JP2016175700A - nozzle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a nozzle which achieves a small drop amount in an eye drop container, prevents deterioration etc. of dropping performance from being caused by repetitive use, and inhibits variations in the drop amount to allow small drops to be stably provided in a secure manner.SOLUTION: A nozzle 10 drops droplets. A tip part surface of the nozzle 10 includes: a first drop part 11 having a first surface 11a positioned at the center side of the nozzle 10; and a second drop part 12 having a second surface 12a which continues into the outer periphery side of the first surface 11a. The first surface 11a has liquid repellency higher than that of the second surface 12a.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a nozzle that is provided, for example, in an eye drop container for dropping eye drops and can drop liquid in a container little by little.

In general, an eye drop container or the like is provided with a nozzle at a dispensing portion so that a liquid (eye drop) in the container can be dropped little by little.
Here, the human eye usually has a volume for holding about 20 μl of tear fluid, but with a conventional eye dropper nozzle, the drop volume of one drop is generally about 30 to 40 μl. There was a problem that almost half of the dropped eye drops overflowed from the eyes.
In view of this, a proposal has been made regarding a nozzle for an eye drop container that allows a smaller amount of dripping corresponding to the tear volume of human eyes.

For example, Patent Document 1 includes a needle part having an outer diameter of 0.5 mm or more and 2.5 mm or less at the tip of a pouring nozzle for dropping eyedrops from a container, so that the dropping amount of one drop is about 5 to 5. An “eye drop container” that can be about 25 μl has been proposed.
Further, in Patent Document 2, a liquid-repellent substance is applied to the nozzle tip sealing portion inside the cap of the chemical solution container, and when the cap is closed, the liquid-repellent substance is transferred to the nozzle side. There has been proposed a “liquid container with a water repellency on the nozzle” that allows the tip of the nozzle to have liquid repellency so that the amount of one drop can be controlled.

International Publication No. JP 2011-105339 A

However, in the “eye drops container” described in Patent Document 1, an attempt is made to reduce the amount of dripping by providing a fine needle part at the tip of the nozzle, but the needle part itself has no liquid repellency and is dripping. In the meantime, there is a problem that droplets adhere to or remain at the tip of the nozzle including the needle portion, and stable quantitative dropping cannot be performed as it is repeatedly used.
In addition, the fine needle of 0.5 to 2.5 mm has a fear of being pierced by the eyes because the tip looks very sharp for the user who is instilling.
Also, even with such a fine needle, the amount of dripping is limited to about 10 μl at most, and it cannot be said that the amount of dripping is small enough.

On the other hand, in the “liquid container” described in Patent Document 2, a liquid-repellent substance is applied to the tip of the nozzle through a cap, and a substance different from eye drops is applied to the tip of the eye drop container. Problems such as contamination caused by the inflow of foreign matter into the container and adverse effects on the human body were easily recalled. In addition, similarly to Patent Document 1, there is also a problem in that stable quantitative dropping cannot be performed while repeated use.
For this reason, there are basically problems as eye drop containers for eye drops, and it is considered impossible to actually carry out, and cannot be a means for solving the problems of the conventional eye drop containers as described above. It was.

  The present invention has been proposed in order to solve the problems of the conventional techniques as described above, and it is possible to reduce the amount of dripping in an eye drop container and to reduce dripping and remaining liquid on the nozzle top surface. Prevents contamination of the tip of the nozzle, contamination from foreign matter and microorganisms due to liquid return from the nozzle to the container body, and no problems such as deterioration of dripping performance due to repeated use, stable without dripping variation It is an object of the present invention to provide a nozzle suitable for an eye drop container that can reliably drop a small amount of drops.

  In order to achieve the above object, the nozzle of the present invention is a nozzle for dropping droplets, and the tip surface of the nozzle is a first surface located on the nozzle center side, and the outer periphery of the first surface. A second surface that is continuous to the side, and the first surface and the second surface are composed of surfaces having different surface free energies.

According to the present invention, it is possible to reduce the amount of dripping in an eye drop container, to prevent dripping and remaining liquid on the nozzle top surface, contamination of the nozzle tip, foreign matter due to liquid return from the nozzle into the container body, There is no contamination with microorganisms, and it is possible to prevent problems such as deterioration in dropping performance even by repeated use.
Further, there is no variation in the amount of dripping, and a stable small amount of dripping can be reliably performed, and a nozzle suitable for an eye drop container can be realized.

The nozzle which concerns on one Embodiment of this invention is shown, (a) is sectional drawing of the whole container for eye drops, (b) is an expanded sectional view of the front-end | tip part of the nozzle shown to (a). It is explanatory drawing which shows typically the state of the droplet of a nozzle by the presence or absence of liquid repellent finishing, (a) is a case without a liquid repellent finish, (b) is a case with a nozzle with liquid repellent finish. It is explanatory drawing which shows the dispersion | variation in the dripping amount in a nozzle with a liquid repellent process typically, (a) is normal, (b) is uneven in liquid repellency, (c) is a droplet. When air is caught, (d) is a case where there is a circumferential protrusion (burr) at the opening of a nozzle with liquid repellent finish. It is explanatory drawing which shows typically embodiment of the 1st / 2nd surface of the nozzle front-end | tip part which concerns on this invention. (A) is a case where the 1st / 2nd surface is constituted by projecting the cylindrical 1st dropping part from the tip of the 2nd dropping part arranged on the perimeter. (B) is a case where the area of the 1st surface is expanded by thickening the cylindrical part which comprises the 1st dripping part shown to (a). (C) is a case where the side surface of the 1st dripping part shown to (b) is liquid-repellent processed similarly to the 2nd surface. (D) is a case where the first / second surface is configured without causing the first dropping portion to protrude from the tip of the second dropping portion. (E) is a case where the front-end | tip of the 1st dripping part shown to (a) is made into a taper shape, and the 1st surface is made to incline in a dripping direction. (F) is a case where the tip of the first dripping portion shown in (a) is formed in a trumpet shape to enlarge the area of the first surface and project to the second surface side. (G) is a case where the first / second surface is integrally formed at the tip of the second dropping portion. (H) is a case where a 1st dripping part is comprised with a fiber member, a nonwoven fabric, etc. instead of the cylindrical 1st dripping part shown to (a). FIG. 5 is an explanatory view schematically showing an embodiment of the first / second surface of the nozzle tip portion according to the present invention, following FIG. 4. (A) is a case where the 1st dripping part which chamfered the front-end | tip part inner surface is arrange | positioned without protruding from the front-end | tip of a 2nd dripping part, and a chamfering shape part is comprised as a 1st surface. (B) is a case where the chamfered first surface shown in (a) is formed integrally with the second surface at the tip of the second dropping portion. It is explanatory drawing which shows typically the form of the liquid-repellent rough surface formed as a 2nd surface in the front-end | tip part of the nozzle which concerns on one Embodiment of this invention. It is explanatory drawing which shows typically the contact pattern of the droplet in the rough surface shown in FIG. 6 by Cassie-Baxter model and Wenzel model. It is explanatory drawing which expands and shows the other form of the rough surface formed as a 2nd surface in the front-end | tip part of the nozzle which concerns on one Embodiment of this invention. It is explanatory drawing which expands and shows the form of the suitable rough surface formed as a 2nd surface in the front-end | tip part of the nozzle which concerns on one Embodiment of this invention. The cap which covers the nozzle which concerns on one Embodiment of this invention is shown, (a) is principal part sectional drawing of the container for eye drops which attached the cap, (b) is an expanded sectional view of the nozzle front-end | tip part of the cap shown to (a). It is. The other form of the cap which covers the nozzle which concerns on one Embodiment of this invention is shown, (a) is principal part sectional drawing of the eye drop container which removed the cap, (b) is the principal part of the eye drop container which attached the cap. Sectional drawing, (c) is an enlarged sectional view of the nozzle tip portion of the cap shown in (b). FIG. 4 shows still another embodiment of a cap covering a nozzle according to an embodiment of the present invention, (a) is a cross-sectional view of the main part of an eye drop container equipped with the cap, and (b) is a nozzle tip of the cap shown in (a). It is an expanded sectional view of a part. It is explanatory drawing which shows typically the manufacturing method of the nozzle which concerns on one Embodiment of this invention, (a) uses general injection molding, (b) performs injection compression molding or heat & cool type injection molding. This is the case. It is explanatory drawing which shows the manufacturing method of the nozzle which concerns on one Embodiment of this invention typically, and in the manufacturing method shown to Fig.13 (a), the front-end | tip part of a 2nd dripping part without using a 1st dripping part This is a case where a chamfered first surface is formed in the opening. It is explanatory drawing which shows typically the method of the fluorine plasma etching process for roughening the front-end | tip part of the nozzle which concerns on one Embodiment of this invention, and forming a 2nd surface. It is a fragmentary sectional view of the nozzle in the case of providing the reservoir part in the outer edge of the front-end | tip part of the nozzle which concerns on one Embodiment of this invention, (a) is the shape of a reservoir part over the top | upper surface of a nozzle front-end | tip part. When hung, (b) shows the case where the shape of the reservoir is slanted with respect to the top surface of the nozzle tip, and (c) shows the nozzle without the reservoir. Yes. It is principal part sectional drawing of a nozzle for demonstrating the liquid run-off performance at the time of providing the slant-shaped meat reservoir part in the outer edge of the front-end | tip part of a nozzle. It is principal part sectional drawing for demonstrating the liquid run-off performance at the time of providing the overhang-shaped meat reservoir part in the outer edge of the front-end | tip part of a nozzle. BRIEF DESCRIPTION OF THE DRAWINGS It is explanatory drawing which shows typically the manufacturing method in the case of forming a meat pool part in the nozzle which concerns on one Embodiment of this invention by hot press, (a) is an opening (discharge port) of a nozzle not obstruct | occluded by hot press. In this way, the state before hot pressing when the opening is formed large in advance is shown, (b) shows the state after hot pressing, and (c) shows the state where the nozzle opening is blocked by hot pressing. ing.

Hereinafter, embodiments of a nozzle according to the present invention will be described with reference to the drawings.
1A and 1B show a nozzle according to an embodiment of the present invention, in which FIG. 1A is a cross-sectional view of the whole eye drop container, and FIG. 1B is an enlarged cross-sectional view of a tip portion of the nozzle shown in FIG.

