IT8985695A1 - DISPENSER DEVICE FOR LIQUIDS - Google Patents

Description

Description of the patent for industrial invention entitled "DOSING DEVICE FOR LIQUIDS".

SUMMARY

According to the invention, a metering device is provided which comprises an essentially tubular external body (10), a sliding metering element (20) inserted inside the external body (10), a dispensing duct (30) coaxial with the interior of the external body (13), a pre-metering chamber (40) for the liquid located between the internal surface (11) of the external body (10) and the external surface (32) of the delivery duct. 'dosing element (20) and the pre-dosing chamber (40) when the device is delivering the' selected dose and there takes place by hydraulic thrust on the sliding metering element as soon as the container tilts downwards beyond the horizontal line.

DESCRIPTION

The invention relates to a dosing device for liquids to be applied in containers, for example for dosing detergent liquids, oils or chemical products in general which must be used at predetermined doses. The trend development of the chemical industry especially in the detergent sector, and? that of providing containers equipped with dispensers in order to optimize the performance of the product contained therein and also in order to avoid uncontrolled use of the product which could first of all lead to worse results than those obtainable with a regulated dose and secondly which would also lead to ecological problems. For this reason, containers for liquids equipped with liquid dosing devices are increasingly widespread.

Known dosing devices consist of dispensers equipped with channels inside which a sphere flows which, immersed in the liquid, exhibits a certain inertia to movement and when the container is overturned, after a certain obligatory path, blocks the outflow of the liquid by obstructing the hole. disbursement.

One of the drawbacks deriving from the use of similar devices is? that the spheres used, to optimize their performance, must vary their weight according to the density of the liquid to be dosed. In fact, with a rather dense liquid such as that of a concentrated liquid detergent, a very heavy sphere must be used to prevent it from remaining in suspension for a prolonged or indefinite time in the liquid itself. Naturally these types of dispensers suffer from inaccuracy, as the speed of the ball in closing also depends on the head of the liquid above it.

Other types of dosers are essentially formed by bodies consisting of a dosing chamber usually with annular development into which the liquid to be dosed enters from the bottom when the container is overturned, and by a further collection chamber for the dosed liquid which fills when the container comes back straight. The liquid is dispensed when the container is overturned again, in which case the pre-dosed liquid is dispensed and the new dosage is obtained for the entry of new liquid into the dosing chamber.

The main drawback of these devices consists in the fact that good dosing precision is obtained only when one quickly passes from the vertical position to the inverted position, always vertical, while obtaining results that are sometimes disappointing or even in contrast with the desired objectives. reach when the position of the container is not perfectly vertical: in fact, in some cases, the aforementioned dispensers deliver continuously since? a continuous flow of liquid is established between the pre-dosing chamber and the dispensing chamber.

The object of the invention is that of realizing a dosing device for liquids which overcomes the aforementioned drawbacks.

first of all we want to ensure that the dosing device works correctly without having to overturn the container in a completely vertical position.

We also want to avoid that, despite the not quite vertical position, but a little more inclined than the horizontal position, the dosing device is able to guarantee the pre-dosing and the dispensing of the liquid already? dosed correctly and without variations in subsequent dosages.

Furthermore, it is desired to realize a dispenser with few elements preferably made of molded plastic material so that the cost of the dispenser is extremely low. All the purposes mentioned above and others which will be better highlighted hereinafter are achieved by the realization of a metering device for liquids to be mounted hermetically in an opening of a container which, in accordance with the content of the first claim, comprises:

- a tubular outer body having a neck connected tightly in the opening of a container, having one or more holes in proximity to it; of said neck for the inlet of the liquid to be dosed and with an open bottom which houses a sliding element inserted on said external body;

- a tubular-shaped metering element slidably inserted into the opening of the bottom of the external body and having a closed bottom, said element being able to collect the dose of the liquid to be dispensed;

an essentially cylindrical-shaped dispensing duct having a crown which is coupled to the inside of the neck of the external body and having a central tube whose lower edge is suitable for being closed by the free edge of the sliding tubular element;

- a liquid pre-metering chamber formed by the internal surface of the external body and by the external surface of the delivery duct,

said device being characterized in that the metering element and the lower edge of the dispensing duct are in a reciprocal position so as to create an opening for the passage of the liquid from the pre-metering chamber to the metering element only when the metering device is in substantially vertical position, said passage closing by the contact in support of the metering element on the extreme edge of the delivery duct when the device tilts downwards beyond the horizontal position.

Advantageously, according to the invention, the metering element, which functions as a collection chamber for the metered liquid, can be slide towards the delivery duct being guided on the final tubular part of the external body of the dispenser so that the surface of said metering element rests on the edge of the tubular element of the dispensing duct when the container tilts downwards beyond the horizontal line, ensuring a seal between the two component parts of the dispenser and so as to consequently exclude any communication with the pre-dosing chamber. This contact between the delivery duct and the tubular element that collects the pre-dosed liquid occurs, as mentioned, as soon as the dispenser is tilted beyond the horizontal position and this is due to the hydraulic thrust of the liquid that surrounds it inside the container. Since ?? the intensity of this thrust also depends on the viscosity. of the liquid, the invention provides that for dense liquids the delivery duct has such a shape as to offer greater surface to the action of the liquid pressure so as to ensure the thrust necessary for the metering element to rest on the edge of the delivery duct .

