JP2019081582A - Measuring container - Google Patents

Abstract

To provide a measuring container capable of suppressing the remaining of content liquid in a storage space.SOLUTION: A measuring container 1 according to the present invention includes a container body 10 having a mouth 13 connected to a storage space S of content liquid, a nozzle cap 20 mounted on the mouth 13, and a measuring cap 30 closing the nozzle cap 20. The nozzle cap 20 has an outer peripheral wall 23, a fitting cap part 21 having a top wall 26 connected to an upper part of the outer peripheral wall 23, a partition wall 27 connected to the fitting cap part 21 and having a bottomed cylindrical shape, a first nozzle 28 protruding upward in a bowl from an edge part of a pouring hole 27c, and a second nozzle 29 provided opposite to the first nozzle 28 and having a lower tip part than the first nozzle 28. A notch 27d communicating an accommodation space S with the second nozzle 29 is formed at a circumferential position on the partition wall 27 or the top wall 26 where the second nozzle 29 is formed.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a measuring container having a container main body provided with a cylindrical opening communicating with a content storage space, a nozzle cap attached to the opening, and a measuring cap closing the nozzle cap.

  Conventionally, a nozzle cap equipped with a nozzle is attached to the mouth of a container main body provided with a storage space for content liquid as a container for containing content liquid with a relatively high viscosity such as liquid detergent for washing or softener. In addition, a liquid measuring container having a configuration in which the nozzle cap is closed by a measuring cap is known (see, for example, Patent Document 1).

  In such a liquid measuring container, the nozzle is formed in a bowl shape and supported by the partition of the nozzle cap so that the tip thereof protrudes outward from the tip opening of the nozzle cap and is spaced from the inner circumferential surface of the nozzle cap It is common to be placed apart. This makes it possible to easily pour out the content liquid at the target location through the nozzle.

  On the other hand, the measuring cap is configured to include, for example, a measuring cup formed in a top cylindrical shape of a transparent or translucent resin material and a cap main body integrally provided on the measuring cup. The measuring cup portion has a rib-like protrusion or a scale indicated by printing or the like, and the scale can be used to measure the poured liquid. In addition, when the measuring cap is attached to the nozzle cap, the open end of the measuring cup portion is positioned at the inner portion of the nozzle cap, whereby the content liquid remaining inside the measuring cup portion is It can be returned to the inside of the container body without dropping down to the outside of the mouth.

JP, 2010-126232, A

  However, in the above-mentioned conventional liquid measuring container, when the container body is inclined to the inclined posture for pouring out the content liquid, the content liquid gets into the recess formed between the outer edge of the partition wall and the opening, It was difficult to pour out all the contents in the storage space.

  An object of the present invention is to solve such problems, and it is an object of the present invention to provide a measuring container capable of suppressing the residual liquid content in the accommodation space.

The measuring container of the present invention is
A measuring container comprising a container main body provided with a cylindrical opening communicating with a storage space for content liquid, a nozzle cap attached to the opening, and a measuring cap closing the nozzle cap.
The nozzle cap is
A mounting cap portion having an outer peripheral wall mounted to the mouth portion and a top wall connected to an upper portion of the outer peripheral wall;
A partition which is connected to the mounting cap and disposed radially inside and has a bottomed cylindrical shape;
A first nozzle protruding like a bowl from the edge of the pouring hole formed on the bottom wall of the partition wall;
And a second nozzle provided circumferentially opposite to the first nozzle and having a lower tip end than the first nozzle.
The measuring cap is
An apical cylindrical cap main body which is detachably mounted on the mounting cap and covers the first nozzle and the second nozzle;
And a measuring cup section defined by the top wall of the cap body and the cylindrical wall projecting from the lower surface of the top wall;
In the circumferential position including at least a part of the circumferential position at which the second nozzle is formed in the partition wall or the top wall, a notch communicating the accommodation space with the second nozzle is formed. It is characterized by

  In the measuring container of the present invention according to the above-mentioned configuration, preferably, the second nozzle is formed on the radially outer side of the cylindrical wall.

  In the measuring container of the present invention according to the above-mentioned configuration, it is preferable that the base end of the second nozzle does not protrude downward from the ceiling wall.

  In the measuring container according to the present invention as described above, preferably, the notch extends upward at least to the height of the ceiling wall.

  In the measuring container according to the present invention, in the above-mentioned configuration, the notch is provided apart from the pouring hole, and constitutes a second pouring hole having a smaller opening area than the pouring hole. Is preferred.

  ADVANTAGE OF THE INVENTION According to this invention, the measuring container which can suppress the remaining of the content liquid in accommodation space can be provided.