[Eye container]
As shown in the figure, the nozzle according to the present embodiment constitutes a nozzle 10 serving as a spout for the eye drop container 1 for eye drops.
Specifically, the eye drop container 1 includes a container main body 2 capable of containing and storing a liquid serving as eye drops inside, and a liquid protrusion protruding from substantially the center of the upper surface of the container main body 2 (bottom surface when used for dripping). The nozzle 10 used as the extraction means is provided. The container main body 2 and the nozzle 10 communicate with each other, and the eye drops stored in the container main body 2 are poured out and dripped from the opening at the tip of the nozzle 10 to the outside of the container.

[nozzle]
As shown in FIG. 1, the nozzle 10 is formed separately from the container main body 2, and is inserted and fitted into a nozzle mounting protrusion formed on the container main body 2 so as to be integrated with the container main body 2. Thus, the eye drop container 1 is configured.
Specifically, the nozzle 10 is formed in, for example, a cylindrical shape or a rectangular tube shape, and communicates with the liquid storage space of the container body 2. Then, liquid is poured out and dropped from the inside of the container body 2 through the opening at the tip of the cylindrical nozzle 10.
And the nozzle 10 which concerns on this embodiment is provided with the 1st surface 11a in which a front-end | tip part surface is located in the nozzle center side, and the 2nd surface 12a which follows the outer peripheral side of the 1st surface 11a. The first surface 11a and the second surface 12a are made of surfaces having different surface free energies. Specifically, the second surface 12a has higher liquid repellency than the first surface 11a. It has become.

More specifically, in the example illustrated in FIG. 1, the nozzle 10 is configured by combining a first dropping unit 11 and a second dropping unit 12 that are formed separately.
As shown in FIG. 1B, first, the second dropping part 12 constitutes the main body of the nozzle 10, and the first dropping part 11 is formed at the center of the tip of the second dropping part 12. Is provided with an opening (through hole) into which is inserted and fitted. And the front-end | tip part surface of this 2nd dripping part 12 is the 2nd surface 12a.
The 1st dripping part 11 consists of a hollow cylindrical member inserted and fitted in the through-hole of the center of the 2nd surface 12 of the 2nd dripping part 12, and this 1st dripping part 11 is a container main body. 2 constitutes a nozzle opening through which the liquid stored in 2 can pass and drop. And the front-end | tip part surface of this 1st dripping part 11 is the 1st surface 11a.

Thus, in this embodiment, the 2nd dripping part 12 and the 1st dripping part 11 are united, and the nozzle 10 is comprised.
And the surface of each front-end | tip part of these 1st dripping parts 11 and the 2nd dripping part 12 comprises the 1st surface 11a and the 2nd surface 12a, and the 2nd surface 12a is the 1st surface. By having higher liquid repellency than the surface 11a, the first surface 11a and the second surface 12a have different surface free energies.
Differentiating the surface free energy of the first surface 11a and the second surface 12a (giving liquid repellency) will be described later with reference to FIGS.

A cap 20 described later is detachably attached to the container body 2 including the nozzle 10 (see FIGS. 10 and 11). By providing such a cap 20, the nozzle 10 is covered, the inside of the container body 2 is sealed, and the tip of the nozzle 10 is protected.
Specifically, the surface of the protruding portion of the container body 2 to which the nozzle 10 is mounted is provided with a screw structure that is screwed to the inner surface of the cap 20, and the cap 20 is screwed to the container body 2. The container body 2 is hermetically sealed with the cap 20 attached.
Further, in the present embodiment, as shown in FIG. 1, the side surface portion 12b of the second dripping portion 12 constituting the tip portion of the nozzle 10 is formed in a tapered shape inclined toward the tip portion. The side surface portion 12b of the second dripping portion 12 and the tip (first surface 11a) of the first dripping portion 11 are brought into contact with and pressed against the liner 21 on the inner surface of the cap 20, so that the container body 2 is sealed. It has become so.
Details of the cap 20 will be described later with reference to FIGS.

Here, the container body 2 and the nozzle 10 (first / second dripping portions 11 and 12) are formed of a predetermined plastic material including the cap 20 described later.
The plastic material for forming the container body 2 and the nozzle 10 is not particularly limited, and is similar to known ophthalmic containers and plastic bottles. Various thermoplastic resins, for example, olefin resins such as polyethylene and polypropylene, polyethylene terephthalate, etc. It can form with the polyester resin represented by (PET).
In particular, as to the nozzle 10, as will be described later, since the rough surface 100 made of an uneven surface is formed on the second surface 12a of the tip (see FIGS. 6 to 9), the shape stability and strength of the uneven surface 100 are increased. In view of the above, it is preferable to employ polyolefin resins such as polyethylene and polypropylene which are non-fluorine resins.

Using such a plastic resin material, the container body 2 and the nozzle 10 can be formed using a known technique such as injection molding.
In addition, since the container main body 2 and the nozzle 10 are formed as separate bodies (separate parts), the container main body 2 can also be formed of a non-plastic material such as glass or metal. Further, the container body 2 and the nozzle 10 can be integrally configured by integral molding such as a blow fill seal molding method.
A method for forming the nozzle 10 of the present embodiment will be described later with reference to FIGS.

And the nozzle 10 which concerns on this embodiment has two types (1st surface 11a located in the nozzle center side, and the 2nd surface 12a which follows the outer peripheral side of the 1st surface 11a in the front-end | tip part surface ( The first surface 11a and the second surface 12a have different surface free energies, that is, the second surface 12a has higher liquid repellency than the first surface 11a. It is constituted as follows.
Here, as the liquid repellency, for example, when a target liquid (such as water) is placed on a horizontal mounting surface, a “contact angle” that is an angle formed by a tangent line between the mounting surface and the liquid surface is θ _E. In this case, if θ _E ≧ 90 °, the mounting surface is “high” (low energy surface) for the target liquid, and if θ _E <90 °, the liquid repellency The property is “low” (high energy surface).

In the present embodiment, by using such a liquid repellency standard, the first surface 11a is increased with respect to the two surfaces constituting the tip portion surface of the nozzle 10, the first surface 11a and the second surface 12a. The nozzle 10 is configured such that the energy surface and the second surface 12a are low energy surfaces, and the liquid repellency of the second surface 12a is higher than that of the first surface 11a.
For example, the first surface 11a can be configured to satisfy θ _E <90 ° with respect to the target liquid, and the second surface 12a can be configured to satisfy θ _E ≧ 90 °. .

More specifically, in the present embodiment, the first surface 11a is constituted by, for example, the bulk plastic resin (low liquid repellency) surface as it is, and the second surface 12a is the nozzle 10 The surface of the tip portion can be formed into a surface (high liquid repellency) by surface treatment, for example, fluorination treatment or roughening treatment by a predetermined method.
Normally, the surface of a plastic resin that has not been subjected to any surface treatment is such that the above-mentioned “contact angle” is θ _E <90 ° with respect to a liquid containing a surfactant or oil and fat such as eye drops, and the liquid repellency is “ Low "(high energy with high wettability) surface. On the other hand, by applying surface treatment such as fluorination or roughening to the surface of the resin, the “contact angle” becomes θ _E ≧ 90 ° on the surface of “high” liquid repellency (low energy with low wettability). It can be modified.
As a result, the liquid repellency of the first surface 11a out of the two surfaces constituting the tip surface of the nozzle 10 is “low” (surface free energy is high), and the liquid repellency of the second surface 12a is “ Can be "high" (low surface free energy).

Here, with respect to the second surface 12a having “high” liquid repellency (low surface free energy), for example, the tip surface of the nozzle 10 formed of a plastic molded body made of a non-fluorine resin is plastic molded. It can be fluorinated by incorporating a fluorine atom into the molecular chain of the non-fluorinated resin constituting the body. Furthermore, the second surface 12a of the nozzle 10 thus fluorinated can be roughened as required.
In this way, by fluorinating and roughening the second surface 12a at the tip of the nozzle 10, the liquid repellency is improved as compared with the first surface 11a on the center side of the nozzle 10, whereby the container body When the liquid (eye drops) is dispensed from 2, the liquid droplets can be guided so as to be formed only on the first surface 11 a, and the dispensed liquid gets wet extensively to the second surface 12 a side. It becomes possible to prevent spreading.
Therefore, by adjusting and setting the inner diameter of the opening of the nozzle 10 and the surface area and shape of the first surface 11a, it is possible to set the amount of liquid dropped from the nozzle 10 to an arbitrary and small amount.

FIG. 2 is an explanatory diagram schematically showing the state of liquid droplets on the nozzle depending on whether or not the liquid repellent process is performed, where (a) is a nozzle without liquid repellent process, and (b) is a nozzle with liquid repellent process. Is the case.
First, as shown in FIG. 2A, when the surface of the tip of the nozzle is not subjected to liquid repellency, for example, when the surface of the bulk plastic resin is left as it is, the liquid repellency of the surface is “low”. For this reason, the liquid droplets poured out from the nozzle adhere to the surface of the nozzle tip and spread, and spread in a substantially hemispherical shape. And if the liquid spread at the tip of the nozzle does not detach from the nozzle surface unless it becomes a considerable amount, as a result, a larger amount of droplets than the desired droplet is dropped and the inner diameter of the nozzle expands so that it can be ignored. Depending on the inner diameter of the nozzle, it is difficult to control the droplet amount.

  On the other hand, as shown in FIG. 2B, when the surface of the tip of the nozzle is subjected to liquid repellent processing, for example, when the surface of the plastic resin is fluorinated or roughened, the surface Since the liquid repellency of the liquid is “high”, the liquid droplets dispensed from the nozzle are almost spherical without being wetted and spread on the nozzle tip. Then, at the timing when the weight of the droplet exceeds the adhesion force between the droplet and the tip of the nozzle, the droplet detaches from the nozzle surface and falls and drops. Since the liquid droplets are not wet and spread, the adhesion is small and the amount of liquid droplets to be dropped is small. Also, by setting the inner diameter of the nozzle to a predetermined size, a desired amount of liquid droplets can be dispensed and dropped. be able to.