Further characteristics and particularities of the invention will be better highlighted in two preferred forms of

execution of the invention given as an indication but not of limitation and illustrated in the attached drawing tables, where:

- fig. 1 shows a view of a container which has the metering device of the invention;

- fig. 2 shows in section the metering device of the invention inserted in a container;

- fig. 3 shows in section? the device of the invention during the first step of loading the dose of liquid; - fig. 4 shows in section the device of the invention during the second phase of transferring the pre-dosed liquid into the collection chamber;

- fig. 5 shows in section the device of the invention during the delivery of the dose and the loading of a new dose into the dosing chamber;

- fig. 6 shows in section a constructive variant of the device of the invention.

With reference to the aforementioned figures, it can be observed that the metering device of the invention is formed by an external body indicated as a whole with 10, by a metering element of tubular shape, sliding inside the external body indicated as a whole by 20 and by a delivery duct also inserted on the external body indicated as a whole with 30.

The external body 10 in the case of the example is substantially cylindrical in shape. It has a surface 11 and at the top a neck 13 which is connected tightly to the hole of the liquid container, so as to prevent the liquid from escaping during dispensing operations.

On the cylindrical surface 11 of the external body 10 there are a series of holes indicated with 14 equally distributed and arranged in proximity to the neck 13 of the external body. These holes, we will see, are the inlets for the liquid that is loaded into the dosing chamber.

At the bottom, on the bottom, the external body 10 has an opening 15 on which the metering element 20 slides on the internal walls of the body 10 is housed. The tubular part 11 of the body 10 has a preferably but not necessarily cylindrical shape as it is sufficient. that the shape of the part 11 has the same geometry as the shape of the metering element 20 so that it can slide on the walls of the body 12 and be guided by them.

The metering element 20 is substantially a double-diameter cylinder and precisely has a lower part 22 equipped with a bottom 21 and with a smaller diameter than the upper part 24 which is? slidably inserted on the internal wall 12 of the body 10.

The two cylindrical parts 22 and 24 are connected by a conical surface 23 which rests on the inclined edge 16 present on the bottom of the external body 10.

On the conical surface 23 there are a series of holes 25 which we will see have the function of overflow spillways so as to always ensure a constant dosage.

The body 30 is the duct for dispensing the dosed liquid, has an essentially cylindrical shape and has a crown 31 which is coupled to the inside of the edge of the external body and has a central tubular body 32 open on the bottom concentric to said crown and which is 'the actual delivery duct.

Since? ' the external diameter of the delivery tube 32 is smaller than the internal diameter of the external body 10 in the zone 11, due to the difference between the two diameters 11 and 32, an annular space 40 is created which constitutes the actual dosing chamber for the liquid 51 present in the container 50. The delivery duct 30 then has a seal 33 which is removed when the package is opened and the container is ready for use.

The operation of the dispenser of the invention takes place as follows.

With reference to fig. 3, once the container 50 has been turned downwards, the liquid 51 contained therein passes through the holes 14 in the annular chamber 40. The level of the liquid rises until it reaches the conical wall 23, but it cannot? pass into the delivery duct 30 since the passage is obstructed by the conical surface 23 of the metering element 20 which rests on the edge 34 of the delivery duct 30.

When the container 50 is again placed in an upright position, as can be seen in FIG. 4, the liquid contained in the metering chamber 40 is transferred into the metering element 20 since said tubular element by gravity descends downwards, leaning with the conical surface 23 on the inclined edge 16 belonging to the external body 10 and therefore creates the annular opening 41 through which the metered liquid flows.

The holes 25 present on the conical surface 23 during the pouring of the liquid from the metering chamber 40 inside 26 of the metering element 20 allow a quantity to pass. of essentially negligible liquid, quantity? which returns inside the container 50. Since, however, the volume of the metering chamber 40 is greater than the volume 26 of the metering element 20, the liquid transferred from the metering chamber to the metering element is always in excess, and therefore, once the transfer has taken place from the holes 25, the excess liquid overflows and touches the conical part 23 so that the the holes 25 become overflow elements which guarantee a constant level of the pre-dosed liquid.

In the subsequent actual dispensing phase which is represented in fig. 5, it is observed that the liquid contained inside the tubular element 20 is discharged through the delivery duct 30 and exits outside. With the container in this position it happens that, both by gravity and by the pressure exerted by the liquid 51 on the external walls of the tubular element 20, said tubular element rests again with the conical surface 23 on the edge 34 of the delivery duct, closing the annular passage 41 between the metering chamber 40 and the dispensing duct 30.