It is a partial cross section figure of the measuring container which is a 1st embodiment of the present invention. It is sectional drawing which expands and shows the principal part of the measuring container which is 1st Embodiment of this invention. It is sectional drawing which expands and shows the principal part of the measuring container which is 2nd Embodiment of this invention.

  The invention will now be illustrated in more detail with reference to the drawings.

  The measuring container 1 according to the first embodiment of the present invention shown in FIG. 1 is used for the purpose of containing a relatively viscous content liquid such as a liquid detergent for washing and a softener, for example. , The nozzle cap 20 and the measuring cap 30. In the specification, claims, abstract, and drawings, the side on which the measuring cap 30 is located is the upper side (upper side in FIG. 1), and the side on which the container body 10 is positioned is the lower side (lower side in FIG. 1). I assume. Further, the radially outer side is a direction toward the outside along a straight line perpendicular to the central axis through the central axis of the measuring container 1 extending in the vertical direction in FIG. 1, and the radially inner side is along the straight line It points in the direction towards the central axis. In addition, the central axis in FIG. 1 is used for the definition of radial direction outer side and radial inner side, and each member of the measuring container 1 of this embodiment is always formed axially symmetrical around this central axis line. Does not mean.

  The container body 10 is formed in a bottle shape having a body portion 11 provided with an accommodation space S inside, a bottom portion 12 closing the lower end of the body portion 11, and a cylindrical mouth portion 13 connected to the accommodation space S Content liquid (not shown) can be accommodated in the accommodation space S. As this container main body 10, for example, those made of synthetic resins such as polyethylene (PE), polypropylene (PP), polystyrene (PS) and the like can be used. In addition, the opening 13 is not limited to a cylindrical shape, and may be formed into another shape as long as it has a cylindrical shape such as an elliptical cylindrical shape or a square cylindrical shape.

  As shown in FIG. 2, the nozzle cap 20 has a mounting cap 21 having a peripheral wall 23 mounted on the mouth 13 of the container body 10 and a top wall 26 connected to an upper portion of the peripheral wall 23; And a partition 27 having a cylindrical shape with a bottom, which is connected to the inner side in the radial direction, and protrudes upward from the edge of the pouring hole 27c formed in the bottom wall 27b of the partition 27 The first nozzle 28 and a second nozzle 29 provided so as to face the first nozzle 28 in the circumferential direction and having a lower tip end than the first nozzle 28 are provided. In the present embodiment, the mounting cap portion 21, the partition wall 27, the first nozzle 28, and the second nozzle 29 are integrally formed, and can be made of, for example, synthetic resin.

  More specifically, the mounting cap portion 21 has a cylindrical outer peripheral wall 23 larger in diameter than the opening 13, and a female screw 23a integrally provided on the inner peripheral surface of the outer peripheral wall 23 is of the opening 13. The mounting cap portion 21 is mounted on the mouth portion 13 by screwing to an external thread 13 a integrally provided on the outer peripheral surface. A plurality of recessed grooves 23 b are provided at the lower end of the outer peripheral wall 23, and a locking rib 13 b provided at the root of the mouth 13 is engaged with the recessed groove 23 b. Thus, the mounting cap portion 21 is held in the mounted state with respect to the mouth 13 and is not easily removed from the mouth 13.

  In the case of illustration, the mounting cap portion 21 is configured to be attached to the opening 13 by screw connection, but is not limited to this. For example, the attachment cap 21 may be attached to the opening 13 by other means such as undercut. You can also In this case, the outer peripheral wall 23 can be formed into another shape such as an elliptical cylindrical shape or a rectangular cylindrical shape in accordance with the shape of the opening 13.

  The mounting cap portion 21 includes a top wall 26 connected to the upper portion of the outer peripheral wall 23. The seal wall 26 a is suspended from the inside in the radial direction of the outer peripheral wall 23 of the top wall 26, and by fitting the seal wall 26 a to the inner peripheral surface of the opening 13, the mounting cap 21 is formed of the opening 13. The top opening is sealed in a liquid tight manner. At the radially inner end of the top wall 26, a partition wall 27 is formed. The partition wall 27 has a bottomed cylindrical shape as shown in FIG. 2, and has a side wall 27a and a bottom wall 27b closing the lower end portion of the side wall 27a. At the center in the radial direction of the bottom wall 27b, there is provided a pouring hole 27c for communicating the storage space S with the outside and for discharging the content liquid in the storage space S to the outside. The configuration of the partition wall 27 will be described in detail later.

