JP2024006126A - Discharge container with nozzle - Google Patents

Abstract

To provide a dispenser with a nozzle capable of choosing between a mode of measurement discharge of contents and a mode of discharge in an arbitrary amount.SOLUTION: A dispenser with a nozzle includes: an inner cap 8 which has a top wall 12 covering an opening surface of a mouth cylindrical part 6 of a container body 2 and opens a main communication hole 16a in one part of the top wall 12; and an outer cap 20 which is rotatably fitted outward of the inner cap 8 and is provided with a nozzle 40 extending upward from a part of a top plate 24 facing the top wall 12. The nozzle 40 is arranged at a position axially eccentric to the center of the top plate 24, and the main communication hole 16a is formed near the center of the top wall 12. A sub communication hole 16b opened is formed at a part of a circumferential direction of an outer periphery part 13 of the top wall 12, and a measurement chamber C is formed above the other part of the outer periphery part 13. The nozzle 40 is displaced between a position where it faces the measurement chamber C by rotary operation of the outer cap 20 and a position where it faces the sub communication hole 16b.SELECTED DRAWING: Figure 1

Description

The present invention relates to a dispensing container with a nozzle, and particularly to a dispensing container for discharging granular materials such as fertilizer.

In order to efficiently spray fertilizers, herbicides, etc. to the roots of plants while avoiding their leaves, a discharge container with a nozzle has been proposed (see paragraph 0002 of Patent Document 1).
This dispensing container includes a container body with an upright spout, a lower lid that fits into the spout and has a top with an open discharge port, and is connected to the rear end of the lower lid via a first hinge. and a nozzle that hangs down from the front end of the lower lid to the front side of the lower lid via a second hinge. By turning the nozzle upside down, the base end of the nozzle can be fitted into the discharge port.

JP2017-226469

Granules used in fertilizers and the like are often measured using a cap or the like and applied by hand.
Since the dispensing container of Patent Document 1 only has a dispensing mode that allows discharging an arbitrary appropriate amount, when measurement is required, the dispensing device ends up being measured using a cap that discharges from a nozzle. In this case, fertilizer will be applied as usual, and the granules that have been spread will end up on the leaves of the plants, and there is a risk that the measured amount of granules will not be accurately spread on the soil (under the soil).

An object of the present invention is to provide a dispensing device with a nozzle that allows the user to select between a metered dispensing mode and an arbitrary amount discharging mode of the contents.

A first means includes a container body 2 having a mouth barrel portion 6;
an inner cap 8 that is attached to the mouth barrel part 6 and has a top wall 12 that covers the opening of the mouth barrel part 6, and has a main communication hole 16a opened in a part of the top wall 12;
An outer peripheral wall 22 hanging down from the peripheral end side of a top plate 24 facing the top wall 12 is fitted into the inner cap 8, and an outer cap 20 is provided with a nozzle 40 extending upward from the top plate 24. ,
A measuring chamber C is provided in a part of the space between the top wall 12 and the top plate 24, close to the main communication hole 16a when viewed from above, and is used to measure the contents introduced through the main communication hole 16a. In a dispensing container with a nozzle, the dispensing container is equipped with a nozzle for discharging the measured contents from the nozzle 40.
The outer cap 20 is rotatably attached to the inner cap 8,
The nozzle 40 is arranged at a position eccentric from the rotation center of the top plate 24 when viewed from above, and can be moved between a first position and a second position in the circumferential direction by rotating the outer cap 20 with respect to the inner cap 8. It is installed so that it can be displaced between
The nozzle 40 was configured to face the measuring chamber C at the first position, and to face the sub-communication hole 16b opened in the top wall 12 at the second position.

