DE1773954B2 - Dry gas meter - Google Patents

Description

A known gas meter according to the preamble of claims 1, 3 and 4 (DE-PS 1 86 185) has three Measuring chambers, which are separated from one another by two

2) other are separated. Correspond to the three measuring chambers at the top of the meter housing three inlet openings around a triangular outlet opening are arranged around. The supply or discharge of gas to or from the measuring chambers is through a

controlled in valve slide, which is above the inlet openings and the outlet opening is set in motion by a crank, whereby by a parallelogram guide it is ensured that the slide remains parallel to itself in every position. In the course

η of this movement, one inlet opening is always exposed to the influx of gas and one after the other this inlet opening is then connected to the outlet opening. The connection of a respective inlet opening with the outlet opening takes place via a

ι »Recess in the valve slide, which is arranged within the valve seat surface with which the valve slide slides over the inlet ports and the outlet port.

The crank that drives the valve slide is

T> in turn driven by a crank or lever gear, which is actuated by the membranes of the measuring chambers, which are under the influence of the measuring chambers Incoming gas or gas flowing out of it bulge out cyclically, but with a time delay.

V) To ensure that at any given time interval of a working cycle, ie one full turn of the valve slide, only one inlet opening is exposed to the flow of gas and only one other inlet opening with the

v, outlet opening is connected, the said parallelogram guide is assigned to the crank drive of the valve slide, which ensures that the valve slide does not change its position in the plane of its path of movement. This parallelogram guidance requires two

w) Link arms and a total of eight pivot bearings. That increases not only the manufacturing cost of the known gas meter, but also reduces the measuring accuracy of the known gas meter, because as a result of being moved together with the valve slide

tv, the masses of the parallelogram and the friction that occurs in the numerous joints of the valve slide occurs. In addition, this means that the space required by the meter is relatively large.

The invention is therefore based on the object of providing a valve slide drive for a gas cylinder To create the type described above, which has a smaller number of joints and in which the disadvantages mentioned do not occur.

To solve this problem, use is made of the principle that the valve slide is not only used a parallel shift, but also one at the same time Rotation experiences

Three constructive solutions are laid down in claims 1, 3 and 4, with the preamble in each case based on the gas meter according to DE-PS 1 86 185

In the gas meter according to claim 1, instead of the parallelogram guide present in the known gas meter, which prevents a change in the angle of the valve slide in the plane of its movement path .., a mounting of the valve slide is provided, which is formed by a pin engaging in an elongated hole is. The valve slide only experiences one point, namely the one where the crank of the Crank gear attacks, a pure circular motion, while its other points a rotary motion experience superimposed translational movement resulting from the pivoting about the pin axis and the displacement of the valve slide along the elongated hole

According to an advantageous development of the solution according to claim 1 it is provided that the pin of Pin / slot mounting on the meter housing adjustable jn This allows the working cycle of the membranes to be coordinated so that one continuous operation of the gas meter is achieved. The adjustment takes place transversely to the longitudinal direction of the elongated hole. r,

In the embodiment according to claim 3, the angular position of the valve slide changes in the plane of its Periodic movement path, although the swivel arm forming the guide is additionally driven is to, together with the crank acting on the valve slide, the continuous rotation of the valve slide to ensure. Above all, this embodiment results in a small size of the gas meter, since the valve slide itself is part of the crank mechanism.

In the solution according to claim 4, the Movement of the valve slide composed of two pivoting and sliding movements impressed on it, the can be initiated via the two swivel arms. The crank that also acts on the valve slide thus forms a pure guide that guides the valve slide at the point of application of the crank on a circular path. Even In this embodiment, the valve slide can be made smaller and smaller due to its combined movement Build lighter than the known gas meters and the design effort is lower.

Embodiments of the three basic embodiments of the invention are given below explained in more detail with reference to the drawings. In the drawings, mi shows

F i g. 1 is a partially sectioned plan view of a first embodiment of a gas meter (Claim 1);

F i g. 2 shows a side view of the gas meter according to FIG. 1, partly in section; b->

F i g. 3a, b a schematic representation of a valve grille with inlet openings and an outlet opening and a valve slide for the gas meter according to FIGS. 1,2;

Fig. 4-7 schematic representations, the four Illustrate relative positions of the valve slide to the valve grid during a work cycle;

F i g. 8 is a plan view of a second embodiment of the gas meter (claim 3);

F i g. 9 is a side view of the gas meter according to FIG. 8, partly in section and

F i g. 10 is an exploded perspective view of a valve slide and its drive for a third one Embodiment of the gas meter (claim 4).

