JP2015085997A - Eye drop container - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an eye drop container for preventing a liquid spill from a nozzle more reliably when mounting a cap.SOLUTION: An eye drop container C comprises: a container body 1 having a liquid storage 10 for storing an eye drop liquid, and a nozzle 16; and a cap 2 mounted on the container body 1 for covering the nozzle 16. The nozzle 16 includes a spherical leading part 17 having a nozzle hole 22 opened, and a leading part 17 positioned closer to the side of the liquid storage 10 than the leading part 17. The cap 2 includes: a side wall part 30 enclosing the nozzle 16; a ceiling part 32; a first plug part 34 of a shaft shape protruding from the ceiling part 32 to the nozzle side and inserted into the nozzle hole 22, while the cap 2 is mounted in the liquid storage 10, to block said nozzle hole 22; and a second plug part 36 of a cylindrical shape protruding to the nozzle side from a position of such a concentric circle of the ceiling part 32 as is around said first plug part 34, and abutting from the outer side against the nozzle 16 at the position of the substantially maximum diameter of the leading part 17 in said cap mounting state.

Description

  The present invention relates to an eye drop container for containing eye drops (eye drops).

  Conventionally, it includes a container body with a nozzle and a cap that is detachably attached to the container body, and removes the cap so that the tip of the nozzle faces downward, and lightly presses the container body so that the chemical solution is dripped from the tip of the nozzle. Such ophthalmic containers are generally known.

  For example, in Patent Document 1, as one type of eye drop container, when a cap is attached to a container body, a shaft-shaped plug portion formed on the cap side is inserted into the nozzle hole (lightly press-fitted), and the plug is inserted. The nozzle opening is closed by the part. According to such an eye drop container, liquid leakage from the nozzle can be prevented while being carried.

JP-A-10-329855

  In recent years, for reasons such as prevention of makeup breakage, eye drops containers have been conceived in which the diameter of the nozzle is reduced, and the amount of one eye drop that has conventionally been about 40 to 50 μl is, for example, about half to 20 to 30 μl.

  In this type of eye drop container, the hole diameter of the nozzle hole is relatively small, and accordingly, the cap portion on the cap side is also reduced in diameter. For this reason, it becomes difficult to manage the dimensions of the nozzle hole and the plug portion, and it is difficult to reliably prevent liquid leakage from the nozzle. In particular, when the nozzle is formed of an elastomer, a soft resin, or the like, if the plug portion is inserted into the nozzle hole for a long period of time, the nozzle hole may be deformed (expanded) and cause liquid leakage. In the case of a conventional nozzle having a relatively large diameter, such a phenomenon hardly occurs because the nozzle is thick.

  Therefore, in addition to the plug portion (first plug portion) to be inserted into the nozzle hole, the applicant provides a cylindrical plug piece (second plug portion) that comes into contact (closely) with the nozzle from the outside. Therefore, it was considered to prevent liquid leakage to the outside. According to this configuration, in the cap mounted state, the nozzle is substantially double-closed by the two plug portions, so that it is possible to prevent liquid leakage more reliably. Further, since the second plug portion is in contact with the nozzle from the outside, deformation (expansion) of the nozzle is suppressed even when the first plug portion is inserted into the nozzle hole for a long time.

  However, in order to surely prevent liquid leakage, it is necessary to bring the second plug portion into close contact with the nozzle. In this case, the resistance when the cap is attached / detached increases, which may hinder operability. It is conceivable that the nozzle is deformed.

  The present invention has been made in view of the above circumstances, and the liquid from the ophthalmic container suitable for a small amount of ophthalmic application is not accompanied by inconveniences such as obstructing the cap detachment operability and causing deformation of the nozzle. It aims at providing the technique which can prevent a leak highly.

  The present invention for solving the above-mentioned problems is an ophthalmic container, which is a container main body comprising a liquid container that contains an ophthalmic solution and a nozzle for deriving the ophthalmic solution contained in the liquid container. And a cap mounted on the container body so as to cover the nozzle, and the nozzle has a spherical head portion in which the nozzle hole is opened and a body portion located on the container body side from the head portion. The cap includes a side wall surrounding the nozzle, a ceiling connected to one end of the side wall to cover the nozzle from the top side, and protruding from the ceiling to the nozzle side, and A shaft-shaped first plug portion that is inserted into the nozzle hole and closes the nozzle hole in a cap mounted state in which the cap is mounted on the container body, and a concentric circle centering on the plug portion of the ceiling portion. Noz from the position of Projecting side, those that and a second plug part cylindrical abutting from outside with respect to the nozzle at a position of substantially maximum diameter of the head portion in the cap mounting state. The cylindrical second plug portion does not mean only a strictly perfect circular cylinder, but also includes a somewhat elliptical cylinder.