However, even when the liquid repellency is increased by fluorinating or roughening the surface of the nozzle, there may be variations in the amount of droplets dispensed.
FIG. 3 is an explanatory diagram schematically showing variation in the amount of dripping in a nozzle having a liquid repellent finish on the tip surface.
First, as shown in FIG. 3A, a droplet dropped from a nozzle whose surface of the tip is liquid-repellent is formed into a sphere at the center of the opening at the tip of the nozzle. When it reaches the point, it comes off the tip of the nozzle and drops and drops.

However, when the liquid repellency of the nozzle surface subjected to liquid repellency is uneven, the liquid droplets ejected from the nozzle move to the side with lower liquid repellency, for example, as shown in FIG. In other words, the state is deviated from the center of the nozzle opening. In such a state, since the droplets are larger than in the normal case, the amount of the dropped droplets is also larger than in the original normal case.
Further, when the liquid is poured out from the nozzle, so-called air entrapment, in which bubbles are generated and mixed in the liquid, may occur. When such air is caught, the liquid ejected from the nozzle is separated into a plurality of liquid droplets having different liquid amounts as shown in FIG. 3C, for example. May be dripped separately or integrally, resulting in a dripping amount different from the normal normal case.

On the other hand, when liquid repellent processing is performed on the tip of the nozzle, as shown in FIG. 3D, a protruding portion that protrudes from the tip surface (see FIG. If the circumferential protrusion (burr) 13) shown in d) is present, it is possible to prevent the variation in the amount of dripping as described above.
That is, since there is a protruding portion on the outer periphery of the opening of the nozzle, the liquid droplets poured out of the nozzle do not contact the tip of the nozzle but become a sphere in a state where only the tip of the protruding portion is in contact. For this reason, the liquid droplet is formed and guided at the center of the opening of the nozzle tip, and the liquid droplet is prevented from being poured out to a biased position on the nozzle tip surface. Etc., it is possible to prevent the liquid droplets from being separated and dispensed. For this reason, there is no unevenness or dispersion of droplets as shown in FIGS. 3B and 3C, and it is possible to dispense and drop a desired amount of droplets more reliably and stably. Become.

In the present embodiment, based on such a principle, first, the tip of the nozzle 10 is provided with a predetermined liquid repellent processing / liquid repellency structure on the tip of the nozzle 10 for pouring the liquid from the container body 20. The liquid repellency of the surface is enhanced.
In addition, from the viewpoint of eliminating variations in the amount of dripping due to uneven liquid repellency on the nozzle surface or air entrainment, the liquid repellent bias is positively created so that the liquid droplets are always in the center of the nozzle 10. In order to guide the nozzle to be formed, a surface having lower liquid repellency than the surface of the nozzle subjected to liquid repellency is provided at the center of the nozzle.

That is, the nozzle 10 according to the present embodiment includes a first surface 11a whose tip end surface is located on the nozzle center side, and a second surface 12a continuous with the outer peripheral side of the first surface 11a. The second surface 12a has higher liquid repellency than the first surface 11a.
More specifically, in the present embodiment, as described above, the nozzle 10 is constituted by two members, the first dropping portion 11 and the second dropping portion 12, and the surface of the first dropping portion 11 is formed. The first surface 11a and the surface of the second dripping portion 12 are defined as the second surface 12a, and only the second surface 12a is subjected to a predetermined water-repellent process so that the liquid repellency is higher than that of the first surface 11a. It is supposed to have sex.

Thus, by providing the 2nd surface 12a which improves the liquid repellency of the nozzle 10, and the 1st surface 11a which guides a droplet to the center of the nozzle 10, the internal diameter of the opening of the nozzle 10 or the 1st surface 11a According to the surface area and shape of the liquid, a desired drop amount (for example, 10 μl or less) of liquid can be stably poured out and dropped without causing variations in the drop amount.
Further, the nozzle 10 having the first / second surfaces 11a and 12a as described above is protected by a cap 20 which will be described later, and droplet processing / droplet on the second surface 12a of the nozzle 10 is performed. The structure is not damaged or deteriorated.

[Configuration of nozzle surface]
Hereinafter, a specific surface configuration of the nozzle 10 having the two-stage surface structure including the first surface 11a and the second surface 12a as described above will be described with reference to FIGS.
4 and 5 are explanatory views schematically showing embodiments of the first / second surface of the nozzle tip according to the present invention.
In the present embodiment, first, as a basic configuration, as shown in FIG. 4A, a cylindrical first dropping portion 11 and a second dropping portion 12 arranged on the outer periphery thereof are provided. The tip of the first dropping part 11 (first surface 11a) can be configured to protrude from the tip of the second dropping part 12 (second surface 12a).

If it does in this way, the 1st dripping part 11 (1st surface 11a) will protrude and exist in the opening perimeter of nozzle 10, and the 2nd surface 12a is more water-repellent than the 1st surface 11a. Since the droplets poured out from the nozzle 10 do not come into contact with the second dropping portion 12 (second surface 12a), the surface of the projecting first dropping portion 11 (first surface 11a) does not contact the second dropping portion 12 (second surface 12a). ) Is formed and guided so as to be in contact with only.
As a result, even if there is a variation in liquid repellency on the second surface 12a, it is not affected, and even when air is caught, droplets are separated and dispersed on the second surface 12a side. In addition, the liquid droplets are always guided to be formed at the center of the opening of the nozzle 10, and the liquid can be reliably and stably dispensed and dropped without causing any deviation or dispersion of the liquid droplets.

Moreover, with respect to the basic configuration as described above, for example, as shown in FIG. 4B, the cylindrical portion constituting the first dripping portion 11 (first surface 11a) may be made thicker. it can.
In this way, the area of the first surface 11a having low liquid repellency (high wettability) can be made larger (wider), and the droplet can be guided more reliably to the center of the nozzle. Compared with the case of FIG. 4A, a large droplet can be formed.

In this case, for example, as shown in FIG. 4C, the side surface of the first dropping part 11 protruding from the second dropping part 12 has a predetermined repellency in the same manner as the second surface 12a. Liquid processing can also be performed.
In this case, the liquid droplets are also repelled from the side surface of the first dropping part 11 from which the liquid droplets protrude, so that the liquid droplets can be more reliably transferred to the second surface as compared with the case of FIG. It can be formed by guiding it to the center of the nozzle away from the liquid 12a.

Further, as shown in FIG. 4 (d), the first dripping part 11 does not protrude from the tip (second surface 12a) of the second dripping part 12, and the first surface 11a It can also be configured such that the surface 12a is substantially “same”.
Also in this case, the liquid drops are dropped into the second dripping portion 12 (second energy level) by the high liquid repellency (low energy surface) of the second surface 12a and the high wettability (high energy surface) of the first surface 11a. Without being moved to the surface 12a) side, it can be formed and guided in a state of contacting only the surface portion (first surface 11a) of the first dropping portion 11.
Further, in this case, since the first dripping portion 11 does not protrude, the sphere of the droplet is prevented from spreading greatly, and the liquid volume is smaller and smaller than in the case of FIG. Liquid droplets.

4A and 4B, the surface portion (first surface 11a) of the first dropping portion 11 has a rectangular cross-sectional shape in a cross section including the nozzle center line. However, as shown in FIG. 4E, for example, the first surface 11a is tapered so as to reduce in the dropping direction by tapering the tip of the first dropping portion 11 into a tapered shape. be able to.
If it does in this way, the area of the 1st surface 11a comprised by the front end surface of the 1st dripping part 11 can be made small compared with the case of Fig.4 (a) and (b), and 1st By reducing the adhesion between the surface 11a and the droplet, the formed droplet can be formed with a smaller sphere and a smaller amount of liquid.

Moreover, the area of the 1st surface 11a comprised by the front end surface of the 1st dripping part 11 can also be formed larger than the case shown to Fig.4 (a)-(e).
For example, as shown in FIG. 4 (f), the tip of the first dripping portion 11 is formed so as to spread in a trumpet shape, and the first surface 11a is tapered so as to expand in the dripping direction. One surface 11a can be made larger and wider.
If it does in this way, the area of the 1st surface 11a comprised by the front end surface of the 1st dripping part 11 can be enlarged compared with the case of Fig.4 (a)-(e), By increasing the adhesion between one surface 11a and the liquid droplet, it becomes possible to hold a larger liquid volume and a larger spherical liquid droplet, and it is possible to form a larger liquid droplet with a larger liquid volume. .

Further, the first / second surfaces 11a and 12a as described above may be formed by, for example, FIG. As shown in FIG. 5, the first surface 11a protruding into the nozzle can be formed together with the second surface 12a at the tip of the second dropping portion 12.
The first surface 11a protruding integrally from the tip opening of the second dropping portion 12 is naturally formed when an opening (through hole) is formed in the second dropping portion 12 with a drill or the like, for example. Can be formed by injection molding or can be formed by “burr”.

In this case, after the first surface 11a is protruded from the tip of the second dripping portion 12, the first surface 11a is covered and protected, and the second dripping portion 12 A fluorination / roughening process, which will be described later, is applied to the tip portion to form the second surface 12a.
In this way, the first surface 11a is not limited to the case where the first surface 11a is formed to protrude from the tip end portion of the second dropping portion 12, but similarly to the case shown in FIG. 4D. However, a configuration in which the first and second surfaces 12a are integrally formed on the second dripping portion 12 can also be configured.
As described above, the first / second surfaces 11a and 12a can be integrally formed of the same parts, so that the number of parts can be reduced and the manufacturing process can be simplified.

Furthermore, when the 1st dripping part 11 and the 2nd dripping part 12 are comprised by a separate part, the 1st dripping part 11 is a tubular body as shown to Fig.4 (a)-(g). In addition to the case of being configured by a cylindrical body, for example, as shown in FIG. 4 (h), a means capable of dropping liquid by a capillary phenomenon such as a fiber member or a nonwoven fabric may be configured as the first dropping unit 11. Is possible.
Thus, the 1st dripping part 11 which constitutes nozzle 10 concerning this embodiment is especially limited to a cylindrical body and a tubular body, as long as the liquid in container body 2 can be dripped only a predetermined amount from the nozzle tip. It is not a thing.

