Connector for Bottle-Like Containers

Abstract

The present invention concerns a connector (1) able to be mounted on the neck of a container for liquids (100), in the form of a bottler consisting of a main body having, sliding longitudinally therein, a slider provided with a radially expandable bottom portion so as to engage reversibly with a hollow:, probe, in which the hollow probe is able to perform the longitudinal displacement of the the slider and connect the inside of the container (100) with its interior so as to allow the dispensing of liquid from the container.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

The characteristic features and advantages of the present invention will become clear from the following detailed description of a practical embodiment provided by way or a non-limiting example, with reference to the accompanying drawings, in which:

FIG. 1 shows a partial cross-section and a partial front view of an example of a connector according to a preferred embodiment of the present invention, mounted on the mouth of a bottle-like container and a probe able to engage with the connector;

FIG. 2 shows a partial cross-section and a partial front view of the connector according to FIG. 1 in the closed configuration with probe completely engaged inside it;

FIG. 3 a shows a partial cross-section and a partial front view of the connector according to FIG. 1 in an intermediate configuration between the closed configuration and the open configuration shown in FIG. 5;

FIG. 3 b shows the cross-section of a detail of the connector according to FIG. 3a:

FIG. 4 shows a partial cross-section and a partial front view of the connector according to FIG. 3a in an intermediate configuration between the configuration shown in FIG. 3a and the open configuration;

FIG. 5 shows a partial cross-section and a partial front view of the container according to FIG. 1 in the open configuration

FIG. 6 shows an enlarged view of a detail according to FIG. 1

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

With reference to the figures, 100 denotes a container with a longitudinal axis Z-Z, having a neck 101 and a mouth, such as a bottle for example. A probe 103, which in FIG. 1 is shown separate from the container/connector assembly, is connected to the apparatus which controls it and which forms the dispensing device. As can be seen in the figures, it has a retaining groove 104 and windows 105 for allowing the introduction of liquid from the container 100 into the channel 106 of probe 103.

1 denotes overall a connector which is integrally joined to the container 100 and composed of a main body 3 and a slider 4 situated inside it and longitudinally sliding therein.

The connector 1 has a longitudinal axis X-X which, when the connector 1 is mounted on container 100, coincides with the longitudinal axis Z-Z of the container 100.

The main body 3 is provided with retaining means able to constrain it firmly to the container 100. For example, it may advantageously comprise an outer skirt 5 with a lip 7 such as to engage with a suitable locating element formed on the neck 101 of the container 100, preventing extraction of the connector 1 from the neck 101 of the container 100.

The retaining means may also be formed by an inner thread able to engage with a corresponding thread formed on the container 100.

The main body 3 may also comprise means able to prevent rotation relative to the container 100; these means may advantageously consist of projections which are parallel to the axis X-X and engage with corresponding projections formed on the outer surface of the neck of the container 100.

Slider 4 is able to slide longitudinally between a bottom closed position, shown in FIGS. 1, 2 and 6, where it defines a closed configuration of the connector 1, and at least one upper open position, shown in FIG. 5, where it defines an open configuration of the connector 1, and vice versa.

In the bottom closed position, slider 4 ensures the liquid-tightness of the connector 1 and is able to engage with and disengage from probe 103.

When connector 1 is in the upper open configuration, slider 4 is completely disengaged from main body 3 and is situated completely within container 100; the apertures of windows 105 associated with probe 103 are completely free.

It is also possible to regard as open those intermediate configurations between the upper open configuration and the bottom closed configuration, which nevertheless allow the liquid to flow out of the container 100. During the course of the present description reference will be made mainly to the upper open configuration shown in FIG. 5.

The direction from the bottom closed position towards the tipper open position thus defines the bottom-to-top direction and relates to the arrangement of the container 100 when it is being used, i.e. is upside down.

The connector 1 may furthermore comprise special means (not shown) for indicating attempts to remove the connector 1 from the container 100 or the fact that initial opening has occurred.

The main body 3 comprises a sliding sleeve 9 which preferably has a circular cross-section and which has a first end 11 such that, when the connector 1 is fixed to the container 100, the first end 11 is directed towards the mouth of the container 100; the first end 11 is therefore the bottom end of the sleeve 9, according to the definition given above.

Slider 4 comprises a central guiding portion 6 which is able to be guided by the sleeve 9 of the main body 3 and a bottom, engaging portion 8 which is able to engage reversibly with probe 103 and is arranged towards the mouth of the container 100, i.e. on the bottom side of the central portion 6.

Slider 4 defines inside it a seat 10 able to receive probe 103.

When the connector 1 is in the closed configuration, the bottom engaging portion 8 of slider 4 is situated outside the sleeve 9 of the main body 3.

In other words, if α indicates the plane perpendicular to the axis X-X and passing through the first end 11 of the sleeve 9 directed towards probe 103, the bottom portion 8 of slider 4 is situated on the side of the plane a which is opposite to the the sleeve 9. The bottom portion 8 is able to receive probe 103 by expanding radially. It may be advantageously divided into a plurality, for example six, eight or ten elongated parts 12 which may advantageously be identical to each other and preferably equally spaced along the outer perimeter of the bottom portion 8 of slider 4.