In this means, as shown in FIG. 1(B), the outer cap 20 is fitted to the inner cap 8 attached to the mouth barrel part 6 of the container body 2, and the top wall 12 of the inner cap 8 and the top wall of the outer cap 20 are fitted. A discharge container with a nozzle in which a measuring chamber C is formed in a part of the space V between the plate 24, a main communication hole 16a is opened in a part of the top wall, and a nozzle 40 is erected from the top plate 24. .
The outer cap 20 is rotatable with respect to the inner cap 8.
The nozzle 40 is arranged at a position eccentric from the rotation center of the top plate 24 when viewed from above, and can be moved to the first position shown in FIG. 1(B) by rotating the outer cap 20 with respect to the inner cap 8. and the second position shown in FIG. 3(B).
The nozzle 40 faces the measuring chamber C in the first position, and faces the sub-communication hole 16b opened in the top wall 12 in the second position.
According to this structure, two modes of metered discharge and arbitrary appropriate amount discharge can be selected as appropriate.

The second means has the first means, and the top wall 12 includes a substantially flat outer circumferential portion 13 and a raised tube 14 that protrudes from the outer circumferential portion 13 toward the center. The main communication hole 16a is opened in the upper part of 14,
An upright cylindrical portion 10b stands up from the peripheral end of the top wall 12,
A pair of partition walls 18, 18 extending from the raised cylinder 14 to the upright cylinder part 10b are formed on both sides in the circumferential direction of the sub-communication hole 16b formed in a part 13a of the outer peripheral part 13, when viewed from above. death,
A space defined above the other part 13b of the outer peripheral part 13 by these partition walls 18, 18, the upright cylinder part 10b, and the raised cylinder 14 was defined as the measuring chamber C.

As shown in FIG. 1(B), this means includes a raised tube 14 that protrudes from the outer peripheral portion 13 of the top wall 12 toward the center, and an upright tube portion 10b that rises from the peripheral end of the top wall 12. Furthermore, as shown by dotted lines in FIG. 1(A), a pair of partition walls 18, 18 extending from the raised tube 14 to the upright tube portion 10b are provided on both sides of the sub-communication hole 16b.
According to this structure, since the measuring chamber C and the sub-communication hole 16b are partitioned off by the partition walls 18, 18, the above-mentioned two discharge modes can be realized with a simple structure.

The third means has a second means, and the sub-communication hole 16b extends from the outer peripheral portion 13 to the cylindrical wall w of the raised cylinder 14, and is continuous with the main communication hole 16a. ing.

In this means, as shown in FIG. 1(B), the auxiliary communication hole 16b extends from the outer peripheral portion 13 to the cylindrical wall w of the raised cylinder 14, and is continuous with the main communication hole 16a. ing.
According to this structure, a sufficient opening area of the sub-communication hole 16b can be ensured, and an arbitrary appropriate amount can be smoothly discharged.

The fourth means has the first means, and the nozzle 40 is detachably attached to the top plate 24,
A storage section 5 for storing the nozzle 40 removed from the top plate 24 is formed on a side surface of the body 3 of the container body 2.

In this means, as shown in FIG. 1(B), the nozzle 40 is detachably attached to the top plate 24, and a storage space for storing the nozzle 40 removed from the top plate 24 is provided. A portion 5 is formed on a side surface of the body portion 3 of the container body 2.
According to this structure, the entire container does not become bulky when the nozzle 40 is housed, and it is easy to respond to the request for a long nozzle.

The fifth means includes the first means, and the nozzle 40 is arranged eccentrically in one direction X with respect to the center of the top plate 24 when viewed from above. The distal end portion 44 is formed to have an outlet portion e2 that is closed at the upper end and opens in a direction opposite to the one direction X.

In this means, as shown in FIG. 6, the nozzle 40 is arranged eccentrically in one direction X with respect to the center of the top plate 24 when viewed from above, and the tip 44 of the nozzle 40 is It has an outlet portion e2 that is closed at the upper end and opens in the opposite direction to the one direction X.
According to this structure, when the container body 2 is tilted to one side in the radial direction of the cylinder, the contents are not discharged all at once from the tip of the nozzle 40, and an appropriate amount can be dispensed.

According to the present invention, it is possible to appropriately select the manner in which the contents are metered and discharged and the manner in which an arbitrary amount of the contents is discharged.

