EP0514659A1 - Closing cap with a brush - Google Patents

Abstract

The invention relates to a closure cap (1) with a brush (7) for permanent closure and sealing of bottles (4), in particular nail varnish bottles, which are intended for repeated opening and closing. Provided on the closure cap (1) are two sealing means in the form of an annular bead (19), provided on a cylindrical part (18) connected to the closure cap (1), and of a sealing shoulder (14') which interacts with the plane surface (12) of the bottle (4) during use. Additionally, the closure cap (1) has a brush-bearing shaft (5). According to the invention, the closure cap (1) is characterised in that the cylindrical part (18) is a hollow journal which is connected to the closure cap (1) at one end only and, at the other end, is of resilient construction in the radial direction, relative to the axis of symmetry of the closure cap (1). Additionally, it has a convexly curved surface and surrounds the brush-bearing shaft (5) coaxially, the hollow journal forming an annular gap (17) with the brush-bearing shaft (5). <IMAGE>

Description

The invention relates to a sealing plug according to the preamble of patent claim 1.

Paints, varnishes and other liquids that can be applied to smaller areas with a brush are often packaged and sold in small bottles, which are provided with a cap to which a brush protruding into the bottle is attached. Especially for those users of these liquids who only need them occasionally, it is desirable that the bottles are tightly closable in order to keep the liquid in question usable for as long as possible. In addition, the bottles must be secure against leakage. This problem particularly affects bottles that contain nail polish, since they are also exposed to fluctuations in air pressure and temperature fluctuations, for example when traveling by air, and must be leakproof.

DE-GM 0 379 692 A3 describes a brush for applying a liquid containing volatile solvents, in particular nail polish. This brush is intended as an insert for a sealing cap, which is provided with an internal thread that fits a thread on a bottle. The brush has a conically widening shaft that merges into a cylindrical part on which a sealing bead is molded. Above the sealing bead, a sealing shoulder adjoins the cylindrical part, which carries a sealing lip of approximately triangular cross-section. The sealing lip is located on the side of the sealing shoulder that faces a flat surface provided on the bottle. Above the sealing shoulder is an attachment piece for holding the brush in the cap on the brush.

Especially when used improperly, for example when the brush is inserted obliquely into the opening of the bottle, the sealing effect can be impaired. The sealing lip can also be jeopardized if the cap is tightened too much.

The object of the invention is therefore to provide a stopper with a brush, with which bottles can be securely and permanently sealed even after frequent opening and closing, and which is not impaired by obliquely inserting or over-tightening the closure cap.

The object is achieved by the plug with a brush with the features of the characterizing part of claim 1.

The stopper has a sealing shoulder which forms a sealing surface which forms an acute angle with the flat surface of the bottle neck surrounding the bottle opening. If the diameter of the sealing shoulder is less than the outside diameter of the flat surface, the sealing surface initially only lies linearly on the flat surface with a small axial pressure. This alone provides a seal. With a firmer pressure, the line touches without much deformation effort into a surface contact. Because of the slight deformation, destruction of the sealing surface due to excessive pressure, such as occurs when the closure cap is tightened too strongly, is definitely ruled out.

The conditions for inserting the hollow pin into the opening and for removing it are particularly favorable if the convexly curved surface represents a section of an imaginary sphere. Even if the hollow spigot is inserted obliquely, tilting and damage is not possible.

Since the material from which the sealing plug is made is resilient, the hollow pin can spring in the radial direction. This ensures a good adaptation of the hollow pin to the diameter tolerances of the bottle opening.

The stopper is advantageously made in one piece from a plastic which is insensitive to the liquid contained in the bottle.

Further features of the sealing plug are the subject of subclaims.

Fig. 1

einen Verschlußstopfen mit Pinsel in Seitenansicht und in teilweiser Schnittdarstellung,

Fig. 2

eine zum Verschluß mit dem in Fig. 1 dargestellten Verschlußstopfen vorgesehene Öffnung einer Flasche in Schnittdarstellung,

Fig. 3

eine zur Aufnahme des Verschlußstopfens vorgesehene Verschlußkappe in teilweiser Schnittdarstellung und

Fig. 4

den in die zylindrische Öffnung der Flasche eingesetzten Verschlußstopfen in teilweise geschnittener Darstellung.

In the drawing, an embodiment of the invention is shown. Show it:

Fig. 1

a sealing plug with brush in side view and in partial sectional view,

Fig. 2

an opening of a bottle provided for closure with the stopper shown in FIG. 1 in a sectional view,

Fig. 3

a closure cap provided for receiving the closure plug in a partial sectional view and

Fig. 4

the plug inserted into the cylindrical opening of the bottle in a partially sectioned view.