  The mounting cap portion 21 further includes a mounting cylinder 25. The mounting cylinder 25 has a smaller diameter than the outer peripheral wall 23 and is formed in a cylindrical shape coaxial with the outer peripheral wall 23, and protrudes upward from the upper surface of the top wall 26. A male screw 25 a for mounting the measuring cap 30 is integrally provided on the outer peripheral surface of the mounting cylinder 25.

  The first nozzle 28 is formed in a C-shape in cross section, that is, in a bowl shape, having a slit 28a extending from one end to the other end along the axial direction on the side surface. The first nozzle 28 is disposed radially spaced from the inner peripheral surface of the cylindrical wall 32 a of the measuring cup portion 32 when the measuring cap 30 is attached. The front end of the first nozzle 28 is inclined to the upper end opening of the mouth 13 so that the side on which the slit 28 a is provided is lowered toward the accommodation space S of the container body 10, the front end Protrudes upward from the upper end of the mounting cylinder 25. Further, this inclined portion is subjected to R-surface processing so that the user can easily handle it. With such a configuration, the content liquid stored in the storage space S of the container main body 10 can be easily poured out to a desired position through the first nozzle 28.

  In addition, the tip of the first nozzle 28 is not limited to the shape inclined obliquely, but various shapes such as a shape parallel to the upper opening of the opening 13 or a shape cut roundly when viewed from the side It can be shaped.

  As shown in FIG. 2, a second nozzle 29 is formed at a position facing the first nozzle 28 in the circumferential direction. The tip of the second nozzle 29 protrudes to a position lower than the first nozzle 28 and higher than the upper end of the mounting cylinder 25. Further, the second nozzle 29 is formed at a radial position which is radially outward of the first nozzle 28. In the present embodiment, the second nozzle 29 is formed in an area less than 180 degrees in the circumferential direction, and is formed so as not to overlap the first nozzle 28 in the circumferential direction. As described later, the second nozzle 29 suppresses the remaining of the content liquid by using the second nozzle 29 instead of the first nozzle 28 when the remaining amount of the content liquid in the storage space S decreases. And you can finish using it.

  The partition wall 27 has a bottom wall 27b inclined downward toward the slit 28a side of the first nozzle 28, and is continuous with a side wall 27a depending from the top wall 26 at the outer peripheral edge thereof. Notches 27d are formed at circumferential positions where the second nozzle 29 is formed in the side wall 27a and the bottom wall 27b. In the present embodiment, the notch 27d extends from the lower surface of the top wall 26 in the side wall 27a to the pouring hole 27c provided in the bottom wall 27b, and the notch 27d is connected to the pouring hole 27c to form an opening. doing. As described above, by forming the notches 27 d in the partition wall 27 at the circumferential position where the second nozzle 29 is provided, even when the remaining amount of the content liquid in the accommodation space S decreases, the second nozzle 29 can be used. By pouring out the remaining content liquid, the content liquid is poured out from the second nozzle 29 through the notch 27d without being stored in the recess formed between the partition wall 27 and the opening 13. can do.

  In addition, the content liquid which drips down along the outer peripheral surface of the 1st nozzle 28 after pouring out of content liquid can be collected to the lowest part of the dividing partition 27 which inclines, and can be returned to the accommodation space S through the slit 28a.

  The measuring cap 30 is made of, for example, transparent or translucent resin, and includes a cap body 31 and a measuring cup 32.

  The cap main body portion 31 is slightly shrunk further upward from the mounting cylinder 31a formed in a cylindrical shape having a larger diameter than the mounting cylinder 25 by a synthetic resin material and the upper end portion of the mounting cylinder 31a. It is formed in a top cylindrical shape having a radially extending side wall 31d and a top wall 31b integrally provided at the upper end of the side wall 31d. A female screw 31c is integrally provided on the inner peripheral surface of the mounting cylinder 31a, and the cap main body portion 31 is mounted on the mounting cap by screwing the female screw 31c to a male screw 25a formed on the outer peripheral surface of the mounting cylinder 25. The unit 21 is detachably mounted. A seal wall 31f is suspended from the lower surface of the upper wall 31e at the radially inner side of the mounting cylinder 31a, and is fitted on the inner peripheral surface of the mounting cylinder 25 to seal the open end of the mounting cylinder 25 in a liquid tight manner. ing.

  When the cap body 31 is attached to the mounting cap 21, the first nozzle 28 and the second nozzle 29 are covered by the cap body 31, and the nozzle cap 20 is closed. On the other hand, when the cap body portion 31 is removed from the mounting cap portion 21, the first nozzle 28 and the second nozzle 29 are exposed, and the content liquid can be poured out.