Further, as shown in FIG. 5 (a), the first dripping portion 11 is not projected from the tip (second surface 12a) of the second dripping portion 12, and the first surface 11a is It can also be configured to have a “chamfered” shape recessed in a tapered shape inside the second surface 12a. This can be formed, for example, by inserting the first dripping portion 11 whose end inner surface is chamfered into a taper shape into the second dripping portion 12 having the second surface 12a.
Even in this case, the droplets dispensed from the nozzle 10 do not contact the second dripping portion 12 (second surface 12a), and the surface of the first dripping portion 11 that is recessed in a tapered shape. Only the (first surface 11a) is brought into contact, and the liquid droplets can be guided to the center of the opening of the nozzle 10 to perform reliable and stable dispensing / dropping.

Further, when the first surface 11a is chamfered so as to be recessed inside the second surface 12a in this way, as shown in FIG. 5B, the chamfered first surface 11a is formed. Can be formed integrally with the second surface 12 a at the tip of the second dripping portion 12.
If it does in this way, the 1st / 2nd surface 11a, 12a can be comprised only with the 2nd dripping part 12, and reduction of a number of parts, simplification of a manufacturing process, etc. can be aimed at. In particular, the insertion process of the first dripping part 11 and the alignment work of the first / second surfaces 11a and 12a are not necessary, and the second dripping part 12 in which the second surface 12a is formed in advance, Since the first surface 11a can be formed simply by chamfering the inner surface of the end of the opening into a tapered shape, the work process can be greatly simplified and facilitated.

[Operation principle of liquid repellent structure]
Next, referring to FIGS. 6 to 7 for the liquid repellency structure by fluorination / roughening provided on the second surface 12a of the tip portion of the nozzle 10 according to the present embodiment as described above and its operation principle. I will explain.
In addition, as shown below, it is preferable that the second surface 12a of the nozzle 10 is fluorinated and the surface thereof is roughened in order to improve liquid repellency.
However, as long as the second surface 12a of the nozzle 10 is at least fluorinated, the nozzle 10 made of a non-fluorine resin can be provided with liquid repellency. Further, as will be described later, the plasma treatment for fluorinating the tip surface (see FIG. 15) has a very strong attack, and the plasma treatment causes fine irregularities on the surface of the tip of the nozzle 10. Formed and roughened.
Therefore, the second surface 12a of the nozzle 10 according to the present embodiment only needs to be at least fluorinated, and may be any surface that further roughens the second surface 12a as necessary.

Here, in order to improve the liquid repellency with respect to the liquid, it is generally considered to use a fluorine-containing resin such as polytetrafluoroethylene (PTFE) as the plastic. However, the contact angle of PTFE with water is about 115 ° at most, and liquid repellency is not exhibited with respect to a liquid containing a substance having a low surface tension such as alcohol or oil. In addition, since the fluorine-containing resin is very expensive and difficult to mold, there is a problem that its use and the like are very limited.
For this reason, it becomes a subject to improve liquid repellency about the plastic molded object formed using non-fluorine-type resin which does not contain fluorine, such as polyolefin and polyester.

Further, as means for enhancing the liquid repellency of the liquid, a means for providing a liquid repellent film on the surface of a nozzle or the like, and a means for forming irregularities are conceivable.
For example, the liquid repellency can be improved by providing a liquid repellent thin film (for example, a film containing a compound or resin containing fluorine or silicon) on the surface. However, in such a method, the adhesion with the base material tends to be insufficient, and when repeated dripping, the liquid-repellent thin film is peeled off and dropped, and the liquid repellency is lost. There is a risk of contamination in the internal solution.

On the other hand, the means of providing irregularities on the surface of the nozzle or the like is to physically impart liquid repellency depending on the surface shape, and the above-described problems due to the thin film and the like do not occur.
That is, when liquid flows on the uneven surface formed on the surface of the nozzle or the like, an air pocket is formed in the recess, and the contact state between the uneven surface and the liquid becomes a mixed contact state consisting of solid-liquid contact and gas-liquid contact, Moreover, gas (air) is the most hydrophobic substance. For this reason, remarkably high liquid repellency can be expressed by appropriately setting the unevenness of the unevenness.
However, it is necessary to consider that when the liquid repeatedly flows on the uneven surface, the liquid gradually accumulates in the recess, the function of the air pocket is gradually lost, and the liquid repellency gradually decreases. is there.

Therefore, in the present embodiment, first, fluorine atoms are incorporated into the molecular chain of the non-fluorinated resin of the plastic molded body constituting the second surface 12a (second dripping portion 12) of the tip portion of the nozzle 10. Like that.
Further, the second surface 12a of the tip portion of the nozzle 10 thus fluorinated is roughened so that an uneven portion is further formed.
In addition, the first surface 11a having a lower liquid repellency than the second surface 12a is disposed at the center of the roughened nozzle surface. A tubular / cylindrical first dropping portion 11 that is not subjected to water repellent processing or the like is inserted and fitted into the central opening of the second dropping portion 12.

In FIG. 6, the form of the rough surface formed in the surface (2nd surface 12a) of a front-end | tip part in the plastic molding (2nd dripping part 12) which comprises the nozzle 10 which concerns on this embodiment is shown.
In the figure, the surface of the tip is made of a non-fluorine resin, and a rough surface 100 made of fine irregularities is formed on this surface (in FIG. The top of the convex portion in the surface 100 is indicated by S).
In the molecular chain of the non-fluorine resin forming the rough surface 100, fluorine atoms are incorporated by post-processing. For example, when the molecular chain of a non-fluorinated resin is represented by — (CH ₂ ) n—, a fluorine atom is incorporated into a part of the molecular chain, and a fluorine-containing moiety such as —CHF— or —CF ₂ — is present. Has been generated. Post-processing for incorporating such fluorine atoms can be performed by fluorine plasma etching described later (see FIG. 15).

The liquid repellency of the liquid on the rough surface 100 will be described with reference to FIG.
As shown in FIG. 7A, the contact pattern of the droplets on the rough surface 100 as described above is such that in the Cassie mode in which the droplets are placed on the rough surface 100, the recesses in the rough surface 100 are air pockets. Thus, the liquid droplet is in a combined contact state between the solid and the gas (air). In such a composite contact, the contact radius R at the contact interface of the droplet is small, the adhesion between the droplet and the rough surface is low, and the liquid comes into contact with the air having the highest lyophobic property. To express. The contact angle of the rough surface 100 in such a Cassie mode is as shown in the following theoretical formula (1).
_{^{cosθ * = (1-φ S}} ) cosπ + φ S cosθ E
_{= Φ S -1 + φ S cosθ} E (1)
θ _E : contact angle θ ^* : apparent contact angle φ _S : area ratio (projected area of solid-liquid interface per unit area)
As can be understood from the theoretical formula (1), the smaller the φ _S , the closer the apparent contact angle θ ^* approaches 180 degrees and the super liquid repellency is exhibited.

On the other hand, when the liquid droplet enters the concave portion in the rough surface 100, the liquid droplet is not in contact with the composite as described above, but in contact with only the solid, and is shown in the Wenzel mode. In such a Wenzel mode, the contact radius R at the contact interface of the droplet is large, and the adhesion between the droplet and the rough surface is high. The contact angle of the uneven surface is as shown in the following theoretical formula (2).
cosθ ^* = rcosθ _E (2)
θ _E : Contact angle θ ^* : Apparent contact angle r: Concavity and convexity (= actual contact area / droplet projection area)
As understood from the theoretical formula (2), as r is larger, the apparent contact angle θ ^* approaches 180 degrees and exhibits super-liquid repellency.

Here, with respect to the liquid repellency, as described above, it is known that the liquid repellency is improved in both the Wenzel mode and the Cassie mode, but the adhesion between the rough surface 100 and the droplet is reduced. In order to drop a small amount of liquid droplets, it is considered necessary to stably maintain the Cassie mode, not the Wenzel mode, that is, stably maintain the air pockets of the recesses.
That is, in the Wenzel mode, the interface between the liquid phase and the solid phase is large, and as a result, the physical adsorption force acting on the interface also increases. It will not fall.
On the other hand, in the Cassie mode, since the interface is small, the adhesion force that must be overcome when droplets are dropped is low, and the droplets are easily dropped and tumbled.

Therefore, in the present embodiment, in order to effectively maintain the contact of the droplets in the above Cassie mode, fluorine is contained in the molecular chain of the non-fluorine resin forming the rough surface 100 at the tip of the nozzle 10. By incorporating atoms, liquid repellency is imparted chemically.
That is, if the liquid enters the concave portion in the rough surface 100, the contact pattern of the droplet becomes the Wenzel mode, and as a result, the super-liquid repellency by the Cassie mode is impaired. Then, by incorporating fluorine atoms into the molecular chain of the non-fluorine resin that forms the rough surface 100, the liquid repellency can be imparted chemically to the rough surface 100, whereby the liquid into the recesses can be provided. Is effectively suppressed, and the super-liquid repellency by the Cassie mode is stably maintained.

In particular, in this embodiment, at least a part of the rough surface 100, for example, at the top of the convex portion or the bottom of the concave portion, chemical liquid repellency is expressed in the molecular chain of the non-fluorine resin forming this surface. The fluorine atom is incorporated. Therefore, even when the liquid repeatedly contacts the rough surface 100, the fluorine atoms are not removed and the chemical liquid repellency is stably maintained. As a result, the super liquid repellency by the Cassie mode is maintained. Without being lowered, the high level is maintained as in the initial stage.
Furthermore, since a fluorine atom is incorporated in the molecular chain of the non-fluorine resin on the surface instead of forming a film containing fluorine atoms, there is no problem of peeling or dropping off of the fluorine film.

Here, the degree of unevenness of the rough surface 100 as described above is represented by the area of the convex portion top S per unit area in the rough surface 100 so that the liquid repellency by the Cassie mode is sufficiently exhibited. It is preferable that the area ratio φs is 0.05 or more, preferably 0.08 or more.
Furthermore, from the viewpoint of moldability and mechanical strength, the area ratio Φ is preferably in the range of 0.8 or less, particularly 0.5 or less.
The depth d in the rough surface 100 is preferably in the range of 5 to 200 μm, particularly 10 to 50 μm.