The stopper 1 shown in FIG. 1 is an essentially rotationally symmetrical one-piece body which is intended for use in a closure cap 2 shown in FIG. 3 and together with this for closing an opening 3 of a bottle 4 shown in FIG. 2. The bottle 4 contains a solvent-containing liquid, for example nail polish or the like. and it is necessary that the opening 3 is closed as tightly as possible. In addition, it should be possible to apply the contents of the bottle to smaller areas with the sealing plug 1. For this purpose, the sealing plug 1 has a shaft 5 which extends coaxially to the axis of symmetry and which carries a round or oval brush 7 on its end 6 facing away from the sealing plug. The length of the shaft 5 is dimensioned such that the brush 7 just extends to the bottom of the bottle 4, not shown in the drawing. The brush-bearing shaft 5 is connected coaxially and directly to a cup-shaped part 8 provided for fastening in the closure cap 2, the cup-shaped part being opened on the side facing away from the shaft 5 and being delimited by an end face 8a. The cup-shaped part 8 is made relatively thin-walled and essentially cylindrical, which means that it can spring somewhat in the radial direction. In order to hold the sealing plug 1 captively in the sealing cap 2 shown in FIG. 3, in the sealing cap 2 there is provided a sack-shaped recess 9 for receiving the sealing plug 1 with a flat bottom 9a which widens downwards to conical. The sack-shaped recess 9 is arranged coaxially in the rotationally symmetrical sealing cap and below the center and corresponds in its dimensions exactly to the cup-shaped part 8 of the sealing plug 1. To fix the sealing plug in the To hold recess 9, a circumferential groove 10 is provided on the cup-shaped part 8. Correspondingly, the sack-shaped recess 9 of the closure cap 2 has a bead 11 which is complementary to the circumferential groove 10. Otherwise, the closure cap is provided with a grip part 2a and an internal thread 2b adjoining the recess 9, which is designed to match an external thread 4a provided on the neck of the bottle 4.

To securely seal the opening 3 of the bottle 4, the sealing plug 1 has two independently acting sealing means. A sealing shoulder 12 with a sealing surface 13 extending in the radial direction is provided as the first sealing means on the sealing plug 1. With the outer circumferential surface of the cup-shaped part 8, the sealing surface 13 forms a circular circumferential sealing lip 14. The sealing surface 13 is inclined somewhat in relation to the radial in the direction of the brush 7. The sealing surface 13 forms an angle of approximately 8.5 ° with the radial direction. Here, the diameter of the sealing lip 13 formed by the sealing surface 13 and the outer surface of the cup-shaped part 8 is significantly larger than the diameter of the cylindrical opening 3 of the bottle 4, but smaller than the outer diameter of a flat surface 15 surrounding the opening 3, so that it is at the use rests approximately in the middle of the flat surface 15 (Fig. 4). The flat surface 15 surrounding the opening 3 is oriented essentially transversely with respect to the axis of symmetry and merges with a chamfer 15a into the opening 3 with an approximately cylindrical inner surface 15b. On the radially outer side of the flat surface 15, the thread 4a connects for screwing on the closure cap 2.

As a second sealant which acts independently of the sealing lip 14, a hollow pin 16 is provided on the sealing plug 1, which axially aligns the brush-bearing shaft 5 surrounds. While the hollow pin 16 is firmly connected on one side to the sealing plug 1, to be precise with the cup-shaped part 8, it is open on the side facing the brush 7, so that it forms with the shaft 5 an annular gap 17 which is open on one side and has a square cross section . The outer circumferential surface of the hollow pin 16 is a cylinder surface 18 immediately following the sealing surface 13. The diameter of this cylinder surface 18 is only slightly smaller than the diameter of the cylindrical opening 3 of the bottle 4. In the direction of the brush 7, the cylinder surface closes 18 a convexly curved surface 19. At the point of its greatest expansion, it has a radius 20, the diameter of which is markedly larger than the inside diameter of the cylindrical opening 3. In the direction of the brush 7, the diameter of the convex surface 19 decreases again until the diameter of the opening 3 is significantly below. At this point, the hollow pin 16 is delimited by an annular surface 21. The radius of curvature of the convexly curved surface 19 is only slightly smaller than the radius of the circumference 20. Accordingly, the convexly curved surface essentially describes a section of an imaginary sphere 22.

The hollow pin 16 is relatively thin-walled, so that it can spring in the radial direction in the material used, for example polyester, without the remaining sealing plug 1 being noticeably deformed thereby.

