RU2468339C2 - Distribution cap for diaphragm-type gas counter with rotary distribution drive - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: gas counter has several measurement chambers and a distribution valve (2) which can rotate about a fixed axis of rotation on the top surface of the distribution cap (1), representing several openings (10-12), each linked to one measurement chamber. That distribution valve (2) enables alternate inlet of gas into the measurement chambers and outlet of gas from these chambers when the distribution valve rotates about the axis of rotation, and the distribution cap (1) has at least two seal crowns (15a, 15b), lying essentially concentrically about the fixed axis of rotation, on the top flat edge of which contact surfaces (25, 26) of the distribution valve slide. The top flat edge (15d) of at least one of the seal crowns is not circular and is such that any point on the contact surface lying opposite that flat top edge (15d), having a shape which is not circular, is without mechanical contact with that edge at least once in a revolution. The advantage is assisting removal of contaminants.

EFFECT: high accuracy of counting gas volume, as well as removal of any contaminant.

3 cl, 5 dwg

Description

The present invention relates to the field of gas meters with deformable membranes containing several measuring chambers and a distribution element or spool mounted for rotation relative to a fixed axis of rotation on the upper surface of the cover or distribution block, in which several holes are made, each of which is associated with one measuring camera, and this distribution element in an alternating manner allows gas to enter the said measuring chamber s and its release of these chambers during the rotational movement of the distributor element relative to its axis of rotation.

The distribution element is brought into rotational motion synchronously with the movement of the membranes due to the transmission device containing a number of levers, as well as a part called a crank. In the process of carrying out alternating translational movements of the membranes, said levers transform these translational movements into rotational motion transmitted to the crank. In this case, the crank transfers its rotational movement, on the one hand, to the distribution element, and on the other hand, to the set of gears, which, in turn, drive the integrating volume counter.

Reference may be made, in particular, to patent document EP 0128838 in order to understand the principle of operation of such a membrane gas meter with bringing the distribution mechanism into rotational motion.

Further, particular attention will be paid to the interaction of said distribution element or spool with a cover or distribution unit.

Figures 1a to 1c illustrate a distribution element and a distribution unit used in the construction of a gas meter distributed on the market by the Applicant under the registered trademark GALLUS 2000. More specifically, Fig. 1a shows a perspective view of the assembled position of the distribution unit 1 and the distribution valve 2b, FIG. 1b is a top view of a distribution unit 1 alone, and FIG. 1c is a bottom view of a distribution valve 2 only.

As can be seen in more detail in Figures 1a and 1b, the cover or distribution unit 1 comprises a first outer circular crown 15a defining four holes 10 through 13 from the outside, each of which has the shape of a sector in the form of a quarter circle distributed concentrically and separated by each other from each other using radial partitions 14 sealing. Each hole from 10 to 13 has the ability to provide communication with the corresponding measuring chamber of the gas meter in order to provide gas inlet into this measuring chamber. The lid or distribution unit 1 also comprises a second circular crown 15b arranged concentrically with respect to said first crown 15a, but having a slightly smaller diameter. This second circular crown defines, together with three other radial partitions 16, three other openings designed to enter into communication with the connection channel of this gas meter and providing the possibility of gas discharge. And finally, the third inner circular rim 15c, which is concentric with respect to the first two rims, defines a central hole 17, centered on a fixed axis of rotation and intended, in particular, to accommodate a crank sleeve (not shown in the figures in the appendix), providing the possibility of bringing into rotational movement of the distributor valve 2 relative to this axis of rotation.

As can be seen in more detail in Figures 1a and 1c, the distribution element or spool 2 contains circular sectors made in such a way as to form a hole 20 and a convex zone 21, separated by two flat zones 22, 23, each of which overlapping the angular sector having a magnitude of the order of 90 °. The spool 2 also contains a central hollow zone 24, forming a bearing intended to be placed in a concentric manner against the Central hole 17 of the distribution cover 1. The hole 20, defined by the valve 2, is designed to sequentially provide communication of each of the holes 10 to 13 with the measuring chamber in order to allow gas to flow during a full revolution of the spool around its fixed axis of rotation. The convex zone 21, bounding some internal space, and the central hollow zone 24 are designed to sequentially provide communication of the measuring chambers with the output channel. In this case, two flat zones 22, 23 sequentially overlap the remaining holes.

Thus, during operation, the spool 2 and, more specifically, its three concentric surfaces 25, 26 and 27, which are in contact with the upper flat edge of the first, second and third crowns 15a, 15b, 15c of the distribution cover 1, respectively, rotate relative to a fixed axis of rotation, sliding on the surface of this cover and, more specifically, on the upper edge of each of the said crowns.

It should be noted here that in the case of a gas meter sold on the market under the trademark GALLUS 2000, the internal sealing crown 15c is necessary due to the fact that the axis of bringing into rotational movement passes through the distribution valve. There are also other technical solutions, for example, the technical solution described in patent document FR 2778981, according to which no axis passes through the distributor valve so that the cover can only contain two crowns 15a and 15b.