  The measuring cup portion 32 has a cylindrical tubular wall 32a projecting from the inner surface of the top wall 31b of the cap main body portion 31, and is partitioned by the tubular wall 32a and the top wall 31b of the cap main body portion 31 It is formed in a cup shape. On the side surface of the cylindrical wall 32a, for example, a rib-like protrusion or a measurement scale displayed by printing or the like may be provided.

  The measuring cap 30 is used as a measuring cup for measuring liquid by setting the top wall 31 b of the cap main body 31 formed in a flat plate shape to the lower side and setting the opening of the measuring cup 32 to the upper side. be able to.

  When the measuring cap 30 is attached to the nozzle cap 20 shown in FIG. 1, the cap main body 31 is turned to release the screw connection between the cap main body 31 and the mounting cylinder 25. 30 moves upward. Then, with the screw engagement completely released, the cap body 31 is pulled upward, thereby moving the cylindrical wall 32a disposed between the side wall 27a of the partition wall 27 and the first nozzle 28 upward. Can be removed from the nozzle cap 20.

  With the measuring cap 30 removed from the nozzle cap 20 and the first nozzle 28 and the second nozzle 29 exposed, the slit 28 a is directed upward from an upright position in which the tip of the first nozzle 28 faces upward with the container body 10 facing upward. By setting it as the following inclination attitude | position, the content liquid in the accommodation space S can be poured out from the front-end | tip part of the 1st nozzle 28 through the pouring hole 27c. At this time, the partition 27 is provided inside the mouth portion 13 and the first nozzle 28 is erected from the inner peripheral edge of the partition 27. Therefore, the content liquid in the storage space S of the container main body 10 has a bowl shape. It is guided along the formed first nozzle 28 and poured out from the tip of the first nozzle 28. In addition, even if the content liquid attached to the tip of the first nozzle 28 drips down along the outer peripheral surface of the first nozzle 28 when the container main body 10 is returned to the upright posture after the content liquid is poured out, The content liquid drips down along the first nozzle 28 without dropping to the outside of the mouth portion 13 and is received by the upper surface of the partition wall 27, and the receiving space of the container body 10 from the portion of the slit 28 a of the first nozzle 28 It will be returned to S. Therefore, according to this measuring container 1, it is possible to prevent dripping of the content liquid to the outside while pouring out the content liquid from the first nozzle 28.

  In the pouring of the content liquid by the first nozzle 28, the container body 10 is in the inclined posture in which the slit 28a is at the upper side, so that the content liquid is poured out. Therefore, the partition wall at the circumferential position facing the slit 28a in FIG. The content liquid is stored in the gap (concave portion) formed between the side wall 27 a of the housing 27 and the inner peripheral surface of the opening 13, and the stored content liquid can not be poured out. So, in this embodiment, the 2nd nozzle 29 is formed in the circumferential direction position which counters the 1st nozzle 28. As shown in FIG. The tip of the second nozzle 29 is lower than the first nozzle 28, and the base end of the second nozzle 29 terminates at the top wall 26 and extends downward from the top wall 26. Absent. In the partition wall 27, a notch 27d extends from the lower surface of the top wall 26 to a pouring hole 27c provided in the bottom wall 27b at a circumferential position where the second nozzle 29 is disposed. That is, the notch 27d is connected to the pouring hole 27c to form an opening.

  As described above, at the circumferential position where the second nozzle 29 is formed, a member that blocks the pouring of the content liquid is not disposed below the top wall 26. Therefore, when the remaining amount of the content liquid is reduced, the user causes the container body 10 to be inclined so that the second nozzle 29 is located below the first nozzle 28, and causes the content liquid to be poured out. The liquid content in the storage space S passes through the opening 13 along the inner peripheral surface of the container body 10, and then passes through the notch 27d immediately below the second nozzle 29 and is ejected from the tip of the second nozzle 29. Be As described above, when the second nozzle 29 is used, a recess like the first nozzle 28 is not formed in the flow path through which the content liquid flows, so that the storage of the content liquid is suppressed. Can. Therefore, it is possible to finish using the measuring container 1 with the content liquid almost used up.

  In the present embodiment, since the height of the tip of the second nozzle 29 is formed lower than that of the first nozzle 28, a small amount of the content liquid is more accurately poured out to the target location through the second nozzle 29. can do. In addition, when the container main body 10 is returned to the upright posture after pouring out the content liquid, even if the content liquid attached to the tip of the second nozzle 29 drips down along the outer peripheral surface of the second nozzle 29, It is received by the upper surface of the wall 26 and returned to the storage space S of the container main body 10 from the slit 28 a portion via the top wall 26 and the partition wall 27 on the first nozzle 28 side. Therefore, according to this measuring container 1, it is possible to prevent dripping of the content liquid to the outside while pouring out the content liquid from the second nozzle 29.