The sealing plug described so far works as follows:
In use, the plug 1 is inserted into the cap 2. The cup-shaped part 8 is inserted into the sack-shaped recess, the groove 10 being locked in place with the bead 11 and the end face 8a on the flat bottom surface 9a is present. So that the plug 1 is fixed in the recess 9, but due to the conical expansion of the recess 9 downward, the sealing lip 14 is spaced from the cap 2.

If the user, with the intention of closing the bottle 4, inserts the sealing plug 1 of the sealing cap 2 into the opening 3, the ring surface 21 first comes into the region of the opening 3. However, the diameter of the ring surface 21 is smaller than that of the opening 3 surrounding chamfer 15a, so that the annular surface 21 can enter the opening 3 without resistance until the surface 19 abuts the chamfer 15a. Since the surface 19 is a section of the imaginary ball 22, the surface 19 always lies evenly on the chamfer 15a, regardless of whether the sealing plug 1 is inserted straight or at a slight angle. Because of the quite large radius of curvature of the surface 19, it encloses a small angle with the cylindrical surface 15b.

When the surface 19 abuts the chamfer 15a, a force acting in the direction of the brush 7 must be applied by the user. Due to the fact that the surface 19 abuts the chamfer 15a at an acute angle, the force acting in the direction of the brush 7 is converted into a large, essentially radially directed compressive force acting on the surface 19. The more acute the angle, the greater the radially directed compressive force with the same force in the direction of the brush 7. The resulting compressive force is at least so great that the hollow cylindrical pin 16, which is inherently quite rigid, is compressed inwards and into the opening 3 slips in. The friction force to be overcome between the opening 3 and the surface 19 is low due to the material pairing of glass and plastic. Consequently, as soon as the circumference 20 has penetrated the opening to such an extent that it touches the inner surface 15b, only the low frictional force is still there overcome. The user therefore initially feels a high and then a decreasing resistance when inserting the sealing plug 1 into the opening 3, which is subjectively perceived as a clear and pleasant snap effect.

The hollow pin 16 is subjected to a significant deformation, particularly on its convexly curved surface 19, when the sealing plug 1 is inserted into the opening 3. FIG. 4 shows that the surface 19 has undergone flattening and lies flat against the cylinder surface 15b. The radius 20 is reduced to the diameter of the opening 3. The deformation forces that occur are considerable and result in a corresponding surface pressure. Due to the surface contact of the surface 19 on the cylinder surface 15b and the large surface pressure between these surfaces, a certain sealing of the opening 3 is already achieved.

In order to close the bottle 4 completely tight, the internal thread 2b is then brought into engagement and screwed with the thread 4a provided on the bottle 4 by rotating the closure cap 2. The closure cap 2 with the bottom 9a of the sack-shaped recess 9 exerts pressure on the end face 8a of the closure plug 1. First of all, the hollow pin 16 of the sealing plug is thereby pushed further into the opening 3 and the shoulder 12 approaches the flat surface 15. The sealing plug 1 rotates together with the sealing cap 2, the surface 19 sliding on the cylindrical surface 15b. Because of the not very large friction between the surface 19 and the cylinder surface 15b, the torques to be applied for rotating the closure cap 2 are low.

Finally, the closure cap 2 is screwed on so far that the sealing shoulder 12 lies against the flat surface 15. First, the sealing lip 14 touches the flat surface 15 in one Circular line. Between the circular line and the surface 19, a small, ring-shaped, closed space 23 is created. If the user now firmly pulls the sealing cap 2, the force acting on the sealing plug 1 increases so much that the sealing lip 14 and the sealing surface 13 are deformed. The originally inclined sealing surface 13 is pressed onto the rigid surface 15 and adapts to its shape and position. The initially linear contact becomes a surface contact that is loaded by an axially acting force. This surface contact seals the annular space 23 from the environment.

In the case of a stopper 1 inserted into the bottle 4 in the manner described, there is a double sealing effect: the bottle 4 is sealed against the annular space 23 by the firmly pressed surfaces 19 and the cylindrical surface 15b and the space 23 is pressed against the environment by the pressed together Flat surface 15 and the sealing shoulder 12 sealed. If a pressure drop occurs between the interior of the bottle 4 and the environment due to temperature or air pressure fluctuations, a liquid or its vapors contained in the bottle would have to overcome a double barrier in order to get into the environment. In particular, an increase in the internal pressure caused by temperature influences acts as an additional radial force in the annular gap 17. This increases the surface pressure between the surface 19 and the inner surface 15b and consequently also the sealing effect. The stopper 1 therefore closes the bottle 4 permanently tight. An undesired automatic loosening or screwing of the sealing plug 1 as a result of repeated pressure fluctuations is also impossible. This ensures that the liquid contained in the bottle 4 does not dry up even after a long storage period and that it retains the properties necessary for use.