The F i g. 1 and 2 show a dry gas meter 1, in which of four measuring chambers two each other are assigned in pairs. The two measuring chambers assigned to one another in pairs are in each case separated from each other by a membrane The meter housing 2 has two shell parts 3, 4, the are each attached to one side of the gas meter. The shell parts 3, 4 form the housing for the outer measuring chambers. The meter housing is closed at the top by a plate 5 in which an opening 6 is designed for the discharge of measured gas. The optional filling and emptying of the measuring chambers of the gas meter 1 takes place via a slide valve with a valve slide 7, which is equipped with a valve grille 8 cooperates, which is formed in the plate 5. For the drive of the valve slide 7 there is a drive device with rotating shafts 9 and 10 use, which are rotatable through not shown, with the membranes connected arms are driven.

An outwardly directed arm U of the valve slide 7 is provided with an elongated hole 12 into which an upwardly projecting pin 13 of the plate 5 engages. The valve slide 7 can thus around the pin 13 a Perform pivoting movement and at the same time move in the longitudinal direction of the arm 11 as far as this is possible with regard to the limits given by the ends of the elongated hole 12 which the pin 13 strikes.

According to Figure 2 are on the rotating shafts 9, 10 of this upward and radially outwardly extending pivot arms 14 and 15 attached to the free Ends of the pivot arms 14, 15 are tangential arms 16 and 17 articulated at an angle, which are shown in phantom in FIG are shown. These are in turn articulated to one another on a crank pin 18, which protrudes from a crank arm 19 at the upper end of a counter drive shaft 20 upwards. A case 21 for the count display is held by means not shown. The arrangement is such that the Counter drive shaft 20 is secured against lateral movement and only a rotational movement around their can run its own axis. The lower end of the counter drive shaft 20 has a crank 22 with a downwardly projecting crank pin 23 into one formed on the top of the valve slide 7 Bearing bore 24 engages freely rotatably. The bearing bore 24 can thus have a circular movement around the Run the axis of the counter drive shaft 20.

Due to the described mounting of the valve slide 7, it can execute a rotary movement, which is composed of two swivel movements, each of which is one of two at right angles mutually standing axes proceed during the valve slide 7 a movement around the stationary Executes pin 13, the elongated hole 12, which is displaced along the pin 13, has an effect as if a radial movement symmetrically around a movement

axis perpendicular to the pin 13, namely - in Fig. 1 - perpendicular to the longitudinal axis of the arm 11 would take place. Such a movement can take various forms; in the Embodiment according to FIGS. 1,2 the only constraining effect exerted on this movement is: that the bearing bore 24 has a continuous circular movement about the axis of the counter drive shaft 20 carries out The movement carried out from every other point of the valve slide 7 takes place always continuously, but not necessarily circular, but z. B. elliptical.

The counter gear has a worm 25 which is attached to the counting drive shaft 20 and cooperates with a worm wheel 26 attached to a display spindle 27.

In the case of the FIGS. The embodiment shown in FIGS. 1 and 2 is the space located above the plate 5 enclosed by a gas-impermeable housing, which is not shown. This housing forms the Inlet chamber of the gas meter. An outlet line 28, which leads upwards, connects to the opening 6 on, which is sealingly passed through said housing and connected to a distribution network is through an inlet opening formed in the housing, not shown, a corresponding Inlet line, for example the main gas line, can be connected to the gas meter.

The drive arrangement for the rotating shafts 9, 10 is known and will therefore not be described in detail. The movement of the diaphragms of the gas meter causes the swivel arms 14, 15 to oscillate which results in a rotary movement of the crank pin 18 about the axis of the counter drive shaft 20. in the In the course of this rotary movement, which is transmitted to the bearing bore 24 via the crank pin 23, one thing follows Pivoting the valve slide 7 about the pin 13 and at the same time also a reciprocating displacement movement of the valve slide 7 in the direction of the Elongated hole 12 This movement of the valve slide 7 has a corresponding opening or closing of the various valve openings which are formed in the valve grille 8 result.

The arrangement and design of the four measuring chambers of the gas meter 1 is as follows: The shell part 3 encloses a first measuring chamber A. Two further measuring chambers B and D are formed in the middle part of the meter housing 2 but are separated from one another by a wall formed in the meter housing 2 B is there - in FIG. 1 - arranged at the top In addition, there is another measuring chamber C within the shell part 4. The measuring chambers A and B are separated from one another by a membrane; There is a similar separation between the measuring chambers C and D.