This figure shows the configuration of the nozzle-equipped dispensing container according to the first embodiment of the present invention in a metered dispensing mode, and FIG. It is a diagram. FIG. 2 is an enlarged sectional view of a main part of the nozzle-equipped discharge container shown in FIG. 1. FIG. The configuration of the dispensing container shown in FIG. 1 in an appropriate amount dispensing mode is shown, with (A) being a plan view of the state, and (B) being a partial sectional view seen from the side. FIG. 2 is an explanatory diagram of the process of metering and discharging in the dispensing container shown in FIG. 1 . FIG. 2 is an explanatory diagram of a process of dispensing an appropriate amount using the dispensing container shown in FIG. 1 . This figure shows the configuration of a dispensing container with a nozzle according to a second embodiment of the present invention in a metered dispensing mode, and FIG. The figure (C) is a sectional view of the mouth member of the container, and the figure (D) is an explanatory diagram of the state of use.

1 to 5 show a nozzle-equipped discharge container according to an embodiment of the present invention.
This discharge container is composed of a container body 2, an inner cap 8, an outer cap 20, an upper lid 30, a nozzle 40, and a surrounding member 50.
Each of these members can be made of, for example, a synthetic resin material.
In this embodiment, the nozzle 40 is formed to be detachable from the outer cap 20.

As shown in FIG. 1(B), the container body 2 has a spout portion 6 that stands up from a body portion 3 via a shoulder portion 4. A male screw portion 7 is formed on the outer surface of the mouth tube portion 6.
The upper end portion of the mouth barrel portion 6 is formed into a reduced diameter portion 6a.
On the shoulder portion 4, a first display m1 (FIG. 1 (A ) and a second display m2 (see FIG. 3(A)) are formed.
For example, the first display m1 may read "measurement", and the second display m2 may read "appropriate amount".
It can be displayed that when the nozzle 40 is in the vicinity of the characters ``metering'', the metered discharge mode is possible, and when the nozzle 40 is in the vicinity of the characters ``appropriate amount'', the proper amount discharge mode is possible.
Note that in this specification, discharging an arbitrary amount of contents for the user is expressed as "discharging an appropriate amount."

As shown in FIG. 1(A), a part of the body 3 in the circumferential direction (in the illustrated example, a side part equally distant from the first display m1 and the second display m2) has a part that is removed from the outer cap 20. A vertically elongated storage recess 5 for storing the nozzle 40 is formed.
In the illustrated storage recess 5, as shown in FIG. 1A, a groove having a depth comparable to the outer diameter of the nozzle 40 is formed in a part of the cylindrical body 3 in the circumferential direction.
The upper end of the storage recess 5 is open to the shoulder 4, and the nozzle 40 can be inserted from the upper end side. Further, the lower end of the storage recess 5 is closed.

The inner cap 8 has a base cylinder 10 attached to the outer surface of the mouth cylinder part 6, as shown in FIG. A top wall 12 is attached to the inner surface of the base tube 10, which opens a communication hole 16 communicating with the inside of the mouth tube portion 6.
It is preferable to provide a rotation prevention mechanism between the inner cap 8 and the container body 2. The anti-rotation mechanism is provided with engaging elements that engage with each other on opposing surfaces of the inner cap 8 and the container body 2, and is formed to prevent the inner cap from rotating together with the outer cap when the outer cap 20 is rotated. do.
In the illustrated example, a fitting tube portion 10a, which is the lower half of the base tube 10, is fitted (screwed in the illustrated example) to the outer surface of the mouth tube portion 6. A female threaded portion 11 that engages with the male threaded portion 7 is formed on the inner surface of this fitting cylindrical portion 10a.
The upper half of the base tube 10 (erected tube section 10b) extends upward from the peripheral end of the top wall 12.
The outer peripheral portion 13 of the top wall 12 is brought into contact with the upper end of the reduced diameter portion 6a of the mouth tube portion 6.
The top wall 12 includes a substantially flat outer circumferential portion 13 and a raised tube 14 that protrudes from the outer circumferential portion 13 toward the center.
The corners a between the outer peripheral portion 13 and the raised tube 14 are each formed into a round corner.
The raised cylinder 14 is formed in a vertical straight cylinder shape above the corner a2, and is erected higher than the upright cylinder part 10b.
The illustrated raised tube 14 is disposed at a position slightly shifted from the center of the inner cap 8 toward a hinge 29, which will be described later. However, the arrangement can be changed as appropriate.