  According to this eye drop container, the spherical top portion is formed on the nozzle, and the second stopper portion abuts the nozzle at the position of the substantially maximum diameter, so that the contact resistance does not become too large and the contact area is relatively small. It becomes possible to make the nozzle and the second stopper portion closely contact each other. Therefore, it is possible to highly suppress the ophthalmic solution from leaking without inconveniences such as hindering cap detachment operability and deformation of the nozzle. In addition, since the top portion of the nozzle is spherical, when the cap is mounted, the nozzle is easily guided to the inside of the second plug portion. Therefore, it is also suppressed that the nozzle hits the end surface of the second plug portion and the nozzle is deformed.

  In this eye drop container, it is preferable that the second plug portion has a tapered portion for inviting the nozzle inside the tip.

  According to this configuration, when the cap is mounted, the nozzle is more easily guided to the inside of the second plug portion, which is advantageous in suppressing deformation of the nozzle during the cap mounting operation.

  In the above-mentioned eye drop container, the body of the nozzle may have a constant outer diameter from the base end side to the head end side. In the case of reducing the target diameter, it is preferable that the outer diameter is gradually reduced from the base end side toward the leading end side. In this case, the body portion of the nozzle may be formed such that the outer surface changes in a curved shape in the direction along the central axis.

  According to such a configuration, it is possible to ensure the rigidity of the entire nozzle while reducing the diameter of the nozzle tip and relatively reducing the amount of eye drops at one time, and the deformation of the nozzle due to contact with the outside, etc. This is advantageous in terms of suppression. That is, it can be suitably used for an eye drop container designed so as to relatively reduce the amount of eye drop once.

  Moreover, each said eye drop container is useful also for the said nozzle formed with the elastomer. That is, a flexible material such as an elastomer has a property that it is difficult to return to its original shape when the deformed state is maintained. In a structure in which a plug portion is simply inserted into a nozzle hole, However, according to the above structure, the second plug is inserted from the outside with the first plug portion inserted into the nozzle hole. Since the two parts (diametrically outward and radial inward) act on the nozzle by the contact of the portions, the deformation of the nozzle is suppressed. Therefore, even when a flexible material such as an elastomer is used as the nozzle material, the deformation of the nozzle is effectively suppressed. In addition, according to the eye drop container of the present invention, it is possible to use a flexible material such as an elastomer that has heretofore been difficult to apply as the nozzle material. .

  As described above, according to the eye drop container of the present invention, liquid leakage at the time of mounting the cap can be prevented to a higher degree without inconveniences such as hindering the cap detachment operability and causing deformation of the nozzle. It becomes possible.

It is a front view (partial sectional view) showing the container for eye drops concerning the present invention. It is a schematic sectional drawing (II-II sectional view taken on the line of FIG. 1) which shows the container for eye drops. It is a front view which shows the principal part of the container for eye drops (part sectional drawing / state which removed the cap). It is a front view which shows the principal part of the container for eye drops (partial sectional view / state which attached cap).

  Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

  1 and 2 schematically show an ophthalmic container according to the present invention. An eye drop container (hereinafter abbreviated as “container”) C shown in FIG. 1 includes a liquid container 10 in which eye drops (eye drops) are stored, and a nozzle 16 for deriving the eye drops stored in the liquid container 10. And a cap 2 that is detachably attached to the container body 1 so as to cover the nozzle 16. The container C is a so-called twist cap type container.

  The method of using the container C is the same as the conventional one. When instilling ophthalmic solution, the tip of the nozzle 16 is turned downward with the cap 20 removed, and the ophthalmic solution is gently pressed by pressing the liquid container 11. It is dripped from the tip of the nozzle 16.

  As shown in the figure, the liquid container 10 has a flat shape in the front-rear direction (direction perpendicular to the paper surface of FIG. 1). The liquid container 10 includes a liquid container 11 that can store about 10 to 15 ml of ophthalmic solution, a shoulder 12 that is connected to the upper side thereof, and a cylindrical mouth that is connected to the upper side and is located at the upper center of the liquid container 11. The liquid storage part 11, the shoulder part 12, and the cylindrical mouth / neck part 13 include a neck part 13, and have a configuration in which they are integrally molded from a synthetic resin material such as polypropylene, polyethylene, polyethylene terephthalate, or the like.

