FR2921483A1 - DISTRIBUTION DRAWER FOR MEMBRANE GAS METER WITH ROTARY DISTRIBUTION DRIVE. - Google Patents

Abstract

The present invention relates to a rotary distribution drive diaphragm gas meter comprising a plurality of measuring chambers, and a distribution slide (2) rotatably mounted about an axis of rotation on the upper surface of a cover (1) of distribution in which are formed several openings which are each connected to a measuring chamber, the distribution drawer (2) allowing the gas to enter and exit alternately measuring chambers during its rotational movement about the axis of rotation, and the dispensing cover (1) comprising an external sealing ring (15a), substantially concentric with respect to the axis of rotation, on the upper plane edge of which slides the external contact surface (25) of the drawer dispenser forming a sliding interface (28) between the outer sealing ring (15a) and the outer contact surface (25), characterized in that the gas meter comprises in a protective skirt (30) sealingly surrounding the entire outer contact surface (25) and having a peripheral wall extending towards the cover (1) so as to cover said sliding interface (28) .

Description

The present invention relates to the field of gas meters with deformable membranes comprising a plurality of measuring chambers, and a distribution element or spool mounted rotatably about an axis of rotation on a spindle. the upper surface of a lid or a dispensing box in which are formed several openings which are each connected to a measuring chamber, the dispensing element allowing the gas to enter and exit alternately measuring chambers at during its rotational movement around the axis of rotation. The rotational drive of the dispensing element is performed in synchronism with the movement of the membranes by means of a transmission device comprising a certain number of levers, and a part called crank. During the alternating translation movements of the membranes, the levers transform these translational movements into a rotational movement printed on the crank. The crank then transmits its rotational movement on the one hand to the distribution element, and on the other hand, to a series of gears which themselves operate a volume totalizer.

Reference can be made in particular to EP 0128 838 to understand the operating principle of such a rotary distribution drive membrane gas meter. We will focus more particularly later on the cooperation of the element or dispensing drawer with the cover or distribution box.

FIGS. 1a-1d illustrate the distribution box and the distribution box used in the meter marketed by the Applicant under the registered trademark GALLUS 2000. More specifically, FIG. 1a illustrates an assembled perspective of a distribution box 1 and of FIG. a distribution drawer 2, FIG. 1b shows a view from above of the distribution box 1 only, FIG. 1c represents a bottom view of the distribution drawer 2 alone, and FIG. 1d represents a partial schematic sectional view of the distribution box 1 assembled with the distribution drawer 2.

As can be seen more particularly in FIGS. 1a, 1b and 1d, the cover or distribution box 1 comprises a first external circular ring 15a externally defining four openings 10 to 13 each having the shape of a quarter sector of a circle, distributed concentrically and separated by radial strips 14 sealing. Each opening 10 to 13 is able to communicate with a corresponding measuring chamber of the meter to allow admission of the gas into said measuring chamber. The lid or dispensing box 1 also comprises a second circular ring 15b, concentric with the first ring 15a, but of smaller diameter. This second circular ring defines, with three other radial bars 16, three other openings intended to be placed in communication with a communication channel of the meter allowing the evacuation of the gas. Finally, a third internal circular ring 15c, concentric with the first two, delimits the central opening 17 centered on the axis of rotation and intended to receive in particular the hub of a crank (not shown) for driving in rotation the distribution drawer 2 around this axis of rotation. As can be seen more particularly in FIGS. 1a, 1c and 1d, the distribution element or drawer 2 comprises circular sectors arranged so as to form an orifice 20 and a convex zone 21 separated by two plane zones 22, 23, each area covering an angle of about 90 °. The drawer 2 also comprises a central recessed area 24 forming a bearing intended to be placed concentrically facing the central opening 17 of the dispensing cover 1. The orifice 20 defined by the drawer 2 is intended to successively put each opening 10 to 13 in communication with a measuring chamber for penetrating the gas. The convex zone 21 delimiting an interior space and the recessed central zone 24 are intended to put in communication successively the measurement chambers with the exit. The two planar zones 22, 23 successively close off the remaining openings.