Further, the rough surface 100 may have a concavo-convex structure as shown in FIG.
That is, a droplet having a surface tension of γ and an initial contact angle of θ has a Laplace represented by a concavo-convex tip angle α and a concavo-convex ½ pitch R ₀ as shown in the following formula (3). Supported by pressure (Δp), it forms an air pocket. That is, when the concave / convex tip angle α becomes small, the 1/2 pitch R ₀ becomes small, and the concave / convex structure becomes a sword-like shape, the Laplace pressure increases, so that the liquid droplet does not easily enter the concave / convex portion and exhibits liquid repellency Is done.
Therefore, as shown in FIG. 8, when the arithmetic average roughness Ra representing the amplitude of the concavo-convex structure is larger and the average length RSm corresponding to the 1/2 pitch R ₀ is smaller, the Laplace pressure is larger and the liquid repellency is exhibited. Ra / RSm is preferably 50 × 10 ⁻³ or more. In particular, it is preferably 200 × 10 ⁻³ or more.
Δp = −γcos (θ−α) / (R ₀ + hcosα) (3)

In the present embodiment, the rough surface 100 composed of the fine irregularities as described above can generally be easily formed by a transfer method using a metal stamper. For example, by heating a stamper having a rough surface portion corresponding to the fine unevenness described above by a resist method or the like to an appropriate temperature, and pressing the stamper against a predetermined portion of the surface of the plastic molded body, the rough surface portion is transferred. Such a rough surface 100 can be formed on the surface of the tip of the nozzle 10 made of a plastic molded body. Therefore, the uneven surface of the stamper is formed on the surface of the tip portion of the nozzle 10 with the unevenness reversed.
Moreover, the roughening process by such a stamper can simultaneously form a later-described meat reservoir 15 on the outer edge of the tip of the nozzle 10 (see FIGS. 16 to 19).
In this embodiment, the rough surface formed at the tip of the nozzle 10 is not limited to the uneven shape of the rough surface 100 shown in FIGS. 6 and 8, but from the viewpoint of stably forming the air pocket. The convex portions and concave portions as shown in FIG. 6 are preferably formed in a rectangular shape. For example, if the concave portion is shaped like a V shape, the droplets easily enter the concave portion.

Further, the incorporation of the non-fluorinated resin forming the surface of the nozzle 10 into the molecular chain can be performed by etching using fluorine plasma.
Here, the fluorine plasma etching can be performed using a known method (see FIG. 15 described later). For example, by using CF ₄ gas, SiF ₄ gas, or the like, the surface of the plastic molded body forming the rough surface 100 is disposed between a pair of electrodes, and a high-frequency electric field is applied, thereby generating a plasma of atomic fluorine (atomic Fluorine) is generated and collided with the portion forming the rough surface 100, whereby fluorine atoms are incorporated into the molecular chain of the non-fluororesin forming the surface (rough surface 100). That is, the resin on the surface is vaporized or decomposed, and at the same time, fluorine atoms are incorporated.
Accordingly, ultra fine irregularities are formed by etching in the region where fluorine atoms are incorporated. The arithmetic average roughness Ra of the ultra-fine irregularities is generally 100 nm or less, and Ra / RSm ≧ 5 × 10 ⁻³ .

Further, conditions such as a high frequency voltage to be applied and an etching time can be set in an appropriate range according to the roughness (area ratio φs) of the rough surface 100.
For example, in the drop endurance test, when the drop amount is measured after dropping the droplet (eye drops) 100 times repeatedly to contaminate the nozzle tip, the performance of the drop amount ≦ 10 μL may be shown, Such conditions may be set by a laboratory test or the like in advance.
Although it depends on the roughness of the rough surface 100, generally, when the element ratio (F / C) of fluorine atoms to carbon per unit area is 40% or more, particularly 50 to 300%, the surface strength is impaired. In addition, it is possible to ensure the stable super liquid repellency as described above. The element ratio can be calculated by analyzing the surface elemental composition using an X-ray photoelectron spectrometer.

Further, in the present embodiment, the rough surface 100 formed at the tip of the nozzle 10 is not limited to the form shown in FIG. 6 and FIG. 8 described above. For example, the rough surface 100 shown in FIG. The rough surface 100 can also be formed by a hierarchical structure.
Specifically, as shown in FIG. 9, fine secondary irregularities can be formed on the primary irregularities 160 formed by relatively large convex portions 160a and concave portions 160b. In this way, since the droplet 170 is placed on the secondary unevenness, an air pocket (secondary air pocket) is also formed between the droplet 170 and the secondary unevenness. A secondary air pocket between the droplet 170 and the secondary unevenness prevents the droplet 170 from entering the recess 160 b of the primary unevenness 160, and is formed between the primary unevenness 160 and the droplet 170. The loss of air pockets can be more effectively prevented. As a result, the state in the Cassie mode is held more stably, and the liquid repellency can be maintained more stably.

In the rough surface 100 having the hierarchical structure as described above, the secondary unevenness on the surface portion of the primary unevenness 160 prevents the droplets on the secondary unevenness from penetrating into the recessed portion 160b of the primary unevenness 160. It is only necessary to have a surface roughness large enough to form such secondary air pockets. For example, the ratio of arithmetic average roughness to average length, Ra / RSm should be 50 × 10 ⁻³ or more. Particularly, it is particularly preferable that it is 200 × 10 ⁻³ or more.
Further, the primary unevenness 160 only needs to have the same area ratio Φ and unevenness depth d as those of the rough surface 100 in the form shown in FIG. 6, so that the liquid repellency by Cassie mode is sufficient. Demonstrated.

In addition, the secondary unevenness is optimally formed on the entire surface of the primary unevenness 160 in terms of more effectively preventing the droplet 170 from entering the recess 160b of the primary unevenness 160. It may be formed at least on the upper end of the convex portion 160a of the primary unevenness 160.
The rough surface 100 having the hierarchical structure as described above is formed by forming a fine secondary uneven surface on the uneven surface of a stamper for forming primary unevenness by, for example, blasting, etching, etc., and using such a stamper. It can be formed by all transfer.

Further, in the present embodiment, at least a part on the primary unevenness 160 where the secondary unevenness is formed as described above, in particular, a portion that becomes the top portion of the convex portion 160a of the primary unevenness 160 and a portion that becomes the bottom portion of the concave portion 160b. Fluorine plasma etching causes fluorine atoms to be incorporated into the molecular chain of the non-fluorine resin forming the surface. In such regions, secondary unevenness is caused by etching when fluorine atoms are incorporated. Thus, finer tertiary irregularities are formed. The arithmetic average roughness Ra of the tertiary irregularities is generally 100 nm or less, and Ra / RSm ≧ 5 × 10 ⁻³ , similar to the ultrafine irregularities formed by the etching described above.

In addition, the nozzle 10 according to the present embodiment is formed using a non-fluorine-based resin. As such a non-fluorine-based resin, that is, a resin not containing fluorine, a rough surface including the above-described unevenness is used. As long as 100 can be formed and fluorine atoms can be incorporated into the molecular chain by fluorine plasma etching, any thermoplastic resin, thermosetting resin, photocurable resin, etc. can be used. An appropriate resin may be selected in accordance with the molding conditions and the like, and a multi-layer structure may be used.
In general, in the field of liquid containers, polyesters such as polyethylene, polypropylene, olefin-based resins represented by copolymers of ethylene or propylene and other olefins, polyethylene terephthalate (PET), polyethylene isophthalate, polyethylene naphthalate, etc. It is representative as a resin for surface formation.

  And, the nozzle 10 according to the present embodiment as described above can be applied as nozzles and dispensing means for various containers by taking advantage of the long life and excellent liquid repellency of the rough surface 100. In particular, the liquid dropability and liquid breakage are improved, and dripping and remaining liquid on the top of the nozzle are also suppressed. Therefore, like the eye drop container 1 for containers / packaging bodies containing various chemicals Can be used as effectively.

[cap]
The container body 2 including the nozzle 10 to be liquid-repellent processed as described above is detachably mounted with a cap 20. The nozzle 20 is covered by the cap 20, and the inside of the container body 2 is covered. While being sealed, the tip of the nozzle 10 is protected.
10A and 10B are diagrams showing a cap 20 that covers the nozzle 10 according to the present embodiment, in which FIG. 10A is a cross-sectional view of the main part of an eye drop container equipped with the cap, and FIG. 10B is a nozzle of the cap shown in FIG. It is an expanded sectional view of a tip part.
Moreover, FIG. 11 is a figure which shows the other form of the cap 20 which concerns on this embodiment, (a) is principal part sectional drawing of the eye drop container which removed the cap, (b) is for eye drops which attached the cap. Sectional drawing of the principal part of a container, (c) is an expanded sectional view of the nozzle front-end | tip part of the cap shown to (b).
Furthermore, FIG. 12 is also a figure which shows the other form of the cap 20 which concerns on this embodiment, (a) is principal part sectional drawing of the container for eye drops which attached the cap, (b) is a cap shown to (a). It is an expanded sectional view of the nozzle front-end | tip part.

As shown in these drawings, the cap 20 is configured by a bottomed cylindrical body that can be mounted so as to cover the protruding portion of the container body 2 including the nozzle 10. 10 is provided with a sealing liner 21 that comes into contact with the front end surface (first surface 11 a) of the first dripping portion 11 and the side surface portion of the second dripping portion 12. The liner 21 is brought into contact with and pressed against the front end surface of the first dropping portion 11 of the nozzle 10 and the side surface portion 12b of the second dropping portion 12, so that the nozzle 10 and the container body 2 are shielded and sealed from the outside. The liquid (eye drops) stored in the container body 2 is prevented from leaking.
Further, the inner side surface of the cap 20 is provided with a screw structure that is screwed together with the surface of the protruding portion of the container body 2 to which the nozzle 10 is mounted. Accordingly, the cap 20 is detachably attached to the container body 2 by screwing. When the cap 20 is attached, the tip surface of the first dropping portion 11 of the nozzle 10 and the side surface portion of the second dropping portion 12 are attached. The liner 21 comes into close contact with 12b, and the inside of the container is sealed.