  The nozzle 16 is fixed to the liquid container 10 by being inserted into the cylindrical mouth / neck portion 13. As shown in FIGS. 2 and 3, the nozzle 16 has a substantially spherical top portion 17, a substantially truncated cone-shaped body portion 18 extending in the vertical direction connected to the lower side thereof, and outwardly extending from the lower end portion thereof. Including a disc-shaped flange portion 19 and a cylindrical leg portion 20 extending downward from the lower surface of the body portion 18, and the head portion 17, the body portion 18, the flange portion 19, and the leg portion 20 are made of, for example, low-density polyethylene, It has a structure integrally molded with a soft synthetic resin material such as linear low-density polyethylene, high-density polyethylene, or polypropylene, or an elastomer. Then, the leg portion 20 is press-fitted into the cylindrical mouth / neck portion 13 so that the collar portion 19 abuts on the upper end of the cylindrical mouth / neck portion 13 of the liquid container 10, whereby the nozzle 16 is moved to the liquid container 10. It is fixed to the upper end of the.

  The nozzle 16 has a nozzle hole 22 extending in the vertical direction along the center line from the tip of the head portion 17 to the lower end of the body portion 18, and when the eye drop is instilled, the liquid container 10. The inner ophthalmic solution is led out to the tip of the head portion 17 through the nozzle hole 22.

  As shown in the figure, the body portion 18 of the nozzle 16 is formed such that the outer diameter dimension gradually decreases from the flange portion 19 side toward the head portion 17 side. As a result, in the container C of this example, the tip of the nozzle 16 is made thinner than the conventional container of this type (the container for eye drops described in the background art), and the diameter of the nozzle hole 22 is approximately 0. 0. It is set to 5 mm to 1.5 mm. Thereby, the amount of eye drops at one time can be suppressed to about 20 to 30 μl, for example.

  As shown in FIGS. 1 and 3, the cap 2 is formed so as to cover the container body 1 above the shoulder portion 10. More specifically, the cap 2 includes a side wall portion 30 that surrounds the nozzle 16 and the cylindrical mouth / neck portion 13 and the like, and a ceiling portion 32 that is connected to the upper end of the side wall portion 30 and covers the nozzle 16 from the front portion 17 side. The side wall part 30 and the ceiling part 32 are integrally formed by synthetic resin materials, such as a polypropylene, polyethylene, a polystyrene, etc. similarly to the liquid container 10, respectively.

  As shown in FIGS. 1 and 2, the side wall portion 30 has a side surface of the liquid storage portion 11 and a side surface of the cap 2 in a state where the cap 2 is mounted on the container body 1 (hereinafter simply referred to as a cap mounting state). It is configured to form a smooth outline line that is continuous in the vertical direction.

  As shown in FIG. 3, the ceiling portion 32 of the cap 2 is integrally formed with a shaft-shaped first plug portion 34 that protrudes downward (nozzle 16 side) from the center of the lower surface thereof. A cylindrical second plug portion 36 protruding downward from a position on a concentric circle centering on 34 is integrally formed.

  The first plug portion 34 is inserted into the nozzle hole 22 from the tip of the nozzle 16 in a cap mounted state to close the nozzle hole 22. The first plug portion 34 has a hemispherical distal end portion and is formed in a cross-sectional mountain shape whose outer diameter dimension gradually increases from the distal end side toward the proximal end side. With this configuration, when the cap is attached, the first plug portion 34 is inserted into the nozzle hole 22 so that the outer peripheral surface of the first plug portion 34 is in close contact with the opening edge of the nozzle hole 22.

  The second plug portion 36 substantially closes the nozzle 16 by being in close contact with the head portion 17 of the nozzle 16 from the outside in the cap mounted state. As shown in FIG. 3, the inner diameter dimension D <b> 2 of the second plug part 36 is set to a value slightly smaller than the maximum diameter dimension D <b> 1 of the head part 17 of the nozzle 16. With this configuration, the second plug portion 36 is formed so as to be in close contact with the nozzle 16 from the outside only at the position of the substantially maximum diameter of the head portion 17 formed in a spherical shape in the cap mounted state. In addition, a taper portion for inviting the nozzle 16 (leading portion 17) to the inside of the second plug portion 36 when the cap 2 is attached to the container body 1 is provided inside the tip (lower end) of the second plug portion 36. 36a is formed.