Thus, in operation, the drawer 2, and more precisely the three concentric surfaces 25, 26 and 27 which are in contact with the upper plane edge respectively of the first, second and third ring 15a, 15b, 15c of the distribution cover 1, slide on the surface of this lid, and more precisely on the upper edge of each of said crowns. Furthermore, it should be noted that, in the case of the meter marketed under the trademark GALLUS 2000, the inner sealing ring 15c is made necessary by the fact that the rotational drive shaft passes through the distribution spool. Other solutions exist, for example that described in document FR 2 778 981, in which no axis passes through the distribution drawer, so that the lid can have only two rings 15a and 15b. In all cases, the seal between the spool 2 and the lid 1 is ensured by the weight of the spool 2 alone and by the gas pressure difference in the spool and outside thereof. To obtain a good seal, and therefore a good accuracy of counting the volume of gas used, it is necessary that the surfaces in contact on the one hand, the drawer and on the other hand, the lid are as smooth as possible. However, the gas distribution networks can be polluted by contaminants originating, for example, from glycol-type fatty agents that may be present in the gas distributors, or particles such as iron filings or soil. from the pipes. These contaminants are deposited mainly at the sliding interface 28, as shown in FIG. 1d, situated between the flat top edge of the first outer circular ring 15a and the second one. outer concentric surface 25, thus increasing the coefficient of friction during rotation of the drawer on the lid. This results in an alteration of the counting accuracy of the meter.

More particularly, the flat upper edge of the first outer circular ring 15a cooperates with the outer concentric surface 25 at a contact area 28, as shown in Figure 1d. The present invention aims to overcome the aforementioned drawbacks including providing a particular geometry distribution drawer. The solution according to the present invention is to provide a rotary distribution drive membrane gas meter comprising a plurality of measuring chambers, and a distribution spool mounted rotatably about an axis of rotation on the upper surface of a dispensing cover. in which are provided several openings which are each connected to a measuring chamber, the distribution valve allowing the gas to enter and exit alternately measurement chambers during its rotational movement about the axis of rotation, and the dispensing cover comprising an outer sealing ring, substantially concentric with respect to the axis of rotation, on the upper plane edge of which slides the external contact surface of the distribution spool forming a sliding interface between the sealing ring external and external contact surface, characterized in that the gas meter further comprises a skirt of pro sealingly surrounding the entire periphery of the outer contact surface and having a peripheral wall extending towards the cover so as to cover said slip interface. Other features and advantages of the present invention will emerge in the light of the description of a non-limiting embodiment of a dispensing drawer, made with reference to the annotated figures, in which: FIG. 1a illustrates an assembled perspective a dispensing spool and a dispensing cover for a gas meter of the state of the art; - Figure 1b shows a top view of the metering distribution cover of the state of the art; - Figure 1c shows a bottom view of the dispenser of the counter of the state of the art; - Figure 1d is a partial schematic sectional view of a distribution valve assembled with a distribution cover for a gas meter 5 of the state of the art; - Figure 2 shows a partial schematic sectional view of a distribution valve assembled with a distribution cover for a gas meter according to the present invention; FIG. 3 represents a diagrammatic perspective bottom view of the distribution drawer 10 as partially shown in FIG. 2. FIGS. 1a to 1d have already been described above, and for ease of understanding, the elements common to the present invention and the prior art have the same references. Figures 2 and 3 illustrate different views of an embodiment according to the present invention of a gas meter having a dispensing lid 1 and a dispensing drawer 2. The dispensing drawer 2 has a protective skirt 30 forming an integral part of the dispensing drawer 2. In other words, the protective skirt 30 forms with the drawer 2 of distribution one and the same piece. The dispensing drawers of the prior art are typically obtained by a method well known to those skilled in the art, such as for example the hot pressing of a thermosetting polymer in a mold of appropriate shape. Once said thermoset polymer (or crosslinked) and after demolding, the distribution drawer 2 is obtained, for example identical or similar to that shown in Figures la to Id. However, it is necessary to perform an additional step in order to be able to use the dispensing spool in a deformable membrane gas meter. 6

This additional step consists of honing the distribution drawer 2 at its contact surfaces 25, 26, 27 to obtain the necessary flatness (smooth surface) to a sufficient seal between the distribution cover 1 and the distribution drawer 2.