Here, the cap 20 is formed of a plastic material similarly to the container body 2 and the nozzle 10. The plastic material for forming the cap 20 is not particularly limited, and as with the container body 2 and the nozzle 10 described above, various thermoplastic resins, for example, olefin resins such as polyethylene and polypropylene, and polyethylene terephthalate (PET). It can be formed with a representative polyester resin.
The liner 21 provided on the inner surface of the cap 20 can be formed of a known elastic material, for example, a thermoplastic elastomer such as an ethylene-propylene copolymer elastomer or a styrene elastomer.
Furthermore, the cap 20 can be made of, for example, a glass or metal cap in addition to the plastic material. Further, the cap 20 may be integrally formed with the container body 2 via a hinge or the like.

And the cap 20 which concerns on this embodiment is comprised so that the protrusion part of the container main body 2 containing the nozzle 10 may be covered, without contacting the front end surface (2nd surface 12a) of the 2nd dripping part of the nozzle 10. FIG. Has been.
As a result, the cap 10 can be protected by the cap 20 without contacting the cap 20 with the second surface 12a of the nozzle 10 to be fluorinated and roughened as described above. The liquid repellency and the liquid repellency structure of the surface 12a are not impaired.

Specifically, as shown in FIG. 1, the nozzle 10 according to the present embodiment has a second dripping portion 12, a side surface portion 12 b that is continuous with the second surface 12 a of the tip portion, toward the tip portion. It is formed in the taper shape which inclines so that it may taper off.
And the liner 21 with which the inner surface of the cap 20 is equipped is formed in the mortar shape corresponding to the taper shape of the side part 12b of the nozzle 10, as shown in FIG. With such a configuration, in the cap 20, the liner 21 comes into contact with the side surface portion 12 b of the nozzle 10, and no part of the cap 20 comes into contact with the tip portion.
As a result, the cap 20 can seal the container body 2 by the liner 21 coming into contact with and pressed against the side surface portion 12b of the nozzle 10, and the liquid-repellent structure itself at the tip of the nozzle 10 contacts any portion. Will be protected without.

Here, in the cap 20 shown in FIG. 10, the nozzle 21 is attached to the container body 2 and the liner 21 is in contact with the tip surface (first surface 11 a) of the first dripping portion 11 of the nozzle 10. The opening (first dripping portion 11) is sealed and sealed in a state where it is in communication with the container body 2. In this state, the opening is sealed by the liner 21, and liquid does not leak out of the cap 20 from the opening.
However, in this case, since the pressure loss increases when the inner diameter of the opening is reduced, the liquid cannot ooze from the opening to the inner surface of the liner 21 of the cap 20 at the discharge pressure due to its own weight. However, when the container 1 is crushed by some external force and the internal pressure increases, the content liquid may ooze out.
In that case, there is a possibility that the liquid that has exuded to the tip of the nozzle 10 may adhere to the first / second surfaces 11a, 12a. Can be considered.

Therefore, the cap 20 can be configured to prevent the liquid from oozing out from the nozzle opening.
For example, as shown in FIG. 11, the liner 21 disposed on the inner surface of the cap 20 presses the side surface portion 12 b of the second dripping portion 12 continuous from the tip portion of the nozzle 10, thereby opening the opening of the nozzle 10. It can be configured to close the tip.

Specifically, in the cap 20 shown in FIG. 11, the liner 21 in contact with the side surface portion 12 b of the second dripping portion 12 of the nozzle 10 is tighter than the tapered shape of the side surface portion 12 b of the second dripping portion 12. It is formed in an inclined mortar shape, and the side surface portion 12b of the second dripping portion 12 in contact with the liner 21 is pressed toward the center of the nozzle. As a result, the nozzle 10 bends into the nozzle due to the elasticity of the plastic molded body, and the opening (first dripping portion 11) is closed and closed.
As a result, when the cap 20 is attached, the opening of the nozzle 10 is closed, so that the liquid in the container body 2 does not ooze out from the opening, and the above-described problems are solved. . The cap 20 may be engaged and connected so as not to be detached from the container body 2 via a hinge or the like.

Further, the cap 20 shown in FIG. 12 has a nozzle 10 in which the first surface 11a shown in FIGS. 5 (a) and 5 (b) is chamfered so as to be recessed inside the second surface 12a. On the other hand, a needle valve 22 that abuts and fits into a tapered chamfered recess is provided, whereby the opening of the nozzle 10 is closed.
Even with such a configuration, the container body 2 can be reliably sealed and closed by the needle valve 22 that fits into the tapered chamfered recess without touching the liquid repellent tip surface of the nozzle 10. .

[Nozzle manufacturing method]
Next, a manufacturing method of the nozzle 10 according to this embodiment in which the second surface 12a of the tip portion is fluorinated and roughened as described above will be described with reference to FIGS.
FIG. 13 is an explanatory view schematically showing a method for manufacturing the nozzle 10 according to the present embodiment, where (a) is a general injection molding, and (b) is an injection compression molding or a heat and cool injection. The case where molding is used is shown.
FIG. 14 shows a case where the chamfered first surface 11a is formed at the tip end opening of the second dropping portion 12 without using the first dropping portion 11 in the manufacturing method shown in FIG. ing.
FIG. 15 schematically shows a fluorine plasma etching method for forming a rough surface at the tip of the nozzle 10 according to this embodiment.

In the nozzle 10 according to the present embodiment, when the nozzle body 10 is configured, the second dripping portion 12 and the first dripping portion 11 inserted and fitted at the tip of the second dripping portion 12 are configured separately. Both are manufactured separately.
As shown to Fig.13 (a), the 2nd dripping part 12 which comprises a nozzle body is the 2nd dripping part 12 by which the front-end | tip part surface is not fluorinated and roughened first, for example using injection molding. Can be formed.
In this case, as shown in (1) of FIG. 13 (a), the second dripping portion is obtained by filling, solidifying, demolding and taking out a predetermined molten plastic resin using an injection mold. 12 can be formed.

Here, according to the size and shape of the mold, the nozzle 10 can be formed in a predetermined shape and size, and the first dropping portion 11 that becomes the final opening of the nozzle 10 can be inserted and fitted. The inner diameter, specifically, the outer diameter of the first dripping portion 11 can be formed to be approximately the same or slightly larger.
Although not particularly illustrated, the first dropping unit 11 is also manufactured in a predetermined shape and size using, for example, injection molding, as in the manufacturing of the second dropping unit 12.
Since the opening (inner diameter) of the first dripping portion 11 is the final opening of the nozzle 10, an inner diameter of a desired size, for example, 0.5 mm or less (0.1 mm), depending on the size and shape of the mold. , 0.2 mm, 0.4 mm, etc.).

Thereafter, as shown in (2) of FIG. 13 (a), a predetermined stamper is pressed against the surface of the tip of the second dripping portion 12 to form predetermined irregularities, and the second liquid having high liquid repellency. The surface 12a (low energy surface) can be formed.
Further, as shown in (3) of FIG. 13A, fluorine plasma etching is performed on the second surface 12a.
Here, in the fluorine plasma etching shown in (3) of FIG. 13A, for example, as shown in FIG. 15, one electrode 200 is fixed in the vicinity of the distal end portion of the second dropping portion 12, and the surface of the distal end portion is obtained. The other electrode 201 can be opposed so that the (second surface 12a) is positioned between them, and a high frequency electric field can be applied while flowing a fluorine-containing gas between the electrodes.

As described above, the rough surface 100 as shown in FIGS. 6 to 9 described above can be formed, and the distal end portion (second surface 12a) of the second dripping portion 12 serving as the main body of the nozzle 10 is fluorinated. It can be roughened.
Thereafter, as shown in (4) of FIG. 13 (a), the first dripping manufactured in a separate process is made in the through hole at the center of the tip of the second dripping section 12 that has been fluorinated and roughened. The part 11 can be inserted and fitted.
Thereby, the nozzle 10 is completed.

In addition, the second drop having a predetermined unevenness on the tip surface by using special injection compression molding or heat & cool type injection molding instead of the general injection molding as shown in FIG. The part 12 can be formed by integral molding.
By using a special injection compression molding or heat and cool injection molding technology, it becomes possible to apply fine irregularities and rough surfaces to the desired part of the molded product in the molding process. As shown in 1), the forming step of the second dripping portion 12 and the surface roughening step of the tip portion (forming step of the second surface 12a) can be processed as one step, One process can be omitted. That is, as shown in (2) of FIG. 13 (b), the concavo-convex processing / roughening process using the stamper shown in (2) of FIG. 13 (a) can be omitted.
Thereafter, as shown in (3) and (4) of FIG. 13B, the nozzle 10 is subjected to fluorination / roughening treatment by fluorine plasma etching on the surface of the tip (see FIG. 15). The nozzle 10 is completed by inserting and fitting the first dropping part 11 manufactured in a separate process into the second dropping part 12.

Further, as shown in FIG. 14, when the chamfered first surface 11a is formed at the tip end opening of the second dripping portion 12 without using the first dripping portion 11, (1 of FIG. ), By using an injection mold corresponding to the outer diameter of the chamfered concave portion, the second dropping portion 12 having a tapered concave portion at the opening end can be formed. (See (2) in FIG. 14).
Thereafter, as shown in FIGS. 14 (3) and 14 (4), the unevenness processing / roughening process using a stamper or the like and the fluorination / roughening process by fluorine plasma etching are performed to complete the nozzle 10. .
In the roughening / fluorination treatment, the taper-shaped chamfered concave portion formed by molding is masked to prevent roughening / fluorination. In addition, the first surface of the nozzle 10 is first roughened and fluorinated to form the second surface 12a, and then the opening inner surface of the second surface 12a is chamfered to make the tapered first It is also possible to form the surface 11a. In this case, the above-described masking process is not necessary.

[Meat reservoir]
As described above, the reservoir 10 can be further provided for the nozzle 10 whose tip is liquid-repellent.
FIG. 16 is a partial cross-sectional view of the nozzle when the meat reservoir 15 is provided at the outer edge of the tip of the nozzle 10 according to the present embodiment. FIG. 16A is a top view of the nozzle tip at the shape of the meat reservoir 15. (B) is the case where the shape of the meat reservoir 15 is slanted with respect to the top surface of the nozzle tip, and (c) is not provided with the meat reservoir 15. Each nozzle is shown.