  The ceiling portion 32 of the cap 2 is further provided with a pair of locking arms 38 extending downward from the lower surfaces of the cap portions 34, 36 on the left and right sides (left and right sides in FIG. 1). It is integrally formed.

  These locking arms 38 lock the cap 2 attached to the container main body 1 to the container main body 1, and the cap 2 is attached to the container main body 1 when the cap 2 is attached to the container main body 1. It is a guide.

  Specifically, as shown in FIGS. 1 and 2, a locking projection 13 a is formed on the outer peripheral surface of the proximal end portion of the cylindrical mouth-neck portion 13 of the liquid container 10. On the other hand, a locking recess 38 a is formed in the vicinity of the tip of the opposing surface of each locking arm 38. When the cap 2 is attached to the container body 1, as shown in FIG. 1, the nozzle 16 and the cylindrical mouth / neck portion 13 are inserted between the locking arms 38, and the cylindrical mouth / neck portion 13 The locking projection 13a is inserted into the locking recess 38a. As a result, the cap 2 is locked to the container body 1 (liquid container 10) via both locking arms 38. In addition, each of the locking arms 38 is formed so that the opposing surface has an arc shape so as to correspond to the outer peripheral surface shape of the cylindrical mouth-and-neck portion 13 over the entire arm longitudinal direction, and the opposing surface is a cylindrical mouth. The interval is set so as to come into contact with the outer peripheral surface of the neck 13 from both the left and right sides. With this configuration, when the nozzle 16 and the cylindrical mouth / neck portion 13 are inserted between the locking arms 38 when the cap 2 is mounted on the container body 1, the cap 2 is interposed via the locking arms 38. The entirety is guided along the cylindrical mouth and neck portion 13.

  In the container C as described above, at the time of instillation, the cap 2 is rotated about 90 ° around the cylindrical mouth-neck portion 13 from the cap-mounted state shown in FIG. 1, thereby removing the cap 2 from the container body 1. That is, when the cap 2 is rotated, the cap 2 rides on the shoulder portion 12 of the liquid container 10, and the cap 2 is pushed upward along with this riding. Thereby, the latching state of each latching arm 38 with respect to the cylindrical mouth neck part 13 is cancelled | released. Therefore, instillation is possible by removing the cap 2 from the container body 1 in this way.

  On the other hand, after use, the cap 2 is mounted along the cylindrical mouth-neck portion 13 of the container body 1 (liquid container 10). Specifically, the cap body 2 is covered with the cap 2 so that the nozzle 16 and the cylindrical mouth-neck portion 13 are inserted between the locking arms 38, and the cap 2 is guided along the cylindrical mouth-neck portion 13. Then, the cap 2 is pushed into the container body 1 side.

  When the cap 2 is attached to the container main body 1 in this way, the first plug portion 34 of the cap 2 is inserted into the nozzle hole 22 and the nozzle hole 22 is closed as shown in FIG. In addition, the top portion 17 of the nozzle 16 is inserted inside the second plug portion 36, and the inner peripheral surface of the second plug portion 36 is in close contact with the nozzle 16 at the position of the substantially maximum diameter of the top portion 17. Become. As a result, the nozzle 16 is closed by the plug portions 34 and 36. Further, the locking projections 13 a of the cylindrical mouth and neck portion 13 are inserted into the locking recesses 38 a of the locking arms 38, whereby the cap 2 is locked to the container body 1.

  According to the ophthalmic container as described above, the nozzle 16 is doubly closed by the first plug portion 34 and the second plug portion 36 as described above. Precisely, the nozzle hole 22 is blocked by the first plug portion 34, thereby preventing liquid leakage from the nozzle hole 22. Even if the ophthalmic solution flows out from the nozzle hole 22, the first plug part 34 is in close contact with the nozzle hole 22 (leading part 17), in other words, between the nozzle hole 22 and the first plug part 34. Since the ophthalmic solution is sealed, the ophthalmic solution is prevented from leaking outside the first plug portion 34. Therefore, liquid leakage from the container C can be prevented to a high degree.