In this embodiment, the communication hole 16 is formed in a main communication hole 16a opened at the upper end of the raised cylinder 14, and at least in a part 13a of the outer peripheral part 13, and extends toward the cylinder wall w side of the raised cylinder 14. It is formed with an extending sub-communication hole 16b.
In this embodiment, the sub-communication hole 16b extends to the upper end of the raised tube 14 and is continuous with the main communication hole 16a.
However, these structures can be modified as appropriate. For example, the sub-communication hole 16b may be formed only in the outer peripheral portion 13 and not be continuous with the main communication hole 16a.
On both sides of the sub-communication hole 16b in the circumferential direction, a pair of partition walls 18, 18, which will be described later, are arranged radially in the radial direction of the inner cap 8, as shown by dotted lines in FIG. ing.
The portion of the sub-communication hole 16b that is open to the outer peripheral portion 13 is formed in a fan shape between the pair of partition walls 18, 18 when viewed from above.
As shown in FIG. 1(B), the sub-communication hole 16b is formed to open inward from the reduced diameter portion 6a of the mouth tube portion 6 when viewed from the side.

The inner cap 8 has a pair of partition walls 18, 18 extending from the raised cylinder 14 to the upright cylinder part 10b on both sides in the circumferential direction of the sub-communication hole 16b formed in a part 13a of the outer peripheral part 13. is formed.
These pair of partition walls 18, 18 are formed in a V-shape when viewed from above. The heights of these partition walls 18, 18 are set so that they do not come into contact with a hanging cylinder 26, which will be described later.
As shown by the dotted line in FIG. 3(A), a C-shaped measuring chamber C is formed above the other portion 13b of the outer circumferential portion 13 (other than the part 13a of the outer circumferential portion 13). has been done. This measuring chamber C is formed between the inner surface of the upright tube portion 10b and the outer surface of the raised tube 14, and both sides of the measuring chamber C in the circumferential direction are partitioned by the pair of partition walls 18, 18. ing.
This measuring chamber C is adjacent to the main communication hole 16a using the cylinder wall w of the raised cylinder 14 as a partition, and the contents introduced from the main communication hole 16a are measured in the measurement chamber C. The nozzle 40 is configured to discharge the contents from the nozzle 40.

The outer cap 20 has an outer circumferential wall 22, which is an operation tube, hanging from the circumferential end of a top plate 24 facing the top wall 12, and this outer circumferential wall 22 is rotatably fitted to the inner cap 8. ing.
Further, an upper lid 30 is connected to a portion of the outer peripheral wall 22 via a hinge 29.
A portion of the top plate 24 opposite to the hinge 29 is formed into a recessed portion 27 having a flat bottom surface. A mounting tube portion 28, which is a mounting location for the nozzle 40, is erected through the recessed portion 27. The mounting cylinder portion 28 in the illustrated example is formed into a short cylinder shape.
However, the structure of the attachment point can be changed as appropriate, for example, it may be a fitting recess for attachment.
Note that the mounting position of the nozzle 40 only needs to be located eccentrically from the rotation center of the outer cap 20, and can be changed as appropriate.
On the upper surface of the top plate 24, a nozzle mounting position indicating means N (indicated by an arrow in the illustrated example) is formed near the mounting cylinder portion 28.
Further, from the top plate 24, a hanging cylinder 26 is provided hanging down from the mounting cylinder part 28 at a position closer to the hinge. This hanging cylinder 26 is located inside the upright cylinder part 10b as shown in FIG. 3(A) when viewed from above, and hangs down to near the upper end of the upright cylinder part 10b as shown in FIG. 3(B). has been done.

As shown in FIG. 2, the upper lid 30 has a lid peripheral wall 32 formed from the peripheral end of the lid plate 34 connected to the outer cap 20 via the hinge 29.
The upper lid 30 is provided with a finger rest 36 located on the opposite side of the hinge 29.
The top plate 24 is provided with a closure portion 38 that closes off the mounting cylinder portion 28 when the lid is closed.