In the embodiment shown in Figures 2 and 3, it is no longer necessary to carry out this additional burn-in step on the distribution drawer 2. Indeed, the distribution drawer 2 together with the protective skirt 30 are obtained by injection-molding a thermoplastic polymer into a mold of appropriate shape. Prior to the injection-molding step, the surfaces of the mold intended to be in contact with the contact surfaces 25, 26, 27 of said drawer are deformed so as to obtain, after demolding, a distribution drawer with the necessary flatness. (Smooth surface) to a sufficient seal between the dispensing lid 1 and the dispensing drawer 2. For example, the mold is machined by electroerosion prior to the injection-molding step. Therefore, the dispensing spool 2 together with the skirt 30 (injected-molded thermoplastic polymer part) are thus made by advantageously avoiding any further step of running-in. In addition, the integration of the protective skirt in the distribution drawer ensures that said skirt tightly surrounds all the periphery of the outer contact surface 25 of said drawer. An alternative embodiment not shown in accordance with the present invention is to provide not a protection skirt integrated in the drawer, but a protective skirt in the form of an additional piece that is fixed on the dispensing drawer. In this case, it is necessary to provide a fastening which allows the protective skirt to surround all around the outer contact surface 25 of the distribution drawer in a sealed manner.

Thus, the protective skirt can be advantageously adapted to the distribution drawers according to the prior art described above, for example identical or similar to those of Figures la to 1 d. Of course, the dispensing spool according to the embodiment variant not shown can also be obtained by a method of injection-molding a thermoplastic polymer in a previously eroded mold of appropriate shape, as described above. After obtaining the dispensing spool by one or other of these methods, the protective skirt is fixed, for example by gluing, wrapping or screwing, around the outer contact surface 25 of the distribution drawer 2 . Thus, the protective skirt tightly surrounds all the periphery of the external contact surface 25 of the distribution drawer 2, as in the embodiment described in Figures 2 and 3.

The peripheral wall of the protective skirt obtained according to the two embodiments described above extends in the direction of the cover 1 so as to cover the interface 28 of sliding. This peripheral wall is preferably concentric with respect to the axis of rotation, and may be of cylindrical shape (see FIGS. 2 and 3) when it extends parallel to the axis of rotation, or of frustoconical shape. The protective skirt thus advantageously makes it possible to limit or even avoid any external contamination at the level of the sliding interface 28.

Claims (4)

1. Diaphragm gas meter with rotary distribution drive comprising a plurality of measuring chambers, and a distribution spool (2) rotatably mounted about an axis of rotation on the upper surface of a dispensing lid (1) in which several openings are provided which are each connected to a measuring chamber, the distribution slide (2) allowing the gas to enter and exit alternately measurement chambers during its rotational movement about the axis of rotation, and the dispensing cover (1) having an outer sealing ring (15a), substantially concentric with respect to the axis of rotation, on the upper plane edge of which slides the external contact surface (25) of the distribution spool forming an interface (28) for sliding between the outer sealing ring (15a) and the external contact surface (25), characterized in that the gas meter further comprises a protective skirt (30) and sealingly surrounding the outer contact surface (25) and having a peripheral wall extending towards the cover (1) so as to cover said sliding interface (28). 2. Membrane gas meter according to claim 1, characterized in that the peripheral wall of the protective skirt (30) extends parallel to the axis of rotation. Diaphragm gas meter according to claim 1 or 2, characterized in that the protective skirt (30) is an integral part of the distribution drawer (2). 4. Diaphragm gas meter according to claim 3, characterized in that the distribution spool together with the protective skirt is an injected-molded thermoplastic polymer part. . Diaphragm gas meter according to claim 1 or 2, characterized in that the protective skirt is an additional part which is fixed on the distribution drawer (2). 6. Diaphragm gas meter according to claim 5, characterized in that the protective skirt is fixed by gluing, wrapping or screwing, on the periphery of the outer contact surface (25) of the spool (2) distribution.