  In addition, in this container C, the spherical top portion 17 is formed on the nozzle 16, and the second plug portion 36 contacts the nozzle 16 at the position of the substantially maximum diameter, so that the contact resistance does not increase too much. The nozzle 16 and the 2nd stopper part 36 can be made to closely_contact | adhere with a contact area. That is, it is possible to ensure a sufficient surface pressure that can achieve a liquid-tight state. Therefore, the ophthalmic solution can be highly prevented from leaking without inconveniences such as hindering the attaching / detaching operability of the cap 2 and deformation of the nozzle 16 during the attaching / detaching operation.

  Moreover, according to this container C, since the top part 17 of the nozzle 16 is spherical, and the tapered part 36a is formed inside the tip (lower end) of the second plug part 36, the cap 2 is attached. At this time, the nozzle 16 is smoothly guided to the inside of the second plug portion 36. Therefore, the nozzle 16 abuts against the end surface (lower end surface) of the second plug portion 36 and is prevented from being deformed.

  Therefore, according to this container C, the liquid leakage from the container C can be highly prevented without impeding the detachability of the cap 2 or causing the deformation of the nozzle 16.

  In addition, the container C mentioned above is illustration of preferable embodiment of the container for eyedrops based on this invention, Comprising: The specific structure can be suitably changed in the range which does not deviate from the summary of this invention.

  For example, in the container C of the above-described embodiment, the body portion 18 of the nozzle 16 is formed such that the outer diameter dimension gradually decreases from the flange portion 19 (liquid container 10 side) toward the head portion 17. Of course, the outer diameter dimension of the trunk portion 18 may be constant from the flange portion 19 to the head portion 17. However, according to the configuration of the container C, it is possible to increase the rigidity of the entire nozzle 16 while reducing the diameter of the tip of the nozzle 16 and suppressing the amount of eye drops per one time. Therefore, it is advantageous in suppressing deformation of the nozzle 16 due to external contact or the like. In addition, since the constriction is formed at the connecting portion between the head portion 17 and the body portion 18, liquid breakage at the time of instillation is good. In this embodiment, as shown in FIG. 3 and the like, the body portion 18 of the nozzle 16 is formed so that the outer surface changes in a curved shape in the direction along the central axis. It may be formed to change upward.

  In the above-described embodiment, an example in which the present invention is applied to a so-called twist cap type eye drop container has been described. Of course, the present invention is also applicable to a so-called screw type eye drop container.

  In the nozzle 16 of the container C of the above embodiment, the shape of the leading portion 17 is “spherical”. In short, this “spherical” means that the leading end from the base end (body 18 side) toward the leading end. It means a shape in which the outer diameter of the portion 17 gradually increases and reaches a maximum diameter and then gradually decreases, and the outline of the leading portion 17 is rounded as a whole. Therefore, the head portion 17 is not limited to the shape described in FIG. 3 and the like, and can be appropriately changed within a range that matches the above definition.

C container for eye drops 1 container body 2 cap 10 liquid container 12 shoulder part 14 container body 16 nozzle 17 head part 18 trunk part 20 leg part 30 side wall part 32 ceiling part 34 1st plug part 36 2nd plug part

Claims (5)

A container body including a liquid container that contains the eye drop and a nozzle for deriving the eye drop contained in the liquid container;
A cap mounted on the container body so as to cover the nozzle,
The nozzle has a spherical head part in which the nozzle hole is opened and a body part located on the container body side from the head part,
The cap includes a side wall that surrounds the nozzle, a ceiling that is connected to one end of the side wall and covers the nozzle from the front side, protrudes from the ceiling toward the nozzle, and is disposed on the container body. A shaft-shaped first plug portion that is inserted into the nozzle hole and closes the nozzle hole in a cap-mounted state in which a cap is mounted, and a nozzle side from a position on a concentric circle centering on the plug portion of the ceiling portion And a cylindrical second stopper portion that contacts the nozzle from the outside at the position of the substantially maximum diameter of the head portion in the cap mounted state. The ophthalmic container according to claim 1,
The ophthalmic container characterized in that the second stopper portion has a tapered portion for inviting the leading portion of the nozzle inside the tip. The ophthalmic container according to claim 1 or 2,
The eye drop container is characterized in that the body portion of the nozzle is formed so that the outer diameter gradually decreases from the base end side toward the leading end side. The ophthalmic container according to claim 3,
The ophthalmic container characterized in that the body of the nozzle is formed such that the outer surface changes in a curved shape in a direction along the central axis. In the ophthalmic container according to any one of claims 1 to 4,
The ophthalmic container, wherein the nozzle is made of an elastomer.

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