As shown in FIG. 2, the nozzle 40 is erected from the top plate 24 by having its lower end portion 42 removably fitted into the mounting tube portion 28.
In the illustrated example, the lower end portion 42 of the nozzle 40 is fitted to the outer surface of the mounting tube portion 28 to such an extent that the nozzle 40 does not easily separate from the attachment tube portion 28 .
When the nozzle 40 is not in use, it can be removed from the top plate 24 and stored in the storage recess 5. Thereby, even if the nozzle 40 is a long nozzle, there is an advantage that the container as a whole does not become bulky during storage.
The nozzle 40 is arranged at a position eccentric from the rotation center of the top plate 24 when viewed from above, so that by rotating the outer cap 20 with respect to the inner cap 8, the position shown in FIG. As shown, a first position where the inlet part e1 on the lower end side of the nozzle 40 faces the measuring chamber, and a second position where the inlet part e1 faces the sub-communication hole 16b as shown in FIG. 3(B). It is possible to shift between
In this embodiment, when viewed from above, the nozzle 40 approaches the first display m1 such as "Weighing" displayed on the shoulder 4 when it is in the first position, and when it is in the second position it approaches the first display m1 such as "Weighing". The second display m2 is configured to approach the second display m2 such as "appropriate amount".
Although not shown, the aforementioned nozzle 40 is fitted between the mouth barrel portion 6 and the base barrel 10 of the inner cap 8, and between the base barrel 10 and the outer cap 20 in a mutually fitted state. A means for positioning the first display m1 and the second display m2 may be provided so that the positional relationship between the first display m1 and the second display m2 is maintained.
This positioning means can be formed, for example, by providing a vertical groove on one of the base cylinder 10 and the outer circumferential wall 22, and providing a vertical rib on the other that fits in the vertical groove.

The surrounding material 50 is a member that surrounds the body 3 and can be formed as a thin membrane or film (enveloping film) wrapped around the body 3.
By wrapping the surrounding material 50, the nozzle 40 can be held between the surrounding material 50 and the storage recess 5.
As a suitable example, the surrounding material 50 can be a shrink film.

In the above configuration, when the discharge container of the present invention is used, the nozzle 40 is pulled out from the storage recess 5, the upper lid 30 is opened, and the lower end of the nozzle 40 is attached to the mounting tube 28.
At this time, when the upper lid 30 is opened, the nozzle attachment position display means appears, so even if the user is using the dispensing container for the first time, he or she can attach the nozzle 40 to the attachment cylinder part 28 without hesitation. can.
Next, the positional relationship between the nozzle 40 and the usage mode display means M is viewed from above, and the current visibility mode of the discharge container is confirmed.
If the usage mode desired by the user and the mode indicated by the display located near the nozzle 40 do not match, the outer cap 20 is rotated with respect to the inner cap 8 to change the usage mode desired by the user. The display is adjusted so that it is near the nozzle 40.
When discharging a metered amount by rotating the outer cap 20, place the inlet e1 on the lower end side of the nozzle 40 in the first position facing the metering chamber C (see FIG. 1(B)), and discharge the appropriate amount. In this case, the inlet portion e1 can be moved to a second position (see FIG. 3(B)) facing the sub-communication hole 16b.
When dispensing a measured amount, the container body 2 is tilted toward the nozzle 40 (opposite the hinge 29) from the state shown in FIG. 1(B). Then, the granules (fertilizer, etc.) in the container body 2 enter the hanging cylinder 26, and when the container body 2 is returned to its original upright state, a certain amount of granules enters the measuring chamber C, and the remaining granules enter the measuring chamber C. returns to the container body 2 side. Next, when the container body 2 is tilted again, a predetermined amount of granules measured into the measuring chamber C is discharged through the nozzle 40, as shown in FIG.
When discharging an appropriate amount, the container body 2 is tilted toward the nozzle from the state shown in FIG. 3(B). Then, the particulate matter in the container body 2 is discharged from the nozzle 40 to the outside through the sub-communication hole 16b. In this case, as shown in FIG. 5, the amount of granules is discharged in accordance with the length of the operation time for tilting the container body 2 and discharging. Therefore, an appropriate amount of liquid can be discharged.