  As shown in FIGS. 16A and 16B, the meat pool portion 15 is a protruding portion that protrudes outward from the outer peripheral edge of the tip portion of the nozzle 10. By providing such a meat reservoir portion 15, the liquid breakage of the liquid turned to the outer peripheral edge side of the tip portion, that is, the separation property between the liquid droplet falling from the outer edge of the nozzle 10 and the liquid remaining on the nozzle 10 side is improved. Can be made. This prevents the liquid from dripping down to the side surface continuous to the tip of the nozzle 10, and combined with the high liquid repellency of the tip, the dripping of liquid droplets poured out from the opening of the nozzle 10. Generation | occurrence | production can be suppressed thru | or prevented.

Hereinafter, the mechanism of the liquid running out performance of the meat reservoir 15 will be described with reference to FIGS.
FIG. 17 is a cross-sectional view of the main part of the nozzle for explaining the liquid drainage performance when the slant-shaped reservoir 15 is provided at the outer edge of the tip of the nozzle 10, and FIG. 18 is the tip of the nozzle 10. It is principal part sectional drawing of the nozzle for demonstrating the liquid running-out performance at the time of providing the overhang-shaped meat reservoir part 15 in the outer edge of this.

In the meat reservoir 15 shown in these drawings, the tip portion (top surface) of the nozzle 10 is hot-pressed, for example, so that the resin on the surface layer of the tip portion melts, and a part of the melted resin is part of the tip portion. It is formed by extruding radially outward from the outer peripheral edge and solidifying as it is.
In addition, the shape of the meat reservoir 15 is, for example, a shape in which the tip protrudes acutely as shown in FIG. 17 (slant shape), or a shape in which the tip protrudes in a droplet shape as shown in FIG. (Overhang shape).
By providing such a meat reservoir 15, it is possible to improve the drainage of the content liquid poured out from the opening at the outer edge of the nozzle 10, and to prevent the content liquid from leaking from the outer edge of the nozzle 10 to the side surface side. It can be effectively suppressed. The mechanism will be described below.

[Slant mode]
First, as shown in FIG. 17, when the meat reservoir 15 is projected at an acute angle (slant mode) substantially flush with the top surface (surface of the tip) of the nozzle 10, the liquid traveling at the contact angle θ _E When the outer edge (edge portion) of the tip portion is reached (see FIG. 17A), when the angle formed by the liquid traveling surface (top surface of the tip portion) and the outer surface of the edge portion is α, it moves forward. The liquid stays at the edge portion until the angle (critical contact angle of the edge portion) θ ^* becomes θ ^* = θ _E + (π−α) (see FIG. 17B).
This is a phenomenon known as a pinning effect in the relationship between the surface tension of the liquid and the contact angle. As shown in FIG. 17, the meat reservoir 15 has a tip protruding at an acute angle (α <90 °). Is formed (slant mode), the advance angle is increased by the pinning effect, and the content liquid is liable to stay in the meat accumulation portion 15 by the surface tension.

Thereby, it is possible to improve the liquid breakage of the liquid that has turned to the outer edge side of the nozzle tip, that is, the separation between the liquid droplet falling from the outer edge of the nozzle 10 and the liquid remaining on the top surface side of the nozzle 10, As a result, the liquid poured out from the nozzle 10 can be prevented from dripping to the nozzle side surface side.
In the example shown in FIG. 17, the upper surface of the meat reservoir 15 is flush with the top surface (surface of the tip) of the nozzle 10, but the meat is so shaped that the tip protrudes acutely. When forming the pool part 15, although not particularly illustrated, the upper surface of the meat pool part 15 may be formed so as to be inclined (slant) linearly or curvedly with respect to the top surface of the nozzle 10.

[Overhang mode]
Next, as shown in FIG. 18, when the leading end of the meat reservoir 15 is shaped like a droplet and the advancing surface of the content liquid is curved downward (overhang) in an arc shape ( In the overhang mode), the content liquid that has flowed to the base side beyond the lowest point of the meat reservoir 15 remains in the meat reservoir 15 at the critical contact angle θ _{E due} to surface tension.
At this time, when the angle formed between the tangent L to the wall reservoir 15 at the end point and the top surface (tip portion) of the nozzle 10 is α, the advancing angle (critical contact angle of the edge portion) θ ^* is θ ^* = Θ _E + (2π−α), which is supported by the apparent large surface tension at the edge portion, so that the liquid content does not fall off.

When the liquid content falls, a large droplet that is no longer supported by the surface tension is separated and dropped, and the liquid is separated from the outer edge of the nozzle 10 without falling on the side surface of the nozzle 10 and falling. Will do.
Accordingly, even in this overhang mode, the liquid running around the outer edge side of the tip, that is, the separation between the liquid droplet falling from the outer edge of the nozzle 10 and the liquid remaining on the top surface side of the nozzle 10 can be obtained. And the liquid poured out from the nozzle 10 can be prevented from dripping to the side surface of the nozzle.

Thus, in the present embodiment, the reservoir 10 can be formed by hot pressing or the like on the nozzle 10 formed into a predetermined shape by injection molding or the like, and the surface of the liquid explained by the pinning effect By apparently increasing the tension, the remaining liquid of the content liquid poured out from the container can be easily retained in the meat reservoir 15 and the liquid drainage can be improved.
As a result, it is possible to improve the liquid breakage of the liquid that has turned to the outer edge side of the tip portion of the nozzle 10, which is compatible with the high liquid repellency (droplet fallability) of the fluorinated and roughened tip portion. As a result, it is possible to effectively prevent the liquid poured out from the nozzle 10 from dripping into the side surface of the nozzle.

[Manufacturing method of meat reservoir]
Next, a method for manufacturing the meat reservoir 15 provided at the tip of the nozzle 10 as described above will be described with reference to FIG.
FIG. 19 is an explanatory view schematically showing a manufacturing method in the case where the pool portion 15 is formed on the nozzle 10 according to the present embodiment by hot pressing. FIG. 19A shows the nozzle opening (discharge port) being hot pressed. (B) shows the state after the hot pressing, and (c) shows the state where the nozzle opening is closed by the hot pressing. , Respectively.

As shown in FIG. 19 (a), the meat reservoir 15 provided in the nozzle 10 is heated and pressurized by pressing a hot plate P for performing hot pressing on the surface (top surface) of the tip. The reservoir 15 that protrudes radially outward from the outer peripheral edge of the tip of the nozzle 10 can be formed.
As described above, the shape, size, and the like of the meat reservoir portion 15 formed by hot pressing press the hot plate P when the hot plate P that presses the tip of the nozzle 10 is pressed. By appropriately adjusting the pressing force, the time for pressing the hot plate P, and the like, the desired meat reservoir 15 can be formed.

Here, the hot press for forming the meat reservoir 15 is performed simultaneously with the step of forming predetermined irregularities on the surface of the tip of the nozzle 10 shown in FIG. 13A (2) with a stamper. be able to.
Specifically, a stamper (see FIGS. 13A and 13B) that forms irregularities at the tip of the nozzle 10 is constituted by a hot plate P shown in FIG. 19A, and the hot plate P (stamper) is used. By forming the unevenness on the top surface of the tip portion by hot pressing, the reservoir 15 can be formed on the outer edge of the tip portion.

Further, when the meat reservoir 15 is formed by hot pressing, the size and shape of the resin melting / expanding are predicted and estimated, and the nozzle length and opening of the nozzle 10 before being subjected to hot pressing are increased in advance. It is preferable to design and form.
In the case of a small amount dripping nozzle 10 such as an eye drop container, the opening for dispensing the droplet has a very small size, and the opening (ejection port) is narrowed or blocked by heat press. (See FIG. 19C).

Therefore, as shown in FIG. 19 (a), the opening (discharge port) of the nozzle 10 is formed large in advance so that the opening (discharge port) is not blocked by the hot press, so that the meat reservoir 15 is formed by hot pressing. Even so, the opening can have a predetermined size and length (see FIG. 19B).
In addition, since the meat reservoir 15 can be formed by hot pressing, it is necessary to consider defects such as deformation when taking out the mold without changing the existing mold when manufacturing the nozzle 10. There is also an advantage that the mold cost can be kept low.

  As described above, according to the nozzle of the present embodiment, the tip surface of the nozzle 10 is constituted by a plurality of surfaces having different surface free energies, that is, the first surface 11a and the second surface 12a. The first surface 11a located at the center is a high energy surface with low liquid repellency, and the second surface 12a located around the first surface 11a is a low energy surface with high liquid repellency, so that the liquid droplets are surely generated by the nozzle 10. The amount of dripping can be reduced while guiding to be formed at the center of the opening.

As a result, the drop performance is not deteriorated by repeated use, and there is no variation in the amount of drops, and a stable and small amount of drops can be reliably ensured. Can be realized.
In addition, the nozzle 10 to which liquid repellency has been imparted has improved droplet fall-off due to the liquid repellency on the top surface of the tip, and can also suppress or prevent the occurrence of liquid residue on the nozzle top surface.
Further, by forming the reservoir 15 at the outer edge of the tip of the nozzle 10, it is possible to improve the liquid breakage of the dispensed liquid droplets, and high liquid repellency (liquid) due to fluorination and roughening. Combined with the dropability of the droplets, the occurrence of dripping can be suppressed or prevented.

That is, the nozzle 10 of this embodiment is a surface in which the liquid repellency of the surface of the tip of the nozzle 10 is improved by first applying a predetermined liquid repellency processing / liquid repellency structure to the tip of the nozzle from which the liquid is poured out. That is, the second surface 12a to be a low energy surface is provided.
In addition, from the viewpoint of eliminating variations in the amount of dripping due to uneven liquid repellency on the nozzle surface or air entrainment, the liquid repellent bias is positively created so that the liquid droplets are always in the center of the nozzle 10. In order to guide it to be formed, a surface having lower liquid repellency than the second surface 12a subjected to liquid repellency, that is, a first surface 11a which is a high energy surface is provided at the center of the nozzle. .

