact liquid R can be poured out each time.

Further, as described above, when the pouring container 10 is tilted and then put into an upright posture, a substantially fixed amount of the first agent P stays in the second agent accommodating portion 32 and comes into contact with the second agent S. For example, as compared with the configuration in which the entire amount of the first agent P in the container body 1 is brought into contact with the second agent S, from the contact of the first agent P with the second agent S until the injection from the injection hole 22a. Time can be shortened. As a result, for example, when a hydrogen generating agent is used as the second agent P, it is possible to prevent the hydrogen eluted in the contact liquid R from escaping from the contact liquid R after a long period of time.

Further, since the opening area of the introduction hole 2a is larger than the opening area of the dropping hole 32b, when the pouring container 10 is tilted and then returned to the upright posture, it flows into the second agent accommodating portion 32 from the introduction hole 2a. The excess first agent P can be rapidly discharged into the container body 1 to stabilize the amount of the first agent P remaining in the second agent accommodating portion 32.

When the container body 1, the measuring cylinder member 30, and the storage member 40 are made of a transparent material, the state of the first agent P and the second agent S in the second agent accommodating portion 32 and the dropping hole 32b The state of the contact liquid R dripping from the container 10 can be visually recognized from the outside of the pouring container 10, and the aesthetic appearance of the pouring container 10 can be improved. Further, since the inside of the second agent accommodating portion 32 becomes visible, the injection container 10 is tilted with the first agent P remaining in the second agent accommodating portion 32, and is dispensed from the injection hole 22a. It is possible to suppress variations in the amount of contact liquid R.

(Second Embodiment)
Next, a second embodiment according to the present invention will be described, but the basic configuration is the same as that of the first embodiment. Therefore, the same reference numerals are given to the same configurations, the description thereof is omitted, and only different points will be described.

In the present embodiment, as shown in FIG. 3, the mounting cap 2 is formed with a replenishment hole 22e that penetrates the top wall of the fixing portion 22 in the vertical direction. The replenishment hole 22e is located inside the small cylinder portion 22b in the radial direction and communicates with the inside of the second agent accommodating portion 32. The replenishment hole 22e is located behind the injection hole 22a and the injection cylinder 22c (on the hinge portion 23 side). A replenishment cap 3 is detachably fitted in the replenishment hole 22e.

Further, the opening / closing lid 21 of the present embodiment is formed with a tubular pressing portion 21b extending downward from the top wall thereof. The pressing portion 21b faces the replenishment hole 22e with the replenishment cap 3 interposed therebetween in the vertical direction. The pressing portion 21b is arranged behind the seal cylinder 21a (on the hinge portion 23 side). In the vertical direction, the lower end of the pressing portion 21b is located above the lower end of the seal cylinder 21a.

According to the present embodiment, by repeatedly using the pouring container 10, for example, the effect of changing the properties of the first agent P by the second agent S is reduced, or the second agent S is eluted into the first agent P. When the remaining amount becomes low, the replenishment hole 22e is opened by removing the replenishment cap 3, and the second agent S in the second agent accommodating portion 32 is replaced through the replenishment hole 22e, or the second agent. The second agent S can be replenished into the accommodating portion 32.

Further, when the replenishment cap 3 is refitted into the replenishment hole 22e after the replenishment of the second agent S is completed, even if the fitting is insufficient, it is replenished by the pressing portion 21b by closing the opening / closing lid 21. The cap 3 can be pressed toward the replenishment hole 22e to reliably close the replenishment hole 22e.
Further, since the replenishment hole 22e is located behind the injection hole 22a, the distance from the hinge portion 23, which is the center of rotation of the opening / closing lid 21, to the replenishment cap 3 is reduced, and the pressing portion 21b is the replenishment cap 3 The operating force of the operating portion 21c when pressing the replenishment hole 22e can be suppressed to a small size.

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

For example, in the above embodiment, it has been described that the storage member 40 is located below the fixing portion 22 of the cap body 20 in the vertical direction, but the present invention is not limited to this. For example, the storage member 40 may be located at the same position in the vertical direction as the fixed portion 22, and the storage member 40 may be covered by the fixed portion 22. Even in this case, by forming the cap body 20 with a transparent material, it is possible to visually recognize the appearance of the contact liquid R dripping from the dropping hole 32b from the outside of the pouring container 10.

Further, in the above-described embodiment, the gap between the inner surface of the through hole 31a of the measuring cylinder member 30 and the regulation plate 22f is the introduction hole 2a, but the introduction hole 2a is not limited to this, and the introduction hole 2a is the second agent accommodating portion. It may be a slit formed in 32 or the like.

In addition, it is possible to appropriately replace the constituent elements in the above-described embodiments with well-known constituent elements without departing from the spirit of the present invention, and the above-described embodiments and modified examples may be appropriately combined.

1 ... Container body 1a ... Mouth part 2 ... Mounting cap 2a ... Introduction hole 2b ... Communication part 10 ... Dispensing container 22a ... Dispensing hole 32 ... Second agent accommodating part 32b ... Drop hole 40 ... Storage member (storage part) O … Central axis P… 1st agent S… 2nd agent

Claims (4)

A container body for accommodating the liquid first agent,
An injection hole is formed, and a mounting cap mounted on the mouth of the container body is provided.
The mounting cap is
A second agent accommodating portion in which an introduction hole for the first agent is formed and the second agent is accommodated.
A storage unit arranged below the second agent storage unit and
It has a communication part that communicates the inside of the storage part and the injection hole.
A pouring container characterized in that the second agent accommodating portion is formed with a dropping hole located below the introduction hole and communicating the inside of the second agent accommodating portion and the inside of the storage portion. The pouring container according to claim 1, wherein the opening area of the introduction hole is larger than the opening area of the dropping hole. The pouring container according to claim 1 or 2, wherein the inside of the storage portion and the inside of the container main body communicate with each other through the communication portion. The mounting cap is provided with a replenishment hole that communicates with the inside of the second agent accommodating portion.
The pouring container according to any one of claims 1 to 3, wherein a replenishment cap is detachably fitted in the replenishment hole.

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