Engagement with the retaining groove 104 of probe 103 is achieved by means of teeth 14 which are advantageously formed on the bottom portion 8 and preferably project towards the seat 10. Advantageously, a tooth 14 is formed on each elongated part 12.

In this way, when probe 103 moves longitudinally towards the seat 10 of slider 4, the conical end 108 of probe 103 will push the bottom portion 8 of slider 4 outwards, boy means of the teeth 14 and the elongated parts 12, making use of their radial elasticity.

As soon as teeth 14 have completely passed over the conical part 108 of probe 103, the elasticity of the elongated parts 12 will allow the teeth 14 to return elastically into their rest position, thus resulting in snap-engagement of the bottom portion 8 Inside the retaining groove 104.

The size of the seat 10 of slider 4 is determined so that the base 16 of the seat 10 is in contact with the top end, 109 of probe 103, which is generally flat so as to allow also the transmission to slider 4 of high longitudinal forces directed towards the centre of the container 100.

Advantageously, the distance between the teeth 14 and the base 16 is slightly less than the distance between the top, end 109 and the groove 104, so as to ensure constant contact between probe 103 and slider 4.

The main body 3 comprises, at the end of the sleeve 9 opposite to the bottom end 11, a first abutment surface 17 able to cooperate with a second corresponding abutment surface 18 formed on slider 4 in the vicinity of the end of the central portion 6 which is longitudinally opposite to the bottom portion 8 and which has an outer diameter d2.

These first and second abutment surfaces 17, 18 are preferably formed as surfaces converging towards the plane α, for example frustoconical surfaces and/or surfaces with a cross-section in the form of a circumferential arc, and are respectively adjacent to the inner surface of the sleeve 9 and to the outer surface of the central portion 6 of slider 4.

The function of these surfaces is to allow extraction of probe 103 from the seat 10 formed in slider 4 and preventing extraction of slider 4 from the main body 3, exerting a longitudinal, force greater than the maximum force which the bottom portion 8 is able to exert on probe 103 via the teeth 14.

When probe 103 must be extracted from the container 100 and slider 4 reaches the bottom closed position, the two abutment surfaces 17, 18 come into abutment with each other and the bottom portion 8 of slider 4 is situated outside the sleeve 9.

The bottom portion 8 is formed so that the longitudinal force which It is able to exert via the retaining means (i.e. teeth 14) is less than the maximum longitudinal force which the abutment surfaces 17 and 18 may exert.

Consequently, each additional longitudinal movement of probe 103 out from the seat 10 of slider 4 results n radial expansion of the bottom portion 8, therefore allowing probe 103 to pass over the teeth 14. Probe 103 at this point is free from its engagement inside the seat 10.

Advantageously, the in diameter d1 of the sleeve 9 is such that in is able to provide a liquid-tight seal when the sleeve is engaged with the outer surface of slider 4 or with its central portion 6 or with the outer surface of the channel 106.

Normally the diameter of channel 106 constitutes one of the design data and consequently determines the dimensions of the other parts.

On the side of the first abutment surface 17 opposite to sleeve 9 (and therefore above it), the main body 3 comprises an upper portion 19 able to engage with a corresponding upper portion 20 of slider 4, formed on the opposite side, relative to the first abutment surface 18, to that of the central portion 6.

This upper portion 19 of the main body 3 is advantageously cylindrical, having an inner diameter d3>d1.

The bottom portion 19 of the main body 3 has, in the vicinity of its upper end (namely opposite to plane α), a third and a fifth abutment surface denoted by 25 and 27 in FIG. 2, respectively. These surfaces are advantageously formed on a circumferential projection 23 projecting towards the inside of main body 3 and with an inner diameter d5.

The abutment surfaces 25 and 27 therefore define two conical surfaces having opposite vertices with respect to the projection 23 and are advantageously inclined relative to axis X-X by about 15° and about 45°, respectively.

The upper portion 20 of slider 4 terminates in an end 22 opposite to the bottom portion 8 where the outer diameter d4 is such as to engage, with slight interference, with the upper portion 19 having a diameter d3, so as to prevent any relative movements of slider 4 and main body 3.

The upper portion 20 may advantageously have a cylindrical section with an outer diameter d6 (not indicated in the figures), where d2<d6<d4 and d6>d5, joined on one side to the first abutment surface 18 and, on the opposite side, to an additional conical surface which converges towards the bottom portion 8 and the outer diameter of which reaches the value of d4 substantially at the end 22.

In the vicinity of this maximum diameter d4, namely above and below it, it is possible to identify a fourth abutment surface 26, facing the bottom of the container, and a sixth abutment surface 23 which is directed towards sleeve 9 and the functions of which will be described more fully below.

The surfaces 25 and 27 co-operate with surfaces 28 and 26, respectively, so as to allow safe opening and closing of the connector 1.

In fact, when the upper portion 20, during its longitudinal movement, passes over projection 23, the pairs 25/28 and 27/26 of abutment surfaces produce a peak in the axial resistive force which opposes the movement of slider 4.