  The measuring cap 30 removed from the nozzle cap 20 can be used as a measuring cup for measuring liquid by setting the top wall 31 b downward and the opening of the measuring cup portion 32 upward.

  After use, the lower end portion of the cylindrical wall 32a is inserted into the space between the side wall 27a and the first nozzle 28, and the measuring cap 30 is attached to the nozzle cap 20 again, whereby the first nozzle 28 and the second nozzle 29 can be closed.

  In the present embodiment, the cap body 31 of the measuring cap 30 is attached to the attached cylinder 25 provided on the nozzle cap 20. However, the present invention is not limited to this, and the attached cylinder 25 may be provided on the nozzle cap 20. Instead, the measuring cap 30 may be mounted on the outside of the outer peripheral wall 23.

  Moreover, in this embodiment, although it was comprised so that notch 27d might be formed in the circumferential direction position same as the 2nd nozzle 29, it is not limited to this aspect. The circumferential positions of the second nozzle 29 and the notch 27d may overlap with each other only partially, and the liquid content in the accommodation space S passes through the notch 27d without being stored and is poured from the second nozzle 29. It is good if it can go out.

  Moreover, in this embodiment, although it comprised so that the 2nd nozzle 29 might be terminated to the top wall 26, it is not limited to this aspect. If the notch 27d is provided in an appropriate place with an appropriate size, it is possible if the content liquid in the accommodation space S is poured out from the second nozzle 29 without passing through the notch 27d without being stored, The second nozzle 29 may project downward beyond the top wall 26.

  Moreover, in this embodiment, although the notch 27d was comprised so that it might extend from the top wall 26 to the pouring hole 27c, it is not limited to this aspect. The notch 27 d may extend beyond the top wall 26. Moreover, the notch 27d does not necessarily have to extend to the top wall 26, and the liquid content in the accommodation space S can be poured out of the second nozzle 29 through the notch 27d without being stored. Just do it.

  As described above, in the present embodiment, the partition wall 27 connected to the mounting cap portion 21 and the edge portion of the pouring hole 27 c formed in the bottom wall 27 b of the partition wall 27 protrude upward in a bowl shape A second nozzle 29 provided so as to face the first nozzle 28 in the circumferential direction with respect to the first nozzle 28 and having a lower tip end than the first nozzle 28; At the circumferential position at which the nozzle 29 is formed, a notch 27 d for communicating the accommodation space S with the second nozzle 29 is formed. Thus, when the second nozzle 29 is used, no recess like the first nozzle 28 is formed in the flow path through which the content liquid flows, so that the remaining content liquid in the accommodation space S is suppressed. The weighing container 1 can be used up.

  Further, in the present embodiment, the second nozzle 29 is formed on the radially outer side of the cylindrical wall 32a. By this, even when the measuring volume of the measuring cup portion 32 is large and the cylindrical wall 32a extends to the lower side, it is not necessary to extend the second nozzle 29 to the lower side from the lower end of the cylindrical wall 32a. The formation of the recess to be stored can be easily avoided, and the residual content can be suppressed.

  Further, in the present embodiment, the base end portion of the second nozzle 29 is configured not to protrude below the top wall 26. By this, it is possible to avoid the formation of a recess due to the downward extension of the second nozzle 29 and to suppress the remaining of the content liquid.

  Further, in the present embodiment, the notch 27 d is configured to extend upward to the height of the ceiling wall 26. As a result, even if a recess is formed between the opening 13 and the partition wall 27, the content liquid flows to the second nozzle 29 via the notch 27d extending to the top wall 26, so that the content liquid remains It can be suppressed.

  Next, a measuring container 101 according to a second embodiment of the present invention will be exemplarily described with reference to the drawings.

  A measuring container 101 according to a second embodiment of the present invention shown in FIG. 3 has a container body 110, a nozzle cap 120 and a measuring cap 130. The present embodiment is similar to the first embodiment except for the configuration of the nozzle cap 120. Therefore, the configuration of the nozzle cap 120 will be mainly described in detail.

  As shown in FIG. 3, the nozzle cap 120 has a mounting cap portion 121 having an outer peripheral wall 123 mounted to the mouth 113 of the container body 110 and a top wall 126 connected to an upper portion of the outer peripheral wall 123; And a partition 127 having a cylindrical shape with a bottom, which is connected to the inner side in the radial direction, and protrudes upward from the edge of the pouring hole 127c formed in the bottom wall 127b of the partition 127 The first nozzle 128 and a second nozzle 129 provided to face the first nozzle 128 in the circumferential direction and having a lower tip end than the first nozzle 128 are provided.