To open the bottle 4, the cap 2 is loosened by a screwing movement. First, the sealing surface 13 is lifted off the flat surface 15, whereby it relaxes and, due to the elasticity of the plastic from which the sealing plug is made, returns to its original flat shape. After the sealing cap 2 has been unscrewed from the thread 4a, the hollow pin 16 of the sealing plug 1 is pulled out of the opening 3 by pulling on the sealing cap 2. Initially, all that needs to be overcome is the frictional force that occurs when the surface 19 slides on the cylindrical surface 4b. This frictional force is not very great, but you can feel it. As soon as the hollow pin 16 with the surface 19 has been pulled out of the opening 3 to such an extent that the circumference 20 is at the level of the flat surface 15, the spring action of the hollow pin 16 with the surface 19 deformed by insertion into the opening 3 supports the pulling movement. The surface 19 encloses with the cylinder surface an increasingly blunt angle in the course of the movement, so that the pulling movement is supported more and more. The user registers this effect as a clear snapping out of the sealing plug 1.

The described closing and opening processes can be repeated very often without noticeable wear of the sealing plug, in particular on the surface 19 and on the sealing surface 13, being noted. So that the plug 1 remains tight even after repeated opening and closing. Because of the shape of the hollow pin 16 and the convexly curved surface 19 as a section of an imaginary ball 22, the angles which occur when the hollow pin 16 is inserted into the opening 3 between the cylinder surface 4b delimiting the opening 3 and the surface 19 are very small. This precludes the material 3 being scraped from the surface 19 when the hollow pin 16 is inserted into the opening would. Even after being plugged in frequently, the surface 19 is undamaged and fully fulfills its function.

Claims (13)

Sealing plug with brush for permanent closing and sealing of bottles intended for repeated opening and closing, containing volatile substances, in particular nail polish bottles, which have a neck with a substantially circular cylindrical opening, a flat surface surrounding the opening and an external thread, with two sealants in the form of a on a cylindrical part provided with the sealing plug and a sealing shoulder which cooperates with the flat surface of the bottle when in use, as well as with a brush-bearing shaft, characterized in that the cylindrical part is a hollow pin (16) which only connects at one end to the sealing plug (1 ) connected and at the other end based on the axis of symmetry of the sealing plug (1) is designed to be resilient in the radial direction, which has a convexly curved surface (19) and which coaxially surrounds the brush-bearing shaft (5), the hollow pin (16) mi t the brush-bearing shaft (5) forms an annular gap (17), and that the sealing shoulder (12) has a sealing surface (13) which is inclined inwards relative to the radial direction, such that the sealing surface (13) with the flat surface (15) includes an acute angle. Sealing plug according to claim 1, characterized in that the sealing shoulder (12) has a diameter which is smaller than the outer diameter of the plane surface (15) surrounding the opening. Sealing plug according to claim 1, characterized in that the acute angle which the sealing surface (13) forms with the flat surface (15) is between 5 ° and 15 °. Sealing plug according to claim 1, characterized in that the hollow pin (16) has a cylindrical surface (18) whose diameter is smaller than the inside diameter of the opening (3) provided on the bottle (4). Sealing plug according to claim 1, characterized in that the radial diameter of the convexly curved surface (19) is larger than the inside diameter of the opening (3) provided on the bottle (4). Sealing plug according to claim 1, characterized in that the difference between the maximum diameter of the convexly curved surface (19) and the inside diameter of the opening (3) lies in the elastic region of the hollow pin (16). Sealing plug according to Claim 1, characterized in that the convexly curved surface (19) has an essentially circular section-shaped configuration in cross-section, the radius of the circular-arc-shaped border of the cross-sectional area between the radius of the hollow pin (16) on the side facing the bottle and the radius the circumference (20) of the surface (19). Sealing plug according to claim 1, characterized in that the convexly curved surface (19) is essentially a section of an imaginary ball (22) which has the diameter of the circumference (20). Sealing plug according to claim 1, characterized in that the annular gap (17) formed by the hollow pin (16) with the brush-bearing shaft (5) is open even when the sealing plug (1) is inserted into the opening (3). Sealing plug according to claim 1, characterized in that an attachment piece for fastening in a sealing cap (2) is provided on the sealing plug (1). Sealing plug according to claim 1, characterized in that the extension piece is a cup-shaped part (8) with a circumferential groove (10). Sealing plug according to claim 1, characterized in that the sealing plug (1) is a single, correspondingly shaped plastic part. Sealing plug according to claims 1 and 12, characterized in that the sealing plug (1) consists of an elastic plastic which is resistant to the liquid contained in the bottle.

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