According to the above configuration and operation, the nozzle 40 extending upward from a part of the top plate 24 of the outer cap 20 is moved between the position facing the measuring chamber C and the sub-communication hole by rotating the outer cap 20 with respect to the inner cap 8. 16 and the opposite position, two modes of metered discharge and arbitrary appropriate amount discharge can be selected as appropriate.
A raised cylinder 14 that rises from the outer peripheral part 13 of the top wall 12 toward the center, an upright cylinder part 10b that stands up from the peripheral end of the top wall 12, and a sub-communication hole formed in a part 13a of the outer peripheral part 13. A pair of partition walls 18, 18 extending from the raised tube 14 to the upright tube portion 10b are provided on both sides of the tube 16B, and these partition walls 18, 18 partition the measuring chamber C and the sub-communication hole 16B, resulting in a simple structure. The above two discharge modes can be realized.
Since the sub-communicating hole 16b extends from the outer peripheral portion 13 to the cylinder wall w of the raised cylinder 14, a sufficient opening area of the sub-communicating hole 16b can be ensured, and any appropriate amount can be smoothly discharged. Can be done.
The nozzle 40 is detachably attached to the top plate 24, and a storage section 5 for storing the nozzle 40 removed from the top plate 24 is located on the side surface of the body 3 of the container body 2. Because the nozzle 40 is housed in the container, the entire container does not become bulky, and it is easy to respond to the request for a long nozzle.

Other embodiments of the present invention will be described below. In these descriptions, descriptions of structures that are the same as those in the first embodiment will be omitted.

FIG. 6 shows a nozzle-equipped discharge container according to a second embodiment of the present invention.
In this embodiment, a mouth member 45 is attached to the upper end 44 side of the nozzle 40 of the first embodiment.
The mouth member 45 is formed by closing the upper end of a cylinder peripheral wall 46 having a vertically long cylindrical shape with a closing plate 47.
The lower half 46a of the cylinder peripheral wall 46 is fitted onto the upper end 44 of the nozzle 40.
An opening 48 that opens laterally is formed in the upper half 46b of the cylinder peripheral wall 46. This opening 48 is a particulate material discharge port (exit part e2).
A vertical rib 49 is vertically provided on the outer surface of the upper half portion 46b of the cylinder peripheral wall 46, located on the opposite side of the opening 48.
A stepped portion s is provided between the lower half portion 46a and the upper half portion 46b, and the nozzle 40 is formed so as to abut against this stepped portion s.
The opening 48 of the mouth member 45 is located on the hinge 29 side (the top plate 24 The nozzle 40 is arranged so as to face in the direction opposite to the direction X in which the nozzle 40 is eccentric with respect to the center.
The inside of the mouth member 45 serves as a temporary fixing chamber R for the granules.
In this aspect, when discharging the granules, a certain amount of the granules weighed into the measuring chamber C are not immediately discharged from the nozzle 40, but instead enter the temporary fixing chamber R, as shown in FIG. 6(D). temporarily fastened.
When the user shakes the hand holding the container body, the granules in the temporary fixing chamber R are discharged to the outside from the opening 48 due to the vibration.
The reason for adopting such a configuration is as follows.
For example, when applying fertilizer to plants, as mentioned above, the leaves of the plants are already thick, and even if you spray the fertilizer from above, those leaves will get in the way and you will not be able to reach the intended application area ( Fertilizer does not reach the roots of plants.
Therefore, it is necessary to use a long nozzle and bring the tip of the nozzle closer to the spraying location when spraying.
However, in the mode of metering and discharging, after measuring the granules into the metering chamber C, after tilting the container body 2 toward the nozzle 40 and before bringing the tip of the nozzle 40 close to the root of the plant, the amount of granules in the metering chamber C must be There is a possibility that the granules may flow downward from the nozzle 40 against the user's will.
In this case, a portion of the weighed granules ends up being scattered in places other than the intended location, such as on the leaves of the plants, making it impossible to spread a certain amount of the weighed granules to the intended location.
When using the mouth member 45 of this embodiment, these inconveniences can be avoided.

According to the configuration and operation, the nozzle 40 is arranged eccentrically in one direction In addition, since it has an outlet portion e2 that opens in the opposite direction to the one direction You can dispense an appropriate amount without any problems.