  The mounting cap portion 121 includes a top wall 126 connected to the upper portion of the outer peripheral wall 123. The seal wall 126a is suspended from the inside in the radial direction of the outer peripheral wall 123 of the top wall 126, and the seal wall 126a is fitted to the inner peripheral surface of the opening 113 so that the mounting cap 121 The top opening is sealed in a liquid tight manner. At the radially inner end of the top wall 126, a partition wall 127 is formed. The partition wall 127 has a bottomed cylindrical shape as shown in FIG. 3 and includes a sloped portion 127e extending radially inward from the top wall 126 downward and a side wall depending from the inner peripheral end of the sloped portion 127e. A bottom wall 127b closes the lower end of the side wall 127a. At the center in the radial direction of the bottom wall 127b, a pouring hole 127c is provided for communicating the storage space S with the outside and for discharging the content liquid in the storage space S to the outside.

  The first nozzle 128 is formed in a C-shape in cross section, that is, a bowl shape, having a slit 128a extending from one end to the other end along the axial direction in the side surface. The first nozzle 128 is disposed radially spaced from the inner peripheral surface of the cylindrical wall 132 a of the measuring cup portion 132 when the measuring cap 130 is attached. The tip end portion of the first nozzle 128 is formed to be obliquely inclined with respect to the upper end opening of the mouth portion 113 so that the side where the slit 128a is provided is lowered toward the accommodation space S of the container main body 110 Protrudes upward from the upper end of the mounting cylinder 125. Further, this inclined portion is subjected to R-surface processing so that the user can easily handle it. With such a configuration, the content liquid stored in the storage space S of the container main body 110 can be easily poured out to a desired position through the first nozzle 128.

  As shown in FIG. 3, a second nozzle 129 is formed at a position facing the first nozzle 128 in the circumferential direction. The tip of the second nozzle 129 protrudes to a position lower than the first nozzle 128 and higher than the upper end of the mounting cylinder 125. Further, the second nozzle 129 is formed at a radial position that is radially outward of the first nozzle 128. In the present embodiment, the second nozzle 129 is formed in an area less than 180 degrees in the circumferential direction, and is formed so as not to overlap the first nozzle 128 in the circumferential direction. As described later, the second nozzle 129 suppresses the remaining of the content liquid by using the second nozzle 129 instead of the first nozzle 128 when the remaining amount of the content liquid in the storage space S decreases. While using it, it is possible to finish using the measuring container 101.

  The partition wall 127 has a bottom wall 127b inclined downward toward the slit 128a side of the first nozzle 128, and is continuous with a side wall 127a hanging from the top wall 126 via an inclined portion 127e at the outer peripheral edge thereof. . A second pouring hole 127 d (notch) is formed at a circumferential position on the inclined portion 127 e where the second nozzle 129 is formed. As described above, when the second pouring hole 127 d is formed in the inclined portion 127 e at the circumferential position where the second nozzle 129 is provided, the remaining amount of the content liquid in the accommodation space S decreases. The remaining liquid can be poured out through the second pouring hole 127 d and the second nozzle 129. Thus, the content liquid can be poured out of the second nozzle 129 through the second pouring hole 127 d without being stored in the recess formed between the partition wall 127 and the opening 113.

  In addition, the content liquid which drips down along the outer peripheral surface of the 1st nozzle 128 after pouring out of content liquid can be collected to the lowest part of the dividing partition 127 which inclines, and can be returned to the accommodation space S through the slit 128a.

  When the measuring cap 130 is attached to the nozzle cap 120 shown in FIG. 3, turning the cap main body portion 131 to release the screw connection between the cap main body portion 131 and the mounting cylinder 125, the measuring cap against the nozzle cap 20 130 moves upward. Then, by pulling the cap main body portion 131 upward in a state in which the screw engagement is completely released, the cylindrical wall 132 a disposed between the side wall 127 a of the partition wall 127 and the first nozzle 128 is moved upward Can be removed from the nozzle cap 120.