3a shows the general outline of the valve grille 8 in dashed lines and the total of five passages in solid lines. The inlet openings A ', B \ C and D' establish the connection with the measuring chambers A, B, QD assigned to them. Fist denotes the outlet opening which is connected to the outlet line 28. 3a also shows the fixed pin 13 which controls the angular movement of the valve slide 7 in the plane of the valve seat surface

The Fig.3b shows a simplified form of the Valve slide 7 with the arm 11 protruding in the longitudinal direction and a head part 35. Γη the head part 35 a central recess 36 is formed. The rectangular recess 36 forms a dome-shaped chamber through which the measured backflow from the individual measuring chambers A, B, QD is measured

Gas to the centrally located outlet port E

got. The recess 36 enclosing

The valve seat surface of the head part 35 is flat and acts

together with the valve grille 8 in a sealing manner.

When the outer circumference of the valve slide 7 to

ίο is large, then the inlet openings A ', B', C and D 'are adequately sealed with respect to the gas inlet space during three quarters of the working cycle of the valve slide 7, but are only inadequate for the rest of the working cycle Gas inlet chamber open. It is therefore essential that the outer circumference of the valve seat surface of the valve slide 7 is kept as small as possible, like the The requirement for proper sealing to the inlet space allows this to be achieved through a design of the outer circumference of the head part 35 is obtained from the dashed line in FIGS. 4 to 7 results. This design provides that an outer edge of the head part 35, which has an inlet opening for But it seals the gas inlet space from the outlet opening The opening E out essentially coincides with the edge of the respective inlet opening which is furthest away from the outlet opening E. In a similar way, an enlargement of the recess 35 is achieved in that when a seal certain inlet opening opposite the gas inlet space as well as opposite the outlet opening E is the edge of the respective inlet opening which is closest to the outlet opening Earn essentially with the closest edge of the recess 36 coincides

The F i g. 4 to 7 show the valve slide 7 in each of the four main positions in dashed lines. The meter drive shaft 20 and the bearing bore 24 on the valve slide 7 are shown in FIGS. 4 to 7 shown in dashed lines to the To illustrate rotary motion. The area of an inlet opening open to the gas inlet space is shown in FIGS. 4 to 7 by cross-hatching and that of the recess 36, the outlet opening E and the inlet opening connected to the latter with a depression hatching provided.

According to FIG. 4, the inlet opening Λ 'to the outlet opening is open so that the measured gas can get there, while the inlet opening B' is open to the gas inlet space. The gas to be measured thus passes down through the inlet opening B ' into the measuring chamber Bund moves the membrane separating the measuring chambers A and B from one another in the direction of the measuring chamber A, the volume of which is thereby reduced. This will put the gas that has already been measured in the Measuring chamber A is ejected and passes upwards from the inlet opening Λ 'and via the recess 36 to the outlet opening E.

According to FIG. 5, the inlet opening D ' is open to the gas inlet space and the inlet opening C is open connected to the outlet port £. Here, too, the gas flowing in through the inlet opening D ' causes a movement of the membrane located between the measuring chambers C and D , whereby the gas already measured from the measuring chamber C through the inlet opening C " is pushed out to the outlet opening f.

According to a further quarter rotation of the crank pin 23, the position shown in Figure 6 is reached-in which the inlet opening to the gas inlet space toward Al

is open and the gas in the measuring chamber B is expelled through the inlet port B ' to the outlet port E. In the case of the FIG. 7 finally the inlet opening C is open to the gas inlet space and the inlet opening D 'is connected to the outlet opening E.

As shown in FIGS. 4 and 6, the part ρ of the outer edge of the valve slide 7 runs essentially in the same direction as the corresponding part p 'of the inlet opening D'. Similarly, the part q of the outer edge of the valve slide is substantially parallel to the corresponding part q 'of the inlet opening D'. This ensures that during the inlet cycle relating to the inlet opening D ' (FIG. 5), the inlet opening D' towards the gas inlet space is essentially completely open, but it is nevertheless open to the outlet opening E and the adjoining inlet openings A ' and B'. is sealed. The same applies to all other inlet openings.

The membranes between the measuring chambers must be coordinated in such a way that the Reaching the end point of their movement through one membrane, the other membrane is just theirs average deflection approaches or moves out of this. In the case of the above-described Embodiment of the gas meter according to the invention, such timing can be done in such a way that the pin 13 is displaced over the plate 5 in a direction which is transverse to the longitudinal direction of the arm 11 in FIG. 7 runs thereby can be a continuous Operation of the gas meter can be achieved. Once the correct timing has been determined, the can Pin 13 are clamped in the corresponding position. With all similar meters where the pen 13 is formed in one piece with the plate 5, this can from the outset in the corresponding position are provided.

