FR2538103A1 - Device for measuring volumes of liquids - Google Patents

Abstract

The device measures volumes of liquids, particularly for delivering predetermined amounts of water in espresso coffee machines. It consists of a wheel with blades 14 placed in the path taken by the water and driven in rotation by it. One or more built-on magnetic components 28, 30 move with the wheel 14. At least one proximity detector 52 is fixed in such a way as to detect the passage of the built-on components 28, 30 and to send pulses to a central processing unit which counts the pulses and controls the amount of liquid. The proximity detector is based on the Hall effect. Usable especially in espresso coffee-making machines.

Description

 The present invention relates to a volumetric meter for liquids, in particular for dosing predetermined quantities of water, in "express" coffee machines intended especially for bars for the preparation of coffee in a cup, said meter being of the type comprising a wheel with paddles placed on the liquid supply path and driven in rotation by the latter, one or more inserts9 in particular magnetic, movable with the wheel, and at least one proximity sensor fixedly placed in a position suitable for detecting the passage of attachments and for sending pulses to a central unit for calculating said pulses and for controlling the metering.

 It has already been proposed to use, for the metering of the quantity of water which must be supplied at once to the express coffee machines, volumetric meters with paddle wheels, placed along the water course and suitable for detecting the amount of water passing through the meter to counter the shutdown of the water supply when a predetermined dose has been reached. In practice, these volumetric meters are formed by a paddle wheel, housed in a seat, which is traversed by the feed water through a nozzle. The wheel comprises one or more inserts acting on a proximity detector, which , in turn, transmits to the aforesaid central computer unit and controls the detected pulses, which are proportional to predetermined fractions of the wheel revolution.

In order for this arrangement to function safely, it is necessary that two conditions are satisfied, namely: that the wheel is free to rotate with the lowest possible inertia and friction and that, moreover, the means for detecting the wheel rotation act safely under the intended operating conditions, and durably
The first condition is satisfied if one uses means of detection of the turns of the wheel which act without contact, while, for the second condition, attempts at solution have been made either by means of photodiode and phototransitor systems or by sys hermetic inert gas relay relay ('return' relay).

 The first of these systems is insecure because the surfaces concerned can become soiled and, consequently, can interfere with the correct transmission of rays or light pulses for commands.

 The "reed" relay system being the most commonly used, it is preferable to the previous one, but it also has drawbacks due to the fact that its safety is limited to frequencies and, consequently, to rotation speeds of the wheel, significantly reduced. In addition, it requires, for its drive, the present of magnetic inserts which are capable of creating a relatively large magnetic field and whose dimensions and, consequently, the weights are not negligible compared to the weight of the wheel. This fact ang-- slows the inertia of the wheel and, consequently, reduces the sensitivity of the system to the lowest flow rates. Finally, the "reed" relay is sensitive to the temperatures normally involved and it must besides positioned with thermal insulation. - Mique with respect to the wheel, which creates later problems either of achieving such insulation, or of adjusting the exact position of the relay relative to the magnetic parts of the wheel.

 This being the case, the main object of the present invention is to produce a volumetric counter of the aforementioned type which makes it possible to eliminate the drawbacks of known embodiments and which is capable of giving better safety, a possibility of operating at higher frequencies and good sensitivity to the temperatures involved for the intended applications compared to systems comprising "reed" relays.

 The volumetric meter for liquids, in particular for dosing predetermined quantities of water in express coffee machines, is characterized in that it comprises: a paddle wheel placed on the liquid supply path and rotated by it; one or more magnetic inserts, movable with the wheel, and at least one proximity detector fixedly placed in a position suitable for detecting the passage of the inserts and for sending pulses to a central pulse calculation and control unit metering, said proximity detector being a Hall effect detector.

The Hall effect is well known in the art and will not be described here. I1 suffices to know that this type of detector is remarkably more sensitive than the "reed" relay and that it therefore only requires magneto ~ smaller and lighter parts, thus making it possible to produce a paddle wheel with less inertia. In addition, the Hall effect detector is safer because it has no moving parts, it can operate at higher frequencies and it is not sensitive to the temperatures involved because it can be positioned very easily without it either be necessary to provide thermal insulation and without the difficulty of adjusting the magnetic parts on said wheel
An exemplary embodiment of the invention will now be described with reference to the accompanying drawings, in which
FIG. 1 is a view in axial section of the part of the volumetric counter comprising the paddle wheel,
Fig 2 is a plan view, partially in section, of the counter part illustrated in Fig 1,
Fig 3 is an axial section of the second part of the same counter, intended to close at the top the part shown in fig 1 and 2,
FIG. 4 is a plan view of the part of the counter in FIG. 3, and
Fig 5 is an axial section of the counter with the two parts assembled together.

Referring first to FIGS. 1- and 2, the counter which is illustrated therein comprises a body 10, for example of parallelepipedal shape having a cavity 12 of cylindrical shape, in which is housed a paddle wheel tes 14 mounted so as to be able to rotate freely with very low friction on an axis 16. The vanes of the wheel 14 are rotated by a liquid, in particular by water, which enters the body 10 along the arrow X, through a fitting 18 and a nozzle 20 opening onto said pallets. The water leaves the conduit 22 and the connector 24, according to the arrow Y
The wheel 14 has a hub 26 on which two added magnetic parts 28, 30 are mounted in a known manner, which are similar to those of known "reed" relay systems, but which can advantageously be smaller and, consequently, more light because you only need a less important magnetic field. The body 10 finally comprises tapped holes 32 to allow its tight assembly with the upper body, designated as a whole by 34, for closing the cavity 12, shown in FIGS. 3 and 4.

 This body 34 comprises a plate 36 surmounting a cylindrical protuberance 38 which can penetrate into the cylindrical cavity ia of the upper body 10. The lower surface 42 of the plate 36 is supported on the upper body surface 10 and the plate 36 is provided with holes 44 for the passage of screws 46- (fig 5) for fixing the two bodies 10 and 34; the hub 26 of the wheel 14 is housed without contact in a central cavity 40 of the protuberance 3S In its upper part the body 3 has a recess 48 of suitable shape, in which one can position, insert and maintain a plate 50 carrying a circuit -print and a Hall effect detector 52, well known per se, which is connected, in a known manner, to said printed circuit and which, in turn, sends the desired pulses to the control unit through one or more terminals 54- .

 The shape of the recess 48 and the fact of having provided a step 56 make it possible to position the plate 50 and, consequently, the detector 52 relatively to the body 34, while the mechanical parts cooperating between the latter and the body 10 make it possible to position the detector 52 exactly with respect to the wheel 14 and, in particular, to the magnetic parts 28, 30 of the latter, so that there is no need for adjustments in the reciprocal positions once the two bodies 10 and 34 are assembled and fixed to each other by means of the screws 46, as shown in fig 5.

Claims (2)

RRVESZDICATIONS  1. Volumetric meter for liquids, in particular for dosing predetermined quantities of water in express coffee machines, characterized in that it comprises, in combination: a paddle wheel (14) placed on the supply path liquid and driven in rotation by it; one or more magnetic inserts (28,) 0) movable with the wheel (14) and at least one proximity detector (52) fixedly placed in a position suitable for detecting the passage of the inserts (28, 30) and transmitting pulses to a central pulse calculation and dosing control, said proximity detector (52) being a Hall effect detector.  2. Counter according to claim 1, characterized in that said Hall effect detector (52) is mounted on a printed circuit board (50) and that the wheel housing comprises, at its external part, a seat (42) for the exact positioning of the plate (50) and the detector (52) relative to the clamp, or to the attached parts of the wheel C 14).