  With the measuring cap 130 removed from the nozzle cap 120 and the first nozzle 128 and the second nozzle 129 exposed, the container body 110 is moved upward from the erected posture in which the tip of the first nozzle 128 faces upward. By setting it as the following inclination attitude | position, the content liquid in the accommodation space S can be poured out from the front-end | tip part of the 1st nozzle 128 through the pouring hole 127c. At this time, since the partition 127 is provided inside the mouth 113 and the first nozzle 128 is erected from the inner peripheral edge of the partition 127, the content liquid in the storage space S of the container main body 110 is in a bowl shape. It is guided along the formed first nozzle 128 and poured out from the tip of the first nozzle 128. In addition, even if the content liquid attached to the tip of the first nozzle 128 drips down along the outer peripheral surface of the first nozzle 128 when the container main body 110 is returned to the upright posture after the content liquid is poured out, The content liquid drips down along the first nozzle 128 without dripping to the outside of the opening 113 and is received by the upper surface of the partition 127, and from the portion of the slit 128 a of the first nozzle 128, the accommodation space of the container body 110 It will be returned to S. Therefore, according to this measuring container 101, it is possible to prevent dripping of the content liquid to the outside while pouring out the content liquid from the first nozzle 128.

  In the pouring of the content liquid by the first nozzle 128, the container body 110 is in the inclined posture in which the slit 128a is at the upper side, so that the content liquid is poured out. Therefore, the partition wall at the circumferential position facing the slit 128a in FIG. The content liquid is stored in the gap (concave portion) formed between the side wall 127 a of the portion 127 and the inner circumferential surface of the opening 113, and the stored content liquid can not be poured out. So, in this embodiment, the 2nd nozzle 129 is formed in the circumferential direction position which counters the 1st nozzle 128. As shown in FIG. The height of the tip of the second nozzle 129 is lower than that of the first nozzle 128, and the base end of the second nozzle 129 terminates at the top wall 126 and extends below the top wall 126. Absent. And the 2nd pouring hole 127d is provided in the circumferential direction position in which the 2nd nozzle 129 is arranged at inclination part 127e of partition 127. As shown in FIG.

  As described above, at the circumferential position where the second nozzle 129 is formed, the second pouring hole 127 d is formed adjacent to the top wall 126. Therefore, when the remaining amount of the content liquid is reduced, the user causes the container main body 110 to be inclined so that the second nozzle 129 is located below the first nozzle 128, and the content liquid is poured out. After the content liquid in the accommodation space S passes through the opening 113 along the inner peripheral surface of the container body 110, it passes through the second pouring hole 127d immediately below the second nozzle 129, and the tip of the second nozzle 129 It is poured out from As described above, when the second nozzle 129 is used, a recess like the first nozzle 128 is not formed in the flow path through which the content liquid flows, so that the storage of the content liquid is suppressed. Can. Therefore, it is possible to finish using the measuring container 101 while the content liquid is almost used up.

  In the present embodiment, since the height of the tip of the second nozzle 129 is formed lower than that of the first nozzle 128, a small amount of content liquid is more accurately poured out to the target location through the second nozzle 129. can do. In addition, when the container main body 110 is returned to the upright posture after the content liquid is poured out, even if the content liquid attached to the tip of the second nozzle 129 drips down along the outer peripheral surface of the second nozzle 129 It is received by the upper surface of the wall 126, and is returned from the slit 128a portion to the accommodation space S of the container body 110 via the top wall 126 and the partition wall 127 on the first nozzle 128 side. Therefore, according to this measuring container 101, it is possible to prevent dripping of the content liquid to the outside while pouring out the content liquid from the second nozzle 129.

  In the present embodiment, the second pouring holes 127d are formed at the same circumferential position as the second nozzle 129, but the present invention is not limited to this aspect. The circumferential positions of the second nozzle 129 and the second pouring hole 127 d may be partially overlapped with each other, and the second nozzle may not flow through the second pouring hole 127 d without the content liquid in the accommodation space S being stored. It is good if it can pour out from 129.

  Moreover, in this embodiment, although it comprised so that the 2nd nozzle 129 might be terminated by the top wall 126, it is not limited to this aspect. By providing the second pouring hole 127 d with a suitable size at an appropriate place, the content liquid in the accommodation space S passes through the second pouring hole 127 d without being stored, and is poured from the second nozzle 129. If possible, the second nozzle 129 may project downward beyond the top wall 126.

  Further, in the present embodiment, the top wall 126 and the side wall 127a are connected via the inclined portion 127e, and the second pouring hole 127d is formed in the inclined portion 127e, but the present invention is not limited thereto. The side wall 127a may be directly connected to the ceiling wall 126 without providing the inclined portion 127e. Further, the second pouring hole 127d may be formed in the side wall 127a or the top wall 126.