In any case, the tightness between the spool 2 and the cover 1 is only ensured by the dead weight of the spool 2 and by the difference in gas pressure inside and outside the spool. In order to ensure satisfactory sealing and, therefore, high accuracy in calculating the volume of gas used, it is necessary that the contact surfaces, on the one hand, the spool, and on the other hand, the covers are as smooth as possible. However, gas distribution networks may contain contaminants, such as, for example, fatty substances such as glycol, which may be present in gas distribution devices or may contain particles such as iron filings coming from pipelines. These contaminants are deposited on the contact surfaces and can thus increase the coefficient of friction during rotation of the spool on the cover. A consequence of this circumstance is a decrease in the accuracy of meter measurements.

The technical task of this invention is to offer specific geometric characteristics of the distribution cover, allowing to eliminate the above-mentioned disadvantage.

To solve this technical problem, the object of the invention is a membrane gas meter with a rotary distribution drive, comprising several measuring chambers and a distributor valve mounted for rotation relative to a fixed axis of rotation on the upper surface of the distribution cover, in which several holes are made, each of which is connected with one measuring chamber, and this distribution spool provides alternately the possibility of entry and gas into the measuring chambers and its exit from these chambers during its rotational movement relative to the axis of rotation, and the distribution cover contains at least two sealing crowns located essentially concentrically with respect to the fixed axis of rotation, on the upper flat edge of which the contact slide the surface of the distribution valve, characterized in that the upper flat edge of at least one of the sealing crowns is a non-circular shape, is determined so that any point on the contact surface that is located against this flat upper edge, which has a shape that is not round, at least once in one complete revolution, appears without mechanical contact with this edge.

Preferably, the crown, which is a flat top edge having a non-circular shape, for example an elliptical shape, is an outer crown of the largest diameter. However, a non-circular shape can be used for all crowns of the distribution cover.

In contrast to the case of the distribution cover from the prior art, in which the shape of the first, second and third rims 15a, 15b and 15c is round and exactly corresponds, thus, described when the contact surface 25, 26, 27 of the contact on the distribution valve is rotated, then that, in accordance with the invention, it is provided that any point on the contact surface that is located against the crown having a shape that is not round at least once in one full revolution the spool turned out to be without mechanical contact with this crown, helps to remove any contaminant that may be there.

The invention will be better understood from the description below, which is not a restrictive example of the implementation of the distribution cover, which provides links to the drawings, among which:

- Figa is a perspective view in the assembled state of the distribution valve and distribution cover for a gas meter in accordance with the prior art;

- Fig.1b is a top view of the distribution cover of the gas meter in accordance with the prior art;

- Fig. 1c is a bottom view of the distribution spool of a gas meter in accordance with the prior art;

- Fig. 2a is a perspective view from above of a non-restrictive example of a distribution cover in accordance with the invention;

- Fig.2b is a top view of the distribution cover shown in figa.

Figures 1a through 1c have already been described previously. To simplify the understanding of the description of the invention, the elements common between the prior art and the proposed invention are denoted by the same digital position.

The spool in accordance with a possible and non-limiting method of implementing the present invention, presented in figures 2A and 2b, contains only two crowns, namely, the first outer crown 15A and the second concentric inner crown 15b having a diameter smaller than the diameter of the first crown 15a . Thus, this crown is intended for connection with a spool (not shown in the figures given in the appendix) without an axis passing through it. As can be seen in the two figures mentioned above and in accordance with the instructions given in the present invention, the crown 15a has an upper flat edge 15d having an elliptical shape. According to this embodiment, the inner rim 15b has an upper flat edge, the shape of which remains round. However, a shape that is not round and is, for example, an ellipse, may also be provided for this inner crown.

Due to this specific shape, any point on the contact surface corresponding to the spool twice during the implementation of one full revolution of this spool relative to the fixed axis of rotation is out of mechanical contact with two sections of the upper edge 15d. In this case, pollutants that may appear at this level are exposed to the gas stream and can be removed using this stream.

It is easy to understand that other geometric shapes can be considered, based on their characteristics, that these shapes do not correspond to a strictly circular path of movement of the corresponding contact surfaces of the spool. Of course, the present invention can be used with any number of crowns located on the distribution cover, usually in an amount of two in the case where the cover should be used in conjunction with a spool having a through axis, such as that shown in figures 1a and 1c, or in the amount of three in the case when the cover should be used in conjunction with a spool without a through axis.

Claims (3)

1. A membrane gas meter with a rotary distribution drive, comprising several measuring chambers and a distributor valve (2) mounted rotatably relative to a fixed axis of rotation on the upper surface of the distribution cover (1), in which several holes (10-12) are made, each of which is connected to one measuring chamber, moreover, this distribution valve (2) allows the gas to enter and exit the measuring chambers alternately during the rotational movement of the valve the circumference of the axis of rotation, and the distribution cover (1) contains at least two sealing crowns (15a, 15b) located essentially concentrically with respect to the fixed axis of rotation, on the upper flat edge of which the contact surfaces slip (25, 26 ) a spool valve, characterized in that the upper flat edge (15d) of at least one of the sealing crowns has a shape other than round, defined so that any point on the contact surface that is opposite this plane Coy top edge (15d), having a shape other than circular, at least once per one complete revolution provided without mechanical contact with this edge. 2. The gas meter according to claim 1, characterized in that the two sealing crowns (15a, 15b) contain an upper flat edge having a shape other than round. 3. Gas meter according to any one of the preceding paragraphs, characterized in that the said upper flat edge has the shape of an ellipse.

Images