Thereby, the first surface 11a which becomes a high energy surface exists on the outer periphery of the opening of the nozzle 10, and the second surface which becomes a low energy surface having higher water repellency than the first surface 11a around the first surface 11a. Since 12a continues, the liquid droplets poured out from the nozzle 10 are positively repelled from the second surface 12a and actively adsorbed to the first surface 11a. The droplet is formed and guided at the center of the nozzle while being adsorbed and contacted only by the first surface 11a.
For this reason, even if there is a variation in liquid repellency on the second surface 12a, or even if there is air entrainment in the dispensed droplet, the droplet may be biased toward the second surface 12a. Without being dispersed, the droplets are always guided to be formed at the center of the opening of the nozzle 10.
Therefore, in the nozzle 10 of the present embodiment, the liquid can be reliably and stably dispensed / dropped without causing unevenness or dispersion of the liquid droplets.

The second surface 12a, which is a low-energy surface with high liquid repellency, can be improved and maintained in the liquid repellency of the nozzle tip surface by applying fluorine plasma processing or rough surface processing.
That is, the plastic molded body constituting the second surface 12a of the nozzle 10 is formed of a non-fluorine resin such as polyolefin or polyester, but the portion constituting the second surface 12a has a non-fluorine resin. A fluorine atom is incorporated in the molecular chain.
Moreover, the rough surface which consists of fine unevenness | corrugation is formed in the fluorinated 2nd surface 12a as needed.

The second surface 12a of the nozzle 10 thus fluorinated and roughened is improved in liquid repellency by fluorine atoms and air pockets by a rough surface comprising fine irregularities when liquid is poured out from the container. Further high liquid repellency is ensured by the presence of (gas-liquid contact). As a result, the dispensed droplet does not adhere to the second surface 12a but is guided to be formed on the first surface 11a at the center of the nozzle.
Further, the fluorination of the nozzle tip can be performed stably without dropping off from the surface (rough surface) because fluorine atoms are incorporated in the molecular chain of the non-fluorine resin constituting the second surface 12a. It exists on the surface (rough surface) of the nozzle tip. For this reason, even when the liquid is repeatedly poured out, the liquid repellency is not impaired.

That is, the nozzle 10 with the tip portion fluorinated and roughened maintains excellent liquid repellency over a long period of time, and even when the liquid repeatedly contacts, the liquid repellency at the same level as the initial stage is maintained. Therefore, a small amount of dripping is possible.
Accordingly, by setting the inner diameter of the nozzle 10 and the surface area and shape of the first surface 11a to a predetermined size, the amount of liquid (eye drops) dispensed from the nozzle 10 can be set to an arbitrary amount such as 10 μl or less. The drop amount can be reduced and optimized, and the optimal eye drop amount and drop amount for the human eye can be realized.

Further, the tip of the fluorinated and roughened nozzle 10 is protected by the cap 20, and in this case, the inner surface of the cap 20 contacts and contacts the fluorinated and roughened surface of the nozzle 10. The nozzle 10 is covered with the cap 20 in a state where the cap 20 is not in contact with the second surface 12a, and the inside of the container is protected in a sealed state.
Therefore, even if the cap 20 is repeatedly attached and detached, the fluorination / roughening performance of the tip of the nozzle 10 is not impaired, and the small amount of the nozzle 10 can be dripped until the end of the liquid (eye drops) in the container. It will be able to be demonstrated.

As described above, according to the nozzle 10 according to the present embodiment, the dripping amount in the eye drop container 1 can be reduced, and dripping and remaining liquid on the top surface of the nozzle can be prevented. Therefore, it is possible to effectively prevent the occurrence of problems such as deterioration of the dropping performance even after repeated use.
Furthermore, the nozzle performance according to the present invention can be stably maintained by reliably protecting the tip of the nozzle 10 with the cap 20 so that the function thereof is not impaired. Good eye drops can be performed until all eye drops are used up.

Hereinafter, an embodiment of the nozzle according to the present invention will be described with reference to Table 1.
The present invention will be further described with reference to the following examples, but the present invention is not limited in any way by the following examples.
(Nozzle base 1)
・ Resin: Polyethylene (Nippon Polyethylene LJ8041)
・ Molding method: Injection molding method ・ External shape: Diameter 6mm x Length 5mm
・ Aperture diameter: 0.8mm
(Nozzle base 2)
・ Resin: Polyethylene (Nippon Polyethylene LJ8041)
・ Molding method: Injection molding method ・ External shape: Diameter 6mm x Length 5mm
・ Aperture diameter: 1.2mm
(Nozzle base 3)
・ Resin: Polyethylene (Nippon Polyethylene LJ8041)
・ Molding method: Injection molding method ・ External shape: Diameter 6mm x Length 5mm
・ Aperture diameter: 0.4mm
(First dripping part a)
・ Resin: Polyethylene (Nippon Polyethylene LJ8041)
・ Molding method: Injection molding method ・ Outer shape: Diameter 0.8 mm x Inner diameter 0.4 mm x Length 1 mm
-Shape of the first surface: rectangle (first dripping part b)
・ Resin: Polyethylene (Nippon Polyethylene LJ8041)
・ Molding method: Injection molding method ・ External shape: Diameter 1.2 mm x Inner diameter 0.4 mm x Length 1 mm
-Shape of the first surface: rectangle (first dripping portion c)
・ Resin: Polyethylene (Nippon Polyethylene LJ8041)
・ Molding method: Injection molding method ・ Outer shape: Diameter 0.8 mm x Inner diameter 0.4 mm x Length 1 mm
-Shape of the first surface: reduced taper (tip angle 30 °)
(First dripping part d)
・ Resin: Polyethylene (Nippon Polyethylene LJ8041)
・ Molding method: Injection molding method ・ Outer shape: Diameter 0.8 mm x Inner diameter 0.4 mm x Length 1 mm
-Shape of the first surface: enlarged taper (tip angle 45 °)
(Roughening process)
・ Ni stamper with layered concavo-convex structure formed on the surface was heated to 230 ℃ and hot press molded to the nozzle base ・ Primary concavo-convex structure ・ Line & space pattern ・ Area ratio = 0.2
・ Secondary uneven structure ・ Ra / Rsm = 250 × 10 ⁻³
(Fluorine plasma process)
・ Surface wave plasma device ・ Power output: 1.5 kW @ 2.45 GHz
・ Raw material gas: CF ₄ 200 sccm
・ Vacuum degree: 4Pa
・ Processing time: 20 seconds (burr installation process)
・ Burr was attached to the nozzle base opening by drilling with a 0.4mm diameter drill (projection assembly process)
・ The first drop part was inserted into the opening of the nozzle base. ・ During the assembly, the drop part was projected 0.3 mm from the surface of the nozzle base (drop test).
-A nozzle was inserted into the eye drop container body filled with the funnel C cube.-The container body was pressed, and 20 drops of the filling liquid were dropped to measure the amount of dripping (small amount dropping performance evaluation).
・ Average drop amount was calculated and evaluated ・ ○ −Average value ≦ 10 μL
-X-average value> 10 μL
(Drip amount reproduction performance evaluation)
-Average drop amount and standard deviation were calculated, and CV was calculated and evaluated from the following formula.-CV (%) = (standard deviation) / (average value) x 100
・ ○-CV ≦ 3.3%
・ △-3.3 <CV ≦ 5.0%
・ ×-CV> 5.0%

  The nozzle of the present invention has been described with reference to the preferred embodiment, but the nozzle according to the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the present invention. Needless to say.

  For example, in the above-described embodiment, an eye drop container for eye drops is described as an example of an application target of the nozzle of the present invention, but the application target of the present invention is not limited to the eye drop container. In other words, any nozzle or spout where it is desired to drop the fluid by a predetermined amount can be applied to containers other than eye drops containers. For example, containers for chemicals other than eye drops, seasonings such as soy sauce and sauces, etc. It can be used as a nozzle for various containers, such as containers for foods, containers for chemical products such as detergents and cosmetics, nozzles for medical and laboratory instruments, and nozzles for liquid dropping devices.

  The present invention can be suitably used as a nozzle for dropping a small amount of, for example, an eye drop container.

DESCRIPTION OF SYMBOLS 1 Container for eye drops 2 Container main body 10 Nozzle 11 1st dripping part 11a 1st surface 12 2nd dripping part 12a 2nd surface 15 Meat pool part 20 Cap 21 Nozzle contact part 100 Rough surface 160 Primary unevenness 160a Concave part 160b Convex portion 165 Secondary unevenness 170 Droplet

Claims (11)

The nozzle tip surface is
A first surface located on the nozzle center side, and a second surface continuous to the outer peripheral side of the first surface,
Said 1st surface and 2nd surface consist of surfaces from which surface free energy differs. The nozzle characterized by the above-mentioned.   The nozzle according to claim 1, wherein the second surface has higher liquid repellency than the first surface.   3. The nozzle according to claim 1, wherein the second surface is roughened to have a surface free energy different from that of the first surface. The nozzle is a nozzle for dropping droplets;
A first dropping section through which the liquid to be dropped passes;
A second dropping part disposed on the outer peripheral side of the first dropping part,
The tip surface of the first dropping part is the first surface,
The nozzle according to any one of claims 1 to 3, wherein a surface of a tip portion of the second dripping portion is the second surface.   The nozzle according to any one of claims 1 to 4, wherein the first surface protrudes in a dispensing direction from the second surface.   The nozzle according to any one of claims 1 to 4, wherein the first surface does not protrude in the dispensing direction from the second surface.   The nozzle according to any one of claims 1 to 5, wherein a shape of the first surface in a cross section including the nozzle center line is a rectangular shape.   The nozzle according to any one of claims 1 to 5, wherein a shape of the first surface in a cross section including a nozzle center line is a tapered shape that is reduced in a dispensing direction.   The nozzle according to any one of claims 1 to 5, wherein a shape of the first surface in a cross section including the nozzle center line is a tapered shape expanding in a dispensing direction.   The nozzle as described in any one of Claim 1 thru | or 9 provided with the cap which seals the said nozzle by contact | abutting to said 1st surface. Having a reservoir that protrudes outward from the outer peripheral edge of the tip of the nozzle;
The nozzle according to any one of claims 1 to 10, wherein the meat pool portion is formed by hot pressing a tip portion of the nozzle.

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