  As described above, in the present embodiment, the partition wall 127 coupled to the mounting cap portion 121 and the edge portion of the pouring hole 127 c formed in the bottom wall 127 b of the partition wall 127 protrude upward in a bowl shape A second nozzle 129 provided so as to face the first nozzle 128 in the circumferential direction with respect to the first nozzle 128 and having a lower tip end height than the first nozzle 128; At the circumferential position where the nozzle 129 is formed, a second pouring hole 127 d is provided, spaced apart from the pouring hole 127 c and communicating the accommodation space S with the second nozzle 129. By this, when using the second nozzle 129, it is possible to flow through the second pouring hole 127d, so it is possible to suppress the remaining of the content liquid in the accommodation space S and finish using the measuring container 101. it can. Further, since the second pouring hole 127d is formed separately from the pouring hole 127c and has a smaller opening area than the pouring hole 127c, the remaining amount of the liquid in the storage space S is small. When it does, a small amount of content liquid can be made easy to pour out through this 2nd pouring hole 127d. In addition, when refilling the content liquid through the pouring hole 127c, the air in the accommodation space S can be discharged from the second pouring hole 127d simultaneously with the pouring of the content liquid, so that the refilling of the content liquid can be performed smoothly. It can be carried out.

  As shown in FIG. 3, an annular lip 132c is integrally provided at the lower end of the cylindrical wall 132a, and when the measuring cap 130 is attached to the nozzle cap 120, the lip 132c is a side wall 127a of the partition 127. It can also be configured to abut on. This prevents the content liquid remaining in the measuring cup portion 132 from coming around between the tip of the cylindrical wall 132a and the partition wall 127 to the outside of the cylindrical wall 132a and adhering to the outer peripheral surface of the cylindrical wall 132a. be able to.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various changes and modifications based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention. For example, functions included in each component can be rearranged so as not to be logically contradictory, and a plurality of components can be combined or divided into one. It should be understood that these are also included in the scope of the present invention.

DESCRIPTION OF SYMBOLS 1 measuring container 10 container main body 11 body 12 bottom 13 opening 13a male screw 13b locking rib 20 nozzle cap 21 mounting cap 23 outer peripheral wall 23a female screw 23 groove 25 mounting cylinder 25a male screw 26 top wall 26a seal wall 27 partition 27a Side wall 27b Bottom wall 27c Injection hole 27d Notch 28 First nozzle 28a Slit 29 Second nozzle 30 Measuring cap 31 Cap body 31a Mounting cylinder 31b Top wall 31c Female thread 31d Side wall 31e Top wall 31f Sealing wall 32 Measurement cup portion 32a Cylinder Wall 101 Measuring container 110 Container body 111 Body 112 Bottom 113 Opening 113a Male thread 113b Locking rib 120 Nozzle cap 121 Mounting cap 123 Outer peripheral wall 123a Female thread 123b Recess groove 125 Mounting cylinder 125a Male thread 126 Top wall 126a Seal wall 27 partition wall 127a side wall 127b bottom wall 127c Note Deana 127d second Note Deana (notch)
127e inclined portion 128 first nozzle 128a slit 129 second nozzle 130 measuring cap 131 cap body portion 131a mounting cylinder 131b top wall 131c female screw 131d side wall 131e upper wall 131e upper wall 131f sealing wall 132 measuring cup portion 132a cylindrical wall S accommodation space

Claims (5)

A measuring container comprising a container main body provided with a cylindrical opening communicating with a storage space for content liquid, a nozzle cap attached to the opening, and a measuring cap closing the nozzle cap.
The nozzle cap is
A mounting cap portion having an outer peripheral wall mounted to the mouth portion and a top wall connected to an upper portion of the outer peripheral wall;
A partition which is connected to the mounting cap and disposed radially inside and has a bottomed cylindrical shape;
A first nozzle protruding like a bowl from the edge of the pouring hole formed on the bottom wall of the partition wall;
And a second nozzle provided circumferentially opposite to the first nozzle and having a lower tip end than the first nozzle.
The measuring cap is
An apical cylindrical cap main body which is detachably mounted on the mounting cap and covers the first nozzle and the second nozzle;
And a measuring cup section defined by the top wall of the cap body and the cylindrical wall projecting from the lower surface of the top wall;
In the circumferential position including at least a part of the circumferential position at which the second nozzle is formed in the partition wall or the top wall, a notch communicating the accommodation space with the second nozzle is formed. Measuring container characterized by   The measuring container according to claim 1, wherein the second nozzle is formed radially outward of the cylindrical wall.   The measuring container according to claim 1, wherein a proximal end portion of the second nozzle does not protrude downward from the ceiling wall.   The measuring container according to any one of claims 1 to 3, wherein the notch extends upward at least to the height of the top wall.   The said notch is spaced apart and provided with the said pouring hole, and comprises the 2nd pouring hole whose opening area is smaller than this pouring hole, It is described in any one of Claim 1 thru | or 4 Weighing container.

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