FIG. 8 shows a plan view of a second embodiment of a gas meter according to the invention. Accordingly, an upper pivot arm 15 "is connected to the valve slide 7" via a pivot pin 45 " connected, which sits at the free end of the pivot arm 15 "and in a corresponding one at the end of an arm 40 "of the valve slide 7" engages in the recess formed.

According to Figure 9 is the upper end of a Counter drive shaft 55 immediately below the valve slide 7 "and is with a transverse crank 56 provided, which has a recess in the region of its free end engages through this recess a pin 57 therethrough which is integral with the valve slide 7 ″ and protrudes downward therefrom With one revolution of the counter drive shaft 55 leads thus the valve slide 7 ″ a movement, in the course of which the pin 57 follows a circular orbit about the axis of the counter drive shaft 55 describes

The upper ends of the swivel arm 15 ″ and another swivel arm 14 ″ are indeed within the gas meter at different heights, but are via a crank mechanism consisting of a Swivel arm 53, a crank element 54, the counter drive shaft 55, the crank 56, the pin 57 and the Arm 40 ", mechanically connected to one another. By appropriate arrangement and choice of between The crank angle given to these components of the crank mechanism can be designed in such a way by the gas meter be sure that his mode of operation takes place exactly in the desired time sequence.

Although in the case of the FIGS. 8, 9 there is only one point at which there is a direct attachment to an upper pivot arm, namely the connection between pivot 45 ″ and arm 40 ″, the same movement is achieved as in the the embodiment according to FIG. 10 discussed below. The upper swivel arm 15 "leads

ίο doing a swivel movement around the axis of the associated rotary shaft 10 ", while the pin 57 of the valve slide 7" a circular movement around the Axis of the counter drive shaft 55 executes. This results in a so-called "double-radial" movement.

The embodiment shown in FIGS can be built much smaller than the known gas meters of this type with the same gas throughput, since the meter transmission 52 below the valve mechanism of the gas meter within the gas outlet space is arranged. In addition, the two rotary shafts 9 ″ and 10 ″ are on in this embodiment attached to the same end of the meter housing and are not diagonally opposite, as is the case with the Embodiment according to FIGS. 1, 2 is the case. In this way the field of motion becomes the upper one Swivel arms and their associated articulated connections are reduced in size. As the F i g. 9 shows can at In this embodiment, purely circular membranes can also be used as the lateral shell parts are attached to the meter housing with circular flanges.

The valve slide T and its drive of a third embodiment of the gas meter according to the invention is shown in FIG. The valve grille 8 shown therein is similar to that which is also shown with reference to FIGS. 4 to 7 is described.

In this embodiment of the valve slide T tangential arms are dispensed with and the upper pivot arms 14 ′, 15 ′ are connected directly to the valve slide T. Two mutually perpendicular arms 40, 41 are formed on the valve slide T , at the free ends of which an elongated hole 42 or a bore 43 are provided. At the free end of the upper pivot arm 14 ', a pivot pin 44 protrudes upwards and engages in the bore 43. A pin 45 is provided at the free end of the swivel arm 15 ′ and engages in the elongated hole 42. A crank 22 is provided at the lower end of the counter drive shaft 20 and forms its axis of rotation. This is secured against lateral movement by attaching the housing 21

A recess 46 is provided in the crank 22, into which a pin 47, which is one piece with the top of the valve slide T, engages in a freely rotatable manner the swivel arms 14 ', 15' and the valve slide T have taken the place of the crank mechanism 14, 15, 16, 17, 18 and 19 used in the embodiment according to FIGS. The pivot arms 14 'and 15' are connected to the upper ends of rotating shafts 9,10. They each rotate freely over a small angular range so that the pivot pin 44 and the pin 45 can each move between two positions which are separated from one another by a distance denoted by 2R in FIG. The radius of the circular path described by the pin 47 is equal to the distance R and

λ; X I

10

the elongated hole 42 also has a length which is equal to 2R \ st.