2...Container body 3...Body part 4...Shoulder part 5...Storage part (storage recess) 6...Bout part 6a...Reduced diameter part 7...Male thread part 8...Inner cap 10...Base cylinder 10a...Fitting cylinder part 10b... Standing cylinder part 11...Female thread part 12...Top wall 13...Outer circumferential part 13a...Part 13b...Other part 14...Elevated tube 16...Communication hole 16a...Main communication hole 16b...Sub-communication hole 18...Partition wall 20...Outer cap 22 …Outer peripheral wall (operation tube) 24…Top plate 26…Descent tube 27…Concave portion 28…Mounting tube portion 29…Hinge 30…Top lid 32…Lid peripheral wall 34…Cover plate 36…Finger hook portion 38…Closing portion
40... Nozzle 42... Lower end part 44... Upper end part (tip part)
45... Mouth member 46... Cylinder peripheral wall 46a... Lower half part 46b... Upper half part 47... Closure plate 48... Opening part 49... Vertical rib
50...Enveloping material (shrink film)
a1, a2...Corner C...Measuring chamber e1...Entrance part e2...Outlet part M...Usage mode display means m1...First display m2...Second display N...Nozzle installation position display means R...Temporary fixing chamber s...Step part V...Space w...Cylinder wall (of the raised cylinder)

Claims (5)

a container body (2) having a neck part (6);
It has a top wall (12) that is attached to the mouth barrel part (6) and covers the opening of the mouth barrel part (6), and a main communication hole (16a) is opened in a part of the top wall (12). Inner cap (8) and
An outer peripheral wall (22) hanging down from the peripheral end side of the top plate (24) facing the top wall (12) is fitted into the inner cap (8), and a nozzle (22) extending upward from the top plate (24) is provided. an outer cap (20) provided with an outer cap (40);
A measuring chamber (C) is provided in a part of the space between the top wall (12) and the top plate (24), close to the main communication hole (16a) when viewed from above, and the main communication hole (16a) In a nozzle-equipped discharge container provided to measure the contents introduced from the measuring chamber (C) and to discharge the measured contents from the nozzle (40),
The outer cap (20) is rotatably attached to the inner cap (8),
The nozzle (40) is arranged at a position eccentric from the rotation center of the top plate (24) when viewed from above, and is rotated in the circumferential direction by rotating the outer cap (20) with respect to the inner cap (8). provided to be displaced between a first position and a second position,
The nozzle (40) is configured to face the measuring chamber (C) at the first position and to face the sub-communication hole (16b) opened in the top wall (12) at the second position. A discharge container with a nozzle, which is characterized by: The top wall (12) includes a substantially flat outer circumferential portion (13) and a raised tube (14) that protrudes from the outer circumferential portion (13) toward the center. The main communication hole (16a) is opened,
An upright cylindrical portion (10b) is erected from the peripheral end of the top wall (12),
On both sides in the circumferential direction of the sub-communication hole (16b) formed in a part (13a) of the outer peripheral part (13), from the raised cylinder (14) to the upright cylinder part (10b) when viewed from above. forming a pair of partition walls (18, 18) leading to the
A space defined above the other part (13b) of the outer peripheral part (13) by these partition walls (18, 18), the upright cylinder part (10b), and the raised cylinder (14) is defined by the measuring chamber. The dispensing container according to claim 1, characterized in that it is (C). The auxiliary communication hole (16b) extends from the outer peripheral portion (13) to the cylindrical wall (w) of the raised cylinder (14), and is continuous with the main communication hole (16a). The nozzle-equipped discharge container according to claim 2. The nozzle (40) is detachably attached to the top plate (24),
A storage section (5) for storing the nozzle (40) removed from the top plate (24) is formed on a side surface of the body (3) of the container body (2). , A discharge container with a nozzle according to claim 1. The nozzle (40) is arranged eccentrically in one direction (X) with respect to the center of the top plate (24) when viewed from above, and the tip (44) of the nozzle (40) is The nozzle-equipped discharge container according to claim 1, characterized in that it is formed to have an outlet portion (e2) whose upper end is closed and which opens in a direction opposite to the one direction (X).