Thus the new liquid 51 recalled through the holes 14 in the chamber 40 is not poured out through the delivery duct but remains only in the dosing chamber 40. All this? it happens precisely because the sealing between the tubular element 20 and the delivery duct 30 is ensured. This condition takes place as soon as the container 50 is in a slightly inclined position with respect to the horizontal line. In fact, it is sufficient that the horizontal line is exceeded even slightly for the hydraulic thrust exerted on the external walls of the metering element 20 to cause said tubular element to close the delivery duct as mentioned above.

Figures 2, 3, 4 and 5 have shown up to now a particular form of metering device in which the metering element proper indicated with 20 had a conical surface 23 and was slidably guided inside the external element 10.

The shape of the dispenser 20 with conical surface 23 is in fact especially suited to be used for dosing liquids with high density. significant, since in fact the surface 23 is added to the bottom surface 21 as regards the thrust that the liquid 51 contained in the container 50 exerts on the dispenser 20. In the case that it is necessary to dose liquids with viscosity instead. low or with a significantly high aqueous component, it is not necessary for the bottom surface 21 on which the hydraulic thrust is carried out to be further increased with the addition of the conical surface 23 as in the example of fig. 2. For this reason in fig. 6 a variant is proposed to the metering device of the invention in which the external element 10 has an open cylindrical part 17 on the bottom which keeps the metering element 20 in the guide which is essentially constituted by a cylindrical part 22 and by a part upper conical 26 which interacts with the extreme edge 34 of the metering element 30. The edge 27 of the surface 26 of the metering device 20, on the other hand, acts as an overflow level as the liquid in excess of the capacity of the metering device 20 overflows from said edge 27 and exits from the holes 28 now belonging to the external body 10 and present in the connecting surface 19 between the two cylindrical surfaces 11 and 22.

The possibility? discharge of the liquid in overflowing the edge 27 through the holes 28 is made possible by the fact that the dispenser 20 rests on the inclined bottom of the surface 19 by means of projections 29 which do not constitute a continuous edge and therefore allow the liquid to pass.

In the case of fig. 7, the body 20 has four longitudinal grooves 35 which accomplish the purpose. In the case of the examples shown in the figures, the dispenser is shown with a lid 60 which is molded together with the external body 10 to complete the dispenser itself.

Claims (6)

CLAIMS 1) Dosing device for liquids inserted in an opening of a container (50), comprising: - an external tubular body (10) having a neck (13) connected tightly in the opening of a container, having one or more holes (14) in proximity of said neck for the inlet of the liquid to be dosed and with an open bottom (15) which receives a sliding metering element inserted on said external body; - a tubular-shaped metering element (20) slidably inserted into the opening (15) of the bottom of the external body (10) and having a closed bottom (21), said element being able to collect the dose of the liquid to be dispensed; - an essentially cylindrical-shaped delivery duct (30) having a crown (31) which is coupled to the inside of the neck of the external body and having a central tube (32) whose lower edge (34) is suitable to be closed by the surface of the sliding tubular element; - a pre-metering chamber (40) for the liquid located between the internal surface (11) of the external body (10) and the external surface (32) of the delivery duct, said device being characterized in that the metering element (20) and the lower edge (34) of the delivery duct are in such a position as to create an opening (41) for the passage of the liquid from the pre-dosing chamber (40) to the 'metering element (20) only when the metering device is in a substantially vertical position, said passage being closed due to the contact of the metering element resting on the outer edge (34) of the dispensing duct when the device tilts downwards beyond the horizontal position. 2) Metering device according to claim 1), characterized in that the metering element (20) has a cylindrical lower part (22) equipped with a bottom (21), an upper part (24) also cylindrical with an increased diameter inserted sliding on the external wall (12) of the body (10), the two cylindrical parts being connected by a truncated conical surface (23) which rests on the inclined edge (16) present on the bottom of the external lid (10) when the container (50 ) tilts down beyond the horizontal position. 3) Metering device according to claim 2), characterized in that the conical area (23) of the metering element (20) has a series of holes (25) through which the liquid exceeding the predetermined dose is discharged. 4) Metering device according to claim 1), characterized in that the metering element (20) is formed by a lower cylindrical part (22) equipped with a bottom (21) ending with a conical upper part (26) which rests on the edge (34) of the metering element when the container of the device tilts downward beyond the horizontal line. 5) Metering device according to claim 4), characterized by the fact that the external body (10) has a cylindrical bottom (17) with a smaller diameter than the upper part (11) where the two parts with different diameters are connected by means of an area with essentially conical shape (19) presenting a series of holes (28) which discharge the overflowing liquid from the edge (27) of the upper part of the metering element (20). 6) Metering device according to claim 5), characterized in that the upper edge (27) with an inverted conical profile of the metering element (20) has a series of protuberances (29) at the bottom, suitable for establishing a passage opening for the liquid overflowing beyond the selected dose.