As the upper pivot arm 15 'rotates about the axis of the rotating shaft 10 associated with it, the pin 45 moves back and forth on a path the length of which is equal to 2R . As a result, the valve slide T is pivoted about the bore 43, at the same time the pin 45 executes a certain movement in the longitudinal direction of the elongated hole 42. A similar rotational movement of the pivot arm 14 'about the pivot shaft 9 causes a movement of the pivot pin 44 and consequently the recess 43 on a path of length 2R. This has the consequence that the pin 45 passes through the elongated hole 42, due to the special design of the valve slide 7 'shown in FIG essentially performs a rotary movement. Because the counter drive shaft 20 is stuck and the crank 22 has a constant length, this movement can only take place in the form of a purely circular orbital movement, so that the counter drive shaft 20 and the counter are set in a corresponding rotary movement. During this rotary movement, the various parts of the valve grille 8 are connected to the gas inlet and the outlet opening, so that the membrane movement required for the rotation of the rotary shafts 9, 10 is thereby maintained. The valve slide movement described above with reference to FIGS. 3a, 3b is easier to imagine with the aid of the illustration in FIG. If the upper swivel arm 15 '

ίο pivoted by the rotary shaft 10, this results in a radial movement of the valve slide T about the pivot pin 44 on the other pivot arm 14 '. However, the pivot pin 44 is itself in motion as a result of the pivoting movement of the pivot arm 4 'through the rotary shaft 9 and thus causes a "radial" pivoting movement of the valve slide 7' about the pin 45 on the pivot arm 15 '.

In the embodiment described here, too, the inlet openings A ', B'. C, D ' and the outlet opening £ of the valve grille 8 be designed so that they are not only square, but also form irregular polygons with more than four sides.

In addition 6 matt drawings

Claims (4)

Patent claims: 1. Dry gas meter with several measuring chambers separated from one another by membranes and inlet openings respectively associated with the measuring chambers, which around an outlet opening are formed around in the meter housing, with a counter actuating valve slide, the one Circumferential valve seat surface on the edge and a recess for connection within the valve seat surface each has an inlet opening with the outlet opening, with one of the membranes of the Measuring chambers driven crank mechanism, one of which is rotatable on the valve slide is mounted and it along a circular path over the inlet openings and the outlet opening in such a way shifts that in the course of a working cycle each inlet port one after the other with a gas inlet and is connected to the outlet opening, and with one the position of the valve slide in the plane of its trajectory influencing leadership, characterized in that the Guide of the valve slide (7) is a pin / elongated hole storage (12,13). 2. Gas meter according to claim 1, characterized in that the in the elongated hole (12) of the Valve slide (7) engaging pin (13) of the pin / slot mounting on the meter housing (5) is arranged adjustable. 3. Dry gas meter with several measuring chambers separated from one another by membranes and inlet openings which are respectively associated with the measuring chambers and which surround an outlet opening are formed around in the meter housing, with a counter actuating valve slide, the one Circumferential valve seat surface on the edge side and a recess for connection within the valve seat surface each has an inlet opening with the outlet opening, driven by a diaphragm Crank mechanism, of which a crank is rotatably mounted on the valve slide and it along a Circular path over the inlet openings and the outlet opening shifts in such a way that in the course a duty cycle of each inlet port sequentially with a gas inlet and with the outlet port; is connected, and with a guide influencing the position of the valve slide in the plane of its trajectory, characterized in that that the valve slide (7 ") in addition to being driven by the crank (56) of the. Crank mechanism (14 ", 53, 54, 55, 56) by a parallel to the plane of movement of the valve slide (7 ") pivotable, articulated swivel arm (15") connected to the valve slide (7 ") is driven, which is drivingly connected to one of the membranes of the measuring chambers. 4. Dry gas meter with several measuring chambers separated from one another by membranes and with inlet openings assigned to the measuring chambers, which are formed around an outlet opening in the meter housing, with a valve slide which actuates a counter, which has a peripheral valve seat surface and a recess within the valve seat surface for connection each has an inlet opening with the outlet oil ηυη ^σ ! with a lever mechanism driven by the diaphragms of the measuring chambers, which drives the valve slide over the inlet openings and the outlet opening moves in such a way that in the course of a working cycle each inlet opening one after the other is connected to a gas inlet and to the outlet opening, characterized in that for the drive of the valve slide (7 ') two each drive-connected to one of the diaphragms, Swivel arms (14 ', 15') pivotable parallel to the plane of the movement path of the valve slide (7 ') are mounted on the meter housing, of which one swivel arm (H ') on the valve slide (7') is articulated and the other swivel arm (15 ') with a pin (45) in a on the valve slide (7') formed elongated hole (42) engages, and that the valve slide (7 ') with a parallel to the plane of the Movement path of the valve slide (7 ') is rotatably connected to the rotating crank (22), the axis (20) of which is stored in the meter housing