This peak depends on the relative inclination of the surfaces, which is chosen so that slider 4 can be suitably actuated by probe 103.

The first of the two peaks mentioned above occurs, during opening of the connector, when surface 28 passes over surface 25; the second peak occurs during the closing phase, when surface 26 passes over surface 27.

The longitudinal distance between the end 22 and the projection 23 when the connector 1 is in the bottom closed configuration, namely the travel movement which probe 103 must perform between the bottom closed position and the position where the abovementioned peak may be detected, must be such as to satisfy a condition clarified below.

Since, when the projection 23 is passed over, a peak value in the force is reached and this force, applied to slider 4, opposes the movement of probe 103, it is important that this force does not cause disengagement of slider 4 from probe 103, namely that the bottom portion 6 should be able to maintain its grip on probe 103.

When probe 103 moves towards the centre of container 100, the force, which probe 103 may apply on slider 4 depends or, the engagement of the upper end 109 against the base 16 of slider. In this case, there is therefore no risk of the probe being able to disengage from seat 10.

In this case, the upper portion 20) of slider 4, which has a conical shape, tends to open, producing interference with the inner wall of the upper portion 19.

When probe 103, however, is moving from the centre of the container 100 towards its mouth, the force which probe 103 may apply on slider 4 depends on the engagement of the bottom portion 8 inside the retaining groove 104. Since the bottom portion 8 of slider 4 is deformable radially outwards, the force pulse produced as a result of passing over projection 23 could be greater than the opposing force which may be generated by the sole resistance to radial expansion of bottom portion 8 of slider 4.

It is therefore possible to design connector 1 so that the bottom portion 8 of slider 4 is situated inside the sleeve 9 when the upper portion 20 of slider 4 passes over the projection 23, as can be seen in FIG. 3b.

In this way, radial expansion of the bottom portion 8 is prevented by the presence of the sleeve 9; moreover, the conical form of the upper portion 20 of slider 4 and the projection 23 are such that, as a result of passing over the projection 23, the cone of the upper portion 20 tends to close. This reduces friction with the inner wall of the upper portion 19 and the axial force which opposes longitudinal sliding of slider 4 and, consequently, also the axial force which tends to open the bottom portion 8.

In other words, the longitudinal distance between second abutment surface 18 and sixth abutment surface 28 may be advantageously greater than the longitudinal extension of the bottom portion 8 and less than the longitudinal distance between the first abutment surface 17 and third abutment surface 25.

Main body 3 and slider 4 may be both made of a single piece of polymer material, preferably by means of moulding.

Obviously a person skilled in the art, in order to satisfy contingent and specific requirements, may make numerous modifications and variations to the configurations described above, all of which are contained, moreover, within the scope of protection of the invention as defined by the following claims.

Claims

1. Connector able to be mounted on the open end of the neck of a bottle, the connector having a main longitudinal axis X-X and comprising: a main body, which comprises constraining means for constraining the connector to the container and a sleeve able to connect the inside of the container to the external environment;a slider which is slidably inserted in the sleeve and is able to love longitudinally between a closed bottom position, where the slider does not allow liquid to flow out from the container, and an open upper position, where the slider allows liquid to flow out from the container; the slider defining internally a seat able to receive a probe able to allow dispensing of the liquid;the slider further comprising:a central portion able to be guided at least partially by the sleeve;a bottom portion, protruding from the sleeve towards the outside of the container when the slider is in the bottom closed position, and comprising a plurality of longitudinally elongated parts, which, when the slider Is in the bottom closed position, reversibly engage with a corresponding engaging portion formed in the probe by expanding elastically in a radial direction with respect to the longitudinal axis X-X,wherein the connector further comprises an upper portion having a conical shape terminating in an end having the outer diameter d4 such as to engage, with slight interference, with the upper portion of the main body;the main body having, in the vicinity of its upper end, a circumferential projection projecting towards the inside of main body and with an inner diameter d5, the connector being such that when the upper portion of the slider passes over the projection, the bottom portion of the slider is situated inside the sleeve.

2. Connector according to claim 1, in which the longitudinally elongated parts each comprise a tooth.

3. Connector according to claim 1, in which the main body comprises: a sleeve with an inner diameter d1;an upper portion having an inner diameter d3>d1;the sleeve being longitudinally closer to the mouth of the container than the upper portion, when the connector is fixed to the container;the upper portion comprising a circumferential projection projecting towards the, inside of the main body and having a height h such that h<d5−d3/2.

4. Connector according to claim 1, in which the slider comprises: a central portion with an outer diameter d2;an upper portion having an outer diameter d4>d2;the central portion being longitudinally closer to the mouth of the container than the upper portion, when the connector is fixed to the container and the slider is in the bottom closed position.

5. Connector according to claim 4, wherein the inner diameter d1 of the sleeve is such to provide a liquid-tight seal when the sleeve is engaged with the outer surface of the slider or with the central portion of the slider or with the outer surface of the channel of the probe.

6. Connector according to claims 3 and 4, in which d1 is substantially equal to d3, and d2 is substantially equal to d4.

7. Connector according to claim 1, the slider comprising a generally flat base between its central and bottom portions.